Four-color DNA sequencing with 3'-O-modified nucleotide reversible terminators and chemically cleavable fluorescent dideoxynucleotides

DNA sequencing by synthesis (SBS) on a solid surface during polymerase reaction can decipher many sequences in parallel. We report here a DNA sequencing method that is a hybrid between the Sanger dideoxynucleotide terminating reaction and SBS. In this approach, four nucleotides, modified as reversible terminators by capping the 3'-OH with a small reversible moiety so that they are still recognized by DNA polymerase as substrates, are combined with four cleavable fluorescent dideoxynucleotides to perform SBS. The ratio of the two sets of nucleotides is adjusted as the extension cycles proceed. Sequences are determined by the unique fluorescence emission of each fluorophore on the DNA products terminated by ddNTPs. On removing the 3'-OH capping group from the DNA products generated by incorporating the 3'-O-modified dNTPs and the fluorophore from the DNA products terminated with the ddNTPs, the polymerase reaction reinitiates to continue the sequence determination. By using an azidomethyl group as a chemically reversible capping moiety in the 3'-O-modified dNTPs, and an azido-based cleavable linker to attach the fluorophores to the ddNTPs, we synthesized four 3'-O-azidomethyl-dNTPs and four ddNTP-azidolinker-fluorophores for the hybrid SBS. After sequence determination by fluorescence imaging, the 3'-O-azidomethyl group and the fluorophore attached to the DNA extension product via the azidolinker are efficiently removed by using Tris(2-carboxyethyl)phosphine in aqueous solution that is compatible with DNA. Various DNA templates, including those with homopolymer regions, were accurately sequenced with a read length of >30 bases by using this hybrid SBS method on a chip and a four-color fluorescence scanner.     

Design and synthesis of a 3'-O-allyl photocleavable fluorescent nucleotide as a reversible terminator for DNA sequencing by synthesis

DNA sequencing by synthesis (SBS) offers an approach for potential high-throughput sequencing applications. In this method, the ability of an incoming nucleotide to act as a reversible terminator for a DNA polymerase reaction is an important requirement to unambiguously determine the identity of the incorporated nucleotide before the next nucleotide is added. A free 3'-OH group on the terminal nucleotide of the primer is necessary for the DNA polymerase to incorporate an incoming nucleotide. Therefore, if the 3'-OH group of an incoming nucleotide is capped by a chemical moiety, it will cause the polymerase reaction to terminate after the nucleotide is incorporated into the DNA strand. If the capping group is subsequently removed to generate a free 3'-OH, the polymerase reaction will reinitialize. We report here the design and synthesis of a 3'-modified photocleavable fluorescent nucleotide, 3'-O-allyl-dUTP-PC-Bodipy-FL-510 (PC-Bodipy, photocleavable 4,4-difluoro-4-bora-3alpha,4alpha-diaza-s-indacene), as a reversible terminator for SBS. This nucleotide analogue contains an allyl moiety capping the 3'-OH group and a fluorophore Bodipy-FL-510 linked to the 5 position of the uracil through a photocleavable 2-nitrobenzyl linker. Here, we have shown that this nucleotide is a good substrate for a DNA polymerase. After the nucleotide was successfully incorporated into a growing DNA strand and the fluorophore was photocleaved, the allyl group was removed by using a Pd-catalyzed reaction to reinitiate the polymerase reaction, thereby establishing the feasibility of using such nucleotide analogues as reversible terminators for SBS.     

3'-O-modified nucleotides as reversible terminators for pyrosequencing

Pyrosequencing is a method used to sequence DNA by detecting the pyrophosphate (PPi) group that is generated when a nucleotide is incorporated into the growing DNA strand in polymerase reaction. However, this method has an inherent difficulty in accurately deciphering the homopolymeric regions of the DNA templates. We report here the development of a method to solve this problem by using nucleotide reversible terminators. These nucleotide analogues are modified with a reversible chemical moiety capping the 3'-OH group to temporarily terminate the polymerase reaction. In this way, only one nucleotide is incorporated into the growing DNA strand even in homopolymeric regions. After detection of the PPi for sequence determination, the 3'-OH of the primer extension products is regenerated through different deprotection methods. Using an allyl or a 2-nitrobenzyl group as the reversible moiety to cap the 3'-OH of the four nucleotides, we have synthesized two sets of 3'-O-modified nucleotides, 3'-O-allyl-dNTPs and 3'-O-(2-nitrobenzyl)-dNTPs as reversible terminators for pyrosequencing. The capping moiety on the 3'-OH of the DNA extension product is efficiently removed after PPi detection by either a chemical method or photolysis. To sequence DNA, templates containing homopolymeric regions are immobilized on Sepharose beads, and then extension-signal detection-deprotection cycles are conducted by using the nucleotide reversible terminators on the DNA beads to unambiguously decipher the sequence of DNA templates. Our results establish that this reversible-terminator-pyrosequencing approach can be potentially developed into a powerful methodology to accurately determine DNA sequences.     

Four-color DNA sequencing by synthesis on a chip using photocleavable fluorescent nucleotides

We report four-color DNA sequencing by synthesis (SBS) on a chip, using four photocleavable fluorescent nucleotide analogues (dGTP-PC-Bodipy-FL-510, dUTP-PC-R6G, dATP-PC-ROX, and dCTP-PC-Bodipy-650) (PC, photocleavable; Bodipy, 4,4-difluoro-4-bora-3alpha,4alpha-diaza-s-indacene; ROX, 6-carboxy-X-rhodamine; R6G, 6-carboxyrhodamine-6G). Each nucleotide analogue consists of a different fluorophore attached to the 5 position of the pyrimidines and the 7 position of the purines through a photocleavable 2-nitrobenzyl linker. After verifying that these nucleotides could be successfully incorporated into a growing DNA strand in a solution-phase polymerase reaction and the fluorophore could be cleaved using laser irradiation ( approximately 355 nm) in 10 sec, we then performed an SBS reaction on a chip that contains a self-priming DNA template covalently immobilized by using 1,3-dipolar azide-alkyne cycloaddition. The DNA template was produced by PCR, using an azido-labeled primer, and the self-priming moiety was attached to the immobilized DNA template by enzymatic ligation. Each cycle of SBS consists of the incorporation of the photocleavable fluorescent nucleotide into the DNA, detection of the fluorescent signal, and photocleavage of the fluorophore. The entire process was repeated to identify 12 continuous bases in the DNA template. These results demonstrate that photocleavable fluorescent nucleotide analogues can be incorporated accurately into a growing DNA strand during a polymerase reaction in solution and on a chip. Moreover, all four fluorophores can be detected and then efficiently cleaved using near-UV irradiation, thereby allowing continuous identification of the DNA template sequence. Optimization of the steps involved in this SBS approach will further increase the read-length.     

Photocleavable fluorescent nucleotides for DNA sequencing on a chip constructed by site-specific coupling chemistry

DNA sequencing by synthesis on a solid surface offers new paradigms to overcome limitations of electrophoresis-based sequencing methods. Here we report DNA sequencing by synthesis using photocleavable (PC) fluorescent nucleotides [dUTP-PC-4,4-difluoro-4-bora-3 alpha,4 alpha-diaza-s-indacene (Bodipy)-FL-510, dCTP-PC-Bodipy-650, and dUTP-PC-6-carboxy-X-rhodamine (ROX)] on a glass chip constructed by 1,3-dipolar azide-alkyne cycloaddition coupling chemistry. Each nucleotide analogue consists of a different fluorophore attached to the base through a PC 2-nitrobenzyl linker. We constructed a DNA microarray by using the 1,3-dipolar cycloaddition chemistry to site-specifically attach azido-modified DNA onto an alkyne-functionalized glass chip at room temperature under aqueous conditions. After verifying that the polymerase reaction could be carried out successfully on the above-described DNA array, we then performed a sequencing reaction on the chip by using a self-primed DNA template. In the first step, we extended the primer using DNA polymerase and dUTP-PC-Bodipy-FL-510, detected the fluorescent signal from the fluorophore Bodipy-FL-510, and then cleaved the fluorophore using 340 nm UV irradiation. This process was followed by extension of the primer with dCTP-PC-Bodipy-650 and the subsequent detection of the fluorescent signal from Bodipy-650 and its photocleavage. The same procedure was also performed by using dUTP-PC-ROX. The entire process was repeated five times by using the three fluorescent nucleotides to identify 7 bases in the DNA template. These results demonstrate that the PC nucleotide analogues can be incorporated accurately into a growing DNA strand during polymerase reaction on a chip, and the fluorophore can be detected and then efficiently cleaved using near-UV irradiation, thereby allowing the continuous identification of the template sequence.     

A photocleavable fluorescent nucleotide for DNA sequencing and analysis

DNA sequencing by synthesis during a polymerase reaction using laser-induced fluorescence detection is an approach that has a great potential to increase the throughput and data quality of DNA sequencing. We report the design and synthesis of a photocleavable fluorescent nucleoside triphosphate, one of the essential molecules required for the sequencing-by-synthesis approach. We synthesized this nucleoside triphosphate by attaching a fluorophore, 4,4-difluoro-5,7-dimethyl-4-bora-3alpha,4alpha-diaza-s-indacene propionic acid (BODIPY), to the 5 position of 2'-deoxyuridine triphosphate via a photocleavable 2-nitrobenzyl linker. We demonstrate that the nucleotide analogue can be faithfully incorporated by a DNA polymerase Thermo Sequenase into the growing DNA strand in a DNA-sequencing reaction and that its incorporation does not hinder the addition of the subsequent nucleotide. These results indicate that the nucleotide analogue is an excellent substrate for Thermo Sequenase. We also systematically studied the photocleavage of the fluorescent dye from a DNA molecule that contained the nucleotide analogue. UV irradiation at 340 nm of the DNA molecule led to the efficient release of the fluorescent dye, ensuring that a previous fluorescence signal did not leave any residue that could interfere with the detection of the next nucleotide. Thus, our results indicate that it should be feasible to use four different fluorescent dyes with distinct fluorescence emissions as unique tags to label the four nucleotides (A, C, G, and T) through the photocleavable 2-nitrobenzyl linker. These fluorescent tags can be removed easily by photocleavage after the identification of each nucleotide in the DNA sequencing-by-synthesis approach.     

DNA sequence analysis with a modified bacteriophage T7 DNA polymerase.

A chemically modified phage T7 DNA polymerase has three properties that make it ideal for DNA sequencing by the chain-termination method. The enzyme is highly processive, catalyzing the polymerization of thousands of nucleotides without dissociating. By virtue of the modification the 3' to 5' exonuclease activity is eliminated. The modified polymerase efficiently uses nucleotide analogs that increase the electrophoretic resolution of bands in gels. Consequently, dideoxynucleotide-terminated fragments have highly uniform radioactive intensity throughout the range of a few to thousands of nucleotides in length. There is virtually no background due to terminations at pause sites or secondary-structure impediments. Processive synthesis with dITP in place of dGTP eliminates band compressions, making possible the unambiguous determination of sequences from a single orientation.     

Photocleavage of a 2-nitrobenzyl linker bridging a fluorophore to the 5' end of DNA

Three single-stranded DNA molecules of different lengths were synthesized and characterized, each containing a fluorescent dye (6-carboxyfluorescein) connected to the 5' end via a photocleavable 2-nitrobenzyl linker and a biotin moiety at the 3' end. UV irradiation (lambda approximately 340 nm) of solutions containing these fluorescent DNA molecules caused the complete cleavage of the nitrobenzyl linker, separating the fluorophore from the DNA. The photocleavage products were characterized by HPLC and matrix-assisted laser desorption ionization/time-of-flight mass spectrometry. Our experimental results indicated that the proximity of the chromophore 6-carboxyfluorescein to the 2-nitrobenzyl linker did not hinder the quantitative photocleavage of the linker in the DNA molecules. The biotin moiety allowed immobilization of the fluorescent DNA on streptavidin-coated glass chips. The photocleavage of the immobilized DNA was investigated directly by fluorescence spectroscopy. The results demonstrated that close to 80% of the fluorophore was removed from the immobilized DNA after UV irradiation at 340 nm. These results strongly support the application of the 2-nitrobenzyl moiety as an efficient photocleavable linker, connecting fluorescent probes to DNA molecules for a variety of biological analyses such as DNA sequencing by synthesis.     

Characterization of Three Types of β0-Thaussemia Resulting from a Partial Deletion of the β-Globin Gene

Three patients heterozygous for a partial deletion of the β-globin gene were studied: an American Black with an ≈1.35 kb deletion, a Turkish patient with an ≈300 nucleotide deletion, and a Greek patient with a newly discovered deletion of 44 nucleotides. The DNA was amplified by the polymerase chain reaction procedure and sequenced; only the DNA with the deletion was amplified for the patients with the ≈1.35 kb and ≈300 bp deletion, facilitating the interpretation of the sequencing gels. The amplified DNA fragments from these two chromosomes were also cloned into a plasmid vector and sequenced. The size of the deletion found in the Turkish patient is 290 nucleotides and includes 123, 124 or 125 nucleotides 5′ to the Cap site, the 5′ untranslated region, exon 1, and 25, 24, or 23 nucleotides of the first intron. The total size of the deletion of the Black patient is 1393 nucleotides including 485 (484) bp 5′ to the Cap site, exon 1, intron 1, exon 2, and 413 (414) nucleotides of the second intron. The new deletion in the Greek β-thalassemic patient was detected by direct sequencing of amplified DNA; the 44 bp deletion begins within codon 24 or between codons 24 and 25, and includes the first 26 or 27 nucleotides of intron 1. This deletion was confirmed by hybridization of amplified DNA with a specific oligonucleotide probe and by sequence analysis of amplified DNA cloned in a plasmid. A 7 bp homology sequence (GACAGGT) was found at both sides of the 290 bp deletion, while only 3 nucleotides were repeated at both sides of the 44 nucleotide deletion (66T). No homology was found between the breakpoints of the 1393 nucleotide deletion.     

From the Cover: PNAS Plus: Design and characterization of a nanopore-coupled polymerase for single-molecule DNA sequencing by synthesis on an electrode array

Scalable, high-throughput DNA sequencing is a prerequisite for precision medicine and biomedical research. Recently, we presented a nanopore-based sequencing-by-synthesis (Nanopore-SBS) approach, which used a set of nucleotides with polymer tags that allow discrimination of the nucleotides in a biological nanopore. Here, we designed and covalently coupled a DNA polymerase to an α-hemolysin (αHL) heptamer using the SpyCatcher/SpyTag conjugation approach. These porin–polymerase conjugates were inserted into lipid bilayers on a complementary metal oxide semiconductor (CMOS)-based electrode array for high-throughput electrical recording of DNA synthesis. The designed nanopore construct successfully detected the capture of tagged nucleotides complementary to a DNA base on a provided template. We measured over 200 tagged-nucleotide signals for each of the four bases and developed a classification method to uniquely distinguish them from each other and background signals. The probability of falsely identifying a background event as a true capture event was less than 1.2%. In the presence of all four tagged nucleotides, we observed sequential additions in real time during polymerase-catalyzed DNA synthesis. Single-polymerase coupling to a nanopore, in combination with the Nanopore-SBS approach, can provide the foundation for a low-cost, single-molecule, electronic DNA-sequencing platform.DNA sequencing is a fundamental technology in the biological and medical sciences (1). Advances in sequencing technology have enabled the growth of interest in individualized medicine with the hope of better treating human disease. The cost of genome sequencing has dropped by five orders of magnitude over the last decade but still remains out of reach as a conventional clinical tool (2, 3). Thus, the development of new, high-throughput, accurate, low-cost DNA-sequencing technologies is a high priority. Ensemble sequencing-by-synthesis (SBS) platforms dominate the current landscape. During SBS, a DNA polymerase binds and incorporates a nucleotide analog complementary to the template strand. Depending on the instrumentation, this nucleotide is identified either by its associated label or the appearance of a chemical by-product upon incorporation (4). These platforms take advantage of a high-fidelity polymerase reaction but require amplification and have limited read lengths (5). Recently, single-molecule strategies have been shown to have great potential to achieve long read lengths, which is critical for highly scalable and reliable genomic analysis (6–9). Pacific Biosciences’ SMRT SBS approach has been used for this purpose but has lower throughput and higher cost compared with current second-generation technology (10).Since the first demonstration of single-molecule characterization by a biological nanopore two decades ago (11), interest has grown in using nanopores as sensors for DNA base discrimination. One approach is strand sequencing, in which each base is identified as it moves through an ion-conducting channel, ideally producing a characteristic current blockade event for each base. Progress in nanopore sequencing has been hampered by two physical limitations. First, single-base translocation can be too rapid for detection (1–3 μs per base), and second, structural similarities between bases make them difficult to identify unambiguously (12). Some attempts to address these issues have used enzymes as molecular motors to control single-stranded DNA (ssDNA) translocation speeds but still rely on identifying multiple bases simultaneously (13–15). Other approaches used exonuclease to cleave a single nucleoside-5′-monophosphate that then passes through the pore (16), or modified the pore opening with a cyclodextrin molecule to slow translocation and increase resolution for individual base detection (17, 18). All of these techniques rely on detecting similarly sized natural bases, which produce relatively similar current blockade signatures. Additionally, no strategies for covalently linking a single enzyme to a multimeric nanopore have been published.Recently, we reported a method for SBS with nanopore detection (19, 20). This approach has two distinct features: the use of nucleotides with specific tags to enhance base discrimination and a ternary DNA polymerase complex to hold the tagged nucleotides long enough for tag recognition by the nanopore. As shown in Fig. 1, a single DNA polymerase is coupled to a membrane-embedded nanopore by a short linker. Next, template and four uniquely tagged nucleotides are added to initiate DNA synthesis. During formation of the ternary complex, a polymerase binds to a complementary tagged nucleotide; the tag specific for that nucleotide is then captured in the pore. Each tag is designed to have a different size, mass, or charge, so that they generate characteristic current blockade signatures, uniquely identifying the added base. This system requires a single polymerase coupled to each nanopore to ensure any signal represents sequencing information from only one DNA template at a time. Kumar et al. (19) demonstrated that nucleotides tagged with four different polyethylene glycol (PEG) molecules at the terminal phosphate were good substrates for polymerase and that the tags could generate distinct signals as they translocate through the nanopore. These modifications enlarge the discrimination of the bases by the nanopore relative to the use of the natural nucleotides. We recently expanded upon this work by replacing the four PEG polymers with oligonucleotide-based tags and showed that a DNA polymerase coupled to the nanopore could sequentially add these tagged nucleotides to a growing DNA strand to perform Nanopore-SBS (20). Although this work showcased the promise of this technology, it did not describe in detail how to build a protein construct capable of Nanopore-SBS and did not obtain enough data to develop a statistical framework to uniquely distinguish the tagged nucleotides from each other.Open in a separate windowFig. 1.Principle of single-molecule DNA sequencing by a nanopore using tagged nucleotides. Each of the four nucleotides carries a different polymer tag (green square, A; red oval, T; blue triangle, C; black square, G). During SBS, the complementary nucleotide (T shown here) forms a tight complex with primer/template DNA and the nanopore-coupled polymerase. As the tagged nucleotides are incorporated into the growing DNA template, their tags, attached via the 5′-phosphate, are captured in the pore lumen, which results in a unique current blockade signature (Bottom). At the end of the polymerase catalytic reaction, the tag is released, ending the current blockade, which returns to open-channel reading at this time. For the purpose of illustration, four distinct tag signatures are shown in the order of their sequential capture. A large array of such nanopores could lead to highly parallel, high-throughput DNA sequencing.Here, we describe the design and characterization of a protein construct capable of carrying out Nanopore-SBS (Fig. 1). A porin attached to a single DNA polymerase molecule is inserted into a lipid bilayer formed on an electrode array. The polymerase synthesizes a new DNA strand using four uniquely tagged nucleotides. The DNA polymerase is positioned in such a way that when the ternary complex is formed with the tagged nucleotide, the tag is captured by the nanopore and identified by the resulting current blockade signature. We first describe the construction and purification of an α-hemolysin (αHL) heptamer covalently attached to a single ϕ29 DNA polymerase using the SpyTag/SpyCatcher conjugation approach (21), followed by binding of this conjugate with template DNA and its insertion into a lipid bilayer array. We confirm that this complex is stable and retains adequate pore and polymerase activities. We verify that the tagged nucleotides developed by Fuller et al. (20) can be bound by the polymerase and accurately discriminated by the nanopore. We develop an experimental approach and computational methods to uniquely and specifically distinguish true tagged-nucleotide captures from background and from other tagged nucleotides. We address ways that tagged-nucleotide captures may be misidentified and demonstrate approaches to correct for these. We further show this protein construct can capture tagged nucleotides during template-directed DNA synthesis in the presence of Mn²⁺, demonstrating its utility for Nanopore-SBS.     

Characterization of three types of beta zero-thalassemia resulting from a partial deletion of the beta-globin gene

Three patients heterozygous for a partial deletion of the beta-globin gene were studied: an American Black with an approximately 1.35 kb deletion, a Turkish patient with an approximately 300 nucleotide deletion, and a Greek patient with a newly discovered deletion of 44 nucleotides. The DNA was amplified by the polymerase chain reaction procedure and sequenced; only the DNA with the deletion was amplified for the patients with the approximately 1.35 kb and approximately 300 bp deletion, facilitating the interpretation of the sequencing gels. The amplified DNA fragments from these two chromosomes were also cloned into a plasmid vector and sequenced. The size of the deletion found in the Turkish patient is 290 nucleotides and includes 123, 124 or 125 nucleotides 5' to the Cap site, the 5' untranslated region, exon 1, and 25, 24, or 23 nucleotides of the first intron. The total size of the deletion of the Black patient is 1393 nucleotides including 485 (484) bp 5' to the Cap site, exon 1, intron 1, exon 2, and 413 (414) nucleotides of the second intron. The new deletion in the Greek beta-thalassemic patient was detected by direct sequencing of amplified DNA; the 44 bp deletion begins within codon 24 or between codons 24 and 25, and includes the first 26 or 27 nucleotides of intron 1. This deletion was confirmed by hybridization of amplified DNA with a specific oligonucleotide probe and by sequence analysis of amplified DNA cloned in a plasmid. A 7 bp homology sequence (GACAGGT) was found at both sides of the 290 bp deletion, while only 3 nucleotides were repeated at both sides of the 44 nucleotide deletion (GGT). No homology was found between the breakpoints of the 1393 nucleotide deletion.     

Mouse DNA polymerase alpha-primase terminates and reinitiates DNA synthesis 2-14 nucleotides upstream of C2A1-2(C2-3/T2) sequences on a minute virus of mice DNA template.

The distribution of termination and initiation sites in a 5081-nucleotide minute virus of mice DNA template being copied by a highly purified mouse DNA polymerase alpha-DNA primase complex in the presence of GTP has been examined. The 3'-hydroxyl termini (17 in all) were clustered at six sites that were located 2-14 nucleotides upstream of C2A2C2, C2AC3, or C2A2T2 sequences. When either [alpha-32P]- or [gamma-32P]GTP was included in the DNA polymerase reaction mixtures, nascent DNA became radiolabeled. Analysis of the 32P-labeled material following treatment of the DNA with tobacco acid pyrophosphatase, bacterial alkaline phosphatase, or ribonuclease T1 revealed the presence of oligoribonucleotide chains averaging 5-7 nucleotides long and beginning with 5' GTP residues. Eight presumptive DNA primase initiation sites were located opposite C4 or C5 sequences 3-9 nucleotides upstream of one of the three closely related hexanucleotides C2A2C2, C2AC3, and C2A2T2. RNA-DNA junctions were found 3-10 nucleotides downstream of DNA primase initiation sites. The results indicate that hexanucleotides having the general formula C2A1-2(C2-3/T2), herein referred to as psi, are involved in promoting termination of DNA synthesis and/or de novo initiation of RNA-primed DNA chains by DNA polymerase alpha-primase.     

Initiation of phi 29 DNA replication occurs at the second 3'' nucleotide of the linear template: a sliding-back mechanism for protein-primed DNA replication.

Bacteriophage phi 29 DNA replication is initiated when a molecule of dAMP is covalently linked to a free molecule of the terminal protein, in a reaction catalyzed by the viral DNA polymerase. We demonstrate that single-stranded DNA molecules are active templates for the protein-primed initiation reaction and can be replicated by phi 29 DNA polymerase. Using synthetic oligonucleotides, we carried out a mutational analysis of the phi 29 DNA right end to evaluate the effect of nucleotide changes at the replication origin and to determine the precise initiation site. The results indicate that (i) there are no strict sequence requirements for protein-primed initiation on single-stranded DNA; (ii) initiation of replication occurs opposite the second nucleotide at the 3' end of the template; (iii) a terminal repetition of at least two nucleotides is required to efficiently elongate the initiation complex; and (iv) all the nucleotides of the template, including the 3' terminal one, are replicated. A sliding-back model is proposed in which a special transition step from initiation to elongation can account for these results. The possible implication of this mechanism for the fidelity of the initiation reaction is discussed. Since all the terminal protein-containing genomes have some sequence reiteration at the DNA ends, this proposed sliding-back model could be extrapolable to other systems that use proteins as primers.     

Reduced in vivo mutagenesis by mutant herpes simplex DNA polymerase involves improved nucleotide selection.

We present evidence that mutation frequencies in a mammalian system can vary according to the replication fidelity of the DNA polymerase. We demonstrated previously that several derivatives of herpes simplex virus type 1 that encode polymerases resistant to various antiviral drugs (e.g., nucleotide analogues) also produce reduced numbers of spontaneous mutants. Here we show that the DNA polymerase from one antimutator virus exhibits enhanced replication fidelity. First, the antimutator virus showed a reduced response to known mutagens that promote base mispairing during DNA replication (N-methyl-N'-nitro-N-nitrosoguanidine, 5-bromo-deoxyuridine). Second, purified DNA polymerase from the antimutator produced fewer replication errors in vitro, based on incorporation of mispaired nucleotides or analogues with abnormal sugar rings. We have investigated possible mechanisms for the enhanced fidelity of the antimutator polymerase. We show that the mutant enzyme has altered interactions with nucleoside triphosphates, as indicated by its resistance to nucleotide analogues and elevated Km values for normal nucleoside triphosphates. We present evidence against increased proofreading by an associated 3',5' exonuclease (as seen for T4 bacteriophage antimutator polymerases), based on nuclease levels in the mutant polymerase. We propose that reduced affinity of the polymerase for nucleoside triphosphates accounts for the antimutator phenotype by accentuating differences in base-pair stability, thus facilitating selection of correct nucleotides.     

Mutagenesis during in vitro DNA synthesis.

The error frequency of in vitro DNA synthesis using a natural DNA template has been measured with a biological assay for nucleotide substitutions. phiX174 DNA containing an amber mutation was copied in vitro by Escherichia coli DNA polymerase I, and the reversion frequency of the progeny DNA was determined by transfection of E. coli spheroplasts. E. coli polymerase I makes less than 1 mistake at the am3 locus for every 7700 nucleotides incorporated under standard reaction conditions. Substitution of Mn2+ for Mg2+ and unequal concentrations of deoxynucleoside triphosphate substrates raises this mutation frequency to greater than 1 in 1000. Thus, E. coli DNA polymerase I can copy natural DNA templates with high fidelity and its accuracy can be affected by alterations in reaction conditions.     

Effect of manganese ions on the incorporation of dideoxynucleotides by bacteriophage T7 DNA polymerase and Escherichia coli DNA polymerase I.

Incorporation of dideoxynucleotides by T7 DNA polymerase and Escherichia coli DNA polymerase I is more efficient when Mn2+ rather than Mg2+ is used for catalysis. Substituting Mn2+ for Mg2+ reduces the discrimination against dideoxynucleotides approximately 100-fold for DNA polymerase I and 4-fold for T7 DNA polymerase. With T7 DNA polymerase and Mn2+, dideoxynucleotides and deoxynucleotides are incorporated at virtually the same rate. Mn2+ also reduces the discrimination against other analogs with modifications in the furanose moiety, the base, and the phosphate linkage. A metal buffer, isocitrate, expands the MnCl2 concentration range effective in catalyzing DNA synthesis. The lack of discrimination against dideoxynucleoside triphosphates using T7 DNA polymerase and Mn2+ results in uniform terminations of DNA sequencing reactions, with the intensity of adjacent bands on polyacrylamide gels varying in most instances by less than 10%.     

Chemical Synthesis of a Primer and Its Use in the Sequence Analysis of the Lysozyme Gene of Bacteriophage T4

We have developed a general approach for determining the nucleotide sequence of a gene, with the aid of a deoxyribonucleotide primer of defined sequence. The selection of the primer sequence was based on a short segment of mRNA sequence of T4 phage lysozyme. A tetradecadeoxyribonucleotide primer was chemically synthesized and its sequence verified by sequence analysis. This primer was found to bind to the single-stranded region of the exonuclease III-treated T4 DNA, and specific nucleotides were incorporated to its 3' end. The result indicated that this primer was bound to the expected location on the T4 DNA. Therefore, long sequences of the T4 lysozyme gene can now be determined from this specific starting point.