Nucleotide sequence from the genetic left end of bacteriophage T7 DNA to the beginning of gene 4

The nucleotide sequence running from the genetic left end of bacteriophage T7 DNA to within the coding sequence of gene 4 is given, except for the internal coding sequence for the gene 1 protein, which has been determined elsewhere. The sequence presented contains nucleotides 1 to 3342 and 5654 to 12,100 of the approximately 40,000 base-pairs of T7 DNA. This sequence includes: the three strong early promoters and the termination site for Escherichia coli RNA polymerase: eight promoter sites for T7 RNA polymerase; six RNAase III cleavage sites; the primary origin of replication of T7 DNA; the complete coding sequences for 13 previously known T7 proteins, including the anti-restriction protein, protein kinase, DNA ligase, the gene 2 inhibitor of E. coli RNA polymerase, single-strand DNA binding protein, the gene 3 endonuclease, and lysozyme (which is actually an N-acetylmuramyl-l-alanine amidase); the complete coding sequences for eight potential new T7-coded proteins; and two apparently independent initiation sites that produce overlapping polypeptide chains of gene 4 primase. More than 86% of the first 12,100 base-pairs of T7 DNA appear to be devoted to specifying amino acid sequences for T7 proteins, and the arrangement of coding sequences and other genetic elements is very efficient. There is little overlap between coding sequences for different proteins, but junctions between adjacent coding sequences are typically close, the termination codon for one protein often overlapping the initiation codon for the next. For almost half of the potential T7 proteins, the sequence in the messenger RNA that can interact with 16 S ribosomal RNA in initiation of protein synthesis is part of the coding sequence for the preceding protein. The longest non-coding region, about 900 base-pairs, is at the left end of the DNA. The right half of this region contains the strong early promoters for E. coli RNA polymerase and the first RNAase III cleavage site. The left end contains the terminal repetition (nucleotides 1 to 160), followed by a striking array of repeated sequences (nucleotides 175 to 340) that might have some role in packaging the DNA into phage particles, and an A · T-rich region (nucleotides 356 to 492) that contains a promoter for T7 RNA polymerase, and which might function as a replication origin.     

Interference between M13 and oriM13 plasmids is mediated by a replication enhancer sequence near the viral strand origin

The origin of replication for the viral strand of bacteriophage M13 DNA is contained within a 507 base-pair intergenic region of the phage chromosome. The viral strand origin is defined as the specific site at which the M13 gene II protein nicks the duplex replicative form of M13 DNA to initiate rolling-circle synthesis of progeny viral DNA. Using in vitro techniques we have constructed deletion mutations in M13 DNA at the unique AvaI site which is located 45 nucleotides away on the 3' side of the gene II protein nicking site. This deletion analysis has identified a sequence near the viral strand origin that is required for efficient replication of the M13 genome. We refer to this part of the intergenic region as a "replication enhancer" sequence. We have also studied the function of this sequence in chimeric pBR322-M13 plasmids and found that plasmids carrying both the viral strand origin and the replication enhancer sequence interfere with M13 phage replication. Based upon these findings we propose a model for the mechanism of action of the replication enhancer sequence involving binding of the M13 gene II protein.     

Binding of an analog of the simian virus 40 T antigen to wild-type and mutant viral replication origins

DNAase footprint analyses of purified AD2 + D2 (D2) T protein binding to simian virus 40 origin region fragments revealed a series of four specific interactions with contiguous sequences constituting a 120 base-pair block, in keeping with previous DNAase protection results reported by others. Protection was observed to extend from a 30 base-pair strong affinity site located on the early side of the replication origin (site 1) to two adjacent lower affinity sites, including the origin of replication (site 2) and a 11 to 13 base-pair site between site 1 and the beginning of the T/t coding sequence (site 1′). A fourth site (site 3) was noted abutting the late border of site 2. Binding to site 1 was associated with enhanced D2T binding to sites 2 and 1′. Thus, binding to these sites is co-operative and/or the sequences which constitute site 1 affect the conformation of the sites 1′ and 2 sequences such that they now serve as sites of more efficient D2T binding. In addition, while deletion of all of site 2 and its substitution by late viral sequences ablated processive T binding to sequences abutting site 1 on its late side, various site 2 deletions comprising up to approximately 40% of that sequence did not affect binding to that site to a major degree. Therefore, binding to the replication origin is a sequence-specific event, but there may be multiple strong protein contact sites within that sequence.     

DNAs of two molecularly cloned endogenous ecotropic proviruses are poorly infectious in DNA transfection assays

We have isolated a series of point mutants in the polyomavirus origin-intergenic control region by using a procedure which exploits the single-stranded nature of DNAs cloned into M13 phage both for the generation of mutants and for their analysis by DNA sequencing. In this report we describe the effects of cytosine X guanine----thymine X adenine base-pair substitutions in the polyomavirus origin region upon replication in mouse 3T6 cells of the M13-polyomavirus constructs. Our results indicate that sequences near the center of a 34-base-pair sequence with dyad symmetry are important for replication, whereas specific nucleotides near the ends of the dyad symmetry are not important. Furthermore, a putative large T antigen-binding site at nucleotides 60 to 80 can be mutated without affecting replication function as measured in this assay.     

Unusual occurrence of EcoP1 and EcoP15 recognition sites and counterselection of type II methylation and restriction sequences in bacteriophage T7 DNA

Selected and counterselected oligodeoxynucleotide sequences were identified in the total sequence of bacteriophage T7 DNA using a statistical criterion derived for a probability model of the Markov chain type. All extremely rare tetra- and pentadeoxynucleotides are (or contain) recognition sequences for the Escherichia coli DNA methylases dam or dcm. Most of the 37 hexadeoxynucleotides absent from T7 DNA are recognition sequences for type II modification/restriction enzymes of E. coli or related species. In contrast to most restriction sites counterselected during evolution, the EcoP1 site GGTCT occurs 126 times in the T7 genome, and phage T7 replication is severely repressed in P1-lysogenic host cells. We demonstrate that the frequency of the EcoP1 site is determined by that of the overlapping recognition sites for T7 primase, an essential phage enzyme. The recognition site of a type III enzyme, EcoP15, is also not counterselected. In T7 DNA all 36 EcoP15 sites are arranged in such a manner that the sequence CAGCAG is confined to the H strand, the complementary sequence CTGCTG to the L strand. This "strand bias" is highly significant and, therefore, very probably selected. A functional relation between this strand bias and the refractive behaviour of phage T7 to EcoP15 restriction is suspected.     

Recognition sites of eukaryotic DNA topoisomerase I: DNA nucleotide sequencing analysis of topo I cleavage sites on SV40 DNA.

Eukaryotic DNA topoisomerase I introduces transient single-stranded breaks on double-stranded DNA and spontaneously breaks down single-stranded DNA. The cleavage sites on both single and double-stranded SV40 DNA have been determined by DNA sequencing. Consistent with other reports, the eukaryotic enzymes, in contrast to prokaryotic type I topoisomerases, links to the 3'-end of the cleaved DNA and generates a free 5'-hydroxyl end on the other half of the broken DNA strand. Both human and calf enzymes cleave SV40 DNA at the identical and specific sites. From 827 nucleotides sequenced, 68 cleavage sites were mapped. The majority of the cleavage sites were present on both double and single-stranded DNA at exactly the same nucleotide positions, suggesting that the DNA sequence is essential for enzyme recognition. By analyzing all the cleavage sequences, certain nucleotides are found to be less favored at the cleavage sites. There is a high probability to exclude G from positions -4, -2, -1 and +1, T from position -3, and A from position -1. These five positions (-4 to +1 oriented in the 5' to 3' direction) around the cleavage sites must interact intimately with topo I and thus are essential for enzyme recognition. One topo I cleavage site which shows atypical cleavage sequence maps in the middle of a palindromic sequence near the origin of SV40 DNA replication. It occurs only on single-stranded SV40 DNA, suggesting that the DNA hairpin can alter the cleavage specificity. The strongest cleavage site maps near the origin of SV40 DNA replication at nucleotide 31-32 and has a pentanucleotide sequence of 5'-TGACT-3'.     

The nuclease specificity of the bacteriophage phi X174 A* protein.

The A* protein of bacteriophage phi X174 is a single-stranded DNA specific nuclease. It can cleave phi X viral ss DNA in many different places. The position of these sites have been determined within the known phi X174 nucleotide sequence (1). From the sequences at these sites it is clear that the A* protein recognizes and cleaves at sites that show only partial homology with the origin of RF DNA replication in the phi X DNA. Different parts of the origin sequence can be deduced that function as a signal for recognition and cleavage by the A* protein. We conclude that different parts within the DNA recognition domain of the A* protein are functional in the recognition of the origin sequence in single-stranded DNA. The existence of different DNA recognition domains in the A* protein, and therefore also in the A protein, leads to a model that can explain how the A protein performs its multiple function in the phi X174 DNA replication process (2).     

Discriminatory function of ribonuclease H in the selective initiation of plasmid DNA replication.

The initiation stage of ColE1-type plasmid replication was reconstituted with purified protein fractions from Escherichia coli. The reconstituted system included DNA polymerase I, DNA ligase, RNA polymerase, DNA gyrase, and a discriminating activity copurifying with RNAase H (but free of RNAase III). Initiation of DNA synthesis in the absence of RNAase H did not occur at the normal replication origin and was non-selective with respect to the plasmid template. In the presence of RNAase H the system was selective for ColE1-type plasmids and could not accept the DNA of non-amplifiable plasmids. Electron microscopic analysis of the reaction product formed under discriminatory conditions indicated that origin usage and directionally of ColE1, RSF1030, and CloDF13 replication were consistent with the normal replication pattern of these plasmids. It is proposed that the initiation of ColE1-type replication depends on the formation of an extensive secondary structure in the origin primer RNA that prevents its degradation by RNAase H.     

Sequence from early region of polyoma virus DNA containing viral replication origin and encoding small, middle and (part of) large T antigens.

The sequence of about one third of the polyoma virus genome is presented. This sequence covers the origin of replication of two large plaque strains (A2 and A3) of polyoma virus. The two strains differ by 11 bp in the origin region. A model for replication is suggested. The sequence probably also covers the entire coding region of two of the polyoma virus early proteins--small and middle T antigens--as well as part of the coding region for large T antigen. Over a small region of the DNA, all three coding frames contain termination codons, which argues a need for spliced early messenger RNAs. In another region of the DNA, two coding frames can be used. Correlation with protein data suggests that one frame codes for part of middle T antigen and the other for part of large T antigen.     

Phage phi29 terminal protein residues Asn80 and Tyr82 are recognition elements of the replication origins.

Initiation of phage phi29 DNA replication starts with the recognition of the origin of replication, located at both ends of the linear DNA, by a heterodimer formed by the phi29 terminal protein (TP) and the phi29 DNA polymerase. The parental TP, covalently linked to the DNA ends, is one of the main components of the replication origin. Here we provide evidence that recognition of the origin is mediated through interactions between the TP of the TP/DNA polymerase heterodimer, called primer TP, and the parental TP. Based on amino acid sequence comparisons, various phi29 TP mutants were generated at conserved amino acid residues from positions 61 to 87. In vitro phi29 DNA amplification analysis revealed that residues Asn80 and Tyr82 are essential for functional interaction between primer and parental TP required for recognition of the origin of replication. Although these mutant TPs can form functional heterodimers with phi29 DNA polymerase that are able to recognize the origin of replication, these heterodimers are not able to recognize an origin containing a mutant TP.     

Chromosomal ARS1 has a single leading strand start site

Initiation sites for DNA synthesis in the chromosomal autonomously replicating sequence (ARS)1 of Saccharomyces cerevisiae were detected at the nucleotide level. The transition from discontinuous to continuous synthesis defines the origin of bidirectional replication (OBR), which mapped adjacent to the origin recognition complex binding site. To ascertain which sites represented starts for leading or lagging strands, we characterized DNA replication from ARS1 in a cdc9 (DNA ligase I) mutant, defective for joining Okazaki fragments. Leading strand synthesis in ARS1 initiated at only a single site, the OBR. Thus, replication in S. cerevisiae is not initiated stochastically by choosing one out of multiple possible sites but, rather, is a highly regulated process with one precise start point.     

Deletion analysis of the DNA sequence required for the in vitro initiation of replication of bacteriophage lambda

Supercoiled DNA containing the replication origin of bacteriophage lambda can be replicated in vitro. This reaction requires purified lambda O and P replication proteins and a partially purified mixture of Escherichia coli proteins (Tsurimoto, T., and Matsubara, K. (1982) Proc. Natl. Acad. Sci. U.S.A. 79, 7639-7643; Wold, M. S., Mallory, J.B., Roberts, J. D., LeBowitz, J. H., and McMacken, R. (1982) Proc. Natl. Acad. Sci. U.S.A. 79, 6176-6180). The lambda origin region has four repeats of a 19-base pair sequence to which O protein binds. To the right of these sites on the lambda map is a 40-base pair region that is rich in adenine and thymine, followed by a 28-base pair palindromic sequence. To define more precisely the boundaries of the lambda origin, we cloned a 358-base pair piece of lambda DNA containing the origin region into M13mp8 in both orientations. In vitro replication of RF I DNAs prepared from cells infected with these two M13 ori lambda phage was dependent on lambda O and P proteins and a crude protein fraction from uninfected E. coli; with these conditions there was no replication of M13mp8 RF I DNA. We made deletions from the left and the right ends of the lambda origin DNA and determined the deletion end points by DNA sequencing. We have tested RF I DNAs prepared from cells infected with phage carrying ori lambda deletions for their ability to function as templates for O- and P-dependent replication in vitro. Our results show that lambda DNA between nucleotide positions 39072 and 39160 is required for efficient O- and P-dependent replication. This 89-base pair piece of DNA includes only two of the four 19-base pair O protein-binding sites (the two right-most) and the adjoining adenine- and thymine-rich region to the right of the O-binding sites.     

Bacteriophage T7 DNA packaging. III. A "hairpin" end formed on T7 concatemers may be an intermediate in the processing reaction

An unusual left end (M-end) has been identified on bacteriophage T7 DNA isolated from T7-infected cells. This end has a "hairpin" structure and is formed at a short inverted repeat sequence centered around nucleotide 39,587 of T7, 190 base-pairs to the left of the site where a mature left end is formed on the T7 concatemer. We do not detect the companion right end that would be formed if the M-end is produced by a double-stranded cut on the T7 concatemer. This suggests that the hairpin left end may be generated from a single-stranded cut in the DNA that is used to prime rightward DNA synthesis. The formation of M-end does not require the products of T7 genes 10, 18 or 19, proteins that are essential for the formation of mature T7 ends. During infection with a T7 gene 3 (endonuclease) mutant, phage DNA synthesis is reduced and the concatemers are not processed into unit length DNA molecules, but both M-end and the mature right end are formed on the concatemer DNA. These two ends are also found associated with the large, rapidly sedimenting concatemers formed during a normal T7 infection while the mature left end is present only on unit length T7 DNA molecules. We propose that DNA replication primed from the hairpin end produced by a nick in the inverted repeat sequence provides a mechanism to duplicate the terminal repeat before DNA packaging. Packaging is initiated with the formation of a mature right end on the branched concatemer and, as the phage head is filled, the T7 gene 3 endonuclease may be required to trim the replication forks from the DNA. Concatemer processing is completed by the removal of the 190 base-pair hairpin end to produce the mature left end.     

The bacteriophage T4 insertion/substitution vector system. A method for introducing site-specific mutations into the virus chromosome

A bacteriophage T4 insertion/substitution vector system has been developed as a means of introducing in vitro generated mutations into the T4 chromosome. The insertion/substitution vector is a 2638-base pair plasmid containing the pBR322 origin of replication and ampicillin resistance determinant, a T4 gene 23 promoter/synthetic supF tRNA gene fusion, and a polylinker with eight unique restriction enzyme recognition sites. A T4 chromosomal "target" DNA sequence is cloned into this vector and mutated by standard recombinant DNA techniques. Escherichia coli cells containing this plasmid are then infected with T4 bacteriophage that carry amber mutations in two essential genes. The plasmid integrates into the T4 chromosome by recombination between the plasmid-borne T4 target sequence and its homologous chromosomal counterpart. The resulting phage, termed "integrants," are selectable by the supF-mediated suppression of their two amber mutations. Thus, although the integrants comprise 1-3% or less of the total phage progeny, growth on a nonsuppressing host permits their direct selection. The pure integrant phage can be either analyzed directly for a possible mutant phenotype or transferred to nonselective growth conditions. In the latter case, plasmid-free phage segregants rapidly accumulate due to homologous recombination between the duplicated target sequences surrounding the supF sequence in each integrant chromosome. A major fraction of these segregants will retain the in vitro generated mutation within their otherwise unchanged chromosomes and are isolated as stable mutant bacteriophage. The insertion/substitution vector system thereby allows any in vitro mutated gene to be readily substituted for its wild-type counterpart in the bacteriophage T4 genome.     

Plasmid R6K DNA replication: I. Complete nucleotide sequence of an autonomously replicating segment

A 1565-base segment of the antibiotic resistance plasmid R6K carries sufficient information to replicate as a plasmid in Escherichia coli. This segment contains a functional origin of replication and the structural gene pir for a protein, designated π, that is required for the initiation of R6K DNA replication. The nucleotide sequence of this 1565 base-pair replicon was determined. From the sequence and the analysis of proteins produced by minicells of E. coli strains carrying the wild-type pir gene and a deletion of the pir gene, it can be concluded that the π structural gene encodes for a protein of a molecular weight of approximately 35,000.On the basis of the nucleotide sequence, the π protein is the only protein containing more than 50 amino acid residues that is encoded by this 1583 base-pair replicon. The nucleotide sequence also contains eight 22 base-pair direct repeats. Seven of the direct repeats are in tandem and located in the origin region, while the eighth repeat is near or part of the promoter for the π structural gene. This eighth repeat may play a role in the autoregulated expression of the π structural gene.