Exercise showed the beneficial effects on mental health in depressed sufferers, whereas, its underlying mechanisms remained unresolved. This study utilized the chronic unpredictable stress (CNS) animal model of depression to evaluate the effects of exercise on depressive behaviors and spatial performance in rats. Furthermore, we tested the hypothesis that the capacity of exercise to reverse the harmful effects of CNS was relative to the hypothalamo-pituitary-adrenal (HPA) system and brain-derived neurotrophic factor (BDNF) in the hippocampus. Animal groups were exposed to CNS for 4 weeks with and without access to voluntary wheel running. Stressed rats consumed significantly less of a 1% sucrose solution during CNS and exhibited a significant decrease in open field behavior. On the other hand, they showed impaired spatial performance in Morris water maze test 2 weeks after the end of CNS. Further, CNS significantly decreased hippocampal BDNF mRNA levels. However, voluntary exercise improved or even reversed these harmful behavioral effects in stressed rats. Furthermore, exercise counteracted a decrease in hippocampal BDNF mRNA caused by CNS. In addition, we also found that CMS alone increased circulating corticosterone (CORT) significantly and decreased hippocampal glucocorticoid receptor (GR) mRNA. At the same time, exercise alone increased CORT moderately and did not affect hippocampal GR mRNA levels. While, when both CNS and exercise were combined, exercise reduced the increase of CORT and the decrease of GR caused by CMS.The results demonstrated that: (1) exercise reversed the harmful effects of CNS on mood and spatial performance in rats and (2) the behavioral changes induced by exercise and/or CNS might be associated with hippocampal BDNF levels, and in addition, the HPA system might play different roles in the two different processes.
We performed a comparative analysis on CHO cells with varying recombinant monoclonal antibody production rates (qAb) and investigated the regulation of MAb production. Two families of CHO cells each composed of one parental and two progeny cell lines, generated by stepwise increases in methotrexate (MTX) concentration, were studied. The MAb heavy chain (HC) and light (LC) gene copy numbers and mRNA levels were quantitated by Southern and northern blotting in midexponential growth phase. We observed 2- to 3-fold amplification in gene copy numbers in high producing cell lines when compared with parental cell lines. However, the mRNA levels in the high producers were 5- to 7-fold higher, correlating well with the 5- to 7-fold increase in qAb. These results were confirmed by real-time qPCR analysis. Our study reveals that the MTX-mediated MAb overexpression results from both an increase in the gene copy number and more efficient transcription of each gene copy. We also observed that the HC to LC gene copy ratio may affect the protein yield in MAb expression systems.
Sodium butyrate treatment can increase the specific productivity of recombinant proteins in mammalian cells; however, it dramatically decreases cell growth and frequently leads to apoptosis. We have studied the responses of several Chinese hamster ovary (CHO) cells lines with different specific productivities (qP) to sodium butyrate treatment. Cell clones with lower productivities exhibited greater enhancement from butyrate treatment than cells with higher productivities. As we observed previously in cell clone characterization (Jiang et al., 2006. Biotechnol Prog 22: 313-318), heavy chain (HC) mRNA levels correlate very well with specific productivity and are amplified by butyrate treatment, indicating that sodium butyrate regulates the HC transcription. Sodium butyrate is an inhibitor of histone deacetylation, and possibly, increases gene transcription by enhancing gene accessibility to transcription factors. In this study, we applied DNase I footprinting to probe the HC and LC gene accessibility. We determined that more HC and LC gene copies are accessible by DNase I in sodium butyrate-treated CHO cells than in untreated controls, demonstrating that sodium butyrate regulates gene transcription by improving gene accessibility. However, the increase in accessibility did not correlate with the increase in transcript abundance, suggesting that butyrate enhances transcription by other mechanisms as well.
Mice homozygous for a dominant-negative allele of the Clock gene (Clock (Δ19/Δ19)) have slightly but significantly decreased male fertility. The molecular mechanism for this reduction in fertility is unknown. In the present study, we used a small hairpin RNA (shRNA) strategy to specifically knock down the Clock gene expression in the testes of male mice and determined its effect on male fertility. Clock knockdown led to smaller litter size, a lower in vitro fertility rate, lower blastula formation rate, and lower acrosin activity of the knockdown sperm. Locomotor activity analysis of the Clock knockdown mice revealed that Clock knockdown in testes did not alter their circadian rhythm. Taken together, these results provide the first evidence that Clock gene expression in round spermatids is essential for maintaining male reproductivity and suggest that acrosin may be a novel regulatory target of the Clock gene that would regulate the fertilization and early embryonic development to blastula. These findings may provide new clues for development of novel male contraceptive strategies.
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