Molecular structure and genetic regulation of SFA, a gene responsible for resistance to formaldehyde in Saccharomyces cerevisiae, and characterization of its protein product

Summary A 3.7 kb DNA fragment of yeast chromosome IV has been sequenced that contains the SFA gene which, when present on a multi-copy plasmid in Saccharomyces cerevisiae, confers hyper-resistance to formaldehyde. The open reading frame of SFA is 1158 by in size and encodes a polypeptide of 386 amino acids. The predicted protein shows strong homologies to several mammalian alcohol dehydrogenases and contains a sequence characteristic of binding sites for NAD. Overexpression of the SFA gene leads to enhanced consumption of formaldehyde, which is most probably the reason for the observed hyper-resistance phenotype. In sfa:LEU2 disruption mutants, sensitivity to formaldehyde is correlated with reduced degradation of the chemical. The SFA gene shares an 868 by divergent promoter with UGX2 a gene of yet unknown function. Promoter deletion studies with a SFA promoter-lacZ gene fusion construct revealed negative interference on expression of SFA by upstream sequences. The upstream region between positons – 145 and – 172 is totally or partially responsible for control of inducibility of SFA by chemicals such as formaldehyde (FA), ethanol and methyl methanesulphonate. The 41 kDa SFA-encoded protein was purified from a hyper-resistant transformant; it oxidizes long-chain alcohols and, in the presence of glutathione, is able to oxidize FA. SFA is predicted to code for a long-chain alcohol dehydrogenase (glutathione-dependent formaldehyde dehydrogenase) of the yeast S. cerevisiae.     

Characterization and Sequence Analysis of the Replicator Region of the Novel Plasmid pALC1 from Paracoccus alcaliphilus

The replicator region of a low-copy-number plasmid, pALC1, of Paracoccus alcaliphilus JCM 7364 was cloned in a form of the minireplicon pALC100 (3.6 kb). The host range of the minireplicon embraces several species of genus Paracoccus, as well as Agrobacterium tumefaciens, Rhizobium leguminosarum, and Rhodobacter sphaeroides (all belonging to alpha-Proteobacteria), but not Escherichia coli. The complete nucleotide sequence of the replicator region (2276 bp) revealed the presence of one complete open reading frame coding for the 28.4-kDa protein (RepA) with similarity to replication proteins of plasmid pSW500 of Erwinia stewartii and pVS1 of Pseudomonas fluorescens. The iteron-like region was identified upstream of the repA gene and consisted of two clusters of repeated sequences (17 bp long) separated by a putative DnaA box. Analysis of the predicted amino acid sequence of two adjacent incomplete ORFs suggests the localization of repA between genes involved in conjugation (traG) and partitioning (parA) within the pALC1 genome.     

Genetic characterization and sequence analysis of the duplicated nifA/nifB gene region of Rhodobacter capsulatus

Summary A DNA region showing homology to Klebsiella pneumoniae nifA and nifB is duplicated in Rhodobacter capsulatus. The two copies of this region are called nifA/nifB copy I and nifA/nifB copy II. Deletion mutagenesis demonstrated that either of the two copies is sufficient for growth in nitrogen-free medium. In contrast, a double deletion mutant turned out to be deficient in nitrogen fixation. The complete nucleotide sequence of a 4838 bp fragment containing nifA/nifB copy I was determined. Two open reading frames coding for a 59653 (NifA) and a 49453 (NifB) dalton protein could be detected. Comparison of the amino acid sequences revealed that the R. capsulatus nifA and nifB gene products are more closely related to the NifA and NifB proteins of Rhizobium meliloti and Rhizobium leguminosarum than to those of K. pneumoniae. A rho-independent termination signal and a typical nif promoter region containing a putative NifA binding site and a consensus nif promoter are located within the region between the R. capsulatus nifA and nifB genes. The nifB sequence is followed by an open reading frame (ORF1) coding for a 27721 dalton protein in nifA/nifB copy I. DNA sequence analysis of nifA/nifB copy II showed that both copies differ in the DNA region downstream of nifB and in the noncoding sequence in front of nifA. All other regions compared, i.e. the 5 part of nifA, the intergenic region and the 3 part of nifB, are identical in both copies.     

Negative regulators of the PHO system in Saccharomyces cerevisiae: isolation and structural characterization of PHO85.

One of the negative regulators of the PHO system of Saccharomyces cerevisiae, PHO85, has been isolated by transformation and complementation of a pho85 strain. The complementing activity was delimited within a 1258 bp DNA segment and this region has been sequenced. The largest open reading frame found in this region can encode a protein of 302 amino acid residues. A pho85 mutant resulted from disruption of the chromosomal counterpart of the open reading frame described above. Therefore, we concluded that the gene we have cloned is PHO85. This result also indicates that PHO85 is nonessential. Northern analysis revealed that the size of the PHO85 message is 1.1 kb. No similarity was found between the putative amino acid sequences of two negative regulators, the PHO80 and PHO85 proteins.     

Separate genes encode functionally equivalent ADP/ATP carrier proteins in Saccharomyces cerevisiae. Isolation and analysis of AAC2

Genetic and biochemical analysis of Saccharomyces cerevisiae containing a disruption of the nuclear gene (AAC1) encoding the mitochondrial ADP/ATP carrier has revealed a second gene for this protein. The second gene, designated AAC2, has been isolated by genetic complementation and sequenced. AAC2 contains a 954-base pair open reading frame coding for a protein of 318 amino acids which is highly homologous to the AAC1 gene product except that it is nine amino acids longer at the NH2 terminus. The two yeast genes are highly conserved at the level of DNA and protein and share identity with the ADP/ATP carriers from other organisms. Both genes complement an ADP/ATP carrier defect (op1 or pet9). However, the newly isolated gene AAC2 need be present only in one or two copies while the previously isolated AAC1 gene must be present in multiple copies to support growth dependent on a functional carrier protein. This gene dosage-dependent complementation combined with the high degree of conservation suggest that these two functionally equivalent genes may be differentially expressed.     

Cloning and characterization of a lysine decarboxylase gene from Hafnia alvei

Summary A lysine decarboxylase (LDC) gene from Hafnia alvei was cloned in the Escherichia coli strain HB101. A gene bank consisting of 2,000 clones, carrying recombinant plasmids with large DNA fragments of H. alvei integrated in the BamH1 site of pBR322, was screened for LDC activity by a colony filter radioimmunoassay. The gene bank yielded clone 462 expressing high LDC activity with the presence of a plasmid carrying a 7.5 kb insert of H. alvei. Two LDC-positive subclones derived from 462 with inserts of 2.9 and 3.3 kb were sequenced by the shotgun method. An open reading frame for a 83 K protein with 739 amino acids was determined as the coding region for the LDC. The identification of this reading frame as the true reading frame of the H. alvei LDC gene and its similarities with LDC of E. coli are described. The use of the cloned gene for the transformation of plant cells is discussed.     

Analysis of putative DNA amplification genes in the element AUD1 of Streptomyces lividans 66

The amplifiable AUD1 element of Streptomyces lividans 66 consists of two copies of a 4.7 kb sequence flanked by three copies of a 1 kb sequence. The DNA sequences of the three 1 kb repeats were determined. Two copies (left and middle repeats) were identical: (1009 by in length) and the right repeat was 1012 bp long and differed at 63 positions. The repeats code for open reading frames (ORFs) with typical Streptomyces codon usage, which would encode proteins of about 36 kD molecular weight. The sequences of these ORFs suggest that they specify DNA-binding proteins and potential palindromic binding sites are found adjacent to the genes. The putative amplification protein encoded by the right repeat was expressed in Escherichia coli.