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Antimicrobial resistance in freshwater Plesiomonas shigelloides isolates: Implications for environmental pollution and risk assessment
Journal Pre-proof Antimicrobial resistance in freshwater Plesiomonas shigelloides isolates: Implications for environmental pollution and risk assessment Temitope Cyrus Ekundayo, Anthony I. Okoh PII:
S0269-7491(19)32028-7
DOI:
https://doi.org/10.1016/j.envpol.2019.113493
Reference:
ENPO 113493
To appear in:
Environmental Pollution
Received Date: 17 April 2019 Revised Date:
23 August 2019
Accepted Date: 24 October 2019
Please cite this article as: Ekundayo, T.C., Okoh, A.I., Antimicrobial resistance in freshwater Plesiomonas shigelloides isolates: Implications for environmental pollution and risk assessment, Environmental Pollution (2019), doi: https://doi.org/10.1016/j.envpol.2019.113493. 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
Antimicrobial resistance in freshwater Plesiomonas shigelloides isolates: implications
2
for environmental pollution and risk assessment
3 Temitope Cyrus Ekundayo1,2,3* and Anthony I. Okoh1,2
4 5 1
6
SAMRC Microbial Water Quality Monitoring Centre, University of Fort Hare, Alice,
7 8
Eastern Cape, South Africa 2
Applied and Environmental Microbiology Research Group, Department of Biochemistry and
9 10
Microbiology, University of Fort Hare, Alice, Eastern Cape, South Africa 3
Department of Biological Sciences, University of Medical Sciences, Ondo City, Ondo State,
11
Nigeria
12 13
*Corresponding author (T.C. Ekundayo). Email: [email protected]
14 15
Abstract
16
Antibiotic resistance is known to impact treatment efficiency of Plesiomonas infections
17
negatively with fatal outcomes. This study investigated antibiogram fingerprint of P.
18
shigelloides (n = 182) isolated from three South Africa rivers using the disc diffusion
19
technique. Environmental pollution and analogous health risk (given infections) that could
20
associate with the freshwaters and empirical treatment of Plesiomonas were assessed using
21
Antibiotic Resistance Index (ARI) and Multiple Antibiotic Resistance Indices (MARI),
22
respectively. Thirteen EUCAST recommended (ERAs) and eleven non-recommended
23
antibiotics (NAs) used as first line agents in the treatment of gastroenteritis and
24
extraintestinal infections were tested. Resistance against ERAs decreased from cefoxitin
25
(37.91%), cefuroxime (35.17%), cefepime (31.87%), ceftriaxone (29.67%), ciprofloxacin
26
(18.13%),
27
ertapenem (4.95%), norfloxacin (4.40%), levofloxacin (2.75%), meropenem (1.10%) to
trimethoprim-sulfamethoxazole
(10.44%),
piperacillin/tazobactam
(8.79%),
28
imipenem (0.55%). The isolates had higher resistance (≥36.07%) against NAs but were
29
susceptible to amikacin (67.58%), gentamycin (73.08%), and tetracycline (80.77%). MARI of
30
the isolates were significantly different between ERAs and NAs (P-value < 0.05) and had an
31
average of 0.17±0.18 and 0.45±0.13, respectively. About 33.87% and 95.63% of the isolates
32
had MARI value from 0.23 − 0.62 and 0.27 − 0.82 to ERAs and NAs, respectively. Also,
33
ERAs-based and NAs-based ARI across sampling units showed significantly different (P-
34
value < 0.05) means of 0.18±0.09 and 0.46±0.05, respectively. MARI attributed low risk of
35
empirical treatment to recommended antibiotics but higher risk to non-recommended
36
antibiotics. Model estimated successful and unsuccessful empirical treatment of infections
37
risks due to resistance in the isolates using recommended antibiotics as 65.93% and 34.07%,
38
respectively; 1.65% and 98.35% in the case of non-recommended antibiotics, respectively.
39
ARI based on recommended antibiotics identified potential environmental pollutions in a
40
number of sites. Resistance in freshwater P. shigelloides especially against cephalosporin,
41
quinolones and fluoroquinolones is distressing and might suggests high pollution of the
42
freshwaters in the Eastern Cape Province.
43
Keywords: Plesiomonas shigelloides; antimicrobials resistance index; risk assessment;
44
public health.
45
Capsule: the study revealed multi-resistance of P. shigelloides against last resort antibiotics;
46
identified pollution risk in 8 sites and greater risk of fatal outcomes of empirical treatment of
47
infection by non-recommended antibiotics.
48
1. Introduction
49
Antimicrobial resistance is one of the major clinical and veterinary challenges worldwide.
50
More disturbing is the resistance of freshwater microorganisms against important antibiotics
51
contrary to their antibiotics sensitive nature. The aquatic environments are now regarded as
52
repositories of antibiotic-resistant bacteria and their resistance genes (Korzeniewska et al.,
53
2013; Li et al., 2014; Leonard et al., 2015; Xu et al., 2015; Calero-Cáceres and Muniesa,
54
2016). Basically, the aquatic environments are open to anthropogenic pollutions (Zhu et al.
55
2017; Shao et al. 2018; Antti et al. 2018; Jiang et al. 2018) from a wide range of influences
56
including storm water/agricultural wastes or surface run-offs (Ahmed et al. 2018); wastewater
57
treatment plant (Rizzo et al. 2014; Hembach et al. 2017; Proia et al. 2018a; Proia et al.
58
2018b); hospital effluents (Harnisz and Korzeniewska 2018); industrial wastes (Karkman et
59
al. 2017);agricultural runoffs from slaughterhouses (Wan and Chou 2015; Fang et al. 2018);
60
effluents from landfills, floodwaters, and recreational functions. Many of these are heavily
61
laden with antibiotics residues, pesticides, herbicides, biocides, pharmaceuticals, textile dye
62
/organic compounds, heavy xenogenetic elements, disinfectants, antibiotic resistant bacteria
63
and antibiotic resistant genes (Jiao et al., 2017; Karkman et al., 2017; Fang et al., 2018; Guo
64
et al., 2018; Harnisz and Korzeniewska, 2018; Jiang et al., 2018; Li et al., 2018; Shao et al.,
65
2018; Zhang et al., 2018).
66
Plesiomonas shigelloides, the only oxidase-positive member of the Enterobacteriaceae, is
67
one of the freshwater- and aquatic resources-borne microorganisms (Wadström and Ljungh,
68
1991; Brenner et al., 2005). It is a Gram-negative rod, motile and non-spore-forming bacteria
69
recognized as a water- and food-borne pathogen and recently grouped into the order
70
Enterobacterales (Brenner et al., 2005; Meng et al., 2012; Santos et al., 2015). P. shigelloides
71
has been isolated from mollusks, crustaceans, reptiles and fishes as well as birds, amphibians,
72
and mammals (Oxley et al., 2002; Huber et al., 2004; Salerno et al., 2007; Alexander et al.,
73
2016; Pan et al., 2017). Mostly, regional distribution of the bacteria is often attributed to the
74
tropics and the subtropics including Southeast Asia, Africa and South America in particular
75
(Arai et al., 1980; Obi et al., 1995; Canosa and Pinilla, 1999; Shigematsu et al., 2000; Gibotti
76
et al., 2000; Tseng et al., 2002; Wong et al., 2000; Maluping et al., 2005;Chen et al., 2013;
77
Nwokocha and and Onyemelukwe, 2014). Notwithstanding, P. shigelloides has been isolated
78
in the cold and temperate regions of Sweden ( Krovacek et al., 2000; Gonzalez-Rey et al.,
79
2003), Netherlands, Serbia, Hungary and Czech Republic ( Medema and Schets, 1993;
80
Aldová et al., 1999; Bardon, 1999; Petrušić et al., 2018).
81
P. shigelloides is very important in human and veterinary medicines as several cases of
82
gastrointestinal and extraintestinal infections have been linked to the pathogen (Ampofo et
83
al., 2001; Auxiliadora-Martins et al., 2010b; Ozdemir et al., 2010; Bonatti et al., 2012; Xia et
84
al., 2015; Bowman et al., 2016). Gastrointestinal infections from P. shigelloides are
85
sometimes self-limiting (Holmberg and Farmer, 1984; Holmberg et al., 1986) but duration of
86
illness and treatment of (extraintestinal) infections often take up to 3 ─ 56 days (Ampofo et
87
al., 2001; Auxiliadora-Martins et al., 2010b; Bonatti et al., 2012; Bowman et al., 2016; Xia et
88
al., 2015). Many deaths have also resulted from Plesiomonas extraintestinal infections,
89
especially among children ( Nolte et al., 1988; Billiet et al., 1989; Terpeluk et al., 1992; Chen
90
et al., 2016; Xia et al., 2015). The clinical importance of P. shigelloides continues to grow in
91
recent times (Bonatti et al., 2012; Pfeiffer et al., 2012; Bowman et al., 2016; Ding et al.,
92
2015; Novoa-Farías et al., 2016; Patel et al., 2016; Pence, 2016; Hustedt and Ahmed, 2017a,
93
2017b). Other public health issues traced to P. shigelloides include food- and water-borne
94
outbreaks (Graciaa et al., 2018; Houten et al., 1998; Wouafo et al., 2006), and disease
95
outbreak in farmed Percocypris pingi in China (Pan et al., 2017).
96
Antibiotic therapy remains one of the primary instruments in infection control and
97
management. However, antibiotic resistance is known to impact treatment efficiency of
98
Plesiomonas infections negatively. Treatment failures and several deaths from Plesiomonas
99
infections have been attributable to resistance and wrong prescription of antibiotics (Pathak et
100
al., 1983; Terpeluk et al., 1992). Studies have revealed survival in neonatal extraintestinal
101
infections caused by P. shigelloides involved treatment with at least one or combination of
102
antibiotics from cephalosporins, carbapenems, aminoglycosides and quinolones (Eason and
103
Peacock, 1996; Riley et al., 1996; Ozdemir et al., 2010). More worrisome, P. shigelloides is
104
not among first-line pathogens routinely assayed in clinical laboratory and in part, share
105
some clinical manifestations with other pathogens, which often lead to its misdiagnosis (Chen
106
et al., 2013) and consequently increasing health risk due to Plesiomonas infections.
107
In this study, antibiogram fingerprint of P. shigelloides isolates from rivers in the Eastern
108
Cape Province, South Africa was investigated. The study modelled environmental pollution
109
risk (EPR) and empirical treatment risk (ETR) of Plesiomonas (given infections) with
110
recommended and non-recommended antibiotics in terms of Antibiotic Resistance Indices
111
(ARI) and Multiple Antibiotic Resistance Indices (MARI), respectively.
112
To the best of our knowledge, this is the first report on freshwater P. shigelloides isolates
113
from the Eastern Cape Province in South Africa, which provides a local context to the
114
antibiogram of the bacteria and indicator for assessment of EPR and ETR.
115
2.
Materials and methods
116
2.1
Study area and sampling sites
117
The study area is located within Amathole District Municipality in the Eastern Cape Province
118
(ECP) of South Africa. The district is the third populous among the six districts of the ECP. It
119
shares boundaries with the Chris Hani, Cacadu, and OR Tambo municipalities. Figure 1 show
120
the location map, some key features, and 15 sites selected on three rivers namely: Kubusie
121
river, tyhume and Kat river. The sites were selected after reconnaissance visits based on
122
presence, proximity and intensity of one or more of the following eco-socioeconomic
123
activities on the rivers’ courses such as irrigation, pastoral activities (livestock watering,
124
poultry, swine, etc.), wastewater treatment plants, recreational activities (waterfall),
125
proximity to farmland and farming activities, dam activity, domestic and household uses,
126
spiritual cleansing, water abstractions, and impoundments.
127
2.2
128
P. shigelloides were isolated from serially diluted water samples collected from the sites
129
following standard membrane filtration technique (APHA, 2005) using Inositol Brilliant
130
Green Bile Agar (details in Appendix A). The genomic DNA of the resultant presumptive P.
131
shigelloides obtained from the samples were subsequently extracted following overnight
132
cultivation on nutrient agar using the boiling method (Salerno et al., 2010) (Appendix A).
133
2.3
134
Polymerase chain reaction (PCR) for confirmation of the isolates was performed as
135
previously
136
GCAGGTTGAAGGTTGGGTAA-3′
137
which amplifies a region of the 23S rRNA gene. Four microliters of the amplification product
138
were electrophoresed in 1.5% agarose gel (Appendix A).
139
2.4
140
The antimicrobial susceptibility profiles
141
assessed using the disc diffusion method and the European Committee on Antimicrobial
142
Susceptibility Testing Guidelines (EUCAST, 2018a). A panel of 24 antibiotics including 13
143
recommended and 11 first-line antibiotic agents for the treatment of gastroenteritis and
144
extraintestinal infection were tested (details in Appendix A). All isolates were grouped as
145
Resistant (R), Intermediate (I) and Susceptible (S) to specific antibiotic based on the
146
interpretative table (CLSI, 2018; EUCAST, 2018a, 2018b).
Plesiomonas isolation and DNA extraction
Molecular confirmation of P. shigelloides
described
(Gu
and
Levin, and
2006)
using
the
primer
pair,
PS-F-5′-
PS-R-5′-TTGAACAGGAACCCTTGGTC-3′,
Antimicrobial susceptibility profiling of P. shigelloides isolates of the confirmed P. shigelloides isolates were
147
2.5
Determination of resistance quotients (RQs) of P. shigelloides isolates
148
RQs determined changes in antimicrobial resistance phenotypes of the isolates across a
149
range of antibiotics for all the sites. The RQs of the antibiotics were computed using the
150
equation (Amos et al., 2018):
151
2.6
152
assessment
153
P. shigelloides isolates from each sampling site was ‘phenotyped’ for multiple antibiotic
154
resistance ((M)ARPs) based on the 2 groups described in section 2.4. Isolates that showed
155
resistance against 3 or more antibiotics were recorded (Kinge et al., 2010). Each sampling
156
site was indexed for isolate-specific MARI (Blasco et al., 2008). The ARI was calculated for
157
each sampling site (Krumperman, 1983; Mohanta and Goel, 2014) (Appendix A).
158
The study modelled ETR and EPR based on comparative MARI and ARI values between
159
recommended and non-recommended antibiotics, respectively. The risk assessment was
160
construed on the following assumptions:
161
1. MARI (risk) based on recommended antibiotics (RAs) for treatment is always lower
162
(MARIRAs ≤ 0.2, when RAs are used) compared to non-recommended antibiotics (non-RAs,
163
MARInon-RAs ˃ 0.2). The 0.2 MARI or ARI value was an arbitrary threshold to differentiate
164
between low- and high-risk (Krumperman, 1983).
165
2. ETR = 0, when isolates are susceptible to RAs used in treatment; ETR ˃ 0, when isolates
166
are resistant against RAs. Generally, the ETR of Plesiomonas infection is defined as
167
MARIemp = MARIRAs + MARInon-RAs (where either MARIRAs or MARInon-RAs = 0, depending
168
on the group selected in an empirical treatment).
Phenotyping and indexing of isolates for multiple antibiotic resistance and risk
169
3. ARI of each site ≤ 0.2 when RAs are screened provided there is no antibiotic selection
170
pressures or pollution (ARIRAs ≤ 0.2); while ARInon-RAs ˃ 0.2 (when non-RAs are screened)
171
regardless of the presence or absence of antibiotic resistance selection pressure or pollution
172
Therefore, the EPR from a given site based on antibiotic resistance profile is defined as
173
ARIenv = ARIRAs + ARInon-RAs (where either ARIRAs or ARInon-RAs = 0, depending of group
174
selected in screening).
175
2.7
176
Hierarchical cluster analysis of antibiotic susceptibility test result was carried out by K-mean
177
and visualized using “ComplexHeatmap” r package (Gu et al., 2016) in R version 3.5.1
178
(2018-07-02). Descriptive analysis and one-way analysis of variance (ANOVA) were also
179
employed to compare different antibiotics response and sites. The difference between ARI
180
and MARI of the 2 groups of antibiotics were compared with the use of Wilcoxon signed-
181
rank test using ggpubr: 'ggplot2' R package version 0.1.8.999 (Kassambara, 2018). The
182
antibiotic resistance quotients (RQs) across the 15 sampling sites were calculated in Excel
183
version 2016. The difference among sites or antibiotics was defined as significant when P
184
values ≤ 0.05.
185
3. Results
186
Appendix B provides additional information on subsection of section 3.
187
3.1
188
A total of 182 confirmed P. shigelloides isolates were selected for antibiotic susceptibility
189
testing as follows: 35 from Kubusie river (KB1=7, KB2=3, KB3=4, KB4=14, KB5=7); 94
190
from Kat river (KT1=9, KT2=25, KT3=18, KT4=11, KT5=31); and 53 from Tyhume river
Data analysis
Confirmation of P. shigelloides
191
(TY1=8, TY2=3, TY3=9, TY4=16, TY5=17). All the 182 isolates yielded the expected
192
amplicon size (628-bp) characteristic of Plesiomonas (Figure 2).
193
3.2
194
Figure 3 presents heatmap cluster analysis of the isolates’ antibiogram fingerprints against
195
recommended antibiotics with respect to sample sites. Full graphic for both recommended
196
and non-recommended antibiotics can be found in Figure S1. The isolates generally have two
197
main clusters of antibiogram profile column-wise (Figure 3) in all the rivers, namely, a
198
cluster depicting antibiotic susceptibility pattern while the other cluster indicates antibiotic
199
resistance pattern of the isolates. For the isolates that originated from Tyhume river, 6
200
clusters characteristics of hetero-site isolates were noticed row-wise (Figure 3(A)). Figure
201
3B presents antibiogram profile clusters of isolates from Kat river. Five antibiogram clusters
202
that grouped isolates of diverse origin were obtained. For isolates from Kubusie river, 5
203
antibiogram clusters of hetero-site isolates were observed row-wise (Figure 3.C).
204
3.3
205
The occurrence of resistant isolates across sampling locations is summarised in Table S1.
206
Resistance occurence against recommended antibiotics was significantly different across
207
sampling sites (inter-sampling sites) on the rivers’ courses (Kubusie river: ANOVA, F =
208
8.675, P-value = 3.44 × 10−8; Kat river: ANOVA, F = 7.41, P-value = 3.15 × 10−7; and
209
Tyhume river: ANOVA, F = 4.336, P-value = 0.0002). Intra-site occurrence of resistant
210
isolates against different antibiotics was significantly different at Tyhume (ANOVA, F =
211
3.945, P-value = 0.01), and KAT (ANOVA, F = 3.763, P-value = 0.01) rivers’ courses, but
212
insignificantly different on Kubusie river (ANOVA, F = 1.654, P-value = 0.17). Generally,
213
high occurrence of resistance against most of the antibiotics tested compared to other sites
Antibiogram profiles and cluster analysis of isolates
Occurrence of resistant isolates per location
214
was found at KT2. Total occurrence of resistant isolates against recommended antibiotic
215
ranged from 9 (TY2/TY3) to 84 (KT2).
216
Occurrence of resistance against non-recommended antibiotics by the isolates was
217
significantly different across sites on the rivers (Tyhume river: ANOVA, F = 7.084, P-value
218
= 4.74 × 10−6; Kubusie river: ANOVA, F = 7.357, P-value = 3.11 × 10−6; and Kat river:
219
ANOVA, F = 5.639, P-value = 5.10 × 10−5). Notably, low frequency of resistance against
220
gentamycin and amikacin (0≥ n≤ 2) was observed in the isolates across locations. The
221
subtotal of resistant isolates against non-RAs across sites ranged from 16 (TY2) to 133
222
(KT5). Intra-site comparison of occurrence of resistant isolates against non-recommended
223
antibiotics showed a significantly different results in all the rivers (Tyhume river: ANOVA, F
224
= 2.670, P-value = 0.04; Kubusie river: ANOVA, F = 2.528, P-value = 0.05; and Kat river:
225
ANOVA, F = 3.451, P-value = 0.02).
226
3.4
227
The antibiotic resistance quotients (RQs) of the isolates across the 15 sampling locations is
228
shown in Table S2. All the Plesiomonas isolates had low RQS against imipenem, meropenem
229
and norfloxacin antimicrobials in all the sites with the exception of sites KT2 and KT5 for
230
imipenem and norfloxacin, respectively. Levofloxacin had 0% RQs at all sites on Kubusie
231
river, at KT4 and KT5 on Kat river, and at TY2, TY3 and TY4 on Tyhume river. The RQs of
232
the isolates against ceftriaxone, ceftazidime, trimethoprim-sulfamethoxazole, cefuroxime and
233
cefoxitin were usually high on Kubusie river at KB2, KB3, and on Kat river at KT2, and
234
KT3.
235
3.5
236
shigelloides isolates
Antibiotic resistance quotients (RQs) of Plesiomonas isolates
Descriptive
analysis
of
antibiogram
fingerprints
profiles
of
P.
237
Table 1 presents the overall descriptive analysis of antibiotic susceptibility profile of the P.
238
shigelloides isolates from the three rivers. For recommended antibiotics, percentage
239
susceptibility of the isolates ranged from 42.31% (cefuroxime) to 95.06% (imipenem). The
240
resistance of the isolates against recommended antibiotics decreased in order from cefoxitin
241
(69, 37.91%), cefuroxime (64, 35.17%), ceftazidime (62, 34.07%), cefepime (58, 31.87%),
242
ceftriaxone (54, 29.67%), ciprofloxacin (33, 18.13%), trimethoprim-sulfamethoxazole (19,
243
10.44%), piperacillin/tazobactam (16, 8.79%), ertapenem (9, 4.95%), norfloxacin (8, 4.40%),
244
levofloxacin (5, 2.75%), meropenem (2, 1.10%) and imipenem (1, 0.55%).
245
Record of isolates’ extreme resistance to some non-recommended antibiotics include
246
vancomycin (163, 89.56%), erythromycin (163, 89.56%) and sulfamethoxazole (172,
247
94.51%); and intermediate resistance to cefazolin (52, 28.57%) and amikacin (53, 29.12%).
248
About 67.58% to 80.77% of the isolates were susceptible to amikacin, gentamycin,
249
polymyxin and tetracycline.
250
3.6
251
shigelloides isolates
252
3.6.1 ETR from comparative MARI of P. shigelloides isolates
253
The comparison of MARPs and MARI of Plesiomonas isolates against recommended and
254
non-recommended antibiotics for assessment of ETR is given in Table S3. The MARI of the
255
isolates were significantly different between recommended and non-recommended antibiotics
256
(Wilcoxon, P = 12 × 10−14). While the average of the isolates MARI based on antibiotics of
257
choice was 0.168±0.181 (median/mode = 0/0.08), the mean MARI according to non-
258
recommended was 0.446±0.133 (Median/Mode = 0.45/0.45). A quick summary of Table S3
259
showed that 120 (65.93%) and 62 (34.07%) isolates had MARI of 0 − 0.15 and 0.23 − 0.62,
260
respectively for the recommended antibiotics. The MARI range of 0.09-0.18 and 0.27 − 0.82
Assessment of ETR and EPR established on MARIs and ARIs of P.
261
were noted for 3 (1.65%) and 175 (96.2%) isolates against non-recommended antibiotics.
262
Most importantly, while some isolates had zero MARI considering recommended antibiotics,
263
they had MARI ˃0.20 in case of non-recommended.
264
Summarily, the successful ETR (MARI < 0.2) and unsuccessful ETR (MARI ≥ 0.2) of P.
265
shigelloides infections due to the isolates considering recommended antibiotics collectively
266
was 65.93% and 34.07%, respectively. Similarly, the successful ETR and unsuccessful ETR
267
of infections due to the isolates on the ground of using non-recommended antibiotics was
268
1.65% and 98.35%, respectively. However, risk varied with individual isolate or antibiotics.
269
3.6.2 EPR from comparative ARI across sampling units.
270
Figure 4 shows the antibiotic resistance indices across sampling units. A single factor
271
comparison
272
antibiotics-based (nonRAs-based) ARI across the sites was significantly different (ANOVA,
273
F = 112.36, P-value = 1.18 × 10−11). The average RAs-based and nonRAs-based ARI across
274
sampling units were 0.184±0.091 and 0.459±0.050, respectively. Generally, recommended-
275
antibiotics-based ARI < 0.13 was found at KB4, KB5, KT4, KT5, TY4, TY5 and TY6; and ≥
276
0.2 at other locations. Non-RAs-based ARI had high values and ranged from 0.38 − 0.55
277
across the locations.
278
3.7
279
(M)ARPs of P. shigelloides isolates across various sampling units of the rivers against
280
recommended antibiotics (RAs) is shown in Table 2. The combinatorial expressions below
281
predicted different theoretical (M)ARPs possible for the 13 recommended and 11 non-
282
recommended antibiotics (nonRAs) as 8192 and 2048, respectively:
283
n
Cr =
of
recommended-antibiotics-based
(RAs-based) and
non-recommended-
Multi-resistance patterns ((M)ARPs) of P. shigelloides isolates
for RAs (n = 13, r = 0, 1 … 13) and;
284
n
285
However, only 61 and 68 (M)ARPs against RAs and nonRAs (data not shown) were
286
observed. Of the 182 isolates, 63 (34.62%) were sensitive to RAs, while 36 (19.8%) showed
287
resistance to 1 antibiotic. Also, 6.04% (n = 11) to 28.6% (n = 52) of the isolates had 3 to ≥5
288
(M)ARPs. For distribution of the observed 61 (M)ARPs across sampling locations, cefoxitin
289
had highest resistance proportion (9.29%). Four (2.19%) isolates were resistant to ceftazidime
290
and ciprofloxacin each. Occasional (M)ARP (resistant found only in one isolate) was seen in
291
16.48% (n = 30) of the isolates. The most frequent (M)ARPs was cefuroxime/cefoxitin
292
observed
293
ceftriaxone/ceftazidime/cefepime/cefuroxime/cefoxitin
294
ceftriaxone/ceftazidime/ciprofloxacin/cefepime/cefuroxime/cefoxitin (5, 2.74% isolates), and
295
ceftriaxone/ceftazidime/trimethoprim-sulfamethoxazole/
296
piperacillin/tazobactam/cefepime/cefuroxime/cefoxitin (5, 2.74% isolates).
297
Different (M)ARPs were observed among the Plesiomonas isolates from 15 locations.
298
Isolates from the sites exhibited ≥ 3 (M)ARPs. Notably, the study observed a high number of
299
(M)ARPs at sites KT5 (17), followed by KT3(13), KT2(12), and TY5/6(10). The number of
300
(M)ARPs at KB5, TY2, TY3, KB3, TY4, KB1, KB2, KB4, KT4, TY1, and KT1(8) ranged
301
from 3 – 8.
302
3.0
Discussion
303
3.1.
Antimicrobial resistance and sample sites relationship
304
Antibiotic therapy remains a major practice in infection control and treatment. Here, we
305
performed antibiogram fingerprint of P. shigelloides isolates against 24 panels of antibiotics.
306
The detection and confirmation of P. shigelloides from the sampling sites can be attributed to
307
possible anthropogenic pollution along the riverbanks. All the sites serve as animal watering
Cr =
for nonRAs (n = 11, r = 0, 1 … 11).
in
10
isolates
(5.47%), (8,
followed 4.4%
by isolates),
308
point in addition to other purposes except TY1, which is chiefly hotspot for
309
swimming/recreational activities. The rivers receive wastewater effluents (WWE) upstream at
310
KT1 and KB5. All these activities could contribute substances that is capable of directly or
311
indirectly induce resistance in microorganisms. For instance, WWE are usually laden with
312
xenogenetic/xenobiotic compound that are capable of inducing resistance in the pathogen.
313
Cluster analysis of the isolates’ antibiogram fingerprints showed diversity in terms of intra-
314
sampling and inter-sampling location, which suggests that (M)ARPs are not site specific. It is
315
not impossible that the clustered isolates have the same origin. Livestock can shed clones of
316
resistant bacteria when they visit sites that are very close to one another such as KB2 and
317
KB3. Heatmap/hierarchical cluster techniques have been used to infer antimicrobial
318
susceptibility profile similarity and antibiotic disturbance on aquatic microbial composition in
319
recent times (McCusker et al., 2019).
320
Despite the antibiogram profile similarity, occurrence of resistant isolates varied significantly
321
with sampling sites. This variation suggests different intensities of anthropogenic pollutions
322
at the sites. The differences in resistance pattern to different classes of antibiotics from the
323
sites could also be attributed to presence of different type of pollutants in the sites. For
324
instance, occurrence of resistant isolates was obvious at sites in wastewater treatment plant
325
(KT1) because wastewater is commonly laden with vast arrays of antibiotic wastes and heavy
326
metals; human settlements (KB3, KB4, KT2, TY3, TY4, TY5/6) which could connote the
327
presence of different antibiotic-resistance-inducing substances in domestic wastes such as
328
disinfectants from various settlements; game farm (KB1) and livestock farm (swine, poultry,
329
sheep and goats e.g. KB1, KB2 and KB5) and different farm inputs in orchids proximities on
330
the rivers’ routes. Extended-spectrum beta-lactamase producing E. coli and fluoroquinolone-
331
resistant isolates have been reported in free-living deer and wild boars in Vojvodina Province,
332
Serbia (Velhner et al. 2018). Wastewater treatment plant effluents (WTPEs) might be
333
responsible for burden of P. shigelloides resistance at KT1. WTPEs are known to contribute
334
ARGs and antimicrobial resistant bacteria to receiving waterbodies ( Hembach et al., 2017;
335
Antti et al., 2018; Sabri et al., 2018). A high relative abundance of antimicrobial resistance
336
genes (ARGs) are common in agriculture impacted watersheds (Zhu et al. 2018). Various
337
farm and livestock management practices in the rivers’ neighbourhoods serve as point and
338
diffused sources of pesticides, herbicides, disinfectants, residual antibiotics and antibiotic
339
metabolic by-products, quaternary ammonium compounds, heavy metals and biocides, which
340
could have promoted P. shigelloides resistance in the receiving river. These substances are
341
known to select microorganisms for ARGs and/or promote horizontal gene transfer among
342
microbial communities.
343
susceptibility of S. enterica and E. coli to multiple antibiotics due to commercial herbicides
344
such as dicamba, glyphosate, 2,4-D and their co-formulants. Also, sub-inhibitory
345
concentration of biocides (triclosan and chlorhexidine), and antibiotics (sulfamethoxazole and
346
gentamicin) have been reported to significantly increased occurrences of ARGs dissemination
347
(Jutkina et al. 2018). Zhao et al. (2017) found that heavy metals (Cr; Cu, Hg, Pb, Zn) and
348
nutrients from mariculture significantly co-driven propagation of macrolide-lincosamide-
349
streptogramin B, fluoroquinolone, aminoglycoside, beta-lactam and tetracycline resistance
350
genes in adjacent environment.
351
Aside from high possibility of diffused and run-off dissemination of the afore-mentioned
352
substances and resistant bacteria selected by their pressures from these farms, direct faecal
353
shedding of resistant P. shigelloides isolates by free ranging animals or livestock could also
354
add to the observed resistance burden in P. shigelloides isolates. Litters of animal faeces were
355
seen at the locations during sampling. Furthermore, human excreta and babies pampers
356
among many other human generated wastes were noticed at KB4. This is indicative that some
357
of the resistant P. shigelloides isolates might originated from human faeces. This is similar to
Kurenbach et al. (2017) found changes in the antibiotic
358
observation of Adesiyan et al. (2019) who found high resistant of P. shigelloides isolates
359
against important antibiotics in rivers impacted with human excreta and washing activities in
360
South-western Nigeria. The probable use of animal manure and poultry dugs in farms along
361
the riverbanks may serve as another source of resistant P. shigelloides isolates or could
362
promote transfer of resistance gene to P. shigelloides in the adjoining riverbanks. Jia et al.
363
(2017) and Fang et al. (2018) found high migration of chloramphenicol, beta-lactam,
364
quinolone, trimethoprim, fosmidomycin, macrolide-lincosamide-streptogramin, polymyxin,
365
vancomycin,
366
aminoglycoside, acridine, fluoroquinolone and multidrug resistance genes from pig farm to
367
adjoining rivers in China. Also, Pornsukarom and Thakur (2017) reported horizontal transfer
368
of beta-lactam resistance genes, tetracycline resistance genes, sulphonamide, aminoglycoside
369
resistance and AMR determinants in Salmonella serotypes after land application of manure
370
from commercial swine farms.
371
The high occurrence of P. shigelloides resistant isolates against non-recommended antibiotics
372
depicts intrinsic resistance of the microorganism against the antibiotics. Although,
373
Plesiomonas isolates were susceptible to gentamycin and amikacin across the sampling
374
locations, this however, does not guarantee an in vivo performance of the antibiotics as these
375
agents are not targets for therapy (EUCAST, 2018b).
376
3.2.
377
The observed low RQs (0%) of imipenem, meropenem, norfloxacin and levofloxacin in most
378
of the sites suggests lack of antibiotic resistance selection pressures for the antibiotics in the
379
sites. Other recommended antibiotics with higher RQs imply isolates’ response to probable
380
presence of antibiotic selection pressures at the sites. High RQs have significantly associated
381
with sites heavily impacted by WTPEs and antibiotics pollution (Amos et al. 2018).
glycopeptide,
sulphonamide,
lincosamide,
macrolide,
tetracycline,
Antibiotic resistance quotients (RQs) and antibiotic susceptibility profiles
382
The resistance shown against antibiotics tested by Plesiomonas in this study is in agreement
383
with literature. Many authors have reported clinical Plesiomonas isolates’ (multi)resistance
384
against many of the tested antibiotics (Depaola et al., 1995; Auxiliadora-Martins et al.,
385
2010a;Jun et al., 2011; Bonatti et al., 2012; Chen et al., 2013; Abdelhamed et al., 2018).
386
Similar to the observed resistance against fluoroquinone, carbapenems and cephalosporins in
387
this study, Adesiyan et al. (2019) reported resistance to trimethoprim + sulphamethoxazole,
388
ciprofloxacin, norfloxacin, and imipenem in 36%, 30%, 30%, and 18% of environmental
389
isolates of P. shigelloides, respectively. High susceptibility of environmental P. shigelloides
390
isolates
391
piperacillin/tazobactam, cefepime, meropenem, cefoxitin, norfloxacin, imipenem, ertapenem,
392
gentamicin and tetracycline is in agreement with other authors (Auxiliadora-Martins et al.,
393
2010a; Matsuyama et al., 2015; Xia et al., 2015).
394
The MARI of P. shigelloides isolates established on recommended and non-recommended
395
antibiotics was significantly different and attests to the inherent potency of the two groups of
396
antibiotics. With modal value of the isolates’ MARI equals zero for recommended drugs
397
while the corresponding value for non-recommended antibiotics was 0.45, it implies an
398
underlying risk that should normally be associated with empirical treatment of P. shigelloides
399
infections with the antibiotic groups if there is no resistance case. The estimated EPR of P.
400
shigelloides infection in this study suggests that, should empirical treatment of infection be
401
necessary in the communities, clinicians that opt for any of the recommended antibiotics
402
against the usual first line agents (non-recommended) prior to proper diagnosis have 65.93%
403
chance of avoiding fatal scenario or outcome. However, early diagnosis of P. shigelloides
404
extraintestinal infections as well as the use of appropriate antibiotics treatment have been
405
advised (Xia et al., 2015). Late diagnosis, misdiagnosis and wrong antibiotics treatment lead
406
to high mortality rate (Xia et al., 2015). Several cases of empirical treatment and late
to
trimethoprim-sulfamethoxazole,
levofloxacin,
ciprofloxacin,
407
diagnosis of P. shigelloides infection have been reported to cause death in extraintestinal
408
infections (Billiet et al., 1989; Nolte et al., 1988; Terpeluk et al., 1992). Some of the non-
409
recommended antibiotics reported in unsuccessful empirical (combinatorial) treatment of P.
410
shigelloides extraintestinal infections include ampicillin, gentamicin and vancomycin ( Nolte
411
et al., 1988;Billiet et al., 1989; Terpeluk et al., 1992). Empirical treatments that involved at
412
least one of the appropriate antibiotics as first-line agent increased survival rate (Waecker et
413
al., 1988; Fujita et al., 1994).
414
ARI established by recommended antibiotics proved a good indicator for assessment of EPR
415
compared to non-recommended antibiotics as the group modal and mean values were both
416
lower than 0.2. Meanwhile, non-recommended antibiotics had group modal and mean ARI
417
values greater than 0.2 even in the absence of potential environmental pollution or resistance
418
selection pressures. The ARI values greater than 0.2 for recommended antibiotics at KB1,
419
KT1, TY2, KB2, KB3, KT2, KT3 and TY3 identified possible environmental pollution.
420
However, ARI values lower than 0.2 at TY5, KB4 and KT5, where a number of (M)ARPs
421
were observed is indicative of direct inputs from point/diffuse source pollutions rather than
422
presence of selection pressure. Sewage contamination could reintroduced resistant P.
423
shigelloides into natural habitats (Foster et al., 2000).
424
The use of comparative approach of ARI/MARI between recommended antibiotics and non-
425
recommended antibiotics against P. shigelloides further alerts the need for caution whenever
426
Krumperman’s MARI value of 0.2 threshold reference (Krumperman, 1983) is been applied
427
for delimiting low- and high-risk contamination. Because antimicrobials to which a microbe
428
is intrinsically resistance against produce MARI/ARI > 0.2. While several isolates in this
429
study had MARI value of 0 against recommended antibiotics, the same had values >0.2
430
against non-recommended antibiotics (Table S3).
431
Multiple resistance of P. shigelloides to important antibiotics could have serious clinical
432
consequences. The observed differential sensitivity or resistance of the isolates to antibiotics
433
from the same antimicrobial class could be linked to acquisition of different copies of ARG
434
or accumulation of point mutations. For instance, carbapenem resistance in Gram-negative
435
bacteria involve expression of efflux pumps, beta-lactamases, porin loss/mutation and
436
alterations in penicillin binding proteins (Papp-Wallace et al., 2011; Meletis, 2016).
437
Quinolones and fluoroquinolones resistance involve mutations in DNA gyrase and
438
topoisomerase IV, plasmid-borne resistance genes such as Qnr proteins and Aac(6′)-Ib-cr
439
aminoglycoside acetyltransferase, efflux pumps, reduced expression of porins and
440
overexpression of chromosome-encoded efflux pumps (Aldred et al., 2014). One isolate
441
might acquire multiple of these mechanisms, which then accounts for its varied resistance to
442
members of the same antimicrobial class.
443
4. Conclusion
444
The findings revealed an unusual P. shigelloides resistance against cephalosporins,
445
quinolones and fluoroquinolones. The resistance observed in the isolates is reflective of the
446
qualities of the freshwaters and consequence of anthropogenic activities in the catchments.
447
MARI attributed low risk of ET to recommended panel of antibiotics but higher risk to non-
448
recommended antibiotics. The likelihood of successful ET of P. shigelloides infections due to
449
resistance in the isolates using recommended antibiotics was very higher compared to low
450
chance of success obtained in the case of non-recommended antibiotics. ARI based on
451
recommended antibiotics identified potential likelihood of environmental pollutions at KB2,
452
KB3, KT2, KT3 and TY3. Resistance in P. shigelloides especially against cephalosporin,
453
quinolones and fluoroquinolones is distressing and suggests high pollution loading of the
454
freshwaters with substances with potential public health concerns in the Eastern Cape
455
Province.
Future
research
should
consider
direct
quantification
456
antimicrobials/antimicrobial metabolic by-product, pesticides, herbicides and other
457
xenobiotics/xenogenetic elements in the freshwater and their relevant hazard quotients in the
458
catchment.
459
Acknowledgements
460
The authors thank the South Africa Medical Research Council (SAMRC) and the National
461
Research Foundation, The World Academy of Science (NRF-TWAS) for financial support
462
(Grant Numbers: 99796 and 116382). Conclusions arrived at and opinions expressed in this
463
article are those of the authors and are not necessarily to be attributed to SAMRC or NRF-
464
TWAS.
465
Supplementary data
466
Appendix A
467
Appendix B
468
Tables S1 to S3
469
Figure S1
470
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Wadström, T., Ljungh, Å., 1991. Aeromonas and Plesiomonas as food- and waterborne
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pathogens. Int. J. Food Microbiol., 12, 303-311. https://doi.org/10.1016/0168-
870
1605(91)90144-E
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Waecker, N.J., Davis, C.E., Bernstein, G., Spector, S.A., 1988. Plesiomonas shigelloides
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septicemia and meningitis in a newborn. Pediatr. Infect. Dis. J. 7, 877–879.
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Wan, M.T., Chou, C.C., 2015. Class 1 integrons and the antiseptic resistance gene (qacE∆1)
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Wong, T.Y., Tsui, H.Y., So, M.K., Lai, J.Y., Lai, S.T., Tse, C.W., Ng, T.K., 2000.
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Plesiomonas shigelloides infection in Hong Kong: retrospective study of 167 laboratory-
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881
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Wouafo, M., Pouillot, R., Kwetche, P.F., Tejiokem, M.-C., Kamgno, J., Fonkoua, M.-C.,
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2006. An acute foodborne outbreak due to Plesiomonas shigelloides in Yaounde,
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Cameroon. Foodborne Pathog. Dis., 3, 209-211. https://doi.org/10.1089/fpd.2006.3.209
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Xia, F.-Q.Q., Liu, P.-N.N., Zhou, Y.-H.H., 2015. Meningoencephalitis caused by
886
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887
Pediatr. 41, 3. https://doi.org/10.1186/s13052-014-0107-1
888
Xu, J., Xu, Y., Wang, H., Guo, C., Qiu, H., He, Y., Zhang, Y., Li, X., Meng, W., 2015.
889
Occurrence of antibiotics and antibiotic resistance genes in a sewage treatment plant and
890
its effluent-receiving river. Chemosphere 119, 1379–1385.
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892
Zhang, Y., Gu, A.Z., Cen, T., Li, X., He, M., Li, D., Chen, J., 2018. Sub-inhibitory
893
concentrations of heavy metals facilitate the horizontal transfer of plasmid-mediated
894
antibiotic resistance genes in water environment. Environ. Pollut. 237, 74–82.
895
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896 897
Zhu, Y.G., Zhao, Y., Li, B., Huang, C.L., Zhang, S.Y., Yu, S., Chen, Y.S., Zhang, T., Gillings, M.R., Su, J.Q., 2017. Continental-scale pollution of estuaries with antibiotic
898
resistance genes. Nat. Microbiol., 2, 16270. https://doi.org/10.1038/nmicrobiol.2016.270
899
Table 1: Descriptive presentation of antibiotic susceptibility profile of freshwater P. shigelloides isolates (N = 182). Recommended antibiotics
Non-recommended antibiotics
Antibiotics
No. R (%)
No. I (%)
No. S (%)
Antibiotics
No. R (%)
No. I (%)
No. S (%)
CRO30C
54 (29.67)
7 (3.85)
122 (67.03)
CZ30C
89 (48.90)
52 (28.57)
42 (23.08)
CAZ30C
62 (34.07)
9 (4.95)
112 (61.54)
ATM30C
66 (36.26)
11 (6.04)
105 (57.69)
TS25C
19 (10.44)
3 (1.65)
161 (88.46)
T30C
31 (17.03)
5 (2.75)
147 (80.77)
LEV5C
5 (2.75)
14 (7.69)
164 (90.11)
GM10C
6 (3.30)
43 (23.64)
133 (73.08)
CIP5C
33 (18.13)
30 (16.48)
120 (65.93)
*PB300C
41 (22.53)
0 (0)
141 (77.47)
PTZ110C
16 (8.79)
9 (4.95)
158 (86.81)
VA30C
163 (89.56)
0 (0)
20 (10.99)
CPM30C
58 (31.87)
4 (2.20)
121 (66.48)
E15C
163 (89.56)
3 (1.65)
17 (9.34)
MEM10C
2 (1.10)
17 (9.34)
164 (90.11)
AK30C
6 (3.30)
53 (29.12)
123 (67.58)
CXM5C
64 (35.17)
42 (23.08)
77 (42.31)
AP10C
103 (56.59)
0 (0)
79 (43.41)
FOX30C
69 (37.91)
11 (6.04)
103 (56.59)
SMX25C
172 (94.51)
5 (2.75)
6 (3.30)
NOR10C
8 (4.40)
8(4.40)
167 (91.76)
C10C
61 (33.52)
0 (0)
121 (66.48)
ETP10C
9 (4.95)
5 (2.75)
169 (92.86)
IMI10C
1 (0.55)
9 (4.95)
173 (95.06)
900
Footnote: *disc diffusion screening was not recommended, for that reason it was grouped among nonRAs; zone interpretation was done using E.
901
coli ATCC®b 25922 (CLSI, 2018) quality control interpretative zone as surrogate.
902 903
904
Table 2: Resistance patterns of freshwater Plesiomonas isolates from the Tyhume, Kubusie and Kat rivers. TY Resistance patterns
TY1
No resistance
2
2
KB TY3
TY4
TY5/6
1
5
9
7
1
KB KB2
3
KB
KT
KT
KB4
5
1
2
KT3
KT 4
KT5
su m
9
4
3
7
4
2
10
63
3
1
0.55
% 34.4
CPM30C
1
CRO30C
1
0.55
ETP10C
1 1
1
0.55
MEM10C
1
1
0.55
NOR10C
1
1
0.55
1
0.55
2
1.09
3
1.64
4
2.19
PTZ110C
1
TS25C
1
CXM5C
1
CAZ30C
1
1 1
1
1
1
CIP5C
1
FOX30C
4
1
2
1
1
1
CAZ30C/CIP5C CIP5C/FOX30C
1
CIP5C/FOX30C CPM30C/NOR10C
CIP5C/CPM30C/CXM5C
2.19 9.29
1
1
0.55
1
1
0.55
1
1
0.55
1
0.55
1
0.55
1
0.55
1
1
0.55
1
0.55
1
3
1.64
3
10
5.47
1
0.55
1
0.55
1
0.55
1 1
CXM5C/FOX30C
CAZ30C/LEV5C/CIP5C
4 17
1
TS25C/CIP5C
CAZ30C/CPM30C/CXM5C
1 5
1
CXM5C/ETP10C
CAZ30C/CPM30C
2 2
1
CRO30C/CAZ30C
PTZ110C/FOX30C
1
1 2
1
4
1 1 1
CIP5C/CXM5C/FOX30C CIP5C/PTZ110C/MEM10C
1 1
CPM30C/CXM5C/FOX30C
1
CRO30C/CXM5C/ETP10C
1
CRO30C/CXM5C/FOX30C
1
TS25C/CIP5C/NOR10C CRO30C/CAZ30C/CPM30C
1
CAZ30C/CPM30C/CXM5C/FOX30C CAZ30C/CXM5C/NOR10C/ETP10C
0.55
0.55
1
2
1.09
1
0.55
1
0.55
1
0.55
1
0.55
1
0.55
1
0.55
1
0.55
1
0.55
4
2.19
1
0.55
1
0.55
1
0.55
1
0.55
1
0.55
1
0.55
3
1.64
8
4.37
1
0.55
1 1
CRO30C/CPM30C/CXM5C/FOX30C
1 1
CRO30C/LEV5C/CIP5C/FOX30C
1
CRO30C/CAZ30C/CPM30C/CXM5C
1
1
1
1
1
CAZ30C/TS25C/CPM30C/CXM5C/FOX30C
1
CRO30C/CAZ30C/CIP5C/CPM30C/FOX30C
1
0.55
CRO30C/CAZ30C/LEV5C/CPM30C
CAZ30C/TS25C/CIP5C/CPM30C/FOX30C
0.55
1
1
CRO30C/CXM5C/NOR10C/ETP10C
1
1
1
CRO30C/CAZ30C/PTZ110C/CPM30C
0.55 0.55
1
1
CRO30C/CAZ30C/CPM30C/ETP10C
1 1
1
CRO30C/CAZ30C/LEV5C/CPM30C/CXM5C/FOX30C/NOR10C/ETP1 0C
1
CRO30C/CAZ30C/TS25C/CPM30C/CXM5C
1
CRO30C/CAZ30C/TS25C/LEV5C/CIP5C CRO30C/CAZ30C/CIP5C/CPM30C/CXM5C
1 1
1
CRO30C/CAZ30C/CPM30C/CXM5C/FOX30C CRO30C/CAZ30C/CIP5C/CPM30C/NOR10C/ETP10C
1
1
1 1
2
1
CRO30C/CAZ30C/CIP5C/PTZ110C/CXM5C/FOX30C
1
CRO30C/CAZ30C/TS25C/CIP5C/CPM30C/CXM5C CRO30C/CAZ30C/PTZ110C/CPM30C/CXM5C/FOX30C CRO30C/CAZ30C/TS25C/CPM30C/CXM5C/FOX30C
2
1 1
1
1
1
0.55
1
1
0.55
1
2
1.09
2
1.09
CRO30C/CAZ30C/CIP5C/CPM30C/CXM5C/FOX30C
2
CRO30C/CAZ30C/CIP5C/CPM30C/CXM5C/FOX30C/NOR10C
1
1
1
5
2.73
1
0.55
CRO30C/CAZ30C/TS25C/CIP5C/CPM30C/CXM5C/FOX30C
1
1
0.55
CRO30C/CAZ30C/CIP5C/PTZ110C/CPM30C/CXM5C/FOX30C
2
2
1.09
1
5
2.73
CRO30C/CAZ30C/TS25C/CIP5C/PTZ110C/CPM30C/CXM5C/FOX30C
CRO30C/CAZ30C/TS25C/PTZ110C/CPM30C/CXM5C/FOX30C
1
1
0.55
CRO30C/CAZ30C/TS25C/PTZ110C/CPM30C/CXM5C/FOX30C/ETP10C
1
1
0.55
Number of resistance patterns
1
1
8
4
4
5
1
10
5
6
1
4
6
3
8
12
13
7
17
905
i Antibiotics: ceftriaxone (CRO30C), ceftazidime (CAZ30C), trimethoprim-sulfamethoxazole (TS25C), levofloxacin (LEV5C), ciprofloxacin
906
(CIP5C), piperacillin/tazobactam (PTZ110C), cefepime (CPM30C), meropenem (MEM10C), cefuroxime (CXM5C, 5 µg), cefoxitin (FOX30C),
907
norfloxacin
(NOR10C),
ertapenem
(ETP10C),
and
imipenem
(IMI10C).
908
909 910 911 912 913 914 915
Figure1.
916 917 918 919
Figure 2.
920
921
922 923
Figure 3.
924 925 926 927 928
Figure 4.
929
Figure captions
930
Figure 1. Map of the Amathole District Municipality showing the sampling points.
931
Tyhume river points = T1: TH1; T2: TH2; T3: TH3; T4: TH4; T5: TH5; T3a: TH3 water
932
abstraction point; T3d: TH3 domestic sewer inflow; T5m: TH5 manhole; Kat river points =
933
K1: KT1; K2: KT2; K3: KT3; K4: KT4; K5: KT5; K5a: KT5 dumpsite; K4f: KT4 farms;
934
K4f1: KT4 farms1; K4f2: KT4farms2; K4f3: KT4 farms3; K1w: KT1 wastewater treatment
935
plant effluent inflow point; K1e: KT1 wastewater treatment plant; Kubusie river points =
936
B1: KB1; B2: KB2; B3: KB3; B4: KB4; B5: KB5; B5f1: KB5farm1; B5f2: KB5 farm2; B5p:
937
KB5 poultary; B4s: KB4 settlement area; B2f: KB2 farms; B1f1: KB1 farm; B1f2: KB1
938
farm1; and B1f3: KB1 farm2.
939 940
Figure 2. A representative gel for molecular confirmation of P. shigelloides
941
isolates. Line 1= 1kb ladder; line 2 = negative control; 3 to 12 isolates; line 13 = positive
942
control.
943
Figure 3. Heatmap cluster analysis of Plesiomonas isolates’ antibiogram profiles. (A):
944
Plesiomonas isolates from Tyhume River; (B): Plesiomonas isolates from Kubusie River, and
945
(C): Plesiomonas isolates from Kat River. Colour interpretation, Blue (1): resistant, White
946
(2): intermediate and red (3): susceptible. The sampling site is denoted by the first 3 digits of
947
the strains’ names (e.g. KT4). Column and row clusters grouped antibiotics and isolates based
948
on
949
(CAZ30C), trimethoprim-sulfamethoxazole (TS25C), levofloxacin (LEV5C), ciprofloxacin
950
(CIP5C), piperacillin/tazobactam (PTZ110C), cefepime (CPM30C), meropenem (MEM10C),
951
cefuroxime (CXM5C), cefoxitin (FOX30C), norfloxacin (NOR10C), ertapenem (ETP10C),
952
and imipenem (IMI10C).
activity/response
respectively.
Antibiotics:
ceftriaxone
(CRO30C),
ceftazidime
953 954 955 956
Figure 4. Comparison of antibiotic resistance index (ARI) across sampling sites according
957
to recommended (RAs) and non-recommended antibiotics (nonRAs).
(A)
(B)
(C)
Highlights • Freshwater P. shigelloides isolates were tested against 24 antibiotics. • P. shigelloides had co-resistance against cephalosporin, quinolones & fluoroquinolones. • About 95.6% isolates had multiresistance index >0.2 to non-recommended antibiotics. • Empirical treatment of infections model linked 34.07% fatal case risk to choice As. • Environmental model identified pollution risk in 8 out of 15 sites.
Declaration of interests ☒ The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper. ☐The authors declare the following financial interests/personal relationships which may be considered as potential competing interests:
S0269-7491(19)32028-7
DOI:
https://doi.org/10.1016/j.envpol.2019.113493
Reference:
ENPO 113493
To appear in:
Environmental Pollution
Received Date: 17 April 2019 Revised Date:
23 August 2019
Accepted Date: 24 October 2019
Please cite this article as: Ekundayo, T.C., Okoh, A.I., Antimicrobial resistance in freshwater Plesiomonas shigelloides isolates: Implications for environmental pollution and risk assessment, Environmental Pollution (2019), doi: https://doi.org/10.1016/j.envpol.2019.113493. 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
Antimicrobial resistance in freshwater Plesiomonas shigelloides isolates: implications
2
for environmental pollution and risk assessment
3 Temitope Cyrus Ekundayo1,2,3* and Anthony I. Okoh1,2
4 5 1
6
SAMRC Microbial Water Quality Monitoring Centre, University of Fort Hare, Alice,
7 8
Eastern Cape, South Africa 2
Applied and Environmental Microbiology Research Group, Department of Biochemistry and
9 10
Microbiology, University of Fort Hare, Alice, Eastern Cape, South Africa 3
Department of Biological Sciences, University of Medical Sciences, Ondo City, Ondo State,
11
Nigeria
12 13
*Corresponding author (T.C. Ekundayo). Email: [email protected]
14 15
Abstract
16
Antibiotic resistance is known to impact treatment efficiency of Plesiomonas infections
17
negatively with fatal outcomes. This study investigated antibiogram fingerprint of P.
18
shigelloides (n = 182) isolated from three South Africa rivers using the disc diffusion
19
technique. Environmental pollution and analogous health risk (given infections) that could
20
associate with the freshwaters and empirical treatment of Plesiomonas were assessed using
21
Antibiotic Resistance Index (ARI) and Multiple Antibiotic Resistance Indices (MARI),
22
respectively. Thirteen EUCAST recommended (ERAs) and eleven non-recommended
23
antibiotics (NAs) used as first line agents in the treatment of gastroenteritis and
24
extraintestinal infections were tested. Resistance against ERAs decreased from cefoxitin
25
(37.91%), cefuroxime (35.17%), cefepime (31.87%), ceftriaxone (29.67%), ciprofloxacin
26
(18.13%),
27
ertapenem (4.95%), norfloxacin (4.40%), levofloxacin (2.75%), meropenem (1.10%) to
trimethoprim-sulfamethoxazole
(10.44%),
piperacillin/tazobactam
(8.79%),
28
imipenem (0.55%). The isolates had higher resistance (≥36.07%) against NAs but were
29
susceptible to amikacin (67.58%), gentamycin (73.08%), and tetracycline (80.77%). MARI of
30
the isolates were significantly different between ERAs and NAs (P-value < 0.05) and had an
31
average of 0.17±0.18 and 0.45±0.13, respectively. About 33.87% and 95.63% of the isolates
32
had MARI value from 0.23 − 0.62 and 0.27 − 0.82 to ERAs and NAs, respectively. Also,
33
ERAs-based and NAs-based ARI across sampling units showed significantly different (P-
34
value < 0.05) means of 0.18±0.09 and 0.46±0.05, respectively. MARI attributed low risk of
35
empirical treatment to recommended antibiotics but higher risk to non-recommended
36
antibiotics. Model estimated successful and unsuccessful empirical treatment of infections
37
risks due to resistance in the isolates using recommended antibiotics as 65.93% and 34.07%,
38
respectively; 1.65% and 98.35% in the case of non-recommended antibiotics, respectively.
39
ARI based on recommended antibiotics identified potential environmental pollutions in a
40
number of sites. Resistance in freshwater P. shigelloides especially against cephalosporin,
41
quinolones and fluoroquinolones is distressing and might suggests high pollution of the
42
freshwaters in the Eastern Cape Province.
43
Keywords: Plesiomonas shigelloides; antimicrobials resistance index; risk assessment;
44
public health.
45
Capsule: the study revealed multi-resistance of P. shigelloides against last resort antibiotics;
46
identified pollution risk in 8 sites and greater risk of fatal outcomes of empirical treatment of
47
infection by non-recommended antibiotics.
48
1. Introduction
49
Antimicrobial resistance is one of the major clinical and veterinary challenges worldwide.
50
More disturbing is the resistance of freshwater microorganisms against important antibiotics
51
contrary to their antibiotics sensitive nature. The aquatic environments are now regarded as
52
repositories of antibiotic-resistant bacteria and their resistance genes (Korzeniewska et al.,
53
2013; Li et al., 2014; Leonard et al., 2015; Xu et al., 2015; Calero-Cáceres and Muniesa,
54
2016). Basically, the aquatic environments are open to anthropogenic pollutions (Zhu et al.
55
2017; Shao et al. 2018; Antti et al. 2018; Jiang et al. 2018) from a wide range of influences
56
including storm water/agricultural wastes or surface run-offs (Ahmed et al. 2018); wastewater
57
treatment plant (Rizzo et al. 2014; Hembach et al. 2017; Proia et al. 2018a; Proia et al.
58
2018b); hospital effluents (Harnisz and Korzeniewska 2018); industrial wastes (Karkman et
59
al. 2017);agricultural runoffs from slaughterhouses (Wan and Chou 2015; Fang et al. 2018);
60
effluents from landfills, floodwaters, and recreational functions. Many of these are heavily
61
laden with antibiotics residues, pesticides, herbicides, biocides, pharmaceuticals, textile dye
62
/organic compounds, heavy xenogenetic elements, disinfectants, antibiotic resistant bacteria
63
and antibiotic resistant genes (Jiao et al., 2017; Karkman et al., 2017; Fang et al., 2018; Guo
64
et al., 2018; Harnisz and Korzeniewska, 2018; Jiang et al., 2018; Li et al., 2018; Shao et al.,
65
2018; Zhang et al., 2018).
66
Plesiomonas shigelloides, the only oxidase-positive member of the Enterobacteriaceae, is
67
one of the freshwater- and aquatic resources-borne microorganisms (Wadström and Ljungh,
68
1991; Brenner et al., 2005). It is a Gram-negative rod, motile and non-spore-forming bacteria
69
recognized as a water- and food-borne pathogen and recently grouped into the order
70
Enterobacterales (Brenner et al., 2005; Meng et al., 2012; Santos et al., 2015). P. shigelloides
71
has been isolated from mollusks, crustaceans, reptiles and fishes as well as birds, amphibians,
72
and mammals (Oxley et al., 2002; Huber et al., 2004; Salerno et al., 2007; Alexander et al.,
73
2016; Pan et al., 2017). Mostly, regional distribution of the bacteria is often attributed to the
74
tropics and the subtropics including Southeast Asia, Africa and South America in particular
75
(Arai et al., 1980; Obi et al., 1995; Canosa and Pinilla, 1999; Shigematsu et al., 2000; Gibotti
76
et al., 2000; Tseng et al., 2002; Wong et al., 2000; Maluping et al., 2005;Chen et al., 2013;
77
Nwokocha and and Onyemelukwe, 2014). Notwithstanding, P. shigelloides has been isolated
78
in the cold and temperate regions of Sweden ( Krovacek et al., 2000; Gonzalez-Rey et al.,
79
2003), Netherlands, Serbia, Hungary and Czech Republic ( Medema and Schets, 1993;
80
Aldová et al., 1999; Bardon, 1999; Petrušić et al., 2018).
81
P. shigelloides is very important in human and veterinary medicines as several cases of
82
gastrointestinal and extraintestinal infections have been linked to the pathogen (Ampofo et
83
al., 2001; Auxiliadora-Martins et al., 2010b; Ozdemir et al., 2010; Bonatti et al., 2012; Xia et
84
al., 2015; Bowman et al., 2016). Gastrointestinal infections from P. shigelloides are
85
sometimes self-limiting (Holmberg and Farmer, 1984; Holmberg et al., 1986) but duration of
86
illness and treatment of (extraintestinal) infections often take up to 3 ─ 56 days (Ampofo et
87
al., 2001; Auxiliadora-Martins et al., 2010b; Bonatti et al., 2012; Bowman et al., 2016; Xia et
88
al., 2015). Many deaths have also resulted from Plesiomonas extraintestinal infections,
89
especially among children ( Nolte et al., 1988; Billiet et al., 1989; Terpeluk et al., 1992; Chen
90
et al., 2016; Xia et al., 2015). The clinical importance of P. shigelloides continues to grow in
91
recent times (Bonatti et al., 2012; Pfeiffer et al., 2012; Bowman et al., 2016; Ding et al.,
92
2015; Novoa-Farías et al., 2016; Patel et al., 2016; Pence, 2016; Hustedt and Ahmed, 2017a,
93
2017b). Other public health issues traced to P. shigelloides include food- and water-borne
94
outbreaks (Graciaa et al., 2018; Houten et al., 1998; Wouafo et al., 2006), and disease
95
outbreak in farmed Percocypris pingi in China (Pan et al., 2017).
96
Antibiotic therapy remains one of the primary instruments in infection control and
97
management. However, antibiotic resistance is known to impact treatment efficiency of
98
Plesiomonas infections negatively. Treatment failures and several deaths from Plesiomonas
99
infections have been attributable to resistance and wrong prescription of antibiotics (Pathak et
100
al., 1983; Terpeluk et al., 1992). Studies have revealed survival in neonatal extraintestinal
101
infections caused by P. shigelloides involved treatment with at least one or combination of
102
antibiotics from cephalosporins, carbapenems, aminoglycosides and quinolones (Eason and
103
Peacock, 1996; Riley et al., 1996; Ozdemir et al., 2010). More worrisome, P. shigelloides is
104
not among first-line pathogens routinely assayed in clinical laboratory and in part, share
105
some clinical manifestations with other pathogens, which often lead to its misdiagnosis (Chen
106
et al., 2013) and consequently increasing health risk due to Plesiomonas infections.
107
In this study, antibiogram fingerprint of P. shigelloides isolates from rivers in the Eastern
108
Cape Province, South Africa was investigated. The study modelled environmental pollution
109
risk (EPR) and empirical treatment risk (ETR) of Plesiomonas (given infections) with
110
recommended and non-recommended antibiotics in terms of Antibiotic Resistance Indices
111
(ARI) and Multiple Antibiotic Resistance Indices (MARI), respectively.
112
To the best of our knowledge, this is the first report on freshwater P. shigelloides isolates
113
from the Eastern Cape Province in South Africa, which provides a local context to the
114
antibiogram of the bacteria and indicator for assessment of EPR and ETR.
115
2.
Materials and methods
116
2.1
Study area and sampling sites
117
The study area is located within Amathole District Municipality in the Eastern Cape Province
118
(ECP) of South Africa. The district is the third populous among the six districts of the ECP. It
119
shares boundaries with the Chris Hani, Cacadu, and OR Tambo municipalities. Figure 1 show
120
the location map, some key features, and 15 sites selected on three rivers namely: Kubusie
121
river, tyhume and Kat river. The sites were selected after reconnaissance visits based on
122
presence, proximity and intensity of one or more of the following eco-socioeconomic
123
activities on the rivers’ courses such as irrigation, pastoral activities (livestock watering,
124
poultry, swine, etc.), wastewater treatment plants, recreational activities (waterfall),
125
proximity to farmland and farming activities, dam activity, domestic and household uses,
126
spiritual cleansing, water abstractions, and impoundments.
127
2.2
128
P. shigelloides were isolated from serially diluted water samples collected from the sites
129
following standard membrane filtration technique (APHA, 2005) using Inositol Brilliant
130
Green Bile Agar (details in Appendix A). The genomic DNA of the resultant presumptive P.
131
shigelloides obtained from the samples were subsequently extracted following overnight
132
cultivation on nutrient agar using the boiling method (Salerno et al., 2010) (Appendix A).
133
2.3
134
Polymerase chain reaction (PCR) for confirmation of the isolates was performed as
135
previously
136
GCAGGTTGAAGGTTGGGTAA-3′
137
which amplifies a region of the 23S rRNA gene. Four microliters of the amplification product
138
were electrophoresed in 1.5% agarose gel (Appendix A).
139
2.4
140
The antimicrobial susceptibility profiles
141
assessed using the disc diffusion method and the European Committee on Antimicrobial
142
Susceptibility Testing Guidelines (EUCAST, 2018a). A panel of 24 antibiotics including 13
143
recommended and 11 first-line antibiotic agents for the treatment of gastroenteritis and
144
extraintestinal infection were tested (details in Appendix A). All isolates were grouped as
145
Resistant (R), Intermediate (I) and Susceptible (S) to specific antibiotic based on the
146
interpretative table (CLSI, 2018; EUCAST, 2018a, 2018b).
Plesiomonas isolation and DNA extraction
Molecular confirmation of P. shigelloides
described
(Gu
and
Levin, and
2006)
using
the
primer
pair,
PS-F-5′-
PS-R-5′-TTGAACAGGAACCCTTGGTC-3′,
Antimicrobial susceptibility profiling of P. shigelloides isolates of the confirmed P. shigelloides isolates were
147
2.5
Determination of resistance quotients (RQs) of P. shigelloides isolates
148
RQs determined changes in antimicrobial resistance phenotypes of the isolates across a
149
range of antibiotics for all the sites. The RQs of the antibiotics were computed using the
150
equation (Amos et al., 2018):
151
2.6
152
assessment
153
P. shigelloides isolates from each sampling site was ‘phenotyped’ for multiple antibiotic
154
resistance ((M)ARPs) based on the 2 groups described in section 2.4. Isolates that showed
155
resistance against 3 or more antibiotics were recorded (Kinge et al., 2010). Each sampling
156
site was indexed for isolate-specific MARI (Blasco et al., 2008). The ARI was calculated for
157
each sampling site (Krumperman, 1983; Mohanta and Goel, 2014) (Appendix A).
158
The study modelled ETR and EPR based on comparative MARI and ARI values between
159
recommended and non-recommended antibiotics, respectively. The risk assessment was
160
construed on the following assumptions:
161
1. MARI (risk) based on recommended antibiotics (RAs) for treatment is always lower
162
(MARIRAs ≤ 0.2, when RAs are used) compared to non-recommended antibiotics (non-RAs,
163
MARInon-RAs ˃ 0.2). The 0.2 MARI or ARI value was an arbitrary threshold to differentiate
164
between low- and high-risk (Krumperman, 1983).
165
2. ETR = 0, when isolates are susceptible to RAs used in treatment; ETR ˃ 0, when isolates
166
are resistant against RAs. Generally, the ETR of Plesiomonas infection is defined as
167
MARIemp = MARIRAs + MARInon-RAs (where either MARIRAs or MARInon-RAs = 0, depending
168
on the group selected in an empirical treatment).
Phenotyping and indexing of isolates for multiple antibiotic resistance and risk
169
3. ARI of each site ≤ 0.2 when RAs are screened provided there is no antibiotic selection
170
pressures or pollution (ARIRAs ≤ 0.2); while ARInon-RAs ˃ 0.2 (when non-RAs are screened)
171
regardless of the presence or absence of antibiotic resistance selection pressure or pollution
172
Therefore, the EPR from a given site based on antibiotic resistance profile is defined as
173
ARIenv = ARIRAs + ARInon-RAs (where either ARIRAs or ARInon-RAs = 0, depending of group
174
selected in screening).
175
2.7
176
Hierarchical cluster analysis of antibiotic susceptibility test result was carried out by K-mean
177
and visualized using “ComplexHeatmap” r package (Gu et al., 2016) in R version 3.5.1
178
(2018-07-02). Descriptive analysis and one-way analysis of variance (ANOVA) were also
179
employed to compare different antibiotics response and sites. The difference between ARI
180
and MARI of the 2 groups of antibiotics were compared with the use of Wilcoxon signed-
181
rank test using ggpubr: 'ggplot2' R package version 0.1.8.999 (Kassambara, 2018). The
182
antibiotic resistance quotients (RQs) across the 15 sampling sites were calculated in Excel
183
version 2016. The difference among sites or antibiotics was defined as significant when P
184
values ≤ 0.05.
185
3. Results
186
Appendix B provides additional information on subsection of section 3.
187
3.1
188
A total of 182 confirmed P. shigelloides isolates were selected for antibiotic susceptibility
189
testing as follows: 35 from Kubusie river (KB1=7, KB2=3, KB3=4, KB4=14, KB5=7); 94
190
from Kat river (KT1=9, KT2=25, KT3=18, KT4=11, KT5=31); and 53 from Tyhume river
Data analysis
Confirmation of P. shigelloides
191
(TY1=8, TY2=3, TY3=9, TY4=16, TY5=17). All the 182 isolates yielded the expected
192
amplicon size (628-bp) characteristic of Plesiomonas (Figure 2).
193
3.2
194
Figure 3 presents heatmap cluster analysis of the isolates’ antibiogram fingerprints against
195
recommended antibiotics with respect to sample sites. Full graphic for both recommended
196
and non-recommended antibiotics can be found in Figure S1. The isolates generally have two
197
main clusters of antibiogram profile column-wise (Figure 3) in all the rivers, namely, a
198
cluster depicting antibiotic susceptibility pattern while the other cluster indicates antibiotic
199
resistance pattern of the isolates. For the isolates that originated from Tyhume river, 6
200
clusters characteristics of hetero-site isolates were noticed row-wise (Figure 3(A)). Figure
201
3B presents antibiogram profile clusters of isolates from Kat river. Five antibiogram clusters
202
that grouped isolates of diverse origin were obtained. For isolates from Kubusie river, 5
203
antibiogram clusters of hetero-site isolates were observed row-wise (Figure 3.C).
204
3.3
205
The occurrence of resistant isolates across sampling locations is summarised in Table S1.
206
Resistance occurence against recommended antibiotics was significantly different across
207
sampling sites (inter-sampling sites) on the rivers’ courses (Kubusie river: ANOVA, F =
208
8.675, P-value = 3.44 × 10−8; Kat river: ANOVA, F = 7.41, P-value = 3.15 × 10−7; and
209
Tyhume river: ANOVA, F = 4.336, P-value = 0.0002). Intra-site occurrence of resistant
210
isolates against different antibiotics was significantly different at Tyhume (ANOVA, F =
211
3.945, P-value = 0.01), and KAT (ANOVA, F = 3.763, P-value = 0.01) rivers’ courses, but
212
insignificantly different on Kubusie river (ANOVA, F = 1.654, P-value = 0.17). Generally,
213
high occurrence of resistance against most of the antibiotics tested compared to other sites
Antibiogram profiles and cluster analysis of isolates
Occurrence of resistant isolates per location
214
was found at KT2. Total occurrence of resistant isolates against recommended antibiotic
215
ranged from 9 (TY2/TY3) to 84 (KT2).
216
Occurrence of resistance against non-recommended antibiotics by the isolates was
217
significantly different across sites on the rivers (Tyhume river: ANOVA, F = 7.084, P-value
218
= 4.74 × 10−6; Kubusie river: ANOVA, F = 7.357, P-value = 3.11 × 10−6; and Kat river:
219
ANOVA, F = 5.639, P-value = 5.10 × 10−5). Notably, low frequency of resistance against
220
gentamycin and amikacin (0≥ n≤ 2) was observed in the isolates across locations. The
221
subtotal of resistant isolates against non-RAs across sites ranged from 16 (TY2) to 133
222
(KT5). Intra-site comparison of occurrence of resistant isolates against non-recommended
223
antibiotics showed a significantly different results in all the rivers (Tyhume river: ANOVA, F
224
= 2.670, P-value = 0.04; Kubusie river: ANOVA, F = 2.528, P-value = 0.05; and Kat river:
225
ANOVA, F = 3.451, P-value = 0.02).
226
3.4
227
The antibiotic resistance quotients (RQs) of the isolates across the 15 sampling locations is
228
shown in Table S2. All the Plesiomonas isolates had low RQS against imipenem, meropenem
229
and norfloxacin antimicrobials in all the sites with the exception of sites KT2 and KT5 for
230
imipenem and norfloxacin, respectively. Levofloxacin had 0% RQs at all sites on Kubusie
231
river, at KT4 and KT5 on Kat river, and at TY2, TY3 and TY4 on Tyhume river. The RQs of
232
the isolates against ceftriaxone, ceftazidime, trimethoprim-sulfamethoxazole, cefuroxime and
233
cefoxitin were usually high on Kubusie river at KB2, KB3, and on Kat river at KT2, and
234
KT3.
235
3.5
236
shigelloides isolates
Antibiotic resistance quotients (RQs) of Plesiomonas isolates
Descriptive
analysis
of
antibiogram
fingerprints
profiles
of
P.
237
Table 1 presents the overall descriptive analysis of antibiotic susceptibility profile of the P.
238
shigelloides isolates from the three rivers. For recommended antibiotics, percentage
239
susceptibility of the isolates ranged from 42.31% (cefuroxime) to 95.06% (imipenem). The
240
resistance of the isolates against recommended antibiotics decreased in order from cefoxitin
241
(69, 37.91%), cefuroxime (64, 35.17%), ceftazidime (62, 34.07%), cefepime (58, 31.87%),
242
ceftriaxone (54, 29.67%), ciprofloxacin (33, 18.13%), trimethoprim-sulfamethoxazole (19,
243
10.44%), piperacillin/tazobactam (16, 8.79%), ertapenem (9, 4.95%), norfloxacin (8, 4.40%),
244
levofloxacin (5, 2.75%), meropenem (2, 1.10%) and imipenem (1, 0.55%).
245
Record of isolates’ extreme resistance to some non-recommended antibiotics include
246
vancomycin (163, 89.56%), erythromycin (163, 89.56%) and sulfamethoxazole (172,
247
94.51%); and intermediate resistance to cefazolin (52, 28.57%) and amikacin (53, 29.12%).
248
About 67.58% to 80.77% of the isolates were susceptible to amikacin, gentamycin,
249
polymyxin and tetracycline.
250
3.6
251
shigelloides isolates
252
3.6.1 ETR from comparative MARI of P. shigelloides isolates
253
The comparison of MARPs and MARI of Plesiomonas isolates against recommended and
254
non-recommended antibiotics for assessment of ETR is given in Table S3. The MARI of the
255
isolates were significantly different between recommended and non-recommended antibiotics
256
(Wilcoxon, P = 12 × 10−14). While the average of the isolates MARI based on antibiotics of
257
choice was 0.168±0.181 (median/mode = 0/0.08), the mean MARI according to non-
258
recommended was 0.446±0.133 (Median/Mode = 0.45/0.45). A quick summary of Table S3
259
showed that 120 (65.93%) and 62 (34.07%) isolates had MARI of 0 − 0.15 and 0.23 − 0.62,
260
respectively for the recommended antibiotics. The MARI range of 0.09-0.18 and 0.27 − 0.82
Assessment of ETR and EPR established on MARIs and ARIs of P.
261
were noted for 3 (1.65%) and 175 (96.2%) isolates against non-recommended antibiotics.
262
Most importantly, while some isolates had zero MARI considering recommended antibiotics,
263
they had MARI ˃0.20 in case of non-recommended.
264
Summarily, the successful ETR (MARI < 0.2) and unsuccessful ETR (MARI ≥ 0.2) of P.
265
shigelloides infections due to the isolates considering recommended antibiotics collectively
266
was 65.93% and 34.07%, respectively. Similarly, the successful ETR and unsuccessful ETR
267
of infections due to the isolates on the ground of using non-recommended antibiotics was
268
1.65% and 98.35%, respectively. However, risk varied with individual isolate or antibiotics.
269
3.6.2 EPR from comparative ARI across sampling units.
270
Figure 4 shows the antibiotic resistance indices across sampling units. A single factor
271
comparison
272
antibiotics-based (nonRAs-based) ARI across the sites was significantly different (ANOVA,
273
F = 112.36, P-value = 1.18 × 10−11). The average RAs-based and nonRAs-based ARI across
274
sampling units were 0.184±0.091 and 0.459±0.050, respectively. Generally, recommended-
275
antibiotics-based ARI < 0.13 was found at KB4, KB5, KT4, KT5, TY4, TY5 and TY6; and ≥
276
0.2 at other locations. Non-RAs-based ARI had high values and ranged from 0.38 − 0.55
277
across the locations.
278
3.7
279
(M)ARPs of P. shigelloides isolates across various sampling units of the rivers against
280
recommended antibiotics (RAs) is shown in Table 2. The combinatorial expressions below
281
predicted different theoretical (M)ARPs possible for the 13 recommended and 11 non-
282
recommended antibiotics (nonRAs) as 8192 and 2048, respectively:
283
n
Cr =
of
recommended-antibiotics-based
(RAs-based) and
non-recommended-
Multi-resistance patterns ((M)ARPs) of P. shigelloides isolates
for RAs (n = 13, r = 0, 1 … 13) and;
284
n
285
However, only 61 and 68 (M)ARPs against RAs and nonRAs (data not shown) were
286
observed. Of the 182 isolates, 63 (34.62%) were sensitive to RAs, while 36 (19.8%) showed
287
resistance to 1 antibiotic. Also, 6.04% (n = 11) to 28.6% (n = 52) of the isolates had 3 to ≥5
288
(M)ARPs. For distribution of the observed 61 (M)ARPs across sampling locations, cefoxitin
289
had highest resistance proportion (9.29%). Four (2.19%) isolates were resistant to ceftazidime
290
and ciprofloxacin each. Occasional (M)ARP (resistant found only in one isolate) was seen in
291
16.48% (n = 30) of the isolates. The most frequent (M)ARPs was cefuroxime/cefoxitin
292
observed
293
ceftriaxone/ceftazidime/cefepime/cefuroxime/cefoxitin
294
ceftriaxone/ceftazidime/ciprofloxacin/cefepime/cefuroxime/cefoxitin (5, 2.74% isolates), and
295
ceftriaxone/ceftazidime/trimethoprim-sulfamethoxazole/
296
piperacillin/tazobactam/cefepime/cefuroxime/cefoxitin (5, 2.74% isolates).
297
Different (M)ARPs were observed among the Plesiomonas isolates from 15 locations.
298
Isolates from the sites exhibited ≥ 3 (M)ARPs. Notably, the study observed a high number of
299
(M)ARPs at sites KT5 (17), followed by KT3(13), KT2(12), and TY5/6(10). The number of
300
(M)ARPs at KB5, TY2, TY3, KB3, TY4, KB1, KB2, KB4, KT4, TY1, and KT1(8) ranged
301
from 3 – 8.
302
3.0
Discussion
303
3.1.
Antimicrobial resistance and sample sites relationship
304
Antibiotic therapy remains a major practice in infection control and treatment. Here, we
305
performed antibiogram fingerprint of P. shigelloides isolates against 24 panels of antibiotics.
306
The detection and confirmation of P. shigelloides from the sampling sites can be attributed to
307
possible anthropogenic pollution along the riverbanks. All the sites serve as animal watering
Cr =
for nonRAs (n = 11, r = 0, 1 … 11).
in
10
isolates
(5.47%), (8,
followed 4.4%
by isolates),
308
point in addition to other purposes except TY1, which is chiefly hotspot for
309
swimming/recreational activities. The rivers receive wastewater effluents (WWE) upstream at
310
KT1 and KB5. All these activities could contribute substances that is capable of directly or
311
indirectly induce resistance in microorganisms. For instance, WWE are usually laden with
312
xenogenetic/xenobiotic compound that are capable of inducing resistance in the pathogen.
313
Cluster analysis of the isolates’ antibiogram fingerprints showed diversity in terms of intra-
314
sampling and inter-sampling location, which suggests that (M)ARPs are not site specific. It is
315
not impossible that the clustered isolates have the same origin. Livestock can shed clones of
316
resistant bacteria when they visit sites that are very close to one another such as KB2 and
317
KB3. Heatmap/hierarchical cluster techniques have been used to infer antimicrobial
318
susceptibility profile similarity and antibiotic disturbance on aquatic microbial composition in
319
recent times (McCusker et al., 2019).
320
Despite the antibiogram profile similarity, occurrence of resistant isolates varied significantly
321
with sampling sites. This variation suggests different intensities of anthropogenic pollutions
322
at the sites. The differences in resistance pattern to different classes of antibiotics from the
323
sites could also be attributed to presence of different type of pollutants in the sites. For
324
instance, occurrence of resistant isolates was obvious at sites in wastewater treatment plant
325
(KT1) because wastewater is commonly laden with vast arrays of antibiotic wastes and heavy
326
metals; human settlements (KB3, KB4, KT2, TY3, TY4, TY5/6) which could connote the
327
presence of different antibiotic-resistance-inducing substances in domestic wastes such as
328
disinfectants from various settlements; game farm (KB1) and livestock farm (swine, poultry,
329
sheep and goats e.g. KB1, KB2 and KB5) and different farm inputs in orchids proximities on
330
the rivers’ routes. Extended-spectrum beta-lactamase producing E. coli and fluoroquinolone-
331
resistant isolates have been reported in free-living deer and wild boars in Vojvodina Province,
332
Serbia (Velhner et al. 2018). Wastewater treatment plant effluents (WTPEs) might be
333
responsible for burden of P. shigelloides resistance at KT1. WTPEs are known to contribute
334
ARGs and antimicrobial resistant bacteria to receiving waterbodies ( Hembach et al., 2017;
335
Antti et al., 2018; Sabri et al., 2018). A high relative abundance of antimicrobial resistance
336
genes (ARGs) are common in agriculture impacted watersheds (Zhu et al. 2018). Various
337
farm and livestock management practices in the rivers’ neighbourhoods serve as point and
338
diffused sources of pesticides, herbicides, disinfectants, residual antibiotics and antibiotic
339
metabolic by-products, quaternary ammonium compounds, heavy metals and biocides, which
340
could have promoted P. shigelloides resistance in the receiving river. These substances are
341
known to select microorganisms for ARGs and/or promote horizontal gene transfer among
342
microbial communities.
343
susceptibility of S. enterica and E. coli to multiple antibiotics due to commercial herbicides
344
such as dicamba, glyphosate, 2,4-D and their co-formulants. Also, sub-inhibitory
345
concentration of biocides (triclosan and chlorhexidine), and antibiotics (sulfamethoxazole and
346
gentamicin) have been reported to significantly increased occurrences of ARGs dissemination
347
(Jutkina et al. 2018). Zhao et al. (2017) found that heavy metals (Cr; Cu, Hg, Pb, Zn) and
348
nutrients from mariculture significantly co-driven propagation of macrolide-lincosamide-
349
streptogramin B, fluoroquinolone, aminoglycoside, beta-lactam and tetracycline resistance
350
genes in adjacent environment.
351
Aside from high possibility of diffused and run-off dissemination of the afore-mentioned
352
substances and resistant bacteria selected by their pressures from these farms, direct faecal
353
shedding of resistant P. shigelloides isolates by free ranging animals or livestock could also
354
add to the observed resistance burden in P. shigelloides isolates. Litters of animal faeces were
355
seen at the locations during sampling. Furthermore, human excreta and babies pampers
356
among many other human generated wastes were noticed at KB4. This is indicative that some
357
of the resistant P. shigelloides isolates might originated from human faeces. This is similar to
Kurenbach et al. (2017) found changes in the antibiotic
358
observation of Adesiyan et al. (2019) who found high resistant of P. shigelloides isolates
359
against important antibiotics in rivers impacted with human excreta and washing activities in
360
South-western Nigeria. The probable use of animal manure and poultry dugs in farms along
361
the riverbanks may serve as another source of resistant P. shigelloides isolates or could
362
promote transfer of resistance gene to P. shigelloides in the adjoining riverbanks. Jia et al.
363
(2017) and Fang et al. (2018) found high migration of chloramphenicol, beta-lactam,
364
quinolone, trimethoprim, fosmidomycin, macrolide-lincosamide-streptogramin, polymyxin,
365
vancomycin,
366
aminoglycoside, acridine, fluoroquinolone and multidrug resistance genes from pig farm to
367
adjoining rivers in China. Also, Pornsukarom and Thakur (2017) reported horizontal transfer
368
of beta-lactam resistance genes, tetracycline resistance genes, sulphonamide, aminoglycoside
369
resistance and AMR determinants in Salmonella serotypes after land application of manure
370
from commercial swine farms.
371
The high occurrence of P. shigelloides resistant isolates against non-recommended antibiotics
372
depicts intrinsic resistance of the microorganism against the antibiotics. Although,
373
Plesiomonas isolates were susceptible to gentamycin and amikacin across the sampling
374
locations, this however, does not guarantee an in vivo performance of the antibiotics as these
375
agents are not targets for therapy (EUCAST, 2018b).
376
3.2.
377
The observed low RQs (0%) of imipenem, meropenem, norfloxacin and levofloxacin in most
378
of the sites suggests lack of antibiotic resistance selection pressures for the antibiotics in the
379
sites. Other recommended antibiotics with higher RQs imply isolates’ response to probable
380
presence of antibiotic selection pressures at the sites. High RQs have significantly associated
381
with sites heavily impacted by WTPEs and antibiotics pollution (Amos et al. 2018).
glycopeptide,
sulphonamide,
lincosamide,
macrolide,
tetracycline,
Antibiotic resistance quotients (RQs) and antibiotic susceptibility profiles
382
The resistance shown against antibiotics tested by Plesiomonas in this study is in agreement
383
with literature. Many authors have reported clinical Plesiomonas isolates’ (multi)resistance
384
against many of the tested antibiotics (Depaola et al., 1995; Auxiliadora-Martins et al.,
385
2010a;Jun et al., 2011; Bonatti et al., 2012; Chen et al., 2013; Abdelhamed et al., 2018).
386
Similar to the observed resistance against fluoroquinone, carbapenems and cephalosporins in
387
this study, Adesiyan et al. (2019) reported resistance to trimethoprim + sulphamethoxazole,
388
ciprofloxacin, norfloxacin, and imipenem in 36%, 30%, 30%, and 18% of environmental
389
isolates of P. shigelloides, respectively. High susceptibility of environmental P. shigelloides
390
isolates
391
piperacillin/tazobactam, cefepime, meropenem, cefoxitin, norfloxacin, imipenem, ertapenem,
392
gentamicin and tetracycline is in agreement with other authors (Auxiliadora-Martins et al.,
393
2010a; Matsuyama et al., 2015; Xia et al., 2015).
394
The MARI of P. shigelloides isolates established on recommended and non-recommended
395
antibiotics was significantly different and attests to the inherent potency of the two groups of
396
antibiotics. With modal value of the isolates’ MARI equals zero for recommended drugs
397
while the corresponding value for non-recommended antibiotics was 0.45, it implies an
398
underlying risk that should normally be associated with empirical treatment of P. shigelloides
399
infections with the antibiotic groups if there is no resistance case. The estimated EPR of P.
400
shigelloides infection in this study suggests that, should empirical treatment of infection be
401
necessary in the communities, clinicians that opt for any of the recommended antibiotics
402
against the usual first line agents (non-recommended) prior to proper diagnosis have 65.93%
403
chance of avoiding fatal scenario or outcome. However, early diagnosis of P. shigelloides
404
extraintestinal infections as well as the use of appropriate antibiotics treatment have been
405
advised (Xia et al., 2015). Late diagnosis, misdiagnosis and wrong antibiotics treatment lead
406
to high mortality rate (Xia et al., 2015). Several cases of empirical treatment and late
to
trimethoprim-sulfamethoxazole,
levofloxacin,
ciprofloxacin,
407
diagnosis of P. shigelloides infection have been reported to cause death in extraintestinal
408
infections (Billiet et al., 1989; Nolte et al., 1988; Terpeluk et al., 1992). Some of the non-
409
recommended antibiotics reported in unsuccessful empirical (combinatorial) treatment of P.
410
shigelloides extraintestinal infections include ampicillin, gentamicin and vancomycin ( Nolte
411
et al., 1988;Billiet et al., 1989; Terpeluk et al., 1992). Empirical treatments that involved at
412
least one of the appropriate antibiotics as first-line agent increased survival rate (Waecker et
413
al., 1988; Fujita et al., 1994).
414
ARI established by recommended antibiotics proved a good indicator for assessment of EPR
415
compared to non-recommended antibiotics as the group modal and mean values were both
416
lower than 0.2. Meanwhile, non-recommended antibiotics had group modal and mean ARI
417
values greater than 0.2 even in the absence of potential environmental pollution or resistance
418
selection pressures. The ARI values greater than 0.2 for recommended antibiotics at KB1,
419
KT1, TY2, KB2, KB3, KT2, KT3 and TY3 identified possible environmental pollution.
420
However, ARI values lower than 0.2 at TY5, KB4 and KT5, where a number of (M)ARPs
421
were observed is indicative of direct inputs from point/diffuse source pollutions rather than
422
presence of selection pressure. Sewage contamination could reintroduced resistant P.
423
shigelloides into natural habitats (Foster et al., 2000).
424
The use of comparative approach of ARI/MARI between recommended antibiotics and non-
425
recommended antibiotics against P. shigelloides further alerts the need for caution whenever
426
Krumperman’s MARI value of 0.2 threshold reference (Krumperman, 1983) is been applied
427
for delimiting low- and high-risk contamination. Because antimicrobials to which a microbe
428
is intrinsically resistance against produce MARI/ARI > 0.2. While several isolates in this
429
study had MARI value of 0 against recommended antibiotics, the same had values >0.2
430
against non-recommended antibiotics (Table S3).
431
Multiple resistance of P. shigelloides to important antibiotics could have serious clinical
432
consequences. The observed differential sensitivity or resistance of the isolates to antibiotics
433
from the same antimicrobial class could be linked to acquisition of different copies of ARG
434
or accumulation of point mutations. For instance, carbapenem resistance in Gram-negative
435
bacteria involve expression of efflux pumps, beta-lactamases, porin loss/mutation and
436
alterations in penicillin binding proteins (Papp-Wallace et al., 2011; Meletis, 2016).
437
Quinolones and fluoroquinolones resistance involve mutations in DNA gyrase and
438
topoisomerase IV, plasmid-borne resistance genes such as Qnr proteins and Aac(6′)-Ib-cr
439
aminoglycoside acetyltransferase, efflux pumps, reduced expression of porins and
440
overexpression of chromosome-encoded efflux pumps (Aldred et al., 2014). One isolate
441
might acquire multiple of these mechanisms, which then accounts for its varied resistance to
442
members of the same antimicrobial class.
443
4. Conclusion
444
The findings revealed an unusual P. shigelloides resistance against cephalosporins,
445
quinolones and fluoroquinolones. The resistance observed in the isolates is reflective of the
446
qualities of the freshwaters and consequence of anthropogenic activities in the catchments.
447
MARI attributed low risk of ET to recommended panel of antibiotics but higher risk to non-
448
recommended antibiotics. The likelihood of successful ET of P. shigelloides infections due to
449
resistance in the isolates using recommended antibiotics was very higher compared to low
450
chance of success obtained in the case of non-recommended antibiotics. ARI based on
451
recommended antibiotics identified potential likelihood of environmental pollutions at KB2,
452
KB3, KT2, KT3 and TY3. Resistance in P. shigelloides especially against cephalosporin,
453
quinolones and fluoroquinolones is distressing and suggests high pollution loading of the
454
freshwaters with substances with potential public health concerns in the Eastern Cape
455
Province.
Future
research
should
consider
direct
quantification
456
antimicrobials/antimicrobial metabolic by-product, pesticides, herbicides and other
457
xenobiotics/xenogenetic elements in the freshwater and their relevant hazard quotients in the
458
catchment.
459
Acknowledgements
460
The authors thank the South Africa Medical Research Council (SAMRC) and the National
461
Research Foundation, The World Academy of Science (NRF-TWAS) for financial support
462
(Grant Numbers: 99796 and 116382). Conclusions arrived at and opinions expressed in this
463
article are those of the authors and are not necessarily to be attributed to SAMRC or NRF-
464
TWAS.
465
Supplementary data
466
Appendix A
467
Appendix B
468
Tables S1 to S3
469
Figure S1
470
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Table 1: Descriptive presentation of antibiotic susceptibility profile of freshwater P. shigelloides isolates (N = 182). Recommended antibiotics
Non-recommended antibiotics
Antibiotics
No. R (%)
No. I (%)
No. S (%)
Antibiotics
No. R (%)
No. I (%)
No. S (%)
CRO30C
54 (29.67)
7 (3.85)
122 (67.03)
CZ30C
89 (48.90)
52 (28.57)
42 (23.08)
CAZ30C
62 (34.07)
9 (4.95)
112 (61.54)
ATM30C
66 (36.26)
11 (6.04)
105 (57.69)
TS25C
19 (10.44)
3 (1.65)
161 (88.46)
T30C
31 (17.03)
5 (2.75)
147 (80.77)
LEV5C
5 (2.75)
14 (7.69)
164 (90.11)
GM10C
6 (3.30)
43 (23.64)
133 (73.08)
CIP5C
33 (18.13)
30 (16.48)
120 (65.93)
*PB300C
41 (22.53)
0 (0)
141 (77.47)
PTZ110C
16 (8.79)
9 (4.95)
158 (86.81)
VA30C
163 (89.56)
0 (0)
20 (10.99)
CPM30C
58 (31.87)
4 (2.20)
121 (66.48)
E15C
163 (89.56)
3 (1.65)
17 (9.34)
MEM10C
2 (1.10)
17 (9.34)
164 (90.11)
AK30C
6 (3.30)
53 (29.12)
123 (67.58)
CXM5C
64 (35.17)
42 (23.08)
77 (42.31)
AP10C
103 (56.59)
0 (0)
79 (43.41)
FOX30C
69 (37.91)
11 (6.04)
103 (56.59)
SMX25C
172 (94.51)
5 (2.75)
6 (3.30)
NOR10C
8 (4.40)
8(4.40)
167 (91.76)
C10C
61 (33.52)
0 (0)
121 (66.48)
ETP10C
9 (4.95)
5 (2.75)
169 (92.86)
IMI10C
1 (0.55)
9 (4.95)
173 (95.06)
900
Footnote: *disc diffusion screening was not recommended, for that reason it was grouped among nonRAs; zone interpretation was done using E.
901
coli ATCC®b 25922 (CLSI, 2018) quality control interpretative zone as surrogate.
902 903
904
Table 2: Resistance patterns of freshwater Plesiomonas isolates from the Tyhume, Kubusie and Kat rivers. TY Resistance patterns
TY1
No resistance
2
2
KB TY3
TY4
TY5/6
1
5
9
7
1
KB KB2
3
KB
KT
KT
KB4
5
1
2
KT3
KT 4
KT5
su m
9
4
3
7
4
2
10
63
3
1
0.55
% 34.4
CPM30C
1
CRO30C
1
0.55
ETP10C
1 1
1
0.55
MEM10C
1
1
0.55
NOR10C
1
1
0.55
1
0.55
2
1.09
3
1.64
4
2.19
PTZ110C
1
TS25C
1
CXM5C
1
CAZ30C
1
1 1
1
1
1
CIP5C
1
FOX30C
4
1
2
1
1
1
CAZ30C/CIP5C CIP5C/FOX30C
1
CIP5C/FOX30C CPM30C/NOR10C
CIP5C/CPM30C/CXM5C
2.19 9.29
1
1
0.55
1
1
0.55
1
1
0.55
1
0.55
1
0.55
1
0.55
1
1
0.55
1
0.55
1
3
1.64
3
10
5.47
1
0.55
1
0.55
1
0.55
1 1
CXM5C/FOX30C
CAZ30C/LEV5C/CIP5C
4 17
1
TS25C/CIP5C
CAZ30C/CPM30C/CXM5C
1 5
1
CXM5C/ETP10C
CAZ30C/CPM30C
2 2
1
CRO30C/CAZ30C
PTZ110C/FOX30C
1
1 2
1
4
1 1 1
CIP5C/CXM5C/FOX30C CIP5C/PTZ110C/MEM10C
1 1
CPM30C/CXM5C/FOX30C
1
CRO30C/CXM5C/ETP10C
1
CRO30C/CXM5C/FOX30C
1
TS25C/CIP5C/NOR10C CRO30C/CAZ30C/CPM30C
1
CAZ30C/CPM30C/CXM5C/FOX30C CAZ30C/CXM5C/NOR10C/ETP10C
0.55
0.55
1
2
1.09
1
0.55
1
0.55
1
0.55
1
0.55
1
0.55
1
0.55
1
0.55
1
0.55
4
2.19
1
0.55
1
0.55
1
0.55
1
0.55
1
0.55
1
0.55
3
1.64
8
4.37
1
0.55
1 1
CRO30C/CPM30C/CXM5C/FOX30C
1 1
CRO30C/LEV5C/CIP5C/FOX30C
1
CRO30C/CAZ30C/CPM30C/CXM5C
1
1
1
1
1
CAZ30C/TS25C/CPM30C/CXM5C/FOX30C
1
CRO30C/CAZ30C/CIP5C/CPM30C/FOX30C
1
0.55
CRO30C/CAZ30C/LEV5C/CPM30C
CAZ30C/TS25C/CIP5C/CPM30C/FOX30C
0.55
1
1
CRO30C/CXM5C/NOR10C/ETP10C
1
1
1
CRO30C/CAZ30C/PTZ110C/CPM30C
0.55 0.55
1
1
CRO30C/CAZ30C/CPM30C/ETP10C
1 1
1
CRO30C/CAZ30C/LEV5C/CPM30C/CXM5C/FOX30C/NOR10C/ETP1 0C
1
CRO30C/CAZ30C/TS25C/CPM30C/CXM5C
1
CRO30C/CAZ30C/TS25C/LEV5C/CIP5C CRO30C/CAZ30C/CIP5C/CPM30C/CXM5C
1 1
1
CRO30C/CAZ30C/CPM30C/CXM5C/FOX30C CRO30C/CAZ30C/CIP5C/CPM30C/NOR10C/ETP10C
1
1
1 1
2
1
CRO30C/CAZ30C/CIP5C/PTZ110C/CXM5C/FOX30C
1
CRO30C/CAZ30C/TS25C/CIP5C/CPM30C/CXM5C CRO30C/CAZ30C/PTZ110C/CPM30C/CXM5C/FOX30C CRO30C/CAZ30C/TS25C/CPM30C/CXM5C/FOX30C
2
1 1
1
1
1
0.55
1
1
0.55
1
2
1.09
2
1.09
CRO30C/CAZ30C/CIP5C/CPM30C/CXM5C/FOX30C
2
CRO30C/CAZ30C/CIP5C/CPM30C/CXM5C/FOX30C/NOR10C
1
1
1
5
2.73
1
0.55
CRO30C/CAZ30C/TS25C/CIP5C/CPM30C/CXM5C/FOX30C
1
1
0.55
CRO30C/CAZ30C/CIP5C/PTZ110C/CPM30C/CXM5C/FOX30C
2
2
1.09
1
5
2.73
CRO30C/CAZ30C/TS25C/CIP5C/PTZ110C/CPM30C/CXM5C/FOX30C
CRO30C/CAZ30C/TS25C/PTZ110C/CPM30C/CXM5C/FOX30C
1
1
0.55
CRO30C/CAZ30C/TS25C/PTZ110C/CPM30C/CXM5C/FOX30C/ETP10C
1
1
0.55
Number of resistance patterns
1
1
8
4
4
5
1
10
5
6
1
4
6
3
8
12
13
7
17
905
i Antibiotics: ceftriaxone (CRO30C), ceftazidime (CAZ30C), trimethoprim-sulfamethoxazole (TS25C), levofloxacin (LEV5C), ciprofloxacin
906
(CIP5C), piperacillin/tazobactam (PTZ110C), cefepime (CPM30C), meropenem (MEM10C), cefuroxime (CXM5C, 5 µg), cefoxitin (FOX30C),
907
norfloxacin
(NOR10C),
ertapenem
(ETP10C),
and
imipenem
(IMI10C).
908
909 910 911 912 913 914 915
Figure1.
916 917 918 919
Figure 2.
920
921
922 923
Figure 3.
924 925 926 927 928
Figure 4.
929
Figure captions
930
Figure 1. Map of the Amathole District Municipality showing the sampling points.
931
Tyhume river points = T1: TH1; T2: TH2; T3: TH3; T4: TH4; T5: TH5; T3a: TH3 water
932
abstraction point; T3d: TH3 domestic sewer inflow; T5m: TH5 manhole; Kat river points =
933
K1: KT1; K2: KT2; K3: KT3; K4: KT4; K5: KT5; K5a: KT5 dumpsite; K4f: KT4 farms;
934
K4f1: KT4 farms1; K4f2: KT4farms2; K4f3: KT4 farms3; K1w: KT1 wastewater treatment
935
plant effluent inflow point; K1e: KT1 wastewater treatment plant; Kubusie river points =
936
B1: KB1; B2: KB2; B3: KB3; B4: KB4; B5: KB5; B5f1: KB5farm1; B5f2: KB5 farm2; B5p:
937
KB5 poultary; B4s: KB4 settlement area; B2f: KB2 farms; B1f1: KB1 farm; B1f2: KB1
938
farm1; and B1f3: KB1 farm2.
939 940
Figure 2. A representative gel for molecular confirmation of P. shigelloides
941
isolates. Line 1= 1kb ladder; line 2 = negative control; 3 to 12 isolates; line 13 = positive
942
control.
943
Figure 3. Heatmap cluster analysis of Plesiomonas isolates’ antibiogram profiles. (A):
944
Plesiomonas isolates from Tyhume River; (B): Plesiomonas isolates from Kubusie River, and
945
(C): Plesiomonas isolates from Kat River. Colour interpretation, Blue (1): resistant, White
946
(2): intermediate and red (3): susceptible. The sampling site is denoted by the first 3 digits of
947
the strains’ names (e.g. KT4). Column and row clusters grouped antibiotics and isolates based
948
on
949
(CAZ30C), trimethoprim-sulfamethoxazole (TS25C), levofloxacin (LEV5C), ciprofloxacin
950
(CIP5C), piperacillin/tazobactam (PTZ110C), cefepime (CPM30C), meropenem (MEM10C),
951
cefuroxime (CXM5C), cefoxitin (FOX30C), norfloxacin (NOR10C), ertapenem (ETP10C),
952
and imipenem (IMI10C).
activity/response
respectively.
Antibiotics:
ceftriaxone
(CRO30C),
ceftazidime
953 954 955 956
Figure 4. Comparison of antibiotic resistance index (ARI) across sampling sites according
957
to recommended (RAs) and non-recommended antibiotics (nonRAs).
(A)
(B)
(C)
Highlights • Freshwater P. shigelloides isolates were tested against 24 antibiotics. • P. shigelloides had co-resistance against cephalosporin, quinolones & fluoroquinolones. • About 95.6% isolates had multiresistance index >0.2 to non-recommended antibiotics. • Empirical treatment of infections model linked 34.07% fatal case risk to choice As. • Environmental model identified pollution risk in 8 out of 15 sites.
Declaration of interests ☒ The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper. ☐The authors declare the following financial interests/personal relationships which may be considered as potential competing interests: