Physicochemical analysis of structural changes in DNA modified with glucose

Reactions of reducing sugars with free amino groups of proteins can form advanced glycation end products (AGEs). While the formation of nucleoside AGEs has been studied in detail, no extensive work has been carried out to assess DNA Amadori and DNA advanced glycation end products. In this study, we report biophysical/chemical characterization of glucose-induced changes in DNA, as well as DNA Amadori and DNA advanced glycation end products. Glucose treated DNA exhibited hyperchromicity, decrease in melting temperature, and enhanced emission intensity in a time dependent manner. Formation of DNA Amadori product and DNA advanced glycation end products, mainly CEdG (N(2)-carboxyethyl-2'-deoxyguanosine), were the major outcome of the study.     

Auxins in the development of an arbuscular mycorrhizal symbiosis in maize

While the levels of free auxins in maize (Zea mays L.) roots during arbuscular mycorrhiza formation have been previously described in detail, conjugates of indole-3-acetic acid (IAA) and indole-3-butyric acid (IBA) with amino acids and sugars were neglected. In this study, we have therefore determined free, ester and amide bound auxins in roots of maize inoculated with Glomus intraradices during early stages of the colonization process. Ester conjugates of IAA and IBA were found only in low amounts and they did not increase in AM colonized roots. The Levels of IAA and IBA amide conjugates increased 20 and 30 days past inoculation (dpi). The formation of free and conjugated IBA but not IAA was systemically induced during AM colonization in leaves of maize plants. This implicated a role for auxin conjugate synthesis and hydrolysis during AM. We have therefore investigated the in vivo metabolism of 3H-labeled IBA by TLC but only slight differences between control and AM-inoculated roots were observed. The activity of auxin conjugate hydrolase activity measured with three different putative substrates showed a decrease in infected roots compared to controls. The fluorinated IBA analog TFIBA inhibited IBA formation in leaves after application to the root system, but was not transported from roots to shoots. AM hyphae were also not able to transport TFIBA. Our results indicate complex control mechanisms to regulate the levels of free and conjugated auxins, which are locally and systemically induced during early stages of the formation of an arbuscular mycorrhizal symbiosis.     

The effect of structural water molecules on the normal mode spectrum of dTn . dAn x dTn DNA

In this paper we present a theoretical treatment of triplex B type DNA hydration using normal mode calculation techniques. Discrete solvent is added as spines of hydration in the Watson-Crick and Crick-Hoogsteen grooves as well as water bridges between the Phosphate groups. The effect of binding the discrete structural waters on the normal mode of vibration of the system was studied by introducing a parameter, Xw, that is proportional to the degree of water binding and inversely proportional to the relative humidity (RH) of the system. We examined the variation of the dipole moments of characteristic modes with Xw. The results show that there is a direct relationship between the degree of binding of the water molecules to the atoms in the triple helix, the relative humidity of the system and the conformation and stability of the triple helix. At high RH and Xw = 0:0 the triple helix has mostly B type conformation characteristics, with C'2 -endo sugars. The emergence of normal modes of vibration characteristic to the A type conformation (C'3 - endo sugars) at Xw = 0:4 and 60% RH indicates a conformational shift towards A-type for some of the sugars between Xw = 0.2 (80% RH) and Xw = 0.4 (60% RH). These results are in agreement with the "economy of hydration hypothesis" of Saenger (Saenger et al., 1986) which maintains that the main difference in the hydration of A- and B- forms of DNA is the presence of water bridges between adjacent Phosphate groups in the low-hydration A-form but not in the B- form. Free energy calculations for the triplex DNA with structural waters show that there is a minimum of the free energy at Xw = 0.2 and the free energy increases with Xw and becomes larger than the free energy of the B conformation without structural waters for Xw equal to and larger than 0.4. This result indicates that the B conformation is more stable with bound structural water molecules (for degrees of water binding that are not over 20% higher than the degree of binding between bulk water molecules). The structural water molecules are bound much tighter in the A conformation than in the B conformation. The model predicts that the B to A transition occurs at higher relative humidities in D2O than in H2O. Part of these results (Dadarlat, 1997) have been subsequently confirmed by the experimental work and MD simulations of Ouali (Ouali et al., 1997). The experimental results showed that the N-type sugars corresponding to the A conformation are clearly detected below 75% RH.     

Inhibitory effect of some acetyl esters and acetamides on glycation of the histone H1

Non-enzymatic glycosylation (glycation) is a spontaneous set of reactions between reducing sugars and free amino groups in proteins or other biomolecules leading to the formation of fluorescent and coloured compounds known as advanced glycation end products (AGEs). AGEs cause structural changes of key proteins in humans, and therefore they are related with a number of physiological processes and diseases such as aging, atherosclerosis, cataract, arthritis, Alzheimer's disease. Two main strategies have been employed to prevent the formation of AGEs: a) low carbohydrate diet and b) pharmacological intervention. The latter includes treatment with reactive compounds which might be either sugar competitors (type A), carbonyl traps (type B) or free radical trapping antioxidants (type C). Acetylsalicylic acid (ASA, aspirin) is a good example of sugar competitor capable of inhibiting glycation by acetylating epsilon-amino groups of lysine residues in proteins. Taking into consideration the inhibiting effect of ASA on glycation we designed to study the antiglycation activity of other acetyl group-containing compounds (acetamides and acetyl esters) using the lysine-rich protein histone H1 as a model. The glycation of the histone H1 was carried out by either fructose or a complex mixture of glycating agents obtained from E. coli and monitored by fluorescent spectroscopy, SDS-PAGE and measurement of the content of reactive carbonyl groups in the target protein. Our results showed that the inhibitory effect of phenyl acetate, acetanilide, 4-acetamidophenylacetic acid and isopropenyl acetate was comparable to that of ASA. Based on the obtained results we conclude that these compounds act as free radical scavengers protecting proteins from the damaging effect of reactive oxygen species produced during the formation of AGEs.     

Unprocessed viral DNA could be the primary target of the HIV-1 integrase inhibitor raltegravir

Integration of HIV DNA into host chromosome requires a 3'-processing (3'-P) and a strand transfer (ST) reactions catalyzed by virus integrase (IN). Raltegravir (RAL), commonly used in AIDS therapy, belongs to the family of IN ST inhibitors (INSTIs) acting on IN-viral DNA complexes (intasomes). However, studies show that RAL fails to bind IN alone, but nothing has been reported on the behaviour of RAL toward free viral DNA. Here, we assessed whether free viral DNA could be a primary target for RAL, assuming that the DNA molecule is a receptor for a huge number of pharmacological agents. Optical spectroscopy, molecular dynamics and free energy calculations, showed that RAL is a tight binder of both processed and unprocessed LTR (long terminal repeat) ends. Complex formation involved mainly van der Waals forces and was enthalpy driven. Dissociation constants (Kds) revealed that RAL affinity for unbound LTRs was stronger than for bound LTRs. Moreover, Kd value for binding of RAL to LTRs and IC50 value (half concentration for inhibition) were in same range, suggesting that RAL binding to DNA and ST inhibition are correlated events. Accommodation of RAL into terminal base-pairs of unprocessed LTR is facilitated by an extensive end fraying that lowers the RAL binding energy barrier. The RAL binding entails a weak damping of fraying and correlatively of 3'-P inhibition. Noteworthy, present calculated RAL structures bound to free viral DNA resemble those found in RAL-intasome crystals, especially concerning the contacts between the fluorobenzyl group and the conserved 5'C(4)pA(3)3' step. We propose that RAL inhibits IN, in binding first unprocessed DNA. Similarly to anticancer drug poisons acting on topoisomerases, its interaction with DNA does not alter the cut, but blocks the subsequent joining reaction. We also speculate that INSTIs having viral DNA rather IN as main target could induce less resistance.     

Neocarzinostatin chromophore-DNA adducts: evidence for a covalent linkage to the oxidized C-5'' of deoxyribose.

The nonprotein chromophore of neocarzinostatin forms a variety of adducts with DNA. The predominant adduct recovered from nuclease digests of chromophore-treated poly(dA-dT). poly(dA-dT) is a compound with structure chromophore-d(TpApT). Mild acid hydrolysis of this compound released free adenine, while snake venom exonuclease (pH 6.5) released 5'-dTMP leaving in both cases adducts of slightly altered chromatographic mobility. These results eliminate adenine and 5'-dTMP as possible sites of covalent chromophore attachment. Electrophoresis data suggest that the adduct is not a phosphotriester. At pH 8.6, chromophore-d(TpApT) spontaneously hydrolyzed, releasing chromophore and 3'-dTMP, leaving a modified d(ApT) which contained deoxyadenosine-5'-aldehyde. Deoxyadenosine-5'-aldehyde was released from the modified d(ApT) by snake venom exonuclease, and identified by a series of derivatizations including 1) mild oxidation to deoxyadenosine-5'-carboxylic acid, 2) NaBH4 reduction to deoxyadenosine, and 3) formation of a hydrazone with phenylhydrazine. Since deoxyadenosine-5'-aldehyde cannot exist as such in the chromophore-d(TpApT) adduct, we suggest that the chromophore may be covalently attached to the C-5' of deoxyadenosine as a phosphorylacetal or similar structure. Hydrolysis of the chromophore-acetal bond at pH 8.6 would leave a phosphorylhemiacetal on C-5', which would be expected to spontaneously decompose to yield the observed 3'-phosphate and 5'-aldehyde groups.     

Isolation and characterization of the native glycoprotein from pig small-intestinal mucus.

Glycoprotein from pig small-intestinal mucus was isolated free of non-covalently bound protein and nucleic acid with a yield of over 60%. No non-covalently bound protein could be detected by sodium dodecyl sulphate/polyacrylamide-gel electrophoresis or by equilibrium centrifugation in a density gradient of CsCl with 4 M-guanidinium chloride. The intrinsic viscosity and reduced viscosity of the glycoprotein preparations rose with the removal of non-covalently bound protein and nucleic acid from the glycoprotein, evidence that non-covalently bound protein does not contribute to the rheological properties of the glycoprotein in the mucus. The pure glycoprotein, in contrast with impure preparations, gelled at the same concentration of glycoprotein as that present in the gel in vivo. The glycoprotein was a single component, as judged by gel filtration and analytical ultracentrifugation. The distribution of sedimentation coefficients was polydisperse but unimodal with an s025,w of 14.5S and a molecular weight of 1.72 X 10(6). The chemical composition of the glycoprotein was 77% carbohydrate and 21% protein, 52% of which was serine, threonine and proline. The glycoprotein had a strong negative charge and contained 3.1% and 18.3% by weight ester sulphate and sialic acid respectively. The molar proportion of N-acetylgalactosamine was nearly twice that of any of the other sugars present, the glycoprotein had A and H blood-group activity and the average maximum length of the carbohydrate chains was deduced to be six to eight sugar residues.     

Determination and analysis of site-specific 125I decay-induced DNA double-strand break end-group structures

End groups contribute to the structural complexity of radiation-induced DNA double-strand breaks (DSBs). As such, end-group structures may affect a cell's ability to repair DSBs. The 3'-end groups of strand breaks caused by gamma radiation, or oxidative processes, under oxygenated aqueous conditions have been shown to be distributed primarily between 3'-phosphoglycolate and 3'-phosphate, with 5'-phosphate ends in both cases. In this study, end groups of the high-LET-like DSBs caused by 125I decay were investigated. Site-specific DNA double-strand breaks were produced in plasmid pTC27 in the presence or absence of 2 M DMSO by 125I-labeled triplex-forming oligonucleotide targeting. End-group structure was assessed enzymatically as a function of the DSB end to serve as a substrate for ligation and various forms of end labeling. Using this approach, we have demonstrated 3'-hydroxyl (3'-OH) and 3'-phosphate (3'-P) end groups and 5'-ends (> or = 42%) terminated by phosphate. A 32P postlabeling assay failed to detect 3'-phosphoglycolate in a restriction fragment terminated by the 125I-induced DNA double-strand break, and this is likely due to restricted oxygen diffusion during irradiation as a frozen aqueous solution. Even so, end-group structure and relative distribution varied as a function of the free radical scavenging capacity of the irradiation buffer.     

Kinetic studies of DNA cleavage reactions catalyzed by an ATP-dependent deoxyribonuclease on a 27-MHz quartz-crystal microbalance

Catalytic DNA cleavage reactions by an ATP-dependent deoxyribonuclease (DNase) from Micrococcus luteus were monitored directly with a DNA-immobilized 27-MHz quartz-crystal microbalance (QCM). The 27-MHz QCM is a very sensitive mass-measuring device in aqueous solution, as the frequency decreases linearly with increasing mass on the electrode at a nanogram level. Three steps in ATP-dependent DNA hydrolysis reactions, including (1) binding of DNase to the end of double-stranded DNA (dsDNA) on the QCM electrode (mass increase), (2) degradation of one strand of dsDNA in the 3' --> 5' direction depending on ATP (mass decrease), and (3) release of the enzyme from the nonhydrolyzed 5'-free-ssDNA (mass decrease), could be monitored stepwise from the time dependencies of QCM frequency changes. Kinetic parameters for each step were obtained as follows. The binding constant (K(a)) of DNase to the dsDNA was determined as (28 +/- 2) x 10(6) M(-)(1) (k(on) = (8.0 +/- 0.3) x 10(3) M (-)(1) s(-)(1) and k(off) = (0.29 +/-0.01) x 10(-)(3) s(-)(1)), and it decreased to (0.79 +/- 0.16) x 10(6) M(-)(1) (k'(on) = (2.3 +/- 0.2) x 10(3) M (-)(1) s(-)(1) and k'(off) = (2.9 +/- 0.1) x 10(-)(3) s(-)(1)) for the completely nonhydrolyzed 5'-free ssDNA. This is the reason the DNase bound to the dsDNA substrate can easily release from the nonhydrolyzed 5'-free-ssDNA after the complete hydrolysis of the 3' --> 5' direction of the complementary ssDNA. K(a) values depended on the DNA structures on the QCM, and the order of these values was as follows: the dsDNA having a 4-base-mismatched base-pair end (3) > the dsDNA having a 5' 15-base overhanging end (2) > the dsDNA having a blunt end (1) > the ssDNA having a 3'-free end (4) > the ssDNA having a 5'-free end (5). Thus, DNase hardly recognized the free 5' end of ssDNA. Michaelis-Menten parameters (K(m) for ATP and k(cat)) of the hydrolysis process also could be obtained, and the order of k(cat)/K(m) was as follows: the dsDNA having a blunt end (1) approximately the dsDNA having a 4-base-mismatched base-pair end (3) > the ssDNA having a free 3' end (4) > the ssDNA having a free 5' end (5). Thus, DNase could not recognize and not hydrolyze the free 5' end of ssDNA. The DNA hydrolysis reaction could be driven by dATP and GTP (purine base) as well as ATP, whereas the cleavage efficiency was very low driven with UTP, CTP (pyrimidine base), ADP, and AMP.     

How an enzyme binds the C1 carrier tetrahydromethanopterin. Structure of the tetrahydromethanopterin-dependent formaldehyde-activating enzyme (Fae) from Methylobacterium extorquens AM1

Tetrahydromethanopterin (H4 MPT) is a tetrahydrofolate analogue involved as a C1 carrier in the metabolism of various groups of microorganisms. How H4MPT is bound to the respective C1 unit converting enzymes remained elusive. We describe here the structure of the homopentameric formaldehyde-activating enzyme (Fae) from Methylobacterium extorquens AM1 established at 2.0 angstrom without and at 1.9 angstrom with methylene-H4MPT bound. Methylene-H4MPT is bound in an "S"-shaped conformation into the cleft formed between two adjacent subunits. Coenzyme binding is accompanied by side chain rearrangements up to 5 angstrom and leads to a rigidification of the C-terminal arm, a formation of a new hydrophobic cluster, and an inversion of the amide side chain of Gln88. Methylene-H4MPT in Fae shows a characteristic kink between the tetrahydropyrazine and the imidazolidine rings of 70 degrees that is more pronounced than that reported for free methylene-H4MPT in solution (50 degrees). Fae is an essential enzyme for energy metabolism and formaldehyde detoxification of this bacterium and catalyzes the formation of methylene-H4MPT from H4MPT and formaldehyde. The molecular mechanism ofthis reaction involving His22 as acid catalyst is discussed.     

Backbone dynamics of sequence specific recognition and binding by the yeast Pho4 bHLH domain probed by NMR

Backbone dynamics of the basic/helix-loop-helix domain of Pho4 from Saccharomyces cerevisae have been probed by NMR techniques, in the absence of DNA, nonspecifically bound to DNA and bound to cognate DNA. Alpha proton chemical shift indices and nuclear Overhauser effect patterns were used to elucidate the secondary structure in these states. These secondary structures are compared to the co-crystal complex of Pho4 bound to a cognate DNA sequence (Shimizu T. Toumoto A, Ihara K, Shimizu M, Kyogou Y, Ogawa N, Oshima Y, Hakoshima T, 1997, EMBO J 15: 4689-4697). The dynamic information provides insight into the nature of this DNA binding domain as it progresses from free in solution to a specifically bound DNA complex. Relative to the unbound form, we show that formation of either the nonspecific and cognate DNA bound complexes involves a large change in conformation and backbone dynamics of the basic region. The nonspecific and cognate complexes, however, have nearly identical secondary structure and backbone dynamics. We also present evidence for conformational flexibility at a highly conserved glutamate basic region residue. These results are discussed in relation to the mechanism of sequence specific recognition and binding.     

Conformational Characteristics and Correlations in Crystal Structures of Nucleic Acid Oligonucleotides: Evidence for Sub-states

Abstract

Sugar phosphate backbone conformations are a structural element inextricably involved in a complete understanding of specific recognition nucleic acid ligand interactions, from early stage discrimination of the correct target to complexation per se, including any structural adaptation on binding. The collective results of high resolution DNA, RNA and protein/DNA crystal structures provide an opportunity for an improved and enhanced statistical analysis of standard and unusual sugar-phosphate backbone conformations together with corresponding dinucleotide sequence effects as a basis for further exploration of conformational effects on binding. In this study, we have analyzed the conformations of all relevant crystal structures in the nucleic acids data base, determined the frequency distribution of all possible ?, ζ, α, β and γ backbone angle arrangements within four nucleic acid categories (A-RNA and A-DNA, free and bound B-DNA) and explored the relationships between backbone angles, sugar puckers and selected helical parameters. The trends in the correlations are found to be similar regardless of the nucleic acid category. It is interesting that specific structural effects exhibited by the different unusual backbone sub-states are in some cases contravariant. Certain α/γ changes are accompanied by C3′ endo (north) sugars, small twist angles and positive values of base pair roll, and favor a displacement of nucleotide bases towards the minor groove compared to that of canonical B form structures. Unusual ?/ζ combinations occur with C2′ (south) sugars, high twist angles, negative values of base pair roll, and base displacements towards the major groove. Furthermore, any unusual backbone correlates with a reduced dispersion of equilibrium structural parameters of the whole double helix, as evidenced by the reduced standard deviations of almost all con- formational parameters. Finally, a strong sequence effect is displayed in the free oligomers, but reduced somewhat in the ligand bound forms. The most variable steps are GpA and CpA, and, to a lesser extent, their partners TpC and TpG. The results provide a basis for considering if the variable and non-variable steps within a biological active sequence precisely determine morphological structural features as the curvature direction, the groove depth, and the accessibility of base pair for non covalent associations.     

Phosphorylation of the Oxytricha telomere protein: possible cell cycle regulation.

In the macronucleus of the ciliate Oxytricha nova, telomeres end with single-stranded (T4G4)2 DNA bound to a heterodimeric telomere protein (alpha beta). Both the alpha and beta subunits (alpha-TP and beta-TP) were phosphorylated in asynchronously growing Oxytricha; beta-TP was phosphorylated to a much higher degree. In vitro, mouse cyclin-dependent kinases (Cdks) phosphorylated beta-TP in a lysine-rich domain that is not required for specific DNA binding but is implicated in higher order structure formation of telomeres. Therefore, phosphorylation of beta-TP could modulate a function of the telomere protein that is separate from specific DNA binding. Phosphoamino acid analysis revealed that the mouse Cdks modify predominantly threonine residues in beta-TP, consistent with the observation that beta-TP contains two consensus Cdk recognition sequences containing threonine residues. In Xenopus egg extracts that undergo cell cycling, beta-TP was phosphorylated in M phase and dephosphorylated in interphase. This work provides the first direct evidence of phosphorylation at telomeres in any organism, as well as indirect evidence for cell cycle regulation of telomere phosphorylation. The Cdc2/cyclin A and Cdc2/cyclin B kinases are required for major mitotic events. An attractive model is that phosphorylation of beta-TP by these kinases is required for the breakdown of telomere associations with each other and/or with nuclear structures prior to nuclear division.     

Dimerization interfaces formed between the DNA binding domains determine the cooperative binding of RXR/RAR and RXR/TR heterodimers to DR5 and DR4 elements.

We have previously reported that the binding site repertoires of heterodimers formed between retinoid X receptor (RXR) and either retinoic acid receptor (RAR) or thyroid hormone receptor (TR) bound to response elements consisting of directly repeated PuG(G/T)TCA motifs spaced by 1-5 bp [direct repeat (DR) elements 1-5] are highly similar to those of their corresponding DNA binding domains (DBDs). We have now mapped the dimerization surfaces located in the DBDs of RXR, RAR and TR, which are responsible for cooperative interaction on DR4 (RXR and TR) and DR5 (RXR and RAR). The D-box of the C-terminal CII finger of RXR provides one of the surfaces which is specifically required for the formation of the heterodimerization interfaces on both DR4 and DR5. Heterodimerization with the RXR DBD on DR5 specifically requires the tip of the RAR CI finger as the complementary surface, while a 7 amino acid sequence encompassing the 'prefinger region', but not the TR CI finger, is specifically required for efficient dimerization of TR and RXR DBDs on DR4. Importantly, DBD swapping experiments demonstrate not only that the binding site repertoires of the full-length receptors are dictated by those of their DBDs, but also that the formation of distinct dimerization interfaces between the DBDs are the critical determinants for cooperative DNA binding of these receptors to specific DRs.     

Conformation of the DNA undecamer 5'd(A-A-G-T-G-T-G-A-T-A-T) bound to the single-stranded DNA binding protein of Escherichia coli. A time-dependent transferred nuclear Overhauser enhancement study

A time-dependent transferred nuclear Overhauser enhancement study of the conformation of the single-stranded DNA 11mer 5'd(A-A-G-T-G-T-G-A-T-A-T) bound to the single-stranded DNA binding protein of Escherichia coli (SSB) is presented. It is shown that the conformation of the bound 11mer is that of a right-handed B-type helix similar to that of the free 11mer. The observation of internucleotide transferred nuclear Overhauser enhancements for every base step excludes the possibility of intercalation by aromatic protein residues. In addition, it is shown that the effective correlation time of the bases (80 ns) corresponds to that of a complex of molecular weight approximately 170,000, containing two SSB tetramers. The sugars, on the other hand, exhibit a shorter effective correlation time (40 ns), indicating the presence of internal motion. This suggests that the bases are anchored to the protein surface, possibly by hydrophobic interactions, whereas the sugar-phosphate groups are directed outwards towards the solvent.     

Ligand interactions with the kringle 5 domain of plasminogen. A study by 1H NMR spectroscopy

The binding of small molecules to the kringle 5 domain fragment of human plasminogen has been investigated by 1H NMR spectroscopy at 300 MHz. The compounds tested as potential ligands include L-arginine, L-lysine, and a number of aliphatic and aromatic analogs of similar size but different ionic charge configurations. Ligand/kringle 5 association constant (Ka) values were obtained from ligand titration experiments at 22 degrees C, pH 7.2. Neither L-arginine nor N alpha-acetyl-L-arginine and N alpha-acetyl-L-arginine methyl ester bind measurably to kringle 5 (Ka approximately less than 0.05 mM-1). In contrast, binding of hexylamine or epsilon-aminocaproic acid (epsilon ACA) is favored (Ka approximately 2.9 and 10.5 mM-1, respectively). Benzamidine and p-benzylaminesulfonic acid associate with kringle 5 with similar affinities (Ka approximately 3.4 and 2.2 mM-1, respectively) while benzylamine binds about twice as tightly (Ka approximately 6.3 mM-1). The higher affinities toward both benzylamine and epsilon ACA indicate that a free carboxylate group is not, by itself, a main determinant of ligand-binding to kringle 5. The experiments also reveal a definite affinity for L-arginine methyl ester, L-lysine, and N alpha-acetyl-L-lysine methyl ester. It is suggested that, although weak (0.1 approximately less than Ka approximately less than 0.6 mM-1), these interactions could be of physiological relevance in the context of plasminogen binding to the fibrin clot. Ligand-induced shifts of kringle 5 proton resonances indicate that the Trp25, His33, Tyr50, Trp62, and Tyr72 (kringle numbering convention) side chains form or neighbor the kringle 5-binding site. Benzamidine-kringle 5 magnetization transfer (Overhauser) experiments verify a close proximity of the bound ligand to these aromatic groups. A model of the binding site is proposed in which the above residues interact closely with each other and define a lipophilic surface which is accessible to the free ligand.     

Isolation of cDNA clones encoding an enzyme from bovine cells that repairs oxidative DNA damage in vitro: homology with bacterial repair enzymes.

Ionizing radiation and radiomimetic compounds, such as hydrogen peroxide and bleomycin, generate DNA strand breaks with fragmented deoxyribose 3' termini via the formation of oxygen-derived free radicals. These fragmented sugars require removal by enzymes with 3' phosphodiesterase activity before DNA synthesis can proceed. An enzyme that reactivates bleomycin-damaged DNA to a substrate for Klenow polymerase has been purified from calf thymus. The enzyme, which has a Mr of 38,000 on SDS-PAGE, also reactivates hydrogen peroxide-damaged DNA and has an associated apurinic/apyrimidinic (AP) endonuclease activity. The N-terminal amino acid sequence of the purified protein matches that reported previously for a calf thymus enzyme purified on the basis of AP endonuclease activity. Degenerate oligonucleotide primers based on this sequence were used in the polymerase chain reaction to generate from a bovine cDNA library a fragment specific for the 5' end of the coding sequence. Using this cDNA fragment as a probe, several clones containing 1.35 kb cDNA inserts were isolated and the complete nucleotide sequence of one of these determined. This revealed an 0.95 kb open reading frame which would encode a polypeptide of Mr 35,500 and with a N-terminal sequence matching that determined experimentally. The predicted amino acid sequence shows strong homology with the sequences of two bacterial enzymes that repair oxidative DNA damage, ExoA protein of S. pneumoniae and exonuclease III of E. coli.