Veterinary ocular microbiome: Lessons learned beyond the culture

Banks, Kayla C.; Ericsson, Aaron C.; Reinero, Carol R.; Giuliano, Elizabeth A.

doi:10.1111/vop.12676

Cited by 13 publications

(17 citation statements)

References 77 publications

(211 reference statements)

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“…NGS can detect and identify virtually all bacteria in a given sample, providing an unprecedented level of information. Conversely, culture‐dependent methods failed to detect a large proportion of the microorganisms in a given community, which was sometimes referred to as the “great plate count anomaly.” 1 Metagenomics is a rapidly evolving area of research that offers great promise in advancing both human and veterinary medicine, and clinical practitioners will increasingly require a working knowledge of the ocular surface microbiota 2 . However, enthusiasm for microbiome research has outpaced agreement upon experimental practices causing a lack of standardized methodologies 3 .…”

Section: Introductionmentioning

confidence: 99%

Current ocular microbiome investigations limit reproducibility and reliability: Critical review and opportunities

Scott

Lewin

Leis

2020

Veterinary Ophthalmology

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Enthusiasm for research describing microbial communities using next‐generation sequencing (NGS) has outpaced efforts to standardize methodology. Without consistency in the way research is carried out in this field, the comparison of data between studies is near impossible and the utility of results remains limited. This holds true for bacterial microbiome research of the ocular surface, and other sites, in both humans and animals. In addition, the ocular surface remains under‐explored when compared to other mucosal sites. Low bacterial biomass samples from the ocular surface lead to further technical challenges. Taken together, two major problems were identified: (1) Normalization of the workflow in studies utilizing NGS to investigate the ocular surface bacteriome is necessary in order to propel the field forward and improve research impact through cross‐study comparisons. (2) Current microbiome profiling technology was developed for high bacterial biomass samples (such as feces or soil), posing a challenge for analyses of samples with low bacterial load such as the ocular surface. This article reviews the challenges and limitations currently facing ocular microbiome research and provides recommendations for minimum reporting standards for veterinary ophthalmologists and clinician scientists to limit inter‐study variation, improve reproducibility, and ultimately render results from these studies more impactful. The move toward normalization of methodology will expedite and maximize the potential for microbiome research to translate into meaningful discovery and tangible clinical applications.

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Section: Introductionmentioning

confidence: 99%

Current ocular microbiome investigations limit reproducibility and reliability: Critical review and opportunities

Scott

Lewin

Leis

2020

Veterinary Ophthalmology

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“…The community of living microorganisms in a particular environment, including its inhabitant bacteria, viruses, fungi and protozoa, is termed the microbiota. [1][2][3][4] By contrast, the microbiome describes all genetic material within the microbiota. 4,5 Initial investigation of the microbiota and microbiome was limited to culture-based and similar techniques.…”

Section: Introductionmentioning

confidence: 99%

“…The advent of metagenomic techniques, such as 16S ribosomal RNA (16S rRNA) gene sequencing, as well as bioinformatics systems, have allowed broader and more detailed investigation of the microbiome and microbiota, and their associations with various host factors and pharmacologic interventions. 2,3,[5][6][7][8][9] Evaluation of the bacterial microbiota can involve various approaches, including comparison of specific members (eg, different phyla and genera), alpha diversity indices (ecological indicators of the bacterial community in a sample) and assessment of beta diversity (evaluation of differences in overall bacterial communities between groups). Additional approaches can be used to provide different insights, such as the use of linear discriminate analysis effect size (LEfSe) to identify operational taxonomic units (OTUs) that are differentially abundant in species groups.…”

Section: Introductionmentioning

confidence: 99%

“…Microbiota analysis frequently begins following assembly of sequences with greater than 97% nucleotide identity into groups called OTUs. 3,10 Alpha diversity metrics indicate the taxonomic diversity (inverse Simpson's index), evenness (Shannon's evenness index) and richness (number of species observed [observed species richness: SOBS] and Chao1 index). 3,[10][11][12] Beta diversity metrics include measurements of microbial community membership (number of shared genera; Jaccard's index) and structure (number of shared genera and their relative abundances; Yue and Clayton index) between samples.…”

Section: Introductionmentioning

confidence: 99%

“…3,10 Alpha diversity metrics indicate the taxonomic diversity (inverse Simpson's index), evenness (Shannon's evenness index) and richness (number of species observed [observed species richness: SOBS] and Chao1 index). 3,[10][11][12] Beta diversity metrics include measurements of microbial community membership (number of shared genera; Jaccard's index) and structure (number of shared genera and their relative abundances; Yue and Clayton index) between samples. 10 A wide range of methods can be used to compare statistically the composition of microbiota communities, such as analysis of molecular variance (AMOVA) and unweighted UniFrac.…”

Section: Introductionmentioning

confidence: 99%

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Feline conjunctival microbiota in a shelter: effects of time, upper respiratory disease and famciclovir administration

Lucyshyn

Maggs

Cooper

et al. 2020

Journal of Feline Medicine and Surgery

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Objectives The aim of this study was to evaluate changes in the conjunctival microbiota of shelter-housed cats with time, upper respiratory disease (URD) and famciclovir administration. Methods Cats were assigned to treatment groups on shelter entry. Healthy cats or cats with URD received ~30 mg/kg or ~90 mg/kg of famciclovir or placebo PO q12h for 7 days, or were untreated. Swabs were collected from ventral conjunctival fornices prior to (day 1) and immediately after (day 8) the treatment period. Microbiota analysis was conducted on 124 randomly selected swabs from healthy (56 swabs) or URD-affected (68 swabs) cats. Following DNA extraction and amplification of the V4 region of the 16S rRNA gene, sequences were assembled into operational taxonomic units (OTUs). Over-represented OTUs (as determined by linear discriminate analysis effect size), alpha and beta diversity, and median relative abundance of known feline ocular surface pathogens were assessed for the entire population and in 10 clinically relevant subpopulations of cats. Results Bacteria from 33 phyla and 70 genera were identified. Considering all cats, median relative abundance of Mycoplasma increased from day 1 to day 8, while Proteobacteria decreased. Community membership and structure (beta diversity) differed between days 1 and 8 for all famciclovir-treated cats (regardless of health status or dose) and healthy or URD-affected cats (regardless of famciclovir dose). Differences in taxonomic diversity within a sample (alpha diversity) between day 1 and day 8 were not detected in any subpopulations. Conclusions and relevance Within 1 week of shelter entry, there were significant changes in community structure and membership of the feline conjunctival microbiota, with a shift towards over-representation of feline ocular surface pathogens. Although famciclovir may impact beta diversity of the feline conjunctival microbiota, absence of change in alpha diversity suggests minimal shift in individual cats.

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Current Methods for Microbiome Analysis

2023

Small Animal Microbiomes and Nutrition

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Veterinary ocular microbiome: Lessons learned beyond the culture

Cited by 13 publications

References 77 publications

Current ocular microbiome investigations limit reproducibility and reliability: Critical review and opportunities

Current ocular microbiome investigations limit reproducibility and reliability: Critical review and opportunities

Feline conjunctival microbiota in a shelter: effects of time, upper respiratory disease and famciclovir administration

Current Methods for Microbiome Analysis

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