- Email: [email protected]
Antibacterial and invitro antioxidant potential of Indian mangroves
Journal Pre-proof Antibacterial and invitro antioxidant potential of Indian mangroves A. Arulkumar, K. Sampath Kumar, S. Paramasivam PII:
S1878-8181(19)30339-1
DOI:
https://doi.org/10.1016/j.bcab.2019.101491
Reference:
BCAB 101491
To appear in:
Biocatalysis and Agricultural Biotechnology
Received Date: 4 May 2019 Revised Date:
17 December 2019
Accepted Date: 30 December 2019
Please cite this article as: Arulkumar, A., Kumar, K.S., Paramasivam, S., Antibacterial and invitro antioxidant potential of Indian mangroves, Biocatalysis and Agricultural Biotechnology (2020), doi: https://doi.org/10.1016/j.bcab.2019.101491. This is a PDF file of an article that has undergone enhancements after acceptance, such as the addition of a cover page and metadata, and formatting for readability, but it is not yet the definitive version of record. This version will undergo additional copyediting, typesetting and review before it is published in its final form, but we are providing this version to give early visibility of the article. Please note that, during the production process, errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain. © 2019 Published by Elsevier Ltd.
1
Antibacterial and invitro antioxidant potential of Indian mangroves
2 3
A. Arulkumar*1,2, K. Sampath Kumar3 and S. Paramasivam1
4 5
1
6 7
2
8
3
9 10 11
Department of Oceanography and Coastal Area Studies, School of Marine Sciences, Alagappa University- Thondi Campus 623 409, Tamil Nadu, India. Achariya Arts and Science College, Villianur Puducherry- 605 110 (Affiliated Pondicherry University). Sengunthar Arts and Science College, Thiruchengode-637 205, Tamil Nadu, India. *
Email: [email protected]; Ph: +91-9597319098.
Abstract
12
Herbal tea is medicinally well-known for its biochemical composition and medicinal
13
usages. The present study proved for the first time that tea would be extracted from
14
mangroves, the plants other than commercial tea. Tea showed a theaflavin (TF), thearubigins
15
(TR), Total liquor color (TLC) and highly polymerized substantce (HPS). These characters
16
revealed the good quality of the tea. Phytochemical screening of tea revealed the presence of
17
phytochemical compounds such as protein, phenol and flavonoids etc. antioxidant properties
18
of tea were tested in invitro at varied concentrations. The antioxidant properties of R.
19
mucronata, R. apiculata, and R. annamalayana showed dose dependent activities and were
20
comparatively much higher in R. mucronata. R. mucronata (86.50±0.35%) showed much
21
higher total antioxidant activity followed by R. apiculata (73.34±0.90%) and R.
22
annamalayana (69.35±0.56%) at 100 µg/ml concentration. The antimicrobial activity was
23
highest in R. mucronata and R. apiculata than R. annamalayana as evident by the presences
24
of phenolic N-H and OH components found in tea. Therefore, it can be concluded that,
25
mangroves are rich source of tea, biochemical consititent, phytochemical, antioxidant and
26
antibacterial properties. The extract contained polyphenolic and other bioactive compounds
27
can be used as a development of herbal drug formuation and nutraceutical.
28 29
Keywords: Tea, Rhizophora mucronata, Phytochemical, antioxidant and R. annamalayana.
30
1. Introduction
1
31
India has a rich and prestigious heritage of mangrove forest oriented medicines among
32
the South Asian countries. However, the majority of these plants have not yet undergone
33
chemical, pharmacological and toxicological studies to investigate their bioactive compounds
34
(Kathiresan, 2000; Singh et al., 2009). Traditional records and ecological diversity indicate
35
that India plants represent an exciting resource for possible lead structures in drug design.
36
Plants are endowed with free radical scavenging molecules, such as vitamins, terpenoids,
37
phenolic acids, lignins, stilbenes, tannins, flavonoids, quinones, coumarins, alkaloids, amines,
38
betalains, and other metabolites, which are rich in antioxidant activity (Zheng and Wang,
39
2001). The mangrove plants naturaly syntheses many bioactive secondary metabolites. Such
40
plant-derived phytochemicals are highly unexplored for therapeutics. Mangroves are
41
biochemically unique, producing a wide array of novel natural products. They are rich in
42
polyphenols and tannins (Kathiresan and Ravi, 1990). In recent years, there is growing
43
interest in the discovery of noval compounds in mangroves resoures to control the emerging
44
human pathogenic microbes. Fascinatlingly, researchers have isolated a variety of other
45
mangrove compounds including taraxerol careaborin and taraxeryl cis-p-hydroxycinnamate
46
from leaves of Rhizophora apiculata (Kokpol et al., 1990); 2-nitro-4-(2'-nitroethenyl phenol)
47
from leaves of Sonneratia acida (Bose et al., 1992); alkanes (46.7–97.9% wax) and
48
triterpenoids (53.3% wax) from leaves of Rhizophora species (Dodd et al., 1995); and iridoid
49
glycosides from leaves of Avicennia officinalis and A. germinans (Fauvel et al., 1995; Sharma
50
and Garg, 1996). Phytoconstituent of R. mucronata was identified as Ethanone, 1-(2-
51
hydroxy- 5- methylphenyl as role in the antibiotic activity against human and fish pathogen
52
(Manilal et al., 2015).
53
In recent past years, mangrove plants have gained much importance due to its used in
54
fisher-folk medicine to treat various diseases (Bandaranayake, 2002) and it has been studied
55
for their medicinal properties. Coastal plant extracts have been tested against viruses that
56
cause human and animal diseases, such as human immunodeficiency virus (HIV), new castle
57
disease virus, vaccinia virus, semliki forest virus, encephalomyocarditis virus, and hepatitis-
58
B-virus (Kathiresan, 2000). A few of the mangrove plants belonging to family-
59
Rhizophoraceae are most effective against the viruses (Premanathan et al., 1992). Bioactive
60
compounds present in the mangrove plants and polysaccharides composed of galactose,
61
galactosamine, glucose and arabinose reported to have potent anti-HIV activity (Premanathan
62
et al., 1999). Scientific studies on a number of medicinal plants indicated that promising
63
phytochemical compounds can be developed for many health problems (Gupta, 1994).
2
64
These phytochemicals are indeed chemically complex and many structurally related
65
active compounds often produce a synergistic effect. Therefore medicinal plants are perhaps
66
the most valuable sources of new bioactive chemical entities to benefit mankind against
67
various ailments. Almost 122 pure chemical substances extracted from higher plants are used
68
in medicine throughout the world (Fabriant and Farnsworth, 2001). Therefore, it very
69
important to determined the phytochemical screening, bioactive compound (FTIR) and
70
biochemical constitutent in Rhizophora species for noval drug discovary, antibiotics and
71
navol nutraceutical compounds. However, for first time in this present investigation, was
72
evaluate the campartive study of phytochemical, antioxidant and antibacterial activity of
73
mangroves species viz. Rhizophora mucronata, R. apiculata and R. annamalayana. The
74
bioactive efficacy of tea, extracted from three mangrove Rhizophora species and
75
identification of the functional groups present in the tea extracts by using Fourier transform-
76
infrared spectroscopy (FT-IR) analysis.
77
2. Materials and Methods
78
2.1 Collection of mangrove leaves
79
The fresh mangrove leaves of Rhizophora mucronata, Rhizophora apiculata and
80
Rhizophora annamalayana were collected from the artificially developed Vellar Estuary
81
mangroves vegetation at Parangipettai, Tamilnadu, India. The river Vellar is flowing on the
82
Southeast Coast of India, mixing with the sea at Porto Novo (also known as Parangipettai;
83
Lat. 11° 29’ N; Long. 79° 47’ E). The estuary is connected to the Pichavaram mangroves
84
through the backwater channel. The mouth of the Vellar Estuary opens to the sea and a sand
85
bar sometimes closes it completely during summer season.
86
2.2 Preparation and extraction of tea
87
Black tea was extracted from the leaves of Rhizophora species, adopting the method of
88
Kathiresan (1995). Fresh leaves were allowed to dry using a warming blender. A known
89
weight of the macerated sample was placed in a piece of cloth and distilled water was
90
continuously trickled over it for 1hrs. The fermented sample was dried in hot air oven at 95°C
91
for 30 minutes. 1.25% of mangrove black tea was added to the boiling water and allowed to
92
infuse for 5 minutes, after which the infusions were filtered through sterile mambrean filter.
93
The filtrates were lyophilized and used for further study.
3
94
2.3 Tea quality constituents and Caffine content of Tea
95
Theaflavin (TF), Thearubigins (TR), Total liquor color (TLC), highly polymerized
96
substantce (HPS) and caffeine content were analysed, for determination of quality of tea
97
(Thanraj and Shesadari, 1990; Ronald and Ronald, 1991).
98
2.4 Qualitative analysis of phytochemical screening
99
The qualitative chemical constituents present in the tea extracts of mangroves plants were
100
determined by (Trease and Evans, 1989).
101
Proteins-xanthoprotein: to 1mL of extract, 3-5 drops of nitric acid was added by the sides
102
of the test tube and observed for formation of yellow colour indicated presence of proteins.
103
Steroids: two mL of acetic anhydride was added to 0.5 g of extract and 2 mL of sulphuric
104
acid was added by the sides of the test tube and observed the colour change from violet or
105
blue-green.
106
Tannins: about 0.5 g of the each extract was taken in a boiling tube and boiled with 20 mL
107
distilled water filtered and then added few drops of 0.1% ferric chloride mixed well and
108
allowed to stand for some time. Brownish green or a blue-black colouration was observed.
109
Glycosides─Keller-Killani method: about 0.5 mL of alcoholic extracts was taken and
110
subjected to the following test. One ml of glacial acetic acid containing traces of ferric
111
chloride and 1mL of conc. sulphuric acid were added to extract and observed for the
112
formation of reddish brown colour at the junction of two layers and the upper layer turned
113
bluish green in the presence of glycosides.
114
Reducing sugars─Fehling’s test: few drops of Fehling’s solution A and B in equal volume
115
were added in dilute extracts and heated for 30 min and observed for the formation of brick
116
red coloured precipitate.
117
Sterols-Liebermana-Buchard method: the insoluble residue was dissolved in chloroform
118
and few drops of anhydride were added along with a few drops of concentration H2SO4 from
119
the side of the test tube and the formation of blue to blood red color was obderved.
120
Terpenoids ─ Salkowski test: to 0.5 g of the extract, 2 mL of chloroform was added; conc.
121
H2SO4 (3mL) was carefully added to form a layer. A reddish brown coloration of the
122
interface indicates the presence of terpenoids.
4
123
Cardiac glycosides (Keller ─ Killiani’s test): 100 mg of extract was dissolved in 1 mL of
124
glacial acetic acid containing one drop of ferric chloride solution. This was then underlayered
125
with 1 mL of concentrated H2SO4. A brown ring obtained at the interface indicated the
126
presence of a de-oxy sugar charactersitcs of cardenolides.
127
Carbohydrates─Molisch’s test: small quantities of alcoholic and aqueous extracts were
128
dissolved in 5 mL of distilled water and filtered. To this solution 2−3 drops of α-naphthol was
129
added and 1 mL of concentrated H2SO4 was added along the sides of inclined test tube so as
130
to form two layers and observed for formation of violet coloured ring at the interface to detect
131
the presence carbohydrates.
132
Flavonoids: a portion of the acqueous extract (2 ml) was heated, and metallic magnesium
133
and concentrated hydrochloric acid (5 drops) were added. A red or orange coloration
134
indicated the presence of flavonoids.
135
Phenols: the extracts were taken in water and warmed. To this 2 mL of ferric chloride
136
solution was added and observed for formation of green or blue colour.
137
2.5 Chemicals and reagents
138
Butyled hydoxytoluene (BHT), DPPH (1, 1-diphenyl, 2-picrylhydrazyl), resazurin of
139
Sigma Chemicals, (USA) and all others high purity chemical reagents of Merck (Germany)
140
were used.
141
2.6 Estimation of Antioxidants assay
142
2.6.1 Estimation of total antioxidants
143
Total antioxidant activity was measured by the method of (Mitsuda et al., 1996). 7.45 mL
144
sulphuric acid (0.6 M solution), 0.9942 g sodium phosphate (28 mM solution) and 1.2359 g
145
ammonium molybdate (4 mM) were mixed together in 250 mL with distilled water and
146
labeled as total antioxidant capacity (TAC). 100 µL of extract was dissolved in 1mL of TAC
147
and the absorbance was read at 695 nm after 15 min. Butyled hydoxtoluene (BHT) was used
148
as positive control.
149
Calculation of 50% inhibitory concentration (IC50)
150
The concentration (µg/mL) of the fractions that was required to scavenge 50% of the
151
radicals was calculated by using the percentage scavenging activities at three different
5
152
concentrations of the fractions. Percentage inhibition (%) was calculated using the following
153
formula,
154
% Inhibition = [(Ac-As) /Ac] X 100
155
Where, Ac = absorbance of the control As = absorbance of the sample.
156
2.6.2 Determination of total phenol content
157
Total phenolic content of tea were estimated with the Folin-Ciocalteu’s method
158
(Singleton et al., 1999). Black tea extracts (10 mg) were dissolved in 10 mL of distilled
159
water. An aliquot of 100 µL of appropriate dilution of the samples were shaken for 1min with
160
500 µL of the folin-ciocalteu reagent freshly prepared in the laboratory and 6 mL of distilled
161
water. After the mixture was shaken 2 mL of 15% (mass per volume) sodium carbonate was
162
added and the mixture was shaken again for 0.5 min. Finally, the solution was brought up to
163
10 mL with distilled water. After 2 hrs of reaction at ambient temperature, the absorbance
164
was measured at 750 nm. Using gallic acid as standard, the total phenolic content of both
165
mangroves was expressed as gallic acid equivalents (GAE).
166
2.6.3 DPPH radical scavenging assay
167
The free radical scavenging activity of tea extracts were measured by DPPH according to
168
(Blois, 1958) method. 1 mL of DPPH (0.1mM) solution in methanol was added to 3 mL of
169
water extract of tea (100 µg/mL), shaken vigorously, allowed to stand at room temperature
170
for 30 min and the absorbance was measured at 517 nm in a UV-visible spectrophotometer
171
(U-2800 model, Hitachi, Japan). A low absorbance of the reaction mixture indicated the high
172
free radical scavenging activity. Butylated hytroxytoluene (BHT) was used as positive
173
control. The DPPH scavenging effect was calculated.
174
DPPH radical scavenging activity = {(Abs control – Abs sample) / (Abs Control)} × 100
175
Where; Abs control = absorbance of DPPH radical +BHT;
176
Abs sample = absorbance of DPPH radical + sample extract or Standard.
177
2.6.4 Total reducing power
6
178
Total reducing capacity of tea was determined according to the method of (Oyaizu,
179
1986). The tea extracts (100 µg/mL) in distilled water and 1% potassium ferricyanide were
180
mixed with phosphate buffer (0.2 M, pH 6.6) and the mixture was incubated at 50°C for 20
181
min. 2.5 mL of 10% TCA was added to the reaction mixture which was centrifuged at
182
1000×g for 5 min. The upper layer of the solution (2.5 mL) was mixed with distilled water
183
(2.5 mL), FeCl2 (0.5 mL, 0.1%) and the absorbance was measured at 700 nm. Ascorbic acid
184
was used as a positive control. The higher absorbance of the reaction mixture indicated the
185
greater reducing power.
186
2.6.5 Nitric oxide radical (NO*) scavenging activity
187
Nitric oxide radical scavenging activity was determined by the method reported by
188
(Garrat, 1964). Sodium nitroprusside in aqueous solution at physiological pH spontaneously
189
generates nitric oxide, which interacts with oxygen to produce nitrite ions, which can be
190
determined by the griess-illosvoy reaction. Briefly, 3 mL of the reaction mixture containing
191
10 mM sodium nitroprusside and the tea extract (100 µg/mL) in phosphate buffer were
192
incubated at 25°C for 150 min. After incubation, 0.5 ml of the reaction mixture was mixed
193
with 1mL of sulfanilic acid reagent (0.33% in 20% glacial acetic acid) and allowed to stand
194
for 5 min for complete diazotization. Then 1 mL of naphthyl ethylene diamine
195
dihydrochloride (0.1%) was added and after mixing well the solution was allowed to stand
196
for 30 min at 25°C. A pink coloured chromophore was formed in diffused light. The
197
absorbance of these solutions was measured at 540 nm against the corresponding blank
198
solutions. BHT was used as positive control. Nitric oxide scavenging activity of the tea
199
extract is reported as % inhibition and was calculated.
200
NO radical scavenging activity = {(Abs control – Abs sample) / (Abs control)} × 100
201
Where; Abs control = absorbance of NO radical + BHT; Abs
202
Sample = absorbance of NO radical + sample extract or standard.
203
2.7 FT-IR analysis of tea
204
For this 2 mg of the tea extracts samples of (R. mucronata, R. apiculata and R.
205
annamalayana) were mixed with 200 mg KBr (FT-IR grade) and made into thick pellets in a
206
hydraulic press by allying 500 Kg/m3 pressure. The pellet was immediately placed into the
7
207
sample holder and FT-IR spectra were recorded between ranges of 7800–350cm-1 (Mid-IR)
208
for the compound under study. FT-IR spectra of the purified compound were recorded on a
209
Shimadzu, Model No: A21374801626, Japan FT-IR spectrometer.
210
2.8 Bacterial strains and culture conditions
211
Bacterial cultures namely Staphylococcus aereus, Escherichia coli, Salmonella typhi, and
212
Proteus vulgaris were obtained from the CAS in Marine Biology, Annamalai University,
213
Parangipettai, India. The above cultures were long term storage took place at -20 oC in
214
Nutrient broth (Hi Media, Mumbai, India) supplemented with 50% glycerol. Before
215
experimental use each strain was grown twice in Nutrient broth at 37 oC for 48 h.
216
2.8.1 Determination of In vitro antibacterial activity against human pathogenic bacteria
217
The antibacterial activity of the tea extracts (R. mucronata, R. apiculata and R.
218
annamalayana) was performed by the well diffusion method on Muller-Hinton agar MHA
219
(Hi media, India). About 100 µL of 105 CFU/ml diluted inoculum bacterial culture was
220
applied on the surface of MHA plates and allowed to solidify. MHA well was made with well
221
borer under aseptic conditions and filled with mangroves tea extract samples and DMSO as
222
used as negative control and penicilin was act as positive control. The plates were incubated
223
at 37oC for bacterial growth/ the antibacterial activity of the mangrove samples was evaluated
224
by measuring the zone of inhibition against the test human pathogenic bacteria. All the
225
experiments were done three times and the data were expressed as the mean values of
226
experiments.
227 228 229
2.9 Thin layer chromatography (TLC)
230
apiculata and R. annamalayana (Abu et al., 2011). Methanol and chloroform (1:9) was used
231
as mobile phase. The sample with the concentration of about (1 mg/mL) was spotted on the
232
TLC plates and dried. The spots were identified in long UV, short UV and also in the iodine
233
chamber. Rƒ value was calculated to find the active metabolites. Rƒ value is distance
234
travelled by the solute to the distance traveled by the solvent.
235
3.0 Statistical analysis
TLC is used to separate the bioactive compounds present in the tea extract R. mucronata, R.
236
Datas were expressed in triplicates (n=3) and strandard devision. The data were obtained
237
were analyzed by the one way analysis of variation (ANOVA), with a P values of < 0.05
8
238
being significant. All the statistical were performed using the OriginPro version 8.0 statistical
239
package.
240
4. Results and Discusion
241
4.1 Physical nature of tea
242
The present study evaluated that phytochemical constituent of tea from the three
243
mangroves species, R. mucronata, R. apiculata and R. annamalayana. The black tea extract
244
showed a golden brown colour with pleasant aroma taste. These characters revealed the good
245
quality of the tea. It was observed that, the maximum yield of tea was obtained for the R.
246
mucronata. The percentage yield of R.mucronata (0.125%) followed by R. apiculata
247
(0.121%) and R.annamalayana (0.110%) respectively. The colour and the yield of the tea
248
extraction might be attributed to the levels of polyphenol content.
249
4.2 Tea quality constituents of tea extracts
250
The chemical constituent and quality of tea determined theaflavin (TF), Thearubigins
251
(TR), Total liquor color (TLC), highly polymerized substantce (HPS) and caffeine content
252
statistically significance different with P< 0.05 were presented in (Table 1). The R.
253
mucronata was observed to possess higher TF 0.42±0.02% when compared to R.apiculata
254
(0.18±0.02%) and R. annamalayana (0.5±0.08%) tea extracts. The higher thearubigins (TR)
255
was observated in R. mucronata (4.60±0.24%) followed by R. annamalayana and
256
R.apiculata. The R.mucronata was observed to possess higher HPS 4.71±0.20% followed by
257
R.apiculata 3.9±0.29% and R.annamalayana 3.95±0.18%. The total liquire colour (TLC) was
258
higher R. mucronata in (1.1±0.14%) followed by R. annamalayana (0.51±0.03%) and R.
259
apiculata (0.49±0.03%). Coffien content all the three mangroves speices was not detected
260
(ND). It was observed that, R. mucronata contains higher TF, TR, TLC and HPS content than
261
R. apiculata and R.annamalayana. Venkatesan et al. (2005) have repoted that, the polyphenol
262
found in the tea leaves and it important responsible for all the biochemical reaction with
263
contribution to make a good quality of tea. The chemical basis of the quality of mangrove
264
black tea indicated theaflavin (TF), Thearubigins (TR), Total liquor color (TLC), highly
265
polymerized substantce (HPS) are the important factors determine the liquor quality of
266
mangrove black tea. Liang et al., (2007) have reported that, the tea owing to its favorable
267
benefits on human health dring currently enjoys a great popularity among other beverages
268
throught out the worldwide. In this study, higher TF, TR, TLC and HPS was oberverved in
9
269
R.mucronata followed by other potential species (Table 1). Bagyalakshmi et al., 2012 have
270
reported that, the quality of tea characterisitics TF, TR, HPS, TLC and caffeine 0.8, 7.6, 7.2,
271
2.3 and 2.1 respectively in Camellia sinensis. In This study first time proved that HPS was
272
higher in R.mucronata (4.71±0.20%) followed by R.apiculata (3.9±0.29%) and
273
R.annamalayana (3.95±0.18%) and there is no caffien content in all the Rhizophora species.
274
4.3 Qualitative analysis of phytochemical constituents
275
Phytochemical constituents of R. mucronata, R. apiculata and R. annamalayana were
276
qualitatively analyzed and the results are presented in (Table 2). The tea extract of all the
277
three species viz. R. mucronata, R. apiculata and R. annamalayana showed the presence of
278
phytochemical active compounds such as xanthoprotein, steroids, tannins, glycosides,
279
reducing sugar, carbohydrates, sterols, terpenoids, phenol, cardioglycosides and flavonoids.
280
Mangroves and mangrove associates possess novel agrochemical products, compounds of
281
medicinal value, and biologically active compounds (Bandaranayake, 2002). The
282
phytochemical screening of tea extracts of R. mucronata, R. apiculata and R. annamalayana
283
revealed the presence of tannins, flavonoids, steroids and saponins. Its clearly indicates that,
284
the presence of the functional group –OH in the structure and positions of the flavonoid
285
molecules to determine the phytochemical capacity. Recently, Saranya et al. 2014 reported
286
that, the important active metabolities find out through the phytochemical screening
287
R.mucronata showed the presence of alkaloids, terpenoids, steroids, tannins, quinines,
288
sapnins, flavonoids, cardiac glycosides and phenol, which corroborates the results of the
289
present study. Abdurahman et al., (2016) reported that, the Rhizophora species have various
290
phyo-chemical compounds includes alcohol, aldehydes, aminoacids, aromatic carboxylic
291
acid, carbohydrates, carboxlic acids, esters, fatty acids, flavonoid, ketone, lipids, phenol,
292
saponins, steroids, tannin and terpenoid for the biological acitivity.
293 294
These results support the finding that mangrove plants are a rich source of steroids,
295
triterpenes, saponins, flavonoids, alkaloid and tannins (Agramoorthy et al., 2008;
296
Bandarnayake, 2002). Alkaloids, tannins, flavonoids and other phytochemicals are present in
297
other plants as well (Barnabas and Nagarajan 1988). In the present study it is found that
298
Rhizophora species contain these secondary metabolities which showed phenolic compounds
299
(N-H and OH molecules) and other substance. Hence, the beneficial medicinal effects of
300
plant material may result from the combinations of secondary products present in the plant.
10
301
Secondary products play a role in a plant defense through cytotoxity towards microbial
302
pathogens (Briskin, 2000).
303
Tannins are known to be useful in the medicine flok and treatment of inflamed or ulcerated
304
tissue and thery remarkable anticancer (Ruch et al., 1989). Thus, Rhizophora species
305
containing bioactive compounds and its may serve as a potential sources of bioactive
306
compounds in the treatment of cancer. The presence of phenol compounds in this Rhizophora
307
species may contribute to their antioxidant and antibacterial propertices, its very usefulness
308
developments of herbal medicine and nuetraceuticals. Earlier study reported that, the
309
phenolic compounds may exhibit a widal range of physiological function, such as anti
310
bacterial, anti fungual, antioxidant, anti inflammatory, anti artherogenic, anti thrombotic
311
effects (Benavente et al., 1997; Samman et al., 1998; Puupponen-Pimia et al., 2001; Manilal
312
et al., 2015; Abdurahman et al., 2016).
313
4.4 Antioxidant
314
The antioxidant activities of tea extracts of three mangrove species, R. mucronata, R.
315
apiculata and R. annamalayana at different concentration are shown in (Fig.1a-e). It was
316
found that, of the three species of tea extracts screened, R. mucronata (100 µg/ml) showed
317
significant levels of antioxidant properties, in terms of total antioxidants, total phenol, DPPH
318
assay, and total reducing power and nitric oxide radical scavenging activity. The total
319
antioxidant activity of the tea extracts increased with increase in concentration (P< 0.05). The
320
result suggested that, the R. mucronata showed highest total antioxidant activity of
321
85.50±0.35% when compared to R. apiculata 73.34±0.90% and R. annamalayana
322
69.35±0.56% at the concentration of 100 µg/ml respectively (Fig.1a). It was observed that,
323
R.mucronata contains 12.16% and 16.15 % time’s higher total antioxidant activity than
324
R.apiculata and R.annamalayana. Gao and Xiao, 2012 reported that, the Rhizophora species
325
contains lyoniresinol-3α-o-β-arabinopyranoside, lyoniresinol-3α-O-β-rhamnoside, afzelechin-
326
3-rahmnoside bioactive compounds for antioxidant and better radical scavenging activity.
327 328
The total phenol contents of the tea extracts are possibly proportional to the
329
concentration. The highest TPC was observed from R. mucronata 84.80±1.47% followed by
330
R. apiculata 79.23±0.70% and R. annamalayana 74.35±0.90% at the concentration of 100
331
µg/ml significance level (P< 0.05) (Fig.1b ). It was clearly noted that, R.mucronata contains
332
5.59% and 10.45% times higher total phenol content than R.apiculata and R.annamalayana.
333
Pandima Devi et al. 2009 have reported that, the TPC of R.mucronata was 720.7 mg GAE/g
11
334
for methanolic extracts which corrabotes the results of R.mucronata in the present study. The
335
higher content of phenolic in mangroves tea extracts indicates a better free radical scavenging
336
ability, which can prevent lipid oxidation in food products. Screening of antioxidant
337
substances derived from natural resources is one of the basic tool for drug design and
338
development. Agoramoorthy et al. 2008 have reported that, the TPC higher phenol content of
339
R. mucronata and R.apiculata was 157.4 mg GAE/g and 302 mg GAE/g for dry weight
340
respectively, which was comparatively much higher than the results of the present experiment
341
(Fig.1b). Recently, Wei et al. 2010 reported that, the TPC of mangrove plant (Kandelia
342
candel) was 400.43µg GAE /ml. Haq et al. 2011 have reported that, the total phenol content
343
of Bruguiera gymnorrhiza was 178.73 mg GAE/g of dry leaves. The present study indicates
344
that R.mucronata, R. apiculata, and R. annamalayana tea extracts were potential free radical
345
scavengers, wich reacted with free radicals by donating their hydrogen (H2) and act as
346
primary antioxidants and prevent oxidation.
347
Several free radical such as OH, O2, LOO have different reactivities are formed
348
during lipid oxidation. Antioxidants are able to scavenge these radicals by donating H iorns.
349
Relatively stable DPPH radical has been widely used to test the ability of compounds to act
350
as free radicals scaverngers or H irons donors and thus to evaluate the antixodant activity (Jao
351
and Ko, 2002). In this study, evident that the ability of DPPH radicals scavenging activity of
352
tea extracts is shown in (Fig.1c). The activity of tea extract increased with increase
353
concentration (P< 0.05). The result suggested that, the IC50 value of R. mucronata showed
354
highest radical scavenging activity was 91.83±1.26% when compared to 78.92±1.72% for R.
355
apiculata and 90.87±1.56% for R. annamalayana at the concentration 100 µg/ml
356
respectively. Pandima Devi et al. 2009 have reported that, the IC50 value of R.mucronata
357
DPPH was 43.171µg/ml, which was comparatively much lower than the results of the present
358
study. Similalry, Agoramoorthy et al., 2008 have reported that, the DPPH free radical
359
scavengers
360
comparable to our results (93.39 and 90.31%). Wei et al., 2010 have reported that, the DPPH
361
radical scavengers was 115.67 µg/ml in K.candel in 70% acetone extracts, which was
362
comparatively higher than the results of the present study. The high radical scavenging
363
activity of R. mucronata could be due to presence of flavonoids that can be perform radical
364
scavenging activity action of on free radical (DPPH, hydroxyl and hydrogen H2O2) for their
365
reduction of hydroxide formation. In this study, the presence of the functional group -OH in
366
the structure and its position of flavonoid and or phenol molecules determine the antioxidant
in R. mucronata and R.apiculata were 79.9 and 64.7 µg/ml, which was
12
367
activity (Fig.1c). This suggests that the mangrove extracts contain compounds that are
368
capable of donating hydrogen to a free radical in order to remove odd electron which is
369
responsible for radical's reactivity (Wang et al., 1998). Research also indicates that the total
370
antioxidant and DPPH scavenging potential are particularly suitable for the evaluation of
371
antioxidant activity of crude extracts (Poli et al., 2003). The result of DPPH scavenging
372
activity assay in this study indicated that the mangroves species were potently active.
373
Reducing capacity of tea extracts can serve as a significant indicator of their potential
374
antioxidant activity. The total reducing ability of the mangrove black teas were evaluvated at
375
different varied concentrations (50,100, 500 mg/mL) are shown in (Fig.1d). Among the three
376
tea extract tested, R. mucronata showed maximum reducing power at all the concentrations
377
(P< 0.05) and showed highest reducing activity R. mucronata 0.9733±0.55% when
378
comparted for R. apiculata 0.9276±1.84% and R. annamalayana 0.8255±1.20% at the
379
concentration of 500 µg/ml (Fig.1d). Similarly, Pandima Devi et al. 2009 have reported that,
380
the reducing capacity of R.mucronata, R.apiculata and R.annamalayana were 0.360, 0.263
381
and 0.259 µg/ml, which was comparatively much lower than the present study. The reducing
382
capacity of a compound may serve also as an important indicator of its potential antioxidant
383
activity. The results of high reducing power of R.mucronata were agreement with highest
384
DPPH activity of the present study. The reducing properties are thought to be associated with
385
the development of reductones, which have been shown to exert antioxidant action by
386
terminating the free radical chain reactions by donating a hydrogen atom. Reductones are also
387
reported to react with certain precursors of peroxide, thus preventing peroxide formation
388
(Singh and Rajini, 2004). The result of teas were capable of reducing Fe3+ to Fe2+, which was
389
related to the capability of donating electrons of the present phenolics, suggesting that teas
390
may act as the terminators of free radical chains, transforming reactive free radical species
391
into more stable non-radical products. The antioxidant capacity of flavonoids may improve
392
endothelial function by lowering oxidative stress. Better endothelial function impacts on
393
vasomotor tone, platelet activity, leukocyte adhesion and vascular smooth muscle cell
394
function. Studies have shown that black tea flavonoids improve coronary circulation Hirata et
395
al., (2004) and attenuate endothelial dysfunction in humans (Duffy et al., 2001). The results
396
suggested that, a reducing power of the compound appears to be related to degree of
397
hydroxylation and extent of conjugation in polyphenols wich was seen in tea extracts
398
especially in R.mucronata when comapare to R.apiculata and R. annamalayana.
13
399
NO* causes ischemic injury, the toxicity of the due to increases on reaction with O2*-
400
to produce ONOO-, wich reacts with biomolecules like DNA, proteins, lipids (Halliwell,
401
1991). Nitric oxide was generated when sodium nitro preside reacts with oxygen to form
402
nitrite. Suppression of NO* release may be attributed to a direct NO* scavenging effect of tea
403
extracts decreasing the amount of nitrite generated from the decomposition of sodium nitro
404
preside invitro as shown in (Fig.1e). The nitric oxide radical scavenging activity of three
405
mangrove extracts increased as the concentration increased (P< 0.05). The maximum activity
406
was observed from R. mucronata (75.33±0.91%) followed by R. apiculata (72.53±1.65%)
407
and R. annamalayana (62.8±1.53%) at the concentration of 100 µg/ml. Similarly, Pandima
408
Devi et al., 2009 found that NO* scavenging values of R.mucronata, R.apiculata and
409
R.annamalayan were 58.14, 27.5 and 29.7 µg/ml in nitric oxide assay. Nitric oxide (NO) is a
410
reactive free radical produced by phagocytes and endothelial cells, to yield more reactive
411
species such as peroxynitrite which can be decomposed to form OH radical. The level of
412
nitric oxide was significantly reduced in this study by the black tea extracts. Since NO plays a
413
crucial role in the pathogenesis of inflammation (Moncada et al., 1991), this may explain the
414
use of Rhizophoraceae members for the treatment of inflammation and for wound healing.
415
Table 4 showed biological potential i.e antioxidant, antibacterial and phytochemical and
416
others activities in the mangroves species of this region was compared with different region
417
in this world.
418
The tea extracts was analyzed by FT-IR to identifiy the functional groups in the
419
bioactive components based on its peack values and electron transition of compounds shown
420
in Fig 2a, 2b and 2c. The FT-IR spectrum for the methanolic extracts of R.mucronata,
421
R.apiculata and R.annamalayan with its peak values were observed at 441,665,754, 1028,
422
1228, 1450, 1664, 2044, 2222, 1255, 2599, 2833, 2943, 3348, 3350 and confirmed the
423
presence of the chloro alkanes, flour alkenes/ phenol, alkenes, nitrile, amide, methylene,
424
methyl, alcohol/phenol/ flavonoid.
425
4.5 Antibacterial activity
426
The antibacterial activity of tea from Rhizophoraceae members (R. mucronata, R.
427
apiculata and R. annamalayana) showed significant and effective antimicrobial activity
428
against human pathogenic bacterial strains (Escherichia coli, Salmonella typhi, Proteus
429
vulgaris and Staphylococcus aureus) tested and the results are shown in (Table 3). No zone
430
of inhibition was observed in DMSO (negative control) and the positive control of penicillin
14
431
tested for antibacterial activity exhibited maximum zone of inhibio of 13.1±0.02 mm against
432
Salmonella typhi. R.mucronata showed higher antibacterial activity compared with
433
R.apiculata and R.annamalayan, R.mucronata was more effective against E. coli, S. typhi and
434
P.vulgaris compared to gram positive bacteria like S. aureus. These results are in agreement
435
with reported given by Kumar et al. 2011 observed that, the Avicinea marina, E.agallocha,
436
and C.decandra showed higher antibacterial activity against S.aureus, Bacillus subtilis,
437
S.epidermides, E.coli, P.aeruginosa and K.pneumoniae at methanolic extract. The
438
antimicrobial properties of mangroves extracts could be due the presence of core compounds
439
Ethanone, 1-(2-hydroxy- 5- methylphenyl), which might play an important role in their
440
antibacterial activity (Manilal et al., 2015). Extracts from different mangrove plants and
441
mangrove associates are active against human and plant pathogens (Chandrasekaran et al.,
442
2009). This indicates that R. mucronata, R.apiculata and R. annmalayana tea extracts showed
443
more antibacterial activity against Staphylococcus aereus, Proteus vulgaris and E.coli than
444
other strains. These results indicated that, the effective anti bacterial activity due to the
445
potential bioactive, functional group OH and N-H group (Phenol and flavonoids) present of
446
mangrove plants. Recently Abdurahman et al., 2016 documented that, the antimicrobial
447
compouns present in Rhizophora sp includes polyphenols, carbohydrates, fatty acids, palmitic
448
acid, cis and trans isomers of oleic acid, linolenic acid miristic acid, tannin and sterols.
449
4.6 TLC
450
The methanol extract with a concentration of 1 mg/mL reported the presence of three major
451
compounds with Rf values of 0.50, 0.36 and 0.14 in R.mucronata, 0.49, 0.46 and 0.12 in
452
R.appiculata and 0.52, 0.31, 0.11 in R. annmalayana as visualized under iodine chamber and
453
UV light. The larger Rf value of a compound, the larger the distance it travels on the TLC
454
plate.
455
CONCLUSION
456
The present study concluted that mangroves are rich source of tea extracts. The extracts
457
contained phenolic and polyphenolic compounds that exhibited high antioxidant properties
458
and considerable antibacterial activities against human bacterial pathogens. The tea extracts
459
had stable scavenging activity against the free radial molecules prevent cell and DNA
460
demage. The most powerful antioxidant activity of Rhizophora species can be accredited to
461
neutralizing and scavenging ability of the free radicals. The leaf extracts of mangroves in
15
462
particular Rhizophora species has potential to be developed as an herbal drug and
463
nutraceutical and thus in curing infective human diseases. Furthermore, research is needed to
464
elucidate the complete mode of action and application of phenol compounds to prevent the
465
human bacterial pathogenic diseases and aquatic pathogenic bacteria.
466
Acknowledgements
467
The authors are thankful to the authorities of Alagappa University, Tamilnadu, India, for
468
providing necessary facilities to carry out this research work.
469
Conflicts of interest
470 471
All the authors declare that there is no potential conflict of interest. 6. References
472 473
Abdurahman,
N.H., Nitthiya,
J., Omer, M.S. 2016.The Potential of Rhizophora
474
mucronata Composition and Biological Activities asMangrove Plants: A Review.
475
Aust. J.Bas. Appl. Sci., 10(4), 114-139.
476
Abu, OM., Abdul, AM., Rowshanul, HM., Rezaul, KM. 2011. Antimicrobial
477
investigation on Manilkara zapota (L.) P. Royen. Int J Drug Develop Res. 3, 185-
478
190.
479
Agoramoorthy, G., Chen, FA., Venkatesalu, V., Kuo, DH., Shea, PC. 2008. Evaluation of
480
antioxidant polyphenols from selected mangroves plants of India. Asian. J. Chem.
481
20(2), 131-1322.
482
Bagyalskshime, B., Ponmurugan, P., Marimuthu, S. 2012. Influence of potassium
483
solubilizing bacteria on crop productivity and quality of tea (Camellia sinensis). Afr.
484
J. Agric. Res. 7(30), 4250-4259.
485 486 487 488 489 490 491 492
Bandaranayake, WM. 2002. Bioactivities, bioactive compounds and chemical constituents of mangrove plants. Wetl. Ecol. Manag. 10, 442 - 452. Barnabas, CG., Nagarajan, S. 1988. Antibacterial activity of flavonoids of some medicinal plants. Fittoterapia. 3, 508-10. Benavente, GO., Castillo, J., Marin, FR., Ortuno, A.,
Del, RJA. 1997. Uses and
properties’ of citrus flavonoids. J.Agric. Food Chem. 45, 4505- 4515. Blois, M.S. 1958.Antioxidant determination by the use of a stable free radical. Nature. 181, 1199 -1120. 16
493
Bose, AK., Urbanczy, k., Lipkowska, Z., Subbaraju, GV., Manhas, MS., Ganguly, SN.
494
1992. In: Desai, B.N. (Ed.). Oceanography of the Indian Ocean. Oxford and IBH,
495
New Delhi. Pp. 407- 411.
496 497 498 499
Briskin, DP. 2000. Medicinal plants and phytomedicines: Linking plant biochemistry and physiology to human health. Plant Physiol. 124: 507-14. Dodd, R.S., Fromard, F., Rafii, Z.A., Blasco, F. 1995. Biodiversity among West African, Rhizophora: Foliar wax chemistry. Bio. Sys. Ecol. 23 (7-8), 859 - 868.
500
Duffy, SJ., Keaney, JF., Holbrook, M., Gokie, N., Swerdloff Fueib, PT. 2001. Short–and
501
long–term black tea consumption reverses endothelial dysfunction in patients with
502
coronary artery disease. Ciruclation. 104, 151-156.
503 504 505 506 507 508 509 510 511 512 513 514 515
Fabricant, DS., Farnsworth, NR. 2001. The value of plants used in traditional medicine for drug discovery. Environ. Health Perspect. 11, 69-75. Fauvel, MT., Bousquet Melou, A., Moulis, C., Gleye, J., Jensen, SR. 1995. Iridoid glycosides from Avicennia germinans. Phytochem. 38 (4): 893- 894. Gao, M., Xiao, H. 2012. Activity-guided isolation of antioxidant compounds from Rhizophora apiculata. Molecules. 17(9): 10675-10682. Garrat, DC. 1964. The quantitative analysis of drugs. Chapman and Hall Ltd, Takyo.3: pp. 456- 458. Gupta, S. 1994. Prospects and perspective of natural plants products in medicine. Indian J Phamacol. 26, 1- 12. Halliwell, B. 1991. Reactive oxygen species in living systems: source, biochemistry, and role in human disease. Am J Med. 91, 14-22. Haq, M., Sani, W., Hossain, A.B.M.S., Taha, RM., Monneruzzaman, K.M. 2011. Total
516
phenolic
contents,
antioxidant
and
antimicrobial
517
gymnorrhiza. J Med. Plant Res. 5(17), 4112-4118.
activities
of
Bruguiera
518
Hirata, K., Shimada, K., Watanabe, H., Otsuka, R., Tokai, K., Yoshiyama, M. 2004.
519
Black tea increases coronary flow rate velocity reserve in healthy male subjects.
520
Am. J. Cardiol. 133, 1384 - 1388.
521 522
Jao, CH., Ko, WC. 2002. 1, 1- Diphenyl-2- picrylhydrazyl (DPPH) radical scavenging by protein hydrolysates from tuna cooking juice. Fich Sci. (68), 430-435.
523
Kathiresan, K. 1995. Studies on tea from mangroves leaves. Environ. Ecol. 13, 321- 323.
524
Kathiresan, K. 2000. A review of studies on pichavaram mangroves, southeast India,
525
Hydrobiologia. 430, 185- 205.
17
526 527
Kathiresan, K., Ravi, V. 1990. Seasonal changes in tannin content of mangrove leaves. Indian Forester. 116 (5), 390 − 92.
528
Khafagi, I., Gab-Alla, A., Salama, W., Fouda, M. 2003. Biological activities and
529
phytochemical constituent of the gray mangrove Avicennia marina (Forssk,) Vierh.
530
Egyptian J Biol. 5, 62-69.
531
Kokpal, V., Miles, DH., Payne, AM., Chittawong, V. 1990. Chemical constituents and
532
bioactive compounds from mangroves plants. Studies in Natural Products
533
Chemistry. 7:175- 199.
534
Kumar, VA., Ammani, K., Siddharadha, B. 2011. In vitro antimicrobial activity of leaf
535
extracts of certain mangrove plants colleted from Godavari estuarine of Konaseema
536
delta, India. Int. J. Med. Arom. Plants. 2249-4340.
537
Liang, CAE., Zhi-Xiu Zhou, AE., Ya-Jun, Y. 2007. Genetic improvement and breeding of
538
tea plant (Camellia sinensis) in China: from individual selection to hybridization and
539
molecular breeding. Euphytica. 154, 239-248.
540
Manilal, A., Merdekios, B., Idhayadhulla, A., Muthukumar, C., Melkie, M. 2015. An
541
invitro antagonistic efficacy validation of Rhizophora mucronata. Asian Pac J Trop
542
Dis. 5(1), 28-32.
543
Mitsuda, H., Yuasumoto, K., and Iwami, K. 1996. Antioxidation action of indole
544
compounds during the autoxidation of linoleic acid. Eiyo to Shokuryo. 19, 210- 214.
545
Moncada S, Palmer RMJ, Higgs EA. 1991. Nitric oxide: physiology, pathophysiology
546
and pharmacology. Pharmacol. Rev. 43, 109- 142.
547
Osawa, T. 1994. Novel natural antioxidants for utilization in food and biological systems.
548
In: Uritani I, Garcia VV, and Mendoza EM (eds.). Post-harvest biochemistry of plant
549
food-materials in the tropics. Japan Scientific Societies Press. 241 - 251.
550 551
Oyaizu, M. 1986. Studies on product of browning reaction prepared from glucose amine. Japa J Nut. 44, 307- 315.
552
Pandima Devi, K., Suganthy, N., Kerika, P., Karutha Pandian, S. 2009. Mangrove plant
553
extracts: radical scavenging activity and the battle agains food borne pathogens.
554
Forsch komplementmed. 16, 41-48.
555
Poli, F., Muzzoli, M., Sacchetti, G., Tassinato, G., Lazzarin, R., Bruni, A. 2003. Endemic
556
species of sardo-corso-balearic area: molecular composition and biological assay of
557
Teucrium Pharm. Biol. 41, 379.
558 559
Premanathan, M., Chandra, K., Bajpai, SK., Kathiresan, K. 1992. A survey of Indian marine plants for antiviral activity, Bot. Mar. 35, 31- 35. 18
560
Premanathan, M., Kathiresan, K., Yamamoto, N., Nakashima, H. 1999. In vitro anti-
561
human immunodeficiency virus activity of polysaccharide from the Rhizophora
562
mucronata Poir., Soil Biotechnology Biochem. 63, 1187- 1191.
563
Puupponen-Pimia, R., Nohynek, L., Meier, C., Kahkonen M, Heinonen M, Hopia A.
564
2001. Antimicrobial properties of phenolic compounds from berries. J. Appl.
565
Microb. 90, 494 -507.
566
Rice-Evans, CA., Miller, NJ., Bolwell, PG., Bramley, PM., Pridham, JB. 1995. The
567
relative activities of plant-derived polyphenolic flavonoids. Free Radical Res. 22,
568
375-383.
569
Ronald, SK., Ronald, S. 1991. Beverages and chocolate. In pearson’s composition and
570
analysis of foods, 9th ed., Longman scientific & technical publishers, England, pp.
571
356 – 362.
572
Ruch, RJ., Cheng, SJ., Klaunig, JE. 1989. Prevention of cytotoxicity and inhibition of
573
Intercellular communication by antioxidant catechins isolated from Chinese green
574
tea. Carcinogens. 10, 1003-1008.
575
Samman, LWPM., Cook, NC. 1998. Flavonoids and coronary heart disease: Dietary
576
perspectives. In: Rice-Evans C.A. and Packer, L. Eds, Flavonoids in health and
577
disease, marcel dekker, New York, pp.469 − 482.
578
Saranya, A., Dinesh, P., Ramanathan, TS. 2014. Identification of bioactive compounds of
579
Rhizophora mucronata poir. Leaves using supercritical fluid extraction and GC-MS.
580
World J Pharm and Pharmaceut Sci. 3(10), 1621-1631.
581 582 583 584 585 586 587 588
Sharma, M., Garg, HS. 1996. Iridoid glycosides from Avicennia officinalis. Ind. J. Chem. 35, 459- 462. Singh, A. 2009. Acanthus illicifolius Linn. Lesser known medicinal plant with significant pharmacological activities. Ethanobotanical leafleat. 13, 431- 36. Singh, N., Rajini, P.S. 2004. Free radical scavenging activity of aqueous extract of potato peel. Food Chem. 85, 611- 616. Singleton, VL., Rossi, JA. 1965. Colorimetry of total phenolics with phosphomolybdicphosphotungstic acid reagents. Am. J. Enol. Vitic. 16, 144 -158.
589
Sithranga Boopathy, N., Kathiresan, K., Jeon, YJ. 2011. Effect of mangrove black tea
590
extract from Ceriops decandra (Griff.) on hematology and biochemical changes in
591
dimethyl benz[a]anthracene-induced hamster buccal pouch carcinogenesis. Environ
592
Toxicol Pharmacol. 32(2), 193-200.
19
593
Sithranga Boopathy,N., Kathiresan, K., Manivannan, S.,, Jeon ,Y.J. 2011. Effect of
594
Mangrove Tea Extract from Ceriops decandra (Griff.) Ding Hou. on Salivary
595
Bacterial Flora of DMBA Induced Hamster Buccal Pouch Carcinoma. Indian J
596
Microbiol. 51(3): 338–344.
597
Thanaraj, SNS., Seshadri, R. 1990. Inflence of polyphenol oxidase activity and
598
polyphenol content of tea shoot on quality of black tea. J. Sci. Food Agric. 51, 57-
599
69.
600
Trease, GE., Evans, WC. 1989. Pharmacognosy (13th ed.). London: Balliere Tindall Ltd.
601
Vadlapudi V, Chandrasekhr Naidu K. 2009. Evaluation of antioxidant potential of
602
selected mangrove plants. J Pharm Res. 2(11), 1742-1745.
603
Venkatesan, S., Murugesan, S., Senthurpandian, VK., Ganapathy, MNK., 2005. Impact of
604
sources and doses of potassium on biochemical parameters of tea. Food Chem. 90,
605
535-539.
606
Wang, M., Li, J., Rangarajan, M., Shao, Y., LaVoie, EJ., Huang, T., Ho, C. 1998.
607
Antioxidative phenol compounds from sage (Salvia officinalis). J. Agric. Food.
608
Chem. 46, 4869- 4873.
609
Wei, S.D., Zhou, H.C., Lin, Y.M. 2010. Antioxidant activities of extract and factions
610
from the Hypocotyls of the mangrove plant Kandelia candel. Int. J. Mol. Sci. 11,
611
4080-4093.
612 613
Zheng, W., Wang, SY. 2001. Antioxidant activity and phenolic compounds in selectedherbs.J.Agric Food Chem. 49(11), 5165 - 5170.
614 615 616
Figure Caption:
617
Fig. 1. Antioxidant assay of mangroves black tea (a) Total Antioxidant (b) Total Phenol (c)
618
DPPH assay (d) Total Reducing Power (e) Nitric Oxide Assay
20
50 100 500
90 80
Total antioxidant %
70 60 50 40 30 20 10 0
R.mucronata
R.apiculata
R. annamalayana
Different concentrations
619 620 621
(1a)
50 100 500
90 80
Total phenol %
70 60 50 40 30 20 10 0 R. mucornata
R. apiculata Different Concentrations
622 623
(1b)
21
R. annamalayana
50 100 500
100
DPPH activity %
80
60
40
20
0 R. mucornata
R. apiculata
R. annamalayana
Different concentrations
624 625 626
(1c) 50 100 500
1.1 1.0
Total Reducing Power %
0.9 0.8 0.7 0.6 0.5 0.4 0.3 0.2 0.1 0.0 R. mucornata
R. apiculata
Different concentrations
627 628 629
(1d)
22
R. annamalayana
50 100 500
80 70
Nitric Oxide %
60 50 40 30 20 10 0 R. mucornata
R. apiculata
R. annamalayana
Different concentrations
630 631
(1e)
632
All the values expressed mean and standard division. The statistical significant different
633
letters (a-e) with (P< 0.05).
634
635 636 637
Fig. 2a FTIR spectrum for R. mucronata tea extract
638
23
639 640
Fig. 2b FTIR spectrum for R. apiculata tea extract
641 642 643 644
645 646
Fig. 2c FTIR spectrum for R. annamalayana black tea extract
647
24
648 649
Table 1 Chemical constituent quality and caffeine content of tea extracts (R. mucronata, R. apiculata and R. annamalayana).
650
Table 2 Phyto-chemical characterization of tea extracts.
651
Table 3 Effect of tea extracts on the growth of Gram positive and Gram negative human
652
pathogenic bacteria.
653
Table 4 Comparison of biological potential in mangrove species as reported in the literature.
654 655
25
Table 1 Chemical constituent quality and caffeine content of tea extracts (R. mucronata, R. apiculata and R. annamalayana). Chemicals constituent
R. mucronata
R. apiculata
R. annamalayana
Theaflavine
0.42±0.02a
0.18±0.02a
0.5±0.08a
Thearubigin
4.60±0.24b
3.49±0.22 b
4.52±0.20 b
Highly polymerized substane
3.95±0.18 c
4.71±0.20 c
3.9±0.28 c
Total liquor colour
1.1±0.14 d
0.49±0.03 d
0.51±0.03 d
Caffeine
ND
ND
ND
Dates were expressed as mean ± standard division; ND- Not Detectable. The different letters a-c are statistically significant with P<0.05.
Table 2 Phyto-chemical characterization of tea extracts. Phytochemical test
R. mucronata
R. apiculata
R. annamalayana
Proteins-xanthoprotein
+
+
+
Steroids
+
+
+
Tannins
+
+
+
Glycosides
+
+
+
Reducing sugar
+
+
+
Sterols
+
+
+
Terpenoids
+
+
+
Cardioglycoside
+
+
+
Carbohydrate
+
+
+
Flavanoids
+
+
+
Phenol
+
+
+
+; presence of phyto-chemical components.
Table 3 Effect of tea extracts on the growth of Gram positive and Gram negative human pathogenic bacteria. Bacteria
Positive
Negative
control
control
Penicillin Escherichia
DMSO
Zone of inhibition in (mm)
R. mucronata
R. apiculata
R. annamalayana
11±0.01
-
10±0.11
2.0±0.01
6.0±0.05
13.1±0.02
-
8.0±0.07
7.0±0.06
2.0±0.03
9.0±0.04
-
6.0±0.05
5.0±0.03
10±0.09
10.1±0.00
-
5.0±0.04
15±0.12
7.0±0.05
coli Salmonella typhi Proteus vulgaris Staphylococcus aureus Mean values (n=3 with SD).- No zone of inhibition. Table 4 Comparison of biological potential in mangrove species as reported in the literature. Name of the
Study area
Biological properties
Reference
Parangipettai,
Antiviral and anti larvicidal
Premanathan
mangroves R.apiculata
Tamilnadu, India R.mucronata
Parangipettai,
et al., 1999 Antiviral, anti- HIV
Tamilnadu, India R.mucronata,
Pichavaram and
R.apiculata,
Tamilnadu, India
Premanathan et al., 1999
Polyphenol and antioxidant
Agoramoorthy et al., 2008
Avicennia officinalis, Ceriops decandra Avicennia marina
Gulf of Aqaba,
Antibcaterial, anticandidal, anti
Khafagi et al.,
Egypt
bacteriophage, cytotoxicity and
2003
plant growth grgulatar R.mucronata,
Pichavaram and
Antioxidant activity and
Pandima Devi
R.apiculata,
Thondi, Tamilnadu,
R.annamalayana,
India
antibacterial properties
et al., 2009
Antioxidant activity
Vadlapudi and
Avicennia marina and Ceriops decandra Avicennia
Andhra Pradesh,
officinalis,
India
Naidu, 2009
A.marina, R.conjugata, R.mucronata, Salicornia brachiata, Salvodara persica, xylocarpus granatum Kandelia candel
China
Antioxidant properties
Wei et al., 2010
R.mucronata
R.mucronata
Ceriops decandra
Parangipettai,
Phytochemical and Bioactive
Saranya et al.,
Tamilnadu, India
compound
2014
Kerala, Kollam,
Phytochemical and Bioactive
Manilal et al.
India
compound
2015
Parangipettai,
Mangrove black tea buccal pouch
Sithranga
Tamilnadu, India
carcinogenesis in hamsters
Boopathy et al., 2011
C. decandra
Parangipettai,
Mangrove black tea prevents the
Sithranga
Tamilnadu, India
oral cancer incidences
Boopathy et al., 2011
R.mucronata,
Parangipettai,
Mangrove black tea rich in
R.apiculata,
Tamilnadu, India
Phytochemical, antioxidant and
R.annamalayana
antibacterial activity
Present study
S1878-8181(19)30339-1
DOI:
https://doi.org/10.1016/j.bcab.2019.101491
Reference:
BCAB 101491
To appear in:
Biocatalysis and Agricultural Biotechnology
Received Date: 4 May 2019 Revised Date:
17 December 2019
Accepted Date: 30 December 2019
Please cite this article as: Arulkumar, A., Kumar, K.S., Paramasivam, S., Antibacterial and invitro antioxidant potential of Indian mangroves, Biocatalysis and Agricultural Biotechnology (2020), doi: https://doi.org/10.1016/j.bcab.2019.101491. This is a PDF file of an article that has undergone enhancements after acceptance, such as the addition of a cover page and metadata, and formatting for readability, but it is not yet the definitive version of record. This version will undergo additional copyediting, typesetting and review before it is published in its final form, but we are providing this version to give early visibility of the article. Please note that, during the production process, errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain. © 2019 Published by Elsevier Ltd.
1
Antibacterial and invitro antioxidant potential of Indian mangroves
2 3
A. Arulkumar*1,2, K. Sampath Kumar3 and S. Paramasivam1
4 5
1
6 7
2
8
3
9 10 11
Department of Oceanography and Coastal Area Studies, School of Marine Sciences, Alagappa University- Thondi Campus 623 409, Tamil Nadu, India. Achariya Arts and Science College, Villianur Puducherry- 605 110 (Affiliated Pondicherry University). Sengunthar Arts and Science College, Thiruchengode-637 205, Tamil Nadu, India. *
Email: [email protected]; Ph: +91-9597319098.
Abstract
12
Herbal tea is medicinally well-known for its biochemical composition and medicinal
13
usages. The present study proved for the first time that tea would be extracted from
14
mangroves, the plants other than commercial tea. Tea showed a theaflavin (TF), thearubigins
15
(TR), Total liquor color (TLC) and highly polymerized substantce (HPS). These characters
16
revealed the good quality of the tea. Phytochemical screening of tea revealed the presence of
17
phytochemical compounds such as protein, phenol and flavonoids etc. antioxidant properties
18
of tea were tested in invitro at varied concentrations. The antioxidant properties of R.
19
mucronata, R. apiculata, and R. annamalayana showed dose dependent activities and were
20
comparatively much higher in R. mucronata. R. mucronata (86.50±0.35%) showed much
21
higher total antioxidant activity followed by R. apiculata (73.34±0.90%) and R.
22
annamalayana (69.35±0.56%) at 100 µg/ml concentration. The antimicrobial activity was
23
highest in R. mucronata and R. apiculata than R. annamalayana as evident by the presences
24
of phenolic N-H and OH components found in tea. Therefore, it can be concluded that,
25
mangroves are rich source of tea, biochemical consititent, phytochemical, antioxidant and
26
antibacterial properties. The extract contained polyphenolic and other bioactive compounds
27
can be used as a development of herbal drug formuation and nutraceutical.
28 29
Keywords: Tea, Rhizophora mucronata, Phytochemical, antioxidant and R. annamalayana.
30
1. Introduction
1
31
India has a rich and prestigious heritage of mangrove forest oriented medicines among
32
the South Asian countries. However, the majority of these plants have not yet undergone
33
chemical, pharmacological and toxicological studies to investigate their bioactive compounds
34
(Kathiresan, 2000; Singh et al., 2009). Traditional records and ecological diversity indicate
35
that India plants represent an exciting resource for possible lead structures in drug design.
36
Plants are endowed with free radical scavenging molecules, such as vitamins, terpenoids,
37
phenolic acids, lignins, stilbenes, tannins, flavonoids, quinones, coumarins, alkaloids, amines,
38
betalains, and other metabolites, which are rich in antioxidant activity (Zheng and Wang,
39
2001). The mangrove plants naturaly syntheses many bioactive secondary metabolites. Such
40
plant-derived phytochemicals are highly unexplored for therapeutics. Mangroves are
41
biochemically unique, producing a wide array of novel natural products. They are rich in
42
polyphenols and tannins (Kathiresan and Ravi, 1990). In recent years, there is growing
43
interest in the discovery of noval compounds in mangroves resoures to control the emerging
44
human pathogenic microbes. Fascinatlingly, researchers have isolated a variety of other
45
mangrove compounds including taraxerol careaborin and taraxeryl cis-p-hydroxycinnamate
46
from leaves of Rhizophora apiculata (Kokpol et al., 1990); 2-nitro-4-(2'-nitroethenyl phenol)
47
from leaves of Sonneratia acida (Bose et al., 1992); alkanes (46.7–97.9% wax) and
48
triterpenoids (53.3% wax) from leaves of Rhizophora species (Dodd et al., 1995); and iridoid
49
glycosides from leaves of Avicennia officinalis and A. germinans (Fauvel et al., 1995; Sharma
50
and Garg, 1996). Phytoconstituent of R. mucronata was identified as Ethanone, 1-(2-
51
hydroxy- 5- methylphenyl as role in the antibiotic activity against human and fish pathogen
52
(Manilal et al., 2015).
53
In recent past years, mangrove plants have gained much importance due to its used in
54
fisher-folk medicine to treat various diseases (Bandaranayake, 2002) and it has been studied
55
for their medicinal properties. Coastal plant extracts have been tested against viruses that
56
cause human and animal diseases, such as human immunodeficiency virus (HIV), new castle
57
disease virus, vaccinia virus, semliki forest virus, encephalomyocarditis virus, and hepatitis-
58
B-virus (Kathiresan, 2000). A few of the mangrove plants belonging to family-
59
Rhizophoraceae are most effective against the viruses (Premanathan et al., 1992). Bioactive
60
compounds present in the mangrove plants and polysaccharides composed of galactose,
61
galactosamine, glucose and arabinose reported to have potent anti-HIV activity (Premanathan
62
et al., 1999). Scientific studies on a number of medicinal plants indicated that promising
63
phytochemical compounds can be developed for many health problems (Gupta, 1994).
2
64
These phytochemicals are indeed chemically complex and many structurally related
65
active compounds often produce a synergistic effect. Therefore medicinal plants are perhaps
66
the most valuable sources of new bioactive chemical entities to benefit mankind against
67
various ailments. Almost 122 pure chemical substances extracted from higher plants are used
68
in medicine throughout the world (Fabriant and Farnsworth, 2001). Therefore, it very
69
important to determined the phytochemical screening, bioactive compound (FTIR) and
70
biochemical constitutent in Rhizophora species for noval drug discovary, antibiotics and
71
navol nutraceutical compounds. However, for first time in this present investigation, was
72
evaluate the campartive study of phytochemical, antioxidant and antibacterial activity of
73
mangroves species viz. Rhizophora mucronata, R. apiculata and R. annamalayana. The
74
bioactive efficacy of tea, extracted from three mangrove Rhizophora species and
75
identification of the functional groups present in the tea extracts by using Fourier transform-
76
infrared spectroscopy (FT-IR) analysis.
77
2. Materials and Methods
78
2.1 Collection of mangrove leaves
79
The fresh mangrove leaves of Rhizophora mucronata, Rhizophora apiculata and
80
Rhizophora annamalayana were collected from the artificially developed Vellar Estuary
81
mangroves vegetation at Parangipettai, Tamilnadu, India. The river Vellar is flowing on the
82
Southeast Coast of India, mixing with the sea at Porto Novo (also known as Parangipettai;
83
Lat. 11° 29’ N; Long. 79° 47’ E). The estuary is connected to the Pichavaram mangroves
84
through the backwater channel. The mouth of the Vellar Estuary opens to the sea and a sand
85
bar sometimes closes it completely during summer season.
86
2.2 Preparation and extraction of tea
87
Black tea was extracted from the leaves of Rhizophora species, adopting the method of
88
Kathiresan (1995). Fresh leaves were allowed to dry using a warming blender. A known
89
weight of the macerated sample was placed in a piece of cloth and distilled water was
90
continuously trickled over it for 1hrs. The fermented sample was dried in hot air oven at 95°C
91
for 30 minutes. 1.25% of mangrove black tea was added to the boiling water and allowed to
92
infuse for 5 minutes, after which the infusions were filtered through sterile mambrean filter.
93
The filtrates were lyophilized and used for further study.
3
94
2.3 Tea quality constituents and Caffine content of Tea
95
Theaflavin (TF), Thearubigins (TR), Total liquor color (TLC), highly polymerized
96
substantce (HPS) and caffeine content were analysed, for determination of quality of tea
97
(Thanraj and Shesadari, 1990; Ronald and Ronald, 1991).
98
2.4 Qualitative analysis of phytochemical screening
99
The qualitative chemical constituents present in the tea extracts of mangroves plants were
100
determined by (Trease and Evans, 1989).
101
Proteins-xanthoprotein: to 1mL of extract, 3-5 drops of nitric acid was added by the sides
102
of the test tube and observed for formation of yellow colour indicated presence of proteins.
103
Steroids: two mL of acetic anhydride was added to 0.5 g of extract and 2 mL of sulphuric
104
acid was added by the sides of the test tube and observed the colour change from violet or
105
blue-green.
106
Tannins: about 0.5 g of the each extract was taken in a boiling tube and boiled with 20 mL
107
distilled water filtered and then added few drops of 0.1% ferric chloride mixed well and
108
allowed to stand for some time. Brownish green or a blue-black colouration was observed.
109
Glycosides─Keller-Killani method: about 0.5 mL of alcoholic extracts was taken and
110
subjected to the following test. One ml of glacial acetic acid containing traces of ferric
111
chloride and 1mL of conc. sulphuric acid were added to extract and observed for the
112
formation of reddish brown colour at the junction of two layers and the upper layer turned
113
bluish green in the presence of glycosides.
114
Reducing sugars─Fehling’s test: few drops of Fehling’s solution A and B in equal volume
115
were added in dilute extracts and heated for 30 min and observed for the formation of brick
116
red coloured precipitate.
117
Sterols-Liebermana-Buchard method: the insoluble residue was dissolved in chloroform
118
and few drops of anhydride were added along with a few drops of concentration H2SO4 from
119
the side of the test tube and the formation of blue to blood red color was obderved.
120
Terpenoids ─ Salkowski test: to 0.5 g of the extract, 2 mL of chloroform was added; conc.
121
H2SO4 (3mL) was carefully added to form a layer. A reddish brown coloration of the
122
interface indicates the presence of terpenoids.
4
123
Cardiac glycosides (Keller ─ Killiani’s test): 100 mg of extract was dissolved in 1 mL of
124
glacial acetic acid containing one drop of ferric chloride solution. This was then underlayered
125
with 1 mL of concentrated H2SO4. A brown ring obtained at the interface indicated the
126
presence of a de-oxy sugar charactersitcs of cardenolides.
127
Carbohydrates─Molisch’s test: small quantities of alcoholic and aqueous extracts were
128
dissolved in 5 mL of distilled water and filtered. To this solution 2−3 drops of α-naphthol was
129
added and 1 mL of concentrated H2SO4 was added along the sides of inclined test tube so as
130
to form two layers and observed for formation of violet coloured ring at the interface to detect
131
the presence carbohydrates.
132
Flavonoids: a portion of the acqueous extract (2 ml) was heated, and metallic magnesium
133
and concentrated hydrochloric acid (5 drops) were added. A red or orange coloration
134
indicated the presence of flavonoids.
135
Phenols: the extracts were taken in water and warmed. To this 2 mL of ferric chloride
136
solution was added and observed for formation of green or blue colour.
137
2.5 Chemicals and reagents
138
Butyled hydoxytoluene (BHT), DPPH (1, 1-diphenyl, 2-picrylhydrazyl), resazurin of
139
Sigma Chemicals, (USA) and all others high purity chemical reagents of Merck (Germany)
140
were used.
141
2.6 Estimation of Antioxidants assay
142
2.6.1 Estimation of total antioxidants
143
Total antioxidant activity was measured by the method of (Mitsuda et al., 1996). 7.45 mL
144
sulphuric acid (0.6 M solution), 0.9942 g sodium phosphate (28 mM solution) and 1.2359 g
145
ammonium molybdate (4 mM) were mixed together in 250 mL with distilled water and
146
labeled as total antioxidant capacity (TAC). 100 µL of extract was dissolved in 1mL of TAC
147
and the absorbance was read at 695 nm after 15 min. Butyled hydoxtoluene (BHT) was used
148
as positive control.
149
Calculation of 50% inhibitory concentration (IC50)
150
The concentration (µg/mL) of the fractions that was required to scavenge 50% of the
151
radicals was calculated by using the percentage scavenging activities at three different
5
152
concentrations of the fractions. Percentage inhibition (%) was calculated using the following
153
formula,
154
% Inhibition = [(Ac-As) /Ac] X 100
155
Where, Ac = absorbance of the control As = absorbance of the sample.
156
2.6.2 Determination of total phenol content
157
Total phenolic content of tea were estimated with the Folin-Ciocalteu’s method
158
(Singleton et al., 1999). Black tea extracts (10 mg) were dissolved in 10 mL of distilled
159
water. An aliquot of 100 µL of appropriate dilution of the samples were shaken for 1min with
160
500 µL of the folin-ciocalteu reagent freshly prepared in the laboratory and 6 mL of distilled
161
water. After the mixture was shaken 2 mL of 15% (mass per volume) sodium carbonate was
162
added and the mixture was shaken again for 0.5 min. Finally, the solution was brought up to
163
10 mL with distilled water. After 2 hrs of reaction at ambient temperature, the absorbance
164
was measured at 750 nm. Using gallic acid as standard, the total phenolic content of both
165
mangroves was expressed as gallic acid equivalents (GAE).
166
2.6.3 DPPH radical scavenging assay
167
The free radical scavenging activity of tea extracts were measured by DPPH according to
168
(Blois, 1958) method. 1 mL of DPPH (0.1mM) solution in methanol was added to 3 mL of
169
water extract of tea (100 µg/mL), shaken vigorously, allowed to stand at room temperature
170
for 30 min and the absorbance was measured at 517 nm in a UV-visible spectrophotometer
171
(U-2800 model, Hitachi, Japan). A low absorbance of the reaction mixture indicated the high
172
free radical scavenging activity. Butylated hytroxytoluene (BHT) was used as positive
173
control. The DPPH scavenging effect was calculated.
174
DPPH radical scavenging activity = {(Abs control – Abs sample) / (Abs Control)} × 100
175
Where; Abs control = absorbance of DPPH radical +BHT;
176
Abs sample = absorbance of DPPH radical + sample extract or Standard.
177
2.6.4 Total reducing power
6
178
Total reducing capacity of tea was determined according to the method of (Oyaizu,
179
1986). The tea extracts (100 µg/mL) in distilled water and 1% potassium ferricyanide were
180
mixed with phosphate buffer (0.2 M, pH 6.6) and the mixture was incubated at 50°C for 20
181
min. 2.5 mL of 10% TCA was added to the reaction mixture which was centrifuged at
182
1000×g for 5 min. The upper layer of the solution (2.5 mL) was mixed with distilled water
183
(2.5 mL), FeCl2 (0.5 mL, 0.1%) and the absorbance was measured at 700 nm. Ascorbic acid
184
was used as a positive control. The higher absorbance of the reaction mixture indicated the
185
greater reducing power.
186
2.6.5 Nitric oxide radical (NO*) scavenging activity
187
Nitric oxide radical scavenging activity was determined by the method reported by
188
(Garrat, 1964). Sodium nitroprusside in aqueous solution at physiological pH spontaneously
189
generates nitric oxide, which interacts with oxygen to produce nitrite ions, which can be
190
determined by the griess-illosvoy reaction. Briefly, 3 mL of the reaction mixture containing
191
10 mM sodium nitroprusside and the tea extract (100 µg/mL) in phosphate buffer were
192
incubated at 25°C for 150 min. After incubation, 0.5 ml of the reaction mixture was mixed
193
with 1mL of sulfanilic acid reagent (0.33% in 20% glacial acetic acid) and allowed to stand
194
for 5 min for complete diazotization. Then 1 mL of naphthyl ethylene diamine
195
dihydrochloride (0.1%) was added and after mixing well the solution was allowed to stand
196
for 30 min at 25°C. A pink coloured chromophore was formed in diffused light. The
197
absorbance of these solutions was measured at 540 nm against the corresponding blank
198
solutions. BHT was used as positive control. Nitric oxide scavenging activity of the tea
199
extract is reported as % inhibition and was calculated.
200
NO radical scavenging activity = {(Abs control – Abs sample) / (Abs control)} × 100
201
Where; Abs control = absorbance of NO radical + BHT; Abs
202
Sample = absorbance of NO radical + sample extract or standard.
203
2.7 FT-IR analysis of tea
204
For this 2 mg of the tea extracts samples of (R. mucronata, R. apiculata and R.
205
annamalayana) were mixed with 200 mg KBr (FT-IR grade) and made into thick pellets in a
206
hydraulic press by allying 500 Kg/m3 pressure. The pellet was immediately placed into the
7
207
sample holder and FT-IR spectra were recorded between ranges of 7800–350cm-1 (Mid-IR)
208
for the compound under study. FT-IR spectra of the purified compound were recorded on a
209
Shimadzu, Model No: A21374801626, Japan FT-IR spectrometer.
210
2.8 Bacterial strains and culture conditions
211
Bacterial cultures namely Staphylococcus aereus, Escherichia coli, Salmonella typhi, and
212
Proteus vulgaris were obtained from the CAS in Marine Biology, Annamalai University,
213
Parangipettai, India. The above cultures were long term storage took place at -20 oC in
214
Nutrient broth (Hi Media, Mumbai, India) supplemented with 50% glycerol. Before
215
experimental use each strain was grown twice in Nutrient broth at 37 oC for 48 h.
216
2.8.1 Determination of In vitro antibacterial activity against human pathogenic bacteria
217
The antibacterial activity of the tea extracts (R. mucronata, R. apiculata and R.
218
annamalayana) was performed by the well diffusion method on Muller-Hinton agar MHA
219
(Hi media, India). About 100 µL of 105 CFU/ml diluted inoculum bacterial culture was
220
applied on the surface of MHA plates and allowed to solidify. MHA well was made with well
221
borer under aseptic conditions and filled with mangroves tea extract samples and DMSO as
222
used as negative control and penicilin was act as positive control. The plates were incubated
223
at 37oC for bacterial growth/ the antibacterial activity of the mangrove samples was evaluated
224
by measuring the zone of inhibition against the test human pathogenic bacteria. All the
225
experiments were done three times and the data were expressed as the mean values of
226
experiments.
227 228 229
2.9 Thin layer chromatography (TLC)
230
apiculata and R. annamalayana (Abu et al., 2011). Methanol and chloroform (1:9) was used
231
as mobile phase. The sample with the concentration of about (1 mg/mL) was spotted on the
232
TLC plates and dried. The spots were identified in long UV, short UV and also in the iodine
233
chamber. Rƒ value was calculated to find the active metabolites. Rƒ value is distance
234
travelled by the solute to the distance traveled by the solvent.
235
3.0 Statistical analysis
TLC is used to separate the bioactive compounds present in the tea extract R. mucronata, R.
236
Datas were expressed in triplicates (n=3) and strandard devision. The data were obtained
237
were analyzed by the one way analysis of variation (ANOVA), with a P values of < 0.05
8
238
being significant. All the statistical were performed using the OriginPro version 8.0 statistical
239
package.
240
4. Results and Discusion
241
4.1 Physical nature of tea
242
The present study evaluated that phytochemical constituent of tea from the three
243
mangroves species, R. mucronata, R. apiculata and R. annamalayana. The black tea extract
244
showed a golden brown colour with pleasant aroma taste. These characters revealed the good
245
quality of the tea. It was observed that, the maximum yield of tea was obtained for the R.
246
mucronata. The percentage yield of R.mucronata (0.125%) followed by R. apiculata
247
(0.121%) and R.annamalayana (0.110%) respectively. The colour and the yield of the tea
248
extraction might be attributed to the levels of polyphenol content.
249
4.2 Tea quality constituents of tea extracts
250
The chemical constituent and quality of tea determined theaflavin (TF), Thearubigins
251
(TR), Total liquor color (TLC), highly polymerized substantce (HPS) and caffeine content
252
statistically significance different with P< 0.05 were presented in (Table 1). The R.
253
mucronata was observed to possess higher TF 0.42±0.02% when compared to R.apiculata
254
(0.18±0.02%) and R. annamalayana (0.5±0.08%) tea extracts. The higher thearubigins (TR)
255
was observated in R. mucronata (4.60±0.24%) followed by R. annamalayana and
256
R.apiculata. The R.mucronata was observed to possess higher HPS 4.71±0.20% followed by
257
R.apiculata 3.9±0.29% and R.annamalayana 3.95±0.18%. The total liquire colour (TLC) was
258
higher R. mucronata in (1.1±0.14%) followed by R. annamalayana (0.51±0.03%) and R.
259
apiculata (0.49±0.03%). Coffien content all the three mangroves speices was not detected
260
(ND). It was observed that, R. mucronata contains higher TF, TR, TLC and HPS content than
261
R. apiculata and R.annamalayana. Venkatesan et al. (2005) have repoted that, the polyphenol
262
found in the tea leaves and it important responsible for all the biochemical reaction with
263
contribution to make a good quality of tea. The chemical basis of the quality of mangrove
264
black tea indicated theaflavin (TF), Thearubigins (TR), Total liquor color (TLC), highly
265
polymerized substantce (HPS) are the important factors determine the liquor quality of
266
mangrove black tea. Liang et al., (2007) have reported that, the tea owing to its favorable
267
benefits on human health dring currently enjoys a great popularity among other beverages
268
throught out the worldwide. In this study, higher TF, TR, TLC and HPS was oberverved in
9
269
R.mucronata followed by other potential species (Table 1). Bagyalakshmi et al., 2012 have
270
reported that, the quality of tea characterisitics TF, TR, HPS, TLC and caffeine 0.8, 7.6, 7.2,
271
2.3 and 2.1 respectively in Camellia sinensis. In This study first time proved that HPS was
272
higher in R.mucronata (4.71±0.20%) followed by R.apiculata (3.9±0.29%) and
273
R.annamalayana (3.95±0.18%) and there is no caffien content in all the Rhizophora species.
274
4.3 Qualitative analysis of phytochemical constituents
275
Phytochemical constituents of R. mucronata, R. apiculata and R. annamalayana were
276
qualitatively analyzed and the results are presented in (Table 2). The tea extract of all the
277
three species viz. R. mucronata, R. apiculata and R. annamalayana showed the presence of
278
phytochemical active compounds such as xanthoprotein, steroids, tannins, glycosides,
279
reducing sugar, carbohydrates, sterols, terpenoids, phenol, cardioglycosides and flavonoids.
280
Mangroves and mangrove associates possess novel agrochemical products, compounds of
281
medicinal value, and biologically active compounds (Bandaranayake, 2002). The
282
phytochemical screening of tea extracts of R. mucronata, R. apiculata and R. annamalayana
283
revealed the presence of tannins, flavonoids, steroids and saponins. Its clearly indicates that,
284
the presence of the functional group –OH in the structure and positions of the flavonoid
285
molecules to determine the phytochemical capacity. Recently, Saranya et al. 2014 reported
286
that, the important active metabolities find out through the phytochemical screening
287
R.mucronata showed the presence of alkaloids, terpenoids, steroids, tannins, quinines,
288
sapnins, flavonoids, cardiac glycosides and phenol, which corroborates the results of the
289
present study. Abdurahman et al., (2016) reported that, the Rhizophora species have various
290
phyo-chemical compounds includes alcohol, aldehydes, aminoacids, aromatic carboxylic
291
acid, carbohydrates, carboxlic acids, esters, fatty acids, flavonoid, ketone, lipids, phenol,
292
saponins, steroids, tannin and terpenoid for the biological acitivity.
293 294
These results support the finding that mangrove plants are a rich source of steroids,
295
triterpenes, saponins, flavonoids, alkaloid and tannins (Agramoorthy et al., 2008;
296
Bandarnayake, 2002). Alkaloids, tannins, flavonoids and other phytochemicals are present in
297
other plants as well (Barnabas and Nagarajan 1988). In the present study it is found that
298
Rhizophora species contain these secondary metabolities which showed phenolic compounds
299
(N-H and OH molecules) and other substance. Hence, the beneficial medicinal effects of
300
plant material may result from the combinations of secondary products present in the plant.
10
301
Secondary products play a role in a plant defense through cytotoxity towards microbial
302
pathogens (Briskin, 2000).
303
Tannins are known to be useful in the medicine flok and treatment of inflamed or ulcerated
304
tissue and thery remarkable anticancer (Ruch et al., 1989). Thus, Rhizophora species
305
containing bioactive compounds and its may serve as a potential sources of bioactive
306
compounds in the treatment of cancer. The presence of phenol compounds in this Rhizophora
307
species may contribute to their antioxidant and antibacterial propertices, its very usefulness
308
developments of herbal medicine and nuetraceuticals. Earlier study reported that, the
309
phenolic compounds may exhibit a widal range of physiological function, such as anti
310
bacterial, anti fungual, antioxidant, anti inflammatory, anti artherogenic, anti thrombotic
311
effects (Benavente et al., 1997; Samman et al., 1998; Puupponen-Pimia et al., 2001; Manilal
312
et al., 2015; Abdurahman et al., 2016).
313
4.4 Antioxidant
314
The antioxidant activities of tea extracts of three mangrove species, R. mucronata, R.
315
apiculata and R. annamalayana at different concentration are shown in (Fig.1a-e). It was
316
found that, of the three species of tea extracts screened, R. mucronata (100 µg/ml) showed
317
significant levels of antioxidant properties, in terms of total antioxidants, total phenol, DPPH
318
assay, and total reducing power and nitric oxide radical scavenging activity. The total
319
antioxidant activity of the tea extracts increased with increase in concentration (P< 0.05). The
320
result suggested that, the R. mucronata showed highest total antioxidant activity of
321
85.50±0.35% when compared to R. apiculata 73.34±0.90% and R. annamalayana
322
69.35±0.56% at the concentration of 100 µg/ml respectively (Fig.1a). It was observed that,
323
R.mucronata contains 12.16% and 16.15 % time’s higher total antioxidant activity than
324
R.apiculata and R.annamalayana. Gao and Xiao, 2012 reported that, the Rhizophora species
325
contains lyoniresinol-3α-o-β-arabinopyranoside, lyoniresinol-3α-O-β-rhamnoside, afzelechin-
326
3-rahmnoside bioactive compounds for antioxidant and better radical scavenging activity.
327 328
The total phenol contents of the tea extracts are possibly proportional to the
329
concentration. The highest TPC was observed from R. mucronata 84.80±1.47% followed by
330
R. apiculata 79.23±0.70% and R. annamalayana 74.35±0.90% at the concentration of 100
331
µg/ml significance level (P< 0.05) (Fig.1b ). It was clearly noted that, R.mucronata contains
332
5.59% and 10.45% times higher total phenol content than R.apiculata and R.annamalayana.
333
Pandima Devi et al. 2009 have reported that, the TPC of R.mucronata was 720.7 mg GAE/g
11
334
for methanolic extracts which corrabotes the results of R.mucronata in the present study. The
335
higher content of phenolic in mangroves tea extracts indicates a better free radical scavenging
336
ability, which can prevent lipid oxidation in food products. Screening of antioxidant
337
substances derived from natural resources is one of the basic tool for drug design and
338
development. Agoramoorthy et al. 2008 have reported that, the TPC higher phenol content of
339
R. mucronata and R.apiculata was 157.4 mg GAE/g and 302 mg GAE/g for dry weight
340
respectively, which was comparatively much higher than the results of the present experiment
341
(Fig.1b). Recently, Wei et al. 2010 reported that, the TPC of mangrove plant (Kandelia
342
candel) was 400.43µg GAE /ml. Haq et al. 2011 have reported that, the total phenol content
343
of Bruguiera gymnorrhiza was 178.73 mg GAE/g of dry leaves. The present study indicates
344
that R.mucronata, R. apiculata, and R. annamalayana tea extracts were potential free radical
345
scavengers, wich reacted with free radicals by donating their hydrogen (H2) and act as
346
primary antioxidants and prevent oxidation.
347
Several free radical such as OH, O2, LOO have different reactivities are formed
348
during lipid oxidation. Antioxidants are able to scavenge these radicals by donating H iorns.
349
Relatively stable DPPH radical has been widely used to test the ability of compounds to act
350
as free radicals scaverngers or H irons donors and thus to evaluate the antixodant activity (Jao
351
and Ko, 2002). In this study, evident that the ability of DPPH radicals scavenging activity of
352
tea extracts is shown in (Fig.1c). The activity of tea extract increased with increase
353
concentration (P< 0.05). The result suggested that, the IC50 value of R. mucronata showed
354
highest radical scavenging activity was 91.83±1.26% when compared to 78.92±1.72% for R.
355
apiculata and 90.87±1.56% for R. annamalayana at the concentration 100 µg/ml
356
respectively. Pandima Devi et al. 2009 have reported that, the IC50 value of R.mucronata
357
DPPH was 43.171µg/ml, which was comparatively much lower than the results of the present
358
study. Similalry, Agoramoorthy et al., 2008 have reported that, the DPPH free radical
359
scavengers
360
comparable to our results (93.39 and 90.31%). Wei et al., 2010 have reported that, the DPPH
361
radical scavengers was 115.67 µg/ml in K.candel in 70% acetone extracts, which was
362
comparatively higher than the results of the present study. The high radical scavenging
363
activity of R. mucronata could be due to presence of flavonoids that can be perform radical
364
scavenging activity action of on free radical (DPPH, hydroxyl and hydrogen H2O2) for their
365
reduction of hydroxide formation. In this study, the presence of the functional group -OH in
366
the structure and its position of flavonoid and or phenol molecules determine the antioxidant
in R. mucronata and R.apiculata were 79.9 and 64.7 µg/ml, which was
12
367
activity (Fig.1c). This suggests that the mangrove extracts contain compounds that are
368
capable of donating hydrogen to a free radical in order to remove odd electron which is
369
responsible for radical's reactivity (Wang et al., 1998). Research also indicates that the total
370
antioxidant and DPPH scavenging potential are particularly suitable for the evaluation of
371
antioxidant activity of crude extracts (Poli et al., 2003). The result of DPPH scavenging
372
activity assay in this study indicated that the mangroves species were potently active.
373
Reducing capacity of tea extracts can serve as a significant indicator of their potential
374
antioxidant activity. The total reducing ability of the mangrove black teas were evaluvated at
375
different varied concentrations (50,100, 500 mg/mL) are shown in (Fig.1d). Among the three
376
tea extract tested, R. mucronata showed maximum reducing power at all the concentrations
377
(P< 0.05) and showed highest reducing activity R. mucronata 0.9733±0.55% when
378
comparted for R. apiculata 0.9276±1.84% and R. annamalayana 0.8255±1.20% at the
379
concentration of 500 µg/ml (Fig.1d). Similarly, Pandima Devi et al. 2009 have reported that,
380
the reducing capacity of R.mucronata, R.apiculata and R.annamalayana were 0.360, 0.263
381
and 0.259 µg/ml, which was comparatively much lower than the present study. The reducing
382
capacity of a compound may serve also as an important indicator of its potential antioxidant
383
activity. The results of high reducing power of R.mucronata were agreement with highest
384
DPPH activity of the present study. The reducing properties are thought to be associated with
385
the development of reductones, which have been shown to exert antioxidant action by
386
terminating the free radical chain reactions by donating a hydrogen atom. Reductones are also
387
reported to react with certain precursors of peroxide, thus preventing peroxide formation
388
(Singh and Rajini, 2004). The result of teas were capable of reducing Fe3+ to Fe2+, which was
389
related to the capability of donating electrons of the present phenolics, suggesting that teas
390
may act as the terminators of free radical chains, transforming reactive free radical species
391
into more stable non-radical products. The antioxidant capacity of flavonoids may improve
392
endothelial function by lowering oxidative stress. Better endothelial function impacts on
393
vasomotor tone, platelet activity, leukocyte adhesion and vascular smooth muscle cell
394
function. Studies have shown that black tea flavonoids improve coronary circulation Hirata et
395
al., (2004) and attenuate endothelial dysfunction in humans (Duffy et al., 2001). The results
396
suggested that, a reducing power of the compound appears to be related to degree of
397
hydroxylation and extent of conjugation in polyphenols wich was seen in tea extracts
398
especially in R.mucronata when comapare to R.apiculata and R. annamalayana.
13
399
NO* causes ischemic injury, the toxicity of the due to increases on reaction with O2*-
400
to produce ONOO-, wich reacts with biomolecules like DNA, proteins, lipids (Halliwell,
401
1991). Nitric oxide was generated when sodium nitro preside reacts with oxygen to form
402
nitrite. Suppression of NO* release may be attributed to a direct NO* scavenging effect of tea
403
extracts decreasing the amount of nitrite generated from the decomposition of sodium nitro
404
preside invitro as shown in (Fig.1e). The nitric oxide radical scavenging activity of three
405
mangrove extracts increased as the concentration increased (P< 0.05). The maximum activity
406
was observed from R. mucronata (75.33±0.91%) followed by R. apiculata (72.53±1.65%)
407
and R. annamalayana (62.8±1.53%) at the concentration of 100 µg/ml. Similarly, Pandima
408
Devi et al., 2009 found that NO* scavenging values of R.mucronata, R.apiculata and
409
R.annamalayan were 58.14, 27.5 and 29.7 µg/ml in nitric oxide assay. Nitric oxide (NO) is a
410
reactive free radical produced by phagocytes and endothelial cells, to yield more reactive
411
species such as peroxynitrite which can be decomposed to form OH radical. The level of
412
nitric oxide was significantly reduced in this study by the black tea extracts. Since NO plays a
413
crucial role in the pathogenesis of inflammation (Moncada et al., 1991), this may explain the
414
use of Rhizophoraceae members for the treatment of inflammation and for wound healing.
415
Table 4 showed biological potential i.e antioxidant, antibacterial and phytochemical and
416
others activities in the mangroves species of this region was compared with different region
417
in this world.
418
The tea extracts was analyzed by FT-IR to identifiy the functional groups in the
419
bioactive components based on its peack values and electron transition of compounds shown
420
in Fig 2a, 2b and 2c. The FT-IR spectrum for the methanolic extracts of R.mucronata,
421
R.apiculata and R.annamalayan with its peak values were observed at 441,665,754, 1028,
422
1228, 1450, 1664, 2044, 2222, 1255, 2599, 2833, 2943, 3348, 3350 and confirmed the
423
presence of the chloro alkanes, flour alkenes/ phenol, alkenes, nitrile, amide, methylene,
424
methyl, alcohol/phenol/ flavonoid.
425
4.5 Antibacterial activity
426
The antibacterial activity of tea from Rhizophoraceae members (R. mucronata, R.
427
apiculata and R. annamalayana) showed significant and effective antimicrobial activity
428
against human pathogenic bacterial strains (Escherichia coli, Salmonella typhi, Proteus
429
vulgaris and Staphylococcus aureus) tested and the results are shown in (Table 3). No zone
430
of inhibition was observed in DMSO (negative control) and the positive control of penicillin
14
431
tested for antibacterial activity exhibited maximum zone of inhibio of 13.1±0.02 mm against
432
Salmonella typhi. R.mucronata showed higher antibacterial activity compared with
433
R.apiculata and R.annamalayan, R.mucronata was more effective against E. coli, S. typhi and
434
P.vulgaris compared to gram positive bacteria like S. aureus. These results are in agreement
435
with reported given by Kumar et al. 2011 observed that, the Avicinea marina, E.agallocha,
436
and C.decandra showed higher antibacterial activity against S.aureus, Bacillus subtilis,
437
S.epidermides, E.coli, P.aeruginosa and K.pneumoniae at methanolic extract. The
438
antimicrobial properties of mangroves extracts could be due the presence of core compounds
439
Ethanone, 1-(2-hydroxy- 5- methylphenyl), which might play an important role in their
440
antibacterial activity (Manilal et al., 2015). Extracts from different mangrove plants and
441
mangrove associates are active against human and plant pathogens (Chandrasekaran et al.,
442
2009). This indicates that R. mucronata, R.apiculata and R. annmalayana tea extracts showed
443
more antibacterial activity against Staphylococcus aereus, Proteus vulgaris and E.coli than
444
other strains. These results indicated that, the effective anti bacterial activity due to the
445
potential bioactive, functional group OH and N-H group (Phenol and flavonoids) present of
446
mangrove plants. Recently Abdurahman et al., 2016 documented that, the antimicrobial
447
compouns present in Rhizophora sp includes polyphenols, carbohydrates, fatty acids, palmitic
448
acid, cis and trans isomers of oleic acid, linolenic acid miristic acid, tannin and sterols.
449
4.6 TLC
450
The methanol extract with a concentration of 1 mg/mL reported the presence of three major
451
compounds with Rf values of 0.50, 0.36 and 0.14 in R.mucronata, 0.49, 0.46 and 0.12 in
452
R.appiculata and 0.52, 0.31, 0.11 in R. annmalayana as visualized under iodine chamber and
453
UV light. The larger Rf value of a compound, the larger the distance it travels on the TLC
454
plate.
455
CONCLUSION
456
The present study concluted that mangroves are rich source of tea extracts. The extracts
457
contained phenolic and polyphenolic compounds that exhibited high antioxidant properties
458
and considerable antibacterial activities against human bacterial pathogens. The tea extracts
459
had stable scavenging activity against the free radial molecules prevent cell and DNA
460
demage. The most powerful antioxidant activity of Rhizophora species can be accredited to
461
neutralizing and scavenging ability of the free radicals. The leaf extracts of mangroves in
15
462
particular Rhizophora species has potential to be developed as an herbal drug and
463
nutraceutical and thus in curing infective human diseases. Furthermore, research is needed to
464
elucidate the complete mode of action and application of phenol compounds to prevent the
465
human bacterial pathogenic diseases and aquatic pathogenic bacteria.
466
Acknowledgements
467
The authors are thankful to the authorities of Alagappa University, Tamilnadu, India, for
468
providing necessary facilities to carry out this research work.
469
Conflicts of interest
470 471
All the authors declare that there is no potential conflict of interest. 6. References
472 473
Abdurahman,
N.H., Nitthiya,
J., Omer, M.S. 2016.The Potential of Rhizophora
474
mucronata Composition and Biological Activities asMangrove Plants: A Review.
475
Aust. J.Bas. Appl. Sci., 10(4), 114-139.
476
Abu, OM., Abdul, AM., Rowshanul, HM., Rezaul, KM. 2011. Antimicrobial
477
investigation on Manilkara zapota (L.) P. Royen. Int J Drug Develop Res. 3, 185-
478
190.
479
Agoramoorthy, G., Chen, FA., Venkatesalu, V., Kuo, DH., Shea, PC. 2008. Evaluation of
480
antioxidant polyphenols from selected mangroves plants of India. Asian. J. Chem.
481
20(2), 131-1322.
482
Bagyalskshime, B., Ponmurugan, P., Marimuthu, S. 2012. Influence of potassium
483
solubilizing bacteria on crop productivity and quality of tea (Camellia sinensis). Afr.
484
J. Agric. Res. 7(30), 4250-4259.
485 486 487 488 489 490 491 492
Bandaranayake, WM. 2002. Bioactivities, bioactive compounds and chemical constituents of mangrove plants. Wetl. Ecol. Manag. 10, 442 - 452. Barnabas, CG., Nagarajan, S. 1988. Antibacterial activity of flavonoids of some medicinal plants. Fittoterapia. 3, 508-10. Benavente, GO., Castillo, J., Marin, FR., Ortuno, A.,
Del, RJA. 1997. Uses and
properties’ of citrus flavonoids. J.Agric. Food Chem. 45, 4505- 4515. Blois, M.S. 1958.Antioxidant determination by the use of a stable free radical. Nature. 181, 1199 -1120. 16
493
Bose, AK., Urbanczy, k., Lipkowska, Z., Subbaraju, GV., Manhas, MS., Ganguly, SN.
494
1992. In: Desai, B.N. (Ed.). Oceanography of the Indian Ocean. Oxford and IBH,
495
New Delhi. Pp. 407- 411.
496 497 498 499
Briskin, DP. 2000. Medicinal plants and phytomedicines: Linking plant biochemistry and physiology to human health. Plant Physiol. 124: 507-14. Dodd, R.S., Fromard, F., Rafii, Z.A., Blasco, F. 1995. Biodiversity among West African, Rhizophora: Foliar wax chemistry. Bio. Sys. Ecol. 23 (7-8), 859 - 868.
500
Duffy, SJ., Keaney, JF., Holbrook, M., Gokie, N., Swerdloff Fueib, PT. 2001. Short–and
501
long–term black tea consumption reverses endothelial dysfunction in patients with
502
coronary artery disease. Ciruclation. 104, 151-156.
503 504 505 506 507 508 509 510 511 512 513 514 515
Fabricant, DS., Farnsworth, NR. 2001. The value of plants used in traditional medicine for drug discovery. Environ. Health Perspect. 11, 69-75. Fauvel, MT., Bousquet Melou, A., Moulis, C., Gleye, J., Jensen, SR. 1995. Iridoid glycosides from Avicennia germinans. Phytochem. 38 (4): 893- 894. Gao, M., Xiao, H. 2012. Activity-guided isolation of antioxidant compounds from Rhizophora apiculata. Molecules. 17(9): 10675-10682. Garrat, DC. 1964. The quantitative analysis of drugs. Chapman and Hall Ltd, Takyo.3: pp. 456- 458. Gupta, S. 1994. Prospects and perspective of natural plants products in medicine. Indian J Phamacol. 26, 1- 12. Halliwell, B. 1991. Reactive oxygen species in living systems: source, biochemistry, and role in human disease. Am J Med. 91, 14-22. Haq, M., Sani, W., Hossain, A.B.M.S., Taha, RM., Monneruzzaman, K.M. 2011. Total
516
phenolic
contents,
antioxidant
and
antimicrobial
517
gymnorrhiza. J Med. Plant Res. 5(17), 4112-4118.
activities
of
Bruguiera
518
Hirata, K., Shimada, K., Watanabe, H., Otsuka, R., Tokai, K., Yoshiyama, M. 2004.
519
Black tea increases coronary flow rate velocity reserve in healthy male subjects.
520
Am. J. Cardiol. 133, 1384 - 1388.
521 522
Jao, CH., Ko, WC. 2002. 1, 1- Diphenyl-2- picrylhydrazyl (DPPH) radical scavenging by protein hydrolysates from tuna cooking juice. Fich Sci. (68), 430-435.
523
Kathiresan, K. 1995. Studies on tea from mangroves leaves. Environ. Ecol. 13, 321- 323.
524
Kathiresan, K. 2000. A review of studies on pichavaram mangroves, southeast India,
525
Hydrobiologia. 430, 185- 205.
17
526 527
Kathiresan, K., Ravi, V. 1990. Seasonal changes in tannin content of mangrove leaves. Indian Forester. 116 (5), 390 − 92.
528
Khafagi, I., Gab-Alla, A., Salama, W., Fouda, M. 2003. Biological activities and
529
phytochemical constituent of the gray mangrove Avicennia marina (Forssk,) Vierh.
530
Egyptian J Biol. 5, 62-69.
531
Kokpal, V., Miles, DH., Payne, AM., Chittawong, V. 1990. Chemical constituents and
532
bioactive compounds from mangroves plants. Studies in Natural Products
533
Chemistry. 7:175- 199.
534
Kumar, VA., Ammani, K., Siddharadha, B. 2011. In vitro antimicrobial activity of leaf
535
extracts of certain mangrove plants colleted from Godavari estuarine of Konaseema
536
delta, India. Int. J. Med. Arom. Plants. 2249-4340.
537
Liang, CAE., Zhi-Xiu Zhou, AE., Ya-Jun, Y. 2007. Genetic improvement and breeding of
538
tea plant (Camellia sinensis) in China: from individual selection to hybridization and
539
molecular breeding. Euphytica. 154, 239-248.
540
Manilal, A., Merdekios, B., Idhayadhulla, A., Muthukumar, C., Melkie, M. 2015. An
541
invitro antagonistic efficacy validation of Rhizophora mucronata. Asian Pac J Trop
542
Dis. 5(1), 28-32.
543
Mitsuda, H., Yuasumoto, K., and Iwami, K. 1996. Antioxidation action of indole
544
compounds during the autoxidation of linoleic acid. Eiyo to Shokuryo. 19, 210- 214.
545
Moncada S, Palmer RMJ, Higgs EA. 1991. Nitric oxide: physiology, pathophysiology
546
and pharmacology. Pharmacol. Rev. 43, 109- 142.
547
Osawa, T. 1994. Novel natural antioxidants for utilization in food and biological systems.
548
In: Uritani I, Garcia VV, and Mendoza EM (eds.). Post-harvest biochemistry of plant
549
food-materials in the tropics. Japan Scientific Societies Press. 241 - 251.
550 551
Oyaizu, M. 1986. Studies on product of browning reaction prepared from glucose amine. Japa J Nut. 44, 307- 315.
552
Pandima Devi, K., Suganthy, N., Kerika, P., Karutha Pandian, S. 2009. Mangrove plant
553
extracts: radical scavenging activity and the battle agains food borne pathogens.
554
Forsch komplementmed. 16, 41-48.
555
Poli, F., Muzzoli, M., Sacchetti, G., Tassinato, G., Lazzarin, R., Bruni, A. 2003. Endemic
556
species of sardo-corso-balearic area: molecular composition and biological assay of
557
Teucrium Pharm. Biol. 41, 379.
558 559
Premanathan, M., Chandra, K., Bajpai, SK., Kathiresan, K. 1992. A survey of Indian marine plants for antiviral activity, Bot. Mar. 35, 31- 35. 18
560
Premanathan, M., Kathiresan, K., Yamamoto, N., Nakashima, H. 1999. In vitro anti-
561
human immunodeficiency virus activity of polysaccharide from the Rhizophora
562
mucronata Poir., Soil Biotechnology Biochem. 63, 1187- 1191.
563
Puupponen-Pimia, R., Nohynek, L., Meier, C., Kahkonen M, Heinonen M, Hopia A.
564
2001. Antimicrobial properties of phenolic compounds from berries. J. Appl.
565
Microb. 90, 494 -507.
566
Rice-Evans, CA., Miller, NJ., Bolwell, PG., Bramley, PM., Pridham, JB. 1995. The
567
relative activities of plant-derived polyphenolic flavonoids. Free Radical Res. 22,
568
375-383.
569
Ronald, SK., Ronald, S. 1991. Beverages and chocolate. In pearson’s composition and
570
analysis of foods, 9th ed., Longman scientific & technical publishers, England, pp.
571
356 – 362.
572
Ruch, RJ., Cheng, SJ., Klaunig, JE. 1989. Prevention of cytotoxicity and inhibition of
573
Intercellular communication by antioxidant catechins isolated from Chinese green
574
tea. Carcinogens. 10, 1003-1008.
575
Samman, LWPM., Cook, NC. 1998. Flavonoids and coronary heart disease: Dietary
576
perspectives. In: Rice-Evans C.A. and Packer, L. Eds, Flavonoids in health and
577
disease, marcel dekker, New York, pp.469 − 482.
578
Saranya, A., Dinesh, P., Ramanathan, TS. 2014. Identification of bioactive compounds of
579
Rhizophora mucronata poir. Leaves using supercritical fluid extraction and GC-MS.
580
World J Pharm and Pharmaceut Sci. 3(10), 1621-1631.
581 582 583 584 585 586 587 588
Sharma, M., Garg, HS. 1996. Iridoid glycosides from Avicennia officinalis. Ind. J. Chem. 35, 459- 462. Singh, A. 2009. Acanthus illicifolius Linn. Lesser known medicinal plant with significant pharmacological activities. Ethanobotanical leafleat. 13, 431- 36. Singh, N., Rajini, P.S. 2004. Free radical scavenging activity of aqueous extract of potato peel. Food Chem. 85, 611- 616. Singleton, VL., Rossi, JA. 1965. Colorimetry of total phenolics with phosphomolybdicphosphotungstic acid reagents. Am. J. Enol. Vitic. 16, 144 -158.
589
Sithranga Boopathy, N., Kathiresan, K., Jeon, YJ. 2011. Effect of mangrove black tea
590
extract from Ceriops decandra (Griff.) on hematology and biochemical changes in
591
dimethyl benz[a]anthracene-induced hamster buccal pouch carcinogenesis. Environ
592
Toxicol Pharmacol. 32(2), 193-200.
19
593
Sithranga Boopathy,N., Kathiresan, K., Manivannan, S.,, Jeon ,Y.J. 2011. Effect of
594
Mangrove Tea Extract from Ceriops decandra (Griff.) Ding Hou. on Salivary
595
Bacterial Flora of DMBA Induced Hamster Buccal Pouch Carcinoma. Indian J
596
Microbiol. 51(3): 338–344.
597
Thanaraj, SNS., Seshadri, R. 1990. Inflence of polyphenol oxidase activity and
598
polyphenol content of tea shoot on quality of black tea. J. Sci. Food Agric. 51, 57-
599
69.
600
Trease, GE., Evans, WC. 1989. Pharmacognosy (13th ed.). London: Balliere Tindall Ltd.
601
Vadlapudi V, Chandrasekhr Naidu K. 2009. Evaluation of antioxidant potential of
602
selected mangrove plants. J Pharm Res. 2(11), 1742-1745.
603
Venkatesan, S., Murugesan, S., Senthurpandian, VK., Ganapathy, MNK., 2005. Impact of
604
sources and doses of potassium on biochemical parameters of tea. Food Chem. 90,
605
535-539.
606
Wang, M., Li, J., Rangarajan, M., Shao, Y., LaVoie, EJ., Huang, T., Ho, C. 1998.
607
Antioxidative phenol compounds from sage (Salvia officinalis). J. Agric. Food.
608
Chem. 46, 4869- 4873.
609
Wei, S.D., Zhou, H.C., Lin, Y.M. 2010. Antioxidant activities of extract and factions
610
from the Hypocotyls of the mangrove plant Kandelia candel. Int. J. Mol. Sci. 11,
611
4080-4093.
612 613
Zheng, W., Wang, SY. 2001. Antioxidant activity and phenolic compounds in selectedherbs.J.Agric Food Chem. 49(11), 5165 - 5170.
614 615 616
Figure Caption:
617
Fig. 1. Antioxidant assay of mangroves black tea (a) Total Antioxidant (b) Total Phenol (c)
618
DPPH assay (d) Total Reducing Power (e) Nitric Oxide Assay
20
50 100 500
90 80
Total antioxidant %
70 60 50 40 30 20 10 0
R.mucronata
R.apiculata
R. annamalayana
Different concentrations
619 620 621
(1a)
50 100 500
90 80
Total phenol %
70 60 50 40 30 20 10 0 R. mucornata
R. apiculata Different Concentrations
622 623
(1b)
21
R. annamalayana
50 100 500
100
DPPH activity %
80
60
40
20
0 R. mucornata
R. apiculata
R. annamalayana
Different concentrations
624 625 626
(1c) 50 100 500
1.1 1.0
Total Reducing Power %
0.9 0.8 0.7 0.6 0.5 0.4 0.3 0.2 0.1 0.0 R. mucornata
R. apiculata
Different concentrations
627 628 629
(1d)
22
R. annamalayana
50 100 500
80 70
Nitric Oxide %
60 50 40 30 20 10 0 R. mucornata
R. apiculata
R. annamalayana
Different concentrations
630 631
(1e)
632
All the values expressed mean and standard division. The statistical significant different
633
letters (a-e) with (P< 0.05).
634
635 636 637
Fig. 2a FTIR spectrum for R. mucronata tea extract
638
23
639 640
Fig. 2b FTIR spectrum for R. apiculata tea extract
641 642 643 644
645 646
Fig. 2c FTIR spectrum for R. annamalayana black tea extract
647
24
648 649
Table 1 Chemical constituent quality and caffeine content of tea extracts (R. mucronata, R. apiculata and R. annamalayana).
650
Table 2 Phyto-chemical characterization of tea extracts.
651
Table 3 Effect of tea extracts on the growth of Gram positive and Gram negative human
652
pathogenic bacteria.
653
Table 4 Comparison of biological potential in mangrove species as reported in the literature.
654 655
25
Table 1 Chemical constituent quality and caffeine content of tea extracts (R. mucronata, R. apiculata and R. annamalayana). Chemicals constituent
R. mucronata
R. apiculata
R. annamalayana
Theaflavine
0.42±0.02a
0.18±0.02a
0.5±0.08a
Thearubigin
4.60±0.24b
3.49±0.22 b
4.52±0.20 b
Highly polymerized substane
3.95±0.18 c
4.71±0.20 c
3.9±0.28 c
Total liquor colour
1.1±0.14 d
0.49±0.03 d
0.51±0.03 d
Caffeine
ND
ND
ND
Dates were expressed as mean ± standard division; ND- Not Detectable. The different letters a-c are statistically significant with P<0.05.
Table 2 Phyto-chemical characterization of tea extracts. Phytochemical test
R. mucronata
R. apiculata
R. annamalayana
Proteins-xanthoprotein
+
+
+
Steroids
+
+
+
Tannins
+
+
+
Glycosides
+
+
+
Reducing sugar
+
+
+
Sterols
+
+
+
Terpenoids
+
+
+
Cardioglycoside
+
+
+
Carbohydrate
+
+
+
Flavanoids
+
+
+
Phenol
+
+
+
+; presence of phyto-chemical components.
Table 3 Effect of tea extracts on the growth of Gram positive and Gram negative human pathogenic bacteria. Bacteria
Positive
Negative
control
control
Penicillin Escherichia
DMSO
Zone of inhibition in (mm)
R. mucronata
R. apiculata
R. annamalayana
11±0.01
-
10±0.11
2.0±0.01
6.0±0.05
13.1±0.02
-
8.0±0.07
7.0±0.06
2.0±0.03
9.0±0.04
-
6.0±0.05
5.0±0.03
10±0.09
10.1±0.00
-
5.0±0.04
15±0.12
7.0±0.05
coli Salmonella typhi Proteus vulgaris Staphylococcus aureus Mean values (n=3 with SD).- No zone of inhibition. Table 4 Comparison of biological potential in mangrove species as reported in the literature. Name of the
Study area
Biological properties
Reference
Parangipettai,
Antiviral and anti larvicidal
Premanathan
mangroves R.apiculata
Tamilnadu, India R.mucronata
Parangipettai,
et al., 1999 Antiviral, anti- HIV
Tamilnadu, India R.mucronata,
Pichavaram and
R.apiculata,
Tamilnadu, India
Premanathan et al., 1999
Polyphenol and antioxidant
Agoramoorthy et al., 2008
Avicennia officinalis, Ceriops decandra Avicennia marina
Gulf of Aqaba,
Antibcaterial, anticandidal, anti
Khafagi et al.,
Egypt
bacteriophage, cytotoxicity and
2003
plant growth grgulatar R.mucronata,
Pichavaram and
Antioxidant activity and
Pandima Devi
R.apiculata,
Thondi, Tamilnadu,
R.annamalayana,
India
antibacterial properties
et al., 2009
Antioxidant activity
Vadlapudi and
Avicennia marina and Ceriops decandra Avicennia
Andhra Pradesh,
officinalis,
India
Naidu, 2009
A.marina, R.conjugata, R.mucronata, Salicornia brachiata, Salvodara persica, xylocarpus granatum Kandelia candel
China
Antioxidant properties
Wei et al., 2010
R.mucronata
R.mucronata
Ceriops decandra
Parangipettai,
Phytochemical and Bioactive
Saranya et al.,
Tamilnadu, India
compound
2014
Kerala, Kollam,
Phytochemical and Bioactive
Manilal et al.
India
compound
2015
Parangipettai,
Mangrove black tea buccal pouch
Sithranga
Tamilnadu, India
carcinogenesis in hamsters
Boopathy et al., 2011
C. decandra
Parangipettai,
Mangrove black tea prevents the
Sithranga
Tamilnadu, India
oral cancer incidences
Boopathy et al., 2011
R.mucronata,
Parangipettai,
Mangrove black tea rich in
R.apiculata,
Tamilnadu, India
Phytochemical, antioxidant and
R.annamalayana
antibacterial activity
Present study