Bacillus subtilis has two replicative DNA polymerases. PolC is a processive high-fidelity replicative polymerase, while the error-prone DnaEBs extends RNA primers before hand-off to PolC at the lagging strand. We show that DnaEBs interacts with the replicative helicase DnaC and primase DnaG in a ternary complex. We characterize their activities and analyse the functional significance of their interactions using primase, helicase and primer extension assays, and a ‘stripped down’ reconstituted coupled assay to investigate the coordinated displacement of the parental duplex DNA at a replication fork, synthesis of RNA primers along the lagging strand and hand-off to DnaEBs. The DnaG–DnaEBs hand-off takes place after de novo polymerization of only two ribonucleotides by DnaG, and does not require other replication proteins. Furthermore, the fidelity of DnaEBs is improved by DnaC and DnaG, likely via allosteric effects induced by direct protein–protein interactions that lower the efficiency of nucleotide mis-incorporations and/or the efficiency of extension of mis-aligned primers in the catalytic site of DnaEBs. We conclude that de novo RNA primer synthesis by DnaG and initial primer extension by DnaEBs are carried out by a lagging strand–specific subcomplex comprising DnaG, DnaEBs and DnaC, which stimulates chromosomal replication with enhanced fidelity.
Bacterial primases are essential for DNA replication due to their role in polymerizing the formation of short RNA primers repeatedly on the lagging-strand template and at least once on the leading-strand template. The ability of recombinant Staphylococcus aureus DnaG primase to utilize different single-stranded DNA templates was tested using oligonucleotides of the sequence 5-CAGA (CA) 5 XYZ (CA) 3 -3, where XYZ represented the variable trinucleotide. These experiments demonstrated that S. aureus primase synthesized RNA primers predominately on templates containing 5-d(CTA)-3 or TTA and to a much lesser degree on GTA-containing templates, in contrast to results seen with the Escherichia coli DnaG primase recognition sequence 5-d(CTG)-3. Primer synthesis was initiated complementarily to the middle nucleotide of the recognition sequence, while the third nucleotide, an adenosine, was required to support primer synthesis but was not copied into the RNA primer. The replicative helicases from both S. aureus and E. coli were tested for their ability to stimulate either S. aureus or E. coli primase. Results showed that each bacterial helicase could only stimulate the cognate bacterial primase. In addition, S. aureus helicase stimulated the production of full-length primers, whereas E. coli helicase increased the synthesis of only short RNA polymers. These studies identified important differences between E. coli and S. aureus related to DNA replication and suggest that each bacterial primase and helicase may have adapted unique properties optimized for replication.
The adherence of Ruminococcus albus 8 to crystalline cellulose was studied, and an affinity-based assay was also used to identify candidate cellulose-binding protein(s). Bacterial adherence in cellulose-binding assays was significantly increased by the inclusion of either ruminal fluid or micromolar concentrations of both phenylacetic and phenylpropionic acids in the growth medium, and the addition of carboxymethylcellulose (CMC) to assays decreased the adherence of the bacterium to cellulose. A cellulose-binding protein with an estimated molecular mass following sodium dodecyl sulfate-polyacrylamide gel electrophoresis of ∼21 kDa, designated CbpC, was present in both cellobiose- and cellulose-grown cultures, and the relative abundance of this protein increased in response to growth on cellulose. Addition of 0.1% (wt/vol) CMC to the binding assays had an inhibitory effect on CbpC binding to cellulose, consistent with the notion that CbpC plays a role in bacterial attachment to cellulose. The nucleotide sequence of the cbpC gene was determined by a combination of reverse genetics and genomic walking procedures. ThecbpC gene encodes a protein of 169 amino acids with a calculated molecular mass of 17,655 Da. The amino-terminal third of the CbpC protein possesses the motif characteristic of the Pil family of proteins, which are most commonly involved with the formation of type 4 fimbriae and other surface-associated protein complexes in gram-negative, pathogenic bacteria. The remainder of the predicted CbpC sequence was found to have significant identity with 72- and 75-amino-acid motifs tandemly repeated in the 190-kDa surface antigen protein of Rickettsia spp., as well as one of the major capsid glycoproteins of the Chlorella virus PBCV-1. Northern blot analysis showed that phenylpropionic acid and ruminal fluid increase cbpC mRNA abundance in cellobiose-grown cells. These results suggest that CbpC is a novel cellulose-binding protein that may be involved in adherence of R. albus to substrate and extends understanding of the distribution of the Pil family of proteins in gram-positive bacteria.
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