In vivo mutational analysis of highly conserved amino acid residues of the small subunit Cpa1p of the carbamylphosphate synthetase of Saccharomyces cerevisiae.

The role of selected amino acid residues located in the putative catalytic domain and of two conserved histidine residues within the small subunit of the carbamylphosphate synthetase (CPS) specific to the arginine biosynthesis pathway of the yeast Saccharomyces cerevisiae was studied using site-directed mutagenesis to change all residues to aspartic acid. Carbamylphosphate synthesis catalysed by modified CPS was tested in vivo. The C264D, H307D and H349D mutants were unable to grow on minimal medium, indicating the importance of these three residues for efficient CPS activity, whereas, four other mutated residues located in the catalytic site (including a proline residue) do not affect the growth rate. These results in comparison to those obtained with the CPS of Escherichia coli, implicate residues Cys 264 and His 349 in the glutaminase catalytic activity, and His 307 in the binding of glutamine to the active site. Using these three defective mutants, we investigated the in vivo utilization of ammonia by CPS. C264D and H307D mutants are able to use ammonia as a substrate when provided in sufficiently high concentrations (up to 200 mM). The H349D mutant, however, did not grow even at ammonium sulfate concentrations above 400 mM, suggesting that this substitution is critical to NH3-dependent CPS activity although the ammonia binding site is presumably located within the large subunit of the enzyme.

Genetic instability and associated genome plasticity in Streptomyces ambofaciens: pulsed-field gel electrophoresis evidence for large DNA alterations in a limited genomic region.

Using pulsed-field gel electrophoresis (PFGE) analysis, the amplifiable units of DNA (AUD) loci AUD6 and AUD90 of Streptomyces ambofaciens DSM40697 could be mapped in the wild-type genome within two adjacent AseI restriction fragments estimated to be about 75 and 850 kb. In addition, the genetic instability and formation of very large deletions were strictly correlated. Their sizes were estimated to range from 250 to more than 2,000 kb. These deletions affected the DNA region overlapping both amplifiable loci. PFGE also allowed us to localize the amplified DNA sequences and to establish their structure: amplification takes place at the AUD locus as a tandem array of the wild-type AUD sequence.

Genetic instability and hypervariability in Streptomyces ambofaciens: towards an understanding of a mechanism of genome plasticity.

Many Streptomyces species exhibit a very high degree of genetic instability which is usually manifested as genomic rearrangements such as large deletions. In Streptomyces ambofaciens DSM40697, two levels of genetic instability were previously described: (i) a basic genetic instability similar to that reported for other strains, and (ii) hypervariability, a phenomenon that we believe to be a new aspect of instability closely associated with DNA amplification. A large DNA region undergoes deletions, amplifications and large genomic changes strictly associated with both aspects of genetic instability. The genetic and molecular analyses of the different aspects of genetic instability allow us to propose that they result from a cascade of molecular events and to investigate the relationships between genetic instability phenomena and genome fluidity.

Hypervariability, a new phenomenon of genetic instability, related to DNA amplification in Streptomyces ambofaciens.

The wild-type strain Streptomyces ambofaciens DSM 40697 exhibits a high degree of genetic instability. Pigment-defective colonies were observed in the progeny of wild-type colonies at a frequency of about 0.01. While only 13% of these pigment-defective colonies gave rise to homogeneous progeny exhibiting the mutant parental phenotype, 87% of the mutant colonies gave rise to hetergeneous progeny without a preponderant phenotype. This new phenomenon of instability was called hypervariability. In addition, 21% of the mutant strains arising in hypervariable progeny contained highly reiterated DNA sequences, while amplified DNA sequences could be detected in neither stable pigment-defective mutant clones nor in wild-type clones. These results indicate a frequent association between genetic instability and hypervariability and a frequent association between hypervariability and amplification of DNA sequences.

Characterization of two families of spontaneously amplifiable units of DNA in Streptomyces ambofaciens.

Four highly amplified DNA sequences (ADS) ranging from 5.8 to 24.8 kb were found in spontaneous mutant strains of Streptomyces ambofaciens DSM 40697. Restriction patterns of total DNA were hybridized with purified ADS6 (24.8 kb) as a probe to detect the amplifiable regions in the wild-type (WT) genome. The results suggested that the amplifiable unit of DNA (AUD) was present as a single copy in the WT genome. Moreover, similarities suggested by the restriction maps of three of the ADS were confirmed by hybridization experiments. The fourth ADS did not hybridize with the three others. Therefore, two families of DNA sequences are potentially amplifiable in the S. ambofaciens genome.