Milk-derived Mammary Epithelial Cells As Non-invasive Source to Define Stage-specific Abundance of Milk Protein and Fat Synthesis Transcripts in Native Sahiwal Cows and Murrah Buffaloes

Overview

Journal 3 Biotech

Publisher Springer

Specialty Biotechnology

Date 2019 Mar 14

PMID 30863690

Citations 5

Authors

Ankita Sharma

Umesh K Shandilya

Monika Sodhi

Pradeep Jatav

Ashok Mohanty

Pranay Jain

Preeti Verma

R S Kataria

Parvesh Kumari

Manishi Mukesh

Affiliations

Soon will be listed here.

Abstract

The molecular physiology of milk production of two important dairy species; Sahiwal cows () and Murrah buffaloes () are not fully understood due to constraints in obtaining mammary tissue samples because of sacred and ethical reasons. The present study suggests the use of milk-derived mammary epithelial cells (MECs) as a non-invasive method to understand molecular aspects of lactation biology in dairy animals. A total of 76 MECs were collected from five different lactation periods viz. colostrum (0-2), early (5-20), peak (30-50), mid (90-140) and late lactation (> 215 days) stages from Sahiwal cows and Murrah buffaloes to study the transcription kinetics of milk protein, fat synthesis, and their regulatory genes. Significant changes were observed in milk composition of both dairy species with lactation stages. High mRNA abundance of all milk protein and fat synthesis genes was observed in MECs of Murrah buffaloes as compared to Sahiwal cows. The mRNA abundance of caseins (, and ) and whey protein () were higher in early lactation stage. Similarly, the expression of milk fat synthesis genes () was also high in early lactation stage. The relative abundance of 4 regulatory genes ( and ) remained high during early lactation indicating their regulatory roles in lactogenesis process. Overall, results suggested a significant effect of lactation stages on milk composition and transcription abundance of milk protein and fat synthesis genes. The present study establishes the fact that milk-derived MECs could be utilized as a valuable source to understand mammary gland functioning of native cows and buffaloes.

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