Cultivable Microbial Communities in Raw Cow Milk and Potential Transfers from Stables of Sixteen French Farms

Overview

Journal Int J Food Microbiol

Specialties Microbiology
Nutritional Sciences

Date 2011 Mar 25

PMID 21429612

Citations 50

Authors

Mallory Vacheyrou

Anne-Cecile Normand

Philippe Guyot

Carole Cassagne

Renaud Piarroux

Yvette Bouton

Affiliations

Soon will be listed here.

Abstract

The indigenous microflora in raw milk plays an important role in the diversity of cheese flavours and may protect against the growth of pathogens, but the sources of contamination and the factors that might affect the microbial communities in milk are not well known. The objectives of this study were to broaden knowledge of the microbial composition of milk and to assess microbial transfers from the stable to the milk. Air (collected in milking parlour and stable), dust (passively collected using plastic box), cow teat surface, and hay and milk samples were collected in 16 French farms with either stanchion barn or freestall barn configurations and plated on various culture media. Bacterial and fungal colonies were identified using phenotypic and DNA sequencing methods. Results showed that most of the fungal species and environmental bacteria found in the milk were also found in the stable and the milking parlour environments, indicating large microbial transfer from stable to milking parlour then to milk. However, milk from the stanchion barns were more contaminated than milk from freestall barns. Contrasting with other bacterial and fungal species, useful cheese-making bacteria--lactobacilli and PAB--were frequently identified in the milk and on the teat surface but were rarely found in other environments. In conclusion, milk contamination by the stable environment is considerable, even if it is lower in farms with a milking parlour. Besides this environmental contamination, the teat surface remains the main source of useful cheese-making bacteria.

Citing Articles

Mycotoxins in Cheese: Assessing Risks, Fungal Contaminants, and Control Strategies for Food Safety.

Aranda C, Rodriguez R, Fernandez-Baldo M, Duran P Foods. 2025; 14(3).

PMID: 39941944 PMC: 11816839. DOI: 10.3390/foods14030351.

Phylogenetic analysis of enterotoxin A gene in Iraqi breed cows with bovine mastitis: Implications for disease management.

Jawad A, Dagman S, Yaseen M, Al-Karagoly H Open Vet J. 2024; 14(7):1644-1657.

PMID: 39175982 PMC: 11338610. DOI: 10.5455/OVJ.2024.v14.i7.14.

A comprehensive, large-scale analysis of "terroir" cheese and milk microbiota reveals profiles strongly shaped by both geographical and human factors.

Irlinger F, Mariadassou M, Dugat-Bony E, Rue O, Neuveglise C, Renault P ISME Commun. 2024; 4(1):ycae095.

PMID: 39109360 PMC: 11301721. DOI: 10.1093/ismeco/ycae095.

Serial fermentation in milk generates functionally diverse community lineages with different degrees of structure stabilization.

Gapp C, Dijamentiuk A, Mangavel C, Callon C, Theil S, Revol-Junelles A mSystems. 2024; 9(8):e0044524.

PMID: 39041801 PMC: 11334471. DOI: 10.1128/msystems.00445-24.

One-Year Monitoring of Prevalence and Diversity of Dairy Propionic Acid Bacteria in Raw Milk by Means of Culture-Dependent and Culture-Independent Methods.

Bucher C, Burtscher J, Zitz U, Domig K Foods. 2024; 13(12).

PMID: 38928862 PMC: 11203294. DOI: 10.3390/foods13121921.