TY - JOUR
T1 - Correlations of milk and serum element concentrations with production and management traits in dairy cows
AU - Denholm, S J
AU - McNeilly, T N
AU - Bashir, S
AU - Mitchell, M C
AU - Wall, E
AU - Sneddon, A A
PY - 2022/12
Y1 - 2022/12
N2 - The present study investigated the potential consequences, positive or negative, that selection for favorable production-related traits may have on concentrations of vitamin B
12 and key chemical elements in dairy cow milk and serum and the possible impact on milk healthiness, and associated benefits, for the dairy product consumer. Milk and serum samples (950 and 755, respectively) were collected from Holstein-Friesian dairy cows (n = 479) on 19 occasions over a 59-mo period, generating 34,258 individual records, and analyzed for concentrations of key trace and quantity elements, heavy metals, and milk vitamin B
12. These data were then matched to economically important production data (milk, fat, and protein yield) and management data (dry matter intake, liveweight, and body condition score). Multivariate animal models, including full pedigree information, were used to analyze data and investigate relationships between traits of interest. Results highlighted negative genetic correlations between many quantity and trace elements in both milk and serum with production and management traits. Milk yield was strongly negatively correlated with the milk quantity elements Mg and Ca (genetic correlation between traits, r
a = −0.58 and −0.63, respectively) as well as the trace elements Mn, Fe, Ni, Cu, Zn, and Mo (r
a = −0.32, −0.58, −0.52, −0.40, −0.34, and −0.96, respectively); and in serum, Mg, Ca, Co, Fe, and Zn (r
a = −0.50, −0.36, −0.68, −0.54, and −0.90, respectively). Strong genetic correlations were noted between dry matter intake with V (r
a = 0.97), Fe (r
a = −0.69), Ni (r
a = −0.81), and Zn (r
a = −0.75), and in serum, strong negative genetic correlations were observed between dry matter intake with Ca and Se (r
a = −0.95 and −0.88, respectively). Body condition score was negatively correlated with serum P, Cu, Se, and Pb (r
a = −0.45, −0.35, −0.51, and −0.64, respectively) and positively correlated with Mn, Fe, and Zn (r
a = 0.40, 0.71, and 0.55, respectively). Our results suggest that breeding strategies aimed at improving economically important production-related traits would most likely result in a negative impact on levels of beneficial nutrients within milk for human consumption (such as Mg, Ca, Fe, Zn, and Se).
AB - The present study investigated the potential consequences, positive or negative, that selection for favorable production-related traits may have on concentrations of vitamin B
12 and key chemical elements in dairy cow milk and serum and the possible impact on milk healthiness, and associated benefits, for the dairy product consumer. Milk and serum samples (950 and 755, respectively) were collected from Holstein-Friesian dairy cows (n = 479) on 19 occasions over a 59-mo period, generating 34,258 individual records, and analyzed for concentrations of key trace and quantity elements, heavy metals, and milk vitamin B
12. These data were then matched to economically important production data (milk, fat, and protein yield) and management data (dry matter intake, liveweight, and body condition score). Multivariate animal models, including full pedigree information, were used to analyze data and investigate relationships between traits of interest. Results highlighted negative genetic correlations between many quantity and trace elements in both milk and serum with production and management traits. Milk yield was strongly negatively correlated with the milk quantity elements Mg and Ca (genetic correlation between traits, r
a = −0.58 and −0.63, respectively) as well as the trace elements Mn, Fe, Ni, Cu, Zn, and Mo (r
a = −0.32, −0.58, −0.52, −0.40, −0.34, and −0.96, respectively); and in serum, Mg, Ca, Co, Fe, and Zn (r
a = −0.50, −0.36, −0.68, −0.54, and −0.90, respectively). Strong genetic correlations were noted between dry matter intake with V (r
a = 0.97), Fe (r
a = −0.69), Ni (r
a = −0.81), and Zn (r
a = −0.75), and in serum, strong negative genetic correlations were observed between dry matter intake with Ca and Se (r
a = −0.95 and −0.88, respectively). Body condition score was negatively correlated with serum P, Cu, Se, and Pb (r
a = −0.45, −0.35, −0.51, and −0.64, respectively) and positively correlated with Mn, Fe, and Zn (r
a = 0.40, 0.71, and 0.55, respectively). Our results suggest that breeding strategies aimed at improving economically important production-related traits would most likely result in a negative impact on levels of beneficial nutrients within milk for human consumption (such as Mg, Ca, Fe, Zn, and Se).
KW - micronutrient
KW - production
KW - heavy metal
KW - management data
KW - dairy cow
UR - http://www.scopus.com/inward/record.url?scp=85140223358&partnerID=8YFLogxK
U2 - 10.3168/jds.2021-20521
DO - 10.3168/jds.2021-20521
M3 - Article
C2 - 36207186
SN - 0022-0302
VL - 105
SP - 9726
EP - 9737
JO - Journal of Dairy Science
JF - Journal of Dairy Science
IS - 12
ER -