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The Influence of Heat Stress on Milk Yield, Gastrointestinal Permeability, and Nutrient Partitioning in Lactating Dairy Cattle

dc.contributor.authorEllett Jr, Mark Daviden
dc.contributor.committeechairDaniels, Kristy Marieen
dc.contributor.committeememberRhoads, Robert P.en
dc.contributor.committeememberBaumgard, Lance H.en
dc.contributor.committeememberHanigan, Mark Danielen
dc.contributor.departmentDairy Scienceen
dc.date.accessioned2024-08-07T08:00:20Zen
dc.date.available2024-08-07T08:00:20Zen
dc.date.issued2024-08-06en
dc.description.abstractThe US dairy industry loses approximately $1.2 billion due to heat stress related production losses annually. It was formerly believed that heat-stressed lactating dairy cattle produce less milk because they consume less feed. It has since been established that the reduction of feed intake is only responsible for about 50% of the reduced milk yield in HS cows. It is believed that HS increases gastrointestinal permeability (GIP), resulting in microbial components leaking from the lumen of the gastrointestinal tract into underlying tissue and stimulating an immune response. The immune response is suspected to alter overall metabolism, and milk production specifically, by diverting nutrients away from the mammary gland and other non-essential processes to support immune system activation. Topics examined herein focus on identifying markers to assess gastrointestinal permeability and the influence of heat stress on GIP and nutrient metabolism. The first study utilized an in vitro rumen fermentation system to determine if lactulose, sucralose, and D-mannitol could persist in an in vitro rumen culture. Lactulose could not be quantified in the rumen fluid matrix, D-mannitol was rapidly degraded, and sucralose concentrations did not change after 48 h of incubation, establishing sucralose as an indigestible marker in mature ruminants. The second study utilized a pair feeding design to directly assess the effect of HS on GIP, milk yield, and immune activation by lipopolysaccharide (LPS). HS cows (n=7) were exposed to a temperature-humidity index (THI) value of 74-80 for 4 d. The pair-fed thermoneutral cows (PFTN, n=8) were exposed to a constant THI of 64 with their intake matched to the HS cows. HS lowered milk yield without altering GIP, measured using orally dosed sucralose as a permeability marker, or eliciting an LPS related immune response. Jejunal mucosal scrapings were harvested from each cow, tight junction proteins were quantified, and no differences were detected. Lack of treatment responses in GIP marker recovery and tight junction protein abundance indicate that increased GIP may not be a driving force behind production losses in HS dairy cows. The third study focused on energy substrate utilization during HS with the objective of determining if tissue-level energy substrate metabolism could be influencing glucose sparing mechanisms. Metabolic flexibility of skeletal muscle, liver, and mammary tissue was assessed after 4 d of HS. It was determined that HS reduced skeletal muscle metabolic flexibility and did not alter liver and mammary metabolic flexibility. This indicates that skeletal muscle has a greater dependency on glucose as an energy substrate, which may decrease the pool of glucose available for lactose synthesis in lactating cows. Finally, the last study had the objective of assessing branched-chain amino acid (BCAA) requirements during HS. BCAA are oxidized for ATP synthesis in extrahepatic tissues and provide precursors for the biosynthesis of non-essential amino acids. They are also taken up by the mammary gland at a rate greater than what they are used in milk protein. Taken together, it was hypothesized that BCAA requirements may be increased during HS. BCAA entry rates into blood were assessed using a stable isotope approach and a 4-pool model. No differences were detected in daily entry rates or flux rates between pools indicating no change in requirements. When considering the results of all studies, reductions in milk yield are likely a result of altered macronutrient metabolism but further work is needed to confirm that hypothesis. Understanding the physiology behind HS related production losses is the first step in developing mitigation strategies.en
dc.description.abstractgeneralHeat stress (HS) is a global issue that compromises dairy cattle welfare and reduces milk production. On average the US dairy industry loses approximately $1.2 billion due to heat stress related production losses annually. With the global population expected to exceed 9 billion by 2050, strategies to mitigate HS related production losses are needed. Although cows exposed to HS conditions eat less food, that only explains about 50% of the production losses. It is hypothesized that the other 50% of milk yield losses is at least partially caused by increased gastrointestinal permeability (GIP), which elicits an immune response. Questions examined herein primarily focus on quantification of physiological and metabolic responses to HS. The objective of the first study was to identify a marker to assess GIP we could give orally to cows and detect in their urine. Commonly used GIP markers used in monogastric are carbohydrates, which have the potential to be fermented in the rumen. Sucralose was identified as a suitable marker due to its resistance to degradation in the rumen. The next study focused on measuring physiological responses of lactating dairy cows when exposed to HS conditions. Under the conditions of our experiment, HS decreased dry matter intake and milk yield without increasing GIP or inducing an immune response. It was determined that the reduction in dry matter intake was responsible for 66% of the reduced milk yield with the other 34% being associated with physiological changes other than increased GIP. The next study focused on how HS impacts the ability of skeletal muscle, mammary, and liver tissue to utilize glucose or palmitic acid as an energy substrate. The ability to switch between energy substrates is called metabolic flexibility. It was found that HS lowered the ability of skeletal muscle because it was unable to utilize fat as an energy source. Mammary and liver tissue exhibited no change in metabolic flexibility. The final study focused on how HS changed branched-chain amino acid (BCAA) plasma entry rates into plasma. An in vivo stable isotope method and a 4-pool mathematical model was used to predict how BCAA moved between pools which corresponds to the rate of protein turnover. Under the conditions of this experiment, no differences in BCAA entry rates were observed. Overall, results indicate altered energy substrate metabolism independent of immune activation stemming from altered GIP may be a driving factor in HS related production losses. Overall, this work contributes to understanding of HS biology and questions the established belief that increased GIP resulting in immune activation is responsible for about 50% of production losses.en
dc.description.degreeDoctor of Philosophyen
dc.format.mediumETDen
dc.identifier.othervt_gsexam:41255en
dc.identifier.urihttps://hdl.handle.net/10919/120865en
dc.language.isoenen
dc.publisherVirginia Techen
dc.rightsIn Copyrighten
dc.rights.urihttp://rightsstatements.org/vocab/InC/1.0/en
dc.subjectHeat stressen
dc.subjectdairyen
dc.subjectleaky guten
dc.titleThe Influence of Heat Stress on Milk Yield, Gastrointestinal Permeability, and Nutrient Partitioning in Lactating Dairy Cattleen
dc.typeDissertationen
thesis.degree.disciplineAnimal Sciences, Dairyen
thesis.degree.grantorVirginia Polytechnic Institute and State Universityen
thesis.degree.leveldoctoralen
thesis.degree.nameDoctor of Philosophyen

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