Roles for Pbp1 and caloric restriction in genome and lifespan maintenance via suppression of RNA-DNA hybrids.

Intergenic transcription within repetitive loci such as the ribosomal DNA (rDNA) repeats of yeast commonly triggers aberrant recombination. Major mechanisms suppressing aberrant rDNA recombination rely on chromatin silencing or RNAPII repression at intergenic spacers within the repeats. We find ancient processes operating at rDNA intergenic spacers and other loci to maintain genome stability via repression of RNA-DNA hybrids. The yeast Ataxin-2 protein Pbp1 binds noncoding RNA, suppresses RNA-DNA hybrids, and prevents aberrant rDNA recombination. Repression of RNA-DNA hybrids in Pbp1-deficient cells through RNaseH overexpression, deletion of the G4DNA-stabilizing Stm1, or caloric restriction operating via RNaseH/Pif1 restores rDNA stability. Pbp1 also limits hybrids at non-rDNA G4DNA loci including telomeres. Moreover, cells lacking Pbp1 have a short replicative lifespan that is extended upon hybrid suppression. Thus, we find roles for Pbp1 in genome maintenance and reveal that caloric restriction counteracts Pbp1 deficiencies by engaging RNaseH and Pif1.

A domino effect in antifolate drug action in Escherichia coli.

Mass spectrometry technologies for measurement of cellular metabolism are opening new avenues to explore drug activity. Trimethoprim is an antibiotic that inhibits bacterial dihydrofolate reductase (DHFR). Kinetic flux profiling with (15)N-labeled ammonia in Escherichia coli reveals that trimethoprim leads to blockade not only of DHFR but also of another critical enzyme of folate metabolism: folylpoly-gamma-glutamate synthetase (FP-gamma-GS). Inhibition of FP-gamma-GS is not directly due to trimethoprim. Instead, it arises from accumulation of DHFR's substrate dihydrofolate, which we show is a potent FP-gamma-GS inhibitor. Thus, owing to the inherent connectivity of the metabolic network, falling DHFR activity leads to falling FP-gamma-GS activity in a domino-like cascade. This cascade results in complex folate dynamics, and its incorporation in a computational model of folate metabolism recapitulates the dynamics observed experimentally. These results highlight the potential for quantitative analysis of cellular metabolism to reveal mechanisms of drug action.

Mutagenesis of folylpolyglutamate synthetase indicates that dihydropteroate and tetrahydrofolate bind to the same site.

The folylpolyglutamate synthetase (FPGS) enzyme of Escherichia coli differs from that of Lactobacillus casei in having dihydrofolate synthetase activity, which catalyzes the production of dihydrofolate from dihydropteroate. The present study undertook mutagenesis to identify structural elements that are directly responsible for the functional differences between the two enzymes. The amino terminal domain (residues 1-287) of the E. coli FPGS was found to bind tetrahydrofolate and dihydropteroate with the same affinity as the intact enzyme. The domain-swap chimera proteins between the E. coli and the L. casei enzymes possess both folate or pteroate binding properties and enzymatic activities of their amino terminal portion, suggesting that the N-terminal domain determines the folate substrate specificity. Recent structural studies have identified two unique folate binding sites, the omega loop in L. casei FPGS and the dihydropteroate binding loop in the E. coli enzyme. Mutants with swapped omega loops retained the activities and folate or pteroate binding properties of the rest of the enzyme. Mutating L. casei FPGS to contain an E. coli FPGS dihydropteroate binding loop did not alter its substrate specificity to using dihydropteroate as a substrate. The mutant D154A, a residue specific for the dihydropteroate binding site in E. coli FPGS, and D151A, the corresponding mutant in the L. casei enzyme, were both defective in using tetrahydrofolate as their substrate, suggesting that the binding site corresponding to the E. coli pteroate binding site is also the tetrahydrofolate binding site for both enzymes. Tetrahydrofolate diglutamate was a slightly less effective substrate than the monoglutamate with the wild-type enzyme but was a 40-fold more effective substrate with the D151A mutant. This suggests that the 5,10-methylenetetrahydrofolate binding site identified in the L. casei ternary structure may bind diglutamate and polyglutamate folate derivatives.

Transcriptional regulation of the one-carbon metabolism regulon in Saccharomyces cerevisiae by Bas1p.

The mechanisms mediating responses to glycine withdrawal in budding yeast were studied using a genome-wide profiling approach. A striking pattern of repressed expression of genes with an enrichment for those involved in one-carbon metabolism and AMP biosynthesis was revealed. Sequence analysis of the promoters for the most severely repressed genes identified a conserved sequence, TGACTC, a known binding site for the transcription factors Gcn4p and Bas1p. Loss of BAS1 abolished or significantly reduced the repression of these genes in response to glycine removal but this phenotype was much less apparent in the absence of BAS2 or GCN4. Addition of a Bas1p-LexA fusion protein to a strain with a LexAop-LacZ fusion showed a strong glycine effect both in a BAS2 and a bas2 background. A Bas1p-VP16 fusion protein activated expression in a bas1bas2 strain but no glycine effect was observed while a Bas1p-Bas2p fusion protein activated expression to a lesser extent with a slight stimulation by glycine. These results suggest that glycine affects Bas1p activation of transcription rather than DNA binding and that Bas2p is not required for this affect. Glycine withdrawal repressed many of the same genes as addition of adenine, a process known to be dependent on Bas1p. However, the glycine response is independent of adenine repression, because glycine regulation occurs normally in ade strains. We did not see any difference in the degree of stimulation by glycine in the presence or absence of adenine even in Ade+ strains. Glycine regulation was also found to be dependent on an intact SHM2 gene, which encodes cytoplasmic serine hydroxymethyltransferase. A reporter plasmid containing a DNA sequence from the GCV2 promoter which confers glycine regulation on heterologous genes was introduced into the yeast deletion set to screen for genes required for glycine regulation. A number of genes, including BAS1 were required for activation by glycine but only the SHM2 gene was required for repression in the absence of glycine. We also showed that regulation of the SHM2 promoter by glycine requires Bas1p but not Bas2p or Gcn4p using a beta-galactosidase reporter. The response of the promoter to glycine required an intact SHM2 gene but was restored in a shm2 strain by addition of formate to the medium.