Plasmid expression of Deinococcus radiodurans RecA confers UV-A protection to Escherichia coli with an inverse protein dose dependence, which does not exceed conspecific RecA protection.

Low level expression in Escherichia coli of the RecA protein from the radiation resistant bacterium Deinococcus radiodurans protects a RecA deficient strain of E. coli from UV-A irradiation by up to ∼160% over basal UV-A resistance. The protection effect is inverse protein dose dependent: increasing the expression level of the D.

Pol I DNA polymerases stimulate DNA end-joining by Escherichia coli DNA ligase.

Klenow and Klentaq are the large fragment domains of the Pol I DNA polymerases from Escherichia coli and Thermus aquaticus, respectively. Herein, we show that both polymerases can significantly stimulate complementary intermolecular end-joining ligations by E.coli DNA ligase when the polymerases are present at concentrations lower than that of the DNA substrates.

Enhanced DNA binding affinity of RecA protein from Deinococcus radiodurans.

Deinococcus radiodurans (Dr) has a significantly more robust DNA repair response than Escherichia coli (Ec), which helps it survive extremely high doses of ionizing radiation and prolonged periods of desiccation. DrRecA protein plays an essential part in this DNA repair capability. In this study we directly compare the binding of DrRecA and EcRecA to the same set of short, defined single (ss) and double stranded (ds) DNA oligomers.

The stability of Taq DNA polymerase results from a reduced entropic folding penalty; identification of other thermophilic proteins with similar folding thermodynamics.

The thermal stability of Taq DNA polymerase is well known, and is the basis for its use in PCR. A comparative thermodynamic characterization of the large fragment domains of Taq (Klentaq) and E. coli (Klenow) DNA polymerases has been performed by obtaining full Gibbs-Helmholtz stability curves of the free energy of folding (ΔG) versus temperature.

Enthalpic switch-points and temperature dependencies of DNA binding and nucleotide incorporation by Pol I DNA polymerases.

This study examines the relationship between the DNA binding thermodynamics and the enzymatic activity of the Klenow and Klentaq Pol I DNA polymerases from Escherichia coli and Thermus aquaticus. Both polymerases bind DNA with nanomolar affinity at temperatures down to at least 5°C, but have lower than 1% enzymatic activity at these lower temperatures. For both polymerases it is found that the temperature of onset of significant enzymatic activity corresponds with the temperature where the enthalpy of binding (ΔHbinding) crosses zero (TH) and becomes favorable (negative).

Interactions of replication versus repair DNA substrates with the Pol I DNA polymerases from Escherichia coli and Thermus aquaticus.

Different DNA polymerases partition differently between replication and repair pathways. In this study we examine if two Pol I family polymerases from evolutionarily distant organisms also differ in their preferences for replication versus repair substrates. The DNA binding preferences of Klenow and Klentaq DNA polymerases, from Escherichia coli and Thermus aquaticus respectively, have been studied using a fluorescence competition binding assay.

Analysis of free energy versus temperature curves in protein folding and macromolecular interactions.

Plots of free energy versus temperature are commonly called stability curves or Gibbs-Helmholtz curves, and they have proven to be extremely useful in protein folding and ligand-binding studies. Curvature in a Gibbs-Helmholtz or stability plot is indicative of a heat capacity change, and some of their primary uses in biochemistry over the past few decades have included determining ΔCp values and comparing ΔCp values between two related processes. This chapter describes basic approaches for analyzing curved Gibbs-Helmholtz plots, along with two specific extensions of standard Gibbs-Helmholtz plot analysis: (1) translating ΔG of folding versus temperature into ΔH and ΔS versus temperature for comparing mesophilic-thermophilic protein pairs, and (2) fitting Gibbs-Helmholtz plots to determine if ΔCp changes with temperature or not.

The glutamate effect on DNA binding by pol I DNA polymerases: osmotic stress and the effective reversal of salt linkage.

The significant enhancing effect of glutamate on DNA binding by Escherichia coli nucleic acid binding proteins has been extensively documented. Glutamate has also often been observed to reduce the apparent linked ion release (Deltan(ions)) upon DNA binding. In this study, it is shown that the Klenow and Klentaq large fragments of the Type I DNA polymerases from E.

Thermodynamics of the DNA structural selectivity of the Pol I DNA polymerases from Escherichia coli and Thermus aquaticus.

Understanding the thermodynamics of substrate selection by DNA polymerase I is important for characterizing the balance between replication and repair for this enzyme in vivo. Due to their sequence and structural similarities, Klenow and Klentaq, the large fragments of the Pol I DNA polymerases from Escherichia coli and Thermus aquaticus, are considered functional homologs. Klentaq, however, does not have a functional proofreading site.

Local conformations and competitive binding affinities of single- and double-stranded primer-template DNA at the polymerization and editing active sites of DNA polymerases.

In addition to their capacity for template-directed 5' --> 3' DNA synthesis at the polymerase (pol) site, DNA polymerases have a separate 3' --> 5' exonuclease (exo) editing activity that is involved in assuring the fidelity of DNA replication. Upon misincorporation of an incorrect nucleotide residue, the 3' terminus of the primer strand at the primer-template (P/T) junction is preferentially transferred to the exo site, where the faulty residue is excised, allowing the shortened primer to rebind to the template strand at the pol site and incorporate the correct dNTP. Here we describe the conformational changes that occur in the primer strand as it shuttles between the pol and exo sites of replication-competent Klenow and Klentaq DNA polymerase complexes in solution and use these conformational changes to measure the equilibrium distribution of the primer between these sites for P/T DNA constructs carrying both matched and mismatched primer termini.

Prevalence of temperature-dependent heat capacity changes in protein-DNA interactions.

A large, negative DeltaCp of DNA binding is a thermodynamic property of the majority of sequence-specific DNA-protein interactions, and a common, but not universal property of non-sequence-specific DNA binding. In a recent study of the binding of Taq polymerase to DNA, we showed that both the full-length polymerase and its "Klentaq" large fragment bind to primed-template DNA with significant negative heat capacities. Herein, we have extended this analysis by analyzing this data for temperature-variable heat capacity effects (DeltaDeltaCp), and have similarly analyzed an additional 47 protein-DNA binding pairs from the scientific literature.

Applications of fluorescence anisotropy to the study of protein-DNA interactions.

The use of fluorescence anisotropy to monitor protein-DNA interactions has been on the rise since its introduction by Heyduk and Lee in 1990. As a solution-based, true-equilibrium, real-time method, it has several advantages (and a few disadvantages) relative to the more classical methods of filter binding and the electrophoretic mobility shift assay (gel shift). This chapter discusses the basis for monitoring protein-DNA interactions using fluorescence anisotropy, as well as the advantages and disadvantages of the method, but the bulk of the chapter is devoted to experimental tips and guidance meant to augment existing reviews of the method.

Thermal stability landscape for Klenow DNA polymerase as a function of pH and salt concentration.

The thermal denaturation of Klenow DNA polymerase has been characterized over a wide variety of solution conditions to obtain a relative stability landscape for the protein. Measurements were conducted utilizing a miniaturized fluorescence assay that measures Tm based on the increase in the fluorescence of 1,8-anilinonaphthalene sulfonate (ANS) when the protein denatures. The melting temperature (Tm) for Klenow increases as the salt concentration is increased and as the pH is decreased.

Temperature dependence and thermodynamics of Klenow polymerase binding to primed-template DNA.

DNA binding of Klenow polymerase has been characterized with respect to temperature to delineate the thermodynamic driving forces involved in the interaction of this polymerase with primed-template DNA. The temperature dependence of the binding affinity exhibits distinct curvature, with tightest binding at 25-30 degrees C. Nonlinear temperature dependence indicates Klenow binds different primed-template constructs with large heat capacity (DeltaCp) values (-870 to -1220 cal/mole K) and thus exhibits large temperature dependent changes in enthalpy and entropy.

Extreme free energy of stabilization of Taq DNA polymerase.

We have examined the chemical denaturations of the Klentaq and Klenow large-fragment domains of the Type 1 DNA polymerases from Thermus aquaticus (Klentaq) and Escherichia coli (Klenow) under identical solution conditions in order to directly compare the stabilization energetics of the two proteins. The high temperature stability of Taq DNA polymerase is common knowledge, and is the basis of its use in the polymerase chain reaction. This study, however, is aimed at understanding the thermodynamic basis for this high-temperature stability.

Thermodynamics of the binding of Thermus aquaticus DNA polymerase to primed-template DNA.

DNA binding of the Type 1 DNA polymerase from Thermus aquaticus (Taq polymerase) and its Klentaq large fragment domain have been studied as a function of temperature. Equilibrium binding assays were performed from 5 to 70 degrees C using a fluorescence anisotropy assay and from 10 to 60 degrees C using isothermal titration calorimetry. In contrast to the usual behavior of thermophilic proteins at low temperatures, Taq and Klentaq bind DNA with high affinity at temperatures down to 5 degrees C.

Salt modulates the stability and lipid binding affinity of the adipocyte lipid-binding proteins.

Adipocyte lipid-binding protein (ALBP or aP2) is an intracellular fatty acid-binding protein that is found in adipocytes and macrophages and binds a large variety of intracellular lipids with high affinity. Although intracellular lipids are frequently charged, biochemical studies of lipid-binding proteins and their interactions often focus most heavily on the hydrophobic aspects of these proteins and their interactions. In this study, we have characterized the effects of KCl on the stability and lipid binding properties of ALBP.

Comparative thermal denaturation of Thermus aquaticus and Escherichia coli type 1 DNA polymerases.

Thermal denaturations of the type 1 DNA polymerases from Thermus aquaticus (Taq polymerase) and Escherichia coli (Pol 1) have been examined using differential scanning calorimetry and CD spectroscopy. The full-length proteins are single-polypeptide chains comprising a polymerase domain, a proofreading domain (inactive in Taq) and a 5' nuclease domain. Removal of the 5' nuclease domains produces the 'large fragment' domains of Pol 1 and Taq, termed Klenow and Klentaq respectively.

Global conformations, hydrodynamics, and X-ray scattering properties of Taq and Escherichia coli DNA polymerases in solution.

Escherichia coli polymerase 1 (Pol 1) and Thermus aquaticus Taq polymerase are homologous Type I DNA polymerases, each comprised of a polymerase domain, a proofreading domain (inactive in Taq), and a 5' nuclease domain. "Klenow" and "Klentaq" are the large fragments of Pol 1 and Taq and are functional polymerases lacking the 5' nuclease domain. In the available crystal structures of full-length Taq, the 5' nuclease domain is positioned in two different orientations: in one structure, it is extended out into solution, whereas in the other, it is folded up against the polymerase domain in a more compact structure.

Salt dependence of DNA binding by Thermus aquaticus and Escherichia coli DNA polymerases.

DNA binding properties of the Type 1 DNA polymerases from Thermus aquaticus (Taq, Klentaq) and Escherichia coli (Klenow) have been examined as a function of [KCl] and [MgCl(2)]. Full-length Taq and its Klentaq "large fragment" behave similarly in all assays. The two different species of polymerases bind DNA with sub-micromolar affinities in very different salt concentration ranges.