Characterization of a protein covalently linked to the 5' termini of the DNA of Bacillus subtilis phage phi29

In vitro transcription of the Bacillus subtilis phage phi 29 DNA by Bacillus subtilis and Escherichia coli RNA polymerases

The Escherichia coli RNA polymerase bound to phage phi 29 DNA has been visualized by electron microscopy. Thirteen specific binding sites have been observed at 1.7,2.6,5.5,10.4,13.7,25.2,25.7,26.3,33.5,59.5,69.2,91.7 and 99.6 DNA length units and they have been named A1,A1I,A1II,A1III,A1IV,A2,A2I, A3, A4,B1,B1I,C1 and C2, respectively. The binding sites A1,A2,A3,B1,C1 and C2 coincide with those found with Bacillus subtilis RNA polymerase. The transcription of phage phi 29 DNA with B. subtilis or E. coli RNA polymerases has been studied. With the B. subtilis RNA polymerase eight transcripts were found, starting at positions corresponding to the binding sites A1, A1III, A2,A3,B1I,B2,C1 and C2, respectively. With the E. coli RNA polymerase the same transcripts were found and a new one starting at position corresponding to the A4 binding site. The RNAs starting at binding sites A1,A1III,A2,B1I, B2,C1 and C2 are transcribed from right to left, as expected for early RNA. The RNAs which initiate at positions A3 and A4 are transcribed from left to right and probably correspond to late RNAs.

Antibodies specific for the phi 29 terminal protein inhibit the initiation of DNA replication in vitro

The phi 29 DNA-terminal protein serves as a primer for the initiation of DNA replication by covalently binding the first nucleotide in the DNA chain. Two distinct antibodies were used for functional analysis of this protein. One antibody was raised against sonicated phi 29 DNA-protein complex isolated from phage virions (anti-TP). The other antibody was raised against a conjugate of bovine serum albumin and a synthetic peptide corresponding to the carboxy-terminal of the phi 29 terminal protein (anti-gp3C), which was predicted from the nucleotide sequence of phi 29 DNA. Both antibodies react with native phi 29 terminal protein as determined by immunoprecipitation and enzyme-linked immunosorbent assay. Both antibodies specifically inhibit the complex-forming reaction between the phi 29 terminal protein and dAMP, the first nucleotide of phi 29 DNA.

Nucleotide sequence at the termini of the DNA of Streptococcus pneumoniae phage Cp-1

The 5' ends of Cp-1 DNA, which have a covalently linked terminal protein, can be partially unblocked by treatment with 1 M NaOH (E. Garcia, A. Gomez, C. Ronda, C. Escarmis, and R. Lopez (1983) Virology 128, 92-104) and labeled with polynucleotide kinase and [gamma-32P]ATP. The sequence of the first 444 and 520 nucleotides at the termini of Cp-1 DNA has been determined. A 236-nucleotide-long inverted terminal repeat was found and, in addition, the 116 nucleotides following the repeat show 93% homology. The first 352 nucleotides at both ends have an adenine plus thymine content of 75%. More than 50% of the nucleotides of the sequenced regions are involved in repeats of a minimum of 8 nucleotides. Three promoter-like sequences were also found at each end of Cp-1 DNA.

Enzymology of DNA in replication in prokaryotes

This review stresses recent developments in the in vitro study of DNA replication in prokaryotes. New insights into the enzymological mechanisms of initiation and elongation of leading and lagging strand DNA synthesis in ongoing studies are emphasized. Data from newly developed systems, such as those replicating oriC containing DNA or which are dependent on the lambda, O, and P proteins, are presented and the information compared to existing mechanisms. Evidence bearing on the coupling of DNA synthesis on both parental strands through protein-protein interactions and on the turnover of the elongation systems are analyzed. The structure of replication origins, and how their tertiary structure affects recognition and interaction with the various replication proteins is discussed.

Template requirements for initiation of phage phi 29 DNA replication in vitro

The template requirements for the formation of the phi 29 protein p3-dAMP initiation complex in vitro have been studied. The initiation reaction requires the parental protein p3 but not an intact DNA molecule. Protein p3-containing fragments from the left- or right-hand DNA ends were active as template for formation of the initiation complex provided they had a minimal size: a 26-base-pair-long fragment was active whereas a 10-base-pair-long one was essentially inactive. However, the activity of the latter was restored by ligation of an unspecific DNA sequence. phi 29 DNA internal fragments, as well as denatured phi 29 DNA, were inactive as template for the initiation reaction. The terminal protein-DNA complex isolated from Bacillus phage phi 15 was active in formation of the phi 29 p3-dAMP complex, whereas the protein-DNA complex isolated from Bacillus phage GA-1 or from the pneumococcal phage Cp-1, both with a morphology similar to that of phage phi 29, as well as that obtained from adenovirus, were inactive.

Initiation of phage phi 29 DNA replication by the terminal protein modified at the carboxyl end

A mutant at the carboxyl end of the terminal protein, p3, of phage phi 29 DNA has been constructed by inserting an containing the stop translation codon TGA in the three possible reading frames, immediately downstream of a phage phi 29 DNA fragment coding for all but the last five amino acids of protein p3. The activity in the formation of the p3-dAMP initiation complex in vitro of this mutant as well as another one previously isolated, also mutated at the carboxyl end, have been tested. The results obtained suggest that an intact carboxyl end in the phage phi 29 terminal protein is essential for its normal primer function in DNA replication.

Identification of a protein bound to the termini of bacteriophage PRD1 DNA

Lipid-containing bacteriophage PRD1 has a double-stranded DNA genome of about 14,500 nucleotide base pairs. The phage can infect Escherichia coli and Salmonella typhimurium as well as other gram-negative bacteria harboring an appropriate plasmid. [35S]methionine label is incorporated into the DNA band early in infection. The label remains associated with DNA through phenol extraction and boiling with sodium dodecyl sulfate. Nuclease treatment of the genome released a protein which migrated as an early phage-specific protein (P8). This protein is also necessary for phage DNA replication. By restriction enzyme analysis it was shown that protein was associated with the terminal restriction fragments. Extracts of infected cells catalyzed the labeling of protein P8 with [alpha-32P]dGTP.

Pneumococcal bacteriophage Cp-1 contains a protein bound to the 5' termini of its DNA

The genome of the pneumococcal bacteriophage Cp-1 has been isolated as a DNA-protein complex. The transfecting activity of this complex is destroyed by treatment with proteolytic enzymes. The DNA-protein complexes do not enter into agarose or acrylamide gels and are retained on glass fiber filters. The protein is specifically associated with the two 5' termini of Cp-1 DNA on the basis of experiments carried out with restriction endonucleases, exonucleases, and radioactive labeling with [gamma-32P]ATP and polynucleotide kinase. The protein component, iodinated in vitro with 125I, has a molecular weight of 28,000 determined by SDS-polyacrylamide gel electrophoresis. The protein remains associated with the Cp-1 DNA after thermal or alkali denaturation, incubation with 6 M guanidinium chloride or 8 M urea, and boiling in 2% SDS, 2% mercaptoethanol, and 6 M urea. When the complex was incubated in 1 M sodium hydroxide or 2.5 M piperidine only a partial breakage of the DNA-protein bond was observed. These results indicate that the 28,000-Da protein is covalently bound to the 5' termini of the DNA.

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.

Protein-primed initiation of phage phi 29 DNA replication

We recently reported the development of an in vitro replication system for bacteriophage phi 29 DNA. We have used this system for the isolation of replication activity associated with gene 3 protein (terminal protein) from phi 29-infected Bacillus subtilis cells. We utilized two assay systems: (i) DNA replication dependent on phi 29 DNA with the 5' end covalently linked to terminal protein (DNA-protein) and (ii) the formation of complex between the terminal protein and dAMP. The DNA-replication and the complex-forming activities were purified together through all steps. The complex of terminal protein and dAMP formed in the purified fraction was shown to serve as an effective primer for successive chain elongation in the presence of dNTPs by a pulse-chase experiment. The protein fraction purified from cells infected with a temperature-sensitive phi 29 mutant in gene 3 was thermolabile compared to the wild-type activity in the assay system for complex formation. This shows that the purified fraction having replication activity includes the gene 3 product of phi 29. Both the DNA replication and the complex formation activities are highly specific for phi 29 DNA-protein as template. The product analysis of elongated DNA revealed that the replication starts at both termini of the phi 29 genome. These results are consistent with the basic elements of the protein-priming model for the initiation of linear DNA synthesis.

In vitro synthesis of late bacteriophage phi 29 RNA

A crude P-100 fraction prepared from Bacillus subtilis 21 min after infection with wild-type phage phi 29 supported the in vitro synthesis of late phi 29 RNA by added RNA polymerase. Synthesis of late RNA was also detected when purified phi 29 DNA was transcribed by RNA polymerase in the presence of an S-150 fraction obtained by lysis of phi 29-infected cells in the presence of 1 M NaCl. Late phi 29 RNA was not synthesized when either the P-100 or the S-150 fraction was prepared from cultures infected with phi 29 having a mutation in gene 4.

Organization of DNA sequences and replication origins at yeast telomeres

We have shown that the DNA sequences adjacent to the telomeres of Saccharomyces cerevisiae chromosomes are highly conserved and contain a high density of replication origins. The salient features of these telomeres can be summarized as follows. There are three moderately repetitive elements present at the telomeres: the 131 sequence (1 to 1.5 kb), the highly conserved Y sequence (5.2 kb), and the less conserved X sequence (0.3 to 3.75 kb). There is a high density of replication origins spaced about 6.7 kb apart at the telomeres. These replication origins are part of the X or the Y sequences. Some of the 131-Y repetitive units are tandemly arranged. The terminal sequence T (about 0.33 to 0.6 kb) is different from the 131, X, or Y sequences and is heterogeneous in length. The order of these sequences from the telomeric end towards the centromere is T-(Y-131)n-X-, where n ranges from 1 to no more than 4. Although these telomeric sequences are conserved among S. cerevisiae strains, they show striking divergence in certain closely related yeast species.

Characteristics of the nascent and non-nascent small DNA molecules found in Escherichia coli

We have purified nascent DNA molecules from Escherichia coli pulse-labeled with 5-bromo[6-3H]deoxyuridine by repeated chromatography on nitrocellulose and isopycnic centrifugation in CsCl. The nascent molecules were labeled with 32P either at their 5' ends using polynucleotide kinase or at their 3' ends using terminal transferase. Compared to the non-nascent DNA of normal density, the nascent dense DNA contained a higher proportion of molecules terminated at their 5' ends with ribonucleotides. Exposure of the dense DNA to alkali generated 5' OH termini quantitatively equivalent to the number of molecules bearing 5' ribonucleotides. Experiments designed (1) to detect structures at the 5' ends of phosphatase-treated nascent DNA molecules that caused them to be resistant to hydrolysis by spleen exonuclease or (2) to detect polypeptides that were associated covalently with small DNA molecules and could be iodinated with the Bolton-Hunter reagent did not yield positive results. We conclude that many, if not all, of the intermediates in E. coli DNA replication are initiated with one or more ribonucleotides. The nascent molecules are outnumbered by small non-nascent DNA molecules in the cell, many of which appear to become slightly longer when cells are pulsed with thymidine. Many of the non-nascent DNA molecules behave as if they were self-complementary or crosslinked.

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.

Cloning and expression in Escherichia coli of the gene coding for the protein linked to the ends of Bacillus subtilis phage phi 29 DNA

A phi 29 DNA fragment containing gene 3, coding for the 5'-terminal protein, and several other early genes has been cloned in a pBR322 derivative plasmid (pKC30) under the control of the pL promoter of bacteriophage lambda. Four polypeptides of Mr 27000, 18500, 17500 and 12500 were labelled with [35S]methionine after heat induction, accounting for about 15% of the de novo synthesized protein. The Mr 27000 and 12500 proteins were characterized as p3, the 5'-terminal protein, and p4, involved in the control of late transcription, respectively. Protein p3 synthesized in Escherichia coli was active in the in vitro formation of the initiation complex p3-dAMP when supplemented with extracts from Bacillus subtilis infected with a sus3 mutant.

Morphogenesis of bacteriophage phi 29 of Bacillus subtilis: oriented and quantized in vitro packaging of DNA protein gp3

The assembly of phage phi 29 occurs by a single pathway, and the DNA protein (DNA-gp3) of "packaging intermediates" can be obtained after DNase I interruption of in vitro complementation. A broad spectrum of DNA molecules of variable length was isolated from DNase I-treated proheads. Restriction endonuclease EcoRI digestion and electrophoretic analysis of these DNA molecules suggested that DNA-gp3 packaging was oriented with respect to the physical map and was a complex process. Proteinase K-treated exogenous DNA was not packaged. When exogenous DNA-gp3 was predigested with the restriction endonucleases BstEII. EcoRI, HpaI, and HpaII, the left-end fragments, ranging in size from 8 to 0.9 megadaltons, were selectively and efficiently packaged. During in vivo and in vitro assembly, DNA-gp3 is packaged into proheads, the "core-scaffolding" protein gp7 exits from the particles, and the DNA-filled heads assume the angular morphology of phage phi 29. The packaging of a 4.1-megadalton DNA-gp3 left-end fragment (one third of the genome) resulted in the exit of gp7 and the transition to angularity.

S1 and S2, the linear mitochondrial DNAs present in a male sterile line of maize, possess terminally attached proteins

S1 and S2 are short linear mitochondrial DNA molecules found in a particular male sterile cytoplasm of maize. We show here that these DNA molecules and two other related linear DNA species found in maize mitochondria, have proteins attached, probably covalently, to their 5' ends. This is the first demonstration of such a linear DNA-terminal protein association in higher eukaryotes. Such proteins may be involved in priming replication of these DNAs.

High level synthesis in Escherichia coli of the Bacillus subtilis phage phi 29 proteins p3 and p4 under the control of phage lambda PL promoter

The Hind III G fragment from the Bacillus subtilis phage phi 29 DNA, inserted downstream from the bacteriophage lambda promoter PL carried by a pBR322 derivative plasmid (pPLc28), directed the synthesis in E. coli of two proteins of apparent molecular weight 27500 and 12500. With the use of the recombinants obtained with the DNA from mutants sus3(91) and sus4(56), the two proteins were identified as a modified p3 (p3'), the protein covalently linked to the 5' ends of phi 29 DNA, and p4, responsible for the phi 29 late transcription, respectively. Under the best conditions used, proteins p4 and p3' were produced in E. coli from the cloned DNA fragments in an amount corresponding to approximately 30% and 6% of total de novo protein synthesis, respectively.

Nucleotide sequence of the early genes 3 and 4 of bacteriophage phi 29

The nucleotide sequence of an early region of the phi 29 genome has been determined. The sequenced region includes genes 3 and 4, which code for the protein covalently linked to the 5' ends of phi 29 DNA and the protein involved in the control of late transcription, respectively. The position and nature of the mutations of mutants sus3(91) and sus4(56) has also been determined.

Initiation of phage phi 29 DNA replication in vitro: formation of a covalent complex between the terminal protein, p3, and 5'-dAMP

Incubation of extracts of phi 29-infected Bacillus subtilis with [alpha-32P]dATP produced a labeled protein having the electrophoretic mobility of p3, the 5'-terminal protein of phi 29 DNA. The reaction product was resistant to treatment with micrococcal nuclease, phosphatase, and RNases A and T1 and sensitive to proteinase K. Incubation of the 32P-labeled protein with piperidine under conditions in which the phi 29 DNA-protein p3 linkage is hydrolyzed released 5'-dAMP. The reaction with [alpha-32P]dATP was strongly inhibited by anti-p3 serum and required the preence of phi 29 DNA-protein p3 complex; no reaction took place with proteinase K-treated phi29 DNA. These results, together with those of acid hydrolysis and partial proteolysis, indicated that a covalent complex between protein p3 and 5'-dAMP is formed in vitro. The initiation complex (protein p3-dAMP) formed in the presence of 0.5 microM [alpha-32P]dATP can be elongated by addition of 40 microM dNTPs. Treatment with piperidine of the product elongated in the presence of 2',3'-dideoxycytidine 5'-triphosphate released the expected oligonucleotides, 9 and 12 bases long, taking into account the sequence at the left and right DNA ends, respectively.

In vitro replication of bacteriophage phi 29 DNA

We have been studying the mechanisms of linear DNA replication by using Bacillus bacteriophage phi 29 as a model system. To isolate and characterize the proteins required for phi 29 DNA replication, we have developed a cell-free replication system. A cell-free extract prepared from phi 29-infected Bacillus subtilis catalyzes the semiconservative replication of phi 29 DNA, but only if exogenous phi 29 DNA-protein complex is used as the template. This template consists of linear duplex DNA with a 30,000-dalton terminal protein attached covalently to both 5' ends. Replication starts nonsimultaneously at or near both ends of the template. The extract also catalyzes the specific binding between dATP and the phi 29 terminal protein. Thus, the in vitro system closely mimics the in vivo replication of phi 29 DNA. This system should allow characterization of the phi 29 DNA replication machinery.

Nucleotide sequence of the major early region of bacteriophage phi 29

The nucleotide sequence of the left end of bacteriophage phi 29 DNA has been determined. Together with data reported earlier (Yoshikawa et al., 1981), this sequencing comprises the major early genetic region of this viral genome (5708 bp). Computer analysis of the DNA sequences revealed that there are up to fifteen open reading frames which could encode polypeptides containing more than thirty amino acids. The DNA sequence also revealed a number of potential regulatory signals, promoters and ribosome binding sites. The initiation and the termination of transcription and probable early gene products are discussed.

Morphogenesis of bacteriophage phi 29 of Bacillus subtilis: DNA-gp3 intermediate in in vivo and in vitro assembly

The assembly of phage phi 29 occurs by a single pathway, and DNA-protein (DNA-gp3) has been shown to be an intermediate on the assembly pathway by a highly efficient in vitro complementation. At 30 degrees C, about one-half of the viral DNA synthesized was assembled into mature phage, and the absolute plating efficiency of phi 29 approached unity. DNA packaging at 45 degrees C was comparable to that at 30 degrees C, but the burst size was reduced by one-third. When cells infected with mutant ts3(132) at 30 degrees C to permit DNA synthesis were shifted to 45 degrees C before phage assembly, DNA synthesis ceased and no phage were produced. However, a variable amount of DNA packaging occurred. Superinfection by wild-type phage reinitiated ts3(132) DNA synthesis at 45 degrees C, and if native gp3 was covalently linked to this DNA during superinfection replication, it was effectively packaged and assembled. Treatment of the DNA-gp3 complex with trypsin prevented in vitro maturation of phi 29, although substantial DNA packaging occurred. A functional gp3 linked to the 5' termini of phi 29 DNA is a requirement for effective phage assembly in vivo and in vitro.

Terminal proteins and short inverted terminal repeats of the small Bacillus bacteriophage genomes

The genome of Bacillus phage phi 29 contains covalently linked protein at both ends. These DNA terminal proteins are essential for phi 29 DNA replication. We have isolated phi 29 terminal protein from each end separately and compared their two-dimensional peptide maps. Our results showed the two proteins to be identical. The DNAs of four phages examined (phi 15, Nf, M2Y, and GA-1) also contain protein at both ends of the DNA molecules. The chymotryptic peptide maps of these DNA terminal proteins have been compared with the map of the phi 29 terminal protein. Despite the similarities in molecular size, peptide maps of the terminal proteins show clear differences among the unrelated phages. These results are consistent with the idea that the terminal proteins are encoded by viral DNA rather than by the host chromosome. We have also determined the nucleotide sequences of the termini of four phage DNAs and compared them with the sequence of phi 29 DNA. The sequence data indicate that all of these phages DNA contain short inverted terminal repeats: 5'A-A-A-G-T-A for phi 29 and phi 15, 5' A-A-A-G-T-A-A-G for Nf and M2Y, and 5' A-A-A-T-A-G-A for GA-1.

Nucleotide sequences at the termini of phi 29 DNA

The nucleotide sequences of the first 422 base pairs from the left-hand end and the first 274 base pairs from the right-hand end of phi 29 DNA were determined by using the chemical degradation method of Maxam and Gilbert. The data indicate that phi 29 DNA has inverted terminal repetitions that are six base pairs long 5' (-A-A-A-G-T-A-). No perfectly self-complementary sequence exists within the terminal regions of phi 29 DNA, suggesting that DNA replication via a self-priming mechanism is improbable. The putative early promoter sequences were found in both ends of the phi 29 DNA. The results of the sequence determination are discussed in relation ship to models proposed for the mechanism of replication of linear DNA molecules.

Nucleotide sequence at the termini of the DNA of Bacillus subtilis phage phi 29

Phage phi 29 DNA cannot be phosphorylated with polynucleotide kinase and [gamma-32P]ATP because of the presence of a viral protein covalently linked to the 5' termini. The 5' ends can, however, be made susceptible to phosphorylation by treatment with alkali and alkaline phosphatase. Restriction fragments Hpa II C and Hpa II F, corresponding to the right and left ends of phi 29 DNA, respectively, were labeled at the 5' ends with polynucleotide kinase and [gamma-32P]ATP or at the 3' ends with terminal transferase and [alpha-32P]ATP or [alpha-32P]cordycepin 5'-triphosphate. After a secondary cleavage of the labeled fragments, the sequence of the first 150-180 nucleotides at the termini of phi 29 DNA was determined by the method of Maxam and Gilbert. The ends of phi 29 DNA are flush, and a six-nucleotides-long inverted terminal repetition was found. The functional implications of the sequences determined are discussed.

Identification of the gene and mRNA for the adenovirus terminal protein precursor

The precursor of the 55K adenovirus terminal protein is an 87K protein that is covalently linked to viral DNA. This protein is likely to be identical to the 80,000 dalton protein described by Challberg et al. (1980). The mRNA for the 87K terminal protein precursor, like that for the E2-72K DNA binding protein, is detectable at both early and late times of infection, and its production is sensitive to protein synthesis inhibition (Lewis and Mathews, 1980). The 87K protein, together with proteins of 105,000 and 75,000 daltons, are translated from leftward transcribed (1-strand) messenger RNAs that are complementary to the viral genome between positions 11.2 and 31.5. Additional hybridization to the region between coordinates 37.3 and 41 suggests that the RNA body is spliced to sequences mapping farther right in the genome. Electron microscopic heteroduplex analysis has revealed a family of 1-strand RNAs that probably encode these proteins. The RNA bodies extend from coordinated 30, 26 and 23 to 11.1, with leaders at 39, 68.5 and 75 map units, defining a new adenovirus early region. These RNAs and region E2 RNAs share the first leader and presumably the same promoter, and may be coordinately expressed. Virions of the protease-deficient adenovirus 2 mutant ts1 grown at the restrictive temperature contain only the 87K form; when grown at the permissive temperature they contain both the 87K and 55K forms, and an additional 62K form; wild-type virions contain only the 55K form. Peptide analysis shows all these proteins to be related. The DNA-protein complex containing the 87K form is active as a template for viral DNA replication in vitro. This data supports a model of adenovirus DNA replication in which the 87K terminal protein precursor is the primary translation product and primes DNA synthesis. The 87K precursor is processed curing virus maturation to the 55K terminal protein, possibly via a 62K intermediate form, by the virus-specified Ad2ts1 protease.

Protein p3 is linked to the DNA of phage phi 29 through a phosphoester bond between serine and 5'-dAMP

To investigate the role of protein p3 in bacteriophage phi 29 initiation of replication, we have studied the nature of the covalent linkage between protein p3 and phi 29 DNA. The protein-DNA compound was digested with micrococcal nuclease and pronase resulting in a nucleotidyl-peptide that was further digested by alkaline phosphatase and snake venom phosphodiesterase yielding 5'-dAMP. The DNA-protein linkage is sensitive to alkali. Treatment of the nucleotidyl-peptide with 0.1 M NaOH at 37 degrees C for 3 hr after phosphatase digestion released 5'-dAMP. Hydrolysis of the nucleotidyl-peptide with 5.8 M HCl at 110 degrees C for 90 min yielded O-phosphoserine. These results, together with the sensitivity of the DNA-protein linkage to snake venom phosphodiesterase and its resistance to hydroxylamine, indicate that protein p3 is covalently linked to phi 29 DNA through a phosphoester bond between L-serine and 5'-dAMP, namely a O,5'-deoxyadenylyl-L-serine bond.

Internucleotide protein linkers in Ehrlich ascites cell DNA

DNA from Ehrlich ascites tumor cells is nicked or gapped by a reaction which is induced by proteases such as autodigested pronase, proteinase K, trypsin, chymotrypsin and subtilisin. The cleavage of the protease-sensitive sites is inhibited by protease inhibitors. The nicks or gaps induced by proteases can be demonstrated by nuclease S1 sensitivity of native DNA and by a change of the sedimentation rate of alkali-denatured DNA. The limit size of denatured DNA released after optimal protease treatment is 8.5 x 10(6) daltons (27 kilo bases). The molecular weight of the native DNA pieces released after nuclease S1 degradation of DNA containing the protease-induced nicks or gaps is in the same order indicating that the protease-sensitive sites are alternatively arranged on the opposite DNA strands at an average distance of 13.5 kilo base pairs. Since the protease-induced nicks or gaps in phosphatase-treated DNA are not attacked by Escherichia coli polymerase I, one or both ends liberated by the protease treatment must be blocked by a material other than phosphate groups. The results are most compatible with peptide/protein linkers joining adjacent single-strand DNA subunits. Alternative explanations such as alkali-stable RNA linkers, protein-protected RNA linkers, site-specific nuclease contaminations in the protease preparations or cellular nucleases activated by the protease treatment are eliminated by the results presented in this paper.

Structure of replicating DNA molecules of Bacillus subtilis bacteriophage phi 29

We isolated phi 29 DNA replicative intermediates from extracts of phage-infected Bacillus subtilis, pulsed-labeled with [3H]thymidine, by velocity sedimentation in neutral sucrose followed by CsCl equilibrium density gradient centrifugation. During a chase, the DNA with a higher sedimentation coefficient in neutral sucrose and a lower sedimentation rate in alkaline sucrose than that of viral phi 29 DNA was converted into mature DNA. The material with a density higher than that of mature phi 29 DNA consisted of replicative intermediates, as analyzed with an electron microscope. We found two major types of molecules. One consisted of unit-length duplex DNA with one single-stranded branch at a random position. The length of the single-stranded branches was similar to that of one of the double-stranded regions. The other type of molecules was unit-length DNA with one double-stranded region and one single-stranded region extending a variable distance from one end. Partial denaturation of the latter molecules showed that replication was initiated with a similar frequency from either DNA end. These findings suggest that phi 29 DNA replication occurs by a mechanism of strand displacement and that replication starts non-simultaneously from either DNA end, as in the case of adenovirus.

Adenovirus terminal protein protects single stranded DNA from digestion by a cellular exonuclease

Adenovirus 5 DNA-protein complex is isolated from virions as a duplex DNA molecule covalently attached by the 5' termini of each strand to virion protein of unknown function. The DNA-protein complex can be digested with E. coli exonuclease III to generate molecules analogous to DNA replication intermediates in that they contain long single stranded regions ending in 5' termini bound to terminal protein. The infectivity of pronase digested Adenovirus 5 DNA is greatly diminished by exonuclease III digestion. However, the infectivity of the DNA-protein complex is not significantly altered when up to at least 2400 nucleotides are removed from the 3' ends of each strand. This indicates that the terminal protein protects 5' terminated single stranded regions from digestion by a cellular exonuclease. DNA-protein complex prepared from a host range mutant with a mutation mapping in the left 4% of the genome was digested with exonuclease III, hybridized to a wild type restriction fragment comprising the left 8% of the genome, and transfected into HeLa cells. Virus with wild type phenotype was recovered at high frequency.

Gel electrophoretic separation of transcription complexes: an assay for RNA polymerase selectivity and a method for promoter mapping

We describe a method for analyzing ternary transcription complexes, of RNA polymerase, DNA and nascent RNA32 chains, by agarose gel electrophoresis. When the RNA of such complexes is 32P-labelled, a simple comparison of the DNA fluorogram with an autoradiogram identifies transcriptionally active DNA molecules and restriction fragments in any mixture. Two limitations on the method are described: 1) retardation during electrophoresis of polymerase-DNA complexes relative to their conjugate bare NA fragments; 2) failure of very large ternary complexes to enter gels. The following potential applications of the method are surveyed: transcription unit (elongation) mapping, separation of RNA molecules in a mixture of transcripts, dinucleotide primer mapping and identification of preferred template conformations.

Analysis of the most tightly bound proteins in eukaryotic DNA

DNA isolated by procedures generally considered to be most efficient for purifying DNA still contains detectable peptide components. The characteristics of this material and the stability of its linkage to DNA were investigated: DNA released from [35S]methionine-labelled cells by SDS in the presence of proteases contains a significant amount of 35S label which is not removed by additional treatment with proteases and phenol and which cosediments and cobands together with DNA on alkaline gradients. Furthermore, some peptide material which is copurified with native DNA and which remains complexed with DNA after alkali treatment can be labelled with 125I and analyzed on SDS-polyacrylamide-gels. The amino acid analysis of hydrolysates of purified DNA gives a rough estimate of the amount of the peptide material which is copurified with DNA. The results indicate that distinct proteins between 54 000 and 68 000 daltons in size are not removed from DNA by phenol, proteases, alkali or by any combination of these treatments. They can only be isolated by degradation of DNA. This extreme stability of the DNA-protein linkage indicates that these proteins are not merely contaminants which are difficult to eliminate but are rather covalently or otherwise bound (alkali-stable) to DNA. The size of these proteins and the stability of their linkage to DNA suggests that they are related to the class of non-histone proteins which are thought to be involved in chromatin structure e.g. by keeping DNA in a supercoiled state. Other possible functions are discussed.