Pathogenic Microorganisms in the Environment of Sheep Slaughterhouse

Background: As critical nodes for zoonotic disease transmission, the microbial community composition in sheep slaughterhouse environments directly impacts meat safety and public health. While existing studies have focused on single-pathogen detection, there remains a lack of systematic understanding of the diversity, distribution patterns, and transmission risks of pathogenic microorganisms in complex environments. This study aims to elucidate the microbial community characteristics of mutton slaughterhouse environments using metagenomics approaches, with a focus on analyzing the ecological distribution of zoonotic pathogens and their potential threats. Materials, Methods & Results: A total of 12 environmental samples (n=3 per zone) were collected from a sheep slaughterhouse in Suzhou, Jiangsu Province, including slaughter workshop, slaughter tools, pre-slaughter holding area, and production wastewater. Samples were preserved in liquid nitrogen, and total DNA was extracted using the HiPure Stool DNA Kit. Paired-end sequencing (PE150) was performed on the Illumina HiSeq platform. Raw reads were quality-filtered (Cutadapt), and host-contaminant sequences removed (BWA). Clean reads were assembled with MEGAHIT, and unigenes predicted via Prodigal. Clustering by MMseq2 generated a non-redundant gene set, which was annotated against the NCBI NT database using Diamond to obtain taxonomic assignments. Species abundance was calculated at phylum, genus, and species levels, and principal component analysis (PCA) assessed variation between zones. At the phylum level, microbial communities were dominated by Proteobacteria (31.39% - 75%), Firmicutes (11.89% - 43.66%), Bacteroidota (9.15% -41.61%), and Actinobacteria (3% - 14.69%), with significant clustering by functional zones. Genus-level analysis revealed Chryseobacterium, Comamonas, Acinetobacter, Psychrobacter, and Prevotella as top taxa across samples. Species-level profiling detected 6 categories of zoonotic pathogens, notably Staphylococcus aureus (7.07% relative abundance in slaughter tools), Mycobacteroides abscessus (3.56% in slaughter workshop), Vibrio cholerae, and Klebsiella pneumoniae. Slaughter tools harbored the highest pathogen load; Lactococcus garvieae accounted for 10.39%. Production wastewater contained elevated levels of aquatic pathogens, suggesting environmental dissemination risks. An upset plot showed 116 species shared across all samples, with unique species counts ranging from 88 to 505 per sample. Discussion: This study elucidates the ecological niches of drug-resistant and opportunistic pathogens in a sheep slaughterhouse, identifying production wastewater and slaughter tools as high-risk contamination sources. High abundances of Staphylococcus aureus and Mycobacteroides abscessus underscore occupational exposure risks for abattoir workers, while detection of Vibrio cholerae highlights vulnerabilities in wastewater treatment and potential for zoonotic outbreaks. The prevalence of biofilm-forming Firmicutes on tools indicates that conventional disinfectants may be insufficient. Horizontal transfer of antibiotic resistance genes among dominant phyla could exacerbate public health threats. We recommend implementing targeted disinfection protocols, routine metagenomic monitoring for early pathogen detection, stricter PPE use and worker training, and optimization of wastewater pH control. Future studies should expand geographic sampling and integrate functional metagenomics to unravel resistance mechanisms and cross-species gene flow. These strategies will strengthen slaughterhouse biosafety and mitigate zoonotic disease transmission. Keywords: sheep slaughterhouse, public health, environment microbiology, zoonoses, pathogens, metagenomics.