Abstract
Fescue toxicosis, induced by ingestion of ergot alkaloids from endophyte-infected tall fescue, remains a significant challenge to beef cattle production. This study evaluated the effects of fescue toxicosis on performance, thermoregulation, and liver metabolism in beef heifers maintained under the same experimental conditions as non-exposed controls. Twenty-four commercial Angus heifers were randomly assigned to a diet containing either an endophyte-infected (E+) or endophyte-free (E-) seeds for 49 days. Heifers were allocated to balance genetic representation across the two dietary groups to minimize genetic confounding. Environmental data, including temperature and relative humidity, were continuously recorded, and minimum, mean, and maximum temperature-humidity index (THI) were calculated each day. Two heatwave events occurred during the trial. E + heifers exhibited reductions in dry matter intake (DMI), feeding rate, meal size, average daily gain (ADG), and body weight, and elevated respiration rate and rectal temperature compared to E- heifers (P <0.05). Physiological impairments emerged within the first two weeks of exposure, with a subsequent heatwave exacerbating stress in the E + group. Among the three THI metrics evaluated, minimum THI showed the strongest negative correlation with DMI (r = -0.20). The two heatwave events coincided with notable reductions in DMI across both dietary groups. However, DMI was more severely suppressed in E + heifers compared to the E- group. Serum analysis revealed elevated aspartate aminotransferase (AST) and reduced alkaline phosphatase (ALP) and cholesterol levels in E + heifers, indicating liver stress and metabolic dysfunction (P <0.05). No significant differences were observed in serum albumin, bilirubin, gamma-glutamyltransferase (GGT), or triglyceride levels between groups. Collectively, these findings underscore the complex metabolic and physiological disturbances triggered by ergot alkaloid exposure, which compromise heifer health, thermoregulation, and productivity, particularly under heat stress conditions.