Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:2.7.7.7 (DNA polymerase)
 17,007 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Anisotropic magnetic susceptibility tensors chi of paramagnetic metal ions are manifested in pseudocontact shifts, residual dipolar couplings, and other paramagnetic observables that present valuable long-range information for structure determinations of protein-ligand complexes. A program was developed for automatic determination of the chi-tensor anisotropy parameters and amide resonance assignments in proteins labeled with paramagnetic metal ions. The program requires knowledge of the three-dimensional structure of the protein, the backbone resonance assignments of the diamagnetic protein, and a pair of 2D 15N-HSQC or 3D HNCO spectra recorded with and without paramagnetic metal ion. It allows the determination of reliable chi-tensor anisotropy parameters from 2D spectra of uniformly 15N-labeled proteins of fairly high molecular weight. Examples are shown for the 185-residue N-terminal domain of the subunit epsilon from E. coli DNA polymerase III in complex with the subunit theta and La3+ in its diamagnetic and Dy3+, Tb3+, and Er3+ in its paramagnetic form.
J Biomol NMR 2006 Jun
PMID:Efficient chi-tensor determination and NH assignment of paramagnetic proteins. 1676 2

The potent, ubiquitous environmental mutagen/carcinogen benzo[a]pyrene (B[a]P) induces a single major adduct [+ta]-B[a]P-N2-dG, whose bypass in most cases results in either no mutation (dCTP insertion) or a G-->T mutation (dATP insertion). Translesion synthesis (TLS) of [+ta]-B[a]P-N2-dG generally requires DNA polymerases (DNAPs) in the Y-family, which exist in cells to bypass DNA damage caused by chemicals and radiation. A molecular dynamics (MD) study is described with dCTP opposite [+ta]-B[a]P-N2-dG in Dpo4, which is the best studied Y-family DNAP from a structural point of view. Two orientations of B[a]P-N2-dG (BPmi5 and BPmi3) are considered, along with two orientations of the dCTP (AS1 and AS2), as outlined next. Based on NMR studies, the pyrene moiety of B[a]P-N2-dG is in the minor groove, when paired with dC, and can point toward either the base on the 5'-side (BPmi5) or the 3'-side (BPmi3). Based on published X-ray structures, Dpo4 appears to have two partially overlapping active sites. The architecture of active site 1 (AS1) is similar to all other families of DNAPs (e.g., the shape of the dNTP). Active site 2 (AS2), however, is non-canonical (e.g., the beta- and gamma-phosphates in AS2 are approximately where the alpha- and beta-phosphates are in AS1). In the Dpo4 models generated herein, using the BPmi3 orientation the pyrene moiety of [+ta]-B[a]P-N2-dG points toward the duplex region of the DNA, and is accommodated without distortions in AS1, but with distortions in AS2. Considering the BPmi5 orientation, the pyrene moiety points toward the ss-region of DNA in Dpo4, and sits in a hole defined by the fingers and little fingers domain ("chimney"); BPmi5 is accommodated in AS2 without significant distortions, but poorly in AS1. In summary, when dCTP is paired with [+ta]-B[a]P-N2-dG in the two overlapping active sites in Dpo4, the pyrene in the BPmi3 orientation is accommodated better in active site 1 (AS1), while the pyrene in the BPmi5 orientation is accommodated better in AS2. Finally, we discuss why Y-family DNAPs might have two catalytic active sites.
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PMID:Molecular modeling benzo[a]pyrene N2-dG adducts in the two overlapping active sites of the Y-family DNA polymerase Dpo4. 1678 74

We previously reported the mode of inhibition of DNA polymerase beta (pol. beta) by long chain fatty acids and a bile acid, involving binding analyses to the N-terminal 8-kDa DNA binding domain. Here we describe a site-directed mutational analysis in which the key amino acids (L11, K35, H51, K60, L77, and T79), which are direct interaction sites in the domain, were substituted with K, A, A, A, K, and A, respectively. And their pol. beta interactions with a C24-long chain fatty acid, nervonic acid (NA), and a bile acid, lithocholic acid (LCA), were investigated by gel mobility shift assay and NMR spectroscopy. In the case of K35A, there was complete loss of DNA binding activity while K60A hardly has any activity. In contrast the other mutations had no appreciable effects. Thus, K35 and K60 are key amino acid sites for binding to template DNA. The DNA binding activities of L11K, H51A, and T79A as well as the wild type were inhibited by NA to the same extent. T79A demonstrated a disturbed interaction with LCA. 1H-15N HSQC NMR analysis indicated that despite their many similarities, the wild-type and the mutant proteins displayed some significant chemical shift differences. Not only were the substituted amino acid residues three-dimensionally shifted, but some amino acids which are positioned far distant from the key amino acids showed a shift. These results suggest that the interaction surface was significantly distorted with the result that LCA could not bind to the domain. These findings confirm our previous biochemical and 3D structural proposals concerning inhibition by NA and LCA.
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PMID:Site-directed mutational analysis of structural interactions of low molecule compounds binding to the N-terminal 8 kDa domain of DNA polymerase beta. 1699 74

Paramagnetic metal ions in proteins provide a rich source of structural information, but the resonance assignments required to extract the information can be challenging. Here we demonstrate that paramagnetically shifted (15)N-HSQC cross-peaks can be assigned using N(Z)-exchange spectroscopy under conditions in which the paramagnetic form of the protein is in dynamic equilibrium with its diamagnetic form. Even slow exchange of specifically bound metal ions may be detected within the long lifetime of (15)N longitudinal magnetization of large proteins at high magnetic fields. Alternatively, the exchange can be accelerated using an excess of metal ions. In the resulting exchange spectra, paramagnetic (15)N resonances become visible for residues that are not directly observed in a conventional (15)N-HSQC spectrum due to paramagnetic (1)H(N) broadening. The experiments are illustrated by the 30 kDa lanthanide-binding epsilon186/theta complex of DNA polymerase III in the presence of sub-stoichiometric amounts of Dy(3+) or a mixture of Dy(3+) and La(3+).
J Biomol NMR 2007 Jan
PMID:Assignment of paramagnetic (15)N-HSQC spectra by heteronuclear exchange spectroscopy. 1709 5

Slipped frameshift intermediates can occur when DNA polymerase slows or stalls at sites of DNA lesions. However, this phenomenon is much less common when unmodified DNA is replicated. In order to study the effect of templating bases on the alignment of primer-templates, NMR structural investigation has been performed on primer-template oligonucleotide models which mimic the situation that dNTP has just been incorporated opposite template. NMR evidence reveals the occurrence of misalignment when dGTP is incorporated opposite template T with a downstream nucleotide C. Depending on the template sequence, further extension of the primer can lead to realignment.
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PMID:NMR investigation of DNA primer-template models: structural insights into dislocation mutagenesis in DNA replication. 1710 73

With an increasing number of structural, kinetic, and modeling studies of diverse DNA polymerases in various contexts, a complex dynamical view of how atomic motions might define molecular "gates" or checkpoints that contribute to polymerase specificity and efficiency is emerging. Such atomic-level information can offer insights into rate-limiting conformational and chemical steps to help piece together mechanistic views of polymerases in action. With recent advances, modeling and dynamics simulations, subject to the well-appreciated limitations, can access transition states and transient intermediates along a reaction pathway, both conformational and chemical, and such information can help bridge the gap between experimentally determined equilibrium structures and mechanistic enzymology data. Focusing on DNA polymerase beta (pol beta), we present an emerging view of the geometric, energetic, and dynamic selection criteria governing insertion rate and fidelity mechanisms of DNA polymerases, as gleaned from various computational studies and based on the large body of existing kinetic and structural data. The landscape of nucleotide insertion for pol beta includes conformational changes, prechemistry, and chemistry "avenues", each with a unique deterministic or stochastic pathway that includes checkpoints for selective control of nucleotide insertion efficiency. For both correct and incorrect incoming nucleotides, pol beta's conformational rearrangements before chemistry include a cascade of slow and subtle side chain rearrangements, followed by active site adjustments to overcome higher chemical barriers, which include critical ion-polymerase geometries; this latter notion of a prechemistry avenue fits well with recent structural and NMR data. The chemical step involves an associative mechanism with several possibilities for the initial proton transfer and for the interaction among the active site residues and bridging water molecules. The conformational and chemical events and associated barriers define checkpoints that control enzymatic efficiency and fidelity. Understanding the nature of such active site rearrangements can facilitate interpretation of existing data and stimulate new experiments that aim to probe enzyme features that contribute to fidelity discrimination across various polymerases via such geometric, dynamic, and energetic selection criteria.
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PMID:Regulation of DNA repair fidelity by molecular checkpoints: "gates" in DNA polymerase beta's substrate selection. 1717 36

Three-dimensional structures of DNA N-glycosylases and N-glycosylase/apyrimidine/apurine (AP)-lyase enzymes and other critical components of base excision repair (BER) machinery including structure-specific nuclease, repair polymerase, DNA ligase, and PCNA tethering complexes reveal the overall unity of the simple cut and patch process of DNA repair for damaged bases. In general, the damage-specific excision is initiated by structurally-variable DNA glycosylases targeted to distinct base lesions. This committed excision step is followed by a subsequent damage-general processing of the resulting abasic sites and 3' termini, the insertion of the correct base by a repair DNA polymerase, and finally sealing the nicked backbone by DNA ligase. However, recent structures of protein-DNA and protein-protein complexes and other BER machinery are providing a more in-depth look into the intricate functional diversity and complexity of maintaining genomic integrity despite very high levels of constant DNA base damage from endogenous as well as environmental agents. Here we focus on key discoveries concerning BER structural biology that speak to better understanding the damage recognition, reaction mechanisms, conformational controls, coordinated handoffs, and biological activities including links to cancer. As the three-dimensional crystal and NMR structures for the protein and DNA complexes of all major components of the BER system have now been determined, we provide here a relatively complete description of the key complexes starting from DNA base damage detection and excision to the final ligation process. As our understanding of BER structural biology and the molecular basis for cancer improve, we predict that there will be multiple links joining BER enzyme mutations and cancer predispositions, such as now seen for MYH. Currently, structural results are realizing the promise that high-resolution structures provide detailed insights into how these BER proteins function to specifically recognize, remove, and repair DNA base damage without the release of toxic and mutagenic intermediates.
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PMID:The intricate structural chemistry of base excision repair machinery: implications for DNA damage recognition, removal, and repair. 1720 22

Adduct-induced conformational heterogeneity complicates the understanding of how DNA adducts exert mutation. A case in point is the N-deacetylated AF lesion [N-(2'-deoxyguanosin-8-yl)-2-aminofluorene], the major adduct derived from the strong liver carcinogen N-acetyl-2-aminofluorene. Three conformational families have been previously characterized and are dependent on the positioning of the aminofluorene rings: B is in the "B-DNA" major groove, S is "stacked" into the helix with base-displacement, and W is "wedged" into the minor groove. Here, we conducted (19)F NMR, CD, T(m), and modeling experiments at various primer positions with respect to a template modified by a fluorine tagged AF-adduct (FAF). In the first set, the FAF-G was paired with C and in the second set it was paired with A. The FAF-G:C oligonucleotides were found to preferentially adopt the B or S-conformers while the FAF-G:A mismatch ones preferred the B and W-conformers. The conformational preferences of both series were dependent on temperature and complementary strand length; the largest differences in conformation were displayed at lower temperatures. The CD and T(m) results are in general agreement with the NMR data. Molecular modeling indicated that the aminofluorene moiety in the minor groove of the W-conformer would impose a steric clash with the tight-packing amino acid residues on the DNA binding area of the Bacillus fragment (BF), a replicative DNA polymerase. In the case of the B-type conformer, the carcinogenic moiety resides in the solvent-exposed major groove throughout the replication/translocation process. The present dynamic NMR results, combined with previous primer extension kinetic data by Miller & Grollman, support a model in which adduct-induced conformational heterogeneities at positions remote from the replication fork affect polymerase function through a long-range DNA-protein interaction.
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PMID:Examination of the long-range effects of aminofluorene-induced conformational heterogeneity and its relevance to the mechanism of translesional DNA synthesis. 1721 58

The use of (15)N-relaxation data for determination of the dissociation constant of a protein-protein complex is proposed for the situation where a (15)N-labeled protein is bound to an unlabeled protein of high molecular weight, and the chemical exchange between bound and free protein is fast on the NMR time scale. The approach is shown to be suitable for estimating dissociation constants in the micromolar to millimolar range, using protein solutions at relatively low concentration. An example is shown for the interaction between two subunits from the Escherichia coli DNA polymerase III complex, involving a (15)N-labeled fragment of the C-terminal domain of the tau subunit (15 kDa) and the unlabeled alpha subunit (130 kDa).
J Biomol NMR 2007 May
PMID:Measurement of dissociation constants of high-molecular weight protein-protein complexes by transferred 15N-relaxation. 1739 Jan 6

The use of cationic polymers for the delivery of DNA to mammalian cells has generated significant interest due to the intrinsic properties associated with these delivery vector systems. One particular system utilizing polyethylenimine (PEI) has been rigorously investigated. A major drawback associated with PEI is the cytotoxicity of the vector/delivery system. In an effort to combat this adverse side effect we have synthesized a novel random block copolymer based upon low molecular weight PEI. Here we report the grafting of Traut's reagent to residual primary amines of PEI to form a random block copolymer. The copolymer introduces a disulfide bridge upon oxidation of Traut's reagent capable of intracellular reduction. We confirm the successful grafting of this agent through FTIR and C-13 NMR. Molecular weight determination of the grafted copolymer was performed through HPLC-SEC and light scattering experiments. This polymer retains the ability to deliver GFP encoding plasmid DNA to 3T3 fibroblasts. Transfection levels were found to be approximately 90%. Transfection of T7 RNA dependent DNA polymerase was also performed utilizing our copolymer. We find successful activation of a virally introduced RNA transcript.
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PMID:Enhanced delivery of bioactive molecules to intracellular environments utilizing a cytosolically reducable grafted analog of polyethylenimine. 1745 Aug 55


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