Replication of lambda dv plasmid in vitro promoted by purified lambda O and P proteins.

An in vitro system for replication of lambda dv plasmid DNA has been constructed. This system consists of an ammonium sulfate fraction from Escherichia coli extract, exogenously added purified lambda O and P proteins, and lambda dv DNA in closed circular form. More than 85% of the added template DNA replicated semiconservatively. In the same system, another plasmid, pBR322, also replicated, but less efficiently than lambda dv. Furthermore, its replication was independent of O and P proteins. Inhibitors of DNA gyrase entirely blocked the replication activity, whereas rifampicin, an inhibitor of RNA polymerase, showed a significant effect only when added prior to initiation of the DNA replication. DNA replication was initiated from a region near to or within the four direct repeats in lambda origin (lambda ori) and proceeded bidirectionally, as examined by DNA chain elongation termination with dideoxy CTP. A cloned DNA carrying a 350-base-pair region including the initiation site also initiated replication, dependent on O and P proteins, and its initiation occurred at the same position as with native lambda dv DNA. An A + T-rich structure neighboring the repeats was found to be essential for lambda DNA replication. Regions corresponding to ice and oop were not required for O,P-dependent initiation.     

Initiation sites for discontinuous DNA synthesis of bacteriophage T7

We have previously shown that the discontinuous replication of bacteriophage T7 DNA is primed by tetraribonucleotides (major component) or pentaribonucleotides. Both tetramers and pentamers start with pppA-C and are rich in A and C at the third and fourth nucleotides. In this study, the sites of transition from primer RNA to DNA in vivo have been located on a 340-nucleotide segment of the H strand of the T7 genome by 32P-labeling in vitro of the 5'-hydroxyl ends of DNA resulting from alkaline hydrolysis of RNA-linked T7 DNA fragments. Five strong transition sites were detected with a common sequence 5'-G-A-C-N1-N2-N3-N4-3', in which N1 was either C or A, N2 ws A, C, or G, and either N3 or N4 was the nucleotide for the switchover to DNA synthesis. We conclude that the complementary sequence 3'-C-T-G-G/T-N'2-(N'3)-5' in the template strand is the most frequently used signal for synthesis of primer RNA. Whereas primer-RNA synthesis starts at a precisely defined nucleotide, the transition to DNA synthesis varies within two nucleotides. Because the observed signal sequence would be present on a statistical basis once per 128 nucleotides, only about 10% of the existing signals are used for primer synthesis in each round of replication so that nascent fragments 1000-2000 long result. This provides an unexpected flexibility for RNA priming of DNA synthesis.     

Initiation of bacteriophage lambda DNA replication in vitro with purified lambda replication proteins.

We have developed a soluble enzyme system that replicates exogenously added plasmid DNA (lambda dv) bearing the replication origin of the bacteriophage lambda chromosome. The system contains pure phage lambda O and P replication proteins and a partially purified mixture of Escherichia coli replication proteins [the enzyme system of Fuller, R.S., Kaguni, J.M. & Kornberg, A. (1981) Proc. Natl. Acad. Sci. USA 78, 7370-7374). The features of lambda dv replication in this system closely resemble the known characteristics of phage lambda DNA replication in vivo. The system (i) depends completely on exogenously supplied DNA, (ii) specifically replicates supercoiled plasmid DNA that contains a lambda replication origin, (iii) depends on both the lambda O protein and the lambda P protein, (iv) depends on RNA polymerase, (v) depends on host replication proteins (e.g., primase, dnaB protein, and several others that function in the priming of DNA synthesis in E. coli) as judged by antibody inhibitions, and (vi) replicates as much as 32% of added lambda dv plasmid DNA through a single complete round to generate catenated daughter molecules. Furthermore, replication of lambda dv DNA in vitro requires DNA gyrase and an ATP-regenerating system. It is notable that addition of lambda O and P proteins to the mixture of E. coli replication proteins inhibits replication of plasmids bearing the origin of the E. coli chromosome. Exploitation of this enzyme system should allow a detailed investigation of the biochemical mechanisms involved in bacteriophage lambda DNA replication and its regulation.     

Specialized nucleoprotein structures at the origin of replication of bacteriophage lambda: localized unwinding of duplex DNA by a six-protein reaction.

The O protein of bacteriophage lambda localizes the initiation of DNA replication to a unique site on the lambda genome, ori lambda. By means of electron microscopy, we infer that the binding of O to ori lambda initiates a series of protein addition and transfer reactions that culminate in localized unwinding of the origin DNA, generating a prepriming structure for the initiation of DNA replication. We can define three stages of this prepriming reaction, the first two of which we have characterized previously. First, dimeric O protein binds to multiple DNA binding sites and self-associates to form a nucleoprotein structure, the O-some. Second, lambda P and host DnaB proteins interact with the O-some to generate a larger complex that includes additional DNA from an A + T-rich region adjacent to the O binding sites. Third, the addition of the DnaJ, DnaK, and Ssb proteins and ATP results in an origin-specific unwinding reaction, probably catalyzed by the helicase activity of DnaB. The unwinding reaction is unidirectional, proceeding "rightward" from the origin. The minimal DNA sequence competent for unwinding consists of two O binding sites and the adjacent A + T-rich region to the right of the binding sites. We conclude that the lambda O protein localizes and initiates a six-protein sequential reaction responsible for but preceding the precise initiation of DNA replication. Specialized nucleoprotein structures similar to the O-some may be a general feature of DNA transactions requiring extraordinary precision in localization and control.     

Template recognition sequence for RNA primer synthesis by gene 4 protein of bacteriophage T7

The gene 4 protein of bacteriophage T7 recognizes specific sequences on single-stranded DNA and then catalyzes the synthesis of tetraribonucleotide primers complementary to the template. With phi X174 DNA as a template, the gene 4 protein enables T7 DNA polymerase (deoxynucleosidetriphosphate:DNA deoxynucleotidyltransferase, EC 2.7.7.7) to initiate DNA synthesis at 13 major sites. DNA sequence analysis of the 5' termini of the newly synthesized DNA shows the predominant recognition sequences for the gene 4 protein to be 3'-C-T-G-G-G-5' or 3'-C-T-G-G-T-5'; the products of synthesis at these sites are RNA primers having the sequences pppA-C-C-C or pppA-C-C-A. The gene 4 protein can also synthesize primers at the sequences 3'-C-T-G-G-AC-5' and 3'-C-T-G-T-N-5', although these sites are used less than 10% as frequently as the predominant sites. Comparison of the utilization of primer sites suggests that the gene 4 protein binds randomly to single-stranded DNA and then translocates along the DNA in a unidirectional 5'-to-3' direction with regard to the DNA strand in search of recognition sequences. Models are presented for the role of the gene 4 protein in the initiation of lagging-strand synthesis and in the initiation of DNA replication at the origin.     

Origin of replication of colicin E1 plasmid DNA.

Cleavage maps of colicin E1 plasmid DNA and its smaller derivative, pNT1 DNA, were constructed by using restriction endonucleases. The nucleotide sequence of a region that contains the orgin of replication was determined. The site of the nucleotide from which DNA replication is initiated was determined with 6S L-fragments, the DNA fragment first made on colicin E1 plasmid DNA. The fragments were labeled with [gamma-32P]ATP and polynucleotide 5'-hydroxyl-kinase (ATP:5'-dephosphopolynucleotide 5'-phosphotransferase, EC 2.7.1.78) at the 5'-OH groups which were uncovered by alkali treatment. The site is one of three consecutive nucleotides, dA, dA, and dC, located at a unique position. One or a few rA residues were found to be attached to some of the DNA molecules. The transition from the primer RNA to DNA occurs in a region consisting of a segment of five A residues. Both sides of this segment are rich in G and C.     

Specialized nucleoprotein structures at the origin of replication of bacteriophage lambda: complexes with lambda O protein and with lambda O, lambda P, and Escherichia coli DnaB proteins.

The O protein of bacteriophage lambda is required for initiation of DNA replication at the lambda replicative origin designated ori lambda. The binding sites for O protein are four direct repeats, each of which is an inverted repeat. By means of electron microscopy, we have found that phage lambda O protein utilizes these multiple binding sites to form a specific nucleoprotein structure in which the origin DNA is inferred to be folded or wound. The phage lambda O and P proteins and host DnaB protein interact at ori lambda to generate a larger structure than that formed by O protein alone; P and DnaB proteins fail to form any observable complex when O protein is excluded from the reaction mixture. We conclude that the specialized nucleoprotein structure formed by phage lambda O protein and ori lambda provides for localized initiation of DNA replication by serving as the foundation for the assembly of the initial priming structure. Specialized nucleoprotein structures may be a general means to confer exceptional accuracy on DNA transactions requiring extraordinary precision.     

Tn5supF, a 264-base-pair transposon derived from Tn5 for insertion mutagenesis and sequencing DNAs cloned in phage lambda.

We constructed a derivative of transposon Tn5 called Tn5supF for insertion mutagenesis and sequencing DNAs cloned in phage lambda. This element carries a supF amber-suppressor tRNA gene. Its insertion into lambda can be selected by plaque formation by using nonsuppressing (sup0) Escherichia coli for amber mutant lambda phage and sup0 dnaB-amber E. coli for nonamber lambda phage. Tn5supF is just 264 base pairs long. It transposes efficiently and inserts quasi-randomly into DNA targets. The unique sequences near its termini can be used as primer binding sites for dideoxynucleotide DNA sequencing, thus permitting the direct sequencing of DNAs cloned in phage lambda without subcloning.     

Telomerase recognizes its template by using an adjacent RNA motif

Telomerase adds telomeric repeats to chromosome 3' ends, forestalling the cellular senescence, apoptosis, and genomic instability that result from telomere loss caused by incomplete DNA replication. The telomerase ribonucleoprotein is dedicated to synthesis of tandem, simple-sequence repeats by virtue of its specialization for copying only a specific template region within the integral RNA. Here, using circularly permuted variants of Tetrahymena thermophila telomerase RNA, we identify the features that allow recognition of the template region within the RNA. We engineered a template-less telomerase ribonucleoprotein that can position and reverse transcribe an exchangeable RNA oligonucleotide template accurately. Only a short "template-recognition" element sequence tag is required to direct efficient use of adjacent 5' residues as a template for telomeric repeat synthesis. Our findings reveal molecular requirements for template selection by telomerase and physically resolve templating from other RNA functions in catalysis.