Identification of mucAB-like homologs on two IncT plasmids, R394 and Rts-1

Recent phylogenetic analysis of the superfamily of lesion-replicating DNA polymerases suggest that they can be broadly divided into four sub-groups comprised of UmuC-like, DinB-like, Rev1-like and Rad30-like proteins. The UmuC-like sub-family is best characterized at the genetic level and sequence analysis of eleven umu orthologs, residing on bacterial chromosomes or on self-transmissible R-plasmids allows further subdivision into five sub-groups (UmuDC, MucAB, ImpAB, RumAB and RulAB) based on amino acid sequence conservation. Some of these orthologs are apparently inactive in situ, but may promote increased mutagenesis and survival when subcloned and expressed from high-copy number plasmids. We were, therefore, interested in devising an assay that would identify umuC-like genes in situ in the absence of a functional assay. To this end, degenerate primers directed towards conserved amino acid regions within the UmuC-like sub-family of DNA polymerases were designed and used to identify mucAB-like operons on the IncT plasmids, R394 and Rts-1.

Interestingly, DNA sequence analysis of an 7 kb region of R394 identified two LexA-regulated genes immediately downstream of mucAB_(R394) that are similar to the chromosomally-encoded Escherichia coli tus gene and the IncI plasmid-encoded impC gene, respectively. Analysis of the R394 and Rts-1 mucB genes revealed that both contain insertions which result in the expression of a truncated inactive MucB protein. While R394 was unable to restore mutagenesis functions to a ΔumuDC E. coli strain, Rts-1 surprisingly promoted significant levels of MMS-induced SOS mutagenesis, raising the possibility that Rts-1 encodes another, yet unidentified, umu-like homolog.     

Analysis of the mutagenic properties of the UmuDC, MucAB and RumAB proteins, using a site-specific abasic lesion

ThemucAB andrumAB loci have been shown to promote mutagenesis to a greater extent than the structurally and functionally homologousEscherichia coli umuDC operon. We have analyzed the basis of this enhanced mutagenesis by comparing the influence of these operons, relative toumuDC, on the mutagenic properties of each of two abasic sites, specifically located in a single-stranded vector. Experiments with these vectors are useful analytical tools because they provide independent estimates of the efficiency of translesion synthesis and of the relative frequencies of each type of nucleotide insertion or other kind of mutagenic event. TheumuDC, mucAB, andrumAB genes were expressed from their naturalLexA-regulated promoter on low-copy-number plasmids in isogenic strains carrying aumuDC deletion. In addition, plasmids expressing the UmuD'C, MucA'B, or RumA'B proteins were also used. Compared toumuDC, the chief effect ofmucAB was to increase the efficiency of translesion synthesis past the abasic site. The enhanced capacity ofmucAB for translesion synthesis depended about equally on an inherently greater capacity to promote this process and on a greater susceptibility of the MucA protein to proteolytic processing. The RumA protein also appeared to be more susceptible to proteolytic processing, but the inherent capacity of theRum products for translesion synthesis was no greater than that ofUmuDC. dAMP was inserted opposite one of the two abasic sites studied at a somewhat greater frequency in strains expressingrum (82%) compared to those expressingumu (72%), which might result in higher mutation frequencies inrumAB than inumuDC strains.     

Proteolytic processing of MucA protein in SOS mutagenesis: Both processed and unprocessed MucA may be active in the mutagenesis

Summary The mucAB operon carried on plasmid pKM101, which is an analogue of the umuDC operon of Escherichia coli, is involved in UV mutagenesis and mutagenesis induced by many chemicals. Mutagenesis dependent on either the umuDC or mucAB operon requires the function of the recA gene and is called SOS mutagenesis. By treating the cell with agents that damage DNA, RecA protein is activated by conversion into a form (RecA^*) that mediates proteolytic cleavage of the LexA repressor and derepresses the SOS genes including mucAB. Since UmuD protein is proteolytically processed to an active form (UmuD^*) in a RecA^*-dependent fashion, and MucA shares extensive amino acid homology with UmuD, we examined whether MucA is similarly processed in the cell, using antiserum against a LacZ-MucA fusion protein. Like UmuD, MucA protein is indeed proteolytically processed in a RecA^*-dependent fashion. In recA430 strains, MucAB but not UmuDC can mediate UV mutagenesis. However, MucA was not processed in the recA430 cells treated with mitomycin C. We constructed, by site-directed mutagenesis, several mutant mucA genes that encode MucA proteins with alterations in the amino acids flanking the putative cleavage site (Ala25-Gly26). MucA(Cys25) was processed and was as mutagenically active as wild-type MucA; MucA(Asp26) and MucA(Cys25,Asp26) were not processed, and were mutagenically inactive; MucA-(Thr25) was not processed, but was mutagenically as active as wild-type MucA. The mutant mucA gene that encoded the putative cleavage product of MucA was as active as mucA ⁺ in UV mutagenesis. These results raise the possibility that both the nascent MucA and the processed product are active in mutagenesis.     

Functional complementation between chromosomal and plasmid mutagenic DNA repair genes in bacteria

Summary The umuDC operons of Escherichia coli and Salmonella typhimurium and the analogous plasmid operons mucAB and impCAB have been previously characterized in terms of their roles in DNA repair and induced mutagenesis by radiation and many chemicals. The interrelationships of these mutagenic DNA repair operons were examined in vivo in functional tests of interchangeability of operon subunits in conferring UV resistance and UV mutability phenotypes to wild-type S. typhimurium and umu mutants of E. coli. This approach was combined with DNA and protein sequence comparisons between the four operons and a fifth operon, samAB, from the S. typhimurium LT2 cryptic plasmid. Components of the E. coli and S. typhimurium umu operons were reciprocally interchangeable whereas impCA and mucA could not function with umuC in either of these species. mucA and impB could also combine to give a mutagenic response to UV. These active combinations were associated with higher degrees of conservation of protein sequence than in other heterologous gene combinations and related to specific regions of sequence that may specify subunit interactions. The dominance of the E. coli umuD44 mutation over umuD was revealed in both wild-type E. coli and S. typhimurium and also demonstrated against impCAB. Finally interspecies transfer showed that the apparently poor activity of the S. typhimurium umuD gene in situ is not the result of an inherent defect in umuD but is due to the simultaneous presence of the S. typhimurium umuC sequence. It is suggested that the limitation of umuD activity by umuC in S. typhimurium is the basis of the poor induced mutability of this organism.     

Different efficiency of UmuDC and MucAB proteins in UV light induced mutagenesis in Escherichia coli

Summary Two multicopy plasmids carrying either the umuDC or the mucAB operon were used to compare the efficiency of UmuDC and MucAB proteins in UV mutagenesis of Escherichia coli K12. It was found that in recA ⁺ uvr ⁺bacteria, plasmid pIC80, mucAB ⁺mediated UV mutagenesis more efficiently than did plasmid pSE117, umuDC ⁺. A similar result was obtained in lexA51(Def) cells, excluding the possibility that this was due to a differential regulation by LexA of the umuDC and mucAB operons. We conclude that some structural characteristic of the UmuDC and MucAB proteins determines their different efficiency in UV mutagenesis. This characteristic could be also responsible for the observation that in the recA430 mutant, pIC80 but no pSE117 can mediate UV mutagenesis. In the recA142 mutant, pIC80 also promoted UV mutagenesis more efficiently than pSE117. In this mutant, the recombination proficiency, the protease activity toward LexA and the mutation frequency were increased by the presence of adenine in the medium. In recA ⁺ uvrB5 bacteria, plasmid pSE117,umuDC caused both an increase in UV sensitivity as well as a reduction in the mutation frequency. These nagative effects resulting from the overproduction of UmuDC proteins were higher in recA142 uvrB5 than in recA ⁺ uvrB5 cells. In contrast, overproduction of MucAB proteins in excision-deficient bacteria containing pIC80 led to a large increase in the mutation frequency. We suggest that the functional differences between UmuDC and MucAB proteins might be due to their different dependence on the direct role of RecA protease in UV mutagenesis.     

The spectra of base substitutions induced by the impCAB, mucAB and umuDC error-prone DNA repair operons differ following exposure to methyl methanesulfonate

We have used the lacZ reversion assay to study the mutation spectra induced by the Escherichia coli chromosomal umuDC operon and of its two plasmid-borne analogues impCAB and mucAB following exposure of cells to UV light and methyl methane-sulfonate (MMS). We have shown that the impCAB, mucAB and umuDC operons all produce a similar response to UV light which results almost exclusively in AT GC transitions. However, we found that the three operons produced different responses to alkylating agents. We found that with MMS the chromosomal umuDC operon produced almost exclusively AT GC transitions, whilst both mucAB and impCAB produced predominantly transversions. In the case of the impCAB operon the mutation spectrum contained more AT TA than GC TA transversions; this balance was reversed with mucAB. The effect of the copy number of the error-prone DNA repair operons upon the mutagenic spectra was also studied. The results obtained suggest that the copy number of the imp operon does not greatly affect the specificity of base substitutions observed. However, an increase in the copy number of the umuDC operon greatly affected the specificity of base substitution, such that virtually no transitions were produced and the spectrum was dominated by GC/AT TA transversions. It appears that the three error-prone DNA repair operons impCAB, mucAB and umuDC, despite showing strong structural and functional homologies, can display major differences in the spectrum of base changes induced during mutagenesis. We propose that the type of misincorporation/chain extension which DNA polymerase III is allowed to synthesize on a damaged DNA template is extremely sensitive to both the amount and type of error-prone repair proteins present. The modulation of these events by the different proteins can result in widely different mutagenic changes in the repaired DNA.     

Survey of resistance gene analogs in <Emphasis Type="Italic">Solanum caripense</Emphasis>, a relative of potato and tomato,and update on <Emphasis Type="Italic">R</Emphasis> gene genealogy

The resistance (R) proteins of the TIR- and non-TIR (or CC-) superfamilies possess a nucleotide binding site (NBS) domain. Within an R gene, the NBS is the region of highest conservation, suggesting an essential role in triggering R protein activity. We compared the NBS domain of functional R genes and resistance gene analogs (RGA) amplified from S. caripense genomic DNA via PCR using specific and degenerate primers with its counterpart from other plants. An overall high degree of sequence conservation was apparent throughout the P-loop, kinase-2 and kinase-3a motifs of NBS fragments from all plants. Within the non-TIR class of R genes a prominent sub-class similar to the potato R1 gene conferring resistance to late blight, was detected. All non-TIR-R1-like R gene fragments that were sequenced possessed an intact open reading frame, whereas 22% of all non-TIR-non-R1-like fragments and 59% of all TIR-NBS RGA fragments had an interrupted reading frame or contained transposon-specific sequence. The non-TIR-R1-like fragments had high similarity to Solanaceae R genes and low similarity to RGAs of other plant species including A. thaliana and the cereals. It is concluded that appearance of the non-TIR-R1-like NBS domain represents a relatively recent evolutionary development. Electronic supplementary material Supplementary material is available in the online version of this article at and is accessible for authorized users.     

Derepression of single-stranded DNA-binding protein genes on plasmids derepressed for conjugation, and complementation of an E. coli ssb- mutation by these genes

Summary Plasmid single-stranded DNA-binding protein genes complement the E. coli ssb-1 mutation, and partially restore capacity for DNA synthesis, DNA repair (direct role as well as role in SOS induction) and general recombination. Plasmid mutants derepressed for fertility derived from R1, R64 and R222 show a higher level of complementation compared to the parental repressed plasmids. Derepressed mutants of R222 synthesize more RNA which hybridizes with the ssb gene of the F factor than does the original R222 plasmid. This indicates that plasmid ssb genes are regulated coordinately with fertility genes.     

The Hermes transposon of Musca domestica and its use as a mutagen of Schizosaccharomyces pombe

Transposon mutagenesis allows for the discovery and characterization of genes by creating mutations that can be easily mapped and sequenced. Moreover, this method allows for a relatively unbiased approach to isolating genes of interest. Recently, a system of transposon based mutagenesis for Schizosaccharomyces pombe became available. This mutagenesis relies on Hermes, a DNA transposon from the house fly that readily integrates into the chromosomes of S. pombe. The Hermes system is distinct from the retrotransposons of S. pombe because it efficiently integrates into open reading frames. To mutagenize S. pombe, cells are transformed with a plasmid that contains a drug resistance marker flanked by the terminal inverted repeats of Hermes. The Hermes transposase expressed from a second plasmid excises the resistance marker with the inverted repeats and inserts this DNA into chromosomal sites. After S. pombe with these two plasmids grow 25 generations, approximately 2% of the cells contain insertions. Of the cells with insertions, 68% contain single integration events. The protocols listed here provide the detailed information necessary to mutagenize a strain of interest, screen for specific phenotypes, and sequence the positions of insertion.     

The linear mitochondrial plasmid pClK1 of the phytopathogenic fungus Claviceps purpurea may code for a DNA polymerase and an RNA polymerase

Summary Plasmid pClK1, a linear mitochondrial plasmid of Claviceps purpurea, was completely sequenced. The sequence contains two long open reading frames (ORF1, 3291 bp; ORF2, 2910 bp), and at least four smaller ORFs. The potential polypeptide derived from ORF1 shows homology to the family B type DNA polymerases. The product of ORF2 has significant homology to the mitochondrial RNA polymerase of yeast and RNA polymerases from bacteriophages. ORF1 and ORF2 show homology to URF3 and URF1 of the maize plasmids S1 and S2, respectively. No homology to any published protein sequence was found for the smaller ORFs. The origin of the terminal protein attached to the 5 ends of pClK1 remains open; several alternatives for its origin are discussed. The sequence data as a whole confirm the virus-like character of pClK1 already postulated from structural properties. Thus pClK1 together with S plasmids of maize and several other linear plasmids make up a distinct class of DNA species of plants and fungi probably derived from a common virus-like ancestor.     

Transposon Tn21 encodes a RecA-independent site-specific integration system

Summary The IncW plasmid R388 and the DNA region of Tn21 containing the Sm^r and the Su^r genes are capable of RecA-independent recombination. This recombination occurs at a relatively high frequency (up to 10^-4 recombinants per recipient molecule) and results in integration of the two plasmids. No detectable repeats are formed in the process. The crossover points have been confined to a 0.4-kb homologous segment in both plasmids which contains a 59-bp DNA sequence presumably involved in the acquisition of new genes by Tn21 and its relatives (Cameron et al. 1986). It is likely that the recombination occurs precisely at this point. At least one trans-acting function (an integrase) is required for the site-specific recombination. It has been localized to a 1456-bp BstEII-BamHI fragment of Tn21 and can efficiently complement the integration of plasmids containing the integration site.     

Identification and autonomous replication capability of a chromosomal replication origin from the archaeon <Emphasis Type="Italic">Sulfolobus solfataricus</Emphasis>

Here, we describe the identification of a chromosomal DNA replication origin (oriC) from the hyperthermophilic archaeon Sulfolobus solfataricus (subdomain of Crenarchaeota). By means of a cumulative GC-skew analysis of the Sulfolobus genome sequence, a candidate oriC was mapped within a 1.12-kb region located between the two divergently transcribed MCM- and cdc6-like genes. We demonstrated that plasmids containing the Sulfolobus oriC sequence and a hygromycin-resistance selectable marker were maintained in an episomal state in transformed S. solfataricus cells under selective pressure. The proposed location of the origin was confirmed by 2-D gel electrophoresis experiments. This is the first report on the functional cloning of a chromosomal oriC from an archaeon and represents an important step toward the reconstitution of an archaeal in vitro DNA replication system.     

Indigenous plasmids and cultural characteristics of rhizobia nodulating chickpeas (Cicer arietinum L.)

We examined 27 strains of chickpea rhizobia from different geographic origins for indigenous plasmids, location and organization of nitrogen fixation (nif) genes, and cultural properties currently used to separate fast- and slow-growing groups of rhizobia. By using an in-well lysis and electrophoresis procedure one to three plasmids of molecular weights ranging from 35 to higher than 380 Mdal were demonstrated in each of 19 strains, whereas no plasmids were detected in the eight remaining strains. Nitrogenase structural genes homologous to Rhizobium meliloti nifHD, were not detected in plasmids of 26 out of the 27 strains tested. Hybridization of EcoRI digested total DNA from these 26 strains to the nif probe from R. meliloti indicated that the organization of nifHD genes was highly conserved in chickpea rhizobia. The only exception was strain IC-72 M which harboured a plasmid of 140 Mdal with homology to the R. meliloti nif DNA and exhibited also a unique organization of nifHD genes. The chickpea rhizobia strains showed a wide variation of growth rates (generation times ranged from 4.0 to 14.5 h) in yeast extract-mannitol medium but appear to be relatively homogeneous in terms of acid production in this medium and acid reaction in litmus milk. Although strains with fast and slow growth rates were identified, DNA/DNA hybridization experiments using a nifHD-specific probe, and the cultural properties examined so far do not support the separation of chickpea rhizobia into two distinct groups of the classical fast- and slow-growing types of rhizobia.     

Site-specific recombination between ColE1 tcer and NTP16 nmr sites in vivo

The site-specific recombination system used by multicopy plasmids of the ColE1 family uses two identical plasmid-encoded recombination sites and four bacterial proteins to catalyze the recombination reaction. In the case of the Escherichia coli plasmid ColE1, the recombination site, cer, is a 280 by DNA sequence which is acted on by the products of the argR, pepA, xerC and xerD genes. We have constructed a model system to study this recombination system, using tandemly repeated recombination sites from the plasmids ColE1 and NTP16. These plasmids have allowed us precisely to define the region of strand exchange during site-specific recombination, and to derive a model for cer intramolecular site-specific recombination.     

Macroptilium atropurpureum (siratro) host specificity genes are linked to a nodD-like gene in the broad host range Rhizobium strain NGR234

Summary A 6.7 kb HindIII fragment from the Sym-plasmid of strain NGR234 was found to code a nodD-like gene flanked by two loci which were required for siratro host range. Transfer of the 6.7 kb fragment from NGR234 to R. trifolii strain ANU843 conferred extended host range ability to this strain on siratro plants but not to other plants normally nodulated by strain NGR234. Tn5 mutagenesis of the 6.7 kb fragment showed that insertions located into loci flanking the nodD-like gene abolished the extended host range phenotype. A hybridization probe spanning one of the host specificity loci was shown to hybridize to three specific bands in the NGR234 genome. Complementation and DNA hybridization data showed that the nodD-like gene of strain NGR234 was functionally similar to that in R. trifolii. The introduction to R. trifolii of the 6.7 kb HindIII fragment containing Tn5 insertions located in the nodD-like gene did not abolish the ability to extend the host range of R. trifolii to siratro plants. However, transfer of the 6.7 kb HindIII to R. trifolii derivatives containing Tn5 insertions into either nodA, B or C or other R. trifolii nod genes failed to confer siratro nodulation to these recipients. Reconstruction experiments showed that the 6.7 kb fragment from strain NGR234 and the 14 kb nodulation region of R. trifolii could induce the nodulation of siratro plants when introduced together into Sym-plasmid-cured Rhizobium strains.     

Genetic analysis of an Agrobacterium tumefaciens strain producing an agrocin active against biotype 3 pathogens

Summary The successful biocontrol agent for crown gall disease, Agrobacterium radiobacter strain K84, is unable to protect grapevines from infection. We have identified a strain of Agrobacterium tumefaciens, J73, which produces an agrocin active both in vitro and in vivo against grapevine pathogens (Webster et al. 1986). We now report on the curing of this strain of its nopaline-type Ti plasmid and the location, by transposon mutagenesis, of the genes involved in the production of the agrocin. The Ti plasmid was cured by the introduction of selectable plasmids carrying the origins of replication of either the nopaline Ti plasmid, pTiC58, or the octopine Ti plasmid, pTi15955. Tn5 mutagenesis indicated that the genes responsible for agrocin production and/or export are located both on the chromosome and on a plasmid, pAgJ73, which co-migrated in agarose gels with pTiJ73. As the two plasmids were separable after transposon mutagenesis, we postulate that during or after mutagenesis of the agrocin plasmid, DNA rearrangements occurred between it and pTiJ73, resulting in an increase in size of pAgJ73. We provide evidence that the rearrangements involved the duplication of nopaline catabolism genes from pTiJ73 and their insertion into pAgJ73, which facilitated the resolution of the two plasmids. As expected pTiJ73 has homology with the nopaline Ti plasmid, pTiC58.     

Mutagenic DNA repair genes on plasmids from the ''pre-antibiotic era''

Summary Resistance transfer factors are natural conjugative plasmids encoding antibiotic resistance. Some also encode mutagenic DNA repair genes giving resistance to DNA damage and induced mutagenesis. It has been shown that antibiotic resistance has been acquired by recent transposition events; however, we show here that mutagenic repair genes existed much earlier on these types of plasmids. Conjugative plasmids from eight incompatibility groups from the Murray collection of pre-antibiotic era enterobacteria were tested for complementation of mutagenic repair-deficient Escherichia coli umuC36. Although none of these plasmids carry transposon-encoded drug resistance genes, IncI1 and IncB plasmids were identified which restored ultraviolet resistance and induced mutability to umuC36 mutants. Furthermore they increased the UV resistance and induced mutability of wild-type E. coli, Klebsiella aerogenes and Citrobacter intermedius, thus showing that they could confer a general selective advantage to a variety of hosts. Like know mutagenic repair genes, complementation by these plasmid genes required the SOS response of the host cell. Nucleotide hybridisation showed that these plasmids harboured sequences similar to the impCAB locus, the mutagenic repair operon of modern-day IncI1 plasmids. The evolution of mutagenic repair genes is discussed.     

Hox Genes from the Tapeworm Taenia asiatica (Platyhelminthes: Cestoda)

Hox genes are important in forming the anterior-posterior body axis pattern in the early developmental stage of animals. The conserved nature of the genomic organization of Hox genes is well known in diverse metazoans. To understand the Hox gene architecture in human-infecting Taenia tapeworms, we conducted a genomic survey of the Hox gene using degenerative polymerase chain reaction primers in Taenia asiatica. Six Hox gene orthologs from 276 clones were identified. Comparative analysis revealed that T. asiatica has six Hox orthologs, including two lab/Hox1, two Hox3, one Dfd/Hox4, and one Lox2/Lox4. The results suggest that Taenia Hox genes may have undergone independent gene duplication in two Hox paralogs. The failure to detect Post1/2 orthologs in T. asiatica may suggest that sequence divergence or the secondary loss of the posterior genes has occurred in the lineage leading to the cestode and trematode.     

An efficient system for site-directed mutagenesis to make various mutants of the env gene of human immunodeficiency virus type 1

We developed an efficient system of site-directed mutagenesis for the envelope (env) gene of human immunodeficiency virus type 1 (HIV-1). To make a template plasmid for mutagenesis, pS+B/MluI, two independent selection markers, i.e. a unique restriction site, MluI, and an in-frame termination codon, were introduced into the region encoding the V3 domain of the env gene of an HIV-1 strain, NL4-3, which had been cloned in the pUC118 plasmid. When the env gene of the pS+B/MluI plasmid was mutated successfully using mutagenic primers such as synthetic oligonucleotides or PCR-amplified DNA fragments longer than 1.5 kbp, the plasmids became resistant to digestion with MluI and competent env genes were formed by suppression of the in-frame termination. Various site-directed mutants of the env gene of HIV-1 were accurately constructed in a short time even in the absence of proper restriction sites by this system. The system of site-directed mutagenesis we reported here will be a useful method to analyze the functions of variable genes like the env gene of HIV-1 precisely and rapidly.     

Dicarboxylic acid transport in Rhizobium meliloti: isolation of mutants and cloning of dicarboxylic acid transport genes

The role of the dicarboxylic acid transport (dct) system in the Rhizobium meliloti-Alfalfa symbiosis was investigated. Mutants of R. meliloti CM2 unable to grow on medium containing succinate as the sole carbon source were isolated following chemical and transposon mutagenesis. These mutants were also unable to utilize malate or fumarate as the sole source of carbon. Transport studies with ¹⁴C-labelled succinate showed that the mutants were specifically defective in succinate transport. Revertants of both chemical and transposon mutants were obtained at a frequency of 10^-5–10^-6. The R. meliloti dct mutants were able to nodulate Alfalfa plants but the nodules formed were unable to fix nitrogen. Revertants of the mutants were fully effective on plants. The mutants unable to transport succinate were used to isolate dct genes from a R. meliloti gene bank. Two plasmids containing a common 26.5 Mdal insert were found to complement some of the mutants. The presence of this DNA insert in the complementing mutant strains restored their effectivenss of plants. This DNA fragment encoding succinate transport function(s) was used to produce genetically engineered R. meliloti strains with an increased rate of succinate uptake.Abbreviation dct dicarboxylic acid transport