Coping with replication 'train wrecks' in Escherichia coli using Pol V, Pol II and RecA proteins.

DNA replication machineries tend to stall when confronted with damaged DNA template sites, causing the biochemical equivalent of a major 'train wreck'. A newly discovered bacterial DNA polymerase, Escherichia coli Pol V, acting in conjunction with the RecA protein, can exchange places with the stalled replicative Pol III core and catalyse 'error-prone' translesion synthesis. In contrast to Pol V-catalysed 'brute-force, sloppier copying', another SOS-induced DNA polymerase, Pol II, plays a pivotal role in an 'error-free', replication-restart DNA repair pathway and probably involves RecA-mediated homologous recombination.

Sloppier copier DNA polymerases involved in genome repair.

When chromosomal replication is impeded in the presence of DNA damage, members of a newly discovered UmuC/DinB/Rev1/Rad30 superfamily of procaryotic and eucaryotic DNA polymerases catalyze translesion synthesis at blocked replication forks. Although these polymerases share sequence elements essentially unrelated to the standard replication and repair enzymes, some of them (such as the SOS-induced Escherichia coli pol V) catalyze 'error-prone' translesion synthesis leading to large increases in mutation, whereas others (an example being the Xeroderma pigmentosum variant gene product XPV pol eta) carry out aberrant, yet nonmutagenic translesion synthesis. Ongoing studies of these low fidelity polymerases could provide new insights into the mechanism of somatic hypermutation, a key element in the immune response.

DNA mismatch repair catalyzed by extracts of mitotic, postmitotic, and senescent Drosophila tissues and involvement of mei-9 gene function for full activity.

Extracts of Drosophila embryos and adults have been found to catalyze highly efficient DNA mismatch repair, as well as repair of 1- and 5-bp loops. For mispairs T.G and G.G, repair is nick dependent and is specific for the nicked strand of heteroduplex DNA. In contrast, repair of A.A, C.A, G.A, C.T, T.T, and C.C is not nick dependent, suggesting the presence of glycosylase activities. For nick-dependent repair, the specific activity of embryo extracts was similar to that of extracts derived from the entirely postmitotic cells of young and senescent adults. Thus, DNA mismatch repair activity is expressed in Drosophila cells during both development and aging, suggesting that there may be a function or requirement for mismatch repair throughout the Drosophila life span. Nick-dependent repair was reduced in extracts of animals mutant for the mei-9 gene. mei-9 has been shown to be required in vivo for certain types of DNA mismatch repair, nucleotide excision repair (NER), and meiotic crossing over and is the Drosophila homolog of the yeast NER gene rad1.

Relevance of 'adaptive' mutations arising in non-dividing cells of microorganisms to age-related changes in mutant phenotypes of neurons.

Brattleboro rats do not produce vasopressin (VP) because of a germ-line single-base deletion (di) that causes a frame shift downstream from the VP sequences and a loss of a stop codon. The resulting frame-shifted peptide precursor does not enter the secretory pathway in hypothalamic neurons, thereby blocking the neurosecretion of VP and other peptides. Yet, from birth onwards, a subpopulation of neurons in di/di rats slowly accumulates revertant cells with a hemizygous wild-type phenotype. Because the rate of reversion during aging is slowed by vasopressin infusion, it is of interest to consider these phenomena in relation to recent observations on 'adaptive' mutations in single cell bacteria and yeast that enable reversion of mutations that blocked cell division under conditions of nutrient deficits. In considering mechanisms that could produce revertant phenotypes in non-dividing cells of both pro- and eukaryotes, we note the pertinence of transcription-coupled repair and SOS 'error-prone' repair.

Differential effect of adriamycin on DNA replicative and repair synthesis in cultured neonatal rat cardiac cells.

The effect of the potent antitumor antiobiotic Adriamycin (ADM) on DNA replication and unscheduled DNA synthesis in cultured rat cardiac cells was investigated. Autoradiography and [3H]thymidine incorporation studies were carried out on parallel cultures. DNA replication was depressed for up to 6 days following a 3-hr pulse of ADM administration. An ADM concentration of 1 microgram/ml which was effective in reducing replicative DNA synthesis by as much as 75% did not reduce the ability of cardiac cells to repair UV-damaged DNA. However, cells exposed to higher ADM concentrations failed to undergo significant UV-induced repair. In the absence of UV treatment, ADM did not stimulate unscheduled DNA synthesis. To account for the differential response of the cardiac cell cultures to replicate and repair DNA, we propose that ADM exerts a localized effect on DNA synthesis covering a region proximal to its primary intercalation site.

Effect of a template-located 2',2'-difluorodeoxycytidine on the kinetics and fidelity of base insertion by Klenow (3'-->5'exonuclease-) fragment.

Gemcitabine [2',2'-difluorodeoxycytidine (dFdCyd)], a potent antitumor agent, inhibits DNA synthesis and is incorporated internally into DNA. The effect of a template-incorporated dFdCyd molecule (dFdCyd-) on DNA polymerase function was examined. Two 25-base deoxyoligonucleotides were synthesized with either a single dFdCyd- or template-incorporated deoxycytidine molecule (dCyd-) at the same position. Each was annealed separately to an identical complementary 5'-32P-labeled primer and extended by the Klenow fragment (3'-->5' exo-) of DNA polymerase I. "Correct" insertion of dGMP was 80-fold less efficient opposite dFdCyd- than dCyd-. A comparison of misinsertion efficiencies opposite template dFdCyd gave values of 2.7 x 10(-2) for dAMP insertion, 1.1 x 10(-3) for dTMP insertion, and 5.9 x 10(-4) for dCMP insertion. A similar measurement opposite template dC gave values of 1.8 x 10(-4), 1.7 x 10(-4), and 2.9 x 10(-6) for dAMP, dTMP, and dCMP insertion, respectively. Thus, the presence of dFdCyd on the template strand inhibited "normal" DNA synthesis and increased deoxyribonucleotide misinsertion frequencies. Pausing during DNA synthesis occurred directly opposite template dFdCyd suggesting that dFdC.dG base pairs might be less stable than normal dC.dG pairs, resulting in a decreased rate of primer extension beyond this site. Consistent with kinetic data, thermal denaturation measurements using comparable surrounding sequences showed that dFdC.dG "correct" pairs were less stable than dC.dG base pairs. Measurements on base mispairs showed that dFdC.dC was more stable than dC.dC, while no measurable Tm differences were found between polymers containing dFdC.dA and dC.dA or dFdC.dT, and dC.dT.

Crystallization of DNA polymerase II from Escherichia coli.

DNA polymerase II of Escherichia coli, an alpha-like or group B polymerase, has been crystallized. The crystals are orthorhombic, space group P2(1)2(1)2, with cell dimensions a = 94.4 A, b = 118.2 A, c = 84.2 A and diffract to at least 3.0 A resolution. This is the first example of a group B polymerase to be crystallized.

Ionized and wobble base-pairing for bromouracil-guanine in equilibrium under physiological conditions. A nuclear magnetic resonance study on an oligonucleotide containing a bromouracil-guanine base-pair as a function of pH.

A one and two-dimensional nuclear magnetic resonance study of a non-selfcomplementary oligonucleotide containing a central 5-bromouracil-guanine pair is reported. For these two bases three types of hydrogen bonding schemes could exist; wobble, rare tautomer and ionized. The two-dimensional spectra of non-exchangeable protons together with one-dimensional spectra recorded in water show that at pH 7.0 the predominant species is a right-handed B-form DNA in which the brU.G pair has wobble geometry. On raising the pH we observe a transition monitored by proton chemical shift changes for the brU.G and adjacent base-pairs. The mid-point of the transition was observed at pH 8.6. Spectra recorded at pH 9.8 show that the helix remains intact with B form conformation. It is shown that this high pH form has an ionized brU.G base-pair now in Watson-Crick geometry. Thus under physiological conditions an equilibrium exists between wobble and ionized structures.

Visualization of two binding sites for the Escherichia coli UmuD'(2)C complex (DNA pol V) on RecA-ssDNA filaments.

The heterotrimeric UmuD'(2)C complex of Escherichia coli has recently been shown to possess intrinsic DNA polymerase activity (DNA pol V) that facilitates error-prone translesion DNA synthesis (SOS mutagenesis). When overexpressed in vivo, UmuD'(2)C also inhibits homologous recombination. In both activities, UmuD'(2)C interacts with RecA nucleoprotein filaments. To examine the biochemical and structural basis of these reactions, we have analyzed the ability of the UmuD'(2)C complex to bind to RecA-ssDNA filaments in vitro. As estimated by a gel retardation assay, binding saturates at a stoichiometry of approximately one complex per two RecA monomers. Visualized by cryo-electron microscopy under these conditions, UmuD'(2)C is seen to bind uniformly along the filaments, such that the complexes are completely submerged in the deep helical groove. This mode of binding would impede access to DNA in a RecA filament, thus explaining the ability of UmuD'(2)C to inhibit homologous recombination. At sub-saturating binding, the distribution of UmuD'(2)C complexes along RecA-ssDNA filaments was characterized by immuno-gold labelling with anti-UmuC antibodies. These data revealed preferential binding at filament ends (most likely, at one end). End-specific binding is consistent with genetic models whereby such binding positions the UmuD'(2)C complex (pol V) appropriately for its role in SOS mutagenesis.

DNA polymerase fidelity: from genetics toward a biochemical understanding.

This review summarizes mutagenesis studies, emphasizing the use of bacteriophage T4 mutator and antimutator strains. Early genetic studies on T4 identified mutator and antimutator variants of DNA polymerase that, in turn, stimulated the development of model systems for the study of DNA polymerase fidelity in vitro. Later enzymatic studies using purified T4 mutator and antimutator polymerases were essential in elucidating mechanisms of base selection and exonuclease proofreading. In both cases, the base analogue 2-aminopurine (2AP) proved tremendously useful-first as a mutagen in vivo and then as a probe of DNA polymerase fidelity in vitro. Investigations into mechanisms of DNA polymerase fidelity inspired theoretical models that, in turn, called for kinetic and thermodynamic analyses. Thus, the field of DNA synthesis fidelity has grown from many directions: genetics, enzymology, kinetics, physical biochemistry, and thermodynamics, and today the interplay continues. The relative contributions of hydrogen bonding and base stacking to the accuracy of DNA synthesis are beginning to be deciphered. For the future, the main challenges lie in understanding the origins of mutational hot and cold spots.

A sticker-based model for DNA computation.

We introduce a new model of molecular computation that we call the sticker model. Like many previous proposals it makes use of DNA strands as the physical substrate in which information is represented and of separation by hybridization as a central mechanism. However, unlike previous models, the stickers model has a random access memory that requires no strand extension and uses no enzymes; also (at least in theory), its materials are reusable. The paper describes computation under the stickers model and discusses possible means for physically implementing each operation. Finally, we go on to propose a specific machine architecture for implementing the stickers model as a microprocessor-controlled parallel robotic workstation. In the course of this development a number of previous general concerns about molecular computation (Smith, 1996; Hartmanis, 1995; Linial et al., 1995) are addressed. First, it is clear that general-purpose algorithms can be implemented by DNA-based computers, potentially solving a wide class of search problems. Second, we find that there are challenging problems, for which only modest volumes of DNA should suffice. Third, we demonstrate that the formation and breaking of covalent bonds is not intrinsic to DNA-based computation. Fourth, we show that a single essential biotechnology, sequence-specific separation, suffices for constructing a general-purpose molecular computer. Concerns about errors in this separation operation and means to reduce them are addressed elsewhere (Karp et al., 1995; Roweis and Winfree, 1999). Despite these encouraging theoretical advances, we emphasize that substantial engineering challenges remain at almost all stages and that the ultimate success or failure of DNA computing will certainly depend on whether these challenges can be met in laboratory investigations.

Nucleotide insertion and primer extension at abasic template sites in different sequence contexts.

Efficiencies of insertion and extension at a single site-directed abasic lesion, X, were measured while varying 5'- and 3'-template bases adjacent to X. The preference for insertion was found to be A > G > T approximately C, with the "upstream" (3'-neighboring) template base perturbing insertion efficiencies by an order of magnitude or more. Efficiencies of synthesis past the abasic lesion depended strongly on the "downstream" (5'-neighboring) template base and on the properties of the polymerase. HIV-1 RT favored "direct" extension of X.A > X.G > X.T > X.C, by addition of the next correct nucleotide. However, it was found that X.C, least favored for direct extension, was most favored for "misalignment" extension, occurring when the DNA structure in the vicinity of the lesion collapsed to realign a primer 3'-C terminus opposite a downstream template G site. Polymerase properties have an important role in copying abasic lesions. Drosophila DNA polymerase alpha, HIV-1, and AMV reverse transcriptases had "little" difficulty inserting opposite abasic lesions, with efficiencies comparable to misinsertions opposite normal template bases. However, AMV RT did not extent past the lesion using direct or misalignment mechanisms. Wild-type and mutant T4 DNA polymerases were used to show that although exonucleolytic proofreading inhibits lesion bypass, the presence of a highly active proofreading exonuclease is not sufficient to prevent bypass.

Structural and dynamic properties of a bromouracil-adenine base pair in DNA studied by proton NMR.

We have synthesized and studied by proton NMR a duplex heptaoligonucleotide containing a 5-bromouracil (brU)-adenine base pair. This represents the first structural characterization of a B-form DNA containing brU. The brU.A base pair is Watson-Crick rather than Hoogsteen as seen for the monomers in the crystalline state. From analysis of the NOESY sepctra at very short mixing times evidence is presented that substitution of brU for T induces significant conformational changes from that of a normal B DNA. The helix twist between brU4.A11 and G3.C12 is ca. 15 degrees and for both brU4 and G3 the glycosyl torsion angles are significantly changed. The imino proton of the bru.A base pair shows a pH insensitive line with which shows that the pK of brU in this base pair is very much higher than that of the monomer.

DNA replication fidelity: kinetics and thermodynamics.

Mechanisms that control the fidelity of DNA replication are discussed. Data are reviewed for 3 steps in a fidelity pathway: nucleotide insertion, exonucleolytic proofreading, and extension from matched and mismatched 3'-primer termini. Fidelity mechanisms that involve predominantly Km discrimination, Vmax discrimination, or a combination of the two are analyzed in the context of a simple model for fidelity. Each fidelity step is divided into 2 components, thermodynamic and kinetic. The thermodynamic component, which relates to free-energy differences between right and wrong base pairs, is associated with a Km discrimination mechanism for polymerase. The kinetic component, which represents the enzyme's ability to select bases for insertion and excision to achieve fidelity greater than that available from base pairing free-energy differences, is associated with a Vmax discrimination mechanism for polymerase. Currently available fidelity data for nucleotide insertion and primer extension in the absence of proofreading appears to have relatively large Km and small Vmax components. An important complication can arise when analyzing data from polymerases containing an associated 3'-exonuclease activity. In the presence of proofreading, a Vmax discrimination mechanism is likely to occur, but this may be the result of two Km discrimination mechanisms acting serially, one for nucleotide insertion and the other for excision. Possible relationships between base pairing free energy differences measured in aqueous solution and those defined within the polymerase active cleft are considered in the context of the enzyme's ability to exclude water, at least partially, from the vicinity of its active site.