The beta-propeller protein YxaL increases the processivity of the PcrA helicase.

The DNA helicase PcrA is found in gram-positive bacteria and belongs to the superfamily 1 (SF1) of helicases, together with Rep and UvrD helicases from Escherichia coli. These helicases have been extensively studied in vitro and their mode of unwinding are well characterised. However, little is known about the putative cellular partners of such helicases. To identify PcrA-interacting factors, PcrA was used as a bait in a genome-wide yeast two-hybrid screen of a Bacillus subtilis library. Three proteins with unknown functions - YxaL, YwhK and YerB - were found to interact specifically with PcrA. The yxaL gene was cloned, the product was overexpressed and purified, and its effect on the PcrA activity was investigated in vitro. YxaL enhanced the processivity of the PcrA helicase. A comparison of the amino acid sequence of YxaL with other proteins from data banks suggests that YxaL belongs to a family of proteins with a repeated domain, which adopt a typical three-dimensional structure designated as a "beta-propeller". This raises the possibility that YxaL acts as a connector protein between PcrA and another cellular component.

Interaction between yeast sgs1 helicase and DNA topoisomerase III.

The Saccharomyces cerevisiae Sgs1 protein is a member of the RecQ family of DNA helicases that includes the human Bloom's syndrome and Werner's syndrome proteins. In this work, we report studies on the interaction between Sgs1 and DNA topoisomerase III in vitro and in vivo. Affinity chromatography experiments with various fragments of Sgs1, a 1447-amino acid polypeptide, suggested that its N-terminal one-fifth was sufficient for interaction with DNA topoisomerase III. Gel electrophoretic mobility shift assays also indicated that a fragment Sgs1(1-283), containing residues 1-283, inhibited the binding of DNA topoisomerase III to single-stranded DNA. A shorter protein fragment containing residues 1-107 also showed partial inhibition in these assays. Studies of a sgs1 top1 double mutant lacking both Sgs1 and DNA topoisomerase I showed that the slow growth phenotype of this double mutant is suppressed by expressing full-length Sgs1, but not Sgs1 without the N-terminal 107 amino acid residues. In sgs1 top3 cells devoid of DNA topoisomerase III, however, expression of full-length Sgs1 or Sgs1 lacking the N-terminal 107 amino acid residues has the same effect of reducing the growth rate of the double mutant. These in vitro and in vivo data indicate that Sgs1 and DNA topoisomerase III physically interact and that this interaction is physiologically significant.

Change of a catalytic reaction carried out by a DNA replication protein.

The RepA protein of plasmid pC194 initiates and terminates rolling circle replication. At initiation, it forms a 5'-phosphotyrosyl DNA link, whereas at termination, a glutamate residue directs hydrolytic cleavage of the newly synthesized origin, and the resulting 3'-hydroxyl group undergoes transesterification with the phosphotyrosine link. The protein is thus released from DNA, and the termination is uncoupled from reinitiation of replication. Replacement of the glutamate with tyrosine in RepA altered this mechanism, so that termination occurred by two successive transesterifications and became coupled to reinitiation. This result suggests that various enzymes involved in DNA cleavage and rejoining may have similar mechanistic and evolutionary roots.

Active site of the replication protein of the rolling circle plasmid pC194.

Mutation analysis of the rolling circle (RC) replication initiator protein RepA of plasmid pC194 was targeted to tyrosine and acidic amino acids (glutamate and aspartate) which are well conserved among numerous related plasmids. The effect of mutations was examined by an in vivo activity test. Mutations of one tyrosine and two glutamate residues were found to greatly impair or abolish activity, without affecting affinity for the origin, as deduced from in vitro gel mobility assays. We conclude that all three amino acids have a catalytic role. Tyrosine residues were found previously in active sites of different RC plasmid Rep proteins and topoisomerases, but not in association with acidic residues, which are a hallmark of the active sites of DNA hydrolyzing enzymes, such as the exo- and endonucleases. We propose that the active site of RepA contains two different catalytic centers, corresponding to a tyrosine and a glutamate. The former may be involved in the formation of the covalent DNA-protein intermediate at the initiation step of RC replication, and the latter may catalyze the release of the protein from the intermediate at the termination step.

Characterization of a region of plasmid pBL1 of Brevibacterium lactofermentum involved in replication via the rolling circle model.

The minimal region for autonomous replication of pBL1, a 4.5-kb cryptic plasmid of Brevibacterium lactofermentum ATCC 13869 that has been used to construct a variety of corynebacterium vectors, was shown to be contained on a 1.8-kb HindII-SphI DNA fragment. This region contains two open reading frames (ORFs) (ORF1 and ORF5) which are essential for pBL1 replication in B. lactofermentum. Accumulation of single-strand intermediates in some of the constructions indicates that plasmid pBL1 replicates via the rolling circle replication model; its plus strand and minus strand were identified by hybridization with two synthetic oligonucleotide probes complementary to each pBL1 strand. ORF1 seems to encode the Rep protein and showed partial homology with sequences for Rep proteins from Streptomyces plasmids which replicate via rolling circle replication such as pIJ101, pSB24, and pJV1.