酿酒酵母菌葡萄糖信号传导途径研究进展

简要概述了酿酒酵母细胞的葡萄糖信号传导途径的研究进展,总结了葡萄糖的抑制途径和诱导途径.     

Post-translational processing of urea amidolyase in Saccharomyces cerevisiae.

Urea amidolyase catalyzes the two reactions (urea carboxylase and a allophanate hydrolase) associated with urea degradation in Saccharomyces cerevisiae. Past work has shown that both reactions are catalyzed by a 204-kilodalton, multifunctional protein. In view of these observations, it was surprising to find that on induction at 22 degrees C, approximately 2 to 6 min elapsed between the appearance of allophanate hydrolase and urea carboxylase activities. In search of an explanation for this apparent paradox, we determined whether or not a detectable period of time elapsed between the appearance of allophanate hydrolase activity and activation of the urea carboxylase domain by the addition of biotin. We found that a significant portion of the protein produced immediately after the onset of induction lacked the prosthetic group. A steady-state level of biotin-free enzyme was reached 16 min after induction and persisted indefinitely thereafter. These data are consistent with the suggestion that sequential induction of allophanate hydrolase and urea carboxylase activities results from the time required to covalently bind biotin to the latter domain of the protein.     

Stereochemical specificity for sterols in Saccharomyces cerevisiae

When sterol biosynthesis in oxygen-deprived wild type Saccharomyces cerevisiae was prevented by the presence of 2,3-iminosqualene, an inhibitor of 2,3-oxidosqualene cyclase, an absolute requirement for a sterol with a 24 beta-methyl group was found. Neither the configuration nor the size of the alkyl group at C-24 could be altered. For instance, while 24 beta-methylcholesterol (22-dihydrobrassicasterol) permitted good growth, contrary to earlier work without the inhibitor no growth at all resulted from the presence of cholesterol or its 24 alpha-methyl-, 24 alpha-ethyl-, or 24 beta-ethyl derivatives (campesterol, sitosterol, and clionasterol, respectively). The only sterol lacking a 24 beta-methyl group which allowed growth was desmosterol (24-dehydro-cholesterol), but desmosterol was metabolized to 24 beta-methylcholesterol by C1-transfer and reduction. When cholesterol supported growth in the absence of the inhibitor, small amounts of endogenously synthesized 24 beta-methylsterols (ergosterol and 22-dihydroergosterol) were identified. This previously unrecognized absolute specificity for both chirality and bulk at C-24 suggests the involvement of protein binding in at least one of the roles which sterol plays in this single-celled eukaryote.     

Val216 decides the substrate specificity of alpha-glucosidase in Saccharomyces cerevisiae.

Differences in the substrate specificity of alpha-glucosidases should be due to the differences in the substrate binding and the catalytic domains of the enzymes. To elucidate such differences of enzymes hydrolyzing alpha-1,4- and alpha-1,6-glucosidic linkages, two alpha-glucosidases, maltase and isomaltase, from Saccharomyces cerevisiae were cloned and analyzed. The cloned yeast isomaltase and maltase consisted of 589 and 584 amino acid residues, respectively. There was 72.1% sequence identity with 165 amino acid alterations between the two alpha-glucosidases. These two alpha-glucosidase genes were subcloned into the pKP1500 expression vector and expressed in Escherichia coli. The purified alpha-glucosidases showed the same substrate specificities as those of their parent native glucosidases. Chimeric enzymes constructed from isomaltase by exchanging with maltase fragments were characterized by their substrate specificities. When the consensus region II, which is one of the four regions conserved in family 13 (alpha-amylase family), is replaced with the maltase type, the chimeric enzymes alter to hydrolyze maltose. Three amino acid residues in consensus region II were different in the two alpha-glucosidases. Thus, we modified Val216, Gly217, and Ser218 of isomaltase to the maltase-type amino acids by site-directed mutagenesis. The Val216 mutant was altered to hydrolyze both maltose and isomaltose but neither the Gly217 nor the Ser218 mutant changed their substrate specificity, indicating that Val216 is an important residue discriminating the alpha-1,4- and 1,6-glucosidic linkages of substrates.     

Photoinactivation of peptide transport in Saccharomyces cerevisiae

Oligopeptides and dipeptides are transported into Saccharomyces cerevisiae by a carrier-mediated system. In the dark, leucyl-p-nitroanilide (Leu-p-NA) and leucyl-leucyl-4-azido-2-nitrophenylalanine [Leu-Leu-Phe-(4N3,2NO2)] are competitive inhibitors of peptide transport by S. cerevisiae cells. The photolysis of yeast cells in the presence of Leu-p-NA or Leu-Leu-Phe(4N3,2NO2) at 350 nm results in an irreversible inactivation of peptide transport. Protection against this inactivation is afforded by an excess of trimethionine, a transported peptide. Photolysis with Leu-p-NA or Leu-Leu-Phe(4N3,2NO2) does not affect amino acid or sugar transport, and cell viability is maintained throughout the irradiation procedure. A 5-min irradiation of S. cerevisiae with 2.4 microM Leu-p-NA or 15 microM Leu-Leu-Phe(4N3,2NO2) causes 50% inhibition of trimethionine uptake. p-Nitroaniline, a possible hydrolysis product generated from Leu-p-NA by cellular peptidase activity, has no effect on peptide transport. An exogenous energy source is not required for photoinactivation. The results suggest that a component(s) of the peptide transport system of S. cerevisiae is irreversibly modified by photolysis with Leu-p-NA or Leu-Leu-Phe-(4N3,2NO2) and provide the first example of the use of amino acid p-nitroanilides as photoaffinity labels.     

Molecular specificity of 2-aminopurine in Saccharomyces cerevisiae

The rates of DNA, RNA and protein synthesis were investigated by incorporation of radioactive precursors into the excised root tips of V. faba. 2-h exposure to 0.1% caffeine resulted in inhibition of protein synthesis to about 60% of the control rate. RNA synthesis was reduced in the range of 20–30%. The same concentration of caffeine did not affect the rate of DNA synthesis even during 12-h incubation, but concentrations higher than 1% caused a significant decrease in [³H]thymidine incorporation.     

Molecular specificity of x-radiation and its repair in Saccharomyces cerevisiae.

Molecular specificity of soft X-radiation has been studied in yeast by analyzing the transitions UAA in equilibrium UAG and nonsense leads to sense mutations in the codon tyr7-1. Synchronized cell populations in the most radiosensitive and radioresistant stages were compared: they did not show any qualitative or quantitative differences in their sensitivities to the mutagenic action of X-rays. We conclude that repair mechanisms, which remain unexpressed in the sensitive cells, do not affect point mutations of the base-substitution type.     

A nuclear mutation prevents processing of a mitochondrially encoded membrane protein in Saccharomyces cerevisiae.

Subunit II of cytochrome oxidase is encoded by the mitochondrial OXI1 gene in Saccharomyces cerevisiae. The temperature-sensitive nuclear pet mutant ts2858 has an apparent higher mol. wt. subunit II when analyzed on lithium dodecylsulfate (LiDS) polyacrylamide gels. However, on LiDS-6M urea gels the apparent mol. wt. of the wild-type protein exceeds that of the mutant. Partial revertants of mutant ts2858 that produce both the wild-type and mutant form of subunit II were isolated. The two forms of subunit II differ at the N-terminal part of the molecule as shown by constructing and analyzing nuclear ts2858 and mitochondrial chain termination double mutants. The presence of the primary translation product in the mutant and of the processed form in the wild-type lacking 15 amino-terminal residues was demonstrated by radiolabel protein sequencing. Comparison of the known DNA sequence with the partial protein sequence obtained reveals that six of the 15 residues are hydrophilic and, unlike most signal sequences, this transient sequence does not contain extended hydrophobic parts. The nuclear mutation ts2858 preventing post-translational processing of cytochrome oxidase subunit II lies either in the gene for a protease or an enzyme regulating a protease.     

Functional specificity of the mitochondrial DnaJ protein, Mdj1p, in Saccharomyces cerevisiae

Inactivation of the gene for the mitochondrial DnaJ homolog, Mdj1p, in Saccharomyces cerevisiae results in temperature sensitivity and the loss of respiratory activity; the latter phenotype has been attributed to the loss of mitochondrial DNA. To investigate the functional specificity of Mdj1p, non-mitochondrial DnaJ proteins were targeted to mitochondria and tested for their ability to substitute for Mdj1p. The tested DnaJ proteins were able to complement the two Mdj1p-linked phenotypes, i.e., respiratory activity and growth at 37 °C, to different extents, ranging from full to very poor complementation. All DnaJ homologs ensured faithful propagation of the mitochondrial genome. N-terminal fragments of Mdj1p and Escherichia coli DnaJ comprising the well-characterized J domain partially substituted for Mdj1p. As the only hitherto known function of the N-terminal fragment is modulation of the substrate binding activity of the cognate Hsp70, we conclude that both Mdj1p-linked phenotypes – maintenance of respiratory activity and the ability to grow at elevated temperature – involve a mitochondrial Hsp70 partner protein. Received: 8 October 1999 / Accepted: 21 January 2000     

Defective processing of ribosomal precursor RNA in Saccharomyces cerevisiae.

Saccharomyces cerevisiae (strain A224A) has an abnormal distribution of cytoplasmic ribosomal subunits when grown at 36 degrees C, with sucrose-gradient analysis of extracts revealing an apparent excess of material sedimenting at 60 S. This abnormality is not observed at either 23 degrees C or 30 degrees C. At 36 degrees C the defect(s) is expressed as a slowed conversion of 20 S ribosomal precursor RNA to mature 18 S rRNA, although the corresponding maturation of 27 S ribosomal precursor RNA to mature 25 S rRNA is normal. Studies on this yeast strain and on mutants derived from it may help to elucidate the role(s) of individual ribosomal components in controlling ribosome biogenesis in eukaryotes.     

Topology of ER processing alpha-mannosidase of Saccharomyces cerevisiae.

The yeast specific alpha-mannosidase which converts Man9GlcNAc to a single isomer of Man8GlcNAc is involved in N-linked oligosaccharide processing in the endoplasmic reticulum (ER). Sequence analysis of the structural gene for this enzyme suggested that it is a type II transmembrane protein (Camirand et al., 1991). To firmly establish its membrane topology, the gene was transcribed in vitro and translation was performed in a reticulocyte lysate with and without dog pancreas microsomal membranes. Sodium dodecyl sulphate-polyacrylamide gel electrophoresis (SDS-PAGE) of [35S]methionine-labelled products showed that the largest band formed corresponded in size to the 63 kDa peptide expected from the alpha-mannosidase gene product. It was transformed into a 4 kDa larger endoglycosidase H-sensitive band in the presence of microsomal membranes. This glycosylated translation product was completely protected from proteinase K digestion in the absence of detergent. These results demonstrate that the yeast ER alpha-mannosidase is a type II membrane protein, like Golgi enzymes involved in N-linked glycosylation.     

Signal recognition particle receptor is important for cell growth and protein secretion in Saccharomyces cerevisiae.

In mammalian cells, the signal recognition particle (SRP) receptor is required for the targeting of nascent secretory proteins to the endoplasmic reticulum (ER) membrane. We have identified the Saccharomyces cerevisiae homologue of the alpha-subunit of the SRP receptor (SR alpha) and characterized its function in vivo. S. cerevisiae SR alpha is a 69-kDa peripheral membrane protein that is 32% identical (54% chemically similar) to its mammalian homologue and, like mammalian SR alpha, is predicted to contain a GTP binding domain. Yeast cells that contain the SR alpha gene (SRP101) under control of the GAL1 promoter show impaired translocation of soluble and membrane proteins across the ER membrane after depletion of SR alpha. The degree of the translocation defect varies for different proteins. The defects are similar to those observed in SRP deficient cells. Disruption of the SRP101 gene results in an approximately sixfold reduction in the growth rate of the cells. Disruption of the gene encoding SRP RNA (SCR1) or both SCR1 and SRP101 resulted in an indistinguishable growth phenotype, indicating that SRP receptor and SRP function in the same pathway. Taken together, these results suggest that the components and the mechanism of the SRP-dependent protein targeting pathway are evolutionarily conserved yet not essential for cell growth. Surprisingly, cells that are grown for a prolonged time in the absence of SRP or SRP receptor no longer show pronounced protein translocation defects. This adaptation is a physiological process and is not due to the accumulation of a suppressor mutation. The degree of this adaptation is strain dependent.     

Accumulation of processing intermediates of the RAS2 protein in strain 112 of Saccharomyces cerevisiae

Strain 112 (RAS1 RAS2) contains a naturally occurring mutation which significantly retards processing of the RAS2 gene product. This mutation, resulting in the accumulation of precursor forms of RAS2 protein, has been assigned by genetic analysis to a single chromosomal locus distinct from the RAS2 locus. In addition to the known precursor molecule of 41000 daltons (p41), 112 cells accumulate within the soluble fraction an intermediate form of RAS2 (p40-1), which migrates, in SDS-polyacrylamide gel, between p41 and the fully processed, membrane-bound 40,000 daltons (p40) product. We propose for RAS2 protein processing the following sequence of events: p41 greater than p40-1 greater than p40 where p40-1 represents a RAS2 intermediate required for the targeting of the protein to the plasma membrane.     

Lipid raft-based membrane compartmentation of a plant transport protein expressed in Saccharomyces cerevisiae

The hexose-proton symporter HUP1 shows a spotty distribution in the plasma membrane of the green alga Chlorella kessleri. Chlorella cannot be transformed so far. To study the membrane localization of the HUP1 protein in detail, the symporter was fused to green fluorescent protein (GFP) and heterologously expressed in Saccharomyces cerevisiae and Schizosaccharomyces pombe. In these organisms, the HUP1 protein has previously been shown to be fully active. The GFP fusion protein was exclusively targeted to the plasma membranes of both types of fungal cells. In S. cerevisiae, it was distributed nonhomogenously and concentrated in spots resembling the patchy appearance observed previously for endogenous H(+) symporters. It is documented that the Chlorella protein colocalizes with yeast proteins that are concentrated in 300-nm raft-based membrane compartments. On the other hand, it is completely excluded from the raft compartment housing the yeast H(+)/ATPase. As judged by their solubilities in Triton X-100, the HUP1 protein extracted from Chlorella and the GFP fusion protein extracted from S. cerevisiae are detergent-resistant raft proteins. S. cerevisiae mutants lacking the typical raft lipids ergosterol and sphingolipids showed a homogenous distribution of HUP1-GFP within the plasma membrane. In an ergosterol synthesis (erg6) mutant, the rate of glucose uptake was reduced to less than one-third that of corresponding wild-type cells. In S. pombe, the sterol-rich plasma membrane domains can be stained in vivo with filipin. Chlorella HUP1-GFP accumulated exactly in these domains. Altogether, it is demonstrated here that a plant membrane protein has the property of being concentrated in specific raft-based membrane compartments and that the information for its raft association is retained between even distantly related organisms.     

Characterization of two telomeric DNA processing reactions in Saccharomyces cerevisiae.

We have investigated two reactions that occur on telomeric sequences introduced into Saccharomyces cerevisiae cells by transformation. The elongation reaction added repeats of the yeast telomeric sequence C1-3A to telomeric sequences at the end of linear DNA molecules. The reaction worked on the Tetrahymena telomeric sequence C4A2 and also on the simple repeat CA. The reaction was orientation specific: it occurred only when the GT-rich strand ran 5' to 3' towards the end of the molecule. Telomere elongation occurred by non-template-directed DNA synthesis rather than any type of recombination with chromosomal telomeres, because C1-3A repeats could be added to unrelated DNA sequences between the CA-rich repeats and the terminus of the transforming DNA. The elongation reaction was very efficient, and we believe that it was responsible for maintaining an average telomere length despite incomplete replication by template-directed DNA polymerase. The resolution reaction processed a head-to-head inverted repeat of telomeric sequences into two new telomeres at a frequency of 10(-2) per cell division.