Analysis and stability of Zymomonas mobilis ATCC 10988 plasmid pZMO3

Plasmid pZMO3 of Zymomonas mobilis strain ATCC 10988 was found to be nonhomologous either to chromosomal DNA or to any other plasmids of the strains ATCC 10988, NCIB 11163, and CP4. It contained single sites for the restriction endonucleases SphI, BglI, and HindIII, as well as at least four sites for Sau3A. Its origin of replication is located within the 1.54-kb Sau3A fragment as it was found that only the recombinant plasmid pDS3154, which contained this fragment, showed vectorial incompatibility with the native pZMO3 plasmid. The stability of pZMO3 may be controlled by partitioning sequences located in the 0.64-kb Sau3A fragment. Z. mobilis isolates, which had lost plasmid pZMO3, were successfully isolated.     

Molecular cloning and genetic mapping of the DNA topoisomerase II gene of Saccharomyces cerevisiae

The structural gene for DNA topoisomerase II from the yeast Saccharomyces cerevisiae has been cloned. The clones were selected from a YEp13 plasmid bank of yeast DNA by complementing a temperature-sensitive mutation (top2-1) in the topoisomerase II gene, TOP2. Chromosomal integrants of the clone were derived by homologous recombination in strains lacking the 2 mu circle plasmid. Genetic analysis of these integrants indicates that we have cloned the TOP2 gene and not an extragenic suppressor. A YEp13-TOP2 hybrid plasmid integrant was used to localize the TOP2 gene to the left arm of chromosome XIV by the 2 mu circle-directed marker loss method. Results from standard meiotic mapping experiments indicate that TOP2 is about 16 centi-Morgans to the centromere proximal side of MET4. Northern blot analysis of TOP2 RNA isolated from a wild-type strain and from an rna2 mutant shows the RNA to be 4.5 kb long in both cases, thus indicating that the TOP2 gene has no large introns.     

Construction of plasmid vectors that facilitate subcloning and recovery of yeast and Escherichia coli DNA fragments

We have constructed a plasmid vector (pNF2) which is a derivative of the multicopy yeast cloning vehicle YEp24. This derivative contains a single BamHI site flanked immediately on each side by SalI sites. The latter site was selected because it appears to be infrequent in yeast nuclear DNA. Thus, DNA fragments produced by partial digestion with enzymes (such as Sau3A) that cut at frequent intervals and leave single-stranded ends that have sequence homology with BamHI sites, can be conveniently subcloned into this site. Such fragments can then be excised intact by digestion with SalI enzyme. Plasmid pNF2 also contains the kanamycin-resistance (kanR) gene derived from Tn903 and confers resistance in yeast to the antibiotic G418. pNF2 was converted into an integrating vector (pNF3) by deleting a 2.2-kb EcoRI fragment containing a sequence that determines autonomous replication in yeast. Further deletion of a HindIII fragment containing the yeast URA3 gene converts the plasmid into one containing only pBR322 sequences plus the kanR gene (pNF4).     

Cloning of genes related to exo-beta-glucanase production in Saccharomyces cerevisiae: characterization of an exo-beta-glucanase structural gene

The EXG1 gene of Saccharomyces cerevisiae was cloned and identified by complementation of a mutant strain (exg1-2) with highly reduced extracellular exo-beta-1,3-glucanase (EXG) activity. Two recombinant plasmids containing an overlapping region of 5.2 kb were isolated from a genomic DNA library and characterized by restriction mapping. The coding region was located by subcloning the original DNA inserts in a 2.7-kb HindIII-XhoI fragment. Exg+ strains and Exg- mutants transformed with yeast multicopy plasmids containing this DNA fragment showed an EXG activity 5- to 20-fold higher than for the untransformed Exg+ wild-type (wt) strains. The overproduced EXG had the same enzymic activity on different substrates, and showed the same electrophoretic behaviour on polyacrylamide gels and identical properties upon filtration through Sephacryl S-200 as those of the main EXG from Exg+ wt strains. The EXG1 gene transformed Schizosaccharomyces pombe, yielding extracellular EXG activity which showed cross-reactivity with anti-S. cervisiae EXG antibodies. A fragment including only a part of the EXG1 region was subcloned into the integrating vector YIp5, and the resulting plasmid was used to transform an Exg+ strain. Genetic and Southern analysis of several stable Exg- transformants showed that the fragment integrated by homology with the EXG1 locus. The chromosomal DNA fragment into which the plasmid integrated has a restriction pattern identical to that of the fragment on which we had previously identified the putative EXG1 gene. Only one copy of the EXG1 gene per genome was found in several strains tested by Southern analysis. Furthermore, two additional recombinant plasmids sharing a yeast DNA fragment of about 4.1 kb, which partially complements the exg1-2 mutation but which shows no homology with the 2.7-kb fragment containing the EXG1 gene, were also identified in this study. This 4.1-kb DNA fragment does not appear to contain an extragenic suppressor and could be related in some way to EXG production in S. cerevisiae.     

Cloning and characterization of a novel beta-galactosidase-coding gene from Rhizobium meliloti

The Rhizobium meliloti (Rm) lacZ gene provides a convenient model to investigate patterns of gene regulation in these agronomically important bacteria. A gene encoding beta-galactosidase (beta Gal) activity was cloned from R. meliloti by complementing a lactose-negative Escherichia coli mutant. A series of Sau3A subclones was generated in pBR322, and the coding region for the beta Gal-coding gene was localized to a 2.4-kb core fragment. In E. coli 'maxicells', these lacZ subclones produced a 79-kDa polypeptide, irrespective of the fragment size demonstrating that the translation initiation signal(s) are located on the 2.4-kb fragment. Transposon Tn5 mutagenesis and BAL 31 deletion analysis showed that the expression of the Rm lacZ gene in E. coli was dependent on the tetracycline-resistance promoter of pBR322. The cloned sequence was required for beta Gal synthesis in Rhizobium since mutants generated by reverse genetics lack this enzyme and were specifically defective in lactose catabolism.     

Involvement of cdc13+ in mitotic control in Schizosaccharomyces pombe: possible interaction of the gene product with microtubules.

Previous genetic studies have shown that the fission yeast cdc13+ gene product interacts closely with the cdc2+ protein kinase during mitosis. Here, we have cloned the cdc13+ gene from a S. pombe gene bank by complementation of the temperature-sensitive defect of a cdc13-117 mutant strain. The complementing activity was localized to a 1.9-kb XbaI-NsiI DNA fragment, and nucleotide sequencing revealed a 1446-bp open reading frame. The predicted amino acid sequence contained 482 residues and was not homologous to any protein in a protein database. The cdc13+ gene function was confirmed to be essential for cell division since cells carrying a cdc13 null allele arrested with a cdc phenotype. However, unlike any existing temperature-sensitive cdc13 mutants, cdc13 null mutants arrested in G2 without septa or condensed chromosomes indicating that cdc13+ gene function is required at or prior to the initiation of mitotis. cdc13-117 mutant strains were found to be hypersensitive to the tubulin inhibitor thiabendazole. This observation suggests that the cdc13+ gene product, which is required for mitotic initiation, may interact with microtubules.     

Yeast thioredoxin genes

Based on the conserved protein sequence of thioredoxins from yeast and other organisms, two primers were synthesized for polymerase chain reaction of yeast genomic DNA. A 34-base pair (bp) sequence around the active site of yeast thioredoxin was obtained from the polymerase chain reaction product. This specific sequence was used as a probe in Southern blot analysis of total yeast genomic DNA digested with various restriction enzymes. Under conditions of high stringency, more than one DNA species hybridized with the probe, suggesting that more than one gene encodes yeast genomic library. Two Sau3A1 fragments, 825 and 2045 bp, respectively, from two different clones were cloned into pUC13. Sequence analysis of these fragments gave two different open reading frames without introns. The 825-bp Sau3A1 fragment encodes a 103-amino acid residue protein named thioredoxin I. The 2045-bp Sau3A1 fragment contains a sequence encoding thioredoxin II which has 102 amino acid residues. This is the first report of the cloning and sequencing of eukaryotic thioredoxin genes from any source. Both yeast thioredoxins contain a dithiol active site sequence, Cys-Gly-Pro-Cys. Thioredoxins I and II show 78% amino acid sequence identity. They display more amino acid sequence similarity with mammalian thioredoxin than with Escherichia coli and plant chloroplast thioredoxins.     

Molecular cloning of eucaryotic genes required for excision repair of UV-irradiated DNA: isolation and partial characterization of the RAD3 gene of Saccharomyces cerevisiae.

We describe the molecular cloning of a 6-kilobase (kb) fragment of yeast chromosomal DNA containing the RAD3 gene of Saccharomyces cerevisiae. When present in the autonomously replicating yeast cloning vector YEp24, this fragment transformed two different UV-sensitive, excision repair-defective rad3 mutants of S. cerevisiae to UV resistance. The same result was obtained with a variety of other plasmids containing a 4.5-kb subclone of the 6-kb fragment. The UV sensitivity of mutants defective in the RAD1, RAD2, RAD4, and RAD14 loci was not affected by transformation with these plasmids. The 4.5-kb fragment was subcloned into the integrating yeast vector YIp5, and the resultant plasmid was used to transform the rad3-1 mutant to UV resistance. Both genetic and physical studies showed that this plasmid integrated by homologous recombination into the rad3 site uniquely. We conclude from these studies that the cloned DNA that transforms the rad3-1 mutant to UV resistance contains the yeast chromosomal RAD3 gene. The 4.5-kb fragment was mapped by restriction analysis, and studies on some of the subclones generated from this fragment indicate that the RAD3 gene is at least 1.5 kb in size.