Genomic characterization of antimicrobial resistance in 61 aquatic bacterial isolates.

Antimicrobial resistance (AMR) in pathogens important to aquatic animal health is of increasing concern but vastly understudied. Antimicrobial therapy is used to both treat and prevent bacterial disease in fish and is critical for a viable aquaculture industry and for maintenance of wild fish populations. Unfortunately, phenotypic antimicrobial susceptibility testing is technically difficult for bacteria recovered from aquatic animal hosts resulting in challenges in resistance monitoring using traditional methods. Whole-genome sequencing provides an appealing methodology for investigation of putative resistance. As part of the ongoing efforts of the FDA CVM Vet-LIRN to monitor AMR, source laboratories cultured and preliminarily identified pathogenic bacteria isolated from various fish species collected in 2019 from across the United States. Sixty-one bacterial isolates were evaluated using whole-genome sequencing. We present here the assembled draft genomes, AMR genes, predicted resistance phenotypes, and virulence factors of the 61 isolates and discuss concurrence of the identifications made by source laboratories using matrix-assisted laser desorption/time-of-flight mass spectrometry.

Non-carbapenemase producing carbapenem-resistant Klebsiella pneumoniae isolated from the urinary tract of a dog.

Objective: Carbapenems are broad-spectrum ß-lactams with excellent activity against multidrug-resistant (MDR) Enterobacterales. Unfortunately, resistance to carbapenems within this bacterial family, known as carbapenem-resistant Enterobacterales (CRE), occurs and challenges the ability to treat difficult MDR infections. Although the impact of carbapenem-resistance has been greatest in human medicine, reports in the veterinary literature are increasing especially as national veterinary antimicrobial resistance surveillance programs are now in place. In this brief communication, we report the isolation of a non-carbapenemase-producing, carbapenem-resistant Klebsiella pneumoniae from the urine of a dog, discuss the likely mechanism of resistance, and wider implications. Animal: Canine. Procedure: Whole genome sequencing and phenotypic antimicrobial susceptibility testing was performed on a K. pneumoniae isolated from the urine of a dog. Results: Antimicrobial susceptibility testing identified phenotypic resistance to imipenem and meropenem. Phenotypic detection of carbapenemase production was negative. Whole genome sequencing identified efflux pump genes associated with carbapenem resistance and point mutations in membrane porin genes. No carbapenemase gene was identified. Conclusion: Phenotypic antimicrobial susceptibility testing identified the K. pneumoniae as a non-carbapenemase producing carbapenem-resistant organism with the proposed genotypic mechanism including alteration of efflux pumps and membrane porin activity and/or expression. Clinical significance: Currently, there is limited use of carbapenem antimicrobial drugs in veterinary medicine, and practitioners may be unfamiliar or unaware of this type of resistance, its significance on routine antimicrobial susceptibility test reports, and implications for antimicrobial therapy and public health. Carbapenem-resistant Enterobacterales are infrequently isolated from companion animals; however, due to increasing adoption of advanced medical and surgical interventions, they may become more prevalent.

Objectif: Les carbapénèmes sont des ß-lactamines à large spectre avec une excellente activité contre les Enterobacterales multirésistantes (MDR). Malheureusement, la résistance aux carbapénèmes au sein de cette famille bactérienne, connue sous le nom d'Enterobacterales résistantes aux carbapénèmes (CRE), se produit et remet en question la capacité de traiter les infections MDR difficiles. Bien que l'impact de la résistance aux carbapénèmes ait été plus important en médecine humaine, les rapports dans la littérature vétérinaire se multiplient, d'autant plus que des programmes nationaux de surveillance de la résistance aux antimicrobiens vétérinaires sont désormais en place. Dans cette brève communication, nous rapportons l'isolement d'une Klebsiella pneumoniae non-productrice de carbapénémase et résistante aux carbapénèmes à partir de l'urine d'un chien, discutons du mécanisme probable de résistance et des implications plus larges. Animal: Canin. Procédure: Le séquençage du génome entier et les tests de sensibilité phénotypique aux antimicrobiens ont été effectués sur un isolat de K. pneumoniae provenant de l'urine d'un chien. Résultats: Les tests de sensibilité aux antimicrobiens ont identifié une résistance phénotypique à l'imipénème et au méropénème. La détection phénotypique de production de carbapénèmase était négative. Le séquençage du génome entier a identifié des gènes de pompe à efflux associés à la résistance aux carbapénèmes et à des mutations ponctuelles dans les gènes des porines membranaires. Aucun gène de carbapénémase n'a été identifié. Conclusion: Les tests de sensibilité phénotypique aux antimicrobiens ont identifié cet isolat de K. pneumoniae comme un organisme résistant aux carbapénèmes ne produisant pas de carbapénémase avec le mécanisme génotypique proposé, y compris l'altération des pompes à efflux et l'activité et/ou l'expression de porines membranaires. Signification clinique: Actuellement, l'utilisation des médicaments antimicrobiens à base de carbapénème en médecine vétérinaire est limitée, et les praticiens peuvent ne pas être familiers ou ne pas être au fait de ce type de résistance, de son importance dans les rapports de routine sur les tests de sensibilité aux antimicrobiens et de ses implications pour la thérapie antimicrobienne et la santé publique. Les Enterobacterales résistantes aux carbapénèmes sont rarement isolées des animaux de compagnie; cependant, en raison de l'adoption croissante d'interventions médicales et chirurgicales avancées, elles peuvent devenir plus répandues.(Traduit par Dr Serge Messier).

The fish pathogen Flavobacterium columnare represents four distinct species: Flavobacterium columnare, Flavobacterium covae sp. nov., Flavobacterium davisii sp. nov. and Flavobacterium oreochromis sp. nov., and emended description of Flavobacterium columnare.

Flavobacterium columnare is the causative agent of columnaris disease in freshwater fish and four discrete genetic groups exist within the species, suggesting that the species designation requires revision. The present study determined the taxonomic status of the four genetic groups of F. columnare using polyphasic and phylogenomic approaches and included five representative isolates from each genetic group (including type strain ATCC 23463T; genetic group 1). 16S rRNA gene sequence analysis revealed genetic group 2 isolate AL-02-36T, genetic group 3 isolate 90-106T, and genetic group 4 isolate Costa Rica 04-02-TNT shared less than <98.8 % sequence identity to F. columnare ATCC 23463T. Phylogenetic analyses of 16S rRNA and gyrB genes using different methodologies demonstrated the four genetic groups formed well-supported and distinct clades within the genus Flavobacterium. The average nucleotide identity (ANI) and digital DNA-DNA hybridization (GGDC) values between F. columnare ATCC 23463T, genetic group 2 isolate AL-02-36T, genetic group 3 isolate 90-106T, and genetic group 4 isolate Costa Rica 04-02-TNT were less than 90.84% and 42.7%, respectively. Biochemical and physiological characteristics were similar among the four genetic groups; however, quantitative differences in fatty acid profiles were detected and MALDI-TOF analyses demonstrated numerous distinguishing peaks unique to each genetic group. Chemotaxonomic, MALDI-TOF characterization and ANI/GGDC calculations afforded differentiation between the genetic groups, indicating each group is a discrete species. Herein, the names F. covae sp. nov. (AL-02-36T), F. davisii sp. nov. (90-106T), and F. oreochromis sp. nov. (Costa Rica 04-02-TNT) are proposed to represent genetic groups 2, 3, and 4, respectively.

Effect of an In Vitro Proximal Gastrointestinal Tract on Viability of Commercially Available Equine Probiotics.

Probiotics, by definition, are live micro-organisms and should remain viable when they reach the intended site of action which is typically the cecum and/or colon. In humans, probiotics often need enteric protection to survive transit through the proximal gastrointestinal (GI) tract. Typically, equine probiotics do not advertise enteric protection and to the author's knowledge the viability of equine probiotics after exposure to the proximal GI tract has not been evaluated. The objective of this study was to evaluate the effect of an in vitro simulation of the equine proximal GI tract on probiotic viability. We hypothesized that the simulated proximal GI tract would adversely effect microbial viability and that the adverse effects would be partially ameliorated by increasing the gastric pH to 4. A total of 11 products were evaluated of which six had at least one micro-organism that was adversely effected by exposure to the proximal GI tract and four of which had at least one micro-organism that was adversely affected when the gastric pH was increased to 4.0. Results from this study indicate that some micro-organisms in equine probiotics do not appear to be adversely affected by exposure to the equine proximal GI tract.

In Vitro Evaluation of the Effect of Storage at -20°C and Proximal Gastrointestinal Conditions on Viability of Equine Fecal Microbiota Transplant.

Fecal microbiota transplant (FMT), a technique used to restore normal intestinal microbial communities, has been successful in treating humans with Clostridioides difficile colitis. Subsequently, FMT is being used in veterinary patients with suspected intestinal dysbiosis. Unfortunately, little data are available regarding best practices for FMT in horses. The objective of this study was to evaluate the effects of storing manure prepared for equine FMT (MP-FMT) at -20°C for up to 4 weeks and passage through a simulated proximal gastrointestinal (GI) tract on the viability of MP-FMT. The results of this study indicate that storage at -20°C for greater than 1 week and exposure to conditions consistent with the proximal GI tract significantly decreased viability of the microbial population, with gram-negative enteric bacteria most significantly impacted. This preliminary evaluation indicates that further work is necessary to determine best practices to preserve the viability MP-FMT in horses.

Algal Lymphadenitis in a Dog Caused by Scenedesmus Species.

A 6-year-old, spayed female Labrador/Weimaraner cross-breed dog that had previously lived in Arizona presented in Montana for an annual examination with an incidentally enlarged popliteal lymph node, which was subsequently biopsied. Histologically, the lymph node was expanded by eosinophil-rich granulomas with both extracellular and intrahistiocytic green algae. These algae had intracytoplasmic, birefringent, and refractile granules; readily formed 2 to 3 mm green colonies on Columbia blood agar medium; and ultrastructurally had a multilayered cell wall and intracytoplasmic chloroplasts. Amplified product from the internal transcribed spacer and D1/D2 regions of the 28S ribosomal RNA gene had high sequence identity to Scenedesmus sp. Despite similar infection in the retropharyngeal lymph node 1 year later, the animal remained otherwise healthy with no clinical signs. To the authors' knowledge, this is the first case of Scenedesmus species infection in a dog and is a differential diagnosis for Coccidioides immitis.