Constitutive expression in gal7 mutants of Kluyveromyces lactis is due to internal production of galactose as an inducer of the Gal/Lac regulon.

The induction process of the galactose regulon has been intensively studied, but until now the nature of the inducer has remained unknown. We have analyzed a delta gal7 mutant of the yeast Kluyveromyces lactis, which lacks the galactotransferase activity and is able to express the genes of the Gal/Lac regulon also in the absence of galactose. We found that this expression is semiconstitutive and undergoes a strong induction during the stationary phase. The gal1-209 mutant, which has a reduced kinase activity but retains its positive regulatory function, also shows a constitutive expression of beta-galactosidase, suggesting that galactose is the inducer. A gal10 deletion in delta gal7 or gal1-209 mutants reduces the expression to under wild-type levels. The presence of the inducer could be demonstrated in both delta gal7 crude extracts and culture medium by means of a bioassay using the induction in gal1-209 cells. A mutation in the transporter gene LAC12 decreases the level of induction in gal7 cells, indicating that galactose is partly released into the medium and then retransported into the cells. Nuclear magnetic resonance analysis of crude extracts from delta gal7 cells revealed the presence of 50 microM galactose. We conclude that galactose is the inducer of the Gal/Lac regulon and is produced via UDP-galactose through a yet-unknown pathway.     

Analysis of the galactose signal transduction pathway in Saccharomyces cerevisiae: interaction between Gal3p and Gal80p.

The GAL3 gene plays a critical role in galactose induction of the GAL genes that encode galactose- metabolizing enzymes in Saccharomyces cerevisiae. Defects in GAL3 result in a long delay in GAL gene induction, and overproduction of Gal3p causes constitutive expression of GAL. Here we demonstrate that concomitant overproduction of the negative regulator, Gal80p, and Gal3p suppresses this constitutive GAL expression. This interplay between Gal80p and Gal3p is direct, as tagged Gal3p coimmunoprecipitated with Gal80p. The amount of coprecipitated Gal80p increased when GAL80 yeast cells were grown in the presence of galactose. When both GAL80 and GAL3 were overexpressed, the amount of coprecipitated Gal80p was not affected by galactose. Tagged gal3 mutant proteins bound to purified Gal80p, but only poorly in comparison with the wild type, suggesting that formation of the Gal80p-Gal3p complex depends on the normal function of Gal3p. Gal3p appeared larger in Western blots (immunoblots) than predicted by the published nucleic acid sequence. Reexamination of the DNA sequence of GAL3 revealed several mistakes, including an extension at the 3' end of another predicted 97 amino acids.     

Galactose transporters discriminate steric anomers at the cell surface in yeast

Aldose-1-epimerase or mutarotase (EC 5.1.3.3) catalyzes interconversion of α/β-anomers of aldoses, such as glucose and galactose, and is distributed in a wide variety of organisms from bacteria to humans. Nevertheless, the physiological role of this enzyme has been elusive in most cases, because the α-form of aldoses in the solid state spontaneously converts to the β-form in an aqueous solution until an equilibrium of α : β=36.5 : 63.5 is reached. A gene named GAL10 encodes this enzyme in yeast. Here, we show that the GAL10 -encoded mutarotase is necessary for utilization of galactose in the milk yeast Kluyveromyces lactis , and that this condition is presumably created by the presence of the β-specific galactose transporter, which excludes the α-anomer from the α/β-mixture in the medium at the cell surface. Thus, we found that a mutarotase-deficient mutant of K. lactis failed to grow on medium, in which galactose was the sole carbon source, but, surprisingly, that the growth failure is suppressed by concomitant expression of the Saccharomyces cerevisiae -derived galactose transporter Gal2p, but not by that of the K. lactis galactose transporter Hgt1p. We also suggest the existence of another mutarotase in K. lactis , whose physiological role remains unknown, however.     

Dilution Kinetic Studies of Yeast Populations: IN VIVO Aggregation of Galactose Utilizing Enzymes and Positive Regulator Molecules

By use of a selective medium containing ethidium bromide, population analyses of yeast galactose long-term adaptation mutants (gal3) in the process of deadaptation in the absence of galactose have been performed. The analysis of diploid strains homozygous for the gal3 locus but heterozygous for different combinations of the other mutant galactose loci, which thus have reduced amounts of the gene products of those loci, have demonstrated that, in addition to the two permease units determined in a previous study, a cell requires one complex of the Leloir pathway enzymes and two complexes specified by the Gal4 locus to be readily induced. From the consideration of these complexes as being aggregated molecules which are diluted out as units (i.e., if such a molecule were a dimer, it would not dissociate into monomers) during cell growth, the in vivo aggregation of these enzymes and the Gal4 gene product could be studied. The data indicate that the function of the Gal4 gene product is to activate a Leloir enzyme complex. It is postulated that the gal3 phenotype is the result of such strains' inability to actively synthesize an endogenous co-inducer which allows wild-type cells to be readily induced upon exposure to galactose.     

Galactose induction in yeast involves association of Gal80p with Gal1p or Gal3p

Gal1p carries out two functions in the galactose pathway of yeast. It activates Gal4p by interacting with Gal80p – a function that can also served by Gal3p – and it catalyzes the formation of galactose-1-phosphate. Recently, we and others have presented biochemical evidence for complex formation between Gal1p and Gal80p. Here, we extend these data and present genetic evidence for an interaction between Gal1p and Gal80p in vivo, using a two-hybrid assay. Interaction between Gal1p and Gal80p depends on the presence of galactose, but not on the catalytic activity of Gal1p. A new class of Kluyveromyces lactis mutants was isolated, designated Klgal1-m, which have lost the derepressing activity but retain galactokinase activity, indicating that the two Gal1p activities are functionally independent. The KlGal1-m proteins are defective in their ability to interact with Gal80p in a two-hybrid assay. The locations of gal1-m mutations identify putative interaction sites in Gal1p and Gal80p. A dominant mutation, KlGAL1-d, leads to a high level of constitutive expression of genes of the galactose pathway. The behavior of chimeric proteins consisting of Gal3p and KlGal1p sequences indicates that both the N-terminal and C-terminal halves of KlGal1p are involved in specific interaction with KlGal80p. Received: 12 November 1998 / Accepted: 18 December 1998