Modes of DNA replication primed with the oligomer of palindrome

What is the precise molecular mechanism of semi-conservative DNA replication? After the great efforts of the past 20 years, molecular biology has now established the discontinuous syntheses of daughter DNA on both of the parental strands. In order to explain this type of discontinuous replication, we introduce the concept of a palindromic primer.First we focus our attention on various oligomers (RNA or DNA) which appear usually or occasionally in the process of replication. Then we propose the palindromic nature of these oligomers so as to serve as the primer of DNA synthesis. This postulation gives a theoretical reasoning for the discontinuities of both new strands in the fork region of replication.Subsequently we consider Watson's concatemeric intermediate theory, proposed for the explanation of replicative synthesis of phage T7 DNA. By considering the contribution of some sequence-specific endonuclease(s), we suggest the existence of partial palindromic sequences of bases at the connecting region(s) in which the redundant ends of the respective phage DNA molecules are overlapping. Another theory on the replication of linear chromosomal DNA including the concept of the terminal palindromic sequence of bases is also analyzed from the viewpoint of palindromic primer. Further, some recent experimental approaches, especially on the origin(s) of DNA replication, are shown to favour the concept of a palindromic primer.     

Eukaryotic DNA primase

Eukaryotic DNA primase initiates the synthesis of all new DNA strands by synthesizing short RNA oligomers on single-stranded DNA. Additionally, primase helps couple replication and repair and is critical for telomere maintenance and, therefore, chromosome stability. In light of the many aspects of DNA metabolism in which primase is involved, understanding the unique features of the mechanism of this enzyme and how it interacts with other proteins will greatly advance our knowledge of DNA replication and repair.     

Polynucleotide synthesis at oligomeric templates

The theory of kinetics of polynucleotide synthesis at oligomeric templates is developed. It is shown that the dependence of oligomer efficacy on its size cannot be explained without taking into account the probability of separation of the oligomer from the growing chain. If such a possibility exists, the maximal size which can be achieved by the growing chain is determined by the ratio of the probability of proposed propagation and of the probability of separation. Without any models of the separation mechanism, the study of experimental kinetic data shows that two such mechanisms exist. Very short oligomers can be easily separated from the growing chain, but there is a critical size of oligomer after which the probability of separation is much smaller. The oligomers whose size is equal to or greater than the critical one form helices with growing chains.     

Effect of cytosine arabinoside on replicon initiation in human lymphoblasts

Cytosine arabinoside inhibited DNA synthesis in human lymphoblasts by inhibiting the initiation of DNA replication units. This effect was observed by a decrease in the incorporation of (³H) thymidine into low molecular weight DNA analyzed by velocity sedimentation in alkaline sucrose gradients. In contrast, there was no detectable effect on chain elongation and joining of those molecules that initiated replication before addition of the drug. These data indicate that cytosine arabinoside acts preferentially at the level of initiation of DNA replication rather than chain elongation.     

α-Chymotrypsin catalyses the synthesis of methotrexate oligomers

The enzymatic synthesis of methotrexate (MTX) catalysed by α -chymotrypsin was studied for the first time. The proteolytic enzyme displayed activity for the synthesis of MTX oligomers composed by 6 repeating units (DP_avg = 1.5). For longer oligomers, molecular dynamics simulations confirmed that as the oligomeric chain grows its accommodation in the enzymes’ active site is hindered, which is evidenced by a decrease of the binding energy associated. The full characterization of the oligomers produced was performed by nuclear magnetic resonance (NMR, ¹H and ¹³C), matrix-assisted laser desorption/ionization-time of flight (MALDI-TOF), electrospray ionization (ESI) and differential scanning calorimetry (DSC).     

Origin and diversification of a metabolic cycle in oligomer world

Based on the oligomer-world hypothesis we propose an abstract model where the molecular recognition among oligomers is described in the shape space. The origin of life in the oligomer world is regarded as the establishment of a metabolic cycle in a primitive cell. The cycle is sustained by the molecular recognition. If an original cell acquires the ability of the replication of oligomers, the relationship among oligomers changes due to the poor fidelity of the replication. This change leads to the diversification of metabolic cycles. The selection among diverse cycles is the basis of the evolution. The evolvability is one of the essential characters of life. We demonstrate the origin and diversification of the metabolic cycle by the computer simulation of our model. Such a simulation is expected to be the simplified demonstration of what actually occurred in the primordial soup. Our model describes an analog era preceding the digital era based on the genetic code.     

Synthesis of small polynucleotide chains in thymine-depleted bacteria

Bacteria that are depleted of intracellular thymidine nucleotide pools incorporate [³H]thymine at full specific activity, allowing the detection of early intermediates in DNA replication. A short pulse of [³H]thymine is incorporated almost exclusively into very small DNA chains which, during further incorporation of thymine, are converted into larger chains and high molecular weight DNA. The synthesis of these small DNA chains depends on the products of dna genes B, E and G. Analysis of the DNA by gel filtration on Sepharose 2B revealed an abundance of extremely short DNA chains while the frequency of larger chains decreased exponentially with increasing size. This size distribution of small DNA chains suggests a mechanism of DNA replication in which larger chains (Okazaki pieces, Okazaki et al., 1968a) arise through joining of extremely short polynucleotide chains in a process resembling crystallization rather than unidirectional chain elongation.     

Errors and alternatives in prebiotic replication and catalysis

The work on nonenzymatic nucleic acid replication performed by Leslie Orgel and co-workers over the last four decades, now extended by work on artificial selection of RNA aptamers and ribozymes, is generating some pessimism concerning the 'naked gene' theories of the origin of life. It is suggested here that the low probability of finding RNA aptamers and ribozymes within pools of random sequences is not as disquieting as the poor gain in efficiency obtained with increases in information content. As acknowledged by Orgel and many other authors, primitive RNA replication and catalysis must have occurred within already complex and dynamic environments. I, thus, propose to pay attention to a number of possibilities that bridge the gap between 'naked gene' theories, on one side, and metabolic theories in which complex systems self-propagate by growth and fragmentation, on the other side. For instance, one can de-emphasize nucleotide-by-nucleotide replication leading to long informational polymers, and view instead long random polymers as storage devices, from which shorter oligomers are excised. Catalytic tasks would be mainly performed by complexes associating two or more oligomers belonging to the same or to different chemical families. It is proposed that the problems of stability, binding affinity, reactivity, and specificity could be easier to handle by heterogeneous complexes of short oligomers than by long, single-stranded polymers. Finally, I point out that replication errors in a primitive replication context should include incorporations of alternative nucleotides with interesting, chemically reactive groups. In this way, an RNA sequence could be at the same time an inert sequence when copied without error, and a ribozyme, when a chemically reactive nucleotide is inadvertently introduced during replication.     

Cross-linking of native myosin forms oligomers of myosin heavy chain dimers

Chemical cross-linking of native myosin in 0.6 M NaCl with p-phenylene bis maleimide or glutaraldehyde resulted in rapid formation of myosin heavy chain dimers and their oligomers. Monomers and odd-number oligomers disappeared after the prolonged treatment with these reagents. When denatured myosin was cross-linking, myosin heavy chain monomers and odd-number oligomers remained after the prolonged treatment, although dimers and their even-number oligomers were abundant. For high molecular weight markers, myosin heavy chain oligomers formed from denatured myosin with glutaraldehyde or p-phenylene bis maleimide are recommended.     

Replication of SV40 chromatin in extracts from eggs of Xenopus laevis.

Simian virus 40 (SV40) nucleoprotein complexes were prepared from lytically infected cells and used as primer-templates for DNA replication in protein extracts from Xenopus eggs. We found that nucleoprotein containing replicating SV40 DNA served as primer-template while nucleoprotein with nonreplicating SV40 DNA was ineffective. In vitro DNA synthesis begins with short DNA fragments ("Okazaki fragments") which are, in later steps, joined to give unit length SV40 DNA strands, suggesting that in vivo initiated rounds of replication are completed in vitro in the Xenopus system. This conclusion is supported by a restriction enzyme analysis showing that in vitro DNA synthesis occurs in fragments distal to the SV40 origin of replication. Our studies indicate that SV40 DNA replication in Xenopus extracts can be used an an experimental system to study the biochemistry of replicative DNA chain elongation in vitro.     

Mechanism of initiation of in vitro DNA synthesis by the immunopurified complex between yeast DNA polymerase I and DNA primase

The immunopurified yeast DNA-polymerase-I--DNA-primase complex synthesizes oligo(rA) and oligo(rG) molecules that are used as primer for replication of poly(dT) and poly(dC). Neither initiation nor DNA synthesis is observed with poly(dA) and poly(dI). Nitrocellulose-filter binding shows that the enzyme complex binds to deoxypyrimidine polymers, but not to deoxypurine polymers. Although the yeast complex initiates DNA synthesis on deoxypyrimidine homopolymers, it prefers to elongate pre-existing primer molecules rather than to initiate de novo DNA replication. The size of the oligo(rA) and oligo(rG) primer molecules has been determined by urea/polyacrylamide gel electrophoresis: longer oligoribonucleotides are synthesized when their utilization is prevented by omitting dNTP. An oligodeoxythymidylate template with a chain length as short as five residues can support oligo(rA) synthesis catalyzed by the yeast DNA-polymerase--DNA-primase complex and the size of the oligoribonucleotide products synthesized with oligodeoxythymidylate of differing chain length has also been determined. The mechanistic properties of the DNA-polymerase--DNA-primase complexes, purified from different eukaryotic organisms, appear to be very similar. The possible biological implication of the studies on the mechanism and specificity of initiation of DNA synthesis in a well-defined model template system has been discussed.     

The dawn of the RNA World: Toward functional complexity through ligation of random RNA oligomers

A main unsolved problem in the RNA World scenario for the origin of life is how a template-dependent RNA polymerase ribozyme emerged from short RNA oligomers obtained by random polymerization on mineral surfaces. A number of computational studies have shown that the structural repertoire yielded by that process is dominated by topologically simple structures, notably hairpin-like ones. A fraction of these could display RNA ligase activity and catalyze the assembly of larger, eventually functional RNA molecules retaining their previous modular structure: molecular complexity increases but template replication is absent. This allows us to build up a stepwise model of ligation-based, modular evolution that could pave the way to the emergence of a ribozyme with RNA replicase activity, step at which information-driven Darwinian evolution would be triggered.     

Synthesis of high molecular weight DNA strands during S phase

The organization of the mammalian S phase was studied in synchronized mouse embryo cells in terms of the spatial relationship between replication units whose synthesis is initiated at different times in S phase and the rate of assimilation of replication units into high molecular weight DNA strands.The formation of high molecular weight nascent DNA strands several replication units in length was analyzed by velocity sedimentation in alkaline sucrose gradients and by isopycnic centrifugation in alkaline Cs₂SO₄/CsCl gradients. Differential labeling with an isotopic and a density label shows that replication units synthesized at different stages of the S phase are not found within the same high molecular weight polynucleotide strand. It is thus concluded that replication units duplicated at different stages of the S phase are spatially organized in clusters along the mammalian genome.The rate of formation of high molecular weight nascent DNA strands is at least 4 to 8 times slower than that predicted from the spatial organization of replication units and the rate of chain growth within replication units. It is concluded that the process of joining of the completed nascent strands of adjacent replication units plays a major role in the rate of completion of high molecular weight strands.     

Effect of puromycin on DNA replication in Chinese hamster cells

We have used autoradiography to examine the effect of puromycin on DNA replication in Chinese hamster cells aligned by treatment with fluorodeoxy-uridine. In the absence of puromycin the patterns of replication are consistent with those obtained previously by others (Cairns, 1966; Huberman &; Riggs, 1968). In particular, replication occurs in tandem clusters of replicons but not all replicons in a cluster appear to be activated at the same time.Puromycin decreases the over-all rate of synthesis of DNA per cell, but does not inhibit chain elongation as visualized in autoradiograms. It is suggested that puromycin inhibits the initiation of replication of replicons not yet activated. Puromycin prevents the joining of short stretches of radioactive DNA into longer pieces. This may be due to the inability to activate a few late replicating units within a cluster of replicons.     

Effects of T antigen and replication protein A on the initiation of DNA synthesis by DNA polymerase alpha-primase.

Studies of simian virus 40 (SV40) DNA replication in a reconstituted cell-free system have established that T antigen and two cellular replication proteins, replication protein A (RP-A) and DNA polymerase alpha-primase complex, are necessary and sufficient for initiation of DNA synthesis on duplex templates containing the SV40 origin of DNA replication. To better understand the mechanism of initiation of DNA synthesis, we analyzed the functional interactions of T antigen, RP-A, and DNA polymerase alpha-primase on model single-stranded DNA templates. Purified DNA polymerase alpha-primase was capable of initiating DNA synthesis de novo on unprimed single-stranded DNA templates. This reaction involved the synthesis of a short oligoribonucleotide primer which was then extended into a DNA chain. We observed that the synthesis of ribonucleotide primers by DNA polymerase alpha-primase is dramatically stimulated by SV40 T antigen. The presence of T antigen also increased the average length of the DNA product synthesized on primed and unprimed single-stranded DNA templates. These stimulatory effects of T antigen required direct contact with DNA polymerase alpha-primase complex and were most marked at low template and polymerase concentrations. We also observed that the single-stranded DNA binding protein, RP-A, strongly inhibits the primase activity of DNA polymerase alpha-primase, probably by blocking access of the enzyme to the template. T antigen partially reversed the inhibition caused by RP-A. Our data support a model in which DNA priming is mediated by a complex between T antigen and DNA polymerase alpha-primase with the template, while RP-A acts to suppress nonspecific priming events.     

On the origin of oligomer forms of polyoma DNA

Polyoma virus DNA synthesized in the presence of puromycin or cycloheximide contains an increased proportion of oligomers and molecules having a reduced number of tertiary turns. When doses of inhibitors producing a sub-maximal effect are used, molecules with an anomalous tertiary structure are more frequent among the oligomers than among the monomers. It is suggested that protein synthesis inhibitors modify the balance of factors controlling the topological constraints imposed on replicating molecules. Hence, final closure of the chains upon completion of replication would result in the formation of a mature product with an altered tertiary structure which sometimes fails to segregate into two daughter molecules.     

Preparative production of colominic acid oligomers via a facile microwave hydrolysis

The hydrolysis of colominic acid via microwave irradiation was studied for the production of short-chain oligomers with a degree of polymerization (DP) of 1-5. This method was compared to the traditional acid hydrolytic method for the production of preparative quantities of short colominic acid oligomers. The oligomers were purified by size exclusion chromatography and characterized by ¹H NMR. Optimal conditions for producing the dimer were found to be 12 min at 10% power in a 1000-Watt domestic microwave. This method is advantageous over the traditional technique in that the hydrolysis can be completed in just a few minutes, rather than in a few hours, it is reproducible, and yields large quantities of the desirable short chain oligomers of colominic acid.     

Translating ribosomes inhibit poliovirus negative-strand RNA synthesis

Poliovirus has a single-stranded RNA genome of positive polarity that serves two essential functions at the start of the viral replication cycle in infected cells. First, it is translated to synthesize viral proteins and, second, it is copied by the viral polymerase to synthesize negative-strand RNA. We investigated these two reactions by using HeLa S10 in vitro translation-RNA replication reactions. Preinitiation RNA replication complexes were isolated from these reactions and then used to measure the sequential synthesis of negative- and positive-strand RNAs in the presence of different protein synthesis inhibitors. Puromycin was found to stimulate RNA replication overall. In contrast, RNA replication was inhibited by diphtheria toxin, cycloheximide, anisomycin, and ricin A chain. Dose-response experiments showed that precisely the same concentration of a specific drug was required to inhibit protein synthesis and to either stimulate or inhibit RNA replication. This suggested that the ability of these drugs to affect RNA replication was linked to their ability to alter the normal clearance of translating ribosomes from the input viral RNA. Consistent with this idea was the finding that the protein synthesis inhibitors had no measurable effect on positive-strand synthesis in normal RNA replication complexes. In marked contrast, negative-strand synthesis was stimulated by puromycin and was inhibited by cycloheximide. Puromycin causes polypeptide chain termination and induces the dissociation of polyribosomes from mRNA. Cycloheximide and other inhibitors of polypeptide chain elongation "freeze" ribosomes on mRNA and prevent the normal clearance of ribosomes from viral RNA templates. Therefore, it appears that the poliovirus polymerase was not able to dislodge translating ribosomes from viral RNA templates and mediate the switch from translation to negative-strand synthesis. Instead, the initiation of negative-strand synthesis appears to be coordinately regulated with the natural clearance of translating ribosomes to avoid the dilemma of ribosome-polymerase collisions.     

Mapping the interactions of the single-stranded DNA binding protein of bacteriophage T4 (gp32) with DNA lattices at single nucleotide resolution: gp32 monomer binding

Combining biophysical measurements on T4 bacteriophage replication complexes with detailed structural information can illuminate the molecular mechanisms of these ‘macromolecular machines’. Here we use the low energy circular dichroism (CD) and fluorescent properties of site-specifically introduced base analogues to map and quantify the equilibrium binding interactions of short (8 nts) ssDNA oligomers with gp32 monomers at single nucleotide resolution. We show that single gp32 molecules interact most directly and specifically near the 3′-end of these ssDNA oligomers, thus defining the polarity of gp32 binding with respect to the ssDNA lattice, and that only 2–3 nts are directly involved in this tight binding interaction. The loss of exciton coupling in the CD spectra of dimer 2-AP (2-aminopurine) probes at various positions in the ssDNA constructs, together with increases in fluorescence intensity, suggest that gp32 binding directly extends the sugar-phosphate backbone of this ssDNA oligomer, particularly at the 3′-end and facilitates base unstacking along the entire 8-mer lattice. These results provide a model (and ‘DNA map’) for the isolated gp32 binding to ssDNA targets, which serves as the nucleation step for the cooperative binding that occurs at transiently exposed ssDNA sequences within the functioning T4 DNA replication complex.