Whole genome sequencing as a tool for phylogenetic analysis of clinical strains of Mitis group streptococci.

Identification of Mitis group streptococci (MGS) to the species level is challenging for routine microbiology laboratories. Correct identification is crucial for the diagnosis of infective endocarditis, identification of treatment failure, and/or infection relapse. Eighty MGS from Danish patients with infective endocarditis were whole genome sequenced. We compared the phylogenetic analyses based on single genes (recA, sodA, gdh), multigene (MLSA), SNPs, and core-genome sequences. The six phylogenetic analyses generally showed a similar pattern of six monophyletic clusters, though a few differences were observed in single gene analyses. Species identification based on single gene analysis showed their limitations when more strains were included. In contrast, analyses incorporating more sequence data, like MLSA, SNPs and core-genome analyses, provided more distinct clustering. The core-genome tree showed the most distinct clustering.

Two types of cold sensitivity associated with the A184-->V change in the DnaA protein.

Multicopy dnaA(Ts) strains carrying the dnaA5 or dnaA46 allele are high-temperature resistant but are cold sensitive for colony formation. The DnaA5 and DnaA46 proteins both have an A184-->V change in the ATP binding motif of the protein, but they also have one additional mutation. The mutations were separated, and it was found that a plasmid carrying exclusively the A184-->V mutation conferred a phenotype virtually identical to that of the dnaA5 plasmid. Strains carrying plasmids with either of the additional mutations behaved like a strain carrying the dnaA+ plasmid. In temperature downshifts from 42 degrees C to 30 degrees C, chromosome replication was stimulated in the multicopy dnaA46 strain. The DNA per mass ratio increased threefold, and exponential growth was maintained for more than four mass doublings. Strains carrying plasmids with the dnaA(A184-->V) or the dnaA5 gene behaved differently. The temperature downshift resulted in run out of DNA synthesis and the strains eventually ceased growth. The arrest of DNA synthesis was not due to the inability to initiate chromosome replication because marker frequency analysis showed high initiation activity after temperature downshift. However, the marker frequencies indicated that most, if not all, of the newly initiated replication forks were stalled soon after the onset of chromosome replication. Thus, it appears that the multicopy dnaA(A184-->V) strains are cold sensitive because of an inability to elongate replication at low temperature. The multicopy dnaA46 strains, on the contrary, exhibit productive initiation and normal fork movement. In this case, the cold-sensitive phenotype may be due to DNA overproduction.

The central lysine in the P-loop motif of the Escherichia coli DnaA protein is essential for initiating DNA replication from the chromosomal origin, oriC, and the F factor origin, oriS, but is dispensable for initiation from the P1 plasmid origin, oriR.

The Escherichia coli DnaA protein is essential for initiation of DNA replication from the chromosomal origin, oriC, and from certain plasmid origins such as oriR of P1, oriS of F, and ori of pSCS101. The DnaA protein binds ATP with high affinity and contains a P-loop motif assumed to be the binding site. Three mutations in the E. coli dnaA gene were constructed by oligonucleotide-directed mutagenesis that changed amino acids in the P-loop. A DnaA protein, K178T, in which the central lysine was changed to the smaller amino acid threonine, was able to initiate DNA replication from P1 oriR, but was unable to initiate replication from E. coli oriC or F oriS in vivo. Mutant and wild-type DnaA proteins were overexpressed, partially purified, and tested for replication activity in vitro. The K178T DnaA protein could initiate replication from oriR, although with a decreased activity compared to the wild-type DnaA protein. No replication activity was detected for this mutant protein from oriC. The different responses of the oriR and oriC replicons to the K178T DnaA protein indicate that the role of DnaA is different in the two systems.

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.

Effects of N-terminal extension peptides on the structure and stability of bovine pancreatic trypsin inhibitor studied by 1H n.m.r.

Four N-terminal extended species of the wild-type bovine pancreatic trypsin inhibitor (WT-BPTI), Arg-BPTI (1-BPTI), Met-Glu-Ala-Glu-BPTI (4-BPTI), Ser-Ile-Glu-Gly-Arg-BPTI (5-BPTI) and Gly-Ser-Ile-Glu-Gly-Arg-BPTI (6-BPTI) have been studied by 1H n.m.r. The overall structure of the protein is largely unaffected by the addition of extension peptides. pH titration effects on the C-terminal Ala 58 H beta chemical shift indicate that the structure of 1-BPTI at neutral pH is very similar to that of the WT protein, with a salt bridge between the main chain terminal charges. A salt bridge interaction is prevented by addition of the longer extension peptides. Temperature stabilities are measured by high temperature hydrogen isotope exchange and by microcalorimetry. The stability of 1-BPTI is equal to that of WT-BPTI. A slight decrease in stability is observed for longer extensions, following the order WT-BPTI = 1-BPTI < 5-BPTI = 6-BPTI < 4-BPTI. Small changes in chemical shift are observed for 30 invariant resonances in 4-, 5- and 6-BPTI and for a subset of this group in 1-BPTI. These protons are distributed over about half of the BPTI molecule. The size of the chemical shift changes for many resonances follow the same ranking as the temperature stability. The chemical shift effects are attributed to charge and dielectric effects from extension peptides that probably share a common orientation on the surface of BPTI.

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 MBP's 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.

Nucleotide sequence of a Proteus mirabilis DNA fragment homologous to the 60K-rnpA-rpmH-dnaA-dnaN-recF-gyrB region of Escherichia coli.

A 6.5-kb DNA fragment from Proteus mirabilis hybridized to the Escherichia coli dnaA gene. This DNA fragment was cloned and the nucleotide (nt) sequence determined. The fragment is homologous to a region of the E. coli chromosome containing a part of the gene encoding a 60-kDa membrane-associated protein (60K), the rnpA-rpmH-dnaA-dnaN-recF genes, and the N-terminal part of the gyrB gene. The degree of homology is variable: the amino-acid (aa) sequence of a part of the 60K protein and a part of the DnaA protein is only minimally conserved, whereas the C-terminal 148 aa of DnaA are identical in the two species. The conservation of the nt sequence between the rnpA gene and the gene encoding the 60K protein suggests that this region encodes a hitherto unrecognized protein. The ORF for this protein partially overlaps the 3' end of the rnpA structural gene, and the degree of conservation suggests that this gene is important for these bacteria.

Comparison of dnaA nucleotide sequences of Escherichia coli, Salmonella typhimurium, and Serratia marcescens.

The dnaA genes of Salmonella typhimurium and Serratia marcescens, which complemented the temperature-sensitive dnaA46 mutation of Escherichia coli, were cloned and sequenced. They were very homologous to the dnaA gene of E. coli. The 63 N-terminal amino acids and the 333 C-terminal amino acids of the corresponding DnaA proteins were identical. The region in between, corresponding to 71 amino acids in E. coli, exhibited a number of changes. This variable region coincided with a nonhomologous region found in the comparison of E. coli dnaA and Bacillus subtilis "dnaA" genes. The regions upstream of the genes were also homologous. The ribosome-binding area, one of the promoters, the DnaA protein-binding site, and many GATC sites (Dam methyltransferase-recognition sequence) were conserved in these three enteric bacteria.

Fine structure genetic map and complementation analysis of mutations in the dnaA gene of Escherichia coli.

A fine structure genetic map of several mutations in the dnaA gene of Escherichia coli was constructed by the use of recombinant lambda and M13 phages. The dnaA508 mutation was found to be the mutation most proximal to the promoter, while the dnaA203 mutation was found to be the most distal one. The order of mutations established in this analysis was: dnaA508, dnaA167, (dnaA5, dnaA46, dnaA211), dnaA205, dnaA204, dnaA203. The mutations dnaA601, dnaA602, dnaA603, dnaA604 and dnaA606 were found to map very close to each other and close to dnaA205 in the middle third of the dnaA gene. In analysing the dominance relationship all 13 dnaA mutations were found to be recessive to the wild type. Characteristic phenotypes of the dnaA(Ts) mutants, like reversibility of the temperature inactivation of the dnaA protein, cold sensitivity of haploid or of merodiploid strains and suppressibility by rpoB mutations, are found to correlate with clusters of mutations within the gene.