Overexpression, purification, and characterization of Escherichia coli bacteriophage PRD1 DNA polymerase. In vitro synthesis of full-length PRD1 DNA with purified proteins.

The bacteriophage PRD1 DNA polymerase gene (gene I) has been cloned into the expression vector pPLH101 under the control of the lambda pL promoter. Tailoring of an efficient ribosome binding site in front of the gene by polymerase chain reaction led to a high level heat-inducible expression of the corresponding gene product (P1) in Escherichia coli cells. Expression was confirmed in vivo by complementation of phage PRD1 DNA polymerase gene mutants and in vitro by formation of the genome terminal protein P8-dGMP replication initiation complex. Expressed PRD1 DNA polymerase was purified to apparent homogeneity in an active form. DNA polymerase, 3'-5'-exonuclease, and P8-dGMP replication initiation complex formation activities cosedimented in glycerol gradient with a protein of 65 kDa, the size expected for PRD1 DNA polymerase. The DNA polymerase was active on DNase I-activated calf thymus DNA, poly(dA).oligo(dT) and poly(dA-dT) primer/templates as well as on native phage PRD1 genome. The 3'-5'-exonuclease activity was specific for single-stranded DNA and released mononucleotides. No 5'-3'-exonuclease activity was detected. The inhibitor/activator spectrum of the PRD1 DNA polymerase was also studied. An in vitro replication system with purified components for bacteriophage PRD1 was established. Formation of the P8-dGMP replication initiation complex was a prerequisite for phage DNA replication, which proceeded from the initiation complex and yielded genome length replication products.     

In vitro initiation of bacteriophage phi 29 and M2 DNA replication: genes required for formation of a complex between the terminal protein and 5'dAMP

Cell-free extracts prepared from phi 29 and M2-infected Bacillus subtilis cells catalyse the formation of complexes between terminal protein and [alpha-32P]-dAMP in the presence of [alpha-32P]-dATP, MgCl2, ATP, and phage DNA with terminal protein covalently linked at both the 5'ends. The complex formation does not take place when proteinase K-treated DNA is added or when uninfected extract is used. The phi 29 complex thus formed is smaller than the M2 complex, primarily due to the different molecular weights of the respective terminal proteins. Extracts prepared from cells infected with suppressor-sensitive mutants of genes 2 or 3 of phi 29 or genes G or E of M2 do not support complex formation. When the pair of extracts of phi 29 or M2-infected cells are mixed, however, formation of the complex takes place as a result of in vitro complementation. These results indicate that the complex formation observed in vitro reflects in vivo initiation of phage DNA replication. The product of gene 2 of phi 29 may be the enzyme that catalyses formation of the complex.     

Factors involved in the initiation of phage phi 29 DNA replication in vitro: requirement of the gene 2 product for the formation of the protein p3-dAMP complex.

To study the requirements for the in vitro formation of the protein p3-dAMP complex, the first step in phi29 DNA replication, extracts from B. subtilis infected with phi29 mutants in genes 2, 3, 5, 6 and 17, involved in DNA synthesis, have been used. The formation of the initiation complex is completely dependent on the presence of a functional gene 2 product, in addition to protein p3 and phi29 DNA-protein p3 as template. ATP is also required, although it can be replaced by other nucleotides. The products of genes 5, 6 and 17 do not seem to be needed in the formation of the initiation complex. Inhibitors of the host DNA polymerase III, DNA gyrase or RNA polymerase had no effect on the formation of the protein p3-dAMP complex, suggesting that these proteins are not involved in the initiation of phi29 DNA replication. ddATP or aphidicolin, inhibitors of DNA chain elongation, had also no effect on the formation of the initiation complex.     

Bacteriophage P1 genes involved in the recognition and cleavage of the phage packaging site (pac).

The packaging of bacteriophage P1 DNA is initiated by cleavage of the viral DNA at a specific site, designated pac. The proteins necessary for that cleavage, and the genes that encode those proteins, are described in this report. By sequencing wild-type P1 DNA and DNA derived from various P1 amber mutants that are deficient in pac cleavage, two distinct genes, referred to as pacA and pacB, were identified. These genes appear to be coordinately transcribed with an upstream P1 gene that encodes a regulator of late P1 gene expression (gene 10). pacA is located upstream from pacB and contains the 161 base-pair pac cleavage site. The predicted sizes of the PacA and PacB proteins are 45 kDa and 56 kDa, respectively. These proteins have been identified on SDS-polyacrylamide gels using extracts derived from Escherichia coli cells that express these genes under the control of a bacteriophage T7 promoter. Extracts prepared from cells expressing both PacA and PacB are proficient for site-specific cleavage of the P1 packaging site, whereas those lacking either protein are not. However, the two defective extracts can complement each other to restore functional pac cleavage activity. Thus, PacA and PacB are two essential bacteriophage proteins required for recognition and cleavage of the P1 packaging site. PacB extracts also contain a second P1 protein that is encoded within the pacB gene. We have identified this protein on SDS-polyacrylamide gels and have shown that it is translated in the same reading frame as is PacB. Its role, if any, in pac cleavage is yet to be determined.     

Retention of the herpes simplex virus type 1 (HSV-1) UL37 protein on single-stranded DNA columns requires the HSV-1 ICP8 protein.

The UL37 and ICP8 proteins present in herpes simplex virus type 1 (HSV-1)-infected-cell extracts produced at 24 h postinfection coeluted from single-stranded-DNA-cellulose columns. Experiments carried out with the UL37 protein expressed by a vaccinia virus recombinant (V37) revealed that the UL37 protein did not exhibit DNA-binding activity in the absence of other HSV proteins. Analysis of extracts derived from cells coinfected with V37 and an ICP8-expressing vaccinia virus recombinant (V8) and analysis of extracts prepared from cells infected with the HSV-1 ICP8 deletion mutants d21 and n10 revealed that the retention of the UL37 protein on single-stranded DNA columns required a DNA-binding-competent ICP8 protein.     

Mechanism of head assembly and DNA encapsulation in Salmonella phage p22. I. Genes, proteins, structures and DNA maturation

The functions of ten known late genes are required for the intracellular assembly of infectious particles of the temperate Salmonella phage P22. The defective phenotypes of mutants in these genes have been characterized with respect to DNA metabolism and the appearance of phage-related structures in lysates of infected cells. In addition, proteins specified by eight of the ten late genes were identified by sodium dodecyl sulfate/polyacrylamide gel electrophoresis; all but two are found in the mature phage particle. We do not find cleavage of these proteins during morphogenesis.The mutants fall into two classes with respect to DNA maturation; cells infected with mutants of genes 5, 8, 1, 2 and 3 accumulate DNA as a rapidly sedimenting complex containing strands longer than mature phage length. 5^? and 8^? lysates contain few phage-related structures. Gene 5 specifies the major head structural protein; gene 8 specifies the major protein found in infected lysates but not in mature particles. 1^?, 2^? and 3^? lysates accumulate a single distinctive class of particle (“proheads”), which are spherical and not full of DNA, but which contain some internal material. Gene 1 protein is in the mature particle, gene 2 protein is not.Cells infected with mutants of the remaining five genes (10, 26, 16, 20 and 9) accumulate mature length DNA. 10^? and 26^? lysates accumulate empty phage heads, but examination of freshly lysed cells shows that many were initially full heads. These heads can be converted to viable phage by in vitro complementation in concentrated extracts. 16^? and 20^? lysates accumulate phage particles that appear normal but are non-infectious, and which cannot be rescued in vitro.From the mutant phenotypes we conclude that an intact prohead structure is required to mature the virus DNA (i.e. to cut the overlength DNA concatemer to the mature length). Apparently this cutting occurs as part of the encapsulation event.     

Assembly of bacteriophage PRD1: particle formation with wild-type and mutant viruses

Bacteriophage PRD1 contains DNA, 17 proteins, and lipid. The assembly pathway involves the formation of empty particles that contain lipid and all of the proteins of mature virions, with the possible exception of one. The major and minor capsid proteins, P3 and P5, occur as soluble multimers before they appear in the empty particles. Nonsense mutants of PRD1 that involve structural proteins of the virion other than P3 form particles that are missing only the defective protein. Those mutants that are unable to form P3 do not form particles. Mutations in two other genes that code for nonstructural proteins (P10, which is membrane bound, and P17, which is soluble) result in the absence of particles. Protein P2 is necessary for adsorption to host cells. Protein P9 is necessary for particle filling with DNA, whereas P20 and P22 are necessary for stable DNA packaging. Electron micrographs of infected cells confirmed the gradient analysis of particle formation. No free vesicles were observed in mutants that could not form complete empty particles, indicating that there are no free intermediate particles before the empty virions.     

Herpes simplex virus type 1 origin-specific binding protein: oriS-binding properties and effects of cellular proteins.

The herpes simplex virus type 1 (HSV-1) origin of replication, oriS, contains three highly homologous sequences, sites I, II, and III. The HSV-1 origin-binding protein (OBP), the product of the UL9 gene, has been shown to bind specifically to sites I and II. In this study, gel shift analysis was used to characterize interactions between site I DNA and proteins in infected and uninfected cell extracts. The formation of two protein-DNA complexes, bands A and B, was demonstrated with infected cell extracts, and one predominant protein-DNA complex, band M, was identified with mock-infected extracts. Protein interactions with the highly homologous site II and III DNAs were also characterized. Incubation of infected cell extracts with the lower-affinity site II DNA as a probe resulted in the appearance of two protein-DNA complexes with mobilities identical to those of the A and B complexes, while incubation with site III DNA resulted in the formation of a single complex with the mobility of band B; no A-like band was observed. Incubation of high concentrations of partially purified OBP with site I DNA resulted in the formation of two novel complexes, bands 9-1 and 9-2. Addition of uninfected or HSV-1-infected cell extracts to the purified OBP-site I DNA mix significantly enhanced the formation of complex 9-1. The enhanced formation of complex 9-1 by uninfected cell extracts implicates a cellular factor or factors in the formation or stabilization of the OBP-site I DNA complex.     

Bovine adenovirus‐3 protein VIII associates with eukaryotic initiation factor‐6 during infection

Adenovirus protein VIII appears to connect core with the inner surface of the adenovirus capsid. Because protein–protein interactions are central to virus replication, identification of proteins interacting with protein VIII may help in understanding their role in adenovirus infection. Our yeast 2‐hybrid assay indicated that protein VIII interacts with eukaryotic initiation factor 6 (eIF6). These findings were confirmed by Glutathione S‐transferase‐pull down assay, bimolecular fluorescent complementation assay, and coimmunoprecipitation assay in plasmid DNA transfected and bovine adenovirus‐3 (BAdV‐3) infected cells. The C‐terminus amino acids 147 to 174 of protein VIII and N‐terminus amino acids 44 to 97 of eIF6 are involved in these interactions. Polysome analysis demonstrated increased level of 60S ribosomal subunit and decreased level of 80S complex in protein VIII expressing cells or BAdV‐3 infected cells. Our results suggest that formation of functional 80S ribosome appears impaired in the presence of protein VIII at late times post infection. We speculate that this impaired ribosome assembly may be responsible for the inhibition of cellular mRNA translation observed late in adenovirus infected cells. Moreover, analysis of recombinant BAdV‐3 expressing mutant protein VIII (deletion of eIF6 interacting domain) suggests that interaction of protein VIII and eIF6 may help in preferential translation of adenovirus genes during late phase of adenovirus infection.     

Vaccinia virus telomeres: interaction with the viral I1, I6, and K4 proteins

The 192-kb linear DNA genome of vaccinia virus has covalently closed hairpin termini that are extremely AT rich and contain 12 extrahelical bases. Vaccinia virus telomeres have previously been implicated in the initiation of viral genome replication; therefore, we sought to determine whether the telomeres form specific protein-DNA complexes. Using an electrophoretic mobility shift assay, we found that extracts prepared from virions and from the cytoplasm of infected cells contain telomere binding activity. Four shifted complexes were detected using hairpin probes representing the viral termini, two of which represent an interaction with the "flip" isoform and two with the "flop" isoform. All of the specificity for protein binding lies within the terminal 65-bp hairpin sequence. Viral hairpins lacking extrahelical bases cannot form the shifted complexes, suggesting that DNA structure is crucial for complex formation. Using an affinity purification protocol, we purified the proteins responsible for hairpin-protein complex formation. The vaccinia virus I1 protein was identified as being necessary and sufficient for the formation of the upper doublet of shifted complexes, and the vaccinia virus I6 protein was shown to form the lower doublet of shifted complexes. Competition and challenge experiments confirmed that the previously uncharacterized I6 protein binds tightly and with great specificity to the hairpin form of the viral telomeric sequence. Incubation of viral hairpins with extracts from infected cells also generates a smaller DNA fragment that is likely to reflect specific nicking at the apex of the hairpin; we show that the vaccinia virus K4 protein is necessary and sufficient for this reaction. We hypothesize that these telomere binding proteins may play a role in the initiation of vaccinia virus genome replication and/or genome encapsidation.     

Mapping of a region of the paramyxovirus L protein required for the formation of a stable complex with the viral phosphoprotein P.

The paramyxovirus large protein (L) and phosphoprotein (P) are both required for viral RNA-dependent RNA polymerase activity. Previous biochemical experiments have shown that L and P can form a complex when expressed from cDNA plasmids in vivo. In this report, L and P proteins of the paramyxovirus simian virus 5 (SV5) were coexpressed in HeLa T4 cells from cDNA plasmids, and L-P complexes were examined. To identify regions of the SV5 L protein that are required for L-P complex formation, 16 deletion mutants were constructed by mutagenesis of an SV5 L cDNA. Following coexpression of these L mutants with cDNA-derived P and radiolabeling with 35S-amino acids, cell lysates were analyzed for stable L-P complexes by a coimmunoprecipitation assay and by sedimentation on 5 to 20% glycerol gradients. Mutant forms of L containing deletions that removed as much as 1,008 residues from the C-terminal half of the full-length 2,255-residue L protein were detected in complexes with P by these two assays. In contrast, large deletions in the N-terminal half of L resulted in proteins that were defective in the formation of stable L-P complexes. Likewise, L mutants containing smaller deletions that individually removed N-terminal regions which are conserved among paramyxovirus and rhabdovirus L proteins (domain I, II, or III) were also defective in stable interactions with P. These results suggest that the N-terminal half of the L protein contains sequences important for stable L-P complex formation and that the C-terminal half of L is not directly involved in these interactions. SV5-infected HeLa T4 cells were pulse-labeled with 35S-amino acids, and cell extracts were examined by gradient sedimentation. Solubilized L protein was detected as an approximately 8 to 10S species, while the P protein was found as both a approximately 4S form (approximately 85%) and a species that cosedimented with L (approximately 15%). These data provide the first biochemical evidence in support of a simple domain structure for an L protein of the nonsegmented negative-sense RNA viruses. The results are discussed in terms of a structural model for the L protein and the interactions of L with the second viral polymerase subunit P.     

Relationships among genes and gene products of bacteriophage BF23

Twenty-five gene products of bacteriophage BF23 were identified by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, and their functions were studied in relation to type I and II genes classified by means of genetic complementation tests. All the type I mutants were defective in the synthesis of a tail protein, L3. In addition, 4 type I gene products, L5 (gp21), L7 (gp20), L8 (gp29), and L9 (gp25), were identified as constituents of tails (gp21 denotes that a protein is a product of gene 21). Three type IIb mutants in genes 10, 14, and 19 diminished substantially the production of late proteins, including tail and head proteins, and the two other type IIb mutants in genes 1 and 2 were defective in the synthesis of both early and late proteins. Of 14 type IIa mutants, at least 6 were defective in phage DNA synthesis and 2 were defective in the synthesis of head proteins. The defect in the head donor activities of type IIa mutants in extract complementation tests was due to the failure of the formation of mature heads containing DNA. The above results support directly the results of the genetic characterization of BF23 genes.     

Requirement for three novel protein complexes in the absence of the Sgs1 DNA helicase in Saccharomyces cerevisiae

The Saccharomyces cerevisiae Sgs1 protein is a member of the RecQ family of DNA helicases and is required for genome stability, but not cell viability. To identify proteins that function in the absence of Sgs1, a synthetic-lethal screen was performed. We obtained mutations in six complementation groups that we refer to as SLX genes. Most of the SLX genes encode uncharacterized open reading frames that are conserved in other species. None of these genes is required for viability and all SLX null mutations are synthetically lethal with mutations in TOP3, encoding the SGS1-interacting DNA topoisomerase. Analysis of the null mutants identified a pair of genes in each of three phenotypic classes. Mutations in MMS4 (SLX2) and SLX3 generate identical phenotypes, including weak UV and strong MMS hypersensitivity, complete loss of sporulation, and synthetic growth defects with mutations in TOP1. Mms4 and Slx3 proteins coimmunoprecipitate from cell extracts, suggesting that they function in a complex. Mutations in SLX5 and SLX8 generate hydroxyurea sensitivity, reduced sporulation efficiency, and a slow-growth phenotype characterized by heterogeneous colony morphology. The Slx5 and Slx8 proteins contain RING finger domains and coimmunoprecipitate from cell extracts. The SLX1 and SLX4 genes are required for viability in the presence of an sgs1 temperature-sensitive allele at the restrictive temperature and Slx1 and Slx4 proteins are similarly associated in cell extracts. We propose that the MMS4/SLX3, SLX5/8, and SLX1/4 gene pairs encode heterodimeric complexes and speculate that these complexes are required to resolve recombination intermediates that arise in response to DNA damage, during meiosis, and in the absence of SGS1/TOP3.     

DNA replication with bacteriophage T4 proteins. Purification of the proteins encoded by T4 genes 41, 45, 44, and 62 using a complementation assay.

The proteins encoded by bacteriophage T4 genes 41, 45, 44, and 62 are known from the genetic studies of Epstein et al. ((1963) Cold Spring Harbor Symp. Quant. Biol. 28, 375--394) to be required for viral DNA synthesis. A convenient assay for each of these proteins is described which is based on the specific stimulation by each protein of DNA synthesis in extracts of Escherichia coli infected with mutants of bacteriophage T4 unable to make that protein. The T4 41 protein, 45 protein, and the complex of the 44 and 62 proteins have been highly purified. For each protein there is co-chromatography during the final purification step of (i) activity in the complementation assay, (ii) activity required for DNA synthesis with other purified T4 proteins, and (iii) a subunit of the size previously identified as that of the corresponding gene product.     

The bacteriophage P4 alpha gene is the structural gene for bacteriophage P4-induced RNA polymerase

Two temperature-sensitive mutants of satellite phage P4 which do not synthesize P4 DNA at the nonpermissive temperature have been isolated. One of these phage is mutated in the P4 alpha gene. It complements a P4 delta mutant, but not a P4 alpha amber mutant; both mutants are phenotypically identical to alpha amber mutants in all properties studied. They synthesize P4 early proteins 1 and 2 as well as two additional P4-induced early proteins, 5 and 6, which are described here. P4 late proteins are not synthesized by these mutants and cannot be transactivated by helper phage P2. The mutants are unable to transactivate P2 late proteins from a P2 AB mutant. The P4 RNA polymerase activity which has been suggested to be involved in P4 DNA synthesis is not detected at the nonpermissive temperature. The P4 polymerase activity in partially purified extracts prepared from cells infected with the mutant at the permissive temperature is temperature sensitive. Reduced activity is found in vitro when these extracts are preincubated at 41 degrees C or assayed at temperatures higher than 37 degrees C. Thus, the P4 RNA polymerase is the product of the alpha gene. Temperature shift experiments show that the alpha gene product is required until late in the P4 cycle.     

Two of the three influenza viral polymerase proteins expressed by using baculovirus vectors form a complex in insect cells.

Each of the influenza virus polymerase (P) genes PB1, PB2, and PA was inserted into a baculovirus vector under the control of the polyhedrin promoter. In insect (Spodoptera frugiperda) cells infected by each baculovirus recombinant containing a P gene insert, a large amount of the encoded P protein was synthesized. Gel electrophoretic analysis of the total proteins in infected cells revealed the presence of a new protein band corresponding to the encoded P protein that was abundant enough to be stained with Coomassie blue. In cells infected simultaneously with both the PB1 and PB2 baculovirus recombinants, a PB1-PB2 complex was formed that was immunoprecipitated with an antiserum specific for either PB1 or PB2. In cells infected simultaneously with all three P baculovirus recombinants, a PB1-PB2 complex lacking the PA protein was formed. Formation of this PB1-PB2 complex partially mimics events that occur in influenza virus-infected cells, where all three P proteins form a complex with each other (B. M. Detjen, C. St. Angelo, M. G. Katze, and R. M. Krug, J. Virol. 61:16-22, 1987). These results indicate that the ability of PB1 and PB2 to form a complex is an intrinsic property of these two proteins that does not require the participation of other influenza viral gene products. Possible reasons for the absence of the PA protein from the immunoprecipitable P protein complex in insect cells infected by the three P baculovirus recombinants are discussed.     

Herpes simplex virus helicase-primase: the UL8 protein is not required for DNA-dependent ATPase and DNA helicase activities.

The herpes simplex virus type 1 helicase-primase complex consists of the products of the UL5, UL8 and UL52 genes. We have expressed these proteins in insect cells using baculovirus vectors and studied the requirements for enzymatic activities associated with the DNA unwinding function of the complex. In agreement with a recent report (Dodson, M.S., Crute, J.J., Bruckner, R.C. and Lehman, I.R. 1989, J. Biol. Chem. 264, 20835-20838) we find that DNA-dependent ATPase and DNA helicase activities are assembled in vivo in insect cells triply infected with viruses expressing the UL5, UL8 and UL52 proteins. Moreover, these activities were also detected in cells in which only the UL5 and UL52 products were expressed indicating that the presence of the UL8 protein is essential for neither the ATPase nor helicase activity of the complex.