Temporal and spatial expression of the myostatin gene during chicken embryo development.

Myostatin is a potent growth and differentiation factor involved in skeletal muscle tissue formation in vertebrates. In the present study, temporal and spatial expression patterns of myostatin transcripts were investigated in chicken embryos. Myostatin mRNA was detected by RT-PCR analysis in embryos collected immediately after oviposition (stage HH1) and persisted until the fifth day of incubation (stage HH26). Whole-mount in situ hybridization revealed myostatin to be expressed in the ventral myotomal region of mature somites, thus confirming the importance of myostatin in skeletal muscle tissue formation during avian embryogenesis. A smaller myostatin transcript was also identified. This transcript appears to have resulted from an alternative splicing event from common GT-AG processing sites. Analysis of the amino acid sequence generated from this alternative transcript confirmed the presence of a truncated protein that lacks the C terminal region, including the cysteine domains characteristic of the TGF-beta super family. The temporal and spatial patterns of myostatin expression presented in this study agree with the proposed role of myostatin as modulator of muscle cell proliferation.

Protein secretion in Lactococcus lactis : an efficient way to increase the overall heterologous protein production.

Lactococcus lactis, the model lactic acid bacterium (LAB), is a food grade and well-characterized Gram positive bacterium. It is a good candidate for heterologous protein delivery in foodstuff or in the digestive tract. L. lactis can also be used as a protein producer in fermentor. Many heterologous proteins have already been produced in L. lactis but only few reports allow comparing production yields for a given protein either produced intracellularly or secreted in the medium. Here, we review several works evaluating the influence of the localization on the production yields of several heterologous proteins produced in L. lactis. The questions of size limits, conformation, and proteolysis are addressed and discussed with regard to protein yields. These data show that i) secretion is preferable to cytoplasmic production; ii) secretion enhancement (by signal peptide and propeptide optimization) results in increased production yield; iii) protein conformation rather than protein size can impair secretion and thus alter production yields; and iv) fusion of a stable protein can stabilize labile proteins. The role of intracellular proteolysis on heterologous cytoplasmic proteins and precursors is discussed. The new challenges now are the development of food grade systems and the identification and optimization of host factors affecting heterologous protein production not only in L. lactis, but also in other LAB species.

Effect of moderate and severe heat stress on avian embryonic hsp70 gene expression.

Stress response is a universal mechanism developed by all organisms to deal with adverse changes in the environment, which lead to the synthesis of heat shock proteins (Hsps). In this study, the effect of moderate (41 degrees C) and severe (44 degrees C) heat stress on Hsp70 transcript expression pattern was investigated during chicken embryogenesis. Acute exposure to severe heat stress for one hour resulted in a fifteen-fold increase in Hsp70 mRNA levels. The return of stressed embryos to normal incubation temperature resulted in Hsp70 mRNA levels five-fold higher than control after three hours and normal levels after six hours. Moderate heat stress did not induce enhancements on Hsp70 mRNA levels. The spatial expression of Hsp70 transcripts was detected in embryos under normal incubation conditions. Whole-mount in situ hybridization analysis showed that Hsp70 transcripts were constitutively present in somite and in distinct encephalic domains (predominantly in prosencephalon and mesencephalon areas) of the chicken embryo. These results showed that Hsp70 induction is dependent on incubation temperature conditions, suggesting that early chicken embryos may induce a quick emergence response to cope with severe heat stress by increasing Hsp70 mRNA levels.