David P. Remeta

Thermodynamics of drug-DNA interactions.

Batch calorimetry, differential scanning calorimetry (DSC), uv/vis absorption spectroscopy, fluorescence spectroscopy, and circular dichroism (CD), have been used to detect, monitor, and thermodynamically characterize the binding of daunomycin, dipyrandenium, dipyrandium, and netropsin to poly d(AT) and actinomycin D to salmon testes (ST) DNA. The following thermodynamic binding profiles have been obtained. (table; see text) All the poly d(AT) binding studies were done at 25 degrees C while actinomycin binding to ST DNA was performed at 1 degree C to enhance drug solubility. These thermodynamic parameters are interpreted in terms of specific interactions that have been proposed as part of models for the binding of each drug.

A Revised Picture of the Cu(II)−α-Synuclein Complex: The Role of N‑Terminal Acetylation

α-Synuclein (αS) is an amyloidogenic intrinsically disordered protein implicated in Parkinsons disease, for which copper-mediated pathways of neurodegeneration have been suggested. We have employed nuclear magnetic resonance, circular dichroism, electrospray ionization mass spectrometry, and thioflavin T fluorescence to characterize interactions of Cu(2+) with the physiological acetylated form (Ac-αS). Significantly, N-terminal acetylation abolishes Cu(2+) binding at the high-affinity M1-D2 site present in the nonacetylated protein and maintains Cu(2+) interactions around H50/D121. Fibrillation enhancement observed at an equimolar Cu(2+) stoichiometry with the nonacetylated model does not occur with Ac-αS. These findings open new avenues of investigation into Cu(2+)-mediated neurodegenerative pathology suggested in vivo.

Energetics of Lesion Recognition by a DNA Repair Protein: Thermodynamic Characterization of Formamidopyrimidine-glycosylase (Fpg) Interactions with Damaged DNA Duplexes

As part of an overall effort to map the energetic landscape of the base excision repair pathway, we report the first thermodynamic characterization of repair enzyme binding to lesion-containing duplexes. Isothermal titration calorimetry (ITC) in conjunction with spectroscopic measurements and protease protection assays have been employed to characterize the binding of Escherichia coli formamidopyrimidine-glycosylase (Fpg), a bifunctional repair enzyme, to a series of 13-mer DNA duplexes. To resolve energetically the binding and the catalytic events, several of these duplexes are constructed with non-hydrolyzable lesion analogs that mimic the natural 8-oxo-dG substrate and the abasic-like intermediates. Specifically, one of the duplexes contains a central, non-hydrolyzable, tetrahydrofuran (THF) abasic site analog, while another duplex contains a central, carbocyclic substrate analog (carba-8-oxo-dG). ITC-binding studies conducted between 5.0 degrees C and 15.0 degrees C reveal that Fpg association with the THF-containing duplex is characterized by binding free energies that are relatively invariant to temperature (deltaG approximately -9.5 kcalmol(-1)), in contrast to both the reaction enthalpy and entropy that are strongly temperature-dependent. Complex formation between Fpg and the THF-containing duplex at 15 degrees C exhibits an unfavorable association enthalpy (deltaH=+7.5 kcalmol(-1)) that is compensated by a favorable association entropy (TdeltaS=+17.0 kcalmol(-1)). The entropic nature of the binding interaction, coupled with the large negative heat capacity (deltaC(p)=-0.67 kcaldeg(-1)mol(-1)), is consistent with Fpg complexation to the THF-containing duplex involving significant burial of non-polar surface areas. By contrast, under the high ionic strength buffer conditions employed herein (200 mM NaCl), no appreciable Fpg affinity for the carba-8-oxo-dG substrate analog is detected. Our results suggest that initial Fpg recognition of a damaged DNA site is predominantly electrostatic in nature, and does not involve large contact interfaces. Subsequent base excision presumably facilitates accommodation of the resulting lesion site into the binding pocket, as the enzyme interaction with the THF-containing duplex is characterized by high affinity and a large negative heat capacity change. Our data are consistent with a pathway in which Fpg glycosylase activity renders the base excision product a preferred ligand relative to the natural substrate, thereby ensuring the fidelity of removing highly reactive and potentially mutagenic abasic-like intermediates through catalytic elimination reactions.

The thermodynamics of template-directed DNA synthesis: Base insertion and extension enthalpies

We used stopped-flow calorimetry to measure the overall enthalpy change associated with template-directed nucleotide insertion and DNA extension. Specifically, we used families of hairpin self-priming templates in conjunction with an exonuclease-free DNA polymerase to study primer extension by one or more dA or dT residues. Our results reveal exothermic heats between –9.8 and –16.0 kcal/bp for template-directed enzymatic polymerization. These extension enthalpies depend on the identity of the inserting base, the primer terminus, and/or the preceding base. Despite the complexity of the overall process, the sign, magnitude, and sequence dependence of these insertion and extension enthalpies are consistent with nearest-neighbor data derived from DNA melting studies. We recognize that the overall process studied here involves contributions from a multitude of events, including dNTP to dNMP hydrolysis, phosphodiester bond formation, and enzyme conformational changes. It is therefore noteworthy that the overall enthalpic driving force per base pair is of a magnitude similar to that expected for addition of one base pair or base stack per insertion event, rather than that associated with the rupture and/or formation of covalent bonds, as occurs during this catalytic process. Our data suggest a constant sequence-independent background of compensating enthalpic contributions to the overall process of DNA synthesis, with discrimination expressed by differences in noncovalent interactions at the template–primer level. Such enthalpic discrimination underscores a model in which complex biological events are regulated by relatively modest energy balances involving weak interactions, thereby allowing subtle mechanisms of regulation.

Substrate-Activated Conformational Switch on Chaperones Encodes a Targeting Signal in Type III Secretion

The targeting of type III secretion (TTS) proteins at the injectisome is an important process in bacterial virulence. Nevertheless, how the injectisome specifically recognizes TTS substrates among all bacterial proteins is unknown. A TTS peripheral membrane ATPase protein located at the base of the injectisome has been implicated in the targeting process. We have investigated the targeting of the EspA filament protein and its cognate chaperone, CesAB, to the EscN ATPase of the enteropathogenic E. coli (EPEC). We show that EscN selectively engages the EspA-loaded CesAB but not the unliganded CesAB. Structure analysis revealed that the targeting signal is encoded in a disorder-order structural transition in CesAB that is elicited only upon the binding of its physiological substrate, EspA. Abrogation of the interaction between the CesAB-EspA complex and EscN resulted in severe secretion and infection defects. Additionally, we show that the targeting and secretion signals are distinct and that the two processes are likely regulated by different mechanisms.

Structural Instability Tuning as a Regulatory Mechanism in Protein-Protein Interactions

Protein-protein interactions mediate a vast number of cellular processes. Here, we present a regulatory mechanism in protein-protein interactions mediated by finely tuned structural instability and coupled with molecular mimicry. We show that a set of type III secretion (TTS) autoinhibited homodimeric chaperones adopt a molten globule-like state that transiently exposes the substrate binding site as a means to become rapidly poised for binding to their cognate protein substrates. Packing defects at the homodimeric interface stimulate binding, whereas correction of these defects results in less labile chaperones that give rise to nonfunctional biological systems. The protein substrates use structural mimicry to offset the weak spots in the chaperones and to counteract their autoinhibitory conformation. This regulatory mechanism of protein activity is evolutionarily conserved among several TSS systems and presents a lucid example of functional advantage conferred upon a biological system by finely tuned structural instability.

Energetic signatures of single base bulges: thermodynamic consequences and biological implications

DNA bulges are biologically consequential defects that can arise from template-primer misalignments during replication and pose challenges to the cellular DNA repair machinery. Calorimetric and spectroscopic characterizations of defect-containing duplexes reveal systematic patterns of sequence-context dependent bulge-induced destabilizations. These distinguishing energetic signatures are manifest in three coupled characteristics, namely: the magnitude of the bulge-induced duplex destabilization (ΔΔGBulge); the thermodynamic origins of ΔΔGBulge (i.e. enthalpic versus entropic); and, the cooperativity of the duplex melting transition (i.e. two-state versus non-two state). We find moderately destabilized duplexes undergo two-state dissociation and exhibit ΔΔGBulge values consistent with localized, nearest neighbor perturbations arising from unfavorable entropic contributions. Conversely, strongly destabilized duplexes melt in a non-two-state manner and exhibit ΔΔGBulge values consistent with perturbations exceeding nearest-neighbor expectations that are enthalpic in origin. Significantly, our data reveal an intriguing correlation in which the energetic impact of a single bulge base centered in one strand portends the impact of the corresponding complementary bulge base embedded in the opposite strand. We discuss potential correlations between these bulge-specific differential energetic profiles and their overall biological implications in terms of DNA recognition, repair and replication.

A continuous hyperchromicity assay to characterize the kinetics and thermodynamics of DNA lesion recognition and base excision

We report a continuous hyperchromicity assay (CHA) for monitoring and characterizing enzyme activities associated with DNA processing. We use this assay to determine kinetic and thermodynamic parameters for a repair enzyme that targets nucleic acid substrates containing a specific base lesion. This optically based kinetics assay exploits the free-energy differences between a lesion-containing DNA duplex substrate and the enzyme-catalyzed, lesion-excised product, which contains at least one hydrolyzed phosphodiester bond. We apply the assay to the bifunctional formamidopyrimidine glycosylase (Fpg) repair enzyme (E) that recognizes an 8-oxodG lesion within a 13-mer duplex substrate (S). Base excision/elimination yields a gapped duplex product (P) that dissociates to produce the diagnostic hyperchromicity signal. Analysis of the kinetic data at 25°C yields a Km of 46.6 nM for the E·S interaction, and a kcat of 1.65 min−1 for conversion of the ES complex into P. The temperature dependence reveals a free energy (ΔGb) of −10.0 kcal·mol−1 for the binding step (E + S ↔ ES) that is enthalpy-driven (ΔHb = −16.4 kcal·mol−1). The activation barrier (ΔG‡) of 19.6 kcal·mol−1 for the chemical step (ES ↔ P) also is enthalpic in nature (ΔH‡ = 19.2 kcal·mol−1). Formation of the transition state complex from the reactants (E + S ↔ ES‡), a pathway that reflects Fpg catalytic specificity (kcat/Km) toward excision of the 8-oxodG lesion, exhibits an overall activation free energy (ΔGT‡) of 9.6 kcal·mol−1. These parameters characterize the driving forces that dictate Fpg enzyme efficiency and specificity and elucidate the energy landscape for lesion recognition and repair.

Novel post-synthetic generation, isomeric resolution, and characterization of Fapy-dG within oligodeoxynucleotides: differential anomeric impacts on DNA duplex properties

Accumulation of damaged guanine nucleobases within genomic DNA, including the imidazole ring opened N6-(2-Deoxy-α,β-D-erythro-pentafuranosyl)-2,6-diamino-4-hydroxy-5-formylamidopyrimidine (Fapy-dG), is associated with progression of age-related diseases and cancer. To evaluate the impact of this mutagenic lesion on DNA structure and energetics, we have developed a novel synthetic strategy to incorporate cognate Fapy-dG site-specifically within any oligodeoxynucleotide sequence. The scheme involves the synthesis of an oligonucleotide precursor containing a 5-nitropyrimidine moiety at the desired lesion site via standard solid-phase procedures. Following deprotection and isolation, the Fapy-dG lesion is generated by catalytic hydrogenation and subsequent formylation. NMR assignment of the Fapy-dG lesion (X) embedded within a TXT trimer reveals the presence of rotameric and anomeric species. The latter have been characterized by synthesizing the tridecamer oligodeoxynucleotide d(GCGTACXCATGCG) harboring Fapy-dG as the central residue and developing a protocol to resolve the isomeric components. Hybridization of the chromatographically isolated fractions with their complementary d(CGCATGCGTACGC) counterpart yields two Fapy-dG·C duplexes that are differentially destabilized relative to the canonical G·C parent. The resultant duplexes exhibit distinct thermal and thermodynamic profiles that are characteristic of α- and β-anomers, the former more destabilizing than the latter. These anomer-specific impacts are discussed in terms of differential repair enzyme recognition, processing and translesion synthesis.

Impact of α-Hydroxy-Propanodeoxyguanine Adducts on DNA Duplex Energetics: Opposite Base Modulation and Implications for Mutagenicity and Genotoxicity

Acrolein is an alpha,beta-unsaturated aldehyde that is a major environmental pollutant, as well as a product of cellular metabolism. DNA bases react with acrolein to form two regioisomeric exocyclic guanine adducts, namely gamma-hydroxy-propanodeoxyguanosine (gamma-OH-PdG) and its positional isomer alpha-hydroxy-propanodeoxyguanosine (alpha-OH-PdG). The gamma-OH-PdG isomer adopts a ring-opened conformation with minimal structural perturbation of the DNA host duplex. Conversely, the alpha-OH-PdG isomer assumes a ring-closed conformation that significantly disrupts Watson-Crick base-pair alignments within the immediate vicinity of the damaged site. We have employed a combination of calorimetric and spectroscopic techniques to characterize the thermodynamic origins of these lesion-induced structural alterations. Specifically, we have assessed the energetic impact of alpha-OH-PdG centered within an 11-mer duplex by hybridizing the adduct-containing oligonucleotide with its complementary strand harboring a central base N [where N = C or A], yielding a pair of duplexes containing the nascent lesion (alpha-OH-PdG.C) or mismatched adduct (alpha-OH-PdG.A), respectively. Our data reveal that the nascent lesion is highly destabilizing, whereas its mismatched counterpart partially ameliorates alpha-OH-PdG-induced destabilization. Collectively, our data provide energetic characterizations of the driving forces that modulate error-free versus error-prone DNA translesion synthesis. The biological implications of our findings are discussed in terms of energetically probing acrolein-mediated mutagenicity versus adduct-induced genotoxicity.