Tetracycline resistance transfer among obligate anaerobes from the ruminant gut

Barbosa, Teresa Maria Leite Martins

January 1998

The main aim of this work was to investigate the nature, distribution and transmissibility of tetracycline resistance (Tc^R) genes among ruminant anaerobic bacteria. Two Tc^R rumen strains of <I>Butyrivibrio fibrisolvens,</I> 1.230 and 1.23, were able to transfer the resistance phenotype to the type strain, 2221^R although a third Tc^R strain, 1.210, could not. PCR amplification of 16S rDNA sequences showed that the three isolates were phylogenetically distinct from the recipient strain, but related to each other. Hybridisation work suggested the presence of two chromosomal Tc^R determinants among the <I>B. fibrisolvens </I>isolates. All three strains contained a non-transferable <I>tet</I>(O) gene, 100% identical at the nucleotide level with <I>tet</I>(O) from <I>S. pneumoniae. </I>The mobile Tc^R determinant present in strains 1.230 and 1.23, proved to be a novel ribosome protection <I>tet </I>gene, <I>tet</I>(V), whose gene product shares only 68% amino acid identity with its closest relatives, TetO/TetM and has G+C content considerably higher than that of other <I>B. fibrisolvens </I>genes. <I>tet</I>(V) was also identified in two Australian rumen <I>B. fibrisolvens </I>strains, in the rumen anaerobes <I>Selenomonas ruminantium </I>and <I>Mitsuokella multiacidus, </I>and in a pig isolate of <I>M. multiacidus. </I>These results provide evidence for gene transfer between obligate and facultative anaerobes from different gut ecosystems and different geographical locations. PFGE demonstrated that mobile chromosomal elements 40-50 kb in size, Tn<I>B1230 </I>and Tn<I>B123, </I>with preferred insertion sites in the recipient genome mediated the transfer of <I>tet</I>(V) in <I>B. fibrisolvens. </I>No homology was found between Tn<I>B1230</I> and regions from Tn<I>916</I> and Tn<I>5253. </I>Tn<I>B1230</I> is not associated with <I>tet</I>(V) in the other bacterial strains, suggesting that a diverse range of elements carry the gene in different bacteria. Although <I>tet</I>(V) is chromosomally encoded in the majority of the strains examined, there is some evidence that the gene may be located in a plasmid in <I>S. ruminantium </I>FB32 and FB34.

572

Antibiotic resistance; Bacteria

ELIMINATION OF ANTIBIOTIC RESISTANCE GENES FROM WATER MATRICES USING CONVENTIONAL AND ADVANCED TREATMENT PROCESSES

Das, Dabojani, 0009-0004-1997-0960

05 1900

The overuse and misuse of antibiotics to treat bacterial infections, the release of unmetabolized residuals into the sewer system, and the incomplete removal antibiotic residues by wastewater treatment plants (WWTPs) pose a severe threat to human health. The accumulation of antibiotic residue induces selective pressure on the bacterial population, resulting in the spread of antibiotic-resistant bacteria (ARB) and antibiotic-resistance genes (ARGs) in water. This study investigated the degradation of different types of ARGs in water matrices using a wide variety of treatment technologies. Real wastewater samples were collected from a WWTP in urban Philadelphia and the presence of single and multidrug-resistant bacteria and resistance genes were investigated using molecular-based techniques. Subsequently, an analytical method was developed and validated for the detection and quantification of the ARGs against a range of antibiotics, such as tetracycline (TCN), ciprofloxacin (CIP), and levofloxacin (LVX). Finally, to remove the ARGs from water matrices, different conventional and advanced oxidation processes were applied. At the very onset, conventional treatment processes such as chlorine treatment was used to inactivate the E.coli resistant strains. It was observed that chlorination can potentially deactivate the ARBs by applying a lower dose and contact time. However, the effectiveness of chlorine treatment in removing all types of ARGs from water matrices was limited. For instance, no significant degradation of extracellular ARGs (e-ARGs) was observed in DI water during chlorine treatment. Subsequently, a peracetic acid (PAA) based treatment process was used to degrade the genomic and plasmid-encoded ARGs from the water matrices. Similar to chlorine treatment, no significant changes were observed in the degradation of extracellular ARGs (e-ARGs) in DI and WW. Then, the degradation kinetics of ARGs across different types (gyrAR, tetAR, qnrSR) and forms (chromosomal, plasmids) were evaluated using the Ultraviolet (UV) disinfection process. Compared to chlorination and PAA, UV treatment showed better removal efficiencies for the degradation of different types of e-ARGs in DI water. The degradation profile of e-ARGs showed 1-4 log reductions at a UV fluence of 900 mj/cm2. The i-ARGs showed similar degradation rates as compared to e-ARGs in phosphate buffer saline (PBS) at the same UV dosage. On the other hand, the regrowth potential of ARBs at low UV dosage (60–180 mJ/cm2) showed the evidence of damage repairment after several hours of exposure to light (photoreactivation) and dark conditions, making it susceptible again to the resistance spread. To resolve this issue, process parameters were optimized, and no regrowth of the ARBs were found from the higher fluence from 300 to 600 mJ/ cm2. Later, UV/ H2O2 based AOP was applied to evaluate the degradation and deactivation of the same resistant genes. The addition of H2O2 during the UV treatment produces strongly reactive •OH radicals during the treatment and showed considerable improvements in e-ARGs degradation (1.2-5 logs) compared to UV treatment alone. However, this AOP showed minimal contribution to i-ARG degradation (1-2.4 logs), possibly due to the scavenging of •OH radicals by the cellular components in PBS. In contrast to PBS, the wastewater matrix moderately enhanced the gene degradation during the treatment. In terms of plasmid degradation, the conformational differences of the supercoiled structures showed 1.2-2.8 times slower degradation rates than chromosomal ARGs. In addition, the degradation kinetics of the free residual ARGs (f-ARGs) were assessed during the treatment to reduce the AMR dissemination risk from the treated sample. This study also examined the potential of ozone (O3) based oxidation process to degrade and deactivate the extracellular and intracellular ARGs, and MGE (plasmid, intl-1) from E.coli ARBs. The degradation kinetics of the ARGs across different sizes (118-454 bps) and types were evaluated in different water matrices (DI water, PBS, and WW), and showed a significantly higher removal for chromosomal, and plasmid encoded ARGs than other treatment technologies. For the e-ARGs in DI water, 3.8-5.2 logs removal was observed at ozone dosage of 2.0 × 10-2 M.s. i-ARGs in PBS and wastewater showed nearly similar degradation (3.8-5 logs) during O3, indicating the elimination of i-ARGs was not dependent on the cellular components and effluent organic matter. Moreover, an analysis of environmental DNA (eDNA) from wastewater was conducted to examine the degradation of DNA and ARGs for different storage periods and temperatures (-20°C, 0°C, 4°C, 22±0.87°C). Result indicated that water samples kept at -20°C and 0°C showed the best performance in preventing the DNA concentration and gene degradation over time. Additionally, the effectiveness of different preservatives (Longmire buffers: LB1 and LB2, benzalkonium chloride at 0.1%, 0.01%) were investigated in preserving the DNA integrity and the gene degradation at an ambient temperature. It was found that the Longmire buffer (LB1) exhibited lowest gene degradation during the three-week storage period. In summary, this research provided a comprehensive assessment on the degradation of e-ARGs, i-ARGs, and free ARGs from water using different treatment technologies (i.e., UV, UV/H2O2, O3, PAA, chlorine). Additionally, this study suggested valuable information on optimizing the process parameters of the selected methods and developed a comparative assessment of removing the ARGs from the water matrix (DI/PBS, WW). The estimation of Electrical Energy per Order (EEO, kWh/m3) during UV and ozone treatments provided a comparison of the energy consumption for ARGs degradation in the water. Overall, the findings of this study can be useful for evaluating different types and forms (chromosomal, plasmid) of ARG degradation from water matrices and can help to reduce the risk of AMR dissemination in the environment. / Civil Engineering

Environmental engineering

Advanced treatment processes

Antibiotic resistance bacteria

Antibiotic resistance genes

Emerging contaminant

Wastewater treatment

Editorial: Antimicrobial and Anticancer Peptides

O’Brien-Simpson, Neil M., Hoffmann, Ralf, Chia, C. S. Brian, Wade, John D.

03 April 2023

Editorial on the Research Topic. Antimicrobial and Anticancer Peptides.

info:eu-repo/classification/ddc/540

ddc:540

Biodynamic Imaging of Bacterial Infection and Advanced Phase-sensitive Spectroscopy

Honggu Choi (8802935)

07 May 2020

<div>Biological dynamics have been studied by many methods. Fluorescence dynamic microscopy and optical coherence tomography provided fundamental understandings of biological systems. However, their high NA optics only represent local characteristics. Biodynamic imaging (BDI) technique implements a low NA optics and acquires the statistical average of Doppler shifts that occurred by dynamic light scattering with biological dynamic subsystems provided globally averaged dynamic characteristics. </div><div>BDI is used for this study to investigate biomedical applications. The chemotherapy efficacy measurement by BDI demonstrated a good agreement between the Doppler spectral phenotypes and the preclinical outcomes. Also, dynamic responses of microbiomes by chemical stimuli demonstrated featured Doppler characteristics. The bacterial infection of epithelial spheroids showed consistent spectral responses and antibiotic-resistant E. coli infection treatment with a sensitive and resistive antibiotic showed a dramatic contrast. Furthermore, the phase-sensitive characteristics of BDI provided a clue to understanding the characteristics of the random process of biological systems. Levy-like heavy-tailed probability density functions are demonstrated and </div><div>the shape changed by infection will be discussed. </div>

Applied Physics

Optical Physics not elsewhere classified

Biological Physics

Biodynamic imaging

Doppler spectroscopy

Chemotherapeutic efficacy assay

Bacterial infection

antibiotic-resistance bacteria

Phase-sensitive detection

heterodyne-detection

Levy flights

Assessment of pathogenic bacteria and heavy metal pollution in sediment and water of Kahwa River, Bukavu, Democratic Republic of the Congo

Manegabe, Bahati Justin

02 1900

Anthropogenic activities generate waste products that pollute the environment with bacteria and heavy metals. This research assessed pollution of the Kahwa River, Bukavu Town, DRC with cadmium and lead (HMs) and bacterial enteropathogens. A survey of businesses, households and healthcare facilities showed general use of the river to remove effluent and waste. Indicator organisms were cultured at over 200 cfu/100 ml showing faecal contamination of the river water. Antibiotic resistance was shown by enteropathogenic Vibrio cholerae and Salmonella typhi to ampicillin and cotrimoxazole with some sensitivity shown to ciprofloxacin. River water contained HMs at around 40 times the World Health Organisation limit for drinking water. The bacteria, particularly from river sediment, tolerated HMs up to a concentration of 1.5 mg/ml. The presence in the Kahwa River of antibiotic-resistant pathogens showing tolerance to HMs has serious public health implications / Environmental Management / M.Sc. (Environmental management)

Cadmium

Lead

Pathogenic bacteria

Pollution

Antibiotics

Antibiotic resistance bacteria

Heavy metal resistance bacteria

Indicator bacteria

Kahwa River

Bukavu Town

Kahwa River catchment

Water

Sediment

Democratic Republic of the Congo

551.483096751

Heavy metals -- Environmental aspects

Water -- Pollution

Sediment control South Africa

Assessment of pathogenic bacteria and heavy metal pollution in sediment and water of Kahwa River, Bukavu, Democratic Republic of the Congo

Manegabe, Bahati Justin

02 1900

Anthropogenic activities generate waste products that pollute the environment with bacteria and heavy metals. This research assessed pollution of the Kahwa River, Bukavu Town, DRC with cadmium and lead (HMs) and bacterial enteropathogens. A survey of businesses, households and healthcare facilities showed general use of the river to remove effluent and waste. Indicator organisms were cultured at over 200 cfu/100 ml showing faecal contamination of the river water. Antibiotic resistance was shown by enteropathogenic Vibrio cholerae and Salmonella typhi to ampicillin and cotrimoxazole with some sensitivity shown to ciprofloxacin. River water contained HMs at around 40 times the World Health Organisation limit for drinking water. The bacteria, particularly from river sediment, tolerated HMs up to a concentration of 1.5 mg/ml. The presence in the Kahwa River of antibiotic-resistant pathogens showing tolerance to HMs has serious public health implications / Environmental Management / M.Sc. (Environmental management)

Cadmium

Lead

Pathogenic bacteria

Pollution

Antibiotics

Antibiotic resistance bacteria

Heavy metal resistance bacteria

Indicator bacteria

Kahwa River

Bukavu Town

Kahwa River catchment

Water

Sediment

Democratic Republic of the Congo

551.483096751

Heavy metals -- Environmental aspects

Water -- Pollution

Sediment control South Africa