Mode of reversible binding of neocarzinostatin chromophore to DNA: evidence for binding via the minor groove

Two general approaches have been taken to understand the mechanism of the reversible binding of the nonprotein chromophore of neocarzinostatin to DNA: (1) measurement of the relative affinity of the chromophore for various DNAs that have one or both grooves blocked by bulky groups and (2) studies on the influence of adenine-thymine residue-specific, minor groove binding agents such as the antibiotics netropsin and distamycin on the chromophore-DNA interaction. Experiments using synthetic DNAs containing halogen group (Br, I) substituents in the major groove or natural DNAs with glucosyl moieties projecting into the major groove show that obstruction of the major groove does not decrease the binding stoichiometry or the binding constant for the DNA-chromophore interaction. Chemical methylation of bases in both grooves of calf thymus DNA, resulting in 13% methylation of N-7 of guanine in the major groove and 7% methylation of N-3 of adenine in the minor groove, decreases the binding affinity and increases the size of the binding site for neocarzinostatin chromophore. Similar results were obtained whether binding parameters were determined directly by spectroscopic measurements or indirectly by measuring the ability of the DNA to protect the chromophore against degradation. On the other hand, netropsin and distamycin compete with neocarzinostatin chromophore for binding to the minor groove of DNA, as shown by their decrease in the ability of poly(dA-dT) to protect the chromophore against degradation and their reduction in chromophore-induced DNA damage as measured by thymine release.(ABSTRACT TRUNCATED AT 250 WORDS)     

Preferential protection of the minor groove of non-operator DNA by lac repressor against methylation by dimethyl sulphate.

The binding of lactose repressor to non-operator DNA was studied by the modification of several DNA's, including glycosylated DNA, with dimethyl sulphate, which affects the minor and major grooves of DNA and single stranded DNA regions. The non-specific binding of the repressor to DNA protected the minor groove but apparently not the major groove of the DNA double helix against methylation and did not increase the content of single stranded DNA regions. This suggests that the repressor on binding to non-operator DNA makes contacts mainly in the minor groove of DNA and does not uncoil the DNA double helix. This is different from the interaction of the repressor with lactose operator DNA which occurs, as shown by Gilbert et al. (1), along both the major and the minor groove.     

Towards an understanding of DNA recognition by the methyl-CpG binding domain 1

CpG methylation determines a variety of biological functions of DNA. The methylation signal is interpreted by proteins containing a methyl-CpG binding domain (MBDs). Based on the NMR structure of MBD1 complexed with methylated DNA we analysed the recognition mode by means of molecular dynamics simulations. As the protein is monomeric and recognizes a symmetrically methylated CpG step, the recognition mode is an asymmetric one. We find that the two methyl groups do not contribute equally to the binding energy. One methyl group is associated with the major part of the binding energy and the other one nearly does not contribute at all. The contribution of the two cytosine methyl groups to binding energy is calculated to be -3.6 kcal/mol. This implies a contribution of greater than two orders of magnitude to the binding constant. The conserved amino acid Asp32 is known to be essential for DNA binding by MBD1, but so far no direct contact with DNA has been observed. We detected a direct DNA base contact to Asp32. This could be the main reason for the importance of this amino acid. MBD contacts DNA exclusively in the major groove, the minor groove is reserved for histone contacts. We found a deformation of the minor groove shape due to complexation by MBD1, which indicates an information transfer between the major and the minor groove.     

Towards an Understanding of DNA Recognition by the Methyl-CpG Binding Domain 1

Abstract

CpG methylation determines a variety of biological functions of DNA. The methylation signal is interpreted by proteins containing a methyl-CpG binding domain (MBDs). Based on the NMR structure of MBD1 complexed with methylated DNA we analysed the recognition mode by means of molecular dynamics simulations.

As the protein is monomeric and recognizes a symmetrically methylated CpG step, the recognition mode is an asymmetric one. We find that the two methyl groups do not contribute equally to the binding energy. One methyl group is associated with the major part of the binding energy and the other one nearly does not contribute at all. The contribution of the two cytosine methyl groups to binding energy is calculated to be ?3.6 kcal/mol. This implies a contribution of greater than two orders of magnitude to the binding constant. The conserved amino acid Asp32 is known to be essential for DNA binding by MBD1, but so far no direct contact with DNA has been observed. We detected a direct DNA base contact to Asp32. This could be the main reason for the importance of this amino acid. MBD contacts DNA exclusively in the major groove, the minor groove is reserved for histone contacts. We found a deformation of the minor groove shape due to complexation by MBD1, which indicates an information transfer between the major and the minor groove.     

Use of monoacetyl-4-hydroxyaminoquinoline 1-oxide to probe contacts between guanines and protein in the minor and major grooves of DNA. Interaction of Escherichia coli integration host factor with its recognition site in the early promoter and transposition enhancer of bacteriophage Mu.

Monoacetyl-4-hydroxyaminoquinoline 1-oxide (Ac-HAQO) reacts with DNA to form adducts at the C8- and N2-positions of guanine and with the N6-position of adenine. Only the N2-guanine adduct blocks the 3'-5' exonuclease action of phage T4 DNA polymerase. Piperidine treatment cleaves the DNA at sites bearing C8-guanine adducts. The N2-position of guanine lies in the minor groove of DNA, whereas the C8-position of guanine occupies the major groove. We have taken advantage of these characteristics to employ Ac-HAQO in conjunction with either T4 DNA polymerase or piperidine in a footprinting technique to probe the interaction of the Escherichia coli integration host factor (IHF) with its binding site. We show that when IHF binds to its recognition site both the N2- and C8-positions of guanines are protected from modification by AcHAQO. In addition, the binding of IHF to DNA was prevented when either an N2- or a C8-AQO adduct was present in the binding site. When dimethylsulfate was used as the footprinting reagent, IHF protected against methylation of the N3 position of adenine in the minor groove but not the N7 position of guanine in the major groove. The difference in results obtained with the two reagents is ascribed to their relative sizes. Both DMS and AcHAQO are excluded by IHF from the minor groove, but only the larger AcHAQO molecule is excluded from the major groove.     

Structure of a high fidelity DNA polymerase bound to a benzo[a]pyrene adduct that blocks replication

Of the carcinogens to which humans are most frequently exposed, the polycyclic aromatic hydrocarbon benzo[a]pyrene (BP) is one of the most ubiquitous. BP is a byproduct of grilled foods and tobacco and fuel combustion and has long been linked to various human cancers, particularly lung and skin. BP is metabolized to diol epoxides that covalently modify DNA bases to form bulky adducts that block DNA synthesis by replicative or high fidelity DNA polymerases. Here we present the structure of a high fidelity polymerase from a thermostable strain of Bacillus stearothermophilus (Bacillus fragment) bound to the most common BP-derived N2-guanine adduct base-paired with cytosine. The BP adduct adopts a conformation that places the polycyclic BP moiety in the nascent DNA minor groove and is the first structure of a minor groove adduct bound to a polymerase. Orientation of the BP moiety into the nascent DNA minor groove results in extensive disruption to the interactions between the adducted DNA duplex and the polymerase. The disruptions revealed by the structure of Bacillus fragment bound to a BP adduct provide a molecular basis for rationalizing the potent blocking effect on replication exerted by BP adducts.     

DNA structure and polymerase fidelity.

The accuracy of DNA replication results from both the intrinsic DNA polymerase fidelity and the DNA sequence. Although the recent structural studies on polymerases have brought new insights on polymerase fidelity, the role of DNA sequence and structure is less well understood. Here, the analysis of the crystal structures of hotspots for polymerase slippage including (CA)n and (A)n tracts in different intermolecular contexts reveals that, in the B-form, these sequences share common structural alterations which may explain the high rate of replication errors. In particular, a two-faced "Janus-like" structure with shifted base-pairs in the major groove but an apparent normal geometry in the minor groove constitutes a molecular decoy specifically suitable to mislead the polymerases. A model of the rat polymerase beta bound to this structure suggests that an altered conformation of the nascent template-primer duplex can interfere with correct nucleotide incorporation by affecting the geometry of the active site and breaking the rules of base-pairing, while at the same time escaping enzymatic mechanisms of error discrimination which scan for the correct geometry of the minor groove.In contrast, by showing that the A-form greatly attenuates the sequence-dependent structural alterations in hotspots, this study suggests that the A-conformation of the nascent template-primer duplex at the vicinity of the polymerase active site will contribute to fidelity. The A-form may play the role of a structural buffer which preserves the correct geometry of the active site for all sequences. The detailed comparison of the conformation of the nascent template-primer duplex in the available crystal structures of DNA polymerase-DNA complexes shows that polymerase beta, the least accurate enzyme, is unique in binding to a B-DNA duplex even close to its active site. This model leads to several predictions which are discussed in the light of published experimental data.     

DNA damage and cytotoxicity induced by minor groove binding methyl sulfonate esters

Minor groove specific DNA equilibrium binding peptides (lex) based on N-methylpyrrole-carboxamide and/or N-methylimidazolecarboxamide subunits have been modified with an O-methyl sulfonate ester functionality to target DNA methylation in the minor groove at Ade/Thy- and/or Gua/Cyt-rich sequences. HPLC and sequencing gel analyses show that the Me-lex compounds all selectively react with DNA to afford N3-alkyladenine as a major adduct. The formation of the N3-alkyladenine lesions is sequence-dependent based on the equilibrium binding preferences of the different lex peptides. In addition to the reaction at adenine, the molecules designed to target Gua/Cyt sequences also generate lesions at guanine; however, the methylation is not sequence dependent and takes places in the major groove at the N7-position. To determine if and how the level of the different DNA adducts and the sequence selectivity for their formation affects cytotoxicity, the Me-lex analogues were tested in wild type Escherichia coli and in mutant strains defective in base excision repair (tag and/or alkA or apn). The results demonstrate the importance of 3-methyladenine, and in some cases 3-methylguanine, lesions in cellular toxicity, and the dominant protective role of the DNA glycosylases. There is no evidence that the sequence specificity is related to toxicity.     

Localization of chromatin proteins within DNA grooves by methylation of chromatin with dimethyl sulphate

The use of the comparative modification with ³H-dimethyl sulphate (DMS) of free DNA and DNA in different complexes is proposed to evaluate the shielding of the minor and major grooves of the DNA double helix and to determine the presence of single-stranded DNA in the complexes.Glucosyl groups in DNA of T6 phage protect, as expected, the major groove, and actinomycin d in its complex with DNA shields the minor groove against methylation with DMS.The data obtained suggest that histones and protamine in reconstituted nucleohistone and nucleoprotamine are allocated within partly the major groove leaving the minor groove open, while polylysine does not seem to be buried within either of the grooves, and cations of cetyltrimethylammonium lie within the minor groove of DNA.     

Modeling DNA deformations induced by minor groove binding proteins

Molecular modeling is used to demonstrate that the major structural deformations of DNA caused by four different minor groove binding proteins, TBP, SRY, LEF-1, and PurR, can all be mimicked by stretching the double helix between two 3'-phosphate groups flanking the binding region. This deformation reproduces the widening of the minor groove and the overall bending and unwinding of DNA caused by protein binding. It also reproduces the principal kinks associated with partially intercalated amino acid side chains, observed with such interactions. In addition, when protein binding involves a local transition to an A-like conformation, phosphate neutralization, via the formation of protein-DNA salt bridges, appears to favor the resulting deformation.     

Metabolism of Okazaki fragments during simian virus 40 DNA replication.

Essentially all of the Okazaki fragments on replicating Simian virus 40 (SV40)DNA could be grouped into one of three classes. Class I Okazaki fragments (about 20%) were separated from longer nascent DNA chains by a single phosphodiester bond interruption (nick) and were quantitatively identified by treating purified replicating DNA with Escherichia coli DNA ligase and then measuring the fraction of Okazaki fragments joined to longer nascent DNA chains. Similarly, class II Okazaki fragments (about 30%) were separated by a region of single-stranded DNA template (gap) that could be filled and sealed by T4 DNA polymerase plus E. coli DNA ligase, and class III fragments (about 50%) were separated by RNA primers that could be removed with E. coli DNA olymerase I, allowing the fragments to be joined with E. coli DNA ligase. These results were obtained with replicating SV40 DNA that had been briefly labeled with radioactive precursors in either intact cells or isolated nuclei. When isolated nuclei were further incubated in the presence of cytosol, all of the Okazaki fragments were converted into longer DNA strands as expected for intermediates in DNA synthesis. However, when washed nuclei were incubated in the abscence of cytosol, both class I and class II Okazaki fragments accumulated despite the excision of RNA primers: class III Okazaki fragments and RNA-DNA covalent linkages both disappeared at similar rates. These data demonstrate the existence of RNA primers in whole cells as well as in isolated nuclei, and identify a unique gap-filling step that is not simply an extension of the DNA chain elongation process concomitant with the excision of RNA primers. One or more factos found in cytosol, in addition to DNA polymerase alpha, are specifically involved in the gap-filling and ligation steps. The sizes of mature Okazaki fragments (class I) and Okazaki fragments whose synthesis was completed by T4 DNA polymerase were measured by gel electrophoresis and found to be broadly distributed between 40 and 290 nucleotides with an average length of 135 nucleotides. Since 80% and 90% of the Okazaments does not occur at uniformly spaced intervals along the DNA template. During the excision of RNA primers, nascent DNA chains with a single ribonucleotide covalently attached to the 5' terminus were identified as transient intermediates. These intermediates accumulated during excision of RNA primers in the presence of adenine 9-beta-D-arabinoside 5'-triphosphate, and those Okazaki fragments blocked by RNA primers (class III) were found to have originated the farthest from the 5' ends of long nascent DNA strands. Thus, RNA primers appear to be excised in two steps with the second step, removal of the final ribonucleotide, being stimulated by concomitant DNA synthesis. These and other data were used to construct a comprehensive metabolic pathway for the initiation, elongation, and maturation of Okazaki fragments at mammalian DNA replication forks.     

Three-dimensional model of yeast RNA polymerase I determined by electron microscopy of two-dimensional crystals.

Two-dimensional crystals of yeast RNA polymerase I dimers were obtained upon interaction with positively charged lipid layers. A three-dimensional surface model of the enzyme was determined by analyzing tilted crystalline areas and by taking advantage of the non-crystallographic internal symmetry of the dimer to correct for the missing viewing directions. The structure shows, at approximately 3 nm resolution, an irregularly shaped molecule 11 nm x 11 nm x 15 nm in size characterized by a 3 nm wide and 10 nm long groove which constitutes a putative DNA binding site. The overall structure is similar to the Escherichia coli holo enzyme and the yeast RNA polymerase II delta 4/7 structures. The most remarkable structural feature is a finger-shaped stalk which partially occludes the entrance of the groove and forms a 2.5 nm wide channel. We discuss the possible location of the catalytic centre and of the carboxy-terminal region of the beta-like subunit in the channel. The interference of different DNA fragments with RNA polymerase dimerization and crystallization indicates the orientation of the template in the putative DNA binding groove.