Deifilia Ahuatzi scite author profile

Two major mediators of glucose repression in Saccharomyces cerevisiae are the proteins Mig1 and Hxk2. The mechanism of Hxk2-dependent glucose repression pathway is not well understood, but the Mig1-dependent part of the pathway has been elucidated in great detail. Here we report that Hxk2 has a glucose-regulated nuclear localization and that Mig1, a transcriptional repressor responsible for glucose repression of many genes, is required to sequester Hxk2 into the nucleus. Mig1 and Hxk2 interacted in vivo in a yeast two-hybrid assay and in vitro in immunoprecipitation and glutathione S-transferase pull-down experiments. We found that the Lys 6 -Met 15 decapeptide of Hxk2, which is necessary for nuclear localization of the protein, is also essential for interaction with the Mig1 protein. Our results also show that the Hxk2-Mig1 interaction is of physiological significance because both proteins have been found interacting together in a cluster with DNA fragments containing the MIG1 site of SUC2 promoter. We conclude that Hxk2 operates by interacting with Mig1 to generate a repressor complex located in the nucleus of S. cerevisiae during growth in glucose medium.The yeast Saccharomyces cerevisiae can use different carbon sources for growth, but evolution has selected mechanisms for the preferential and efficient utilization of glucose. In this yeast, glucose regulates carbon utilization mainly by the repression or activation of the transcription of numerous genes that encode enzymes implicated in carbon metabolism (1, 2). Although several of the genes implicated in the pathways that control glucose repression have been identified, a complete mechanistic picture of the process is not yet available. The Hxk2 and Mig1 proteins participate as important repressors in the glucose signaling pathway (3, 4).Hxk2 is the protein that initiates the intracellular metabolism of glucose by its phosphorylation at C-6, but in addition it plays a vital role in glucose repression (5). In hxk2 mutants repression of several genes by glucose is no longer operative (6, 7). If Hxk2 acts as a transcriptional repressor, it should be found in the cell nucleus at least under certain conditions. In fact, results obtained using different approaches have demonstrated that about 15% of the protein is localized in the nucleus (8,9) and that this localization is required for glucose repression of SUC2, HXK1, and GLK1 genes (9, 10). Moreover it has been shown that the nuclear Hxk2 is involved in the formation of specific DNA-protein complexes during glucose-dependent repression of these genes (9, 10).Mig1 is a C 2 H 2 zinc finger protein that binds to the motif WWWWWN(G/C)(C/T)GGGG in several promoters (11). Once bound to this MIG1 element, it recruits the Tup1-Cyc8 (Ssn6p) complex that represses gene transcription during growth in glucose (12). The activity of Mig1 is regulated by phosphorylation and subcellular localization. In high glucose, Mig1 is dephosphorylated by the Glc7-Reg1 protein phosphatase complex (13) and is located in the nucleus wher...

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Hxk2 Regulates the Phosphorylation State of Mig1 and Therefore Its Nucleocytoplasmic Distribution

Ahuatzi¹,

Riera²,

́ez³

et al. 2007

Journal of Biological Chemistry

139

157

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Mig1 and Hxk2 are two major mediators of glucose repression in Saccharomyces cerevisiae. However, the mechanism by which Hxk2 participates in the glucose repression signaling pathway is not completely understood. Recently, it has been demonstrated that Hxk2 interacts with Mig1 to generate a repressor complex located in the nucleus of S. cerevisiae. However, the mechanism by which Mig1 favors the presence of Hxk2 in the nucleus is not clear, and the function of Hxk2 at the nuclear repressor complex level is still unknown. Here, we report that serine 311 of Mig1 is a critical residue for interaction with Hxk2 and that this interaction is regulated by glucose. Our findings suggest that Snf1 interacts constitutively with the Hxk2 component of the repressor complex at high and low glucose conditions. Furthermore, we show that Snf1 binds to Mig1 under low glucose conditions and that binding is largely abolished after a shift to high glucose medium. We found that phosphorylation of serine 311 of Mig1 by Snf1 kinase is essential for Mig1 protein nuclear export and derepression of the SUC2 gene in glucose-limited cells. These results allow postulating that the Hxk2 operates by interacting both with Mig1 and Snf1 to inhibit the Mig1 phosphorylation at serine 311 during high glucose grown.

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Glucose sensing through the Hxk2-dependent signalling pathway

Moreno

Ahuatzi

Riera

et al. 2005

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In this work, we describe the hexokinase 2 (Hxk2) signalling pathway within the yeast cell. Hxk2 and Mig1 are the two major factors of glucose repression in Saccharomyces cerevisiae. The functions of both proteins have been extensively studied but there is no information about possible interactions among them in the repression pathway. Our results demonstrate that Hxk2 interacts directly with Mig1 in vivo and in vitro and that the ten amino acids motif between K6 and M15 is required for their interaction. This interaction has been detected at the DNA level both in vivo by chromatin immunoprecipitation experiments and in vitro using purified proteins and a DNA fragment containing the MIG1 site of the SUC2 promoter. This demonstrates that the interaction is of physiological relevance. Our findings show that the main role of Hxk2 in the glucose signalling pathway is the interaction with Mig1 to generate a repressor complex located in the nucleus of S. cerevisiae.

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Human pancreatic β-cell glucokinase: subcellular localization and glucose repression signalling function in the yeast cell

Riera

Ahuatzi

Herrero

et al. 2008

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Human GK(beta) (pancreatic beta-cell glucokinase) is the main glucose-phosphorylating enzyme in pancreatic beta-cells. It shares several structural, catalytic and regulatory properties with Hxk2 (hexokinase 2) from Saccharomyces cerevisiae. In fact, it has been previously described that expression of GK(beta) in yeast could replace Hxk2 in the glucose signalling pathway of S. cerevisiae. In the present study we report that GK(beta) exerts its regulatory role by association with the yeast transcriptional repressor Mig1 (multicopy inhibitor of GAL gene expression 1); the presence of Mig1 allows GK(beta) to bind to the SUC2 (sucrose fermentation 2) promoter, helping in this way in the maintenance of the repression of the SUC2 gene under high-glucose conditions. Since a similar mechanism has been described for the yeast Hxk2, the findings of the present study suggest that the function of the regulatory domain present in these two proteins has been conserved throughout evolution. In addition, we report that GK(beta) is enriched in the yeast nucleus of high-glucose growing cells, whereas it shows a mitochondrial localization upon removal of the sugar. However, GK(beta) does not exit the nucleus in the absence of Mig1, suggesting that Mig1 regulates the nuclear exit of GK(beta) under low-glucose conditions. We also report that binding of GK(beta) to Mig1 allows the latter protein to be located at the mitochondrial network under low-glucose conditions.

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