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UL9 protein and ICP8 encoded by the herpes simplex virus type 1 (HSV-1) were shown to catalyze a highly active, non-origin-dependent unwinding of DNA. UL9 protein, the HSV-1 origin binding protein, as a modest helicase activity that is greatly stimulated by the HSV-1 single strand (ss) binding protein, ICP8. Here, electron microscopy has been applied to examine the mechanics of this reaction. Negative staining of the proteins revealed particles consisting primarily of ICP8 monomers and UL9 protein dimers. When the binding of UL9 protein to double strand (ds) DNA containing ss tails was examined by shadowcasting methods, UL9 protein was seen bound to the ss tails or ss/ds junctions; addition of ATP led to its appearance internally along the ds segment. When UL9 protein and ICP8 were incubated together with the tailed dsDNA in the presence of ATP, a highly ordered unwinding of the DNA was observed by negative staining that appeared to progress through four distinct stages: (1) binding of ICP8 to the ss tail and progressive coverage of the ds portion by UL9 protein; (2) formation of highly condensed regular filaments; (3) relaxation of the condensed structures into coiled-coils; and (4) unwinding of the coils and release of ICP8-covered linear ssDNAs. This process represents a mechanism of unwinding that is very different from ones that proceed by a progressive unwinding at Y-shaped forks that move along the DNA.
J Mol Biol 1996 May 24
PMID:Visualization of the unwinding of long DNA chains by the herpes simplex virus type 1 UL9 protein and ICP8. 863 10

The DnaB protein is the primary replicative helicase in Escherichia coli, and the active form of the protein is a hexamer. It has been reported that the protein forms a ring with strong 3-fold symmetry, which was suggested to be a trimer of dimers. We show that under different conditions, using either ATP, ATP gamma S, AMP-PNP or ADP as nucleotide cofactors, we always find two different forms of the DnaB ring; one with a 3-fold symmetry and one with 6-fold symmetry. We have used scanning transmission electron microscopy for mass analysis, and have found that both forms are hexamers, excluding the possibility that the 3-fold form is in fact a trimer of the 52 kDa monomer. We have also found rings that are in an intermediate state between these two. The existence of hexamers in discrete states shows that the transitions between these states must be cooperative. These observations suggest that there may be an equilibrium between two different conformations of the hexameric ring. The role of these two states in the mechanism of helicase action remains to be determined.
J Mol Biol 1996 May 31
PMID:The hexameric E. coli DnaB helicase can exist in different Quaternary states. 864 50

We have examined the formation of the primosome subassembly of the bacteriophage T4-coded DNA replication (elongation) complex from its helicase, primase, and DNA components. Previously, we had shown that the T4 helicase (gp41) exists in solution in a stable monomer left and right arrow dimer equilibrium at physiological protein (and salt) concentrations and forms a hexamer upon activation by ATP (or GTP) binding (Dong, F., Gogol, E. P., and von Hippel, P. H.(1995) J. Biol. Chem. 270, 7462-7473). Here we report that the T4 primase (gp61) is a monomer in solution under the same conditions, and that the ATP-activated helicase binds to a single gp61 primase molecule on appropriate DNA templates to reconstitute a stable primosome. We show that: (i) the gp41 helicase alone does not form a stable complex with DNA templates, although this helicase by itself can carry out moderately processive ATP-driven translocation along single-stranded DNA (Young, M. C., Schultz, D. E., Ring, D., and von Hippel, P. H.(1994) J. Mol. Biol. 235, 1447-1458); (ii) the primase alone does form a stable complex with DNA; (iii) the helicase can bind to the primase-DNA complex in the presence of ATP or GTP to form a stable ternary complex; (iv) this complex consists of six helicase subunits and one primase subunit; and (v) the reconstituted primosome is stable for at least 10 to 20 min after NTP cleavage and dissociation of the hydrolysis products. These results strongly suggest that the functional T4 DNA replication primosome consists of an integrated 6:1 helicase-primase complex bound to DNA, and that the ATP-activated helicase hexamer remains intact throughout the processive DNA replication process.
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PMID:The ATP-activated hexameric helicase of bacteriophage T4 (gp41) forms a stable primosome with a single subunit of T4-coded primase (gp61). 870 59

Suppressors of the methyl methanesulfonate sensitivity of Saccharomyces cerevisiae diploids lacking the Srs2 helicase turned out to contain semidominant mutations in Rad5l, a homolog of the bacterial RecA protein. The nature of these mutations was determined by direct sequencing. The 26 mutations characterized were single base substitutions leading to amino acid replacements at 18 different sites. The great majority of these sites (75%) are conserved in the family of RecA-like proteins, and 10 of them affect sites corresponding to amino acids in RecA that are probably directly involved in ATP reactions, binding, and/or hydrolysis. Six mutations are in domains thought to be involved in interaction between monomers; they may also affect ATP reactions. By themselves, all the alleles confer a rad5l null phenotype. When heterozygous, however, they are, to varying degrees, negative semidominant for radiation sensitivity; presumably the mutant proteins are coassembled with wild-type Rad51 and poison the resulting nucleofilaments or recombination complexes. This negative effect is partially suppressed by an SRS2 deletion, which supports the hypothesis that Srs2 reverses recombination structures that contain either mutated proteins or numerous DNA lesions.
Mol Cell Biol 1996 Sep
PMID:Semidominant mutations in the yeast Rad51 protein and their relationships with the Srs2 helicase. 875 36

To understand the relationship between translation and mRNA decay, we have been studying how premature translation termination accelerates the degradation of mRNAs. In the yeast Saccharomyces cerevisiae, the Upf1 protein (Upf1p), which contains a cysteine- and histidine-rich region and nucleoside triphosphate hydrolysis and helicase motifs, was shown to be a trans-acting factor in this decay pathway. A UPF1 gene disruption results in the stabilization of nonsense-containing mRNAs and leads to a nonsense suppression phenotype. Biochemical analysis of the wild-type Upf1p demonstrated that it has RNA-dependent ATPase, RNA helicase, and RNA binding activities. In the work described in the accompanying paper (Y. Weng, K. Czaplinski, and S. W. Peltz, Mol. Cell. Biol. 16:5477-5490, 1996) mutations in the helicase region of Upf1p that inactivated its mRNA decay function but prevented suppression of leu2-2 and tyr7-1 nonsense alleles are identified. On the basis of these results, we suggested that Upf1p is a multifunctional protein involved in modulating mRNA decay and translation termination at nonsense codons. If this is true, we predict that UPF1 mutations with the converse phenotype should be identified. In this report, we describe the identification and biochemical characterization of mutations in the amino-terminal cysteine- and histidine-rich region of Upf1p that have normal nonsense-mediated mRNA decay activities but are able to suppress leu2-2 and tyr7-1 nonsense alleles. Biochemical characterization of these mutant proteins demonstrated that they have altered RNA binding properties. Furthermore, using the two-hybrid system, we characterized the Upf1p-Upf2p interactions and demonstrated that Upf2p interacts with Upf3p. Mutations in the cysteine- and histidine-rich region of Upf1p abolish Upf1p-Upf2p interaction. On the basis of these results, the role of the Upf complex in nonsense-mediated mRNA decay and nonsense suppression is discussed.
Mol Cell Biol 1996 Oct
PMID:Identification and characterization of mutations in the UPF1 gene that affect nonsense suppression and the formation of the Upf protein complex but not mRNA turnover. 881 62

mRNA degradation is an important control point in the regulation of gene expression and has been linked to the process of translation. One clear example of this linkage is the nonsense-mediated mRNA decay pathway, in which nonsense mutations in a gene can reduce the abundance of the mRNA transcribed from that gene. For the yeast Saccharomyces cerevisiae, the Upf1 protein (Upf1p), which contains a cysteine- and histidine-rich region and nucleoside triphosphate hydrolysis and helicase motifs, was shown to be a trans-acting factor in this decay pathway. Biochemical analysis of the wild-type Upf1p demonstrates that it has RNA-dependent ATPase, RNA helicase, and RNA binding activities. A UPF1 gene disruption results in stabilization of nonsense-containing mRNAs, leading to the production of enough functional product to overcome an auxotrophy resulting from a nonsense mutation. A genetic and biochemical study of the UPF1 gene was undertaken in order to understand the mechanism of Upf1p function in the nonsense-mediated mRNA decay pathway. Our analysis suggests that Upf1p is a multifunctional protein with separable activities that can affect mRNA turnover and nonsense suppression. Mutations in the conserved helicase motifs of Upf1p that inactivate its mRNA decay function while not allowing suppression of leu2-2 and tyr7-1 nonsense alleles have been identified. In particular, one mutation located in the ATP binding and hydrolysis motif of Upf1p that changed the aspartic and glutamic acid residues to alanine residues (DE572AA) lacked ATPase and helicase activities, and the mutant formed a Upf1p:RNA complex in the absence of ATP; surprisingly, however, the Upf1p:RNA complex dissociated as a consequence of ATP binding. This result suggests that ATP binding, independent of its hydrolysis, can modulate Upf1p:RNA complex formation for this mutant protein. The role of the RNA binding activity of Upf1p in modulating nonsense suppression is discussed.
Mol Cell Biol 1996 Oct
PMID:Genetic and biochemical characterization of mutations in the ATPase and helicase regions of the Upf1 protein. 881 61

Mutations in the Drosophila mus308 gene confer specific hypersensitivity to DNA-cross-linking agents as a consequence of defects in DNA repair. The mus308 gene is shown here to encode a 229-kDa protein in which the amino-terminal domain contains the seven conserved motifs characteristic of DNA and RNA helicases and the carboxy-terminal domain shares over 55% sequence similarity with the polymerase domains of prokaryotic DNA polymerase I-like enzymes. This is the first reported member of this family of DNA polymerases in a eukaryotic organism, as well as the first example of a single polypeptide with homology to both DNA polymerase and helicase motifs. Identification of a closely related gene in the genome of Caenorhabditis elegans suggests that this novel polypeptide may play an evolutionarily conserved role in the repair of DNA damage in eukaryotic organisms.
Mol Cell Biol 1996 Oct
PMID:Molecular cloning of Drosophila mus308, a gene involved in DNA cross-link repair with homology to prokaryotic DNA polymerase I genes. 881 90

Excessive initiation of chromosomal replication occurs in the dnaAcos mutant at 30 degrees C. Whereas purified wild-type DnA protein binds ATP and ADP tightly, DnaAcos protein is defective for such nucleotide binding. As initiation is a multistep reaction and DnaA protein functions at each step, activities of DnaAcos protein need to be examined precisely. DnaAcos protein specifically bound a DNA fragment containing the chromosomal replication origin with an affinity similar to that seen with the wild-type protein. In a system reconstituted with purified proteins at 30 degrees C, the mutant protein initiated replication of single-stranded DNA that contains a DnA-binding hairpin structure. Thus, DnaAcos protein basically sustains affinity to a DnaA-binding sequence and functions in the loading of DnaB helicase onto single-stranded DNA. Thermal stabilities of wild-type DnA and DnaAcos activities were comparable. Unlike wild-type DnaA protein, DnaAcos protein was inactive for minichromosomal replication in systems reconstituted with purified proteins in which the ATP-bound form of DnaA protein is required for initiation. Taken together, the data indicate that the prominent defect in DnaAcos protein appears to be the inability to bind nucleotide.
Mol Microbiol 1995 Dec
PMID:Characterization of Escherichia coli DnaAcos protein in replication systems reconstituted with highly purified proteins. 882 85

The ATP-dependent deoxyribonuclease enzyme complex (AddAB) of Bacillus subtilis possesses two consensus ATP-binding sequences, located in the N-terminal region of both subunits. The highly conserved lysine residues in both consensus ATP-binding sequences were replaced by glycine, resulting in the mutant enzyme complexes AddAB-A-K36G (AddA*B) and AddAB-B-K14G (AddAB*). The mutation in subunit AddA reduced DNA repair and chromosomal transformation, and abolished bacteriophage PBS1-mediated transduction. This mutation also resulted in a complete loss of the ATP-dependent exonuclease and helicase activity. In contrast, the mutation in subunit AddB had only marginal effects. The recF and addAB genes are not required for transformation with plasmid DNA, but have overlapping activities in transformation with chromosomal DNA. By contrast to RecF, the AddAB enzyme is essential for PBS1-mediated transduction. However, recF has a more important function with respect to DNA repair than addAB.
Mol Microbiol 1996 Sep
PMID:Replacement of the lysine residue in the consensus ATP-binding sequence of the AddA subunit of AddAB drastically affects chromosomal recombination in transformation and transduction of Bacillus subtilis. 888 69

We demonstrate a variation in the effects of seven alleles of the Escherichia coli dnaA gene, which cause temperature sensitivity of initiation of chromosomal replication, on the replication of lambda phage-derived plasmids at 30 degrees C. These mutants showed no allele specificity of dnaA function in replication of either of two lambda pi plasmids studied. On the other hand, the inability of the lambda P+ plasmid to replicate in dnaA508, 46 and 204 cells, in dnaB (groP A15) or in cells that are temperature sensitive for the chaperone genes dnaK756, dnaJ259 and grpE280 at 30 degrees C was suppressible by a single pi mutatation. This suggests that it is a common property of the pi protein, probably its weaker interaction with DnaB helicase, that is responsible for the suppression. One can also conclude that the DnaA-regulated transcriptional activation of ori lambda acts at the step, in which all these gene products cooperate, i.e. during preprimosome loading and chaperone-mediated release of DnaB from P protein inhibition.
Mol Gen Genet 1996 Oct 16
PMID:Allele specificity of the Escherichia coli dnaA gene function in the replication of plasmids derived from phage lambda. 891 19

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