Thyroid hormone regulation of hepatic genes in vivo detected by complementary DNA microarray

The liver is an important target organ of thyroid hormone. However, only a limited number of hepatic target genes have been identified, and little is known about the pattern of their regulation by thyroid hormone. We used a quantitative fluorescent cDNA microarray to identify novel hepatic genes regulated by thyroid hormone. Fluorescent-labeled cDNA prepared from hepatic RNA of T3-treated and hypothyroid mice was hybridized to a cDNA microarray, representing 2225 different mouse genes, followed by computer analysis to compare relative changes in gene expression. Fifty five genes, 45 not previously known to be thyroid hormone-responsive genes, were found to be regulated by thyroid hormone. Among them, 14 were positively regulated by thyroid hormone, and unexpectedly, 41 were negatively regulated. The expression of 8 of these genes was confirmed by Northern blot analyses. Thyroid hormone affected gene expression for a diverse range of cellular pathways and functions, including gluconeogenesis, lipogenesis, insulin signaling, adenylate cyclase signaling, cell proliferation, and apoptosis. This is the first application of the microarray technique to study hormonal regulation of gene expression in vivo and should prove to be a powerful tool for future studies of hormone and drug action.     

CNS-Specific Ribozyme Expression

Targeted genetic deletion is a powerful tool for analysis of gene function, but the standard approaches carry certain inescapable disadvantages. First, deletion is ubiquitous; tissue-specific knockout cannot be obtained. Second, temporal regulation of depletion is unattainable; the deleted functions are absent throughout the animal's development. As a consequence, during ontogeny, other gene products may be able to compensate, filling the functional gap. Furthermore bifunctional proteins exist that fulfill one role during development and another in the mature organism; deletion will remove the early function and, if this is lethal, the later function will remain undetected. Third, if genes utilize alternative splicing to control protein expression, it is difficult to target one spliced mRNA while leaving intact its related, but different, siblings. We review how these problems may be circumvented using ribozymes to diminish gene expression in a tissue-specific and temporally regulated manner and provide guidelines for the design and delivery of active ribozymesin vivo.Such methods may be particularly useful for analysis of genes involved in ontogeny and function of the central nervous system, in which individual genes may be expressed with alternative splicing patterns, or at differentially regulated levels, at different stages of CNS development.     

Gene expression profile change and associated physiological and pathological effects in mouse liver induced by fasting and refeeding

Food availability regulates basal metabolism and progression of many diseases, and liver plays an important role in these processes. The effects of food availability on digital gene expression profile, physiological and pathological functions in liver are yet to be further elucidated. In this study, we applied high-throughput sequencing technology to detect digital gene expression profile of mouse liver in fed, fasted and refed states. Totally 12162 genes were detected, and 2305 genes were significantly regulated by food availability. Biological process and pathway analysis showed that fasting mainly affected lipid and carboxylic acid metabolic processes in liver. Moreover, the genes regulated by fasting and refeeding in liver were mainly enriched in lipid metabolic process or fatty acid metabolism. Network analysis demonstrated that fasting mainly regulated Drug Metabolism, Small Molecule Biochemistry and Endocrine System Development and Function, and the networks including Lipid Metabolism, Small Molecule Biochemistry and Gene Expression were affected by refeeding. In addition, FunDo analysis showed that liver cancer and diabetes mellitus were most likely to be affected by food availability. This study provides the digital gene expression profile of mouse liver regulated by food availability, and demonstrates the main biological processes, pathways, gene networks and potential hepatic diseases regulated by fasting and refeeding. These results show that food availability mainly regulates hepatic lipid metabolism and is highly correlated with liver-related diseases including liver cancer and diabetes.