Inactivation of Ymr1, Sjl2/3 phosphatases promotes stress resistance and longevity in wild type and Ras2G19V yeast.

In Saccharomyces cerevisiae, RAt Sarcoma (Ras) activity plays a central role in mediating the effect of glucose in decreasing stress resistance and longevity, with constitutive Ras activation mutations promoting cell growth and oncogenesis. Here, we used transposon mutagenesis in yeast to identify suppressors of the constitutively active Ras2G19V, orthologue of the KRASG12C mammalian oncogene. We identified mutations in Yeast Myotubularin Related (YMR1), SynaptoJanin-Like (SJL2) and SJL3 phosphatases, which target phosphatidylinositol phosphates, as the most potent suppressors of constitutive active Ras, able to reverse its effect on stress sensitization and sufficient to extend longevity. In sjl2 mutants, the staining of Ras-GTP switched from membrane-associated to a diffuse cytoplasmic staining, suggesting that it may block Ras activity by preventing its localization. Whereas expression of the Sjl2 PI 3,4,5 phosphatase mediated stress sensitization in both the Ras2G19V and wild type backgrounds, overexpression of the phosphatidylinositol 3 kinase VPS34 (Vacuolar Protein Sorting), promoted heat shock sensitization only in the Ras2G19V background, suggesting a complex relationship between different phosphatidylinositol and stress resistance. These results provide potential targets to inhibit the growth of cancer cells with constitutive Ras activity and link the glucose-dependent yeast pro-aging Ras signaling pathway to the well-established pro-aging PhosphoInositide 3-Kinase(PI3K) pathway in worms and other species raising the possibility that the conserved longevity effect of mutations in the PI3K-AKT (AK strain Transforming) pathway may involve inhibition of Ras signaling.

PAH gene mutations in the Sicilian population: association with minihaplotypes and expression analysis.

The molecular basis of PAH deficiency in the Sicilian population is characterized by a marked heterogeneity, with 44 mutations at a single locus identified by a "gene-scanning" approach and accounting for a detection rate of 91%. The remaining 9% of PAH alleles does not bear mutations in any of the 13 exons and 24 exon/intron junctions. Three mutations IVS10nt-11 G > A, R261Q, and A300S accounted for 30.5%, whereas the remaining mutations were found at relative frequencies of less than 5% and 20 mutations were observed once only. Five mutations have been detected only in Sicilians so far. By studying the association of mutations with intragenic STR-VNTR haplotypes ("minihaplotypes"), "identity by descent" has been established for 24 mutations also detected in other populations. This finding supports the hypothesis of a multipolar origin for a large proportion of PAH mutant alleles currently detected in Sicilians. In order to improve our understanding of the clinical heterogeneity of PAH deficiency in this population, we have for the first time analyzed three missense mutations L41F, T92I, and P211T in vitro by the pCDNA3/COS-7 eukaryotic expression system and found an activity of 10, 76, and 72%, respectively, compared to normal PAH. In two HPA patients with mild PKU and mild hyperphenylalaninemia (MHP), harboring respectively L41F/R261Q and T92I/P281L genotypes, the predicted biochemical effect of these genotypes appeared to be consistent with the metabolic phenotypes. In contrast, discordant metabolic phenotypes (mild PKU and MHP) were observed in two unrelated patients bearing the same R261Q/P211T genotype, a finding which underscores the complex relationship linking genotype to phenotype in PAH deficiency. Hypotheses on the possible mechanisms responsible for the observed discordance are discussed. The spectrum of PAH gene mutations in Sicily reflects the complex demographic history of this island at the crossroad of prehistoric and historical migrations in the Mediterranean sea. The data presented in this study also add to the present knowledge on the relationship between PAH genotypes and HPA phenotype and are expected to improve PAH genotyping among individuals with hyperphenylalaninemia.

The IgE-binding epitopes of rPar j 2, a major allergen of Parietaria judaica pollen, are heterogeneously recognized among allergic subjects.

Pollen allergens are multivalent proteins that cross-link IgE antibodies on mast or basophil cells, inducing secretion of biologic mediators, and resulting in various allergic symptoms. The IgE-binding regions of the Parietaria judaica (Pj) pollen major allergen rPar j 2 were investigated. Twenty-nine single sera from Pj-allergic subjects were tested by Western blot against five recombinant peptides. At least four putative IgE-binding epitopes were identified. The analysis of their diffusion suggested a heterogeneous IgE-binding response. In fact, 75% of the sera reacted with peptide 1-54, 48% with peptide 48-101, 24% with peptide 1-30, 7% with peptide 29-54, and none with peptide 48-76. These five peptides were analyzed with the histamine-release assay. Only peptide 48-101 was capable of inducing degranulation and release of histamine. These results suggest that the recombinant rPar j 2 allergen contains IgE epitopes that are heterogeneously recognized by sensitive patients, and that therefore the therapeutic approach based on the use of haptenic peptides needs a careful evaluation.

Identification of an immunodominant IgE epitope of the Parietaria judaica major allergen.

Par j 1.0101 is one of the two major allergens of the Parietaria judaica (Pj) pollen, and its three-dimensional structure was built by three-dimensional structural homology modeling. The resultant model was used to identify putative IgE binding regions. Western blot analysis of gene fragmentation products showed that the 1 to 30 region was capable of binding specific IgE from a pool of sera (n = 30) of patients allergic to Pj pollen. Using the structural model as a guide, deletion and site-directed mutagenesis of the 1 to 30 region was performed, and the amino acids involved in IgE binding were identified. In addition, a synthetic peptide covering the 1 to 30 region was capable of binding human IgE without triggering histamine release from basophils of Pj allergic patients (n = 6) and thus represents a haptenic molecule with potential use as an immunotolerant agent. This epitope is also present on the Par j 2.0101 major allergen representing a common IgE epitope. It is an immunodominant epitope, since it was capable of inhibiting 30% of all specific IgE against the Pj major allergens, and therefore, it might be a candidate for the future development of immunotherapeutics.

cDNA cloning, sequence analysis and allergological characterization of Par j 2.0101, a new major allergen of the Parietaria judaica pollen.

A clone (P2) coding for an allergen of Parietaria judaica (Pj) pollen has been isolated and sequenced from a cDNA library in lambda ZAP using a pool of 23 sera from Pj-allergic patients. The clone contained an insert of 622 nucleotides with an open reading frame of 133 amino acids (aa) and a putative signal peptide of 31 aa giving a deduced mature processed protein of 102 aa with a molecular mass of 11344 Da. The expressed recombinant protein, named rPar j 2.0101, was a major allergen since it reacted with IgE of 82% (23/28) of the sera of Pj-allergic subjects analyzed. It was shown to be a new allergen since (i) the amino acid sequence homology with the already reported recombinant allergen Par j 1.0101 was 45% and (ii) there was no cross-inhibition between rPar j 2.0101 and rPar j 1.0101. In addition, rPar j 2.0101 inhibited 35% of the specific IgE for 10-14 kDa native allergens and preincubation of sera from Pj-allergic patients with both rPar j 2.0101 and rPar j 1.0101 fully abolished the IgE recognition of the 10-14 kDa native allergen region, suggesting that these two allergens contributed to the region.

Mutagenic alteration of the distal switch II region of RAS blocks CDC25-dependent signaling functions.

We have explored the role of the distal switch II region of the yeast RAS2 protein in determining the response to the nucleotide exchange factor CDC25. We first constructed yeast tester strains in which the deletion of the chromosomal CDC25, RAS1, and RAS2 genes, in combination with the chromosomal suppressor CRI4, resulted in detectable phenotypes in vivo and in vitro. Phenotypes included impaired growth at 37 degrees C, defective glucose-induced cyclic AMP signaling, and low adenylyl cyclase activity of membrane preparations. Tester strains were subsequently used for the reintroduction of various combinations of wild-type and mutated RAS2 and CDC25 genes by genetic techniques, as well as for in vitro reconstitution assays with the corresponding proteins. CDC25 restored both growth and glucose-induced cyclic AMP signaling in the presence, but not in the absence of wild-type RAS2. A gene encoding a RAS2 protein with a mutationally altered switch II region was expressed but was ineffective in reintegrating exchange factor-dependent responses in vivo. Wild-type, but not mutagenically altered, RAS2 proteins were stimulated by exchange factors in vitro. We conclude that the conserved distal switch II region is required for CDC25-dependent activation of RAS.

The SCH9 protein kinase mRNA contains a long 5' leader with a small open reading frame.

The SCH9 yeast gene, that was previously identified as a suppressor of cdc25 and ras1- ras2-ts temperature-sensitive mutants, encodes a putative protein kinase that positively regulates the progression of yeast cells through the G1 phase of the cell cycle. We have determined the structure of the SCH9 transcription unit, using primer extension and S1 mapping techniques. The corresponding mRNA included an unusually long 5' region of more than 600 nucleotides preceding the major open reading frame (ORF). While the latter corresponded to a protein of 824 amino acids, an upstream open reading frame (uORF) within the 5' leader could potentially encode a 54 amino acid peptide. To investigate the role of the AUGs within the uORF, we engineered chimaeric plasmid vectors in which SCH9 sequences including the promoter, the mRNA leader and the first 514 nucleotides of the major ORF were fused in-frame with beta-galactosidase-coding sequences. Upon introduction into yeast cells, the fusion protein was efficiently expressed. However, mutational disruption of the uORF using oligonucleotide-directed mutagenesis did not affect the level of expression of the fusion protein. This indicates that regulatory mechanisms in Saccharomyces cerevisiae prevent upstream AUGs within the SCH9 mRNA leader sequence from influencing translation from downstream initiation codons.

RAS residues that are distant from the GDP binding site play a critical role in dissociation factor-stimulated release of GDP.

We have previously shown that a conserved glycine at position 82 of the yeast RAS2 protein is involved in the conversion of RAS proteins from the GDP- to the GTP-bound form. We have now investigated the role of glycine 82 and neighbouring amino acids of the distal switch II region in the physiological mechanism of activation of RAS. We have introduced single and double amino acid substitutions at positions 80-83 of the RAS2 gene, and we have investigated the interaction of the corresponding proteins with a yeast GDP dissociation stimulator (SDC25 C-domain). Using purified RAS proteins, we have found that the SDC25-stimulated conversion of RAS from the GDP-bound inactive state to the GTP-bound active state was severely impaired by amino acid substitutions at positions 80-81. However, the rate and the extent of conversion from the GDP- to the GTP-bound form in the absence of dissociation factor was unaffected. The insensitivity of the mutated proteins to the dissociation factor in vitro was paralleled by an inhibitory effect on growth in vivo. The mutations did not significantly affect the interaction of RAS with adenylyl cyclase. These findings point to residues 80-82 as important determinants of the response of RAS to GDP dissociation factors. This suggests a molecular model for the enhancement of nucleotide release from RAS by such factors.