The phiX174-type primosome promotes replisome assembly at the site of recombination in bacteriophage Mu transposition.

Initiation of Escherichia coli DNA synthesis primed by homologous recombination is believed to require the phiX174-type primosome, a mobile priming apparatus assembled without the initiator protein DnaA. We show that this primosome plays an essential role in bacteriophage Mu DNA replication by transposition. Upon promoting transfer of Mu ends to target DNA, the Mu transpososome undergoes transition to a pre-replisome that permits initiation of DNA synthesis only in the presence of primosome assembly proteins PriA, DnaT, DnaB and DnaC. These assembly proteins promote the engagement of primase and DNA polymerase III holoenzyme, initiating semi-discontinuous replication preferentially at the Mu left end. The results indicate that these proteins play a crucial role in promoting replisome assembly on a recombination intermediate.     

PriA-directed assembly of a primosome on D loop DNA.

Escherichia coli strains carrying null mutations in priA are chronically induced for the SOS response and are defective in homologous recombination, repair of UV damaged DNA, double-strand break repair, and both induced and constitutive stable DNA replication. This led to the proposal that PriA directed replication fork assembly at D loops formed by the homologous recombination machinery. The demonstration that PriA specifically recognized and bound D loop DNA supported this hypothesis. Using DNA footprinting as an assay, we show here that PriA also directs the assembly of a varphiX174-type primosome on D loop DNA. The ability to load a complete primosome on D loop DNA is a step necessary for replication fork assembly.     

The DNA replication priming protein, PriA, is required for homologous recombination and double-strand break repair.

The PriA protein, a component of the phiX174-type primosome, was previously shown to be essential for damage-inducible DNA replication in Escherichia coli, termed inducible stable DNA replication. Here, we show that priA::kan null mutants are defective in transductional and conjugational homologous recombination and are hypersensitive to mitomycin C and gamma rays, which cause double-strand breaks. The introduction of a plasmid carrying the priA300 allele, which encodes a mutant PriA protein capable of catalyzing the assembly of an active primosome but which is missing the n'-pas-dependent ATPase, helicase, and translocase activities associated with PriA, alleviates the defects of priA::kan mutants in homologous recombination, double-strand break repair, and inducible stable DNA replication. Furthermore, spa-47, which was isolated as a suppressor of the broth sensitivity of priA::kan mutants, suppresses the Rec- and mitomycin C sensitivity phenotypes of priA::kan mutants. The spa-47 suppressor mutation maps within or very near dnaC. These results suggest that PriA-dependent primosome assembly is crucial for both homologous recombination and double-strand break repair and support the proposal that these processes in E. coli involve extensive DNA replication.     

Mutational analysis of primosome assembly sites. Evidence for alternative DNA structures

Primosome assembly sites are complex DNA structures that share common functions (they elicit the DNA-dependent ATPase of replication factor Y from Escherichia coli and serve as origins of complementary strand DNA synthesis), but display little sequence homology. In order to ascertain a common basis for factor Y-DNA recognition, a primosome assembly site and its mutated derivatives have been functionally and structurally analyzed. Under conditions in which they lose the capacity to function as ATPase effectors these DNA templates have been (i) assayed for their ability to bind factor Y, and (ii) probed, with pancreatic DNase, for structural alterations. In this ATPase-inactivating environment (suboptimal concentrations of MgCl2 and NaCl, and high levels of the E. coli single-stranded DNA binding protein), factor Y does not bind to its cognate DNA and the DNase cleavage pattern characteristic of this site is perceptibly changed: compared to the DNase digest obtained under activating conditions, cleavage is notably decreased in the 5' half of the site and enhanced at the 3' end. The results of this study strongly indicate that the structure of the primosome assembly site under analysis consists of two hairpins which interact with each other. When the sites of pancreatic DNase attack are plotted on the proposed double hairpin structure, the 5' cleavage sites all map to one duplex while the 3' sites map to the other. The observation that, under factor Y ATPase-activating conditions, the 3' hairpin is largely refractory to the action of pancreatic DNase indicates that tertiary interactions between the two duplexes render a portion of the DNA structure inaccessible to the nuclease.     

Modulation of recombination and DNA repair by the RecG and PriA helicases of Escherichia coli K-12.

The RecG protein of Escherichia coli is a structure-specific DNA helicase that targets strand exchange intermediates in genetic recombination and drives their branch migration along the DNA. Strains carrying null mutations in recG show reduced recombination and DNA repair. Suppressors of this phenotype, called srgA, were located close to metB and shown to be alleles of priA. Suppression depends on the RecA, RecBCD, RecF, RuvAB, and RuvC recombination proteins. Nine srgA mutations were sequenced and shown to specify mutant PriA proteins with single amino acid substitutions located in or close to one of the conserved helicase motifs. The mutant proteins retain the ability to catalyze primosome assembly, as judged by the viability of recG srgA and srgA strains and their ability to support replication of plasmids based on the ColE1 replicon. Multicopy priA+ plasmids increase substantially the recombination- and repair-deficient phenotype of recG strains and confer similar phenotypes on recG srgA double mutants but not on ruvAB or wild-type strains. The multicopy effect is eliminated by K230R, C446G, and C477G substitutions in PriA. It is concluded that the 3'-5' DNA helicase/translocase activity of PriA inhibits recombination and that this effect is normally countered by RecG.     

ATPase-deficient mutants of the Escherichia coli DNA replication protein PriA are capable of catalyzing the assembly of active primosomes.

The PriA replication protein of Escherichia coli (formerly replication factor Y or protein n') is multifunctional. It is a site-specific, single-stranded DNA-dependent ATPase (dATPase), a 3'----5' DNA helicase, and guides the ordered assembly of the primosome, a mobile, multiprotein DNA replication priming/helicase complex. Although PriA is not absolutely required for viability, priA null mutant cells grow very slowly, have poor viability, and form extensive filaments. In order to assess which of the multiple activities of PriA are required for normal replication and growth, site-directed mutagenesis was employed to introduce single amino acid substitutions for the invariant lysine within the consensus nucleotide-binding motif found in PriA. Biochemical characterization of the representative purified mutant PriA proteins revealed them to be completely deficient in nucleotide hydrolysis, incapable of translocation along a single-stranded DNA binding protein-coated single-stranded DNA template, and unable to manifest the 3'----5' DNA helicase activity of wild-type PriA. These mutant proteins were, however, capable of catalyzing the assembly of active primosomes in vitro. Furthermore, when supplied in trans to insertionally inactivated priA cells, plasmids containing a copy of these mutant priA genes restored the wild-type growth rate, viability, and cell morphology. Based on these results, a model for PriA function in vivo is discussed.     

DnaA protein binding to the plasmid origin region can substitute for primosome assembly during replication of pBR322 in vitro

We analyzed the significance of DnaA protein binding to the origin region of pBR322. Replication of pBR322 in vitro was stimulated by DnaA protein. Moreover, the primosomal component protein i was no longer essential for replication after addition of DnaA protein, whereas, among others, proteins DnaB and DnaG were still required. Complete replication products were synthesized under these conditions. We constructed pBR322 deletion derivatives missing the primosome assembly sites. Efficient replication of these deletion plasmids was dependent on the presence of DnaA protein and its binding site, but independent of protein i activity. We conclude that DnaA protein binding to the pBR322 origin region substitutes for primosome assembly by directing DnaB, DnaC, and DnaG proteins to the origin. We term this process DnaA-directed pre-replisome formation.     

The brace for a growing scaffold: mss116 protein promotes RNA folding by stabilizing an early assembly intermediate

The ai5γ group II intron requires a protein cofactor to facilitate native folding in the cell. Yeast protein Mss116 greatly accelerates intron folding under near-physiological conditions both in vivo and in vitro. Although the effect of Mss116 on the kinetics of ai5γ ribozyme folding and catalysis has been extensively studied, the precise structural role and interaction sites of Mss116 have been elusive. Using Nucleotide Analog Interference Mapping to study the folding of splicing precursor constructs, we have identified specific intron functional groups that participate in Mss116-facilitated folding and we have determined their role in the folding mechanism. The data indicate that Mss116 stabilizes an early, obligate folding intermediate within intron domain 1, thereby laying the foundation for productive folding to the native state. In addition, the data reveal an important role for the IBS2 exon sequence and for the terminus of domain 6, during the folding of self-splicing group IIB intron constructs.     

Modulation of desmin intermediate filament assembly by a monoclonal antibody

We have used a monoclonal antibody against desmin to examine the assembly of intermediate filaments (IF) from their building blocks, the tetrameric protofilaments. The antibody, designated D76, does not cross react with any other IF proteins (Danto, S.I., and D.A. Fischman. 1984. J. Cell Biol. 98:2179-2191). It binds to a region amino-terminal to cys-324 of avian desmin that is resistant to chymotrypsin and trypsin digestion, and in the electron microscope appears to bind to the ends of tetrameric protofilaments. In combination, these findings suggest that the epitope of the antibody resides at the amino-terminal end of the alpha-helical rod domain. Preincubation of desmin protofilaments with an excess of D76 antibodies blocks their subsequent assembly into IF. In the presence of sub-stoichiometric amounts of antibodies, IF are assembled from protofilaments but they are morphologically aberrant in that (a) they are capped by IgG molecules at one or both ends; (b) they are unraveled to varying degree, revealing a characteristic right-handed helical arrangement of sub-filamentous strands of different diameters. The antibody binds only to the ends but not along the length of desmin IF. The most straightforward explanation for this is that the epitope resides in a part of the desmin molecule that becomes buried within the core of the filament upon polymerization and is therefore inaccessible to the antibody.     

Duplex opening by dnaA protein at novel sequences in initiation of replication at the origin of the E. coli chromosome

Three tandem repeats of a 13-mer in the AT-rich region are essential to the unique replication origin of E. coli and of remotely related Enterobacteriaceae. These iterated sequences are identified by deletion analysis and sensitivities to endonucleases as the site for initial duplex opening by the initiator dnaA protein. This "open complex" requires ATP and 38 degrees C for optimum formation and stability. The subsequent dnaC-dependent entry of dnaB helicase to form a "prepriming complex" stabilizes the open structure, blocks cleavages by a restriction endonuclease in the 13-mer region, and broadens the endonuclease cutting pattern. We propose that dnaA protein recognizes and successively opens the 13-mer sequences, thereby guiding the entry of dnaB helicase into the duplex preparatory to priming of replication.     

Escherichia coli PriA protein is essential for inducible and constitutive stable DNA replication.

Under certain conditions, Escherichia coli cells exhibit either of two altered modes of chromosomal DNA replication. These are inducible stable DNA replication (iSDR), seen in SOS-induced cells, and constitutive stable DNA replication (cSDR), seen in rnhA mutants. Both iSDR and cSDR can continue to occur in the absence of protein synthesis. They are dependent on RecA protein, but do not require DnaA protein or the oriC site. Here we report the requirement for PriA, a protein essential for assembly of the phi X174-type primosome, for both iSDR and cSDR. In priA1(Null)::kan mutant cells, iSDR is not observed after induction by thymine starvation. Replication from one of the origins (oriM1) specific to iSDR is greatly reduced by the priA1::kan mutation. cSDR in rnhA224 mutant cells deficient in RNase HI is also completely abolished by the same priA mutation. In both cases, SDR is restored by introduction of a plasmid carrying a wild-type priA gene. Furthermore, the viability of an rnhA::cat dnaA46 strain is lost at 42 degrees C upon inactivation of the priA gene, indicating the lethal effect of priA inactivation on those cells whose viability depends on cSDR. These results demonstrate that a function of PriA protein is essential for iSDR and cSDR and suggest the involvement of the PriA-dependent phi X174-type primosome in these DnaA/oriC-independent pathways of chromosome replication. Whereas ColE1-type plasmids, known to be independent of DnaA, absolutely require PriA function for replication, DnaA-dependent plasmid replicons such as pSC101, F, R6K, Rts1 and RK2 are able to transform and to be maintained in the priA1::kan strain.(ABSTRACT TRUNCATED AT 250 WORDS)     

Regulation of mammalian spliceosome assembly by a protein phosphorylation mechanism.

Splicing of mRNA precursors (pre-mRNA) is preceded by assembly of the pre-mRNA with small nuclear ribonucleoprotein particles (snRNPs) and protein factors to form a splicesome. Here we show that stimulating Ser/Thr-specific protein dephosphorylation selectively inhibits an early step during mammalian spliceosome assembly. Treatment of HeLa nuclear splicing extracts with human protein phosphatase 1 (PP1) expressed in Escherichia coli, or PP1 purified from rabbit skeletal muscle, prevents pre-spliceosome E complex (early complex) formation and stable binding of U2 and U4/U6.U5 snRNPs to the pre-mRNA. PP1 does not inhibit splicing catalysis if added after spliceosome assembly has taken place. Addition of purified SR protein splicing factors restores spliceosome formation and splicing to PP1-inhibited extracts, consistent with SR proteins being targets regulated by phosphorylation. These data extend earlier observations showing that splicing catalysis, but not spliceosome assembly, is blocked by inhibiting protein phosphatases. It therefore appears that pre-mRNA splicing, in common with other biological processes, can be regulated both positively and negatively by reversible protein phosphorylation.     

The 47-kD lens-specific protein phakinin is a tailless intermediate filament protein and an assembly partner of filensin

In previous studies we have characterized a lens-specific intermediate filament (IF) protein, termed filensin. Filensin does not self-assemble into regular IFs but is known to associate with another 47-kD lens- specific protein which has been suggested to represent its assembly partner. To address this possibility, we cloned and sequenced the cDNA coding for the bovine 47-kD protein which we have termed phakinin (from the greek phi alpha kappa omicron sigma = phakos = lens). The predicted sequence comprises 406 amino acids and shows significant similarity (31.3% identity over 358 residues) to type I cytokeratins. Phakinin possesses a 95-residue, non-helical domain (head) and a 311 amino acid long alpha-helical domain punctuated with heptad repeats (rod). Similar to cytokeratin 19, phakinin lacks a COOH-terminal tail domain and it therefore represents the second known example of a naturally tailless IF protein. Confocal microscopy on frozen lens sections reveals that phakinin colocalizes with filensin and is distributed along the periphery of the lens fiber cells. Quantitative immunoblotting with whole lens fiber cell preparations and fractions of washed lens membranes suggest that the natural stoichiometry of phakinin to filensin is approximately 3:1. Under in vitro conditions, phakinin self- assembles into metastable filamentous structures which tend to aggregate into thick bundles. However, mixing of phakinin and filensin at an optimal ratio of 3:1 yields stable 10-nm filaments which have a smooth surface and are ultrastructurally indistinguishable from "mainstream" IFs. Immunolabeling with specific antibodies shows that these filaments represent phakinin/filensin heteropolymers. Despite its homology to the cytokeratins, phakinin does not coassemble with acidic (type I), or basic (type II) cytokeratins. From these data we conclude that filensin and phakinin are obligate heteropolymers which constitute a new membrane-associated, lens-specific filament system related to, but distinct from the known classes of IFs.     

Evidence for a pro-oxidant intermediate in the assembly of cytochrome oxidase

The hydrogen peroxide sensitivity of cells lacking two proteins, Sco1 and Cox11, important in the assembly of cytochrome c oxidase (CcO), is shown to arise from the transient accumulation of a pro-oxidant heme A-Cox1 stalled intermediate. The peroxide sensitivity of these cells is abrogated by a reduction in either Cox1 expression or heme A formation but exacerbated by either enhanced Cox1 expression or heme A production arising from overexpression of COX15. Sco1 and Cox11 are implicated in the formation of the Cu(A) and Cu(B) sites of CcO, respectively. The respective wild-type genes suppress the peroxide sensitivities of sco1Delta and cox11Delta cells, but no cross-complementation is seen with noncognate genes. Copper-binding mutant alleles of Sco1 and Cox11 that are nonfunctional in promoting the assembly of CcO are functional in suppressing the peroxide sensitivity of their respective null mutants. Likewise, human Sco1 that is nonfunctional in yeast CcO assembly is able to suppress the peroxide sensitivity of yeast sco1Delta cells. Thus, a disconnect exists between the respiratory capacity of cells and hydrogen peroxide sensitivity. Hydrogen peroxide sensitivity of sco1Delta and cox11Delta cells is abrogated by overexpression of a novel mitochondrial ATPase Afg1 that promotes the degradation of CcO mitochondrially encoded subunits. Studies on the hydrogen peroxide sensitivity in CcO assembly mutants reveal new aspects of the CcO assembly process.     

Rapid assembly and disassembly of complementary DNA strands through an equilibrium intermediate state mediated by A1 hnRNP protein.

A1 hnRNP protein, which rapidly renatures complementary strands of nucleic acids in vitro, affects both the equilibrium and kinetic properties of the reaction (single-stranded DNA in equilibrium with double-stranded DNA). A1 lowers the melting transition of duplex DNA. However, at temperatures above this new Tm, both single- and double-stranded DNAs are present at equilibrium and are rapidly interconverting. Although the ratio of single and double strands under these conditions is a function of both the A1 protein and complementary DNA strand concentrations, it is not strongly affected by further increases in temperature. These surprising results demonstrate that A1 does not act as a simple catalyst in promoting renaturation and indicate how A1 and other proteins could act to speed the turnover of intermediate complexes in important biological processes.     

The geometry of a synaptic intermediate in a pathway of bacteriophage lambda site-specific recombination.

Bacteriophage lambda uses site-specific recombination to move its DNA into and out of the Escherichia coli genome. The recombination event is mediated by the phage-encoded integrase (Int) at short DNA sequences known as attachment ( att ) sites. Int catalyzes recombination via at least four distinct pathways, distinguishable by their requirements for accessory proteins and by the sequence of their substrates. The simplest recombination reaction catalyzed by Int does not require any accessory proteins and takes place between two attL sites. This reaction proceeds through an intermediate known as the straight-L bimolecular complex (SL-BMC), a stable complex which contains two attL sites synapsed by Int. We have investigated the orientation of the two substrates in the SL-BMC with respect to each other using two independent direct methods, a ligation assay and visualization by atomic force microscopy (AFM). Both show that the two DNA substrates in the complex are arranged in a tetrahedral or nearly square planar alignment skewed towards parallel. The DNA molecules in the complex are bent.     

Active-site assembly and mode of DNA cleavage by Flp recombinase during full-site recombination.

A combination of half-site substrates and step arrest mutants of Flp, a site-specific recombinase of the integrase family, had earlier revealed the following features of the half-site recombination reaction. (i) The Flp active site is assembled by sharing of catalytic residues from at least two monomers of the protein. (ii) A Flp monomer does not cleave the half site to which it is bound (DNA cleavage in cis); rather, it cleaves a half site bound by a second Flp monomer (DNA cleavage in trans). For the lambda integrase (Int protein), the prototype member of the Int family, catalytic complementation between two active-site mutants has been observed in reactions with a suicide attL substrate. By analogy with Flp, this observation is strongly suggestive of a shared active site and of trans DNA cleavage. However, reactions with linear suicide attB substrates and synthetic Holliday junctions are more compatible with cis than with trans DNA cleavage. These Int results either argue against a common mode of active-site assembly within the Int family or challenge the validity of Flp half sites as mimics of the normal full-site substrates. We devised a strategy to assay catalytic complementation between Flp monomers in full sites. We found that the full-site reaction follows the shared active-site paradigm and the trans mode of DNA cleavage. These results suggest that within the Int family, a unitary chemical mechanism of recombination is achieved by more than one mode of physical interaction among the recombinase monomers.