Complete enzymatic synthesis of DNA containing the SV40 origin of replication

The replication of simian virus 40 origin-containing DNA has been reconstituted in vitro with SV40 large T antigen and purified proteins isolated from HeLa cells. Covalently closed circular DNA (RF I') daughter molecules are formed in the presence of T antigen, a single-stranded DNA binding protein and DNA polymerase alpha-primase complex, together with ribonuclease H, DNA ligase, topoisomerase II, and a double-stranded specific exonuclease that has been purified to homogeneity. The 44-kDa exonuclease-digested oligo(rA) annealed to poly(dT) in the 5'----3' direction. DNA ligase and the 5'----3' exonuclease were essential for RF I' formation. Covalently closed circular duplex DNA and full length linear single-stranded DNA were detected by alkaline gel electrophoresis as products of the complete system. DNA replication in the absence of either DNA ligase or the 5'----3' exonuclease yielded DNA products that were half length (approximately 1500 nucleotides) and smaller Okazaki-like fragments (approximately 200 nucleotides). Hybridization experiments showed that the longer chains were synthesized from the leading strand template, while the small products were synthesized from the lagging strand template. These results suggest that the RNA primers attached to 5' ends of replicated DNA are completely removed by the 5'----3' exonuclease, with the assistance of RNase H.     

Non-enzymatic template-directed synthesis of RNA copolymers

Cytosine-rich RNA copolymers facilitate the template-directed synthesis of complementary oligomers from mononucleotide 5′-phospho-2-methylimidazolides (Fig. 1). The efficiency of this reaction falls sharply as the ratio of cytosine to non-cytosine in the template is decreased. This is a severe limitation for self-replication because it means that any cytosine-rich polynucleotide that can serve as a good template will produce a cytosine-poor complementary strand that is unable to direct further rounds of synthesis. Studies with low-ratio random copolymer templates have shown that the efficiency can be increased by adjusting initial monomer concentrations and by providing additional activated monomers during later stages of the reaction. The oligomeric reaction products can be studied in detail using high performance liquid chromatography. It is possible to separate oligonucleotides on the basis of chain length and base composition. Thus a wealth of information is available to characterize the distribution of products over the course of the reaction and under a variety of reaction conditions.     

Non-enzymatic template-directed synthesis of RNA copolymers

Cytosine-rich RNA copolymers facilitate the template-directed synthesis of complementary oligomers from mononucleotide 5'-phospho-2-methylimidazolides (Fig. 1). The efficiency of this reaction falls sharply as the ratio of cytosine to non-cytosine in the template is decreased. This is a severe limitation for self-replication because it means that any cytosine-rich polynucleotide that can serve as a good template will produce a cytosine-poor complementary strand that is unable to direct further rounds of synthesis. Studies with low-ratio random copolymer templates have shown that the efficiency can be increased by adjusting initial monomer concentrations and by providing additional activated monomers during later stages of the reaction. The oligomeric reaction products can be studied in detail using high performance liquid chromatography. It is possible to separate oligonucleotides on the basis of chain length and base composition. Thus a wealth of information is available to characterize the distribution of products over the course of the reaction and under a variety of reaction conditions.     

Enzymatic synthesis of duplex circular phiX174 DNA containing phosphoramidate bonds in the (-) strand.

Duplex circular phiX174 DNA (RF I) containing some phosphoramidate links in the backbone chain of the (-) strand was synthesized by reaction of 5'-amino-5'-deoxythymidine 5'-triphosphate, dCTP, dGTP, and 3H-dATP with DNA polymerase I and DNA ligase (T4) on a (+) strand phiX174 amber 3 DNA template. The yield of duplex DNA was higher when dTTP was included along with the amino analog in the initial reaction system or was added late in the synthesis. RF I DNA was observed as a rapidly sedimenting species in an alkaline sucrose gradient, and the presence of phosphoramidate linkages was demonstrated by the unusual lability of the duplex DNA in a weakly acidic solution.     

Complete enzymatic replication of plasmids containing the origin of the Escherichia coli chromosome

During enzymatic replication of plasmids containing the origin of the Escherichia coli chromosome, oriC, formation of an active initiation complex consisting of dnaA, dnaB, dnaC, and HU proteins, requires a supercoiled DNA template. Relaxed covalently closed plasmids are active only if supercoiled by gyrase prior to initiation; nicked and linear DNAs are inactive. Semi-conservative replication proceeds via delta structure as intermediates. Daughter molecules include nicked intermediates. Daughter molecules include nicked monomers and catenated pairs. Elongation is rapid, but late replicative intermediates accumulate because the final elongation and termination steps are slow. Production of covalently closed circular daughter DNA molecules requires removal of ribonucleotide residues (primers) by DNA polymerase I, assisted by ribonuclease H, gap filling, and ligation of nascent strands by ligase. Reconstitution of a complete cycle of oriC plasmid replication, beginning and ending with supercoiled molecules, has been achieved with purified proteins.     

Chemical and enzymatic analysis of covalent bonds between peptides and chromosomal DNA.

DNA from Ehrlich ascites tumor (EAT) cells and from human placenta was examined for covalent bonds between hydroxy amino acid residues in peptides and nucleotide phosphate groups. The residual proteinaceous material in highly purified DNA was radiolabelled with 125Iodine and the linking-groups between peptides and nucleotides released by combined protease and nuclease treatment were investigated with respect to their chemical and enzymatic stabilities. The residual nucleotide(s)-peptide(s) fraction from DNA isolated after prolonged alkaline cell lysis and phenol extraction contains mainly alkali and acid-stable but phosphodiesterase-sensitive peptide-nucleotide complexes which indicates phosphodiesters between tyrosyl residues in peptides and nucleotide phosphates. In contrast, the linking-group fraction from DNA isolated under native conditions contains additional peptide components. (a) Phospho-peptides that co-purify with DNA but that are not covalently bound to nucleotides. (b) A fraction of peptides that is released from nucleotides by alkali in a time and concentration-dependent reaction. Evidence is presented indicating that the latter fraction involves phospho-triesters between hydroxy amino acid residues in peptides and internucleotide phosphates. The phosphodiesters between hydroxy amino acids and nucleotide phosphates representing the predominant class of peptide-nucleotide complexes in alkali-denatured DNA are most likely side products of peptide-nucleotide phospho-triester hydrolysis.     

Chemoenzymatic and template-directed synthesis of bioactive macrocyclic peptides.

Non-ribosomally synthesized peptides have compelling biological activities ranging from antimicrobial to immunosuppressive and from cytostatic to antitumor. The broad spectrum of applications in modern medicine is reflected in the great structural diversity of these natural products. They contain unique building blocks, such as d-amino acids, fatty acids, sugar moieties, and heterocyclic elements, as well as halogenated, methylated, and formylated residues. In the past decades, significant progress has been made toward the understanding of the biosynthesis of these secondary metabolites by nonribosomal peptide synthetases (NRPSs) and their associated tailoring enzymes. Guided by this knowledge, researchers genetically redesigned the NRPS template to synthesize new peptide products. Moreover, chemoenzymatic strategies were developed to rationally engineer nonribosomal peptides products in order to increase or alter their bioactivities. Specifically, chemical synthesis combined with peptide cyclization mediated by nonribosomal thioesterase domains enabled the synthesis of glycosylated cyclopeptides, inhibitors of integrin receptors, peptide/polyketide hybrids, lipopeptide antibiotics, and streptogramin B antibiotics. In addition to the synthetic potential of these cyclization catalysts, which is the main focus of this review, different enzymes for tailoring of peptide scaffolds as well as the manipulation of carrier proteins with reporter-labeled coenzyme A analogs are discussed.     

Enzymatic ligation of DNA fragments containing phosphoamide modification of the internucleotide bonds

DNA fragments with the point amidophosphate (cyclohexylamido- or morpholido-) modification in the sugar-phosphate backbone were synthesized and separated into individual diastereoisomer. The isomers were separated by the reversed-phase HPLC (RPC), and chirality at phosphorus was assigned by a stereochemical correlation scheme using phosphorothioate standards. The RPC-retention time values for Rp-isomers were found to be lower than for Sp-analogues. Amidophosphate DNA fragments were used as P- and OH-components in the T4 DNA-ligation. The enzyme does not ligate amidated fragments with modified internucleotide linkage near 5'- or 3'-end, independently of the amidophosphate chirality. When an unmodified phosphodiester linkage separates the amidophosphate group from 3'-end in O-component, the ligation occurs only with Sp-isomer, whereas Rp-analogue does not give the ligation product. In the P-component of the ligation, configuration of the modified linkage separated from 5'-phosphate by an unmodified linkage does not affect the result of the enzymatic reaction: both Sp-and Rp-stereomers do take part in the ligation. As a result of the ligation of the modified fragments on unmodified templates a set of 31-mers was obtained. They contain FokI and EcoRI recognition sites with the cleavage points of both endonucleases coinciding and being amidated. Upon treatment of duplex DNA consisted of unmodified and amidated strands with these endonucleases Sp-configuration did not hinder the cleavage of the unmodified strand, whereas Rp-configuration inhibited the EcoRI and did not affect the FokI cleavage.     

Simulation of non-enzymatic template-directed synthesis of oligonucleotides and peptides

A simulation model is proposed for the template- and sequence-directed (TSD) condensation of two trideoxyribonucleotide 3'-phosphate molecules into a hexameric template with palindromic sequence studied experimentally by von Kiedrowski (1986;Angew. Int. Ed. Engl.25, 932--935). The model simulates reasonably well the kinetics of synthesis of both the template, and the pyrophosphate product which is not directly involved in the autocatalytic reaction. It offers quantitative approximation of the different rate constants of the processes involved in the reaction. The model simulates and gives predictions for the influence of factors such as the initial concentrations of the trimers and the template, and gives predictions for the effect of temperature on the dynamics of the autocatalytic reaction. The model also simulates well the production rate of a different self-replicating system (coiled coil peptide) used in the experiments of Lee et al. (1997;Nature390, 591--594). Comparing the different rate constants, it seems that chain elongation occurs at higher rates in the peptide system (at 23 degrees C) than in the nucleotide one (at 0 degrees C), but that the relative contribution of template-directed synthesis is significantly larger with the nucleotides.     

Probing structural factors stabilizing antisense oligonucleotide duplexes: NMR studies of a DNA.DNA duplex containing a formacetal linkage.

The duplex formed by annealing the formacetal backbone modified dodecamer d-(CGCGTTOCH2OTTGCGC) to its complementary strand, d(GCGCAAAACGCG) (duplex I), has been studied by NMR techniques and analyzed with reference to its unmodified counterpart (duplex II). Comparison of parameters such as 2D cross-peak intensities, coupling constants, and spectral patterns indicates that structural perturbations caused by the incorporation of the formacetal linkage are minimal and localized to the central T4.A4 block. Duplex I adopts a B-type helical conformation with regular Watson-Crick base pairing and normal minor groove width. The methylene group is accommodated along the phosphate backbone in a conformation similar to that of the PO2 group found in the B-form DNA family. The central T6-T7 base pairs of duplex I melt simultaneously with the duplex, indicating a cooperative transition to single strands. Although the formacetal linkage affects global melting, as evidenced by a 3 degree C reduction in Tm for duplex I with respect to duplex II, the present study indicates that this is not the result of localized premelting at the formacetal site of duplex I but rather reflects the subtle interplay of several structural and energy factors which need to be further explored.     

Increased specificity for antisense oligodeoxynucleotide targeting of RNA cleavage by RNase H using chimeric methylphosphonodiester/phosphodiester structures.

One of the inherent problems in the use of antisense oligodeoxynucleotides to ablate gene expression in cell cultures is that the stringency of hybridization in vivo is not subject to control and may be sub-optimal. Consequently, phosphodiester or phosphorothioate antisense effectors and non-targeted cellular RNA may form partial hybrids which are substrates for RNase H. Such processes could promote the sequence dependent inappropriate effects recently reported in the literature. We have attempted to resolve this problem by using chimeric methylphosphonodiester/phosphodiester oligodeoxynucleotides. In contrast to the extensive RNA degradation observed with all-phosphodiester oligodeoxynucleotides, highly modified chimeric antisense effectors displayed negligible, or undetectable, cleavage at non-target sites without significantly impaired activity at the target site. We also note that all of the all-phosphodiester oligodeoxynucleotides tested demonstrated inappropriate effects, and that such undesirable activity could vary widely between different sequences.     

Efficiency, fidelity and enzymatic switching during translesion DNA synthesis

More than half of the 16 human DNA polymerases may have some role in DNA replication and potentially modulate the biological effects of DNA template lesions that impede replication fork progression. As one approach to understand how multiple polymerases are coordinated at the fork, we recently quantified the efficiency and fidelity with which one particular translesion synthesis enzyme, human DNA polymerase eta, copies templates containing cis-syn thymine dimers. Several observations from that study were unanticipated. Here we discuss the structural and biological implications of those results in light of earlier studies of translesion synthesis.     

Chemical synthesis of DNA oligomers containing cytosine arabinoside.

The solid phase phospite triester synthesis of oligodeoxynucleotides containing cytosine arabinoside (araC) is described. A protected araC phosphoramadite was prepared for the introduction of araC residues at 5'termini and internucleotide positions in DNA oligomers. These oligomers were utilized to demonstrate the formation of correct 3'-5' linkages, to test for alkaline lability at the araC site, and to study the stability of duplexes containing araC-G base pairs. For the introduction of araC residues at 3' terminal positions, a protected derivative of araC was coupled to functionalized silica. This material was used to prepare a test oligomer which was characterized enzymatically.     

Initiation of enzymatic DNA synthesis by yeast RNA polymerase I.

In vitro DNA synthesis by yeast DNA polymerase I can be initiated by partially purified yeast RNA polymerases in the presence or absence of rNTPs. Homogeneous yeast RNA polymerase I initiates DNA synthesis by yeast DNA polymerase I on single-stranded DNA templates only in the presence of all four rNTPs. A protein capable of initiating enzymatic DNA synthesis on single-stranded DNA in the absence of rNTPs has also been separated from partially purified yeast RNA polymerase I fractions. Analysis of the RNA polymerase I initiated replication products of phage fd DNA on alkaline sucrose gradients showed noncovalent linkage between the newly synthesized DNA and the template. Isopycnic analyses of the ribonucleotide initiated fd DNA replication products demonstrated covalent linkage between the initiator RNA and newly synthesized DNA. Results from 32P-transfer experiments confirmed the covalent linkage between RNA and DNA chains and showed the presence of all four ribo- and deoxyribonucleotides at the RNA--DNA junctions. The ribonucleotide found most frequently at the RNA--DNA junction is uridylate and the purine deoxynucleotides occur more frequently than pyrimidine deoxynucleotides.     

Progress towards single-molecule sequencing: enzymatic synthesis of nucleotide-specifically labeled DNA

The enzymatic incorporation of modified dNTPs into a growing DNA strand has intensively been studied. Modifications were detectable reporter groups such as digoxigenin or biotin, fluorochromes or aliphatic side chains covalently attached to the base. Incorporation efficiencies were determined with several DNA polymerases using linear primer-extension reactions followed by denaturing PAGE as a high-resolution detection system. We describe the enzymatic synthesis of DNA consisting of modified nucleotides exclusively. A defined template-primer system allows us to trace incorporation: (1) in up to 18 neighboring positions for several dUTP-derivatives; or (2) in stretches of DNA of up to 40 bases in length with complete substitution of all four natural dNTPs by differently modified counterparts. Synthesized DNA molecules are shown to particularly exhibit dramatically altered physico-chemical properties by contrast with native DNA. These results provide a fundamental data set for probe generation in single-molecule DNA sequencing (SMS).     

Properties of circular dumbbell RNA/DNA chimeric oligonucleotides containing antisense phosphodiester oligonucleotides.

We have designed a new class of oligonucleotides, "dumbbell RNA/DNA chimeric phosphodiesters", containing two alkyl loop structures with RNA/DNA base pairs (sense (RNA) and antisense (DNA) in the double helical stem. The reaction of nicked (NDRDON) and circular (CDRDON) dumbbell RNA/DNA chimeric oligonucleotides with RNaseH gave the corresponding antisense phosphodiester oligonucleotide together with the sense RNA cleavage products. The liberated antisense phosphodiester oligodeoxynucleotide was bound to the target 35mer RNA, which gave 35mer RNA cleavage products by treatment with RNaseH. The circular dumbbell RNA/DNA chimeric oligonucleotide showed more nuclease resistance than the linear antisense phosphodiester oligodeoxynucleotide(anti-ODN) and the nicked dumbbell RNA/DNA chimeric oligonucleotide.