Functional characterization of the repA replication gene of linear plasmid prophage N15

The prophage of coliphage N15 is not integrated into the chromosome, but exists as a linear plasmid molecule with covalently closed ends. The only phage gene required for replication of circular N15 miniplasmids is repA (gene 37). Here we show that RepA-driven replication of the N15-based circular and linear miniplasmids is independent of host DnaB helicase protein, but requires the host DnaG primase. Replication of phage N15 DNA during lytic growth following infection does not depend on either DnaG or DnaB, but DnaG is required for lytic development after induction of the N15 lysogen. Finally, protein sequence analysis and replication data using different mutant strains suggest that RepA protein combines helicase and primase functions.     

YfiF,an unknown protein,affects initiation timing of chromosome replication in Escherichia coli

The Escherichia coli YfiF protein is functionally unknown, being predicted as a transfer RNA/ribosomal RNA (tRNA/rRNA) methyltransferase. We find that absence of the yfiF gene delays initiation of chromosome replication and the delay is reversed by ectopic expression of YfiF, whereas excess YfiF causes an early initiation. A slight decrease in both cell size and number of origin per mass is observed in ΔyfiF cells. YfiF does not genetically interact with replication proteins such as DnaA, DnaB, and DnaC. Interestingly, YfiF is associated with ribosome modulation factor (RMF), hibernation promotion factor (HPF), and the tRNA methyltransferase TrmL. Defects in replication initiation of Δrmf, Δhpf, and ΔtrmL can be rescued by overexpression of YfiF, indicating that YfiF is functionally identical to RMF, HPF, and TrmL in terms of replication initiation. Also, YfiF interacts with the rRNA methyltransferase RsmC. Moreover, the total amount of proteins and DnaA content per cell decreases or increases in the absence of YfiF or the presence of excess YfiF. These facts suggest that YfiF is a ribosomal dormancy-like factor, affecting ribosome function. Thus, we propose that YfiF is involved in the correct timing of chromosome replication by changing the DnaA content per cell as a result of affecting ribosome function.     

Vaccinia virus DNA ligase is nonessential for virus replication: Recovery of plasmids from virus-infected cells

The essentiality of the vaccinia virus DNA ligase gene, SalF 15R, for virus growth was tested by insertional mutagenesis. A plasmid containing E. coli gpt inserted within a large deletion in the DNA ligase gene was transfected into vaccinia virus-infected cells and recombinant viruses selected by three cycles of plaque purification in the presence of mycophenolic acid (MPA). Surprisingly, in some isolates, which replicated in a manner indistinguishable from wild type (WT) virus, the WT gene was replaced by the gpt allele, demonstrating that the DNA ligase gene is nonessential for growth in cultured cells. In other isolates the entire plasmid was integrated into the virus genome by a single crossover event and a functional copy of the DNA ligase was retained. Southern blot analyses of the latter, drug-resistant viruses indicated extra DNA fragments, of sizes inconsistent with predicted viral structures, which represent the plasmid products of homologous recombination. Hirt extracts from cells infected with such multiply plaque purified virus isolates yielded plasmids that produced ampicillin-resistant colonies after transformation of E. coli. These plasmids were of two structures, representing either the original plasmid used for transfection, or a plasmid containing the WT ligase gene rescued by recombination with the virus genome. Similarly, insertional mutagenesis of the vaccinia virus thymidine kinase (TK) gene with gpt yielded plasmids containing mutant or wild type TK alleles when recombinant viruses were selected in MPA. Such plasmids were not isolated when TK minus viruses were selected in 5-bromodeoxyuridine (BUdR).     

Evolution of Lambdoid Replication Modules

Comparison of the putative iteron-binding proteins of lambdoid phages allows us to propose that in the case of lambdoid replication modules, the units on which natural selection acts do not coincide with the open reading frames. Rather, the first replication gene is split into two segments, and its 3 part (corresponding to the C-terminal domain of the iteron-binding protein) forms one unit with the second gene. We also propose from the phylogenetic analysis of phage-encoded homologs of E. coli DnaB and DnaC, that the recombination with the host sequences is not frequent. Accessory ATP-ases for helicase loading (E. coli DnaC homologs) may not be universal replication proteins. Our analysis may suggest that the bacterial helicase loaders might be of phage origin. The comparison of DnaC homologs of enterobacteria and enterobacterial phages supports the experimental data on residues important in interaction with DnaB. We propose that construction of plasmids carrying the replication origins of lambdoid prophages could be useful not only in further research on DNA replication but also on the role of these prophages in shuttling genes for bacterial virulence. The phage replication sequences could be also useful for identification of clinical enterobacterial isolates.     

Factors influencing the copy number of F-like plasmids in Escherichia coli and Salmonella typhimurium

The copy numbers of Flac, four F-like plasmids and pLT2 were estimated in two strains of Salmonella typhimurium and (for all except pLT2) one strain of Escherichia coli. For organisms grown in casamino acids minimal medium, the plasmids spanned a 7–8 fold range of copy number with ColB-K98 having the highest copy number in each strain and R124 the lowest. The copy number of ColB-K98 was substantially greater than 1 in each of the strains tested. There was no clear relation between the plasmid size and copy number, although the plasmids studied spanned only a narrow size range. The copy number of individual plasmids was slightly reduced or not affected at all by the presence of a second plasmid in the same strain. Derivatives harbouring each of the plasmids were grown in three different media to ascertain how plasmid copy number responds to changes in growth rate. For each plasmid, the copy number increased with decreasing growth rate. Extracts from each of the three strains harbouring ColB-K98 contained two distinct plasmid species. One appeared to be about twice as large as the other and both were absent from Col^? segregants.     

Repair of plasmid DNA used for transformation of <Emphasis Type="Italic">Rhizopus oryzae</Emphasis> by gene conversion

Techniques for genetic manipulation of the filamentous fungus Rhizopus have been hampered due to a lack of understanding regarding the recombination and replication mechanisms that affect the fate of introduced DNA. The ability to target chromosomal integration of a plasmid has been difficult because DNA transformed into Rhizopus rarely integrates and is autonomously replicated in a high molecular weight concatenated arrangement (i.e., series or chain). Linearization of the plasmid prior to transformation at a site having homology with the genomic DNA yields the highest frequency of integration, but repair of the double-strand break by end-joining is still the predominant event. We recently attempted to circumvent replication of the plasmid by introducing frameshift mutations in pyrG, the R. oryzae orotidine-5-monophosphate decarboxylase gene used for selection of the vector. It was hypothesized that autonomous replication of the mutated plasmids would be incapable of restoring prototrophic growth, since the genomic pyrG also contained a mutation. However, homologous integration of the plasmid results in duplication of the pyrG gene, which can create a functional copy of pyrG if both the genomic and plasmid mutations are paired on the same duplicate copy. While this event was detected in one of the isolates, it represented less than 8% of the total transformants. The majority of transformants contained plasmid replicating autonomously in a concatenated arrangement. Sequence analysis showed that prototrophic growth was restored by repairing the non-functional pyrG sequence in the plasmid, while the genomic pyrG gene was unaltered. Frequent transfer of the genomic pyrG mutation to the plasmid suggests that gene conversion is likely occurring by recombination pathways involving break-induced replication or synthesis-dependent strand annealing.USDA: Names are necessary to report factually on available data; however, the USDA neither guarantees nor warrants the standard of the product, and the use of the name by USDA implies no approval of the product to the exclusion of others that may also be suitable.     

Isolation and characterization of a mutant of Haemophilus influenzae type b deficient in outer membrane protein P1.

The gene for outer membrane protein P1 of Haemophilus influenzae type b has been previously cloned and expressed in Escherichia coli. To investigate the physiologic role of the P1 protein, the cloned P1 gene was insertionally inactivated with the Tn5 derivative Tn5tac1, and an isogenic P1-deficient Haemophilus mutant was then generated by transformation with linearized plasmid DNA containing the insertionally inactivated gene. The P1-deficient strain grew normally in vitro and induced bacteremia in the infant rat model.     

Mutagenic DNA repair in Escherichia coli. XVIII. Involvement of DNA polymerase III alpha-subunit (DnaE protein) in mutagenesis after exposure to UV light

UV light was unable to induce rifampicin-resistant mutations at 43 degrees C in Escherichia coli ER11 dnaE486. Although DnaE486 gene product is inactive at 43 degrees C, these bacteria contain the pcbA1 mutation which allows DNA replication provided DNA polymerase I is functional. The experiments were carried out under conditions where full expression of rifampicin-resistant mutations could occur so that the lack of induced mutations cannot be ascribed to an effect of incubation at 43 degrees C on mutation expression. UV-mutability at 43 degrees C was restored by the presence of the dnaE+ allele on a plasmid. It is concluded that functional DnaE protein is essential for UV mutagenesis. The dnaE486 mutation also blocked the induction at 43 degrees C of mutations induced by UV plus delayed photoreversal, a procedure that has been postulated to reflect an early misincorporation step in the UV mutagenic process.     

Amplification of the yeast nuclear gene MRS3 confers suppression of a mitochondrial RNA splice defect

Summary The MRS3 gene cloned in the multicopy plasmid YEp13 suppresses the mitochondrial splice defect exerted by mutation M1301 in the group II intron bIl. In this article we report on the behavior of the MRS3 gene cloned in the integration vector pEMBLYi27 and in the CEN4-ARS vector YCp50. Transformation of mutant M1301 cells with these recombinant vectors produced transformants, the majority of which showed the original splice defect and contained the recombinant vectors in single or low copy; a minority, however, was splicing competent and showed exceptionally high copy numbers of the MRS3 gene. These latter transformants had either the pEMBLYi27/MRS3 sequence repeated at least 20 times in tandem at the chromosomal site of the MRS3 gene or they had the YCp50/MRS3 sequence established as a multicopy plasmid lacking the copy number control usually exerted by the CEN4 sequence in this plasmid.     

Multiple copies of the amdS gene of Aspergillus nidulans cause titration of trans-acting regulatory proteins

Summary It has been established that a plasmid containing the amdS gene of Aspergillus nidulans may be used to transform amdS⁺ strains by selecting for increased utilization of acetamide as sole nitrogen source. Analysis of transformants has shown that multiple tandem copies of the plasmid can be integrated into the chromosome, commonly at sites other than the amdS locus. While the transformed phenotype was relatively stable through mitotic and meiotic divisions evidence was found for variation in plasmid copy number presumably due to unequal recombination events. Expression of the integrated amdS genes was related to copy number, and the amdS RNA produced was similar in size to wild-type RNA. Evidence for titration of the product of the regulatory gene amdR by multiple copies of amdS was found. No titration of the product of the areA gene was observed, and amdS expression was still dependent on areA function. Multiple copies of the amdI9 mutation resulted in poor growth on acetate. This was not observed in the case of the amdS⁺ gene. The cis-acting amdI9 mutation causes increased facB dependent acetate induction of amdS expression. Titration of the facB gene produce by amdI9 DNA, but not by amdS⁺ DNA, therefore suggested that the mutation results in increased affinity for the facB gene product.     

DNA repair genes of Saccharomyces cerevisiae: complementing rad4 and rev2 mutations by plasmids which cannot be propagated in Escherichia coli

Summary The RAD4 gene of yeast required for the incision step of DNA excision repair and the REV2 (= RAD5) gene involved in mutagenic DNA repair could not be isolated from genomic libraries propagated in E. coli regardless of copy number of the shuttle vector in yeast. Transformants with plasmids conferring UV resistance to a rad4-4 or a rev2-1 mutant were only recovered if yeast was transformed directly without previous amplification of the gene bank in E. coli. DNA preparations from these yeast clones yielded no transformants in E. coli but retransformation of yeast was possible. This lead to the isolation of a defective derivative of the rad4 complementing plasmid. The modified plasmid was now capable of transforming E. coli but still interfered significantly with its growth.Dedicated to Prof. Dr. Fritz Kaudewitz on the occasion of his 65th birthday     

Multiple-copy integration in the yeast Yarrowia lipolytica

Using an EcoRI-BglII fragment of the G unit of the rDNA of Y. lipolytica and a set of 11 deletions in the URA3 promoter, we have constructed several plasmids to test gene amplification in the rDNA. These plasmids contain the rDNA fragment for integration, defective versions of the URA3 gene, the XPR2 gene encoding alkaline extracellular protease (AEP) as a reporter gene, and part of the pBR322 plasmid for selection and replication in E. coli. Among these plasmids, one corresponds to a deletion which allows multiple integration into the rDNA (plasmid pINA773). Two other plasmids (pINA767 and pINA772) give multiple integration only with a mutated URA3 gene. Transformants carrying these three plasmids were tested for copy number, stability, chromosomal localization and AEP secretion. Transformants containing plasmids pINA767, 772 and 773 displayed an average copy number of 5, 12 and 25–60 copies respectively of the plasmid, as estimated by PCR and DNA hybridization. Integrations occurred in only one chromosome except for transformants containing 60 copies where copies were observed at least in two different chromosomes. Multiple integrations were found both as tandem repeats and as dispersed copies. Plasmid copy number was stable in both minimum and rich media, for strains containing less than ten copies per cells. However, for higher copy number, multiple integrations were stable only when AEP synthesis was not induced, while in inducing medium stability of the multiple integrations was dramatically affected.     

Competition between the replication initiator DnaA and the sequestration factor SeqA for binding to the hemimethylated chromosomal origin of E. coli in vitro

BACKGROUND: Following replication initiation, the replication origin (oriC) in Escherichia coli enters a hemimethylated state at Dam methylation sites which are recognized by the SeqA protein. SeqA binds preferentially to hemimethylated GATC sequences of DNA in vitro. SeqA is essential for the synchronous initiation of chromosome replication from oriC copies in vivo. RESULTS: We show that: (i) purified SeqA binds AT-rich and 13-mers regions and two DnaA boxes, R1 and M, of hemimethylated oriC. (ii) SeqA inhibits the in vitro replication of a hemimethylated oriC plasmid more efficiently than the fully methylated, (iii) SeqA inhibits competitive binding of DnaA protein to the regions of the hemimethylated oriC plasmid, explaining the mechanism of its inhibitory effect. The inhibition of DnaA binding by SeqA also occurs efficiently on a small hemimethylated oriC fragment containing both R1 and M DnaA boxes, but not the 13-mer region. CONCLUSIONS: SeqA binds strongly the long region from the AT-rich region to the M DnaA box of the hemimethylated oriC DNA and releases DnaA molecules from the long region.     

NKBOR, a mini-Tn10-based transposon for random insertion in the chromosome of Gram-negative bacteria and the rapid recovery of sequences flanking the insertion sites in Escherichia coli.

We have constructed an R6K-based suicide vector that permits the random insertion of a mini-transposon named NKBOR into the chromosome of Gram-negative bacteria and the subsequent rapid cloning of sequences flanking the insertion site in Escherichia coli. This mini-transposon contains a conditional R6K plasmid origin of replication, a kanamycin resistance gene and unique restriction sites between the IS10 inverted repeats. NKBOR can be propagated by replication in an E. coli strain containing the R6K replicase pi protein. Alternatively the mini-transposon can be replicated in a pSC 101 derivative that is thermosensitive for its replication so that the mini-transposon acts as a suicide plasmid at nonpermissive temperatures. Efficient NKBOR transposition is ensured by expression of an adjacent transposase gene and has been demonstrated in E. coli, Klebsiella pneumoniae, and Erwinia carotovora. Sequences flanking the insertion sites in these strains can be rapidly recovered and identified in E. coli strains expressing the R6K pi protein.     

The influence of the Ustilago maydis REC1 gene on plasmid-chromosome recombination

The REC1 gene of U. maydis has an important but ill-defined role in DNA recombination and repair. We have examined its role in plasmid-chromosome recombination. Plasmid DNA was linearised at various locations with respect to the cloned U. maydis PYR3 gene and introduced into cells by transformation. Chromosomal integration and repair by an homologous cross-over with plasmid containing a double-strand break or gap in the PYR3 gene was markedly reduced in the absence of the REC1 gene product. Homologous replacement of the chromosomal pyr3-1 allele by a single copy of wild-type sequences from plasmid cut outside PYR3 was not found in the absence of the REC1 product. Instead, novel transformants generated in its absence suggests that ligation plays a role in their generation.     

Role of the 85-Kilobase Plasmid and Plasmid-Encoded Virulence-Associated Protein A in Intracellular Survival and Virulence of Rhodococcus equi

Rhodococcus equi is a facultative intracellular pathogen of macrophages and a cause of pneumonia in young horses (foals) and immunocompromised people. Isolates of R. equi from pneumonic foals typically contain large, 85- or 90-kb plasmids encoding a highly immunogenic virulence-associated protein (VapA). The objective of this study was to determine the role of the 85-kb plasmid and VapA in the intracellular survival and virulence of R. equi. Clinical isolates containing the plasmid and expressing VapA efficiently replicated within mouse macrophages in vitro, while plasmid-cured derivatives of these organisms did not multiply intracellularly. An isolate harboring the large plasmid also replicated in the tissues of experimentally infected mice, whereas its plasmid-cured derivative was rapidly cleared. All foals experimentally infected with a plasmid-containing clinical isolate developed severe bronchopneumonia, whereas the foals infected with its plasmid-cured derivative remained asymptomatic and free of visible lung lesions. By day 14 postinfection, lung bacterial burdens had increased considerably in foals challenged with the plasmid-containing clinical isolate. In contrast, bacteria could no longer be cultured from the lungs of foals challenged with the isogenic plasmid-cured derivative. A recombinant, plasmid-cured derivative expressing wild-type levels of VapA failed to replicate in macrophages and remained avirulent for both mice and foals. These results show that the 85-kb plasmid of R. equi is essential for intracellular replication within macrophages and for development of disease in the native host, the foal. However, expression of VapA alone is not sufficient to restore the virulence phenotype.     

Shuttle vectors for <Emphasis Type="Italic">Candida albicans</Emphasis>: control of plasmid copy number and elevated expression of cloned genes

Plasmids containing the inosine monophosphate dehydrogenase gene CaIMH3 from Candida albicans strain ATCC 32354 transform their host to resistance against mycophenolic acid (MPA). The transformants maintain the plasmids at a high copy number (20–40 per cell) and express the CaIMH3 gene at very high levels relative to untransformed controls. The plasmid copy number can be controlled by the concentration of MPA in the media. The transformation procedure is reproducible and the efficiency of transformation is high, up to 15,000 per microgram. Unrearranged plasmids are readily recovered by transforming total DNA from transformants back into Escherichia coli. C. albicans genes cloned into the plasmid are expressed at elevated levels relative to untransformed controls. A derivative vector containing the CaMAL2 promoter and termination sequences expresses the CaERG11 ORF at high levels and confers moderate resistance to fluconazole. These shuttle vectors should facilitate global genomics approaches in C. albicans that have been hampered by its diploid genome.     

Plasmid-determined resistance to serum bactericidal activity: a major outer membrane protein, the traT gene product, is responsible for plasmid-specified serum resistance in Escherichia coli.

Resistance to the bactericidal activity of serum appears to be an important virulence property of invasive bacteria. The conjugative multiple-antibiotic-resistance plasmid R6-5 was found to confer upon Escherichia coli host bacteria increased resistance against rabbit serum. Gene-cloning techniques were used to localize the serum resistance determinant of R6-5 to a segment of the plasmid that encodes conjugal transfer functions, and a pACYC184 hybrid plasmid, designated pKT107, that contains this segment was constructed. The generation and analysis of deletion and insertion mutant derivatives of the pKT107 plasmid that no longer specify serum resistance permitted precise localization of the serum-resistance cistron on the R6-5 map and demonstrated that this locus is coincident with that of traT, one of the two surface exclusion genes of R6-5. Examination of the proteins synthesized in E. coli minicells of pKT107 and its serum-sensitive mutant derivative plasmids confirmed that the serum-resistance gene product of R6-5 is the traT protein and showed that this protein is a major structural component (about 21,000 copies per cell) of the bacterial outer membrane.