hMutSalpha- and hMutLalpha-dependent phosphorylation of p53 in response to DNA methylator damage.

hMSH2.hMSH6 heterodimer (hMutSalpha) and hMLH1.hPMS2 complex (hMutLalpha) have been implicated in the cytotoxic response of mammalian cells to a number of DNA-damaging compounds, including methylating agents that produce O(6)-methylguanine (O(6)MeG) adducts. This study demonstrates that O(6)MeG lesions, in which the damaged base is paired with either T or C, are subject to excision repair in a reaction that depends on a functional mismatch repair system. Furthermore, treatment of human cells with the S(N)1 DNA methylators N-methyl-N-nitrosourea or N-methyl-N'-nitro-N-nitrosoguanidine results in p53 phosphorylation on serine residues 15 and 392, and these phosphorylation events depend on the presence of functional hMutSalpha and hMutLalpha. Coupled with the previous demonstration that O(6)MeG.T and O(6)MeG.C pairs are recognized by hMutSalpha, these results implicate action of the mismatch repair system in the initial step of a damage-signaling cascade that can lead to cell-cycle checkpoint activation or cell death in response to DNA methylator damage.

Global structure of four-way RNA junctions studied using fluorescence resonance energy transfer.

Four-way helical junctions are found widely in natural RNA species. In this study, we have studied the conformation of two junctions by fluorescence resonance energy transfer. We show that the junctions are folded by pairwise coaxial helical stacking, forming one predominant stacking conformer in both examples studied. At low magnesium ion concentrations, the helical axes of both junctions are approximately perpendicular. One junction undergoes a rotation into a distorted antiparallel structure induced by the binding of a single magnesium ion. By contrast, the axes of the four-way junction of the U1 snRNA remain approximately perpendicular under all conditions examined, and we have determined the stacking conformer adopted.

Recognition and repair of compound DNA lesions (base damage and mismatch) by human mismatch repair and excision repair systems.

Nucleotide excision repair and the long-patch mismatch repair systems correct abnormal DNA structures arising from DNA damage and replication errors, respectively. DNA synthesis past a damaged base (translesion replication) often causes misincorporation at the lesion site. In addition, mismatches are hot spots for DNA damage because of increased susceptibility of unpaired bases to chemical modification. We call such a DNA lesion, that is, a base damage superimposed on a mismatch, a compound lesion. To learn about the processing of compound lesions by human cells, synthetic compound lesions containing UV photoproducts or cisplatin 1,2-d(GpG) intrastrand cross-link and mismatch were tested for binding to the human mismatch recognition complex hMutS alpha and for excision by the human excision nuclease. No functional overlap between excision repair and mismatch repair was observed. The presence of a thymine dimer or a cisplatin diadduct in the context of a G-T mismatch reduced the affinity of hMutS alpha for the mismatch. In contrast, the damaged bases in these compound lesions were excised three- to fourfold faster than simple lesions by the human excision nuclease, regardless of the presence of hMutS alpha in the reaction. These results provide a new perspective on how excision repair, a cellular defense system for maintaining genomic integrity, can fix mutations under certain circumstances.

Nucleic acid structure and recognition.

We review the global structures adopted by branched nucleic acids, including three- and four-way helical junctions in DNA and RNA. We find that some general folding principles emerge. First, all the structures exhibit a tendency to undergo pairwise coaxial helical stacking when permitted by the local stereochemistry of strand exchange. Second, metal ions generally play an important role in facilitating folding of branched nucleic acids. These principles can be applied to functionally important branched nucleic acids, such as the Holliday DNA junction of genetic recombination, and the hammerhead ribozyme in RNA.

Human MutSalpha recognizes damaged DNA base pairs containing O6-methylguanine, O4-methylthymine, or the cisplatin-d(GpG) adduct.

Bacterial and mammalian mismatch repair systems have been implicated in the cellular response to certain types of DNA damage, and genetic defects in this pathway are known to confer resistance to the cytotoxic effects of DNA-methylating agents. Such observations suggest that in addition to their ability to recognize DNA base-pairing errors, members of the MutS family may also respond to genetic lesions produced by DNA damage. We show that the human mismatch recognition activity MutSalpha recognizes several types of DNA lesion including the 1,2-intrastrand d(GpG) crosslink produced by cis-diamminedichloroplatinum(II), as well as base pairs between O6-methylguanine and thymine or cytosine, or between O4-methylthymine and adenine. However, the protein fails to recognize 1,3-intrastrand adduct produced by trans-diamminedichloroplatinum(II) at a d(GpTpG) sequence. These observations imply direct involvement of the mismatch repair system in the cytotoxic effects of DNA-methylating agents and suggest that recognition of 1,2-intrastrand cis-diamminedichloroplatinum(II) adducts by MutSalpha may be involved in the cytotoxic action of this chemotherapeutic agent.

The global folding of four-way helical junctions in RNA, including that in U1 snRNA.

Helical junctions are important elements in the architecture of folded RNA molecules. The global geometry of fully base-paired four-way junctions between RNA helices has been analyzed by comparative gel electrophoresis. Junctions appear to fold by pairwise coaxial helical stacking in one of two possible stereochemically equivalent isomers based upon alternative selections of stacking partners. In the presence of 1 mM Mg2+, the two continuous helical axes are approximately at right angles to each other for all junctions studied, but the RNA junctions exhibit significant sequence-dependent differences in their structures as a function of ionic conditions. The four-way junction found in the U1 snRNA folded by coaxial helical stacking. It retained the 90 degrees crossed stacked structure under all ionic conditions tested, despite the presence of a G.A mismatch at the point of strand exchange.

The modular character of a DNA junction-resolving enzyme: a zinc-binding motif in bacteriophage T4 endonuclease VII.

Bacteriophage T4 endonuclease VII is one of a class of structure-selective enzymes that resolve helical branchpoints in DNA molecules. The sequence of this protein suggests a modular organisation. We have expressed a synthetic gene encoding endonuclease VII, which has been used in a directed mutagenesis exercise, with the aim of understanding the role of different sections of the protein sequence. Towards the N-terminal end of the protein lies a section of polypeptide in which four cysteine residues distributed in a CxxC--CxxC pattern co-ordinate one atom of zinc. The N-terminal section composed of amino acid residues 1 to 65 isolated from the remaining C-terminal section also binds one mole of zinc, suggesting that this region folds autonomously. Mutation shows that the outer cysteine residues are essential for zinc binding, while the inner cysteine residues are partially degenerate in that either one of the two (but not both) can be replaced while retaining some zinc. The activity as a junction-resolving enzyme correlated qualitatively with the presence of the zinc. In the C-terminal part of the protein lies a section that is 48% identical with a sequence found in the DNA repair protein T4 endonuclease V. We can replace the section of T4 endonuclease VII with the corresponding sequence from T4 endonuclease V with no change in the pattern of cleavage on four-way junctions. The evidence supports a modular construction for T4 endonuclease VII.

Binding of the junction-resolving enzyme bacteriophage T7 endonuclease I to DNA: separation of binding and catalysis by mutation.

Bacteriophage T7 endonuclease I is a resolving enzyme that selectively cleaves four-way DNA junctions, and related branched species. We have isolated mutants of this protein that retain full structural selectivity of binding to four-way junctions, but which are completely inactive as nucleases. This is consistent with a divisibility of structure-selective binding and catalysis. The mutations that inactivate endonuclease I as a nuclease are clustered into the second quarter of the primary sequence, a region that displays some sequence similarity with the related junction-resolving enzyme endonuclease VII from bacteriophage T4. This suggests that these residues may form the active site of these enzymes. The configuration of the helical arms of the junction bound by mutant endonuclease I has been investigated by gel electrophoretic methods. We find that the junction is bound in the presence or absence of magnesium ions, and that the global structure of the bound form is apparently identical with or without cations. The patterns of mobilities suggest that the structure of the junction becomes perturbed by the binding of the protein.

Structure of the four-way DNA junction and its interaction with proteins.

The four-way DNA junction is an important intermediate in recombination processes; it is, the substrate for different enzyme activities. In solution, the junction adopts a right-handed, antiparallel-stacked X-structure formed by the pairwise coaxial-stacking of helical arms. The stereochemistry is determined by the juxtaposition of grooves and backbones, which is optimal when the smaller included angle is 60 degrees. The antiparallel structure has two distinct sides with major and minor groove-characteristics, respectively. The folding process requires the binding of metal cations, in the absence of which, the junction remains extended without helix-helix stacking. The geometry of the junction can be perturbed by the presence of certain base-base mispairs or phosphodiester discontinuities located at the point of strand exchange. The four-way DNA junction is selectively cleaved by a number of resolving enzymes. In a number of cases, these appear to recognize the minor groove face of the junction and are functionally divisible into activities that recognize and bind the junction, and a catalytic activity. Some possible mechanisms for the recognition of branched DNA structure are discussed.

Structure of four-way DNA junctions containing a nick in one strand.

We have investigated the structure of the four-way helical DNA junction containing a single covalent discontinuity (nick) in one strand. These could result from either unitary strand exchange processes, or the action of nucleases upon a complete junction. We have employed gel electrophoresis methods to study the global configuration of arms in these junctions. We find that the junction carrying a nick in one strand undergoes a folding process in the presence of magnesium ion concentrations greater than 200 microM. Comparison of the electrophoretic mobilities of the six possible derivative junctions with two long and two shortened arms suggests that the folding occurs by coaxial stacking of pairs of helical arms, which is supported by the suppression of reactivity to osmium tetroxide of thymine bases at the centre of the junction. However, unlike the complete junction (i.e. the junction without nicked strands), the two stacked pairs of helices lie at a mutual angle of approximately 90 degrees. The folding process generates two kinds of strands; two continuous strands and two exchanging strands. Two isomers of the right-angled stacked structure are possible, depending on the selection of stacking partners; it appears that the critical factor determining the relative stabilities of these isomers is the location of the nick. Thus the nicked junctions fold into the isomer that locates the nick on the exchanging strand. However, if the nick is not located at the point of strand exchange, the junction reverts to the stacked X-structure of the complete junction, even if the nick is moved by a single base-pair. These results suggest that the exchanging strands may be significantly strained in the structure of the complete four-way junction, such that an interruption to the continuity at this position allows the two stacked helices to disengage, and rotate to an angle where the overall electrostatic repulsion may be lower.

Structures of bulged three-way DNA junctions.

We have studied a series of three-way DNA junctions containing unpaired bases on one strand at the branch-point of the junctions. The global conformation of the arms of the junctions has been analysed by means of polyacrylamide gel electrophoresis, as a function of conditions. We find that in the absence of added metal ions, all the results for all the junctions can be accounted for by extended structures, with the largest angle being that between the arms defined by the strand containing the extra bases. Upon addition of magnesium (II) or hexamine cobalt (III) ions, the electrophoretic patterns change markedly, indicative of ion-dependent folding transitions for some of the junctions. For the junction lacking the unpaired bases, the three inter-arm angles appear to be quite similar, suggesting an extended structure. However, the addition of unpaired bases permits the three-way junction to adopt a significantly different structure, in which one angle becomes smaller than the other two. These species also exhibit marked protection against osmium addition to thymine bases at the point of strand exchange. These results are consistent with a model in which two of the helical arms undergo coaxial stacking in the presence of magnesium ions, with the third arm defining an angle that depends upon the number of unpaired bases.

Effects of base mismatches on the structure of the four-way DNA junction.

Heteroduplex formation between imperfectly homologous DNA sequences may result in the formation of a four-way junction at which non-Watson-Crick base mismatches are present at the point of strand exchange. This raises the question of the effect of such mismatches on the structure and stability of these potential recombination intermediates. We have constructed a series of four-way DNA junctions containing single-base mismatches, and have studied the structure of the junctions by means of gel electrophoresis and chemical modification. We observed a range of effects on the structure of the junction, ranging from almost total abolition of folding through to normal accommodation into the folded structure. In some cases we observed gel electrophoretic data consistent with a dynamic equilibrium between folded and unfolded conformations, and in general the folded form was favoured at higher concentrations of cation. The effects of single mismatches on the structure of the four-way junction may be summarized in terms of: (1) the nature of the mismatch, where we note a correlation between the thermal stability of a given mismatch and its ability to be accommodated into a folded junction; or (2) the sequence context, where the effect of a given mismatch on the structure of a junction depends on the neighbouring base-pairs. These factors are illustrated by a junction, containing a C.A mismatch, that adopted alternate isomeric conformations dependent upon pH; as the state of protonation of the mispair changed, the structure was altered along with the interaction with neighbouring base-pairs. Most base mismatches may be accommodated into the folded stacked X-conformation of the four-way junction, but many require elevated cation concentration to permit the folding process to proceed. Some mismatches were found to be extremely destabilizing.

The three-way DNA junction is a Y-shaped molecule in which there is no helix-helix stacking.

We have studied the structure of a number of three-way DNA junctions that were closely related in sequence to four-way junctions studied previously. We observe that the electrophoretic mobility of the species derived by selective shortening of one arm of a junction are very similar whichever arm is shortened, and that this remains so whether or not magnesium is present in the buffer. This suggests that the angles subtended between the arms of the three-way junctions are similar. All thymine bases located immediately at the junction are reactive to osmium tetroxide, indicating that out-of-plane attack is not prevented by helix-helix stacking, and this is also independent of the presence or absence of metal cations. The results suggest that the three-way junction cannot undergo an ion-induced conformational folding involving helical stacking, but remains fixed in a Y-shaped extended conformation. Thus the three- and four-way junctions are quite different in character in the presence of cations.

The role of metal ions in the conformation of the four-way DNA junction.

Metal ions fold DNA junctions into a compact conformation that confers protection of all thymine bases to modification by osmium tetroxide. In the absence of the cation the arms of the junction are fully extended in an approximately square-planar configuration. Group IIa cations are effective in achieving a folded conformation of the junction at 80-100 microM, and there is an excellent agreement between the ionic concentrations that fold the junctions as deduced from gel electrophoretic experiments, and those that prevent osmium tetroxide reaction at the junction. Hexamminecobalt(III) achieves full folding at 2 microM, while spermine and spermidine are effective at 25 microM. Some transition metal ions such as Ni(II) may replace the group IIA cations. Monovalent ions of group IA are only partially effective in folding the junctions. Very much higher concentrations are necessary, gel electrophoretic mobilities suggest that a less symmetrical conformation is adopted and thymine bases at the junction remain reactive to osmium tetroxide. Charge-charge interactions at the centre of the junction are structurally extremely important. Substitution of junction phosphate groups by uncharged methyl phosphonates severely perturbs the structure of the junction. If just two phosphates are substituted, diametrically facing across the junction, the structure always folds in order to place the electrically neutral phosphate on the exchanging strands. We suggest that folding of the junction into the stacked X-structure generates electronegative clefts that can selectively bind metal ions, depending on the chemistry, size and charge of the ion. Moreover, occupation of these cavities is essential for junction folding, in order to reduce electrostatic repulsion.(ABSTRACT TRUNCATED AT 250 WORDS)

Fluorescence energy transfer shows that the four-way DNA junction is a right-handed cross of antiparallel molecules.

The four-way junction between DNA helices is the central intermediate in recombination, and the manner of its interaction with resolvase enzymes can determine the genetic outcome of the process. A knowledge of its structure is a prerequisite to understanding the interaction with proteins, and there has been recent progress. Here we use fluorescence energy transfer to determine the relative distances between the ends of a small DNA junction, and hence the path of the strands. Our results are consistent with the geometry of an 'X'. The interconnected helices are juxtaposed so that the continuous strands of each helix generate an antiparallel alignment, and the two interchanged strands do not cross at the centre. The acute angle of the X structure is defined by a right-handed rotation of the helical axes about the axis perpendicular to the X plane, as viewed from the centre of the X.

The structure of the Holliday junction, and its resolution.

The Holliday (four-way) junction is a critical intermediate in homologous genetic recombination. We have studied the structure of a series of four-way junctions, constructed by hybridization of four 80 nucleotide synthetic oligonucleotides. These molecules migrate anomalously slowly in gel electrophoresis. Each arm of any junction could be selectively shortened by cleavage at a unique restriction site, and we have studied the relative gel mobilities of species in which two arms were cleaved. The pattern of fragments observed argues strongly for a structure with two-fold symmetry, based on an X shape, the long arms of which are made from pairwise colinear association of helical arms. The choice of partners is governed by the base sequence at the junction, allowing a potential isomerization between equivalent structural forms. Resolvase enzymes can distinguish between these structures, and the resolution products are determined by the structure adopted, i.e., by the sequence at the junction. In the absence of cations, the helical arms of the junction are fully extended in a square configuration, and unstacking results in junction thymines becoming reactive to osmium tetroxide.