Ole Skovgaard

The two chromosomes of Vibrio cholerae are initiated at different time points in the cell cycle

The bacterium Vibrio cholerae, the cause of the diarrhoeal disease cholera, has its genome divided between two chromosomes, a feature uncommon for bacteria. The two chromosomes are of different sizes and different initiator molecules control their replication independently. Using novel methods for analysing flow cytometry data and marker frequency analysis, we show that the small chromosome II is replicated late in the C period of the cell cycle, where most of chromosome I has been replicated. Owing to the delay in initiation of chromosome II, the two chromosomes terminate replication at approximately the same time and the average number of replication origins per cell is higher for chromosome I than for chromosome II. Analysis of cell‐cycle parameters shows that chromosome replication and segregation is exceptionally fast in V. cholerae. The divided genome and delayed replication of chromosome II may reduce the metabolic burden and complexity of chromosome replication by postponing DNA synthesis to the last part of the cell cycle and reducing the need for overlapping replication cycles during rapid proliferation.

Independent Control of Replication Initiation of the Two Vibrio cholerae Chromosomes by DnaA and RctB

Although the two Vibrio cholerae chromosomes initiate replication in a coordinated fashion, we show here that each chromosome appears to have a specific replication initiator. DnaA overproduction promoted overinitiation of chromosome I and not chromosome II. In contrast, overproduction of RctB, a protein that binds to the origin of replication of chromosome II, promoted overinitiation of chromosome II and not chromosome I.

Genome Engineering in Vibrio cholerae: A Feasible Approach to Address Biological Issues

Although bacteria with multipartite genomes are prevalent, our knowledge of the mechanisms maintaining their genome is very limited, and much remains to be learned about the structural and functional interrelationships of multiple chromosomes. Owing to its bi-chromosomal genome architecture and its importance in public health, Vibrio cholerae, the causative agent of cholera, has become a preferred model to study bacteria with multipartite genomes. However, most in vivo studies in V. cholerae have been hampered by its genome architecture, as it is difficult to give phenotypes to a specific chromosome. This difficulty was surmounted using a unique and powerful strategy based on massive rearrangement of prokaryotic genomes. We developed a site-specific recombination-based engineering tool, which allows targeted, oriented, and reciprocal DNA exchanges. Using this genetic tool, we obtained a panel of V. cholerae mutants with various genome configurations: one with a single chromosome, one with two chromosomes of equal size, and one with both chromosomes controlled by identical origins. We used these synthetic strains to address several biological questions—the specific case of the essentiality of Dam methylation in V. cholerae and the general question concerning bacteria carrying circular chromosomes—by looking at the effect of chromosome size on topological issues. In this article, we show that Dam, RctB, and ParA2/ParB2 are strictly essential for chrII origin maintenance, and we formally demonstrate that the formation of chromosome dimers increases exponentially with chromosome size.

Genome-wide detection of chromosomal rearrangements, indels, and mutations in circular chromosomes by short read sequencing

Whole-genome sequencing (WGS) with new short-read sequencing technologies has recently been applied for genome-wide identification of mutations. Genomic rearrangements have, however, often remained undetected by WGS, and additional analyses are required for their detection. Here, we have applied a combination of WGS and genome copy number analysis, for the identification of mutations that suppress the growth deficiency imposed by excessive initiations from the Escherichia coli origin of replication, oriC. The E. coli chromosome, like the majority of bacterial chromosomes, is circular, and DNA replication is initiated by assembling two replication complexes at the origin, oriC. These complexes then replicate the chromosome bidirectionally toward the terminus, ter. In a population of growing cells, this results in a copy number gradient, so that origin-proximal sequences are more frequent than origin-distal sequences. Major rearrangements in the chromosome are, therefore, readily identified by changes in copy number, i.e., certain sequences become over- or under-represented. Of the eight mutations analyzed in detail here, six were found to affect a single gene only, one was a large chromosomal inversion, and one was a large chromosomal duplication. The latter two mutations could not be detected solely by WGS, validating the present approach for identification of genomic rearrangements. We further suggest the use of copy number analysis in combination with WGS for validation of newly assembled bacterial chromosomes.

The Conserved Sporulation Protein YneE Inhibits DNA Replication in Bacillus subtilis

Cells of Bacillus subtilis triggered to sporulate under conditions of rapid growth undergo a marked decrease in chromosome copy number, which was partially relieved by a mutation in the sporulation-induced gene yneE. Cells engineered to express yneE during growth were impaired in viability and produced anucleate cells. We conclude that YneE is an inhibitor of DNA replication.

A checkpoint control orchestrates the replication of the two chromosomes of Vibrio cholerae

Replication of a specific site on the main chromosome of V. cholerae triggers the replication initiation of its secondary chromosome. Bacteria with multiple chromosomes represent up to 10% of all bacterial species. Unlike eukaryotes, these bacteria use chromosome-specific initiators for their replication. In all cases investigated, the machineries for secondary chromosome replication initiation are of plasmid origin. One of the important differences between plasmids and chromosomes is that the latter replicate during a defined period of the cell cycle, ensuring a single round of replication per cell. Vibrio cholerae carries two circular chromosomes, Chr1 and Chr2, which are replicated in a well-orchestrated manner with the cell cycle and coordinated in such a way that replication termination occurs at the same time. However, the mechanism coordinating this synchrony remains speculative. We investigated this mechanism and revealed that initiation of Chr2 replication is triggered by the replication of a 150-bp locus positioned on Chr1, called crtS. This crtS replication–mediated Chr2 replication initiation mechanism explains how the two chromosomes communicate to coordinate their replication. Our study reveals a new checkpoint control mechanism in bacteria, and highlights possible functional interactions mediated by contacts between two chromosomes, an unprecedented observation in bacteria.

Genetic Population Structure of the Prosobranch Snail Potamopyrgus antipodarum (Gray) in Denmark Using PCR-RAPD Fingerprints

Parthenogenetic species are often more widely distributed geographically than their sexual relatives. This success in colonizing can be explained either by dispersal of one or a few clones of wide physiological tolerance or by the distribution of many locally adapted clones. Here we test the hypothesis that successfully invading clones of Potamopyrgus antipodarum (Gray) are composed of a few broadly adapted genotypes by using polymerase chain reaction random amplified polymorphic DNA (PCR-RAPD) fingerprinting on six different populations of P. antipodarum from Denmark and three morphotypes of P. Antipodarum from Britain. We detected two genotypes of P. antipodarum in six populations examined across Denmark using four decamer primers. The two genotypes were found to be morphologically and genetically indistinguishable from British P. antipodarum.In five of the six Danish populations only one genotype was found; at the remaining site, the two genotypes occurred sympatrically. The present study suggests that P. antipodarum successfully invaded Europe by the proliferation of very few clones.

A novel class of mutations that affect DNA replication in E. coli

Over‐initiation of DNA replication in cells containing the cold‐sensitive dnaA(cos) allele has been shown to lead to extensive DNA damage, potentially due to head‐to‐tail replication fork collisions that ultimately lead to replication fork collapse, growth stasis and/or cell death. Based on the assumption that suppressors of the cold‐sensitive phenotype of the cos mutant should include mutations that affect the efficiency and/or regulation of DNA replication, we subjected a dnaA(cos) mutant strain to transposon mutagenesis and selected mutant derivatives that could form colonies at 30°C. Four suppressors of the dnaA(cos)‐mediated cold sensitivity were identified and further characterized. Based on origin to terminus ratios, chromosome content per cell, measured by flow cytometry, and sensitivity to the replication fork inhibitor hydroxyurea, the suppressors fell into two distinct categories: those that directly inhibit over‐initiation of DNA replication and those that act independently of initiation. Mutations that decrease the cellular level of HolC, the χ subunit of DNA polymerase, or loss of ndk (nucleoside diphosphate kinase) function fall into the latter category. We propose that these novel suppressor mutations function by decreasing the efficiency of replication fork movement in vivo, either by decreasing the dynamic exchange of DNA polymerase subunits in the case of HolC, or by altering the balance between DNA replication and deoxynucleoside triphosphate synthesis in the case of ndk. Additionally, our results indicate a direct correlation between over‐initiation and sensitivity to replication fork inhibition by hydroxyurea, supporting a model of increased head‐to‐tail replication fork collisions due to over‐initiation.

BPTI and N-terminal extended analogues generated by factor Xa cleavage and cathepsin C trimming of a fusion protein expressed in Escherichia coli

A recombinant gene for BPTI (bovine pancreatic trypsin inhibitor) is expressed in Escherichia coli using a MBP (maltose-binding protein) fusion vector. BPTI is fused through an FXa (blood coagulation factor Xa protease) target sequence (Ile-Glu-Gly-Arg) to the C-terminus of MBP. The MBP moiety of the hybrid protein enables purification in one step utilizing MBPs affinity to cross-linked amylose, and the FXa target sequence allows specific cleavage of the hybrid protein. Effective FXa cleavage is achieved by spacing the FXa target sequence and Arg-1 of the BPTI sequence with four residues (Met-Glu-Ala-Glu). The resulting N-terminal extended BPTI is readily converted to the wild-type sequence by trimming with cathepsin C exopeptidase, for the activity of which the spacing tetrapeptide is optimized. FXa cleavage is prohibited when the target sequence is placed next to Arg-1. In this construction, off-target cleavage at a somewhat homologous sequence (Val-Pro-Gly-Arg) results in five- or six-residue extended BPTI, indicating new details of the FXa specificity. The yield of highly purified recombinant BPTI is 3-6 mg/liter of culture, making the MBP-BPTI expression system convenient for the production of sufficient amounts of protein for NMR studies. 1H NMR is used to analyze the N-extended BPTI analogues.

Suppressors of DnaAATP imposed overinitiation in Escherichia coli

Chromosome replication in Escherichia coli is limited by the supply of DnaA associated with ATP. Cells deficient in RIDA (Regulatory Inactivation of DnaA) due to a deletion of the hda gene accumulate suppressor mutations (hsm) to counteract the overinitiation caused by an elevated DnaAATP level. Eight spontaneous hda suppressor mutations were identified by whole‐genome sequencing, and three of these were analysed further. Two mutations (hsm‐2 and hsm‐4) mapped in the dnaA gene and led to a reduced ability to initiate replication from oriC. One mutation (hsm‐1) mapped to the seqA promoter and increased the SeqA protein level in the cell. hsm‐1 cells had prolonged origin sequestration, reduced DnaA protein level and reduced DnaA‐Reactivating Sequence (DARS)‐mediated rejuvenation of DnaAADP to DnaAATP, all of which could contribute to the suppression of RIDA deficiency. Despite of these defects hsm‐1 cells were quite similar to wild type with respect to cell cycle parameters. We speculate that since SeqA binding sites might overlap with DnaA binding sites spread throughout the chromosome, excess SeqA could interfere with DnaA titration and thereby increase free DnaA level. Thus, in spite of reduction in total DnaA, the amount of DnaA molecules available for initiation may not be reduced.