Evaluation of physiological and molecular responses to acute heat stress in two chicken breeds.

High environmental temperatures are a foremost concern affecting poultry production; thus, understanding and controlling such conditions are vital to successful production and welfare of poultry. In view of this, a completely randomized design with a 2 × 2 factorial arrangement involving two local strains (Kirin chicken (KC) and Three-yellow chicken (TYC)) and two temperature groups (normal/control = 30 ±â€¯2 °C and acute heat stress (AHS) = 35 ±â€¯1 °C for 8-h with 70% humidity) was used to assess the main regulatory factors such as heat shock protein (HSP70) gene, cytokine genes (IL-1ß, IL-6, IL-10), muscle development gene (IGF-1) and tissue histopathological changes. At 56 days old, the temperatures of the comb (CT), feet (FT), eyelid (ET) and rectal (RT) from each group were taken thrice at 0, 2, 4 and 8-h during AHS, and 1 and 3-h recovery period after AHS. At 80 days old, the slaughter weight was also analyzed. The CT and ET of the AHS groups increased during the 8-h trial, while the RT of both strains decreased significantly at 4 h but increased at 8 h in the TYC group. All temperature recordings dropped in the AHS groups of both strains during the recovery period. The results revealed that the mRNA expression of HSP70 in the liver was higher in the heat-stressed group of both strains compared to the control. The expression of HSP70 was shown in the AHS-KC group to be significantly high compared to the control (P < 0.05). Moreover, the IGF1 gene in the liver, breast muscle and leg muscle was downregulated in the AHS-TYC group compared to the control (P < 0.05), although that in the AHS-KC was downregulated in the breast muscle. The mRNA expression of spleen IL-1ß significantly decreased in the AHS-TYC group (P < 0.01), whereas that of the AHS-KC had no significant difference (P > 0.05). The mRNA expression of spleen IL-6 and IL-10 was increased in the AHS-KC group but did not exhibit obvious changes in the AHS-TYC. Correspondingly, the histopathological examinations revealed tissue injury in the AHS groups of both strains, with the TYC strain experiencing more severe changes. The final live and carcass weights showed a significant enhancement in the treatments (P < 0.01 and P < 0.05, respectively) and treatment×strain interaction (P < 0.05) with breast muscle rate significantly reducing among the treatments (P < 0.01) at 80 days. In conclusion, the differential response to AHS after physiological, molecular and immune response portrays KC to have better thermal tolerance than the TYC.

Roles of chicken growth hormone receptor antisense transcript in chicken muscle development and myoblast differentiation.

Muscle is one of the important economic traits in poultry production, and its production depends on the increased number of muscle fibers during the embryonic stage. Chicken GHR gene can transcribe in double directions, possessing not only GHR-S but also GHR-AS. The 2 kinds of transcripts are partially complementation in sequences and interact with each other. Until now, the roles and mechanisms of GHR-AS in myoblast differentiation was still unknown. In this study, we not only analyzed the GHR-AS expression patterns in myoblast differentiation phase but also clarified that GHR-AS promoted myoblast differentiation via GH-GHR-IGF1 signal pathway. Quantitative PCR analysis indicated that GHR-AS was increased during myoblast differentiation. Sub-cellular localization showed that GHR-AS and GHR-S were expressed at a higher level in the nucleus than that in the cytoplasm. The expression of MyoD and MyHC and the myoblast differentiation significantly increased after GHR-AS overexpression, while the distance between wounds decreased, suggesting that GHR-AS repressed myoblast migration and promoted differentiation. Additionally, the expression of GHR-AS, IGF1 and MyHC increased after GH protein treated, and the myoblast differentiation also increased. In conclusion, GHR-AS promoted myoblast differentiation by enhancing fusion and inhibiting migration possibly via GH-GHR-IGF1 signal pathway.