论文信息 - The Core and Seasonal Microbiota of Raw Bovine Milk in Tanker Trucks and the Impact of Transfer to a Milk Processing Facility

The Core and Seasonal Microbiota of Raw Bovine Milk in Tanker Trucks and the Impact of Transfer to a Milk Processing Facility

ABSTRACT Currently, the bacterial composition of raw milk in tanker trucks and the outcomes of transfer and storage of that milk at commercial processing facilities are not well understood. We set out to identify the bacteria in raw milk collected for large-scale dairy product manufacturing. Raw bovine milk samples from 899 tanker trucks arriving at two dairy processors in San Joaquin Valley of California during three seasons (spring, summer, and fall) were analyzed by community 16S rRNA gene sequencing. This analysis revealed highly diverse bacterial populations, which exhibited seasonal differences. Raw milk collected in the spring contained the most diverse bacterial communities, with the highest total cell numbers and highest proportions being those of Actinobacteria. Even with this complexity, a core microbiota was present, consisting of 29 taxonomic groups and high proportions of Streptococcus and Staphylococcus and unidentified members of Clostridiales. Milk samples were also collected from five large-volume silos and from 13 to 25 tankers whose contents were unloaded into each of them during 2 days in the summer. Transfer of the milk to storage silos resulted in two community types. One group of silos contained a high proportion of Streptococcus spp. and was similar in that respect to the tankers that filled them. The community found in the other group of silos was distinct and dominated by Acinetobacter. Overall, despite highly diverse tanker milk community structures, distinct milk bacterial communities were selected within the processing facility environment. This knowledge can inform the development of new sanitation procedures and process controls to ensure the consistent production of safe and high-quality dairy products on a global scale. IMPORTANCE Raw milk harbors diverse bacteria that are crucial determinants of the quality and safety of fluid milk and (fermented) dairy products. These bacteria enter farm milk during transport, storage, and processing. Although pathogens are destroyed by pasteurization, not all bacteria and their associated enzymes are eliminated. Our comprehensive analyses of the bacterial composition of raw milk upon arrival and shortly after storage at major dairy processors showed that the communities of milk microbiota are highly diverse. Even with these differences, there was a core microbiota that exhibited distinct seasonal trends. Remarkably, the effects of the processing facility outweighed those of the raw milk microbiome and the microbial composition changed distinctly within some but not all silos within a short time after transfer. This knowledge can be used to inform cleaning and sanitation procedures as well as to enable predictions of the microbial communities in raw milk that result in either high-quality or defective products. Raw milk harbors diverse bacteria that are crucial determinants of the quality and safety of fluid milk and (fermented) dairy products. These bacteria enter farm milk during transport, storage, and processing. Although pathogens are destroyed by pasteurization, not all bacteria and their associated enzymes are eliminated. Our comprehensive analyses of the bacterial composition of raw milk upon arrival and shortly after storage at major dairy processors showed that the communities of milk microbiota are highly diverse. Even with these differences, there was a core microbiota that exhibited distinct seasonal trends. Remarkably, the effects of the processing facility outweighed those of the raw milk microbiome and the microbial composition changed distinctly within some but not all silos within a short time after transfer. This knowledge can be used to inform cleaning and sanitation procedures as well as to enable predictions of the microbial communities in raw milk that result in either high-quality or defective products.

[1] Rob Knight,et al. PyNAST: a flexible tool for aligning sequences to a template alignment , 2009, Bioinform..

[2] M. Heyndrickx,et al. Pseudomonas spp. and Serratia liquefaciens as Predominant Spoilers in Cold Raw Milk. , 2015, Journal of food science.

[3] Timothy L. Tickle,et al. Dysfunction of the intestinal microbiome in inflammatory bowel disease and treatment , 2012, Genome Biology.

[4] C. Delbès,et al. Monitoring Bacterial Communities in Raw Milk and Cheese by Culture-Dependent and -Independent 16S rRNA Gene-Based Analyses , 2007, Applied and Environmental Microbiology.

[5] C. Hill,et al. The Prevalence and Control of Bacillus and Related Spore-Forming Bacteria in the Dairy Industry , 2015, Front. Microbiol..

[6] F. Devlieghere,et al. Psychrotrophic lactic acid bacteria associated with production batch recalls and sporadic cases of early spoilage in Belgium between 2010 and 2014. , 2014, International journal of food microbiology.

[7] C. J. Washam,et al. Heat-Resistant Psychrotrophic Bacteria Isolated from Pasteurized Milk. , 1977, Journal of food protection.

[8] Timothy L. Tickle,et al. Associations between host gene expression, the mucosal microbiome, and clinical outcome in the pelvic pouch of patients with inflammatory bowel disease , 2015, Genome Biology.

[9] S. Makino,et al. Seasonal and Growth-Dependent Dynamics of Bacterial Community in Radish Sprouts , 2016 .

[10] M. Marco,et al. Season, Irrigation, Leaf Age, and Escherichia coli Inoculation Influence the Bacterial Diversity in the Lettuce Phyllosphere , 2013, PloS one.

[11] A. La Storia,et al. Impact of Nisin-Activated Packaging on Microbiota of Beef Burgers during Storage , 2015, Applied and Environmental Microbiology.

[12] Robert C. Edgar,et al. BIOINFORMATICS APPLICATIONS NOTE , 2001 .

[13] E. Smit,et al. Diversity and Seasonal Fluctuations of the Dominant Members of the Bacterial Soil Community in a Wheat Field as Determined by Cultivation and Molecular Methods , 2001, Applied and Environmental Microbiology.

[14] H. Stryhn,et al. The effect of season on somatic cell count and the incidence of clinical mastitis. , 2007, Journal of dairy science.

[15] L. Meunier-Goddik,et al. Effect of commercial hauling practices and tanker cleaning treatments on raw milk microbiological quality. , 2015, Journal of dairy science.

[16] Zoraida P. Aguilar,et al. Propidium monoazide combined with real-time PCR for selective detection of viable Staphylococcus aureus in milk powder and meat products. , 2015, Journal of dairy science.

[17] P. Saris,et al. Inhibition of Staphylococcus aureus by the commensal bacteria of human milk , 2003, Journal of applied microbiology.

[18] P. de Vos,et al. Comparative analysis of the diversity of aerobic spore-forming bacteria in raw milk from organic and conventional dairy farms. , 2008, Systematic and applied microbiology.

[19] Orla O'Sullivan,et al. The complex microbiota of raw milk. , 2013, FEMS microbiology reviews.

[20] D. Zak,et al. Dispersal limitation and the assembly of soil Actinobacteria communities in a long-term chronosequence , 2012, Ecology and evolution.

[21] T. McMahon,et al. Updated world map of the Köppen-Geiger climate classification , 2007 .

[22] N. Fierer,et al. Bacterial Communities Associated with the Surfaces of Fresh Fruits and Vegetables , 2013, PloS one.

[23] R. Marshall,et al. Microbiological Spoilage of Dairy Products , 2009 .

[24] J. Lejeune,et al. Food safety: unpasteurized milk: a continued public health threat. , 2009, Clinical infectious diseases : an official publication of the Infectious Diseases Society of America.

[25] E. Zoetendal,et al. Cultivation-independent assessment of the bacterial diversity of breast milk among healthy women. , 2007, Research in microbiology.

[26] M. Vieira,et al. Characterization of Contaminants from a Sanitized Milk Processing Plant , 2012, PloS one.

[27] F. Villani,et al. Changes in the Spoilage-Related Microbiota of Beef during Refrigerated Storage under Different Packaging Conditions , 2006, Applied and Environmental Microbiology.

[28] T. Nagaraja,et al. Board-invited review: Rumen microbiology: leading the way in microbial ecology. , 2013, Journal of animal science.

[29] M. Cousin. Presence and Activity of Psychrotrophic Microorganisms in Milk and Dairy Products: A Review 1. , 1982, Journal of food protection.

[30] G. Enne,et al. Investigating the relationship between raw milk bacterial composition, as described by intergenic transcribed spacer–PCR fingerprinting, and pasture altitude , 2009, Journal of applied microbiology.

[31] B. Roe,et al. A core gut microbiome in obese and lean twins , 2008, Nature.

[32] R. Harmon,et al. Isolation and identification of coagulase-negative Staphylococcus species from bovine body sites and streak canals of nulliparous heifers. , 1989, Journal of dairy science.

[33] K. Kalanetra,et al. Analysis of raw goat milk microbiota: impact of stage of lactation and lysozyme on microbial diversity. , 2015, Food microbiology.

[34] G. Djira,et al. Prevalence of thermoduric bacteria and spores on 10 Midwest dairy farms. , 2014, Journal of dairy science.

[35] Cheng Li,et al. Adjusting batch effects in microarray expression data using empirical Bayes methods. , 2007, Biostatistics.

[36] R. Knight,et al. Baseline survey of the anatomical microbial ecology of an important food plant: Solanum lycopersicum (tomato) , 2013, BMC Microbiology.