Effects of different light source and media on growth and production of phycobiliprotein from freshwater cyanobacteria

Accepted Manuscript Effects of different light source and media on growth and production of phycobiliprotein from freshwater cyanobacteria Helena Khatoon, Lai Kok Leong, Norazira Abdu Rahman, Sohel Mian, Hasina Begum, Sanjoy Banerjee, Azizah Endut PII: DOI: Reference:

S0960-8524(17)31881-3 https://doi.org/10.1016/j.biortech.2017.10.052 BITE 19093

To appear in:

Bioresource Technology

Received Date: Revised Date: Accepted Date:

19 July 2017 11 October 2017 12 October 2017

Please cite this article as: Khatoon, H., Kok Leong, L., Abdu Rahman, N., Mian, S., Begum, H., Banerjee, S., Endut, A., Effects of different light source and media on growth and production of phycobiliprotein from freshwater cyanobacteria, Bioresource Technology (2017), doi: https://doi.org/10.1016/j.biortech.2017.10.052

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1

EFFECTS OF DIFFERENT LIGHT SOURCE AND MEDIA ON GROWTH AND

2

PRODUCTION

3

CYANOBACTERIA

OF

PHYCOBILIPROTEIN

FROM

FRESHWATER

4 5

Helena Khatoon a*, Lai Kok Leong

b

6

Begum d, Sanjoy Banerjee d, Azizah Endut e

,

Norazira Abdu Rahman b, Sohel Mian

b,c

, Hasina

7 8

a

9

Terengganu, Malaysia

Institute of Tropical Aquaculture, Universiti Malaysia Terengganu, 21030 Kuala

10

b

11

Kuala Terengganu, Malaysia

12

c

13

Sylhet, Bangladesh

14

d

15

e

16

Abidin University, 21300 Kuala Terengganu, Terengganu, Malaysia

School of Fisheries & Aquaculture Sciences, Universiti Malaysia Terengganu, 21030

Department of Fisheries Biology & Genetics, Sylhet Agricultural University, 3100

Institute of Bioscience, Universiti Putra Malaysia, 43400 UPM Serdang, Malaysia

East Coast of Environmental Research Institute, Gong Badak Campus, Sultan Zainal

17 18 19

Abstract

20 21

The aim of this study was to determine the effect of different light sources and media

22

(wastewater and BBM) on the growth of Pseudanabaena mucicola and its

23

phycobiliprotein production. Results showed that P. mucicola grown in white light

24

using wastewater as medium attributed higher biomass (0.55 g L-1) and when extracted

25

with water, also showed significantly higher (P < 0.05) production (237.01 mg g-1) and

26

purity (1.14) of phycobiliprotein. This study validated that phycobiliprotein extracted

27

from P. mucicola using water can be food grade natural blue pigment. Moreover,

28

cyanobacteria grown in wastewater could cut down the production cost of

29

phycobiliprotein.

30 31

Keywords: Phycobiliprotein, Cyanobacteria, Growth, Wastewater, Light Source

32 33

1. Introduction

34 35

Cyanobacteria (blue-green algae) uphold several structural features resemble to

36

those of bacteria. However, these are classified with algae due to their chlorophyll a and

37

other compounds content. Many cyanobacteria species are potential producers of value-

38

added bioactive compounds such as chlorophyll a, b and c, β-carotene, astaxanthin,

39

xanthophylls and phycobiliprotein (Begum et al., 2016). Moreover, cyanobacteria have

40

gained great attention as a natural antioxidant source because of their bioactive

41

compounds composition. Some cyanobacteria species have the ability to produce

42

bioplastic poly-3-hydroxybutyrate under nitrogen deprivation and photoautotrophy

43

(Taepucharoen et al., 2017). Phycobiliprotein are the major light-harvesting pigments of

44

cyanobacteria, red algae, glaucocystophyte and cryptophyte (Sidler, 1994). They are

45

highly fluorescent because of their covalently bound, linear tetrapyrrole chromophores

46

known as bilins (Paliwal et al., 2017). Phycobiliprotein includes blue colored

47

phycocyanin, bluish green colored allophycocyanin and red colored phycoerythrin

48

(Grossman et al., 1993). In cyanobacteria, phycobiliprotein may comprise up to 40% of

49

its total soluble protein content. It is a high-value algae products used in food and

50

cosmetic industries, nutraceuticals and pharmaceuticals, as well as in biomedical

51

research and clinical diagnostics. Different types of cyanobacteria have been recognized

52

as rich source of bioactive compounds (Abarzua et al. 1999; Dahms et al. 2006). Most

53

of the bioactive compounds isolated from cyanobacteria consist of an amino acid and

54

fatty acid portion. Antibacterial, antifungal, antialgal, antiprotozoan, and antiviral are

55

the secondary metabolites isolated from different cyanobacteria. In addition,

56

cyanobacteria such as Phormidium sp., Spirulina platensis, Lyngbya majuscule and

57

Schizochytrium sp. are source of a variety of compounds such as polysaccharides, lipids,

58

proteins, vitamins, sterols, enzymes, pharmaceuticals and some other well recognized

59

fine chemicals (Sørensen et al., 2013; Borowitzka 1992; Pulz and Gross 2004). It has

60

been using as coloring agent in food industry, specially candies and soft drinks. Due to

61

its non-toxic and non-carcinogenic properties, phycobiliprotein is gaining prominence

62

worldwide as a natural food colorants in replacing the potentially toxic and carcinogenic

63

synthetic food colorants (Pandey et al., 2013). It is also considered as a high value

64

natural dye, of which the native pigment price are US$ 3 to US$ 25 mg-1 and can reach

65

up to US$ 1500 mg-1 for certain cross-linked pigments.

66 67

However, the growth of microalgae and pigment production are affected by many

68

factors such as light irradiances, photoperiods, pH, nutrient limitation, nitrogen

69

supplements and salinity (Hemlata and Fatma, 2009). On the other hand, some species

70

are also capable of producing certain metabolites under extreme culture condition, in

71

order to overcome and adapt to the biotic or abiotic stress conditions (Paliwal et al.,

72

2017). Therefore, the production of metabolites during microalgae growth is important

73

to obtain maximum productivity. Ores et al. (2016) reported that by using an ultrasonic

74

homogenizer, it was possible to obtain high extraction yields of phycobiliproteins from

75

cyanobacteria. In addition, extraction method with drying, freezing and maceration were

76

also effective.

77 78

Light on its own plays a very important role in growth and pigment accumulation of

79

cyanobacteria. Most cyanobacteria have the ability to control the amount of their

80

photosynthetic antenna pigments, phycobiliprotein based on the spectrum of ambient

81

light which is also known as chromatic adaptation (Vogelmann and Scheibe et al.,

82

1978). Upon exposure to changes in light color or high irradiance, cyanobacteria

83

dramatically change its pigmentation composition to optimize their light harvesting

84

mechanism (Grossman et al., 2001; Ojit et al., 2015). The changes in cell pigmentation

85

in response to specific spectral illuminations is due to the moderation of the red colored

86

phycoerythrin and the blue-colored phycocyanin, with a predominance of phycoerythrin

87

in green-light-grown cells and of phycocyanin in red-light grown cells (Paliwal et al.,

88

2017). Thus, even a slight fluctuation in light factors may lead to morphological and

89

physiological changes in cyanobacteria.

90 91

In addition, the high cost of the commercial culture medium is also one of the

92

challenges faced in cyanobacteria production. Generally, cyanobacteria can grow in

93

various aquatic environments such as river, lake and wastewater depending on the

94

nutrient availability specially nitrogen and phosphorus. Aquaculture wastewater from

95

fish and shrimp farming was identified as a potential media for microalgae culture as

96

they ensure ample nitrogen and phosphorus (Khatoon et al., 2016). It can be used as a

97

potential cost effective medium for cyanobacteria culture instead of being released as

98

waste to the environment which may lead to a severe pollution problem.

99 100

There is little data on the growth and phycobiliprotein production of the

101

cyanobacteria Pseudanabaena mucicola, especially under different growth factors such

102

as light and media. In addition, extraction step is very important because of the

103

thickness of the cell wall of the microorganisms and the intracellular location of

104

phycobiliprotein (Ores et al., 2016).

105

There is great demand of phycobiliproteins at commercial level. However, there is a

106

scarcity of information in this field because the quality of the pigments depends on the

107

media and different light source use to culture cyanobacteria. The potential of

108

phycobiliprotein extraction by using chemical free water extraction in comparison to the

109

commonly used phosphate buffer was also determined. In addition, this study also

110

highlighted the potential use of wastewater as an alternative to the expensive

111

commercial medium. Findings can be manipulated and applied for specific uses and for

112

high mass production of P. mucicola commercially.

113 114

2. Materials and Methods

115 116

2.1. Sample collection, culture and maintenance

117

Freshwater cyanobacteria, P. mucicola was obtained from Laboratory of Live

118

Food Culture, Institute of Tropical Aquaculture, University Malaysia Terengganu. The

119

pure cyanobacterial species was cultured in an Erlenmeyer flask containing the Bold

120

Basal Media (BBM) (Stein, 1980). Sub culturing was done every two weeks in order to

121

maintain healthy and good stocks. Then the stock cultures were used during the

122

experiment.

123 124

2.2. Media preparation

125

Two different media (wastewater and Bold Basal medium (BBM)) were

126

prepared. BBM, a commercial media for freshwater algae involves the preparation of

127

stock solutions which consisted of the macronutrients and trace metal solutions. On the

128

other hand, wastewater from cage culture in Kenyir Lake, Malaysia was collected to be

129

used as media. The wastewater was filtered using 0.45µm membrane filter before it was

130

sterilized by UV light (model: RIBAO UV-6 Submersible, Singapore) for 72 hours.

131

Afterthat wastewater was kept at room temperature until further used.

132 133

2.3. Culture of cyanobacteria

134

Experiment was carried out using 2 L flask filled with 1.5 L culture media under

135

three different light sources (white light, blue light, and natural light). The light sources

136

used for culturing cyanobacteria are cool white and blue fluorescent tubes (Philips,

137

USA). Two different culture media, which were BBM and wastewater were used. The

138

pH of the wastewater and BBM media were adjusted 7.5 and was measured using a pH

139

meter (Orion, USA). Culture with white light (180 µmol m-2s-1) and blue light (110

140

µmol m-2s-1) source were maintained inside the culture room at 25 oC and 24 hours

141

photoperiod and was measured using light meter (Quantum Light Meter, Spectrum

142

technologies Inc., USA). Meanwhile, the culture under natural condition was kept

143

outside under shade. The initial stock culture was at 10% of culture volume for each

144

treatment.

145

Growth parameters were measured daily. All experimental cultures were

146

harvested at stationary phase. Cells were harvested at their stationary phase by

147

centrifugation at 8000 rpm for 10 min followed by washing twice with sterilized

148

distilled water. The harvested biomass was dried overnight at 40 °C and kept at -20 oC

149

until further used.

150 151

2.4. Growth parameters analysis

152

Cyanobacterial growth was measured using biomass and optical density.

153

Biomass was measured in terms of chlorophyll a according to APHA (1992). The

154

optical density was determined by using a spectrophotometer (UV-VIS 1601,

155

Shimadzu, Japan) and the wavelength used was 650 nm.

156 157

2.5. Extraction of phycobiliprotein from cyanobacteria

158

Dried cyanobacteria biomass (40 mg) was soaked in 10 ml phosphate buffer (pH

159

7.0; 0.1 M) and distilled water, vortexed and stored at 4 °C for 24h. Phycobiliprotein

160

were extracted by centrifuging at 6000 rpm for 10 min after which the supernatants

161

were collected and absorbance were read at different wave lengths (562nm, 615nm, and

162

652nm) by using phosphate buffer and water as blank. The amount of phycocyanin

163

(PC), phycoerythrin (PE) and allophycocyanin (APC) in the samples were calculated

164

according to Siegelman and Kycia (1978). Meanwhile, total phycocyanin,

165

phycoerythrin and allophycocyanin were calculated according to Silveira et al. (2007).

166 167 168

169 170 171

2.6. Purification of Phycobiliprotein The purity of the phycobiliprotein extract was determined by using spectrophotometer at absorbance ratio of A619/A280 and A656/A280 (Reid et al., 1998).

172 173

2.7. Nutrient analysis wastewater and BBM

174

Total ammonia nitrogen, nitrite nitrogen, and phosphate phosphorous of the

175

culture media were determined before P. mucicola culture and after it was harvested.

176

Nutrients analysis were done according to Parsons et al. (1984).

177

chromatography (882 Compact IC Plus, Metrohm, Switzerland) was used to analysed

178

chemical properties of wastewater.

In addition, ion

179 180

2.8. Statistical Analysis

181

The collected data were analyzed using two way analysis of variance (ANOVA) and

182

the significant differences amongst treatments were determined using Tukey test at 95%

183

confidence interval level. All statistical analysis was done using the SPSS (Statistical

184

Package for the Social Sciences) software.

185 186

3. Results and discussion

187 188

3.1. Growth and biomass yield of P. mucicola

189

The optical density and dry biomass yield of P. mucicola cultured under different

190

light sources and media have been shown in Fig. 1 and Fig. 2. In this study, white light

191

had significantly (P < 0.05) highest growth in terms of optical density compared to blue

192

light and natural light (Fig. 1). The highest optical density was obtained by white light

193

and BBM treatment, followed by white light and wastewater media treatment at 0.731

194

and 0.575 abs, respectively. On the other hand, the chlorophyll a content of P. mucicola

195

reached it peaks on Day 8 with the highest value obtained when P. mucicola was

196

cultured under white light and using wastewater media at 2.10 mg m-2. The highest dry

197

biomass was also produced when P. mucicola was cultured under white light source

198

with no significant difference between BMM and wastewater media at 0.577 g L-1 and

199

0.555 g L-1, respectively. This might caused by the Pseudanabaena sp. not similar with

200

other cyanobacteria which grow better in blue light and low light intensity. Besides, P.

201

mucicola may have slower growth in blue light condition.

202 203

Cyanobacteria are influenced by a variety of environmental factors and they play a

204

significant role in the production and composition of the photosynthetic pigments.

205

Factors like light, temperature, pH and nutrient availability are known to influence the

206

amount of various phycobiliprotein in cyanobacteria (Hemlata and Fatma, 2009; Takano

207

et al., 1995). Cyanobacteria have developed unique physiological and morphological

208

features to respond to changes in environmental parameters for instance, nutrient and

209

light (Tandeau de Marsac and Houmard, 1993). Higher growth in terms of optical

210

density and chlorophyll a content under white light is in accordance with Madhyastha

211

and Vatsala (2007), who reported that white light was preferable for chlorophyll

212

synthesis which leads to higher chlorophyll concentration. The higher light intensity of

213

white light also promotes greater biomass production for P. mucicola in this study. The

214

growth of cyanobacteria was directly proportional to light intensity until saturation level

215

(Ravelonandro et al., 2008). Although other cyanobacterial species such as Spirulina sp.

216

showed higher chlorophyll content under blue light (Chauhan and Pathak, 2010), but in

217

this study, P. mucicola showed the lowest chlorophyll content under natural light

218

(wastewater) compared to other light sources. It was reported by Ojit et al. (2015) that

219

the increase in light availability usually lead to a decrease in chlorophyll a content of

220

cyanobacteria as a strategy for prevention of photo-oxidative damage caused by the

221

production of free radicals. Photoinhibition is the inhibition of photosystem II (PSII)

222

activity under strong light. This occurrence is due to an imbalance between the rate of

223

photodamage to PSII and the rate of the repair of damaged PSII. The mechanism of

224

photoinhibition, strong light induces the production of reactive oxygen species (ROS),

225

which directly inactivates the photochemical reaction center of PSII (Murata et al.,

226

2007).

227 228

Excessive light energy absorbed by cells may lead to the formation of free

229

radicals such as singlet oxygen, which can lead to photo-inhibition by oxidizing the key

230

proteins of the photosynthetic apparatus, including the D1 protein of photosystem II

231

(Inoue et al., 2011). In terms of higher growth and biomass production, culture of P.

232

mucicola under white light by using wastewater media is recommended. This finding is

233

in accordance with the study by Khatoon et al. (2016) who also found that cultivation of

234

marine microalgae in wastewater produced higher biomass than commercial media. The

235

use of wastewater as a low cost media can lead to the reduction in overall P. mucicola

236

production cost, especially during mass culture.

237 238

3.2. Phycobiliprotein production and purity

239

The phycobiliprotein production (allophycocyanin, phycocyanin and phycoerythrin)

240

and total content of phycobiliprotein production (sum of the phycocyanin,

241

allophycocyanin and phycoerythrin contents) by P. mucicola in response to different

242

light sources and media are shown in Fig. 2 and Fig. 3 respectively. Water and

243

phosphate buffer were used to extract the phycobiliprotein from the cyanobacterial

244

biomass. In the present study, the production of phycobiliprotein is affected by the

245

changes in light source and extraction solvents. Significantly higher (P < 0.05) total

246

phycobiliprotein content was found in water extract compared to phosphate buffer for

247

all treatments. The highest total phycobliprotein content (237 mg g-1) was found in

248

water extract of P. mucicola when cultured under white light and using wastewater

249

media (Fig. 3). Higher allophycocyanin production was also obtained in similar culture

250

condition (white light, wastewater media) by extraction using distilled water (0.523

251

mg/ml). Meanwhile, higher phycocyanin production was found under blue light and by

252

using BBM. No significant difference was found between the different extraction

253

solvent. There was also no significant difference in phycoerythrin content among

254

treatment and extraction solvent. In terms of purity ratio of phycocyanin, significantly

255

higher purity ratio (P < 0.05) was found in water extract (0.84) of P. mucicola when

256

cultured under white light by using wastewater media (Fig. 4).

257 258

Phycobliprotein

can

be

divided

into

four

different

classes

which

are

259

allophycocyanin (bluish green), phycocyanin (blue), phycoerythrin (purple) and

260

phycoerythrocyanin (orange) (Sekar and Chandramohan, 2007). In this study,

261

phycobiliprotein production varies when cultured under different light sources.

262 263

Light quality is responsible to change the phycobiliproteins composition and

264

colour through complementary chromatic adaptation. The chromatic acclimation

265

procedure allows the cells of cyanobacteria to change its light absorption characteristics

266

to regulate photosynthesis according to light availability in different environments. As a

267

result of this spectacle, the pigment which absorbs the incident wavelengths of light

268

most strongly becomes predominant (Wang et al., 2007). In the present study, the

269

selected strain was capable of complementary chromatic adaptation by synthesizing two

270

different types of phycobilisomes periphery rod depending upon the available light

271

condition. In addition, phycobiliprotein content was significantly correlated with

272

fluorescent white light indicating its important role in cyanobacteria. The present

273

findings are also supported by the work done by Ojit et al. (2015). In the contemporary

274

findings, it was observed that white light was the suitable light source for the enriched

275

production of phycobiliproteins in the selected cyanobacterial strains investigated.

276

According to Ojit et al. (2015) fluorescent white light was the most suitable light source

277

for the enhanced production of phycobiliproteins in almost all cyanobacterial strains. In

278

addition, their study also investigated that when strains were exposed to red light, their

279

PE content decreased but simultaneously phycocyanin (PC) increased when compared

280

to other light qualities. Similarly it was observed in PC rich cultures i.e. in red light, PC

281

quantity decreased and PE production increased in blue light. The chromatic adaptation

282

ability of cyanobacteria comprises of three complex pathway which includes regulation

283

by a phytochrome class photoreceptor (highly responsive to green and red light), a

284

complex two component signal transduction pathway and also reaction based on the

285

redox state (Paliwal et al., 2017). In the present study, higher amount of phycocyanin

286

was found under blue light compared to white light and natural light. Its concentration

287

(0.419 mg mL-1) is also higher compared to the phycocyanin obtained in a study by

288

Ores et al. (2016) on Spirulina sp. LEB 18 (120 µg mL-1). According to Lönneborg et

289

al (1985), phycocyanin content in cyanobacterial cells increase with low light intensity

290

due to the chromatic adaptation ability. Thus, the lower phycocyanin in natural light

291

may be due to the higher light intensity compared to other light sources. Culture under

292

natural condition was exposed to high light intensities (0.02 – 700 µmol m-2 s-1 ) and

293

12:12 h light dark period. According to Raps et al. (1983), with an increase in light

294

intensity, the concentrations of chlorophyll a and phycocyanin decrease. At higher light

295

intensities, the cells lessen the amount of thylakoid membranes and phycobilisomes to

296

decrease the quantity of radiant energy absorbed as possible (Tandeau de Marsac and

297

Houmard, 1993). Another study by Lee et al. (2017) also found lower phycocyanin

298

production when cyanobacterial, Nostoc sp. NK was cultured under white light

299

compared to red and plant fluorescent light. Whereas, similar with the study by Cuellar-

300

Bermudez et al. (2014), phycoerythrin has been found to occur in much lower

301

concentration compared to other pigments because it is mainly affected by changes in

302

pH rather than light.

303 304

Different pH of the medium also affects the phycobiliprotein by changing the

305

culture colour of cyanobacteria. The productions of phycobiliproteins were greatly

306

affected by the pH which might indicate the inability of the cyanobacteria to maintain a

307

constant internal pH. At lower pH 7.5 Anabaena sp. NCCU-9, resulted in reduced

308

phycobiliproteins extraction. This may be due to the extreme buffer’s pH which might

309

cause internal electrostatic attraction by changing the charge on protein giving net

310

positive charge and at this stage protein open up and bound solvent is lost resulting in

311

the denaturation of protein (Roe, 2000).

312

313

Phosphate buffer is expensive, preparation is time consuming and poor purity of

314

the selected cyanobacteria in their final targeted product. Therefore, water is evaluated

315

in this study, as an alternative solvent to extract phycobiliproteins from selected

316

cyanobacteria. In the present study water was used as a solvent to extract

317

phycobiliproteins. It was shown that water solvent had the best extractive performance,

318

not only due to their capacity to extract higher quantity of proteins, but also it

319

circumvents the extraction of chlorophylls. Similarly, Martins et al. (2016) reported

320

that water extract significantly increased the amount of phycobiliproteins when

321

compared

322

conformational structure or chromophore structural integrity.

with

the

conventional

methodology,

without

compromising

their

323 324

The extraction solvent used also affects the allophycocyanin, phycocyanin and

325

phycoerythrin content. The selection of extraction solvent that can lyse the cell wall to

326

increase the seepage of phycobiliprotein pigment is important. In this study,

327

allophycocyanin, one of the pigments production of P. mucicola was significantly

328

higher in all treatments when water was used as the extraction solvent. Whereas, when

329

the cyanobacteria was extracted using phosphate buffer, the most abundant pigment

330

found under phycobiliprotein is the phycocyanin (blue), compared to phycoerythrin and

331

allophycocyanin which is similar to the study by Walter et al. (2011). Hemlata et al.

332

(2011) also reported better phycocyanin and total phycobiliprotein extraction when

333

using phosphate buffer, although with much lower value compared to this study. In

334

terms of total phycobiliprotein production, higher production was obtained in all

335

treatment when P. mucicola was extracted with water, compared to phosphate buffer.

336

This finding is crucial, especially if the extracted phycobiliprotein is intended for human

337

use as it is chemical free.

338 339

In general, the high allophycocyanin, phycocyanin and phycoeryhtrin content

340

and total phycobiliprotein found in P. mucicola (water extract) when cultured in

341

wastewater media might lead to the reduction in the overall cost, especially during mass

342

scale production for commercial purposes. The culture condition, especially nitrogen

343

and carbon sources in the form of culture media, also determines the production of

344

phycobiliprotein by cyanobacteria (Seker and Chandramohan, 2008). In general,

345

cyanobacteria requires nitrogen sources for growth. Cyanobacteria assimilates

346

ammonium ions (NH4+) from external source via an active transport system, while the

347

unprotonated form (NH3) was absorbed by diffusion and is trapped by protonation.

348

Nitrate is taken up by cells via an active transport system before it was reduced to nitrite

349

and then to ammonium (Lioteberg et al., 1996). Under nitrogen depletion, cyanobacteria

350

use phycobiliprotein as a nitrogen source, which can contribute to a decrease in

351

phycobiliprotein production by nblA gene expression (Erikson, 2008). Thus, nitrogen

352

availability plays a very important role in regulating phycobiliprotein and phycocyanin.

353

Eventhough wastewater contain lower amount of nitrogen (TAN and N-NO2), there

354

were no significant decrease in growth and phycobiliprotein content when compared to

355

P. mucicola cultured in BBM. Thus, the wastewater media is capable of providing

356

sufficient amount of nutrient for the cyanobacteria. Collier and Grossman (1994)

357

reported that, deprivation of phosphorus or sulphur can also led to partial or complete

358

decrease of phycobiliprotein by inducing the expression of nblA gene and

359

phycobiliprotein degradation, not only nitrogen.

360

Among the three main pigments of phycobiliprotein, phycocyanin is the most

361

valuable natural blue pigment used in food and pharmaceutical industry due to their

362

colour, fluorescence and antioxidant properties (Kumar et al., 2014). The purity ratio of

363

phycocyanin plays a significant role in commercial applications where it is often

364

evaluated by using absorbance readings. According to Patil et al. (2006), phycocyanin

365

with purity greater than 0.7 is considered as food grade, at ratio 3.9 is considered as

366

reactive grade and above 4.0 as analytical grade. In the present study, higher purity ratio

367

was found in water extract (0.84) of P. mucicola cultured under white light by using

368

wastewater media. The purity ratio was higher than the maximum purity ratio of

369

Spirulina reported by Prabuthas et al. (2011) at only 0.62 purity ratio.

370 371

3.3. Nutrient analysis of wastewater and culture media

372

Wastewater contained sufficient amount of ammonium (6.12±0.01), nitrite (3.80

373

± 0.03), nitrate (3.47 ± 0.02), phosphate (7.20 ± 0.03), calcium (5.40 ± 0.12), potassium

374

(5.45 ± 0.01), sodium (14.25 ± 0.01) and sulphate (5.05 ± 0.02) for culture of

375

microalgae. Physical parameters such as pH (8.25± 0.02), temperature (26.01 ± 0.01)

376

and dissolved oxygen (5.50 ± 0.02) were in the recommended range suitable for

377

cyanobacteria culture.

378 379

Cyanobacteria growth was dependent on a suitable supply of essential

380

macronutrients (nitrogen and phosphorus) but excess nutrients may have toxic effects

381

on the cell metabolism. Excessive nutrients content in commercial media may perhaps

382

affected the selected cyanobacteria growth in the present study. On the other hand,

383

nitrogen and phosphorous are the major nutrients required to grow microalgae. In this

384

study, aquaculture wastewater ensured sufficient amount of nitrogen and phosphorous

385

for proper growth of cyanobacteria. This would facilitate the removal of nutrients from

386

wastewater and production of microalgae biomass concurrently Abdulsada (2014).

387 388

Table 1 showed the nutrient analysis of wastewater before P. mucicola culture and

389

after P. mucicola was harvested. In the present study, both P. mucicola culture by using

390

BBM and wastewater showed a decrease in the nitrite, phosphorus and ammonia

391

content after the culture were harvested. When cultured using wastewater, the highest

392

TAN and N-NO2 uptake of P. mucicola was under white light treatment at 0.142 mg L-1

393

and 1.539 mg L-1, respectively. Initially, the TAN and N-NO2 content of wastewater

394

media was at 6.32 ± 0.01 mg L-1 and 6.50 ± 0.01 mg L-1, respectively. Meanwhile, when

395

P. mucicola was cultured using BBM media, the highest TAN uptake was observed

396

under natural light and N-NO2 uptake was higher under white light at 0.205 mg L-1 and

397

5.424 mg/L, respectively. The initial TAN and N-NO2 of BBM was at 0.483 mg L-1 and

398

12.990 mg L-1. No significant difference (P > 0.05) was found in the P-PO4 content

399

before and after culture of P. mucicola under all treatments.

400 401

Cyanobacteria have developed highly and efficient uptake and retention

402

mechanisms for three nutrient anions: bicarbonate, nitrite, and phosphate (Badger and

403

Price, 2003). P. mucicola culture under white light treatment and natural light treatment

404

utilized most nitrite in both waste water and BBM treatments. However, in blue light

405

treatment, the high nitrite and phosphorus level after harvest in both waste water and

406

BBM may be caused by the slow growth and nutrient uptake by the P. mucicola cells.

407

According to Hu et al. (2000), the nitrate uptake rate increased proportionally with

408

increasing light intensity or parallels to photosynthetic activity. In this study, blue light

409

have lower light intensity compared to white and natural light. Thus, the culture of P.

410

mucicola by using wastewater under white light treatment may serve as an effective

411

way to treat and reuse wastewater.

412 413

Conclusions

414

The growth, biomass yield and phycobiliprotein production as well as purity of

415

P. mucicola varied when cultured under different light sources and media. High growth,

416

chlorophyll a concentration, biomass and phycobiliprotein production were found when

417

P. mucicola was cultivated using wastewater under white light source. Moreover, it was

418

found that extraction of phycobiliprotein by using water, which is chemical free,

419

produced higher phycobiliprotein concentration compared to phosphate buffer. Further

420

studies are warranted for the confirmation and validation of other environmental factors

421

suitable for the production of phycobiliproteins in cyanobacteria.

422 423

Acknowledgement

424 425

This study was supported by the Ministry of Higher Education, Malaysia, through

426

Fundamental

Research

Grant

427

FRGS/1/2015/WAB01/UMT/03/6.

Scheme

(FRGS)

project

No.

428 429

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569

Figure captions

570 571 572 573 574 575 576 577 578 579 580 581 582 583 584 585 586 587 588 589 590 591 592 593 594 595 596 597 598 599 600 601 602

Figure 1. Optical density (abs) versus culture period (day) for P. mucicola cultured under different media (wastewater (WW) and BBM) and light sources (white light (WL), blue light (BL), natural light (NL)). Values are mean ± standard error. Figure 2. Phycobiliprotein pigment production (mg mL-1) of P. mucicola cultured under different media, light sources and extraction solvents.. Values are mean ± standard error. Figure 3. Total phycobiliprotein production (mg mL-1) of P. mucicola cultured under different media, light sources and extraction solvents. Values are mean ± standard error. Figure 4. Purity of phycocyanin from cyanobacteria cultured under different media, light sources and extraction solvents. Values are mean ± standard error.

Optical density (abs)

0.8

BBM WL

0.7

BBM BL

0.6

BBM NL WW WL

0.5

WW BL 0.4

WW NL

0.3 0.2 0.1 0 0

603 604 605

Fig. 1.

1

2

3 4 Culture period (Day)

5

6

7

606 607 0.600

Pigment production (mg mL-1)

BBM WL 0.500

BBM BL BBM NL

0.400

WW WL WW BL

0.300

WW NL 0.200 0.100 0.000 Phosphate buffer

Phycocyanin (PC)

608 609 610 611 612 613 614 615 616 617 618 619 620

Distilled water

Fig. 2.

Phosphate buffer

Distilled water

Allophycocyanin (APC)

Phosphate buffer

Distilled water

Phycoerythrin (PE)

621 622 623 624 625

Total phycobiliprotein (mg G-1)

626 Phosphate buffer

300 250 200 150

100 50 0

WL

BL BBM

627 628 629 630 631 632 633 634 635 636 637 638

Fig. 3.

Water

NL

WL

BL WW

NL

639 640 641 642 643 644 645 646 647 648 1.4

Phosphate buffer

Water

1.2

Purity

1.0 0.8 0.6 0.4 0.2 0.0 WL

BBM

649 650 651 652

BL

Fig. 4.

NL

WL

BL WW

NL

653

Table captions

654

Table 1

655

Nutrient analysis of wastewater before P. mucicola culture and after P. mucicola

656

was harvested. Values are means ± standard errors (n=3).

Culture

Nitrite nitrogen

Phosphate

nitrogen (TAN)

(NO2-N)

phosphorous (P-PO4)

(mg L-1)

(mg L-1)

(mg L-1)

Light

Sample media

Total ammonium

source

Before

Wastewater

-

6.32 ± 0.01

6.50 ± 0.01

5.53 ± 0.06

culture

BMM

-

0.48 ± 0.02

13.09 ± 0.01

11.06 ± 0.03

WL

0.04 ± 0.01

1.53 ± 0.04

4.00 ± 0.01

BL

0.06 ± 0.03

3.25 ± 0.01

4.40 ± 0.01

NL

0.07 ± 0.01

1.32 ± 0.03

5.00 ± 0.08

WL

0.44 ± 0.01

5.42 ± 0.01

10.50 ± 0.01

BL

0.38 ± 0.00

11.64 ± 0.02

10.01 ± 0.02

NL

0.20 ± 0.03

8.10 ± 0.01

9. 80 ± 0.05

Wastewater After harvest

BBM

657 658 659

660 661

662 663

Optical density of cyanobacteria under different light sources and media

Chlorophyll a of cyanobacteria under different light sources and media

Biomass of cyanobacteria under different light sources and media

664 665

Biomass of cyanobacteria was harvest at stationary phase & freeze dried

666 667 668 669

Dried biomass of cyanobacteria was extracted with water and phosphate buffer for phycobiliprotein production

670 671

672 Phycobiliprotein pigment production of cyanobacteria cultured under different media, light sources and extraction solvents

Total phycobiliprotein production of cyanobacteria cultured under different media, light sources and extraction solvents

Purity of phycocyanin from cyanobacteria cultured under different media, light sources and extraction solvents solvents

673

Research highlights

674 675 676 677 678 679 680 681 682 683 684 685 686 687 688

     

Effect of different light sources and media on the growth of cyanobacteria was determind Effect of different light sources and media on the phycobiliprotein production of cyanobacteria Pseudanabaena mucicola grown in wastewater under white light had significantly higher biomass Cyanobacteria biomass extracted with water had higher production and purity of phycocyanin. Phycobiliprotein extracted using water from P. mucicola can be food grade natural blue pigment. Cyanobacteria grown in wastewater could cut down the production cost of phycobiliprotein.