A novel universal DNA labeling and amplification system for rapid microarray-based detection of 117 antibiotic resistance genes in Gram-positive bacteria

Abstract Objectives To investigate the occurrence, the genetic environment and the functionality of novel variants of the MDR gene cfr(C) in Campylobacter from China. Methods A total of 370 Campylobacter isolates of porcine and chicken origin collected from three regions of China in 2015 were screened for cfr(C) by PCR. The phenotypes and genotypes of cfr(C)-positive isolates were investigated by antimicrobial susceptibility testing, PFGE, MLST, S1-PFGE, Southern blotting and WGS. Quantitative RT–PCR was used to compare the expression levels of the cfr(C) variants in their original isolate and clone constructs in Campylobacter jejuni NCTC 11168. Results Four (1.1%) porcine Campylobacter coli isolates were positive for cfr(C). They failed to show elevated MICs of phenicols. The deduced Cfr(C) sequences identified exhibited 2–6 amino acid changes compared with the original Cfr(C) reported in the USA. Cloning of the cfr(C) variant genes into C. jejuni NCTC 11168 resulted in ≥32-fold increases in the MICs of phenicols, indicating that the cfr(C) variant genes are functional. The cfr(C)-carrying isolates belonged to three genotypes and WGS analysis revealed the cfr(C) genes were chromosomally located in MDR genomic islands, which contained multiple antibiotic resistance genes of Gram-positive origin. Conclusions This study identified chromosomal cfr(C) genes in C. coli isolates from China. They appeared functionally dormant in the original isolates but were fully functional when cloned and expressed in C. jejuni. The cfr(C) genes were co-transferred with other antibiotic resistance genes, possibly from Gram-positive bacteria. These findings reveal new insights into the function and transmission of cfr(C) in Campylobacter.

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IS26 Family Members IS257 and IS1216 Also Form Cointegrates by Copy-In and Targeted Conservative Routes

mSphere ◽

10.1128/msphere.00811-19 ◽

2020 ◽

Vol 5 (1) ◽

Cited By ~ 5

Author(s):

Christopher J. Harmer ◽

Ruth M. Hall

Keyword(s):

Antibiotic Resistance ◽

Resistance Genes ◽

Target Selection ◽

Family Members ◽

Low Frequency ◽

Antibiotic Resistance Genes ◽

Temperature Sensitive ◽

Restrictive Temperature ◽

Content Type ◽

Gram Positive Bacteria

ABSTRACT IS26 has been shown to form cointegrates both by a copy-in mechanism involving one insertion sequence (IS) and a target and by a targeted conservative mechanism involving two ISs. IS26 is the flagship of a group of 65 bacterial ISs in the recently redefined IS6/IS26 family. Here, whether other family members can also use two mechanisms was examined using members of the IS257/IS431 and IS1216 isoform groups, which are associated with antibiotic resistance genes in staphylococci and enterococci, respectively. Transposases Tnp257 and Tnp1216 have 39% and 47% amino acid identities, respectively, with Tnp26 and are 62% identical to one another. Using a novel transposition assay, pUC-based plasmids carrying these ISs integrated into the chromosome of a temperature-sensitive polA Escherichia coli strain grown at the restrictive temperature. In the cointegrates, the plasmid carrying IS257 was flanked by various 8-bp target site duplications, consistent with random target selection. However, in a mating-out assay, only the targeted conservative reaction was detectable at a low frequency in a recA-negative E. coli strain, indicating that IS257 is at least 100-fold less active than IS26. For IS1216, in mating-out assays, both copy-in and targeted conservative cointegrate formation were detectable at frequencies similar to those observed for IS26. Duplication of various 8-bp target sites was detected for the copy-in route. For both IS257 and IS1216, when both of the plasmids carried an IS, the targeted conservative route occurred at a significantly higher frequency than the copy-in route, and only cointegrates formed by the conservative route were detected. IMPORTANCE IS26 differs from other studied ISs in the reactions that it can undertake. The differences make IS26 uniquely suited to its key role in the recruitment and spread of antibiotic resistance genes in Gram-negative bacteria. However, whether other ISs in the IS6/IS26 family can perform the same reactions is not known. IS257/IS431 and IS1216 isoforms found associated with antibiotic resistance genes in the Gram-positive bacteria staphylococci, enterococci, streptococci, and clostridia are related to IS26. However, the way that they move had not been investigated, limiting interpretation of their role in resistance gene dissemination and in the formation of cointegrates and complex resistance regions in staphylococci and enterococci. Here, they are shown to share the broad catalytic capabilities of IS26, demonstrating that it is likely that all members of the redefined IS6/IS26 family of bacterial ISs likewise are able to use both the copy-in and conservative routes.

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Transfer of antibiotic resistance genes between gram-positive and gram-negative bacteria.

Antimicrobial Agents and Chemotherapy ◽

10.1128/aac.38.7.1447 ◽

1994 ◽

Vol 38 (7) ◽

pp. 1447-1451 ◽

Cited By ~ 186

Author(s):

P Courvalin

Keyword(s):

Antibiotic Resistance ◽

Resistance Genes ◽

Antibiotic Resistance Genes ◽

Gram Negative Bacteria ◽

Gram Positive ◽

Gram Negative

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Evidence for Extensive Resistance Gene Transfer amongBacteroides spp. and among Bacteroides and Other Genera in the Human Colon

Applied and Environmental Microbiology ◽

10.1128/aem.67.2.561-568.2001 ◽

2001 ◽

Vol 67 (2) ◽

pp. 561-568 ◽

Cited By ~ 303

Author(s):

N. B. Shoemaker ◽

H. Vlamakis ◽

K. Hayes ◽

A. A. Salyers

Keyword(s):

Antibiotic Resistance ◽

Gene Transfer ◽

Resistance Gene ◽

Resistance Genes ◽

Dna Sequences ◽

Human Colon ◽

Bacillus Sphaericus ◽

Erythromycin Resistance ◽

Gram Positive ◽

Gram Positive Bacteria

ABSTRACT Transfer of antibiotic resistance genes by conjugation is thought to play an important role in the spread of resistance. Yet virtually no information is available about the extent to which such horizontal transfers occur in natural settings. In this paper, we show that conjugal gene transfer has made a major contribution to increased antibiotic resistance in Bacteroides species, a numerically predominant group of human colonic bacteria. Over the past 3 decades, carriage of the tetracycline resistance gene, tetQ, has increased from about 30% to more than 80% of strains. Alleles oftetQ in different Bacteroides species, with one exception, were 96 to 100% identical at the DNA sequence level, as expected if horizontal gene transfer was responsible for their spread. Southern blot analyses showed further that transfer of tetQwas mediated by a conjugative transposon (CTn) of the CTnDOT type. Carriage of two erythromycin resistance genes, ermF andermG, rose from <2 to 23% and accounted for about 70% of the total erythromycin resistances observed. Carriage oftetQ and the erm genes was the same in isolates taken from healthy people with no recent history of antibiotic use as in isolates obtained from patients with Bacteroidesinfections. This finding indicates that resistance transfer is occurring in the community and not just in clinical environments. The high percentage of strains that are carrying these resistance genes in people who are not taking antibiotics is consistent with the hypothesis that once acquired, these resistance genes are stably maintained in the absence of antibiotic selection. Six recently isolated strains carriedermB genes. Two were identical to erm(B)-P fromClostridium perfringens, and the other four had only one to three mismatches. The nine strains with ermG genes had DNA sequences that were more than 99% identical to the ermG ofBacillus sphaericus. Evidently, there is a genetic conduit open between gram-positive bacteria, including bacteria that only pass through the human colon, and the gram-negative Bacteroidesspecies. Our results support the hypothesis that extensive gene transfer occurs among bacteria in the human colon, both within the genus Bacteroides and among Bacteroides species and gram-positive bacteria.

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Forecasting the dissemination of antibiotic resistance genes across bacterial genomes

Nature Communications ◽

10.1038/s41467-021-22757-1 ◽

2021 ◽

Vol 12 (1) ◽

Author(s):

Mostafa M. H. Ellabaan ◽

Christian Munck ◽

Andreas Porse ◽

Lejla Imamovic ◽

Morten O. A. Sommer

Keyword(s):

Antibiotic Resistance ◽

Resistance Genes ◽

Antibiotic Resistance Genes ◽

Gram Negative Bacteria ◽

Bacterial Genomes ◽

Exchange Networks ◽

Gram Positive Bacteria ◽

Physiological Constraints ◽

Statistical Framework ◽

Genes Encoding

AbstractAntibiotic resistance spreads among bacteria through horizontal transfer of antibiotic resistance genes (ARGs). Here, we set out to determine predictive features of ARG transfer among bacterial clades. We use a statistical framework to identify putative horizontally transferred ARGs and the groups of bacteria that disseminate them. We identify 152 gene exchange networks containing 22,963 bacterial genomes. Analysis of ARG-surrounding sequences identify genes encoding putative mobilisation elements such as transposases and integrases that may be involved in gene transfer between genomes. Certain ARGs appear to be frequently mobilised by different mobile genetic elements. We characterise the phylogenetic reach of these mobilisation elements to predict the potential future dissemination of known ARGs. Using a separate database with 472,798 genomes from Streptococcaceae, Staphylococcaceae and Enterobacteriaceae, we confirm 34 of 94 predicted mobilisations. We explore transfer barriers beyond mobilisation and show experimentally that physiological constraints of the host can explain why specific genes are largely confined to Gram-negative bacteria although their mobile elements support dissemination to Gram-positive bacteria. Our approach may potentially enable better risk assessment of future resistance gene dissemination.

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Ontology-Aware Deep Learning Enables Novel Antibiotic Resistance Gene Discovery Towards Comprehensive Profiling of ARGs

10.1101/2021.07.30.454403 ◽

2021 ◽

Author(s):

Yuguo Zha ◽

Cheng Chen ◽

Qihong Jiao ◽

Xiaomei Zeng ◽

Xuefeng Cui ◽

...

Keyword(s):

Antibiotic Resistance ◽

Deep Learning ◽

Resistance Gene ◽

Resistance Genes ◽

Antibiotic Resistance Gene ◽

Antibiotic Resistance Genes ◽

Oral Microbiome ◽

Gram Positive Bacteria ◽

Wet Lab ◽

Deep Learning Model

Antibiotic resistance genes (ARGs) have emerged in pathogens and spread faster than expected, arousing a worldwide concern. Current methods are suitable mainly for the discovery of close homologous ARGs and have limited utility for discovery of novel ARGs, thus rendering the profiling of ARGs incomprehensive. Here, an ontology-aware deep learning model, ONN4ARG (http://onn4arg.xfcui.com/), is proposed for the discovery of novel ARGs based on multi-level annotations. Experiments based on billions of candidate microbial genes collected from various environments show the superiority of ONN4ARG in comprehensive ARG profiling. Enrichment analyses show that ARGs are both environment-specific and host-specific. For example, resistance genes for rifamycin, which is an important antibacterial agent active against gram-positive bacteria, are enriched in Actinobacteria and in soil environment. Case studies verified ONN4ARG's ability for novel ARG discovery. For example, a novel streptomycin resistance gene was discovered from oral microbiome samples and validated through wet-lab experiments. ONN4ARG provides a complete picture of the prevalence of ARGs in microbial communities as well as guidance for detection and reduction of the spread of resistance genes.

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Association of nanoparticles with extracellular genetic material and implications for the fate of antibiotic resistance genes in environmental systems

10.1021/scimeetings.0c07368 ◽

2020 ◽

Author(s):

Nadrat Chowdhury

Keyword(s):

Antibiotic Resistance ◽

Resistance Genes ◽

Genetic Material ◽

Antibiotic Resistance Genes ◽

Environmental Systems

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Quintuplex PCR to Detect Antibiotic Resistance Genes in Streptococcus pneumoniae

Journal of Clinical and Health Sciences ◽

10.24191/jchs.v2i1.5861 ◽

2016 ◽

Vol 1 (2) ◽

pp. 22 ◽

Cited By ~ 2

Author(s):

Navindra Kumari Palanisamy ◽

Parasakthi Navaratnam ◽

Shamala Devi Sekaran

Keyword(s):

Antibiotic Resistance ◽

Streptococcus Pneumoniae ◽

Resistance Genes ◽

Bacterial Pathogen ◽

Antibiotic Resistance Genes ◽

Pcr Amplification ◽

Penicillin Resistance ◽

Penicillin Binding Proteins ◽

Efflux Mechanism ◽

Mic Value

Introduction: Streptococcus pneumoniae is an important bacterial pathogen, causing respiratory infection. Penicillin resistance in S. pneumoniae is associated with alterations in the penicillin binding proteins, while resistance to macrolides is conferred either by the modification of the ribosomal target site or efflux mechanism. This study aimed to characterize S. pneumoniae and its antibiotic resistance genes using 2 sets of multiplex PCRs. Methods: A quintuplex and triplex PCR was used to characterize the pbp1A, ermB, gyrA, ply, and the mefE genes. Fifty-eight penicillin sensitive strains (PSSP), 36 penicillin intermediate strains (PISP) and 26 penicillin resistance strains (PRSP) were used. Results: Alteration in pbp1A was only observed in PISP and PRSP strains, while PCR amplification of the ermB or mefE was observed only in strains with reduced susceptibility to erythromycin. The assay was found to be sensitive as simulated blood cultures showed the lowest level of detection to be 10cfu. Conclusions: As predicted, the assay was able to differentiate penicillin susceptible from the non-susceptible strains based on the detection of the pbp1A gene, which correlated with the MIC value of the strains.

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