Kinetics and effect of salts and polyamines on T4 polynucleotide ligase

Transient co-assemblies of micron-scale colloids regulated by ATP-fueled reaction networks

Self-assembly of colloidal particles offers an attractive bottom-up approach to functional materials. Current design strategies for colloidal assemblies are mostly based on thermodynamically controlled principles and lack autonomous behavior. The next advance in the properties of colloidal assemblies will come from coupling these structures to out-of-equilibrium chemical reaction networks furnishing them with autonomous and dynamic behavior. This, however, constitutes a major challenge of carefully modulating the interparticle potentials on a temporal circuit program and avoiding kinetic trapping and irreversible aggregation. Herein, we report the coupling of a fuel-driven DNA-based enzymatic reaction network (ERN) to micron-sized colloidal particles to achieve their transient co-assembly. The ERN operating on the molecular level transiently releases an Output strand which links two DNA functionalized microgel particles together into co-assemblies with a programmable assembly lifetime. The system generates minimal waste and recovers all components of the ERN after the consumption of the ATP fuel. The system can be reactivated by addition of new fuel as shown for up to three cycles. The design can be applied to organize other building blocks into hierarchical structures and materials with advanced biomimetic properties.

Good cop, bad cop: Polyamines play both sides in host immunity and viral replication

Viruses rely on host cells for energy and synthesis machinery required for genome replication and particle assembly. Due to the dependence of viruses on host cells, viruses have evolved multiple mechanisms by which they can induce metabolic changes in the host cell to suit their specific requirements. The host immune response also involves metabolic changes to be able to react to viral insult. Polyamines are small ubiquitously expressed polycations, and their metabolism is critical for viral replication and an adequate host immune response. This is due to the variety of functions that polyamines have, ranging from condensing DNA to enhancing the translation of polyproline-containing proteins through the hypusination of eIF5A. Here, we review the diverse mechanisms by which viruses exploit polyamines, as well as the mechanisms by which immune cells utilize polyamines for their functions. Furthermore, we highlight potential avenues for further study of the host-virus interface.

Investigation of the Basic Steps in the Chromosome Conformation Capture Procedure

A constellation of chromosome conformation capture methods (С-methods) are an important tool for biochemical analysis of the spatial interactions between DNA regions that are separated in the primary sequence. All these methods are based on the long sequence of basic steps of treating cells, nuclei, chromatin, and finally DNA, thus representing a significant technical challenge. Here, we present an in-depth study of the basic steps in the chromatin conformation capture procedure (3С), which was performed using Drosophila Schneider 2 cells as a model. We investigated the steps of cell lysis, nuclei washing, nucleoplasm extraction, chromatin treatment with SDS/Triton X-100, restriction enzyme digestion, chromatin ligation, reversion of cross-links, DNA extraction, treatment of a 3C library with RNases, and purification of the 3C library. Several options were studied, and optimal conditions were found. Our work contributes to the understanding of the 3C basic steps and provides a useful guide to the 3C procedure.

Isothermal cross-boosting extension–nicking reaction mediated exponential signal amplification for ultrasensitive detection of polynucleotide kinase

A novel nucleic acid-based isothermal signal amplification strategy, named cross-boosting extension–nicking reaction (CBENR) is developed and successfully used for rapid and ultrasensitive detection of polynucleotide kinase (PNK) activity.

Making Engineered 3D DNA Crystals Robust

Engineered 3D DNA crystals are promising scaffolds for bottom-up construction of three-dimensional, macroscopic devices from the molecular level. Nevertheless, this has been hindered by the highly constrained conditions for DNA crystals to be stable. Here we report a method to prepare robust 3D DNA crystals by postassembly ligation to remove this constraint. Specifically, sticky ends at crystal contacts were enzymatically ligated, and the covalent bonds significantly enhanced crystal stability, e.g., being stable at 65 °C. This method also enabled the fabrication of DNA crystals with complex architectures including crystal shell, core-shell, and matryoshka dolls. Furthermore, we have demonstrated the applications of the robust DNA crystals in biocatalysis and protein entrapment. Our study removes one key obstacle for the applications of DNA crystals and offers many new opportunities in DNA nanotechnology.

Ligation and Ligases

DNA ligases are used chiefly to create novel combinations of nucleic acid molecules and to attach them to vectors before molecular cloning. They are either of bacterial origin or bacteriophage encoded and have different properties, as discussed here.

Modeling bias and variation in the stochastic processes of small RNA sequencing

The use of RNA-seq as the preferred method for the discovery and validation of small RNA biomarkers has been hindered by high quantitative variability and biased sequence counts. In this paper we develop a statistical model for sequence counts that accounts for ligase bias and stochastic variation in sequence counts. This model implies a linear quadratic relation between the mean and variance of sequence counts. Using a large number of sequencing datasets, we demonstrate how one can use the generalized additive models for location, scale and shape (GAMLSS) distributional regression framework to calculate and apply empirical correction factors for ligase bias. Bias correction could remove more than 40% of the bias for miRNAs. Empirical bias correction factors appear to be nearly constant over at least one and up to four orders of magnitude of total RNA input and independent of sample composition. Using synthetic mixes of known composition, we show that the GAMLSS approach can analyze differential expression with greater accuracy, higher sensitivity and specificity than six existing algorithms (DESeq2, edgeR, EBSeq, limma, DSS, voom) for the analysis of small RNA-seq data.

Rapid Time Scale Analysis of T4 DNA Ligase-DNA Binding

DNA ligases, essential to both in vivo genome integrity and in vitro molecular biology, catalyze phosphodiester bond formation between adjacent 3'-OH and 5'-phosphorylated termini in dsDNA. This reaction requires enzyme self-adenylylation, using ATP or NAD⁺ as a cofactor, and AMP release concomitant with phosphodiester bond formation. In this study, we present the first fast time scale binding kinetics of T4 DNA ligase to both nicked substrate DNA (nDNA) and product-equivalent non-nicked dsDNA, as well as binding and release kinetics of AMP. The described assays utilized a fluorescein-dT labeled DNA substrate as a reporter for ligase·DNA interactions via stopped-flow fluorescence spectroscopy. The analysis revealed that binding to nDNA by the active adenylylated ligase occurs in two steps, an initial rapid association equilibrium followed by a transition to a second bound state prior to catalysis. Furthermore, the ligase binds and dissociates from nicked and nonsubstrate dsDNA rapidly with initial association affinities on the order of 100 nM regardless of enzyme adenylylation state. DNA binding occurs through a two-step mechanism in all cases, confirming prior proposals of transient binding followed by a transition to a productive ligase·nDNA (Lig·nDNA) conformation but suggesting that weaker nonproductive "closed" complexes are formed as well. These observations demonstrate the mechanistic underpinnings of competitive inhibition by rapid binding of nonsubstrate DNA, and of substrate inhibition by blocking of the self-adenylylation reaction through nick binding by deadenylylated ligase. Our analysis further reveals that product release is not the rate-determining step in turnover.

Kinetics of T3-DNA Ligase-Catalyzed Phosphodiester Bond Formation Measured Using the α-Hemolysin Nanopore

The latch region of the wild-type α-hemolysin (α-HL) protein channel can be used to distinguish single base modifications in double-stranded DNA (dsDNA) via ion channel measurements upon electrophoretic capture of dsDNA in the vestibule of α-HL. Herein, we investigated the use of the latch region to detect a nick in the phosphodiester DNA backbone. The presence of a nick in the phosphodiester backbone of one strand of the duplex results in a significant increase in both the blockade current and noise level relative to the intact duplex. Differentiation between the nicked and intact duplexes based on blockade current or noise, with near baseline resolution, allows real-time monitoring of the rate of T3-DNA ligase-catalyzed phosphodiester bond formation. Under low ionic strength conditions containing divalent cations and a molecular crowding agent (75 mg mL^-1 PEG), the rate of enzyme-catalyzed reaction in the bulk solution was continuously monitored by electrophoretically capturing reaction substrate or product dsDNA in the α-HL protein channel vestibule. Enzyme kinetic results obtained from the nanopore experiments match those from gel electrophoresis under the same reaction conditions, indicating the α-HL nanopore measurement provides a viable approach for monitoring enzymatic DNA repair activity.

The Inhibitory Effect of Non-Substrate and Substrate DNA on the Ligation and Self-Adenylylation Reactions Catalyzed by T4 DNA Ligase

DNA ligases are essential both to in vivo replication, repair and recombination processes, and in vitro molecular biology protocols. Prior characterization of DNA ligases through gel shift assays has shown the presence of a nick site to be essential for tight binding between the enzyme and its dsDNA substrate, with no interaction evident on dsDNA lacking a nick. In the current study, we observed a significant substrate inhibition effect, as well as the inhibition of both the self-adenylylation and nick-sealing steps of T4 DNA ligase by non-nicked, non-substrate dsDNA. Inhibition by non-substrate DNA was dependent only on the total DNA concentration rather than the structure; with 1 μg/mL of 40-mers, 75-mers, or circular plasmid DNA all inhibiting ligation equally. A >15-fold reduction in T4 DNA ligase self-adenylylation rate when in the presence of high non-nicked dsDNA concentrations was observed. Finally, EMSAs were utilized to demonstrate that non-substrate dsDNA can compete with nicked dsDNA substrates for enzyme binding. Based upon these data, we hypothesize the inhibition of T4 DNA ligase by non-nicked dsDNA is direct evidence for a two-step nick-binding mechanism, with an initial, nick-independent, transient dsDNA-binding event preceding a transition to a stable binding complex in the presence of a nick site.

Fluorogenic DNA ligase and base excision repair enzyme assays using substrates labeled with single fluorophores

Continuing our work on fluorogenic substrates labeled with single fluorophores for nucleic acid modifying enzymes, here we describe the development of such substrates for DNA ligases and some base excision repair enzymes. These substrates are hairpin-type synthetic DNA molecules with a single fluorophore located on a base close to the 3' ends, an arrangement that results in strong fluorescence quenching. When such substrates are subjected to an enzymatic reaction, the position of the dyes relative to that end of the molecules is altered, resulting in significant fluorescence intensity changes. The ligase substrates described here were 5' phosphorylated and either blunt-ended or carrying short, self-complementary single-stranded 5' extensions. The ligation reactions resulted in the covalent joining of the ends of the molecules, decreasing the quenching effect of the terminal bases on the dyes. To generate fluorogenic substrates for the base excision repair enzymes formamido-pyrimidine-DNA glycosylase (FPG), human 8-oxo-G DNA glycosylase/AP lyase (hOGG1), endonuclease IV (EndoIV), and apurinic/apyrimidinic endonuclease (APE1), we introduced abasic sites or a modified nucleotide, 8-oxo-dG, at such positions that their enzymatic excision would result in the release of a short fluorescent fragment. This was also accompanied by strong fluorescence increases. Overall fluorescence changes ranged from approximately 4-fold (ligase reactions) to more than 20-fold (base excision repair reactions).

Complete steady-state rate equation for DNA ligase and its use for measuring product kinetic parameters of NAD⁺-dependent DNA ligase from Haemophilus influenzae

Background

DNA ligase seals the nicks in the phosphodiester backbone between Okazaki fragments during DNA replication. DNA ligase has an unusual Bi Ter Ping Pong kinetic mechanism. Its substrates in eubacteria are NAD⁺ and nicked DNA (nDNA). Its products are nicotinamide mononucleotide (NMN), adenosine 5′-monophosphate (AMP), and sealed DNA. Investigation of the kinetic mechanism and measurement of the kinetic constants of DNA ligase using steady-state kinetics would benefit from the availability of the complete steady-state rate equation, including terms for product concentrations and product-related kinetic constants, which has not previously been published.

Results

The rate equations for two possible Bi Ter kinetic mechanisms for DNA ligase, including products, are reported. The mechanisms differ according to whether the last two products, AMP and sealed DNA, are released in an ordered or rapid-equilibrium random (RER) manner. Steady-state kinetic studies of product inhibition by NMN and AMP were performed with Haemophilus influenzae NAD⁺-dependent DNA ligase. The complete rate equation enabled measurement of dissociation constants for NAD⁺, NMN, and AMP and eliminated one of 3 possible product release mechanisms.

Conclusions

Steady-state kinetic product inhibition experiments and complete steady-state kinetic rate equations were used to measure dissociation constants of NAD⁺, NMN, and AMP and eliminate the possibility that AMP is the second product released in an ordered mechanism. Determining by steady-state kinetics whether the release of sealed DNA and AMP products goes by an ordered (AMP last off) or RER mechanism was shown to require a product inhibition study using sealed DNA.

DNA ligases

The DNA ligase enzyme family catalyzes the formation of a phosphodiester bond between juxtaposed 5'-phosphate and 3'-hydroxyl termini in duplex DNA. This activity can seal nicks in duplex DNA or join double-stranded DNA fragments having either blunt or cohesive ends. DNA ligases are central enzymes in molecular biology, nucleic acid research, and in next-generation sequencing applications. Reaction conditions and applications for T4 DNA ligase, E. coli DNA ligase, and thermostable DNA ligases are described in this unit. These enzymes differ in their cofactor requirements, substrate specificity, and thermal stability.

Kinetics and thermodynamics of nick sealing by T4 DNA ligase

T4 DNA ligase is an Mg2+-dependent and ATP-dependent enzyme that seals DNA nicks in three steps: it covalently binds AMP, transadenylates the nick phosphate, and catalyses formation of the phosphodiester bond releasing AMP. In this kinetic study, we further detail the reaction mechanism, showing that the overall ligation reaction is a superimposition of two parallel processes: a 'processive' ligation, in which the enzyme transadenylates and seals the nick without dissociating from dsDNA, and a 'nonprocessive' ligation, in which the enzyme takes part in the abortive adenylation cycle (covalent binding of AMP, transadenylation of the nick, and dissociation). At low concentrations of ATP (<10 microM) and when the DNA nick is sealed with mismatching base pairs (e.g. five adjacent), this superimposition resolves into two kinetic phases, a burst ligation (approximately 0.2 min(-1)) and a subsequent slow ligation (approximately 2x10(-3) min(-1)). The relative rate and extent of each phase depend on the concentrations of ATP and Mg2+. The activation energies of self-adenylation (16.2 kcal.mol(-1)), transadenylation of the nick (0.9 kcal.mol(-1)), and nick-sealing (16.3-18.8 kcal.mol(-1)) were determined for several DNA substrates. The low activation energy of transadenylation implies that the transfer of AMP to the terminal DNA phosphate is a spontaneous reaction, and that the T4 DNA ligase-AMP complex is a high-energy intermediate. To summarize current findings in the DNA ligation field, we delineate a kinetic mechanism of T4 DNA ligase catalysis.

Kinetic mechanism of the Mg2+-dependent nucleotidyl transfer catalyzed by T4 DNA and RNA ligases

The Mg(2+)-dependent adenylylation of the T4 DNA and RNA ligases was studied in the absence of a DNA substrate using transient optical absorbance and fluorescence spectroscopy. The concentrations of Mg(2+), ATP, and pyrophosphate were systematically varied, and the results led to the conclusion that the nucleotidyl transfer proceeds according to a two-metal ion mechanism. According to this mechanism, only the di-magnesium-coordinated form Mg(2)ATP(0) reacts with the enzyme forming the covalent complex E.AMP. The reverse reaction (ATP synthesis) occurs between the mono-magnesium-coordinated pyrophosphate form MgP(2)O(7)(2-) and the enzyme.MgAMP complex. The nucleotide binding rate decreases in the sequence ATP(4-) > MgATP(2-) > Mg(2)ATP(0), indicating that the formation of the non-covalent enzyme.nucleotide complex is driven by electrostatic interactions. T4 DNA ligase shows notably higher rates of ATP binding and of subsequent adenylylation compared with RNA ligase, in part because it decreases the K(d) of Mg(2+) for the enzyme-bound Mg(2)ATP(0) more than 10-fold. To elucidate the role of Mg(2+) in the nucleotidyl transfer catalyzed by T4 DNA and RNA ligases, we propose a transition state configuration, in which the catalytic Mg(2+) ion coordinates to both reacting nucleophiles: the lysyl moiety of the enzyme that forms the phosphoramidate bond and the alpha-beta-bridging oxygen of ATP.

Binding of nucleotides by T4 DNA ligase and T4 RNA ligase: optical absorbance and fluorescence studies

The interaction of nucleotides with T4 DNA and RNA ligases has been characterized using ultraviolet visible (UV-VIS) absorbance and fluorescence spectroscopy. Both enzymes bind nucleotides with the K(d) between 0.1 and 20 microM. Nucleotide binding results in a decrease of absorbance at 260 nm due to pi-stacking with an aromatic residue, possibly phenylalanine, and causes red-shifting of the absorbance maximum due to hydrogen bonding with the exocyclic amino group. T4 DNA ligase is shown to have, besides the catalytic ATP binding site, another noncovalent nucleotide binding site. ATP bound there alters the pi-stacking of the nucleotide in the catalytic site, increasing its optical extinction. The K(d) for the noncovalent site is approximately 1000-fold higher than for the catalytic site. Nucleotides quench the protein fluorescence showing that a tryptophan residue is located in the active site of the ligase. The decrease of absorbance around 298 nm suggests that the hydrogen bonding interactions of this tryptophan residue are weakened in the ligase-nucleotide complex. The excitation/emission properties of T4 RNA ligase indicate that its ATP binding pocket is in contact with solvent, which is excluded upon binding of the nucleotide. Overall, the spectroscopic analysis reveals important similarities between T4 ligases and related nucleotidyltransferases, despite the low sequence similarity.

An improved method for the rapid assessment of DNA bending by small molecules

Assessing the effects of non-covalently bound chemicals on DNA structure is particularly challenging. Traditional methods require the use of cumbersome electrophoretic techniques or that the compounds bind DNA with an extremely high affinity. Here we demonstrate that, by extending the use of the exonuclease Bal 31, we can rely on a standard cyclization assay technique and one dimensional gel electrophoresis to identify and quantitate chemical induced DNA bending. An important application of this method is to the study of small molecules that bind to DNA non-covalently and we illustrate the method with the antitumor antibiotic calicheamicin. Our results suggest that the distribution of circles resulting from the polymerization of a 21 bp DNA construct reflects the kinetics of the competing cyclization and dimerization reactions and provides a method for rapidly screening compounds for DNA bending.

Enhanced DNA sequencing by hybridization

An enhanced version of DNA sequencing by hybridization (SBH), termed positional SBH (PSBH), has been developed. PSBH uses duplex probes containing single-stranded 3' overhangs, instead of simple single-stranded probes. Stacking interactions between the duplex probe and a single-stranded target should provide enhanced stringency in distinguishing perfectly matched 3' sequences. A second enhancement is the use of enzyme-catalyzed steps, instead of pure physical hybridization. The feasibility of this scheme has been investigated using biotinylated duplex probes containing single-stranded 5-base 3' overhangs, immobilized on streptavidin-coated magnetic beads. Ligation of a single-stranded target, hybridized to the single-stranded region of the duplex probes, provided enhanced discrimination of perfectly matched targets from those containing mismatches. In distinction to the serious complications caused by base composition effects in ordinary SBH, there was little effect of base composition in PSBH. The hardest mismatch to discriminate was the one furthest from the phosphodiester bond formed by ligation. However, mismatches in this position were efficiently discriminated by 3' extension of the duplex probe using a template-dependent DNA polymerase. These results demonstrate that PSBH offers considerable promise to facilitate actual implementations of SBH.

Branch capture reactions: effect of recipient structure

Branch capture reactions (BCR) contain two DNA species: (i) a recipient restriction fragment terminating in an overhang and (ii) a displacer-linker duplex terminating in a displacer tail complementary to the overhang as well as contiguous nucleotides within the recipient duplex. Branched complexes containing both species are captured by ligation of the linker to the recipient overhang. Specificity depends upon branch migration and is increased by substitution of bromodeoxycytidine for deoxycytidine in the displacer. BCR rates and specificities were determined for recipient overhangs that were (i) 5' and 3', (ii) 3 and 4 nucleotides long, and (iii) 0-100% G+C. Model systems permitted independent determination of G+C and branching effects on ligation rates and verification of rapid equilibrium between the branched complex and its component species. With all 4-base overhangs, recipient duplexes permitting extensive branch migration became saturated with displacer-linker duplexes. With increasing G+C, increasing ligation at competing sites led to decreased BCR specificity. BCR may be used to label a DNA fragment prior to electrophoresis, mark a fragment for affinity chromatography, or introduce a new overhang sequence compatible with a restriction endonuclease site in a cloning vector. A protocol was confirmed for mapping restriction sites in cloned DNA.

Specificity of the nick-closing activity of bacteriophage T4 DNA ligase

Bacteriophage T4 DNA ligase effectively joins two adjacent, short synthetic oligodeoxyribonucleotides (oligos), as guided by complementary oligo, plasmid and genomic DNA templates. When a single bp mismatch exists at either side of the ligation junction, the efficiency of the enzyme to ligate the two oligos decreases. Mismatch ligation is approximately five-fold greater if the mismatch occurs at the 3' side rather than at the 5' side of the junction. During mismatch ligation the 5' adenylate of the 3' oligo accumulates in the reaction. The level of the adenylate formation correlates closely with the level of the mismatch ligation. Both mismatch ligation and adenylate formation are suppressed at elevated temperatures and in the presence of 200 mM NaCl or 2-5 mM spermidine. The apparent Km for the oligo template in the absence of salt is 0.05 microM, whereas the Km increases to 0.2 microM in the presence of 200 mM of NaCl. In this report, we demonstrate these properties of T4 DNA ligase for oligo pairs complementary to the beta-globin gene at the sequence surrounding the single bp mutation responsible for sickle-cell anemia. Because of the highly specific nature of the nick-closing reaction, ligation of short oligos with DNA ligase can be used to distinguish two DNA templates differing by a single nucleotide.

Effect of spermine on cleavage of plasmid DNA by nucleases S1 and Bal 31

S1, a single-strand-specific nuclease, cleaves both strands of supercoiled DNA mostly once at unpaired sites. However, all the sites are not cleaved with the same frequency by the enzyme, there being sites of preferential cleavage and infrequent ones. Spermine was found to reduce this cleavage specificity of S1 with supercoiled plasmid DNA. A similar effect of spermine was observed with Bal 31 nuclease. Bal 31 contains in addition to S1-like activity a quasi-processive exonuclease activity that simultaneously degrades both 3'- and 5'-termini of linearized duplex DNA. Spermine stimulated the exonuclease activity. The above results were obtained within the concentration range of spermine that did not induce DNA aggregation.

An improved assay for DNA ligase reveals temperature-sensitive activity in cdc9 mutants of Saccharomyces cerevisiae

A sensitive and quantitative assay for DNA ligase has been developed which is suitable for the analysis of crude cell extracts of yeast. The assay is sufficiently sensitive to detect the low levels of DNA ligase activity remaining in cdc9 mutants of Saccharomyces cerevisiae. Indeed, we have been able to show that this residual activity is temperature-sensitive, thus establishing finally that CDC9 is the structural gene for DNA ligase.

Influence of monovalent cations on the activity of T4 DNA ligase in the presence of polyethylene glycol

Monovalent cations such as Na+ and K+ inhibit the activity of T4 DNA ligase. However, the extent of inhibition varies with the terminal sequence of the duplex DNA used as substrate; in many cases, ligation of DNA is completely inhibited at 200 mM. The activity of the ligase is stimulated by raising the concentration of polyethylene glycol 6000 from 0 to 15% (w/v) when NaC1 and KC1 were both absent. Ligation was reduced as the concentration of NaC1 or KC1 was raised in a mixture containing 5 or 15% PEG 6000. With 10% PEG 6000, both cohesive- and blunt-end ligation of this ligase increased at high concentrations of salt (150-200 mM NaC1, or 200-250 mM KC1). Further, with 10% PEG 6000, inter- and intramolecular ligation occurred at low salt concentrations (0-100 mM NaC1, or 0-150 mM KC1); only linear oligomers were formed by intermolecular ligation at the high concentrations.

Heterogeneity of mammalian DNA ligase detected on activity and DNA sequencing gels

A new method to detect DNA ligase activity in situ after NaDodSO4 polyacrylamide gel electrophoresis has been developed. After renaturation of active polypeptides the ligase reaction occurs in situ by incubating the intact gel in the presence of Mg++ and ATP. Further treatment with alkaline phosphatase removes the unligated 5'-32P-end of oligo (dT) used as a substrate and active polypeptides having ligase activity are identified by autoradiography. Analysis on DNA sequencing gels of the oligo (dT) reaction products present in the activity bands ensures that the radioactive material detected in activity gels or in standard in vitro ligase assays corresponds unambiguously to a ligase activity. Using these methods, we have analysed the purified phage T4 DNA ligase, and the activities present in crude extracts and in purified fractions from monkey kidney (CV1-P) cells. The purified T4 enzyme yields one or two active peptides with Mr values of 60,000 and 70,000. Crude extracts from CV1-P cells contain several polypeptides having DNA ligase activity. Partial purification of these extracts shows that DNA ligase I isolated from hydroxylapatite column is enriched in polypeptides with Mr 200,000, 150,000 and 120,000, while DNA ligase II is enriched in those with Mr 60,000 and 70,000.

Energetics of DNA twisting. I. Relation between twist and cyclization probability

The twisting potential of DNA has been determined directly by a method that measures the cyclization probability or j-factor of EcoRI restriction fragments as a function of DNA twist. The cyclization probability is proportional to Kc, the equilibrium constant for cyclization of the restriction fragment via its cohesive ends (Shore et al., 1981). Here we vary the twist of the DNA by making small internal additions to or deletions from a 242 bp EcoRI restriction fragment. A series of 12 DNA molecules has been studied, which range in length from 237 to 254 bp. The cyclization probability is measured from the rates of covalent closure by phage T4 DNA ligase of two systems: (1) a linear restriction fragment in equilibrium with its cyclized form and (2) half molecules (cut by a blunt-end endonuclease) in equilibrium with joined half molecules. The striking result is that, in this DNA size range, the j-factor depends strongly on the fractional twist: the difference between the total helical twist and the nearest integer. Thus j depends in an oscillatory manner on DNA length between 237 and 254 bp with a period of about 10 bp. These data give the free energy of DNA twisting as a function of twist. The curve of j versus DNA length can be fitted to a harmonic twisting potential with a torsional constant of C = 2.4 X 10(-19) erg cm. This value is in reasonable agreement with different estimates of C made by Barkley & Zimm (1979: C = 1.8 X 10(-19) to 4.1 X 10(-19) erg cm) and is somewhat larger than the value obtained resulting from the kinetics of DNA twisting measured by fluorescence depolarization of ethidium intercalated into DNA (C = 1.4 X 10(-19) erg cm; Millar et al., 1982; Thomas et al., 1980) or from spin label studies (Hurley et al., 1982). Our experiments provide a direct measurement of the torsional free energy and they show that the DNA twisting potential is symmetric. Our experiments also indicate that the DNA helix is continuous, or nearly so, in a nicked circle; presumably this happens because the DNA stacking interaction maintains the double helix in register across a single-strand nick. As a consequence, the twist of a singly nicked DNA circle is integral for small (approximately equal to 250 bp) planar DNA circles and there is a change in twist upon cyclization.(ABSTRACT TRUNCATED AT 400 WORDS)

Kinetic studies on the reaction catalyzed by DNA ligase from calf thymus

Kinetic analysis of the reaction catalyzed by calf thymus DNA ligase (EC 6.5.1.1) has been carried out using [5'-32P]nicked DNA as substrate. The results of initial velocity and product inhibition studies indicate that the ligase reaction is likely to proceed through the 'uni-uni uni-bi ping-pong' mechanism. The order of substrate addition and product release is as follows: ATP, PPi, nicked DNA, sealed DNA and 5'-AMP. The true Km values for ATP and for nicked DNA (5'-phosphoryl ends) were 2 microM and 0.11 microM, respectively. The turnover number was estimated to be 7 sealing events per min. dATP was an inhibitor competitive with ATP (Ki = 25 microM). The addition of 0.5 mM spermine or 5 mM spermidine resulted in an increase in the apparent Km for nicked DNA as well as in the apparent V, whereas 0.1 M KCl increased only the apparent Km for nicked DNA. Neither polyamine nor KCl affected the apparent Km for ATP. The ligase reaction was not significantly affected by aphidicolin and various phosphate compounds tested.

Sealing of gaps in duplex DNA by T4 DNA ligase

Single-strand gaps in DNA molecules were found to be a substrate for T4 DNA ligase. Sealing of the gaps was optimal at the same conditions as ligation of blunt-ended DNA molecules. Spermidine at a concentration of 2 mM stimulated the ligation of gaps, as well as the joining of DNA molecules with cohesive and blunt ends. In addition, spermidine reduced the optimal ATP concentration. The ligation of single-stranded gaps was a slow process, reaching a plateau after several hours at 25 degrees C. Approximately 10% of circular duplex plasmid pBR322 DNA molecules with a gap of 1-5 nucleotides could be converted to a covalently closed form. When such molecules were used for transformation of E. coli cells deletion mutants were obtained at a high frequency. The size and position of the gaps and the deletions were equivalent, confirming that T4 DNA ligase was sealing the gaps.

Specific and reversible inhibition of the blunt end joining activity of the T4 DNA ligase

Specific, complete and reversible inhibition of the joining of blunt ended DNA duplexes catalyzed by the T4 DNA ligase can be obtained by using ATP, the enzyme cofactor, at concentrations of 5 mM and higher. On cohesive DNA ends, 5 mM ATP, which completely inhibits blunt end ligation, brings about only a limited (8%) reduction in the level of joining obtainable under optimal ATP concentration (0,5 mM or lower). A similar but less drastic uncoupling of the two kinds of joining can be achieved at lower ATP concentration (2,5 mM) using 1 mM Mg++. The joining of DNA blunt ends can also be inhibited almost completely by 10 mM spermidine, without noticeable effect on the joining of cohesive termini.

Protons and Mg2+ cations as probes in investigating the role of GTP in initiation complex formation

fMet-tRNAfMet binding to both 30-S subunits and to 70-S particles is dependent on both pH AND Mg2+ concentration: for fMet-tRNAfMet binding to 70-S particles, variations of pH and Mg2+ concentration are tightly interdependent. This behavior can be interpreted by the polyelectrolyte theory as a direct consequence of the fact that the binding occurs in a polyanionic micro-environment. The pH-dependent binding to 70-S particles clearly shows the involvement of two prototropic groups which appear to be those carrying out GTP hydrolysis, therefore directly linked to initiation complex formation; in the presence of a non-hydrolyzable analogue to GTP, guanosine 5'-[beta, gamma-imido]triphosphate, the binding of fMet-tRNAfMet shows much less interdependence between variation of pH and Mg2+ concentration.

Influence of polyamines on the activity of DNA polymerase I from Escherichia coli

The influence of polyamines on the various activities of DNA polymerase I from Escherichia coli (EC 2.7.7.7) has been investigated. For all high molecular weight DNAs spermine and spermidine caused up to 80% inhibition when present in high concentrations, i.e. above 1 mM for spermine and 2 mM for spermidine. In the presence of low concentrations of polyamines a small activation was seen for some DNAs. The diamines cadaverine and putrescine had little influence on the rate of synthesis with natural occurring DNAs. In the case of d(A--T)n the activation/inhibition was found to be markedly dependent on the molecular weight of the samples used. With a low molecular weight DNA, 5.6 S, addition of spermidine resulted in up to 3-fold stimulation of activity. The activation was dependent on the concentration of MgCl2 and ionic strength; increasing concentration of these gave a decrease in the degree of activation. Polyamines also had a dramatic effect on the rate of synthesis using the homopolymers (dA)n . (dT)10 and (rA)n . (dT)10 . (20:1) as primers. Putrescine, in particular, increased the activity up to 10-fold with (rA)n . (dT)10 and somewhat less for (dA)n . (dT)10. The apparent Km for the primer (rA)n . (dT)10 decreased approx. 35-fold in the presence of 6.6 mM putrescine. There was no influence on the apparent Km for dTTP. The influence of polyamines on both the 5' leads to 3' and 3' leads to 5' nuclease activity was also investigated. Inhibition of nuclease activity was observed in the presence of polyamines, particularly with spermine. Thus with d(A--T)n and T7 DNA as substrates addition of 0.7 mM spermine resulted in almost complete inhibition of the activity. The dramatic inhibition observed with high concentrations of spermine (spermidine) both in the case of polymerizing and nuclease activity is thought to be due to polyamine-induced aggregation of DNA molecules.

Ionic regulation in genetic translation systems

The polyelectrolyte theory can provide an interpretation of the interdependence of pH, ionic strength, and polyamines one observes in the activity of ribonuclease acting on RNA. According to this theory: (i) A nucleic acid-enzyme complex and the suspending medium may be considered as two phases in equilibrium, even though within limits, the complex is soluble in water. (ii) The enzymatic catalysis is under tight control of the electrostatic potential generated by the system. Consequently, modification in electrostatic potential will induce a concomitant change in activity. (iii) The electrostatic potential can be modified through action on the system of "modulators", either "external" (ionic strength, pH, temperature, etc.) or "internal" (specific ligands, substrates, protein factors, etc.). Similarities between the reaction of ribonuclease (ribonuclease 3'-pyrimidino-oligonucleotidohydrolase; EC 3.1.4.22) and RNA and those observed with highly organized systems catalyzing DNA, RNA, and protein synthesis suggest that the electrostatic potential also provides an important regulatory mechanism in genetic translation. In this view, an essential function of nucleic acids is to provide their enzyme partners with polyanionic microenvironments within which their catalytic activities are controlled by variation in physicochemical parameters, including the proton concentration induced through "modulation" of the local electrostatic potential.