X-ray structure of T4 endonuclease V: an excision repair enzyme specific for a pyrimidine dimer.

The x-ray structure of T4 endonuclease V, an enzyme responsible for the first step of a pyrimidine-dimer-specific excision-repair pathway, was determined at a 1.6-angstrom resolution. The enzyme consists of a single compact domain classified into an all-alpha structure. This single domain has two distinct catalytic activities; it functions as a pyrimidine dimer glycosylase and as an apurinic-apyrimidinic endonuclease. The amino-terminal segment penetrates between two major helices and prevents their direct contact. The refined structure suggests the residues involved in the substrate binding and the catalysis of the glycosylation reaction.

Three-dimensional structure of an oncogene protein: catalytic domain of human c-H-ras p21.

The crystal structure at 2.7 A resolution of the normal human c-H-ras oncogene protein lacking a flexible carboxyl-terminal 18 residue reveals that the protein consists of a six-stranded beta sheet, four alpha helices, and nine connecting loops. Four loops are involved in interactions with bound guanosine diphosphate: one with the phosphates, another with the ribose, and two with the guanine base. Most of the transforming proteins (in vivo and in vitro) have single amino acid substitutions at one of a few key positions in three of these four loops plus one additional loop. The biological functions of the remaining five loops and other exposed regions are at present unknown. However, one loop corresponds to the binding site for a neutralizing monoclonal antibody and another to a putative "effector region"; mutations in the latter region do not alter guanine nucleotide binding or guanosine triphosphatase activity but they do reduce the transforming activity of activated proteins. The data provide a structural basis for understanding the known biochemical properties of normal as well as activated ras oncogene proteins and indicate additional regions in the molecule that may possibly participate in other cellular functions.

Plasma HHV-6 viral load-guided preemptive therapy against HHV-6 encephalopathy after allogeneic stem cell transplantation: a prospective evaluation.

Human herpesvirus 6 (HHV-6) causes life-threatening encephalopathy in recipients of allogeneic SCT, but no consensus has been reached regarding appropriate preventive methods. This study evaluated a plasma HHV-6 viral load-guided preemptive approach against HHV-6-associated encephalopathy. Plasma real-time PCR assay was performed once a week. Among 29 patients, 19 developed positive plasma HHV-6 DNA. Median maximum plasma HHV-6 DNA was 4593.5 copies/ml plasma (range, 150.0-127 891.0 copies/ml plasma). In one of eight events with low-level HHV-6 DNA (defined as <1000 copies/ml plasma) and four of seven events with mid-level HHV-6 DNA (1000-9999.5 copies/ml plasma), HHV-6 loads in plasma subsequently continued increasing. Ganciclovir was administered against six of nine patients with high-level HHV-6 DNA (> or =10,000 copies/ml plasma). High-level HHV-6 DNA resolved similarly in both groups with or without ganciclovir therapy. Among the nine patients with high-level HHV-6 DNA two developed encephalopathy. As encephalopathy developed before the detection of high-level HHV-6 DNA in plasma, these two patients had not received preemptive ganciclovir therapy. In conclusion, our preemptive approach against HHV-6-associated encephalopathy cannot prevent all cases of HHV-6 encephalopathy in SCT recipients due to the dynamic kinetics of plasma HHV-6 viral load.

c-Ha-ras down regulates the alpha-fetoprotein gene but not the albumin gene in human hepatoma cells.

We studied the effects of transfection of the normal c-Ha-ras gene, rasGly-12, and its oncogenic mutant, rasVal-12, on expression of the alpha-fetoprotein (AFP) and albumin genes in a human hepatoma cell line, HuH-7. The mutant and, to a lesser extent, the normal ras gene caused reduction of the AFP mRNA but not the albumin mRNA level in transfected HuH-7 cells. Cotransfection experiments with a rasVal-12 expression plasmid and a chloramphenicol acetyltransferase reporter gene fused to AFP regulatory sequences showed that rasVal-12 suppressed the activity of enhancer and promoter regions containing A + T-rich sequences (AT motif). In contrast, rasVal-12 did not affect the promoter activity of the albumin and human hepatitis B virus pre-S1 genes even though these promoters contain homologous A + T-rich elements. ras transfection appeared to induce phosphorylation of nuclear proteins that interact with the AFP AT motif, since gel mobility analysis revealed the formation of slow-moving complexes which was reversed by phosphatase treatment. However, similar changes in complex formation were observed with the albumin and hepatitis B surface antigen pre-S1 promoters. Therefore, this effect alone cannot explain the specific down regulation of the AFP promoter and enhancer activity. ras-mediated suppression of the AFP gene may reflect the process of developmental gene regulation in which AFP gene transcription is controlled by a G-protein-linked signal transduction cascade triggered by external growth stimuli.

Investigation of the recognition of an important uridine in an internal loop of a hairpin ribozyme prepared using post-synthetically modified oligonucleotides.

We introduced 4-thio- ((4S)U), 2-thio- ((2S)U), 4- O -methyluridine ((4Me)U) and cytidine substitutions for U+2, which is an important base for cleavage in a substrate RNA. Oligonucleotides containing 4-thio- and 4- O -methyluridine were prepared by a new convenient post-synthetic modification method using a 4- O - p -nitrophenyl-uridine derivative. A hairpin ribozyme cleaved the substrate RNA with either C+2, (4S)U+2 or (4Me)U+2 at approximately 14-, 6- and 4-fold lower rates, respectively, than that of the natural substrate. In contrast, the substrate with a (2S)U+2 was cleaved with the same activity as the natural substrate. These results suggest that the O4 of U+2 is involved in hydrogen bonding at loop A, but the O2 of U+2 is not recognized by the active residues. Circular dichroism data of the ribozymes containing (4S)U+2 and (2S)U+2, as well as the susceptibility of the thiocarbonyl group to hydrogen peroxide, suggest that a conformational change of U+2 occurs during the domain docking in the cleavage reaction. We propose here the conformational change of U+2 from the ground state to the active molecule during the reaction.

A role for MHR1, a gene required for mitochondrial genetic recombination, in the repair of damage spontaneously introduced in yeast mtDNA.

A nuclear recessive mutant in Saccharomyces cerevisiae, mhr1-1, is defective in mitochondrial genetic recombination at 30 degrees C and shows extensive vegetative petite induction by UV irradiation at 30 degrees C or when cultivated at a higher temperature (37 degrees C). It has been postulated that mitochondrial DNA (mtDNA) is oxidatively damaged by by-products of oxidative respiration. Since genetic recombination plays a critical role in DNA repair in various organisms, we tested the possibility that MHR1 plays a role in the repair of oxidatively damaged mtDNA using an enzyme assay. mtDNA isolated from cells grown under standard (aerobic) conditions contained a much higher level of DNA lesions compared with mtDNA isolated from anaerobically grown cells. Soon after a temperature shift from 30 to 37 degrees C the number of mtDNA lesions increased 2-fold in mhr1-1 mutant cells but not in MHR1 cells. Malonic acid, which decreased the oxidative stress in mitochondria, partially suppressed both petite induction and the temperature-induced increase in the amount of mtDNA damage in mhr1-1 cells at 37 degrees C. Thus, functional mitochondria require active MHR1, which keeps the extent of spontaneous oxidative damage in mtDNA within a tolerable level. These observations are consistent with MHR1 having a possible role in mtDNA repair.

DNA binding mode of the Fab fragment of a monoclonal antibody specific for cyclobutane pyrimidine dimer.

Monoclonal antibodies specific for the cyclobutane pyrimidine dimer (CPD) are widely used for detection and quantification of DNA photolesions. However, the mechanisms of antigen binding by anti-CPD antibodies are little understood. Here we report NMR analyses of antigen recognition by TDM-2, which is a mouse monoclonal antibody specific for the cis - syn -cyclobutane thymine dimer (T[ c, s ]T). (31)P NMR and surface plasmon resonance data indicated that the epitope recognized by TDM-2 comprises hexadeoxynucleotides centered on the CPD. Chemical shift perturbations observed for TDM-2 Fab upon binding to d(T[ c, s ]T) and d(TAT[ c, s ]TAT) were examined in order to identify the binding sites for these antigen analogs. It was revealed that d(T[ c, s ]T) binds to the central part of the antibody-combining site, while the CPD-flanking nucleotides bind to the positively charged area of the V(H)domain via electrostatic interactions. By applying a novel NMR method utilizing a pair of spin-labeled DNA analogs, the orientation of DNA with respect to the antigen-binding site was determined: CPD-containing oligonucleotides bind to TDM-2 in a crooked form, draping the 3'-side of the nucleotides onto the H1 and H3 segments, with the 5'-side on the H2 and L3 segments. These data provide valuable information for antibody engineering of TDM-2.

c-Ha-ras containing 8-hydroxyguanine at codon 12 induces point mutations at the modified and adjacent positions.

To determine the type of mutation induced by 8-hydroxyguanine in a mammalian system, we examined the mutations induced by a synthetic c-Ha-ras protooncogene containing 8-hydroxyguanine in the second position of codon 12 (GGC) in NIH3T3 cells. Transfection of this gene significantly increased the number of transformed foci. The c-Ha-ras gene present in these foci was analyzed by the polymerase chain reaction-restriction enzyme method. Interestingly, sequence analysis revealed random mutations at the modified site (G----T, G----A, and G----C) as well as mutations of the adjacent G on the 5'-side of 8-hydroxyguanine (G----A and G----T).

Induction of mutation of a synthetic c-Ha-ras gene containing hypoxanthine.

The second base of codon 61 of a synthetic c-Ha-ras gene was replaced with a hypoxanthine residue in a site-specific manner. Transfection of this gene into NIH3T3 cells by the calcium phosphate procedure resulted in increased focus formation. Total DNA was extracted from transformed cells, and the sequences of the inserted c-Ha-ras DNA were analyzed by the polymerase chain reaction-single-strand conformation polymorphism method. Mutations with A (or hypoxanthine) to G transition were detected exclusively. These results suggest that the synthetic c-Ha-ras gene can be used for investigations of mutagenesis caused by DNA lesions.

A method for the synthesis of oligonucleotide by single addition of 2'-O-(o-nitrobenzyl)nucleoside 5'-diphosphates using polynucleotide phosphorylase.

Two hexanucleotides A-U-G-U-G-A and C-A-A-U-U-G were synthesized from the chemically synthesized trimers C-A-A and A-U-G by addition of 2'-O-(o-nitrobenzyl)nucleoside diphosphates using polynucleotide phosphorylase isolated from either Escherichia coli or Micrococcus luteus. In each reaction the preference of the enzyme was tested. The o-nitrobenzyl group was removed after addition of the mononucleotide and the deblocked product was isolated by chromatography on DEAE-Sephadex in high yields.

A new Drosophila ultraviolet light-damaged DNA recognition endonuclease that selectively nicks a (6-4) photoproduct site.

We have previously described the purification of an ultraviolet light (UV) damage-specific DNA-binding protein from Drosophila melanogaster, designated D-DDB P1 [Nucleic Acids Res., 23 (1995) 2600-2607]. Here, we obtained highly purified D-DDB P1 from Drosophila Kc cells, and we found that D-DDB P1 is also a nuclease. D-DDB P1 can selectively bind to pyrimidine (6-4) pyrimidone photoproducts, and in the presence of Mg++, D-DDB P1 can catalyze an incision immediately on the 3' and 5' sides of the (6-4) photoproduct site.

Antibodies specific for (6-4) DNA photoproducts: cloning, antibody modeling and construction of a single-chain Fv derivative.

We have investigated a series of four monoclonal antibodies that specifically recognize pyrimidine (6-4) pyrimidone photoproducts. One of these antibodies (64M4), bound all four possible pyrimidine-pyrimidone photoadducts with equal affinities whereas the others (64M2, 64M3 and 64M5) were selective for TC and TT sequences. In addition, 64M5 had the highest binding affinity for photodamaged DNA of the four [T. Mori et al., Photochem. Photobiol. 54 (1991) 225-232]. To help understand the differences between these antibodies, we have cloned and sequenced the variable region genes from all four. Comparing these sequences revealed that all four were highly similar to one another, although there were some differences in potential antigen-contact regions. To assess the influences of these sequence differences at the structural level, computer models were constructed for all four antibodies. Most of the sequence differences occurred in potential antigen contact regions, suggesting specific positions that might account for the observed differences in binding affinities and selectivities. A single-chain Fv derivative of 64M5 was therefore constructed and characterized to provide an experimental system in which structure-function relationships can be tested. This derivative could be isolated from Escherichia coli using two chromatographic steps and possessed the same binding specificity as the parent monoclonal antibody.

Modification of primary structures of hairpin ribozymes for probing active conformations.

Hairpin ribozymes consist of two stem-loop domains, and these domains are assumed to interact with each other to produce the self-cleavage activity. We have studied the relationship of the tertiary structure of the hairpin ribozyme and the cleavage activity by dividing and re-joining the domains. A hairpin ribozyme (E50) was divided at the hinge region, and the main part was joined to a substrate (S1) using tri- or penta-cytidylates. These ribozymes retained the cleavage activity in the presence of the rest of the molecule, indicating that the active conformation could be maintained if the two domains interacted with each other. Based on the these results, we designed a new type of hairpin ribozyme by replacing one of the domains. To maintain the interaction of the domains, oligocytidylates were inserted at a junction. These reversely jointed ribozyme complexes showed cleavage activity that was dependent on the linker lengths. These modifications in the primary structure of the hairpin ribozyme confirm the structural requirement for the catalytic reaction and provide information for the correlation of the tertiary structure with the cleavage of the hairpin ribozyme.

Preliminary crystallographic study of pyrimidine dimer-specific excision-repair enzyme from bacteriophage T4.

Bacteriophage T4 endonuclease V, which is an excision-repair enzyme specific to pyrimidine dimers within DNA, has been crystallized from polyethylene glycol 4000 solution by a vapour diffusion technique. The unit cell is monoclinic, space group P2(1), with unit cell parameters: a = 41.4 A, b = 40.1 A, c = 37.5 A, beta = 90.01 degrees. The unit cell contains two 16,000 Mr molecules. The crystals diffract X-rays beyond 2.3 A resolution and are suitable for structural analysis at high resolution.

Construction of new ribozymes requiring short regulator oligonucleotides as a cofactor.

A hairpin loop and an oligonucleotide bound to the loop form one-half of the pseudoknot structure. We have designed an allosteric hammerhead ribozyme, which is activated by the introduction of this motif by using a short complementary oligonucleotide as a cofactor. Stem II of the hammerhead ribozyme was substituted with a non-self-complementary loop sequence (loop II) to abolish the cleavage activity. The new ribozyme had almost no cleavage activity of the target RNA. However, it exhibited the cleavage activity in the presence of a cofactor oligoribonucleotide, which is complementary to loop II of the ribozyme. The activity is assumed to be derived from the formation of a pseudo-stem structure between the cofactor oligonucleotide and loop II. The structure including the loop may be similar to the pseudo-half-knot structure. The activation efficiencies of the cofactor oligonucleotides were decreased as the lengths of the oligonucleotides increased, and the ribozyme with a longer loop II was more active than that with a short loop II. Oligoribonucleotides with 3'-dangling purine bases served as efficient cofactors of the ribozyme, and a 2'-O-methyloligonucleotide enhanced the cleavage activity of the ribozyme most efficiently, by as much as about 750-fold as compared with that in the absence of the oligonucleotide. Cofactor oligonucleotides with a cytidine base at the 3'-end also activated a ribozyme with the G10.1.G11.1 mutation, which eliminates the cleavage activity in the wild-type. The binding sites of the oligonucleotide were identified by photo-crosslinking experiments and were found to be the predicted sites in the loop. This is the first report of a design aimed at positively controlling the activity of ribozymes by employing a structural motif. This method can be applied to control the activities of other functional RNAs with hairpin loops.

Studies of the interactions between Escherichia coli ribonuclease HI and its substrate.

Ribonuclease H (RNase H) recognizes a DNA-RNA hybrid duplex and catalyzes the hydrolysis of the phosphodiester linkages in only the RNA strand. Previously, we developed a method to cleave RNA in a sequence-dependent manner using RNase H and a complementary oligonucleotide containing 2'-O-methylribonucleosides. Since cleavage is restricted to a single site by the modified complementary strand, this system allows kinetic analysis of the RNase H reaction. We describe an investigation of the interactions between RNase HI from Escherichia coli and its substrate, and between the substrate and a metal ion using synthetic oligonucleotide duplexes modified at the cleavage site in combination with the 2'-O-methylribonucleotides. Firstly, the base moiety was changed to interfere with enzyme binding in either the major or minor groove. When 2-N-methylguanine was incorporated into the cleavage site, the Km value for this substrate, containing a methyl group in the minor groove, was 20-fold larger than that for the unmodified substrate, whereas 5-phenyluracil, with a phenyl group residing in the major groove of the duplex, did not affect the affinity. Secondly, the phosphodiester linkage at the cleavage site was changed into a phosphorothioate with a defined configuration. Only the Rp isomer was cleaved at this site in the presence of Mg2+ or Cd2+. These results suggest that the enzyme, but not the metal ion, interacts with the phosphate residue at the cleavage site. Thirdly, the 2'-position of the nucleoside on the 5'-side of the scissile phosphodiester was modified. Alteration of the 2'-hydroxyl function into an amino, fluoro or methoxy group, or removal of this 2'-hydroxyl group, did not affect the affinity for the enzyme, but reduced the reaction rate. An outer sphere interaction of a metal ion with the 2'-hydroxyl group is suggested.

Crystal structure of a pyrimidine dimer-specific excision repair enzyme from bacteriophage T4: refinement at 1.45 A and X-ray analysis of the three active site mutants.

Crystallographic study of bacteriophage T4 endonuclease V, which is involved in the initial step of the pyrimidine dimer-specific excision repair pathway, has been carried out with respect to the wild-type and three different mutant enzymes. This enzyme catalyzes the cleavage of the N-glycosyl bond at the 5'-side of the pyrimidine dimer, and subsequently incises the phosphodiester bond at the apyrimidinic site through a beta-elimination reaction. The structure of the wild-type enzyme refined at 1.45 A resolution reveals the detailed molecular architecture. The enzyme is composed of a single compact domain classified as an all-alpha structure. The molecule is stabilized mainly by three hydrophobic cores, two of which include many aromatic side-chain interactions. The structure has a unique folding motif, where the amino-terminal segment penetrates between two major alpha-helices and prevents their direct contact, and it is incompatible with the close-packing category of helices for protein folding. The concave surface, covered with many positive charges, implies an interface for DNA binding. The glycosylase catalytic center, which comprises Glu23 and the surrounding basic residues Arg3, Arg22 and Arg26, lie in this basic surface. The crystal structures of the three active-site mutants, in which Glu23 was replaced by Gln(E23Q) and Asp (E23D), respectively, and Arg3 by Gln (R3Q), have been determined at atomic resolution. The backbone structures of the E23Q and R3Q mutants were almost identical with that of the wild-type, while the E23D mutation induces a small, but significant, change in the backbone structure, such as an increase of the central kink of the H1 helix at Pro25. In the catalytic center of the glycosylase, however, these three mutations do not generate notable movements of protein atoms, except for significant shifts of some bound water molecules. Thus, the structural differences between the wild-type and each mutant are confined to the remarkably small region around their replaced chemical groups. Combined with the biochemical studies and the difference circular dichroism measurements, these results allow us to conclude that the negatively charged carboxyl group of Glu23 is essential for the cleavage of the N-glycosyl bond, and that the positively charged guanidino group of Arg3 is crucial to bind the substrate, a DNA duplex containing a pyrimidine dimer. The amino terminal alpha-amino group is located at a position approximately 4.4 A away from the carboxyl group of Glu23. These structural features are generally consistent with the reaction scheme proposed by Dodson and co-workers.

Interaction of the basic protrusion of Escherichia coli ribonuclease HI with its substrate.

In order to determine the actual distance between the active site and the substrate binding site, termed the basic protrusion, of Escherichia coli ribonuclease HI, synthetic oligonucleotide duplexes with gradually extended overhangs were used, in which the enzymatic cleavage was restricted to a single site with 2'-O-methylnucleosides. The affinity of the enzyme for each substrate was determined by kinetic analysis. It was found that the affinity increased markedly when one nucleotide was attached to the 3' end of the DNA strand of the nine-base-pair hybrid duplex and then increased slightly as the DNA strand was extended further, whereas elongation of the strand in the other direction caused no change. When a mutant enzyme, in which three lysine residues in the basic protrusion were altered to alanine, was used, no increase in the kcat/K(m) value was observed. The results indicate that, for the productive binding, the axis from the 3' to the 5' end of the RNA strand of the substrate duplex must be oriented in agreement with the direction from the active site to the basic protrusion of the enzyme. The distance between the active site and the basic protrusion in the enzyme-substrate complex was shorter than that anticipated in modeling studies. A dynamic structure refinement, referred to as the normal mode analysis, was carried out in order to simulate the fluctuations of the basic protrusion.

Crystallization and preliminary crystallographic data of a truncated derivative from the human c-Ha-ras protein.

A truncated derivative of the human c-Ha-ras protein has been crystallized from polyethylene glycol 6000 solution by a vapour diffusion technique. The rectangular prism diffracts X-rays to at least 2.5 A resolution (1 A = 0.1 nm). The unit cell is monoclinic, space group P21, with unit cell parameters of a = 50.2 A, b = 110.9 A, c = 36.4 A, beta = 97.2 degrees. The unit cell contains four molecules.

Crystallization and preliminary X-ray investigation of non-specific complexes of a mutant ribonuclease T1 (Y45W) with 2'AMP and 2'UMP.

We have succeeded in crystallizing complexes of a mutant ribonuclease T1 (Y45W) with the non-cognizable ribonucleotides 2'AMP and 2'UMP by macroscopic seeding of microcrystals of the mutant enzyme complexed with 2'GMP, which is the cognizable nucleotide inhibitor. The mutant enzyme has a tryptophan residue instead of Tyr45 of the wild-type enzyme and thus this mutation enhances the binding of ribonucleotides to the enzyme. The space group is P212121 with unit cell dimensions a = 49.40 A, b = 46.71 A, c = 41.02 A for the complex with 2'AMP and a = 48.97, b = 46.58 A, c = 40.97 A for the complex with 2'UMP, both of which are poorly isomorphous to the mother crystals. Diffraction data for the complexes with 2'AMP and 2'UMP were collected on a diffractometer at 1.7 A and 2.4 A resolution, respectively. The present studies show that crystallization of non-specific complexes of other protein-ligand systems with the dissociation constants around 10(-3) M, or even larger, could be feasible by application of the seeding technique. A comparison of the crystal structures of the complexes with that with 2'GMP may serve as a structural basis for the determination of differences between the specific and non-specific interactions of the enzyme.