S. R. Davis scite author profile

The physiology of growth hormone and the insulin-like growth factors are reviewed with particular reference to the dairy industry. Growth hormone secretion in the ruminant is pulsatile in nature and nutritional factors have a major impact on its secretion. Isolation of growth hormone-releasing factor has allowed further progress in understanding the mechanisms underlying growth hormone release. The receptors appear to be under active endocrine and metabolic control, and nutritional influences on the somatotropic axis are in large part mediated through changes in somatotropic receptors. The mode of action of growth hormone to induce acute metabolic affects and lipolysis remains to be resolved, but there is increasing evidence that its anabolic actions are mediated by the insulin-like growth factors. Recent studies of measurement of insulin-like growth factor-1 and -2 in the ruminant and the role of growth hormone, nutrition, insulin, and sex steroids in their regulation are reviewed. The relative role of the two factors and the multiple forms of their receptors remain to be resolved. It is well-documented that growth hormone is galactopoietic. The evidence that this effect is largely due to enhanced nutrient supply to the mammary gland is not convincing. Effects of growth hormone are indirect and may be mediated by the insulin-like growth factors. The potential is considerable for manipulating the growth hormone insulin-like growth factor axis to enhance lactation.

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Mammary Blood Flow and Regulation of Substrate Supply for Milk Synthesis

Davis¹,

Collier²

1985

Journal of Dairy Science

124

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In ruminants, mammary supply of substrate varies with rate of mammary blood flow and concentrations of blood substrates. Blood concentrations of most mammary substrates, except acetate and tryptophan, do not vary greatly with feed intake, short term. Fasting reduces mammary blood flow, whereas milking and injection of growth hormone or thyroxine increase flow. It is proposed that the fraction of cardiac output that perfuses the udder of lactating ruminants plays a role in regulation of nutrient partitioning between milk and body tissues. In fed animals this fraction is 15 to 16% of cardiac output, which declines on fasting to 8 to 9% and increases slightly following growth hormone treatment to 17.6%. Following realimentation of fasted cows or goats, mammary blood flow takes several hours to return to normal. Investigation of the mechanism of this response, in terms of the ability of the animal to recognize its nutritional status and partition nutrients accordingly, should prove fruitful to understanding causes of variations of milk production in response to feed quantity and quality. Several substrates show increased mammary arteriovenous difference with increasing blood concentrations. This may reflect differing ratios of blood flow:milk yield. The steep gradient of concentration of substrates across the mammary epithelial cell membrane suggests that a major impediment to substrate supply for milk synthesis is the rate of substrate transport across the membrane.

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Genetic parameters for milk components including lactose from test day records in the New Zealand dairy herd

Sneddon

López‐Villalobos

Davis

et al. 2014

New Zealand Journal of Agricultural Research

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There are currently few published estimates of genetic parameters for lactose yield or lactose percentage for dairy cows. Recent trends in milk standardisation for whole milk powder have resulted in whole milk being standardised with the ratio of protein to protein-plus-lactose of at least 0.39. Currently whole milk powder produced from New Zealand milk has a protein to protein-plus-lactose ratio of 0.43, thus requiring additional lactose to be imported to maximise the return from the current product portfolio. Estimates of genetic parameters were obtained using 15,366 test day records from 4378 first-lactation cows in the Livestock Improvement Corporation sire proving scheme in the 2011-12 dairy season, distributed across 70 herds. These data included milk, fat, protein and lactose yields; fat, protein and lactose percentages; somatic cell count; days in milk; and the protein to fat ratio and protein to proteinplus-lactose ratio. Mean milk yield was 13.8 L/day, containing 5.16% fat, 3.93% protein and 5.12% lactose. Heritability estimates were 0.22, 0.35, 0.32 and 0.25 for milk yield, fat, protein and lactose percentages, respectively, which were lower than those reported in the literature but enough to allow for selection of lactose percentage.

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Metabolic clearance rate of insulin-like growth factor-I in fed and starved sheep

Hodgkinson¹,

Davis²,

Burleigh³

et al. 1987

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The metabolic clearance of insulin-like growth factor-I (IGF-I) has been examined in sheep using a radioiodinated hormone preparation (131I-labelled IGF-I). Following i.v. administration, 131I-labelled IGF-I was distributed in a volume equivalent to plasma (60 ml whole blood/kg liveweight) and demonstrated a triphasic pattern of clearance with apparent half-lives (t 1/2) of 4.0 +/- 0.4 (S.E.M.), 52.4 +/- 3.4 and 792 +/- 26.5 min (n = 10). No significant differences in the t1/2 of the three phases were identified in fed compared with starved animals (fed, n = 4, phase 1 = 3.1 +/- 0.64, phase 2 = 46 +/- 5.9 and phase 3 = 756 +/- 27 min; starved, n = 6, phase 1 = 4.6 +/- 0.58, phase 2 = 57 +/- 3.2 and phase 3 = 816 +/- 38.5 min). Similarly, no significant differences in the distribution volume (fed, n = 4, 44 +/- 4 ml/kg live-weight; starved, n = 6, 39 +/- 2 ml/kg liveweight) or metabolic clearance rate (fed, n = 4, 2.9 +/- 0.15 ml/min; starved, n = 6, 3.2 +/- 0.5 ml/min) of the IGF-I were found in fed compared with starved animals. High-performance gel filtration chromatography of sequential plasma samples following injection of 131I-labelled IGF-I revealed three clear peaks of radioactivity which demonstrated markedly different patterns of clearance. These correspond to hormone complexed to binding proteins of 150,000 and 50,000 daltons and to 'free' hormone.(ABSTRACT TRUNCATED AT 250 WORDS)

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Effects of Thyroxine and Growth Hormone Treatment of Dairy Cows on Milk Yield, Cardiac Output and Mammary Blood Flow

Davis

Collier

McNamara

et al. 1988

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Four cows received thyroxine injections (T4; 20 mg/d) and three cows received growth hormone injections (GH; 44 mg/d) for 4 d during successive 16-d experimental periods. Measurement was made of milk yield, protein yield, mammary tyrosine and phenylalanine uptake, blood plasma hormone concentrations, mammary blood flow and cardiac output. Milk yield increased by 25% with T4 and 21% with GH treatment. Milk protein content tended to decline during T4 treatment and increase following GH treatment. Cardiac output increased by 8.9 liter/min (20%) and 4.6 liter/min (10%) with T4 and GH injection. Mammary blood flow (half-udder) increased from 3.6 to 4.9 liter/min (35%) and from 3.3 to 4.4 liter/min (33%) with T4 and GH treatment, respectively. These increases calculated on a whole-udder basis, accounted for 28% (T4) and 48% (GH) of the increases in cardiac output. The proportion of cardiac output perfusing the (whole) udder increased to 19.1% (T4) and 18.7% (GH), increases of 17 and 30%, respectively. Heart rate increased with T4 (but not GH treatment) from 80 to 115/min. Ratio of blood flow to milk yield was not changed by either treatment. The proportion of cardiac output perfusing the udder likely plays a major role in facilitating the partitioning of nutrients for milk synthesis.

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S. R. Davis

Physiology of the Somatotropic Axis with Particular Reference to the Ruminant

Mammary Blood Flow and Regulation of Substrate Supply for Milk Synthesis

Genetic parameters for milk components including lactose from test day records in the New Zealand dairy herd

Metabolic clearance rate of insulin-like growth factor-I in fed and starved sheep

Effects of Thyroxine and Growth Hormone Treatment of Dairy Cows on Milk Yield, Cardiac Output and Mammary Blood Flow

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