Escherichia coli MutY and Fpg utilize a processive mechanism for target location

MutY and formamidopyrimidine-DNA-glycosylase (Fpg) are base-excision repair (BER) enzymes involved in the 8-oxoguanine repair pathway in Escherichia coli. An impressive feature of these enzymes is the ability to locate 8-oxoguanine lesions among a large excess of undamaged DNA. To provide insight into the mechanism of target location, the ability of these enzyme to utilize a one-dimensional processive search (DNA sliding) or distributive (random diffusion-mediated) mechanism was investigated. Each enzyme was incubated with double-stranded concatemeric polynucleotides containing a site-specific target site at 25-nucleotide (nt) intervals. The products of each reaction were analyzed after further treatment and denaturation. A rapid accumulation of predominantly 25-nt fragments would indicate the utilization of a processive mechanism, whereas oligomeric multiples of 25-nt fragments would form if a distributive mechanism were used. Both Fpg and MutY were found to function processively on concatemers containing 7,8-dihydro-8-oxo-2'-deoxyguanosine (OG).C and G.A mispairs, respectively. An increase in sodium chloride concentration results in the modulation from a processive to distributive mechanism for both enzymes. Interestingly, processive behavior was not observed in the reaction of MutY with concatemers containing OG.A mispairs. A truncated form of MutY (Stop 225) containing only the N-terminal domain was found to behave in a manner consistent with a processive mechanism with both OG.A- and G.A-containing substrates. This suggests that the C-terminal domain of MutY plays an important role in the mechanism by which the enzyme detects OG.A base pairs in DNA.     

Step-wise DNA relaxation and decatenation by NaeI-43K.

Nae I protein was originally isolated for its restriction endonuclease properties. Nae I was later discovered to either relax or cleave supercoiled DNA, depending upon whether Nae I position 43 contains a lysine (43K) or leucine (43L) respectively. Nae I-43K DNA relaxation activity appears to be the product of coupling separate endonuclease and ligase domains within the same polypeptide. Whereas Nae I relaxes supercoiled DNA like a topoisomerase, even forming a transient covalent intermediate with the substrate DNA, Nae I shows no obvious sequence similarity to the topoisomerases. To further characterize the topoisomerase activity of Nae I, we report here that Nae I-43K changes the linking number of a single negatively supercoiled topoisomer of pBR322 by units of one and therefore is a type I topoisomerase. Positively supercoiled pBR322 was resistant to Nae I-43K. At low salt concentration Nae I-43K was processive; non-saturating amounts of enzyme relaxed a fraction of the DNA. At high salt concentration the same non-saturating amounts of Nae I-43K partially relaxed all the DNA in a step-wise fashion to give a Gaussian distribution of topoisomers, demonstrating a switch from a processive to a distributive mode of action. Nae I-43K decatenated kinetoplast DNA containing nicked circles, implying that Nae I-43K can cleave opposite a nick. The products of the reaction are decatenated nicked circles under both processive and distributive conditions. The behavior of Nae I-43K is consistent with that of a prokaryotic type I topoisomerase.     

ClpP hydrolyzes a protein substrate processively in the absence of the ClpA ATPase: mechanistic studies of ATP-independent proteolysis

ATP-dependent proteases are processive, meaning that they degrade full-length proteins into small peptide products without releasing large intermediates along the reaction pathway. In the case of the bacterial ATP-dependent protease ClpAP, ATP hydrolysis by the ClpA component has been proposed to be required for processive proteolysis of full-length protein substrates. We present here data showing that in the absence of the ATPase subunit ClpA, the protease subunit ClpP can degrade full-length protein substrates processively, albeit at a greatly reduced rate. Moreover, the size distribution of peptide products from a ClpP-catalyzed digest is remarkably similar to the size distribution of products from a ClpAP-catalyzed digest. The ClpAP- and ClpP-generated peptide product size distributions are fitted well by a sum of multiple underlying Gaussian peaks with means at integral multiples of approximately 900 Da (7-8 amino acids). Our results are consistent with a mechanism in which ClpP controls product sizes by alternating between translocation in steps of 7-8 (+/-2-3) amino acid residues and proteolysis. On the structural and molecular level, the step size may be controlled by the spacing between the ClpP active sites, and processivity may be achieved by coupling peptide bond hydrolysis to the binding and release of substrate and products in the protease chamber.     

Hyaluronic acid: structure of a fully extended 3-fold helical sodium salt and comparison with the less extended 4-fold helical forms.

The consequences of enzyme and template interaction were examined by several independent methods in the replication reactions catalyzed by calf thymus low molecular weight DNA polymerase, calf thymus high molecular weight DNA polymerase, and Eacherichia coli polymerase I. All methods used support a distributive, rather than processive, mechanism for enzyme in the replication of homopolymer templates in vitro. First, addition of an excess of initiated poly(dC) template to an ongoing poly(dA) replication reaction results in immediate cessation of dTTP polymerization. Second, the kinetics of monomer and initiator incorporation in reactions where a large number of initiated template molecules are available to each enzyme molecule show early incorporation of all initiators followed by simultaneous replication of the total population of template molecules. Third, alkaline sucrose gradient analysis of the products formed at various stages during replication show simultaneous growth in product chain lengths. Fourth, analysis of products formed when an average of one to two nucleotides are added at the end of the growing chain, in reactions having a molecular ratio of template to enzyme of about 900, show that the enzyme can dissociate from the replicating template after a single addition. Increasing the ionic strength of the reaction mixture, to decrease the secondary interactions between the enzyme and the template, results in nearly random interaction of the enzyme and the template. The results from this study suggest that translocation of template chain during replication is not an obligatory function of purified DNA polymerases. The possible involvement of other proteins required for DNA replication in vivo in the interaction of DNA polymerase and DNA is discussed.     

Enzymatic activity of alkaline phosphatase inside protein and polymer structures fabricated via multiphoton excitation

We demonstrate micron scale control of bioactivity through the use of multiphoton excited photochemistry, where this technique has been used to cross-link three-dimensional matrixes of alkaline phosphatase, bovine serum albumin, and polyacrylamide and combinations therein. Using a fluorescence-based assay (ELF-97), the enzymatic activity has been studied using a Michaelis-Menten analysis, and we have measured the specificity constants kcat/KM for alkaline phosphatase in both the protein and polymer matrixes to be on the order of 10(5)-10(6) M(-1) s(-1)and are comparable to known literature values in other environments. It is found that the enzyme is simply entrapped in the polymer matrix, whereas it is completely covalently bound in the protein structures. The relative reaction rate of alkaline phosphatase bound to BSA with the ELF substrate was measured as a function of cross-link density and was found to decrease in the more tightly formed matrixes, indicating a decrease in the diffusion in the matrix.     

The DNA scanning mechanism of T4 endonuclease V. Effect of NaCl concentration on processive nicking activity

T4 endonuclease V is a pyrimidine dimer-specific endonuclease which generates incisions in DNA at the sites of pyrimidine dimers by a processive reaction mechanism. A model is presented in which the degree of processivity is directly related to the efficacy of the one-dimensional diffusion of endonuclease V on DNA by which the enzyme locates pyrimidine dimers. The modulation of the processive nicking activity of T4 endonuclease V on superhelical covalently closed circular DNA (form I) which contains pyrimidine dimers has been investigated as a function of the ionic strength of the reaction. Agarose gel electrophoresis was used to separate the three topological forms of the DNA which were generated in time course reactions of endonuclease V with dimer-containing form I DNA in the absence of NaCl, and in 25, 50, and 100 mM NaCl. The degree of processivity was evaluated in terms of the mass fraction of form III (linear) DNA which was produced as a function of the fraction of form I DNA remaining. Processivity is maximal in the absence of NaCl and decreases as the NaCl concentration is increased. At 100 mM NaCl, processivity is abolished and endonuclease V generates incisions in DNA at the site of dimers by a distributive reaction mechanism. The change from the distributive to a processive reaction mechanism occurs at NaCl concentrations slightly below 50 mM. The high degree of processivity which is observed in the absence of NaCl is reversible to the distributive mechanism, as demonstrated by experiments in which the NaCl concentration was increased during the time course reaction. In addition, unirradiated DNA inhibited the incision of irradiated DNA only at NaCl concentrations at which processivity was observed.     

Predicting knot and catenane type of products of site-specific recombination on twist knot substrates

Site-specific recombination on supercoiled circular DNA molecules can yield a variety of knots and catenanes. Twist knots are some of the most common conformations of these products, and they can act as substrates for further rounds of site-specific recombination. They are also one of the simplest families of knots and catenanes. Yet, our systematic understanding of their implication in DNA and important cellular processes such as site-specific recombination is very limited. Here, we present a topological model of site-specific recombination characterizing all possible products of this reaction on twist knot substrates, extending the previous work of Buck and Flapan. We illustrate how to use our model to examine previously uncharacterized experimental data. We also show how our model can help determine the sequence of products in multiple rounds of processive recombination and distinguish between products of processive and distributive recombinations.This model studies generic site-specific recombination on arbitrary twist knot substrates, a subject for which there is limited global understanding. We also provide a systematic method of applying our model to a variety of different recombination systems.     

The efficiency and fidelity of translesion synthesis past cisplatin and oxaliplatin GpG adducts by human DNA polymerase beta

DNA polymerase beta (pol beta) is the only mammalian DNA polymerase identified to date that can catalyze extensive bypass of platinum-DNA adducts in vitro. Previous studies suggest that DNA synthesis by pol beta is distributive on primed single-stranded DNA and processive on gapped DNA. The data presented in this paper provide an analysis of translesion synthesis past cisplatin- and oxaliplatin-DNA adducts by pol beta functioning in both distributive and processive modes using primer extension and steady-state kinetic experiments. Translesion synthesis past Pt-DNA adducts was greater with gapped DNA templates than with single-stranded DNA templates. In the processive mode pol beta did not discriminate between cisplatin and oxaliplatin adducts, while in the distributive mode it displayed about 2-fold increased ability for translesion synthesis past oxaliplatin compared with cisplatin adducts. The differentiation between cisplatin and oxaliplatin adducts resulted from a K(m)-mediated increase in the efficiency of dCTP incorporation across from the 3'-G of oxaliplatin-GG adducts. Rates of misincorporation across platinated guanines determined by the steady-state kinetic assay were higher in reactions with primed single-stranded templates than with gapped DNA and a slight increase in the misincorporation of dTTP across from the 3'-G was found for oxaliplatin compared with cisplatin adducts.     

Elucidating the in vivo phosphorylation dynamics of the ERK MAP kinase using quantitative proteomics data and Bayesian model selection

Ever since reversible protein phosphorylation was discovered, it has been clear that it plays a key role in the regulation of cellular processes. Proteins often undergo double phosphorylation, which can occur through two possible mechanisms: distributive or processive. Which phosphorylation mechanism is chosen for a particular cellular regulation bears biological significance, and it is therefore in our interest to understand these mechanisms. In this paper we study dynamics of the MEK/ERK phosphorylation. We employ a model selection algorithm based on approximate Bayesian computation to elucidate phosphorylation dynamics from quantitative time course data obtained from PC12 cells in vivo. The algorithm infers the posterior distribution over four proposed models for phosphorylation and dephosphorylation dynamics, and this distribution indicates the amount of support given to each model. We evaluate the robustness of our inferential framework by systematically exploring different ways of parameterizing the models and for different prior specifications. The models with the highest inferred posterior probability are the two models employing distributive dephosphorylation, whereas we are unable to choose decisively between the processive and distributive phosphorylation mechanisms.     

Mechanism of U Insertion RNA Editing in Trypanosome Mitochondria: The Bimodal TUTase Activity of the Core Complex

Expression of the trypanosomal mitochondrial genome requires the insertion and deletion of uridylyl residues at specific sites in pre-mRNAs. RET2 terminal uridylyl transferase is an integral component of the RNA editing core complex (RECC) and is responsible for the guide-RNA-dependent U insertion reaction. By analyzing RNA-interference-based knock-in Trypanosoma brucei cell lines, purified editing complex, and individual protein, we have investigated RET2's association with the RECC. In addition, the U insertion activity exhibited by RET2 as an RECC subunit was compared with characteristics of the monomeric protein. We show that interaction of RET2 with RECC is accomplished via a protein-protein contact between its middle domain and a structural subunit, MP81. The recombinant RET2 catalyzes a faithful editing on gapped (precleaved) double-stranded RNA substrates, and this reaction requires an internal monophosphate group at the 5′ end of the mRNA 3′ cleavage fragment. However, RET2 processivity is limited to insertion of three Us. Incorporation into the RECC voids the internal phosphate requirement and allows filling of longer gaps similar to those observed in vivo. Remarkably, monomeric and RECC-embedded enzymes display a similar bimodal activity: the distributive insertion of a single uracil is followed by a processive extension limited by the number of guiding nucleotides. Based on the RNA substrate specificity of RET2 and the purine-rich nature of U insertion sites, we propose that the distributive + 1 insertion creates a substrate for the processive gap-filling reaction. Upon base-pairing of the + 1 extended 5′ cleavage fragment with a guiding nucleotide, this substrate is recognized by RET2 in a different mode compared to the product of the initial nucleolytic cleavage. Therefore, RET2 distinguishes base pairs in gapped RNA substrates which may constitute an additional checkpoint contributing to overall fidelity of the editing process.     

Molecular analysis of plasmid DNA repair within ultraviolet-irradiated Escherichia coli. I. T4 endonuclease V-initiated excision repair

The process by which DNA-interactive proteins locate specific sequences or target sites on cellular DNA within Escherichia coli is a poorly understood phenomenon. In this study, we present the first direct in vivo analysis of the interaction of a DNA repair enzyme, T4 endonuclease V, and its substrate, pyrimidine dimer-containing plasmid DNA, within UV-irradiated E. coli. A pyrimidine dimer represents a small target site within large domains of DNA. There are two possible paradigms by which endonuclease V could locate these small target sites: a processive mechanism in which the enzyme "scans" DNA for dimer sites or a distributive process in which dimers are located by random three-dimensional diffusion. In order to discriminate between these two possibilities in E. coli, an in vivo DNA repair assay was developed to study the kinetics of plasmid DNA repair and the dimer frequency (i.e. the number of dimer sites on a given plasmid molecule) in plasmid DNA as a function of time during repair. Our results demonstrate that the overall process of plasmid DNA repair initiated by T4 endonuclease V (expressed from a recombinant plasmid within repair-deficient E. coli) occurs by a processive mechanism. Furthermore, by reducing the temperature of the repair incubation, the endonuclease V-catalyzed incision step has been effectively decoupled from the subsequent steps including repair patch synthesis, ligation, and supercoiling. By this manipulation, it was determined that the overall processive mechanism is composed of two phases: a rapid processive endonuclease V-catalyzed incision reaction, followed by a slower processive mechanism, the ultimate product of which is the dimer-free supercoiled plasmid molecule.     

A kinetic study of human protein arginine N-methyltransferase 6 reveals a distributive mechanism

Human protein arginine N-methyltransferase 6 (PRMT6) transfers methyl groups from the co-substrate S-adenosyl-L-methionine to arginine residues within proteins, forming S-adenosyl-L-homocysteine as well as omega-N(G)-monomethylarginine (MMA) and asymmetric dimethylarginine (aDMA) residues in the process. We have characterized the kinetic mechanism of recombinant His-tagged PRMT6 using a mass spectrometry method for monitoring the methylation of a series of peptides bearing a single arginine, MMA, or aDMA residue. We find that PRMT6 follows an ordered sequential mechanism in which S-adenosyl-L-methionine binds to the enzyme first and the methylated product is the first to dissociate. Furthermore, we find that the enzyme displays a preference for the monomethylated peptide substrate, exhibiting both lower K(m) and higher V(max) values than what are observed for the unmethylated peptide. This difference in substrate K(m) and V(max), as well as the lack of detectable aDMA-containing product from the unmethylated substrate, suggest a distributive rather than processive mechanism for multiple methylations of a single arginine residue. In addition, we speculate that the increased catalytic efficiency of PRMT6 for methylated substrates combined with lower K(m) values for native protein methyl acceptors may obscure this distributive mechanism to produce an apparently processive mechanism.     

Mammalian proliferating cell nuclear antigen stimulates the processivity of two wheat embryo DNA polymerases.

Multiple DNA polymerases have been described in all organisms studied to date. Their specific functions are not easy to determine, except when powerful genetic and/or biochemical tools are available. However, the processivity of a DNA polymerase could reflect the physiological role of the enzyme. In this study, analogies between plant and animal DNA polymerases have been investigated by analyzing the size of the products synthesized by wheat DNA polymerases A, B, CI, and CII as a measure of their processivity. Thus, incubations have been carried out with poly(dA)-oligo(dT) as a template-primer under varying assay conditions. In the presence of MgCl2, DNA polymerase A was highly processive, whereas DNA polymerases B, CI, and CII synthesized much shorter products. With MnCl2 instead of MgCl2, DNA polymerase A was highly processive, DNA polymerases B and CII were moderately processive, and DNA polymerase CI remained strictly distributive. The effect of calf thymus proliferating cell nuclear antigen (PCNA) on wheat polymerases was studied as described for animal DNA polymerases. The high processivity of DNA polymerase A was PCNA independent, whereas both enzyme activity and processivity of wheat DNA polymerases B and CII were significantly stimulated by PCNA. On the other hand, DNA polymerase CI was not stimulated by PCNA and, like animal DNA polymerase beta, was distributive in all cases. From these results, we propose that wheat DNA polymerase A could correspond to a DNA polymerase alpha, DNA polymerases B and CII could correspond to the delta-like enzyme, and DNA polymerase CI could correspond to DNA polymerase beta.     

Kinetics of ATP-stimulated nuclease activity of the Escherichia coli RecBCD enzyme

The RecBCD enzyme is an ATP-dependent nuclease on both single-stranded and double-stranded DNA substrates. We have investigated the kinetics of the RecBCD-catalyzed reaction with small, single-stranded oligodeoxyribonucleotide substrates under single-turnover conditions using rapid-quench flow techniques. RecBCD-DNA complexes were allowed to form in pre-incubation mixtures. The nuclease reactions were initiated by mixing with ATP. The reaction time-courses were fit to several possible reaction mechanisms and quantitative estimates were obtained for rate constants for individual reaction steps. The relative rates of forward reaction versus dissociation from the DNA, and the fact that inclusion of excess non-radiolabeled single-stranded DNA to trap free RecBCD has no effect on the nuclease reaction, indicates that the reaction is processive. The reaction products show that the reaction begins near the 3'-end of the [5'-32P]DNA substrates and the major cleavage sites are two to four phosphodiester bonds apart. The product distribution is unchanged as the ATP concentration varies from 10 microM to 100 microM ATP, while the overall reaction rate varies by about tenfold. These observations suggest that DNA cleavage is tightly coordinated with movement of the enzyme along the DNA. The reaction time-courses at low concentrations of ATP (10 microM and 25 microM) have a significant lag before cleavage products appear. We propose that the lag represents ATP-dependent movement of the DNA from an initial binding site in the helicase domain of the RecB subunit to the nuclease active site in a separate domain of RecB. The extent of reaction of the substrate is limited (approximately 50%) under all conditions. This may indicate the formation of a non-productive RecBCD-DNA complex that does not dissociate in the 1-2 s time-scale of our experiments.     

Single-molecule analysis reveals three phases of DNA degradation by an exonuclease

λ exonuclease degrades one strand of duplex DNA in the 5'-to-3' direction to generate a 3' overhang required for recombination. Its ability to hydrolyze thousands of nucleotides processively is attributed to its ring structure, and most studies have focused on the processive phase. Here we have used single-molecule fluorescence resonance energy transfer (FRET) to reveal three phases of λ exonuclease reactions: the initiation, distributive and processive phases. The distributive phase comprises early reactions in which the 3' overhang is too short to stably engage with the enzyme. A mismatched base is digested one-fifth as quickly as a Watson-Crick-paired base, and multiple concatenated mismatches have a cooperatively negative effect, highlighting the crucial role of base pairing in aligning the 5' end toward the active site. The rate-limiting step during processive degradation seems to be the post-cleavage melting of the terminal base pair. We also found that an escape from a known pausing sequence requires enzyme backtracking.     

Kinetic Analysis of the Three-step Steroid Aromatase Reaction of Human Cytochrome P450 19A1

Cytochrome P450 19A1 (P450 19A1), the aromatase, catalyzes the conversion of androgens to estrogens through a sequential three-step reaction, generating 19-hydroxy and 19-aldehyde intermediates en route to the product estrogen. A procedure for the heterologous expression and purification of P450 19A1 in Escherichia coli was developed (k_cat of 0.06 s⁻¹ for the conversion of androstenedione to estrone). Binding of the substrate and intermediates show low micromolar dissociation constants and are at least two-step processes. Rates of reduction of the iron were fast in the presence of substrate, either intermediate, or product. P450 19A1 is a distributive rather than a processive enzyme, with the sequential reaction allowing free dissociation of the intermediates as revealed by pulse-chase experiments. Conversion of androstenedione to estrone (under single turnover conditions) generated a progress curve showing changes in the concentrations of the substrate, intermediates, and product. A minimal kinetic model containing the individual rate constants for the steps in P450 19A1 catalysis was developed to globally fit the time course of the overall reaction, the dissociation constants, the two-step ligand binding, the distributive character, the iron-reduction rates, and the steady-state conversion of the 19-hydroxy androstenedione and 19-aldehyde androstenedione intermediates to estrone.     

Most-probable distribution at enzyme depolymerization of polysaccharides

Several research groups have studied depolymerizing processes by enzyme cleavage using product distribution. Although only the shortest chain products can be measured experimentally, interpretation of much evidence requires an assumption of the nature of high polymer distribution. The present work analyzes the high polymer distribution of products on the basis of mathematical models suggested for the two most widespread α-amylase action-mechanisms. The most-probable distribution was found to be distorted by hydrolysis only for the shortest chain products. The size of the distorted region is directly dependent on the characteristics of a specific enzyme. We studied the distribution of products for substrates of varying composition to show that it approaches the most-probable distribution at depolymerization.     

A real-time DNase assay (ReDA) based on PicoGreen fluorescence

DNA nucleases (DNases) perform a wide variety of important cellular functions and are also very useful for research and in biotechnological applications. Due to the biological and technological importance of DNases and their use in a wide range of applications, DNase activity assays are essential. Traditional DNase assays employ radiolabeled DNA substrates and require separation of the products of the reaction from the unreacted substrate before quantification of enzyme activity. As a consequence, these methods are discontinuous. In this report, we describe a continuous DNase assay based on the differential fluorescence output of a DNA dye ligand called PicoGreen. The assay was developed to characterize a processive dsDNA exonuclease, lambda exonuclease. The assay appears to have general utility as it is also suitable for measuring the DNA digestion activities of a processive helicase/nuclease, RecBCD, a distributive exonuclease, T7 gene 6 exonuclease, and an endonuclease, DNaseI. The benefits of, and limitations to, the method are discussed.