dc.description.abstract |
Mastitis, the inflammation of the mammary gland and/or quarters is one of the most
prevalent diseases in the dairy industry worldwide with economic significance. The milk of
the lactating cows presents a complex ecosystem of interconnected microbial communities
which can impose a significant influence on the pathophysiology of mastitis. Bovine mastitis
is caused by a wide range of apparently resident microbes including bacteria, viruses, and
archaea. Our hypothesis- the possible dynamic shifts of microbiome compositions with the
progress of different pathophysiological states of mastitis are determined by its favoring
genomic potentials. In order to address the hypothesis, whole metagenome sequencing
(WMS) is carried out to compare the microbiomes of clinical mastitis (CM = 5), recurrent
clinical mastitis (RCM = 6), subclinical mastitis (SCM = 4), and healthy (H = 5) milk
samples. The metagenomics data analyzed to characterize the microbiomes associated with
bovine mastitis and their cross-talk in respect to disease progression, virulence factorsassociated
genes (VFGs), antibiotic resistance genes (AGRs), resistomes, and metabolic
functional potentials. The WMS generated 416.64 million reads (with an average of 20.83
million reads/sample) from the samples of four metagenomes. PathoScope (PS) and MGRAST
(MR) analyses mapped the WMS data to 442 bacterial, 58 archaeal, and 48 viral
genomes with distinct variation in microbiome composition, and abundances across these
metagenomes (CM>H>RCM>SCM). Significant variations observed in species richness (i.e.,
alpha-diversity; P = 0.003, Kruskal–Wallis test), and microbial community structure (i.e.,
beta-diversity; P = 0.001, Kruskal–Wallis test) among the samples of four metagenomes.
These diversities differ across the CM, RCM, SCM and H metagenomes, and numerically
dominated by phyla Proteobacteria, Firmicutes, Actinobacteria and Bacteroidetes. Through
PS analysis, we detected 385, 65, 80 and 144 bacterial strains in CM, RCM, SCM, and H
milk, respectively, with an inclusion of 67.19% previously unreported opportunistic strains in
mastitis milk metagenomes. The MR pipeline detected 56, 13, 9 and 46 archaeal, and 40, 24,
11 and 37 viral genera in CM, RCM, SCM and H-milk metagenomes, respectively. Of these,
12.06% archaeal and 20.83% viral genera found to be shared in CM, RCM, SCM, and H
metagenomes. Furthermore, we identified 333, 304, 183 and 50 VFGs, and 48, 31, 11 and 6
AGRs in CM, RCM, SCM, and H-microbiomes, respectively, showing a significant
correlation between the relative abundances of VFGs (P = 0.001, Pearson test), ARGs (P =
0.0001, Pearson test), and associated bacterial taxa.
We also detected correlated variations in the presence and abundance of several metabolic
functional genes related to bacterial colonization, proliferation, chemotaxis, motility and
invasion to mammary epithelial cells (P = 0.001, Kruskal–Wallis test) across these
metagenomes. Furthermore, genes coding for oxidative stress, immune-diseases, twocomponent
regulatory systems, regulation and cell signaling, virulence and pathogenicity,
phage integration and excision, biofilm-formation, and quorum-sensing also varied
significantly (P = 0.001, Kruskal–Wallis test) in different episodes of mastitis. In addition, we
found a significant association between the resistomes and microbiome composition of the
CM milk with no apparent association with cattle breeds, despite significant differences in
microbiome diversity among the breeds. The in vitro investigation revealed 76.2% of six
selected CM pathogens that are considered ―biofilm formers‖, and found to be highly
resistant to tetracycline, doxycycline, nalidixic acid, ampicillin, chloramphenicol while being
sensitive to five heavy metals (Cr, Co, Ni, Cu, Zn) at varying concentrations. In a separate
experiment, fecal microbiota transplantation (FMT) from mastitic cows to pregnant mice
resulted in visible mastitis symptoms in mice mammary glands as validated through
histopathologic changes in mammary glands and gut tissues, and microbiome
characterization. We also observed significant (P = 0.012, Kruskal–Wallis test) microbiome
dysbiosis between mastitis and healthy mice fecal samples after FMT. Therefore, profiling
the dynamics of microbiomes in different states of mastitis, concurrent VFGs, ARGs, and
genomic functional correlations contribute to developing microbiome-based diagnostics and
therapeutics for bovine mastitis, and carries significant implications on curtailing the
economic fallout from this disease. Furthermore, the cows-to-mouse FMT might shed new
light on rational selection of animal models to study and interpret host-tropism to interrogate
role of microbiota in this important economic disease of dairy industries. |
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