Abstract:
Antimicrobial resistance (AMR) is regarded as a global health threat, characterized by
rising resistant bacteria and rapid development of resistance genes to existing
antibiotics used in clinical and veterinary settings. AMR has negative impacts and
affects human, animal, and the environment. In Botswana, Africa, AMR is not well
understood, particularly in rural settings with poor sanitation. The misuse and overuse
of commonly used antibiotics like ß-lactam antibiotics, combined with the complex
environment in poor rural communities, could contribute to the high occurrence and
diversity of extended ß-lactamase (ESBL) encoding bacteria that are difficult to treat.
To understand the spectrum of AMR in Botswana, it is critical to use the one health
approach to characterize the occurrence and diversity of antibiotic resistance.
The study was conducted in the town of Palapye, in a rural Boseja ward, and focused
on ESBLs encoding bacteria and resistance genes isolated from various water, soil,
and healthy animal feces within a single household. In this study, the characterization
of ESBL encoding bacteria from a rural community settlement was explored using
two main approaches: the culture dependent (isolation) and culture independent
(genomics) methods. In the culture dependent method, viable bacteria from animal
feces and environmental samples (such as soil and pond water) were isolated using
selective agar, and then randomly selected isolates were tested for phenotypic
antibiotic resistance profiles on nutrient agar supplemented with six ß-lactam
antibiotics (penicillin (16 g/ml), ampicillin (32 g/ml), cephalosporin (32 g/ml),
meropenem (4 g/ml), cefotaxime (64 g/ml), and cefoxitin (32 g/ml)). Following that,
DNA from bacterial isolates and uncultured samples were explored using a culture
independent approach involving next generation sequencing (NGS) methods such as
whole genome, shotgun metagenomics sequencing method and bioinformatics tools.
Based on the output from NGS (whole genome sequence and shotgun metagenomics)
online analysis tools were used to assemble the raw reads into consensus contigs using
PATRIC (Unicycler). The contigs were further analyzed for antibiotic resistance genes
(ARGs), virulence and plasmids using ResFinder, CARD/RGI, VirulenceFinder and
PlasmidFinder bioinformatics programs, respectively. Additionally, the species
present in the whole genome bacterial isolate was determined by KmerFinder whereas
in the shotgun sequence data, taxonomic classification was achieved by Kraken2
which revealed bacterial diversity on animal feces and environmental sources samples.
A total of 21 samples from pond water (n=3), different animal feces (such as chicken,
dogs, ducks) (n=9) and different soil samples (n=9) which were collected in triplicates
from a single household were cultured to isolate viable microorganisms. Overall, both
selective media plates had growth for all the samples which were equally picked for
further characterization. A total of 336 isolates were randomly picked from the
triplicate plates from each sample source and were analyzed for antibiotic
susceptibility test against six ß-lactam antibiotics, where 42.9 % (144/3360) were from
different animal feces, 42.9 % (144/336), were from surrounding soil samples and 14.2
% (48/336) were from pond water. There was an overwhelming resistance to all the
six ß-lactam antibiotics across all 336 isolates from animal feces, surrounding soil
samples and pond exhibited 100 % resistance to penicillins (penicillin and ampicillin),
100 % resistance to cephalosporins (Cephalosporin, 2
nd generation cephalosporins:
Cefoxitin, 3rd generation cephalosporin: cefotaxime) and 100 % resistance to
carbapenem (meropenem).
The results of NGS of cultured and uncultured samples revealed a diversity of genes
encoding resistance to various antibiotics, including ß-lactam antibiotics (blaSHV,
blaOXA, blaTEM, blaOKP-B, blaCMY), tetracycline (tetB(P), tet(J), tet (W), tet(Q)), phenicol
(cat, catA3), aminoglycosides (aph(6)-Id, aac(6')-iid), macrolides (mef(A)),
trimethoprim (dfrA14, dfrA15), fluoroquinolone (OqxA, OqxB) and sulfonamide (sul
1, sul 2). Furthermore, plasmid groups revealed from the samples were ColpVC,
ColRNAI, Col (MG828), Col3M, Col (BS512), IncR, and IncFIB(K), and the
virulence related genes namely colicin gene (cia), tellurium ion resistance gene (ter
C), ferric aerobactin receptor gene (iutA), ABC transporter protein gene (mchF), Outer
membrane protein gene (traT), and glutamate decarboxylase gene (gad) were detected
from the various samples. Chromosomal mutations were also detected (gyrA, gyrB,
parA, OmpK35, OmpK36, OmpK37).
The bacterial genome sequencing revealed the cultured dog feces sample to be a mixed
culture containing five bacterial organisms namely, Proteus mirabilis strain
(CRPM10), Citrobacter sp. (RHB21-C05), Paeniclostridium sordellii strain
(AM370), Proteus mirabilis strain (AR_0059) and Proteus mirabilis strain
(PmSC1111) respectively. Taxonomic profiling from shotgun metagenomic analysis
revealed the presence of different microbial communities in animal feces (dog) and
environmental sources. The most prevalent species in animal feces, pond water and
soil sample were shown to be Klebsiella with 44 %, 49 % and 44 % respectively. It
was followed by Proteus species with relative abundance from animal feces (42 %),
pond water and soil with 39 % and 40% accordingly. Escherichia has shown to be the
least discovered across all samples with animal feces (4 %), pond water (4 %) and soil
sample (8 %).
This study remains critical in Africa, and highlights the importance of AMR
surveillance, and efforts towards the implementation of NGS to provide
comprehensive information on the occurrence and diversity of AMR and mobile
genetic elements from clinical and environmental sources. The research will also aid
in the recommendations for community education on antibiotic use, prevention, and
control measures in order to limit the spread of antibiotic resistance in community
settings.
Portia, B (2024). Characterization of extended-spectrum-β lactamases (esbls) and other resistant genes encoding bacteria from a rural community settlement. Afribary. Retrieved from https://afribary.com/works/characterization-of-extended-spectrum-v-lactamases-esbls-and-other-resistant-genes-encoding-bacteria-from-a-rural-community-settlement
Portia, Brooks "Characterization of extended-spectrum-β lactamases (esbls) and other resistant genes encoding bacteria from a rural community settlement" Afribary. Afribary, 30 Mar. 2024, https://afribary.com/works/characterization-of-extended-spectrum-v-lactamases-esbls-and-other-resistant-genes-encoding-bacteria-from-a-rural-community-settlement. Accessed 24 Nov. 2024.
Portia, Brooks . "Characterization of extended-spectrum-β lactamases (esbls) and other resistant genes encoding bacteria from a rural community settlement". Afribary, Afribary, 30 Mar. 2024. Web. 24 Nov. 2024. < https://afribary.com/works/characterization-of-extended-spectrum-v-lactamases-esbls-and-other-resistant-genes-encoding-bacteria-from-a-rural-community-settlement >.
Portia, Brooks . "Characterization of extended-spectrum-β lactamases (esbls) and other resistant genes encoding bacteria from a rural community settlement" Afribary (2024). Accessed November 24, 2024. https://afribary.com/works/characterization-of-extended-spectrum-v-lactamases-esbls-and-other-resistant-genes-encoding-bacteria-from-a-rural-community-settlement