A.E. Freeman

Study of immunological dysfunction in periparturient Holstein cattle selected for high and average milk production

Data from twenty assays of traits associated with innate and adaptive immunity were evaluated from 137 periparturient Holstein cows. These cows had been selected through planned matings for four different levels of milk production (high and average pounds of milk, and high and average pounds of milk fat plus protein). For up to seven generations, the genetic lines were produced by mating females of each line to sires of corresponding merit. With the exceptions of neutrophil ingestion of Staphylococcus aureus and directed migration, all assays measuring neutrophil functions were depressed beginning 2 to 3 weeks before calving through 3 weeks after calving. Serum concentrations of immunoglobulin G1 decreased while those of immunoglobulin G2 increased around calving time. Serum complement and conglutinin concentrations decreased before calving and reached a minimum around calving time. Cows selected for high milk production (pounds of milk and pounds of milk fat plus proteins) had significantly higher (P < 0.10) numbers of circulating neutrophils and mononuclear cells, had higher (P < 0.10) neutrophil resting chemiluminescence and higher (P < 0.10) neutrophil directed migration than cows with average production potentials. There were significant (P < 0.001) sire progeny group differences for most traits associated with the immune system that we tested. These results can be considered encouraging, in that selection for high milk yield did not produce unfavorable correlated responses in the functional capacity of immune function traits, and that there is sufficient genetic variation in these immunological traits among sires of high genetic merit for milk production to potentially improve the immunocompetence of periparturient cows through planned mating experiments.

The effect of mitochondrial DNA on milk production and health of dairy cattle

Maternal lineage effects, probably indicative of mitochondrial DNA (mtDNA) differences, may be important for milk production and reproductive success in dairy cattle (Bos taurus). Sequence variation of mtDNA in 36 maternal lineages of dairy cattle was studied with animal models to assess effects on milk production and reproductive traits. Cattle within maternal lineages defined by registered pedigrees were assumed to be uniform for the nucleotide sequences examined. Sequence polymorphisms of bovine mtDNA were shown to be associated with milk production, reproduction, and health costs incurred. One particular base-pair substitution was associated with additional production of 842 kg milk and 37 kg milk fat per cow per lactation. Another single base-pair substitution was associated with a decrease of 36 days and one unsuccessful breeding between successive calvings. Effects of this size are economically important and have broad implications in genetic selection of dairy cattle.

Pregnancy-associated glycoprotein and decreased polymorphonuclear leukocyte function in early post-partum dairy cows

Phagocytosis and oxidative burst activity of polymorphonuclear neutrophil leukocytes (PMN) isolated from blood and pregnancy-associated glycoprotein (bPAG) concentrations in plasma were evaluated in two longitudinal studies in dairy cows from 3 weeks before until 5 weeks after calving, carried out in the United States and in Europe. Ingestion of Staphylococcus aureus by blood PMN increased during the first week after calving and normalised 3 weeks post-partum. Phagocytosis of Escherichia coli did not change in the early post-partum period. In both studies, a significant decrease in oxidative burst activity of PMN was observed between 1 and 3 weeks after calving. In all cows, a very significant increase in plasma bPAG concentration was found between 1 week before and 2 weeks after calving. The peak of bPAG concentration in plasma immediately preceded the alterations of blood PMN functions. These results suggest that bPAG may be associated with inhibition of PMN function of dairy cows during the early post-partum period.

Cytoplasmic and mitochondrial inheritance of economic traits in cattle

Abstract Bovine mitochondria contain a 16338 nucleotide closed loop of DNA coding for 13 translated genes, 22 tRNA and 2 rRNA and is inherited exclusively through the maternal line, providing a genetic mechanism for cytoplasmic inheritance. Several early analyses of cattle populations indicating significant cytoplasmic variance in production traits were criticized on statistical grounds. Analysis under an animal model has revealed significant effects on milk fat concentration in two studies with Holsteins, but not in two other studies and no significant effects were found for growth and lactation traits in two beef cattle studies. Studies relating dairy performance to mitochondrial nucleotide variation across previously analyzed mitochondrial lineages found significant associations, but do not provide an independent test of mitochondrial effects. In a separate population no associations were found. The evidence is broadly consistent with 0 to 5% of variation in performance due to cytoplasmic effects, with the weight of evidence pointing to the low end of this range. If at the upper end of this range, however, cytoplasmic effects could be of practical importance.

Associations among individual proteins and fatty acids in bovine milk as determined by correlations and factor analyses

Associations among quantities and concentrations of individual milk proteins and fatty acids were determined in individual milk samples from 233 Holstein cows. Correlation coefficients among the six major proteins and the eleven major fatty acids in bovine milk were grouped hierarchically. Factor analyses grouped the milk components into seven families: fatty acids 4:0-6:0, 6:0-16:0, 16:0, 18:0, 16:1 plus 18:1 plus 18:2, all milk proteins and beta-lactoglobulin alone. Correlation coefficients and groupings by factor analyses coincided with shared pathways of synthesis or genetic origins of milk proteins and fatty acids because they are the basis of the correlation coefficients. Hence, the results from correlations and factor analyses could be used to develop hypotheses for the synthesis of milk components and other coordinately regulated physiological processes.

Genetic Variation in Bovine Neutrophil Sensitivity to Glucocorticoid Challenge

Blood neutrophils use CD62L and CD18 adhesion molecules to contact and migrate rapidly through blood vessels in defense against infections in underlying tissues. Previous work showed that glucocorticoid hormones repress expression of CD62L and CD18, causing neutrophilia and increased mastitis susceptibility in dairy cows. The aim of this study was to determine whether bovine neutrophil sensitivity to glucocorticoids exhibits genetic variability. Test animals included 60 pedigreed Holstein bulls treated on 3 consecutive days with a synthetic glucocorticoid (dexamethasone) and five untreated control bulls. Five indicator traits of neutrophil glucocorticoid sensitivity were monitored, including circulating neutrophil counts and two measures on each of CD62L and CD18 expression. Random regression models with treatment-specific serial correlation were used to estimate genetic and non-genetic sources of variation before, during and after glucocorticoid administration. Significant genetic variation was observed for neutrophil CD18 expression, with longitudinal heritability estimates ranging from 0.10 to 0.54 and influenced by dexamethasone. Significant genetic variation was also observed for blood neutrophil counts (heritability estimates ranging from 0.11 to 0.24) but was not influenced by dexamethasone administration. Estimated genetic correlations between circulating neutrophil counts and various indicators of CD62L and CD18 expression were large and negative (-0.44 to - 0.78). These results imply significant genetic variability and pleiotropic effects for neutrophil traits that are important for stress-induced disease susceptibility in dairy cattle and might be exploited by genetic selection.

Genetic control of disease resistance and immunoresponsiveness.

A great deal of evidence points to substantial genetic control over at least some of the immune responses, although genetic parameters for clinical disease have been less favorable. The past two decades have illustrated that single genes with a large impact on food animal health do exist and can be used to improve the health of domestic populations. The current focus on molecular genetics within food animal species will likely unveil numerous other examples of single genes with large effects, although the use of animals possessing favorable genotypes for disease resistance may represent a compromise in selection for increased production of raw product. Moreover, it is also clear that genetic control over the immune system is not limited to a few genes but is more likely influenced by many genes, each with small effects. The use of this information in animal improvement programs is not straightforward because of factors complicating the identification of superior individuals within the population. The scarcity of information dealing with phenotypic and genetic relationships between measures of disease resistance and aspects of immune response complicates the situation even further. Despite these potential hurdles, the potential for permanent improvement of disease resistance within food animal species in the future is tantalizing and merits intensified future study.

A rapid method for computing the inverse of the gametic covariance matrix between relatives for a marked Quantitative Trait Locus

The inverse of the gametic covariance matrix between relatives, G-1, for a marked quantitative trait locus (QTL) is required in best linear unbiased prediction (BLUP) of breeding values if marker data are available on a QTL. A rapid method for computing the inverse of a gametic relationship matrix for a marked QTL without building G itself is presented. The algorithm is particularly useful due to the approach taken in computing inbreeding coefficients by having to compute only few elements of G. Numerical techniques for determining, storing, and computing the required elements of G and the nonzero elements of the inverse are discussed. We show that the subset of G required for computing the inbreeding coefficients and hence the inverse is a tiny proportion of the whole matrix and can be easily stored in computer memory using sparse matrix storage techniques. We also introduce an algorithm to determine the maximum set of nonzero elements that can be found in G-1 and a strategy to efficiently store and access them. Finally, we demonstrate that the inverse can be efficiently built using the present techniques for very large and inbred populations.

Management traits in dairy cattle. dystocia, udder characteristics related to production, and a review of other traits☆

Abstract The purpose of this paper is to present a short summary of our research on dystocia in Holsteins and a review of management trait information in North America. Primary selection emphasis should be on milk production and milk constituents. Management traits contributing to ease or economy of production should be selected only if economic importance and phenotypic and genetic relationships to productive traits justify such selection. Breeding efficiency is economically important; but, genetic improvement within breeds is difficult. Evidence indicates dystocia can be minimized by selecting sires for production, evaluating them for ease of calving, mating heifers to sires whose offspring are born easily without direct selection against dystocia. Selection against mastitis might be effective, but management practices can reduce the incidence of mastitis. Selection for udder and leg structure may be necessary in order to avoid problems concerning economical food production. Speed of milking has economic importance and it responds to selection. The amount of emphasis for the selection of milking speed and the most efficient way to apply this has not been clarified. Additional study of the genetics of body-weight change is necessary in order to maximize feed conversion. Genetic control of metabolic disorders is not now feasible; management control is necessary. Dairymen desire amenable cows, but heritability estimates for this trait are low. Measures of temperament need improvement. The economic worth of all management traits should be further quantified.