Changes in plasma electrolytes, minerals, and hepatic markers of health across the transition period in dairy cows divergent in genetic merit for fertility traits and postpartum anovulatory intervals.

Peripartum metabolism and subsequent reproductive performance of dairy cows are linked, with maladaptation over the transition period associated with poor reproductive success. A herd of seasonal calving, grazing dairy cows was established that differed in their genetic merit for fertility traits. The heifers were produced by a customized mating program to achieve a 10-percentage point divergence in the New Zealand fertility breeding value (FertBV) as follows: +5 FertBV (POS) versus -5% FertBV (NEG), while also limiting divergence in other breeding values, including body weight, body condition score, and milk production. In this study, we aimed to characterize differences in metabolic, mineral, and metabolic stress marker profiles during their first postpartum transition period as primiparous heifers and to examine if animals with longer postpartum anestrous intervals (PPAI; more than 66 d compared with less than 35 d) had greater metabolic dysfunction. Blood was sampled at -21, -14, -7, 0, 4, 7, 10, 14, 17, 21, 28, and 35 d relative to calving in 455 primiparous cows and plasma analyzed. The NEG cows had lower concentrations of both plasma nonesterified fatty acids and β-hydroxybutyrate at d 7 compared with POS cows. Detailed temporal profiling of various metabolic, mineral, and metabolic stress markers was undertaken in a subset of cows (n = 70). Cows were selected retrospectively to create 4 groups in a 2 × 2 factorial design with either a POS or NEG FertBV and either a short (19-35 d) or long (66-131 d) PPAI. The NEG cows tended, on average, to have lower nonesterified fatty acids and β-hydroxybutyrate concentrations compared with POS cows across the transition period. Mean body weight and body condition score was greatest in NEG cows when compared with the POS cows and an interaction with day demonstrated this only occurred precalving. They also had indications of improved liver health precalving, with higher albumin-to-globulin ratios and lower bilirubin concentrations. Concentrations of aspartate aminotransferase were lower, and the Na-to-Cl ratio was greater in cows with a long versus a short PPAI at d 28 and d 35 after calving, potentially because of cows with a short PPAI (19-35 d) returning to estrous during this time. Magnesium concentrations were lower in NEG cows with a short PPAI from d 21 onwards, indicating NEG cows may metabolically respond to estrous differently than POS cows. The NEG-long PPAI cows had greater gamma-glutamyl transferase concentrations from calving until d 28 and lower bilirubin concentrations throughout the transition period. Together, the results demonstrate significant effects of FertBV on peripartum metabolic status. However, most of the markers tested returned to reference intervals within 4 d after calving or remained within those intervals for the whole transition period, indicating relatively minor biological effects of FertBV on transition period adaptation. The profound differences in reproductive performance among the groups was not explained by underlying differences in metabolic responses during the transition period.

[1]  B. Kuhn-Sherlock,et al.  Positive genetic merit for fertility traits is associated with superior reproductive performance in pasture-based dairy cows with seasonal calving. , 2021, Journal of dairy science.

[2]  K. Dodds,et al.  Heifers with positive genetic merit for fertility traits reach puberty earlier and have a greater pregnancy rate than heifers with negative genetic merit for fertility traits. , 2021, Journal of dairy science.

[3]  F. Peñagaricano,et al.  Genomic merit for reproductive traits. II: Physiological responses of Holstein heifers. , 2019, Journal of dairy science.

[4]  F. Peñagaricano,et al.  Genomic merit for reproductive traits. I: Estrous characteristics and fertility in Holstein heifers. , 2019, Journal of dairy science.

[5]  S. Paltrinieri,et al.  Reference intervals for hematological and biochemical parameters, acute phase proteins and markers of oxidation in Holstein dairy cows around 3 and 30days after calving. , 2017, Research in veterinary science.

[6]  A. Kumaresan,et al.  Evaluation of salivary electrolytes during estrous cycle in Murrah buffaloes with reference to estrus detection , 2016, Veterinary world.

[7]  R. Ventura,et al.  Metabolic blood profile of beef heifers during oestrous and non-oestrous states. , 2016, Reproduction in domestic animals = Zuchthygiene.

[8]  A. Miyamoto,et al.  Influence of hepatic load from far-off dry period to early postpartum period on the first postpartum ovulation and accompanying subsequent fertility in dairy cows , 2016, The Journal of reproduction and development.

[9]  J. Jeong,et al.  Relationship between serum metabolites, body condition, peri- and postpartum health and resumption of postpartum cyclicity in dairy cows , 2015 .

[10]  J. Loor,et al.  Body condition score at calving affects systemic and hepatic transcriptome indicators of inflammation and nutrient metabolism in grazing dairy cows. , 2015, Journal of dairy science.

[11]  M. Crowe,et al.  Risk factors that affect reproductive target achievement in fertile dairy cows. , 2014, Journal of dairy science.

[12]  P. Lonergan,et al.  Genetic merit for fertility traits in Holstein cows: IV. Transition period, uterine health, and resumption of cyclicity. , 2014, Journal of dairy science.

[13]  Ayo,et al.  Effect of oestrous cycle on serum electrolytes and liver enzymes in Red Sokoto goats , 2013 .

[14]  J. Loor,et al.  Calving body condition score affects indicators of health in grazing dairy cows. , 2013, Journal of dairy science.

[15]  A. Khaki,et al.  Calcium and magnesium concentrations in uterine fluid and blood serum during the estrous cycle in the bovine , 2012, Veterinary research forum : an international quarterly journal.

[16]  P. Bossaert,et al.  The association between indicators of inflammation and liver variables during the transition period in high-yielding dairy cows: an observational study. , 2012, Veterinary journal.

[17]  P. Lonergan,et al.  Genetic merit for fertility traits in Holstein cows: I. Production characteristics and reproductive efficiency in a pasture-based system. , 2012, Journal of dairy science.

[18]  G. Piccione,et al.  Pattern of serum protein fractions in dairy cows during different stages of gestation and lactation. , 2011, The Journal of dairy research.

[19]  G. Cozzi,et al.  Short communication: reference values for blood parameters in Holstein dairy cows: effects of parity, stage of lactation, and season of production. , 2011, Journal of dairy science.

[20]  M. Mitchell,et al.  Relationships between endometritis and metabolic state during the transition period in pasture-grazed dairy cows. , 2010, Journal of dairy science.

[21]  D. Nydam,et al.  Associations of elevated nonesterified fatty acids and beta-hydroxybutyrate concentrations with early lactation reproductive performance and milk production in transition dairy cattle in the northeastern United States. , 2010, Journal of dairy science.

[22]  D. Kenny,et al.  Differences in the expression of genes involved in the somatotropic axis in divergent strains of Holstein-Friesian dairy cows during early and mid lactation. , 2009, Journal of dairy science.

[23]  H. Rutigliano,et al.  Risk factors for resumption of postpartum estrous cycles and embryonic survival in lactating dairy cows. , 2009, Animal reproduction science.

[24]  M. Lucy,et al.  Somatotropic axis components and nutrient partitioning in genetically diverse dairy cows managed under different feed allowances in a pasture system. , 2009, Journal of dairy science.

[25]  J. Murphy,et al.  Influence of negative energy balance on cyclicity and fertility in the high producing dairy cow. , 2007, Theriogenology.

[26]  D. Berry,et al.  A comparison of three strains of Holstein-Friesian cows grazed on pasture: growth, development, and puberty. , 2007, Journal of dairy science.

[27]  D. Berry,et al.  Relationships among body condition score, body weight, and milk production variables in pasture-based dairy cows. , 2007, Journal of dairy science.

[28]  D. Kelton,et al.  The effect of subclinical ketosis in early lactation on reproductive performance of postpartum dairy cows. , 2007, Journal of dairy science.

[29]  D. Berry,et al.  Holstein-Friesian strain and feed effects on milk production, body weight, and body condition score profiles in grazing dairy cows. , 2006, Journal of dairy science.

[30]  J R Roche,et al.  Relationships among international body condition scoring systems. , 2004, Journal of dairy science.

[31]  P. Chilibroste,et al.  Effects of parity and body condition at parturition on endocrine and reproductive parameters of the cow. , 2004, Reproduction.

[32]  I. Lean,et al.  Factors influencing fertility of Holstein dairy cows: a multivariate description. , 2002, Journal of dairy science.

[33]  A. Kruif,et al.  Risk factors for post partum ovarian dysfunction in high producing dairy cows in Belgium: a field study. , 2000, Theriogenology.

[34]  J. Woolliams,et al.  The phenotypic association between the interval to post-partum ovulation and traditional measures of fertility in dairy cattle , 1997 .

[35]  W. R. Butler,et al.  Relationships between energy balance and post-partum ovarian activity and fertility in first lactation dairy cows , 1996 .

[36]  D. R. Barnes,et al.  Detecting estrus in synchronized heifers-using tailpaint and an aerosol raddle. , 1988, Theriogenology.

[37]  J. Roussel,et al.  Changes of aldosterone in blood serum of dairy cattle during estrous cycle. , 1983, Journal of dairy science.