RecBC, sbcB independent, (AT)n-mediated deletion of sequences flanking a Xenopus laevis beta globin gene on propagation in E. coli.

Plasmids containing sequences 3' of the adult beta 1 globin gene of Xenopus laevis are unstable on propagation in a range of E. coli host strains. Up to 300 bp of Xenopus DNA are lost by rec A independent recombination between (AT)37 and (AT)17 sequences. Additionally, smaller deletions occurring in or around the (AT)37 sequence are observed. Deletion of these potential cruciform structures occurs in the absence of exonuclease I, exonuclease V and exonuclease VIII as the same pattern of deletion events is observed in recA recBC sbcB and recBC sbcA recE strains.     

Identification and characterization of the Escherichia coli RecT protein, a protein encoded by the recE region that promotes renaturation of homologous single-stranded DNA.

Recombination of plasmid DNAs and recombination of bacteriophage lambda red mutants in recB recC sbcA Escherichia coli mutants, in which the recE region is expressed, do not require recA. The recE gene is known to encode exonuclease VIII (exoVIII), which is an ATP-independent exonuclease involved in the RecE pathway of recombination. A 33,000-molecular-weight (MW) protein was observed to be coexpressed with both exoVIII and a truncated version of exoVIII, pRac3 exo, when they were overproduced under the control of strong promoters. We have purified this 33,000-MW protein (p33) and demonstrated by protein sequence analysis that it is encoded by the same coding sequence that encodes the C-terminal 33,000-MW portion of exoVIII. p33 is expressed independently of exoVIII but is probably translated from the same mRNA. p33 was found to bind to single-stranded DNA and also to promote the renaturation of complementary single-stranded DNA. It appears that p33 is functionally analogous to the bacteriophage lambda beta protein, which may explain why RecE pathway recombination does not require recA.     

Mutation avoidance and DNA repair proficiency in Ustilago maydis are differentially lost with progressive truncation of the REC1 gene product.

The REC1 gene of Ustilago maydis has an uninterrupted open reading frame, predicted from the genomic sequence to encode a protein of 522 amino acid residues. Nevertheless, an intron is present, and functional activity of the gene in mitotic cells requires an RNA processing event to remove the intron. This results in a change in reading frame and production of a protein of 463 amino acid residues. The 3'-->5' exonuclease activity of proteins derived from the REC1 genomic open reading frame, the intronless open reading frame, and several mutants was investigated. The mutants included a series of deletions constructed by removing restriction fragments at the 3' end of the cloned REC1 gene and a set of mutant alleles previously isolated in screens for radiation sensitivity. All of these proteins were overproduced in Escherichia coli as N-terminal polyhistidine-tagged fusions that were subsequently purified by immobilized metal affinity chromatography and assayed for 3'-->5' exonuclease activity. The results indicated that elimination of the C-terminal third of the protein did not result in a serious reduction in 3'-->5' exonuclease activity, but deletion into the midsection caused a severe loss of activity. The biological activity of the rec1-1 allele, which encodes a truncated polypeptide with full 3'-->5' exonuclease activity, and the rec1-5 allele, which encodes a more severely truncated polypeptide with no exonuclease activity, was investigated. The two mutants were equally sensitive to the lethal effect of UV light, but the spontaneous mutation rate was elevated 10-fold over the wild-type rate in the rec1-1 mutant and 100-fold in the rec1-5 mutant. The elevated spontaneous mutation rate correlated with the ablation of exonuclease activity, but the radiation sensitivity did not. These results indicate that the C-terminal portion of the Rec1 protein is not essential for exonuclease activity but is crucial in the role of REC1 in DNA damage repair.     

Genetic and molecular analyses of the C-terminal region of the recE gene from the Rac prophage of Escherichia coli K-12 reveal the recT gene.

The nucleotide sequence of the C-terminal region of the recE gene of the Rac prophage of Escherichia coli K-12 reveals the presence of a partially overlapping reading frame we call recT. Deletion mutations show that recT is required for the RecE pathway of conjugational recombination. By cloning recT with a plasmid vector compatible with pBR322, we showed by cis-trans tests that the portion of the recE gene encoding ExoVIII DNA nuclease activity is also required for RecE pathway conjugational recombination. The recT gene can replace the redB gene of lambda for recA-independent plasmid recombination. A Tn10 insertion mutation previously thought to be in recE is located in recT and is renamed recT101::Tn10. Discrepancies between the molecular mass estimates of wild-type ExoVIII protein determined from mobility in sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) and calculated from the predicted amino acid sequence are discussed. The hypothesis that wild-type ExoVIII protein results from fusion of RecE and RecT proteins is disproved genetically, thus supporting a previous hypothesis that the discrepancies are due to abnormal protein mobility in SDS-PAGE. A computer-performed scan of the bacteriophage nucleotide sequence data base of GenBank revealed substantial similarity between most of recE and a 2.5-kb portion of the b2 region of lambda. This suggests interesting speculations concerning the evolutionary relationship of lambda and Rac prophages.     

Genetic analysis of the RecE pathway of genetic recombination in Escherichia coli K-12.

The RecE pathway of genetic recombination in Escherichia coli K-12 was defined to be the pathway that is utilized in deoxyribonucleic acid exonuclease V (ExoV)-defective cells which express constitutively recE+, the structural gene for deoxyribonucleic acid exonuclease VIII. Dependence on ExoVIII was shown by the occurrence in a recB21 sbcA23 strain of recombination deficiency mutations in recE, the structural gene for ExoVIII. Point mutations in recE were found as well as deletion mutations in which the entire Rac prophage, carrying recE, was lost. In addition, strain construction and mutagenesis revealed the dependence of the RecE pathway on recA+ and on recF+. Dependence on a fourth gene was shown by a mutation (rec-77) which does not map near the other genes. The problem of distinguishing the RecE pathway from that previously called RecF is discussed.     

Alterations in the two globular domains or in the connecting alpha-helix of bacterial ribosomal protein L9 induces +1 frameshifts

The ribosomal 50S subunit protein L9, encoded by the gene rplI, is an elongated protein with an alpha-helix connecting the N- and C-terminal globular domains. We isolated rplI mutants that suppress the +1 frameshift mutation hisC3072 in Salmonella enterica serovar Typhimurium. These mutants have amino acid substitutions in the N-terminal domain (G24D) or in the C-terminal domain (I94S, A102D, G126V, and F132S) of L9. In addition, different one-base deletions in rplI altered either the final portion of the C terminus or removed the C-terminal domain with or without the connecting alpha-helix. An alanine-to-proline substitution at position 59 (A59P), which breaks the alpha-helix between the globular domains, induced +1 frameshifting, suggesting that the geometrical relationship between the N and C domains is important to maintain the reading frame. Except for the alterations G126V in the C terminus and A59P in the connecting alpha-helix, our results confirm earlier results obtained by using the phage T4 gene 60-based system to monitor bypassing. The way rplI mutations suppress various frameshift mutations suggests that bypassing of many codons from several takeoff and landing sites occurred instead of a specific frameshift forward at overlapping codons.     

Plasmidic recombination in Escherichia coli K-12: the role of recF gene function

Interplasmidic and intraplasmidic recombination proficiencies were determined in E. coli bacterial strains carrying rec mutations. Our results defined the role of recF gene function, recB, recC, and sbcB gene products (exonuclease V and exonuclease I) in plasmidic recombination in wild-type E. coli cells and in cells in which the recE recombination pathway is activated. RecF gene function is required for interplasmidic recombination regardless of the recB recC genotype. Intraplasmidic recombination is recF dependent in cells having a functional exonuclease V, but not in recB recC mutants. Exonuclease V activity inhibits both interplasmidic and intraplasmidic recombination via the recE pathway.     

Production of chimeric protein coded by the fused viral H-ras and human N-ras genes in Escherichia coli

A new method for the production of a chimeric protein of two related genes has been developed. The nucleotide sequences of the region from the N terminus to the 86th amino acid (aa) residue of human N-ras and of the Harvey sarcoma virus (Ha-MuSV) H-ras are 80% homologous. We isolated the DNA fragment encoding the N-terminal portion up to the 70th aa residue from plasmid pH-1 which encodes the total genome of Ha-MuSV, and the DNA fragment encoding the C-terminal portion from the 40th aa to the C terminus from plasmid p6a1 which includes the human N-ras cDNA but lacks the N-terminal portion. After partial digestion of both fragments with phage lambda exonuclease, which creates 3'-protruding ends, a hybrid was formed between 73% homologous single-stranded DNA portions at the 3' ends of both fragments. The hybrid was recloned on pBR322 after repairing with Escherichia coli DNA polymerase I and DNA ligase. The chimeric v-H/N-ras gene composed of the N-terminal portion of v-H-ras gene and the remaining region of N-ras gene was inserted into an expression vector containing two tandem trp promoters and a terminator, and expressed in E. coli. The chimeric protein was found to accumulate to approx. 10% of total cellular proteins.     

Nonviable mutants of simian virus 40 with deletions near the 3'' end of gene A define a function for large T antigen required after onset of viral DNA replication

Deletion mutants of simian virus 40 (SV40) with lesions at the three DdeI sites near the 3' end of the early region were constructed. Mutants with deletions at 0.203 and 0.219 map units (mu) which did not change the large T antigen reading frame were viable. This extends slightly the upstream boundary for the location of viable mutants with deletions in the 3' end of the A gene. Mutants with frameshift deletions at 0.193 and 0.219 mu were nonviable. These are the first nonviable mutants with deletions in this portion of the A gene. None of the three nonviable mutants with deletions at 0.219 mu produced progeny viral DNA. These three mutants all used the alternate reading frame located in this portion of the SV40 early region. The mutant with a deletion at 0.193 mu, dlA2459, was positive for viral DNA replication and was defective for adenovirus helper function. All of these mutations were located in the portion of the SV40 large T antigen which has no homology to the polyoma T antigens. These results indicate that this portion of large T antigen is required for some late step in the viral growth cycle and suggest that adenovirus helper function is required for productive infection by SV40.     

Restriction nuclease and enzymatic analysis of transposon-induced mutations of the Rac prophage which affect expression and function of recE in Escherichia coli K-12.

Fourteen Tn5-generated mutations of the Rac prophage, called sbc because they suppress recB21 recC22, were found to fall into two distinct types: type I mutations, which were insertions of Tn5, and type II mutations, which were insertions of IS50. Both orientations of Tn5 and IS50 were represented among the mutants and were arbitrarily labeled A and B. All 14 of the Tn5 and IS50 insertions occurred in the same location (+/- 100 base pairs) approximately 5.6 kilobases from one of the hybrid attachment sites. Eleven of the mutants contained essentially the same amount of exonuclease VIII, the product of recE. The possibility that a promoter for recE was created by the insertion of Tn5 and IS50 was considered. Two IS50 mutants in which such a promoter could not have been created showed three to four times as much exonuclease VIII, and another showed one-half as much as the majority. The possibility was considered that a promoter internal to IS50 is responsible for this heterogeneity. Restriction alleviation was measured in all 14 mutants. An insertion of the transposon Tn10 which reduces expression of exonuclease VIII (recE101::Tn10) was located within the Rac prophage at a position 2.35 kilobases from the left hybrid attachment site. Location and orientation of the Rac prophage on the Escherichia coli genetic map are discussed in light of these results.     

Mutations in fliK and flhB affecting flagellar hook and filament assembly in Salmonella typhimurium.

Mutations in the fliK gene of Salmonella typhimurium commonly cause failure to terminate hook assembly and initiate filament assembly (polyhook phenotype). Polyhook mutants give rise to pseudorevertants which are still defective in hook termination but have recovered the ability to assemble filament (polyhook-filament phenotype). The polyhook mutations have been found to be either frameshift or nonsense, resulting in truncation of the C terminus of FliK. Intragenic suppressors of frameshift mutations were found to be ones that restored the original frame (and therefore the C-terminal sequence), but in most cases with substantial loss of natural sequence and sometimes the introduction of artificial sequence; in no cases did intragenic suppression occur when significant disruption remained within the C-terminal region. By use of a novel PCR protocol, in-frame deletions affecting the N-terminal and central regions of FliK were constructed and the resulting phenotypes were examined. Small deletions resulted in almost normal hook length control and almost wild-type swarming. Larger deletions resulted in loss of control of hook length and poor swarming. The largest deletions severely affected filament assembly as well as hook length control. Extragenic suppressors map to an unlinked gene, flhB, which encodes an integral membrane protein (T. Hirano, S. Yamaguchi, K. Oosawa, and S.-I. Aizawa, J. Bacteriol. 176:5439-5449, 1994; K. Kutsukake, T. Minamino, and T. Yokoseki, J. Bacteriol. 176:7625-7629, 1994). They were either point mutations in the C-terminal cytoplasmic region of FlhB or frameshift or nonsense mutations close to the C terminus. The processes of hook and filament assembly and the roles of FliK and FlhB in these processes are discussed in light of these and other available data. We suggest that FliK measures hook length and, at the appropriate point, sends a signal to FlhB to switch the substrate specificity of export from hook protein to late proteins such as flagellin.     

Structure-function analysis of the BEACH protein LvsA

Most eukaryotes have several members of the BEACH family of proteins but the molecular function of these large proteins remains unknown. The Dictyostelium BEACH protein LvsA is essential for cytokinesis and contractile vacuole activity. The functional contribution of different portions of LvsA was tested here by deletion analysis. The C-terminal WD domain was important for protein stability and C-terminal deletions resulted in loss of LvsA function. In contrast, N-terminal deletions yielded abundant protein expression that could be assayed for function. Despite very low sequence conservation of the N-terminal portion of LvsA, this region is important for its function in vivo . Deletion of 689 N-terminal amino acids produced a protein that was functional in cytokinesis but partially functional in osmoregulation. Further deletions resulted in the complete loss of LvsA function. Using in vitro fractionation assays we found that LvsA sedimented with membranes but that this association does not require the N-terminal portion of LvsA. Interestingly, the association of LvsA with the contractile vacuole was perturbed by the loss of drainin, a protein important for vacuole function. In drainin-null cells, LvsA bound irreversibly to engorged contractile vacuoles that fail to expel water. These experiments help delineate the biochemical and physiological requirements for function of one important BEACH protein, LvsA.     

Cloning and identification of bacteriophage T4 gene 2 product gp2 and action of gp2 on infecting DNA in vivo.

We sequenced bacteriophage T4 genes 2 and 3 and the putative C-terminal portion of gene 50. They were found to have appropriate open reading frames directed counterclockwise on the T4 map. Mutations in genes 2 and 64 were shown to be in the same open reading frame, which we now call gene 2. This gene codes for a protein of 27,068 daltons. The open reading frame corresponding to gene 3 codes for a protein of 20,634 daltons. Appropriate bands on polyacrylamide gels were identified at 30 and 20 kilodaltons, respectively. We found that the product of the cloned gene 2 can protect T4 DNA double-stranded ends from exonuclease V action.     

Cloning and expression analysis of a MAPKKK gene and a novel nodulin gene of Lotus japonicus

We isolated a cDNA encoding mitogen-activated protein kinase kinase kinase alpha, designated LjM3Kalpha, from Lotus japonicus, a model legume. The gene was expressed constitutively in roots, root nodules, and shoots. We also identified a novel nodulin gene, LjNUF, that shows specific expression in nodules. LjNUF resembles the C-terminal half of a hypothetical protein (pir//D85436), the N-terminal half of which is similar to a portion of mitogen-activated protein kinase kinase kinase gamma. Although LjNUF was predicted to be a secreted protein, its function remains to be clarified.     

Sequence of the lyc gene encoding the autolytic lysozyme of Clostridium acetobutylicum ATCC824: comparison with other lytic enzymes

The lyc gene, encoding an autolytic lysozyme from Clostridium acetobutylicum ATCC824, has been cloned. The nucleotide sequence of the lyc gene has been determined and found to encode a protein of 324 amino acids (aa) with a deduced Mr of 34,939. The lyc gene is preceded by two open reading frames with unknown functions, suggesting that this gene is part of an operon. Comparison between the deduced aa sequence of the lyc gene and the directly determined N-terminal sequence of the extracellular clostridial lysozyme suggests that the enzyme is synthesized without a cleavable signal peptide. Moreover, the comparative analyses between the clostridial lysozyme and other known cell-wall lytic enzymes revealed a significant similarity with the N-terminal portion of the lysozymes of Streptomyces globisporus, the fungus Chalaropsis, the Lactobacillus bulgaricus bacteriophage mv1, and the Streptococcus pneumoniae bacteriophages of the Cp family (CPL lysozymes). In addition, the analyses showed that the C-terminal half of the clostridial lysozyme was homologous to the N-terminal domain of the muramoyl-pentapeptide-carboxypeptidase of Streptomyces albus, suggesting a role in substrate binding. The existence of five putative repeated motifs in the C-terminal region of the autolytic lysozyme suggests that this region could play a role in the recognition of the polymeric substrate.