Effects of heat stress on markers of skeletal muscle proteolysis in dairy cattle

Sodium Butyrate Alleviates Heat Stress-Induced Oxidative Stress and Skeletal Muscle Homeostasis Disruption by Promoting Autophagy in Mice

BACKGROUND

The gradual rise in global temperatures can affect skeletal muscle development and intestinal microorganisms. However, the influence of microbial metabolites on skeletal muscle homeostasis under heat stress (HS) remains unclear.

METHODS

C57BL/6J mice were exposed to normal temperature or 40 °C conditions for 3 d, 7 d, or 14 d. The HS 7 d mice also were treated with sodium butyrate (NaB, 200 mg/kg, gavage).

RESULTS

Strikingly, the body weight, antioxidative ability (MDA, T-SOD, and GSH-Px), and average cross-sectional area decreased, but the blood glucose and core temperature increased under HS. However, the NaB treatment reversed these effects. Meanwhile, HS also increased the levels of TNF-α and CORT. Additionally, HS led to a reduction in the villus height and an increase in the crypt depth of the intestine. Microbial 16S rRNA sequencing analysis revealed that HS caused gut microbiota dysbiosis. NaB increased the expression of HSP70 under HS, to maintain skeletal muscle homeostasis. HS stimulated the expression of Pax7, which indicates that skeletal muscle homeostasis was disrupted. Meanwhile, the expressions of MyoG and MyoD were decreased under HS. The immunofluorescence results also show that HS triggered a shift from slow muscle fibers (MYH7) to fast muscle fibers (MYH1). However, NaB recovered the expressions of these muscle-related factors. HS inhibited autophagy initiation (mTOR, Beclin1, Atg5, Atg7, and Atg12), the formation (LC3 II/LC3 I) of autophagosomes, and the binding (p62 and LAMP1) of lysosomes to autophagosomes, which were activated by NaB. C2C12 cells were treated with H2O2 to simulate skeletal muscle oxidative stress, and treated with NaB in advance. Oxidative stress disrupted the homeostasis of the C2C12 cells, characterized by an increase in Pax 7 and decreases in MyoG and MyoD, but these changes were reversed by the NaB treatment. Meanwhile, NaB was unable to maintain the stable expression of Pax7 when autophagy was inhibited.

CONCLUSIONS

This suggests that NaB can regulate oxidative stress induced by HS through autophagy to maintain skeletal muscle homeostasis.

Effect of synchronicity of amino acid supply on the synthesis of protein in C2C12 myotubes cultured in vitro

Previous studies inferred that the synthesis rate/efficiency of protein in body tissue is probably affected by synchronicity of different amino acid (AA) supply in its metabolic pool. In order to further observe the influence of synchronicity of AA supply on the synthesis of protein in cell level, a cell culture experiment in vitro was conducted with C2C12 myotubes. C2C12 myotubes were cultured for 24 h, meanwhile the culture medium was replaced for each 8 h. Those myotubes were subjected to 3 treatments (1 for controlled and 2 for tested), control myotubes were cultured with same normal complete medium within the whole 24 h, and the 2 tested myotubes were cultured with asynchronous amino acid supply medium in which the levels of different AAs (Lysine, threonine, methionine, leucine, valine and glutamic acid) either increased and then decreased or decreased and then increased, at different replaced medium time point (at 0, 8, and 16 h). However, during the whole experiment period all the 3 treated myotubes received same amount of each AA. The sample of the myotubes were used for myotube morphology, protein, AA, and proteomic analysis. The results showed that asynchronous AA nutrition affect the synthesis and degradation of myotube proteins, and the AAAS in the medium increase, thus decreasing the synthesis rate of myotube proteins (p < 0.05) and decreasing the diameter of myotubes (p < 0.05). The process of reduced protein synthesis affects the PI3K-AKT and FoxO signaling pathway by downregulating the levels of IRS1 and EGFR, and the degradation amplitude is greater than the synthesis amplitude. Therefore, this study further revealed the effect of the asynchronous supply of amino acids on myotube protein synthesis and the underlying mechanism and provided a theoretical reference for the precision of nutrition to animals.

One day of environment-induced heat stress damages the murine myocardium

The physiological consequences of environment-induced heat stress (EIHS), caused by prolonged exposure to excess heat and humidity, are largely unknown. The purpose of this investigation was to determine the extent to which EIHS alters cardiac health. We hypothesized that 24 h of EIHS would cause cardiac injury and cellular dysfunction in a murine EIHS model. To test this hypothesis, 7-wk-old female mice were housed under thermoneutral (TN) conditions (n = 12; 31.2 ± 1.01°C, 35 ± 0.7% humidity) or EIHS conditions (n = 14; 37.6 ± 0.01°C, 42.0 ± 0.06% humidity) for 24 h. Environment-induced heat stress increased rectal temperature by 2.1°C (P < 0.01) and increased subcutaneous temperature by 1.8°C (P < 0.01). Body weight was decreased by 10% (P = 0.03), heart weight/body weight was increased by 26% (P < 0.01), and tissue water content was increased by 11% (P < 0.05) in EIHS compared with TN. In comparison with TN, EIHS increased protein abundance of heat shock protein (HSP) 27 by 84% (P = 0.01); however, HSPs 90, 60, 70, and phosphorylated HSP 27 were similar between groups. Histological inspection of the heart revealed that EIHS animals had increased myocyte vacuolation in the left ventricle (P = 0.01), right ventricle (P < 0.01), and septum (P = 0.01) compared with TN animals. Biochemical indices are suggestive of mitochondrial remodeling, increased autophagic flux, and robust activation of endoplasmic reticulum stress in hearts from EIHS mice compared with TN mice. These data demonstrate that 1 day of EIHS is sufficient to induce myocardial injury and biochemical dysregulation.NEW & NOTEWORTHY The consequences of prolonged environment-induced heat stress (EIHS) on heart health are largely unknown. We discovered that a 24-h exposure to environmental conditions sufficient to cause EIHS resulted in cardiac edema and histopathologic changes in the right and left ventricles. Furthermore, among other biochemical changes, EIHS increased autophagic flux and caused endoplasmic reticulum stress. These data raise the possibility that thermic injury, even when insufficient to cause heat stroke, can damage the myocardium.

Relationships between gastrointestinal permeability, heat stress, and milk production in lactating dairy cows

Heat stress (HS) is a global issue that decreases farm profits and compromises animal welfare. To distinguish between the direct and indirect effects of HS, 16 multiparous Holstein cows approximately 100 DIM were assigned to one of 2 treatments: pair fed to match HS cow intake, housed in thermoneutral conditions (PFTN, n = 8) or cyclical HS (n = 8). All cows were subjected to 2 experimental periods. Period 1 consisted of a 4 d thermoneutral period with ad libitum intake. During period 2 (P2), the HS cows were housed in cyclical HS conditions with a temperature-humidity index (THI) ranging from 76 to 80 and the PFTN cows were exposed to a constant THI of 64 for 4 d. Dry matter intake of the PFTN cows was intake matched to the HS cows. Milk yield, milk composition, rectal temperature, and respiration rate were recorded twice daily, blood was collected daily via a jugular catheter, and cows were fed twice daily. On d 3 of each period, Cr-EDTA and sucralose were orally administered and recovered via 24 h total urine collection to assess gastrointestinal permeability. All data were analyzed using the GLIMMIX procedure in SAS. The daily data collected in P1 was averaged and used as a covariate if deemed significant in the model. Heat stress decreased voluntary feed intake by 35% and increased rectal temperature and respiration rate (38.4°C vs. 39.4°C and 40 vs. 71 respirations/min, respectively). Heat stress reduced DMI by 35%, which accounted for 66% of the decrease in milk yield. The yields, and not concentrations, of milk protein, fat, and other solids were lower in the HS cows on d 4 of P2. Milk urea nitrogen was higher and plasma urea nitrogen tended to be higher on d 3 and d 4 of HS. Glucose was 7% lower in the HS cows and insulin was 71% higher in the HS cows than the PFTN cows on d 4 of P2. No difference in lipopolysaccharide-binding protein was observed. Heat stress cows produced 7 L/d more urine than PFTN cows. No differences were detected in the urine concentration or percentage of the oral dose recovered for Cr-EDTA or sucralose. In conclusion, HS was responsible for 34% of the reduction of milk yield. The elevated MUN and the tendency for elevated plasma urea nitrogen indicate a whole-body shift in nitrogen metabolism. No differences in gastrointestinal permeability or lipopolysaccharide-binding protein were observed. These results indicate that, under the conditions of this experiment, activation of the immune system by gut-derived lipopolysaccharide was not responsible for the decreased milk yield observed during HS.

Variation in protein metabolism biomarkers during the transition period and associations with health, colostrum quality, reproduction, and milk production traits in Holstein cows

The aims of this study were to assess (1) the variation of protein metabolism biomarkers and factors affecting them during the transition period, (2) the association of each biomarker with skeletal muscle reserves and their changes, and (3) the association of these biomarkers with postpartum health, colostrum quality, reproduction, and milk production. For this purpose, 238 multiparous Holstein cows from 6 herds were used in a prospective cohort study. Plasma concentrations of 3-methylhistidine (3-MH) and 1-methylhistidine (1-MH) and serum concentrations of total protein (TP), albumin (ALB), urea nitrogen (BUN), and creatinine (SCR) were determined for each cow at -21, -7, 7, 21, and 28 d relative to calving. Clinical diseases were recorded during the first 28 d postcalving, and presence of subclinical ketosis (scKET) was investigated at 7 and 21 d. Colostrum quality was estimated by Brix refractometry. Reproduction data by 150 d in milk (DIM) and milk production records were also available. Linear mixed models including the fixed effects of time point, herd, parity, body condition score (-21 d), duration of dry period and postparturient diseases were fitted to assess the variation in each biomarker's concentration. The association between the biomarkers' concentration during the prepartum period with the odds for each postparturient disease and for a combined trait (CD_1-28), defined as the presence of at least one clinical condition during the first 28 d after calving, were assessed with separate binary logistic models for time points -21 d and -7 d. The relationship of each biomarker's concentration with longissimus dorsi thickness (LDT) and the changes in LDT (ΔLDT) was assessed with pairwise correlations. Separate general linear models were used to assess the association of each biomarker with colostrum Brix values and milk production traits. Finally, the associated hazard for first artificial insemination (AI) and for pregnancy by 150 DIM (PREG_150DIM) was assessed with Cox proportional hazard models, whereas odds for pregnancy to the first AI (PREG_1stAI) were assessed with binary logistic models. The level of 3-MH was affected mainly by herd, time points, and their interaction. Higher 3-MH was associated with increased odds for metritis and CD_1-28, increased hazard for PREG_150 DIM and with increased milk production. 1-Methylhistidine was affected mainly by herd, scKET and occurrence of displaced abomasum. Higher 1-MH was associated with better colostrum quality, increased odds for scKET, increased hazard for first AI by 150 DIM and with decreased milk production. Both 3-MH and 1-MH were weakly to moderately negatively correlated with LDT and moderately to strongly negatively correlated with ΔLDT at the corresponding time periods. Additionally, higher TP was associated with increased odds for metritis and CD_1-28 and increased milk production, while higher ALB was associated with increased odds for scKET and increased milk production. Moreover, higher BUN was associated with decreased odds for scKET, increased odds for PREG_1stAI and increased milk production. Higher SCR was associated with decreased odds for retained fetal membranes, metritis, and CD_1-28. Periparturient protein metabolism is significantly associated with postpartum health, colostrum quality, reproduction, and milk production; mechanisms involved require further investigation.