Yin Z, Hatton L, Brown A J
Department of Molecular and Cell Biology, University of Aberdeen, Institute of Medical Sciences, Foresterhill, Aberdeen AB25 2ZD, UK.
Mol Microbiol. 2000 Feb;35(3):553-65. doi: 10.1046/j.1365-2958.2000.01723.x.
Glucose regulates yeast gene expression at both transcriptional and post-transcriptional levels. Glucose strongly represses the transcription of the gluconeogenic genes, FBP1 and PCK1, and accelerates the degradation of their mRNAs. Together these mechanisms are responsible for the rapid decrease in gluconeogenic enzyme synthesis when yeast cells switch to glycolytic metabolism. In this study, we show that accelerated gluconeogenic mRNA degradation can be triggered by low concentrations of glucose (<0. 02%). This sets the FBP1 and PCK1 mRNAs apart from other glucose-sensitive mRNAs, such as the Ip mRNA, which only responds to high glucose concentrations (>1%). We also show that accelerated gluconeogenic mRNA degradation is co-ordinated with transcriptional repression by common signalling components that include sugar kinases and Ras-cAMP signalling. Furthermore, the ability of the low glucose signal to trigger accelerated gluconeogenic mRNA degradation depends upon the low glucose sensor, Snf3p, but not on the high glucose sensor, Rgt2p. Also, this response is influenced by reg1 and ume5 mutations, but not by grr1 or rgt1 mutations. Our data suggest that several signalling pathways co-ordinate differential post-transcriptional and transcriptional responses in yeast, depending upon the amount of glucose available in the medium.
葡萄糖在转录和转录后水平上调节酵母基因表达。葡萄糖强烈抑制糖异生基因FBP1和PCK1的转录,并加速其mRNA的降解。当酵母细胞转向糖酵解代谢时,这些机制共同导致糖异生酶合成迅速减少。在本研究中,我们发现低浓度葡萄糖(<0.02%)可引发糖异生mRNA的加速降解。这使得FBP1和PCK1 mRNA与其他葡萄糖敏感mRNA(如仅对高浓度葡萄糖(>1%)有反应的Ip mRNA)不同。我们还表明,糖异生mRNA的加速降解与包括糖激酶和Ras-cAMP信号在内的共同信号成分介导的转录抑制相协调。此外,低葡萄糖信号触发糖异生mRNA加速降解的能力取决于低葡萄糖传感器Snf3p,而不是高葡萄糖传感器Rgt2p。同样,这种反应受reg1和ume5突变的影响,但不受grr1或rgt1突变的影响。我们的数据表明,根据培养基中可用葡萄糖的量,几种信号通路在酵母中协调不同的转录后和转录反应。
