{"corpus_id":36066589,"paper_sha":"ea6d7019c78025c6243ba4c3d7739e854ac0484f","doi":"10.1146/ANNUREV.PH.54.030192.004321","arxiv_id":null,"pmid":1562196,"pmcid":null,"mag_id":2175518322,"dblp_id":null,"acl_id":null,"title":"Molecular physiology of the regulation of hepatic gluconeogenesis and glycolysis.","year":1992,"publication_date":null,"venue":"Annual Review of Physiology","journal":{"name":"Annual review of physiology","pages":"\n          885-909\n        ","volume":"54"},"journal_issn":null,"journal_title":null,"publication_types":["Review","JournalArticle"],"pubmed_pub_types":["Journal Article","Review"],"s2_fields_of_study":["Biology","Medicine"],"reference_count":35,"citation_count":872,"influential_citation_count":38,"is_open_access":false,"arxiv_categories":null,"arxiv_license":null,"arxiv_journal_ref":null,"mesh_headings":[{"d":"Animals","mj":false,"ui":"D000818"},{"d":"Enzymes","mj":false,"qs":[{"q":"metabolism","mj":false,"ui":"Q000378"}],"ui":"D004798"},{"d":"Gene Expression Regulation","mj":false,"ui":"D005786"},{"d":"Gluconeogenesis","mj":true,"ui":"D005943"},{"d":"Glycolysis","mj":true,"ui":"D006019"},{"d":"Humans","mj":false,"ui":"D006801"},{"d":"Liver","mj":false,"qs":[{"q":"metabolism","mj":true,"ui":"Q000378"}],"ui":"D008099"},{"d":"Substrate Cycling","mj":false,"ui":"D015219"}],"chemicals":[{"n":"Enzymes","ui":"D004798","reg":"0"}],"comments_corrections":null,"source_flags":5,"s2_open_access_pdf_url":null,"s2_open_access_landing_url":null,"s2_open_access_license":null,"s2_open_access_status":null,"pmc_open_access_pdf_url":null,"pmc_open_access_landing_url":null,"pmc_open_access_license":null,"pmc_open_access_status":null,"unpaywall_open_access_pdf_url":null,"unpaywall_open_access_landing_url":null,"unpaywall_open_access_license":null,"unpaywall_open_access_status":null,"abstract":"Understanding the regulation of hepatic glucose metabolism had its foundation in the elucidation of several pathways, but recent advances have come from the application of molecular genetics. Five years ago little was known about the primary structure of the key regulatory enzymes. Since then, the primary sequence of liver GK, 6-PF-1-K, Fru-1,6-P2ase, PK, PEPCK, and 6-PF-2-K/Fru-2,6-P2ase have been derived from cDNA sequences and/or determined by direct protein sequencing. This has provided new insights into the molecular mechanisms of catalysis and the regulation of these enzymes by covalent modification. Isolation of the cDNAs for these enzymes also has allowed for the quantitation of specific mRNAs and permitted analysis of hormonal control of specific gene expression. The genes for these enzymes have been isolated and sequenced, and their promoter regions are being identified and characterized. Hormone response elements have been delineated in several of the promoters. The promoter regions for 6-PF-2-K/Fru-2,6-P2ase and Fru-1,6-P2ase have also been identified, and future research will focus on the elucidation of the mechanisms whereby hormones regulate the expression of these genes. A number of generalizations can be made about the regulation of gene expression of glycolytic/gluconeogenic enzymes. First, there is coordinate hormonal regulation of gene expression and these effects are consonant with their physiologic actions. Insulin induces the mRNAs that encode glycolytic enzymes and represses the mRNAs that encode gluconeogenic enzymes; cAMP has opposite effects. Both can increase or decrease transcription. Whereas insulin and cAMP affect all of these mRNAs, glucocorticoids appear to have a more restricted action. Second, transcriptional and posttranscriptional regulatory mechanisms are involved. The synthesis of all of the mRNAs discussed is regulated by hormones. Relatively little is known about how mRNA stability is regulated in general, but it is clear that PEPCK mRNA is stabilized by agents that increase the rate of transcription of the gene. Under appropriate metabolic signals this dual control of mRNA synthesis and stability provides for a long-term increase in PEPCK mRNA and protein. Studies with PK mRNA are less direct, but suggest a similar dual mechanism. It will be interesting to see whether multilevel regulation is restricted to these two mRNAs, both of which are involved in the same substrate cycle, or whether the stability of other mRNAs involved in hepatic glucose metabolism is also affected. Third, glucose appears to be important in the regulation of these hepatic genes.(ABSTRACT TRUNCATED AT 400 WORDS)","claims":[{"public_id":"cl_5a6ed514f27e2c74f27c59e5d6bb7740","status":"active","text":"Cloning of the cDNAs for these enzymes has enabled quantitation of specific mRNAs and analysis of hormonal control of gene expression.","confidence":0.94,"contributors":[{"id":1,"public_id":"12632b8b5f","public_label":"Anonymous (12632b8b5f)","roles":["extraction"],"url":"https://sah.borca.ai/u/12632b8b5f"}],"url":"https://sah.borca.ai/claims/cl_5a6ed514f27e2c74f27c59e5d6bb7740"},{"public_id":"cl_7479be7ad73dae3c3f24f97aadbcec0a","status":"active","text":"Hormonal regulation of glycolytic and gluconeogenic gene expression is coordinated: insulin induces glycolytic-enzyme mRNAs and represses gluconeogenic-enzyme mRNAs, whereas cAMP has opposite effects and glucocorticoids act more selectively.","confidence":0.96,"contributors":[{"id":1,"public_id":"12632b8b5f","public_label":"Anonymous 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