Methanopyrus kandleri topoisomerase V contains three distinct AP lyase active sites in addition to the topoisomerase active site

Topoisomerase V (Topo-V) is the only topoisomerase with both topoisomerase and DNA repair activities. The topoisomerase activity is conferred by a small alpha-helical domain, whereas the AP lyase activity is found in a region formed by 12 tandem helix-hairpin-helix ((HhH)₂) domains. Although it was known that Topo-V has multiple repair sites, only one had been mapped. Here, we show that Topo-V has three AP lyase sites. The atomic structure and Small Angle X-ray Scattering studies of a 97 kDa fragment spanning the topoisomerase and 10 (HhH)₂ domains reveal that the (HhH)₂ domains extend away from the topoisomerase domain. A combination of biochemical and structural observations allow the mapping of the second repair site to the junction of the 9th and 10th (HhH)₂ domains. The second site is structurally similar to the first one and to the sites found in other AP lyases. The 3rd AP lyase site is located in the 12th (HhH)₂ domain. The results show that Topo-V is an unusual protein: it is the only known protein with more than one (HhH)₂ domain, the only known topoisomerase with dual activities and is also unique by having three AP lyase repair sites in the same polypeptide.     

The domain organization and properties of individual domains of DNA topoisomerase V, a type 1B topoisomerase with DNA repair activities.

Topoisomerase V (Topo V) is a type IB (eukaryotic-like) DNA topoisomerase. It was discovered in the hyperthermophilic prokaryote Methanopyrus kandleri and is the only topoisomerase with associated apurinic/apyrimidinic (AP) site-processing activities. The structure of Topo V in the free and DNA-bound states was probed by limited proteolysis at 37 degrees C and 80 degrees C. The Topo V protein is comprised of (i) a 44-kDa NH(2)-terminal core subdomain, which contains the active site tyrosine residue for topoisomerase activity, (ii) an immediately adjacent 16-kDa subdomain that contains degenerate helix-hairpin-helix (HhH) motifs, (iii) a protease-sensitive 18-kDa HhH "hinge" region, and (iv) a 34-kDa COOH-terminal HhH domain. Three truncated Topo V polypeptides comprising the NH(2)-terminal 44-kDa and 16-kDa domains (Topo61), the 44-, 16-, and 18-kDa domains (Topo78), and the COOH-terminal 34-kDa domain (Topo34) were cloned, purified, and characterized. Both Topo61 and Topo78 are active topoisomerases, but in contrast to Topo V these enzymes are inhibited by high salt concentrations. Topo34 has strong DNA-binding ability but shows no topoisomerase activity. Finally, we demonstrate that Topo78 and Topo34 possess AP lyase activities that are important in base excision DNA repair. Thus, Topo V has at least two active sites capable of processing AP DNA. The significance of multiple HhH motifs for the Topo V processivity is discussed.     

The C-terminal region of Escherichia coli UvrC contributes to the flexibility of the UvrABC nucleotide excision repair system

Nucleotide excision repair in Escherichia coli involves formation of the UvrB–DNA complex and subsequent DNA incisions on either site of the damage by UvrC. In this paper, we studied the incision of substrates with different damages in varying sequence contexts. We show that there is not always a correlation between the incision efficiency and the stability of the UvrB–DNA complex. Both stable and unstable UvrB–DNA complexes can be efficiently incised. However some lesions that give rise to stable UvrB–DNA complexes do result in a very low incision. We present evidence that this poor incision is due to sterical hindrance of the damage itself. In its C-terminal region UvrC contains two helix–hairpin–helix (HhH) motifs. Mutational analysis shows that these motifs constitute one functional unit, probably folded as one structural unit; the (HhH)₂ domain. This (HhH)₂ domain was previously shown to be important for the 5′ incision on a substrate containing a (cis-Pt)·GG adduct, but not for 3′ incision. Here we show that, mainly depending on the sequence context of the lesion, the (HhH)₂ domain can be important for 3′ and/or 5′ incision. We propose that the (HhH)₂ domain stabilises specific DNA structures required for the two incisions, thereby contributing to the flexibility of the UvrABC repair system.     

Common fold in helix-hairpin-helix proteins

Helix–hairpin–helix (HhH) is a widespread motif involved in non-sequence-specific DNA binding. The majority of HhH motifs function as DNA-binding modules, however, some of them are used to mediate protein–protein interactions or have acquired enzymatic activity by incorporating catalytic residues (DNA glycosylases). From sequence and structural analysis of HhH-containing proteins we conclude that most HhH motifs are integrated as a part of a five-helical domain, termed (HhH)₂ domain here. It typically consists of two consecutive HhH motifs that are linked by a connector helix and displays pseudo-2-fold symmetry. (HhH)₂ domains show clear structural integrity and a conserved hydrophobic core composed of seven residues, one residue from each α-helix and each hairpin, and deserves recognition as a distinct protein fold. In addition to known HhH in the structures of RuvA, RadA, MutY and DNA-polymerases, we have detected new HhH motifs in sterile alpha motif and barrier-to-autointegration factor domains, the α-subunit of Escherichia coli RNA-polymerase, DNA-helicase PcrA and DNA glyco­s­y­lases. Statistically significant sequence similarity of HhH motifs and pronounced structural conservation argue for homology between (HhH)₂ domains in different protein families. Our analysis helps to clarify how non-symmetric protein motifs bind to the double helix of DNA through the formation of a pseudo-2-fold symmetric (HhH)₂ functional unit.     

Structural and functional analyses of an archaeal XPF/Rad1/Mus81 nuclease: asymmetric DNA binding and cleavage mechanisms

XPF/Rad1/Mus81/Hef proteins recognize and cleave branched DNA structures. XPF and Rad1 proteins cleave the 5' side of nucleotide excision repair bubble, while Mus81 and Hef cleave similar sites of the nicked Holliday junction, fork, or flap structure. These proteins all function as dimers and consist of catalytic and helix-hairpin-helix DNA binding (HhH) domains. We have determined the crystal structure of the HhH domain of Pyrococcus furiosus Hef nuclease (HefHhH), which revealed the distinct mode of protein dimerization. Our structural and biochemical analyses also showed that each of the catalytic and HhH domains binds to distinct regions within the fork-structured DNA: each HhH domain from two separate subunits asymmetrically binds to the arm region, while the catalytic domain binds near the junction center. Upon binding to DNA, Hef nuclease disrupts base pairs near the cleavage site. It is most likely that this bipartite binding mode is conserved in the XPF/Rad1/Mus81 nuclease family.     

Protein-protein contacts in the glucocorticoid receptor homodimer influence its DNA binding properties

We have investigated the influence of the N-terminal domain of the 94-kDa glucocorticoid receptor on the DNA:receptor interaction. An alpha-chymotrypsin-induced 39-kDa receptor fragment, containing the hormone and DNA binding domains, binds DNA with a reduced specificity compared to the intact 94-kDa receptor. Various footprinting assays did not reveal any qualitative differences when comparing the DNA contact points made by the two different receptor entities. Like the intact receptor, the 39-kDa receptor fragment binds as a dimer to DNA. Glutaraldehyde cross-linking demonstrated a difference in the protein:protein contacts of the two homodimers. Furthermore, the dimeric 94-kDa receptor did not recognize a half-DNA site, while the dissociated 94-kDa receptor dimer and the dimeric 39-kDa receptor fragment allowed binding to such a site. These results suggest that the loss of the N-terminal domain of the receptor affects the steric arrangement and/or rigidity of the two DNA binding domains of the receptor homodimer, resulting in a decreased DNA binding specificity of the 39-kDa receptor fragment.     

Mammalian DNA polymerase beta: characterization of a 16-kDa transdomain fragment containing the nucleic acid-binding activities of the native enzyme.

The 39-kDa DNA polymerase beta (beta-Pol) molecule can be readily converted into two constituent domains by mild proteolysis; these domains are represented in an 8-kDa N-terminal fragment and a 31-kDa C-terminal fragment [Kumar et al. (1990a) J. Biol. Chem. 265, 2124-2131]. Intact beta-Pol is a sequence-nonspecific nucleic acid-interactive protein that binds both double-stranded (ds) and single-stranded (ss) polynucleotides. These two activities appear to be contributed by separate portions of the enzyme, since the 31-kDa domain binds ds DNA but not ss DNA, and conversely, the 8-kDa domain binds ss DNA but not ds DNA [Casas-Finet et al. (1991) J. Biol. Chem. 266, 19618-19625]. Truncation of the 31-kDa domain at the N-terminus with chymotrypsin, to produce a 27-kDa fragment (residues 140-334), eliminated all DNA-binding activity. This suggested that the ds DNA-binding capacity of the 31-kDa domain may be carried in the N-terminal segment of the 31-kDa domain. We used CNBr to prepare a 16-kDa fragment (residues 18-154) that spans the ss DNA-binding region of the 8-kDa domain along with the N-terminal portion of the 31-kDa domain. The purified 16-kDa fragment was found to have both ss and ds polynucleotide-binding capacity. Thermodynamic binding properties for these activities are similar to those of the intact enzyme.(ABSTRACT TRUNCATED AT 250 WORDS)     

A plant phytotoxin, solanapyrone A, is an inhibitor of DNA polymerase beta and lambda.

Solanapyrone A, a phytotoxin and enzyme inhibitor isolated from a fungus (SUT 01B1-2) selectively inhibits the activities of mammalian DNA polymerase beta and lambda (pol beta and lambda) in vitro. The IC50 values of the compound were 30 microm for pol beta and 37 microm for pol lambda. Because pol beta and lambda are in a family and their three-dimensional structures are thought to be highly similar to each other, we used pol beta to analyze the biochemical relationship with solanapyrone A. On pol beta, solanapyrone A antagonistically competed with both the DNA template and the nucleotide substrate. BIAcore analysis demonstrated that solanapyrone A bound selectively to the N-terminal 8-kDa domain of pol beta. This domain is known to bind single-stranded DNA, provide 5'-phosphate recognition of gapped DNA, and cleave the sugar-phosphate bond 3' to an intact apurinic/apyrimidinic (AP) site (i.e. AP lyase activity) including 5'-deoxyribose phosphate lyase activity. Solanapyrone A inhibited the single-stranded DNA-binding activity but did not influence the activities of the 5'-phosphate recognition in gapped DNA structures and the AP lyase. Based on these results, the inhibitory mechanism of solanapyrone A is discussed.     

Replicative helicases can translocate through abasic site-induced covalent topoisomerase IV-DNA complexes

Some topoisomerase inhibitors trap covalent topoisomerase–DNA complexes as topoisomerase–drug–DNA ternary complexes. Ternary complex formation results in inhibition of DNA replication and generation of permanent double-strand breaks. Recent demonstrations of the stimulation of covalent topoisomerase–DNA complex formation by DNA lesions suggest that DNA damage may act as an endogenous topoisomerase poison. We have investigated the effects of abasic (AP) sites on topoisomerase IV (Topo IV). AP sites can stimulate the formation of covalent Topo IV–DNA complexes when they are located either within the 4 base overhang generated by DNA scission or immediately 5′ to the point of scission (the –1 position). Thus, the AP site acts as a position-specific, endogenous topoisomerase poison. Both EDTA and salt can reverse covalent Topo IV–DNA complexes induced by AP sites located within the 4 base overhang. Interestingly, an AP site at the –1 position inhibits EDTA-mediated reversal of formation of the covalent Topo IV–DNA complex. Furthermore, we find that, unlike quinolone-induced covalent Topo IV–DNA complexes, AP site-induced covalent Topo IV–DNA complexes do not inhibit the helicase activities of the DnaB and T7 Gene 4 proteins. These results suggest that the AP site-induced poisoning of Topo IV does not arrest replication fork progression.     

The Carboxy-Terminal Domain of ROS1 Is Essential for 5-Methylcytosine DNA Glycosylase Activity

Arabidopsis thaliana repressor of silencing 1 (ROS1) is a multi-domain bifunctional DNA glycosylase/lyase, which excises 5-methylcytosine (5mC) and 5-hydroxymethylcytosine (5hmC) as well as thymine and 5-hydroxymethyluracil (i.e., the deamination products of 5mC and 5hmC) when paired with a guanine, leaving an apyrimidinic (AP) site that is subsequently incised by the lyase activity. ROS1 is slow in base excision and fast in AP lyase activity, indicating that the recognition of pyrimidine modifications might be a rate-limiting step. In the C-terminal half, the enzyme harbors a helix–hairpin–helix DNA glycosylase domain followed by a unique C-terminal domain. We show that the isolated glycosylase domain is inactive for base excision but retains partial AP lyase activity. Addition of the C-terminal domain restores the base excision activity and increases the AP lyase activity as well. Furthermore, the two domains remain tightly associated and can be co-purified by chromatography. We suggest that the C-terminal domain of ROS1 is indispensable for the 5mC DNA glycosylase activity of ROS1.     

Biochemical analysis of the N-terminal domain of human RAD54B

The human RAD54B protein is a paralog of the RAD54 protein, which plays important roles in homologous recombination. RAD54B contains an N-terminal region outside the SWI2/SNF2 domain that shares less conservation with the corresponding region in RAD54. The biochemical roles of this region of RAD54B are not known, although the corresponding region in RAD54 is known to physically interact with RAD51. In the present study, we have biochemically characterized an N-terminal fragment of RAD54B, consisting of amino acid residues 26–225 (RAD54B_26–225). This fragment formed a stable dimer in solution and bound to branched DNA structures. RAD54B_26–225 also interacted with DMC1 in both the presence and absence of DNA. Ten DMC1 segments spanning the entire region of the DMC1 sequence were prepared, and two segments, containing amino acid residues 153–214 and 296–340, were found to directly bind to the N-terminal domain of RAD54B. A structural alignment of DMC1 with the Methanococcus voltae RadA protein, a homolog of DMC1 in the helical filament form, indicated that these RAD54B-binding sites are located near the ATP-binding site at the monomer–monomer interface in the DMC1 helical filament. Thus, RAD54B binding may affect the quaternary structure of DMC1. These observations suggest that the N-terminal domain of RAD54B plays multiple roles of in homologous recombination.     

The Fanconi anemia associated protein FAAP24 uses two substrate specific binding surfaces for DNA recognition

To maintain the integrity of the genome, multiple DNA repair systems exist to repair damaged DNA. Recognition of altered DNA, including bulky adducts, pyrimidine dimers and interstrand crosslinks (ICL), partially depends on proteins containing helix-hairpin-helix (HhH) domains. To understand how ICL is specifically recognized by the Fanconi anemia proteins FANCM and FAAP24, we determined the structure of the HhH domain of FAAP24. Although it resembles other HhH domains, the FAAP24 domain contains a canonical hairpin motif followed by distorted motif. The HhH domain can bind various DNA substrates; using nuclear magnetic resonance titration experiments, we demonstrate that the canonical HhH motif is required for double-stranded DNA (dsDNA) binding, whereas the unstructured N-terminus can interact with single-stranded DNA. Both DNA binding surfaces are used for binding to ICL-like single/double-strand junction-containing DNA substrates. A structural model for FAAP24 bound to dsDNA has been made based on homology with the translesion polymerase iota. Site-directed mutagenesis, sequence conservation and charge distribution support the dsDNA-binding model. Analogous to other HhH domain-containing proteins, we suggest that multiple FAAP24 regions together contribute to binding to single/double-strand junction, which could contribute to specificity in ICL DNA recognition.     

N-terminal and Central Segments of the Type 1 Ryanodine Receptor Mediate Its Interaction with FK506-binding Proteins

We used site-directed labeling of the type 1 ryanodine receptor (RyR1) and fluorescence resonance energy transfer (FRET) measurements to map RyR1 sequence elements forming the binding site of the 12-kDa binding protein for the immunosuppressant drug, FK506. This protein, FKBP12, promotes the RyR1 closed state, thereby inhibiting Ca²⁺ leakage in resting muscle. Although FKBP12 function is well established, its binding determinants within the RyR1 protein sequence remain unresolved. To identify these sequence determinants using FRET, we created five single-Cys FKBP variants labeled with Alexa Fluor 488 (denoted D-FKBP) and then targeted these D-FKBPs to full-length RyR1 constructs containing decahistidine (His₁₀) “tags” placed within N-terminal (amino acid residues 76–619) or central (residues 2157–2777) regions of RyR1. The FRET acceptor Cy3NTA bound specifically and saturably to these His tags, allowing distance analysis of FRET measured from each D-FKBP variant to Cy3NTA bound to each His tag. Results indicate that D-FKBP binds proximal to both N-terminal and central domains of RyR1, thus suggesting that the FKBP binding site is composed of determinants from both regions. These findings further imply that the RyR1 N-terminal and central domains are proximal to one another, a core premise of the domain-switch hypothesis of RyR function. We observed FRET from GFP fused at position 620 within the N-terminal domain to central domain His-tagged sites, thus further supporting this hypothesis. Taken together, these results support the conclusion that N-terminal and central domain elements are closely apposed near the FKBP binding site within the RyR1 three-dimensional structure.     

Identification and properties of the catalytic domain of mammalian DNA polymerase beta

Rat DNA polymerase beta (beta-pol) is a 39-kDa protein organized in two tightly folded domains, 8-kDa N-terminal and 31-kDa C-terminal domains, connected by a short protease-sensitive region. The 8-kDa domain contributes template binding to the intact protein, and we now report that the 31-kDa C-terminal domain contributes catalytic activity. Our results show that this domain as a purified proteolytic fragment conducts DNA synthesis under appropriate conditions but the kcat is lower and primer extension properties are different from those of the intact enzyme. A proteolytic truncation of the 31-kDa catalytic domain fragment, to remove a 60-residue segment from the NH2-terminal end, results in nearly complete loss of activity, suggesting the importance of this segment. Overall, these results indicate that the domains of beta-pol have distinct functional roles, template binding and nucleotidyltransferase, respectively; yet, the intact protein is more active for each function than the isolated individual domain fragment.     

Cleavage of the Bloom's syndrome gene product during apoptosis by caspase-3 results in an impaired interaction with topoisomerase IIIalpha

In higher eukaryotes, the integration of signals triggered in response to certain types of stress can result in programmed cell death. Central to these events is the sequential activation of a cascade of proteinases known as caspases. The final activated effector caspases of this cascade digest a number of cellular proteins, in some cases increasing their enzymatic activity, in others destroying their function. Of the proteins shown to be targets for caspase-mediated proteolysis, a surprisingly large proportion are proteins involved in the signalling or repair of DNA damage. Here we investigate whether BLM, the product of the gene mutated in Bloom’s syndrome, a human autosomal disease characterised by cancer predisposition and sunlight sensitivity, is cleaved during apoptosis. BLM interacts with topoisomerase IIIα and has been proposed to play an important role in maintaining genomic integrity through its roles in DNA repair and replication. We show that BLM is cleaved during apoptosis by caspase-3 and reveal that the main cleavage site is located at the junction between the N-terminal and central helicase domains of BLM. Proteolytic cleavage by caspase-3 produces a 120 kDa fragment, which contains the intact helicase domain and three smaller fragments, the relative amounts of which depend on time of incubation with caspase-3. The 120 kDa fragment retains the helicase activity of the intact BLM protein. However, its interaction with topoisomerase IIIα is severely impaired. Since the BLM–topoisomerase interaction is believed to be necessary for many of the replication and recombination functions of BLM, we suggest that caspase-3 cleavage of BLM could alter the localisation and/or function of BLM and that these changes may be important in the process of apoptosis.     

Different functions for the domains of the Arabidopsis thaliana RMI1 protein in DNA cross-link repair,somatic and meiotic recombination

Recombination intermediates, such as double Holliday junctions, can be resolved by nucleases or dissolved by the combined action of a DNA helicase and a topoisomerase. In eukaryotes, dissolution is mediated by the RTR complex consisting of a RecQ helicase, a type IA topoisomerase and the structural protein RecQ-mediated genome instability 1 (RMI1). Throughout eukaryotes, the RTR complex is involved in DNA repair and in the suppression of homologous recombination (HR) in somatic cells. Surprisingly, Arabidopsis thaliana mutants of topoisomerase 3α and RMI1 are also sterile due to extensive chromosome breakage in meiosis I, indicating that both proteins are essential for meiotic recombination in plants. AtRMI1 harbours an N-terminal DUF1767 domain and two oligosaccharide binding (OB)-fold domains. To define specific roles for these individual domains, we performed complementation experiments on Atrmi1 mutants with an AtRMI1 full-length open reading frame (ORF) or deletion constructs lacking specific domains. We show that the DUF1767 domain and the OB-fold domain 1 are both essential for the function of AtRMI1 in DNA cross-link repair as well as meiotic recombination, but partially dispensable for somatic HR suppression. The OB-fold domain 2 is not necessary for either somatic or meiotic HR, but it seems to have a minor function in DNA cross-link repair.     

Indispensable, functionally complementing N and C-terminal domains constitute site-specific topoisomerase I

Mycobacterium smegmatis topoisomerase I differs from the typical type IA topoisomerase in many properties. The enzyme recognizes both single and double-stranded DNA with high affinity and makes sequence-specific contacts during DNA relaxation reaction. The enzyme has a conserved N-terminal domain and a highly varied C-terminal domain, which lacks the characteristic zinc binding motifs found in most of the type I eubacterial enzymes. The roles of the individual domains of the enzyme in the topoisomerase I catalyzed reactions were examined by comparing the properties of full-length topoisomerase I with those of truncated polypeptides lacking the conserved N-terminal or the divergent C-terminal region. The N-terminal larger fragment retained the site-specific binding, DNA cleavage and religation properties, hallmark characteristics of the full-length M.smegmatis topoisomerase I. In contrast, the non-conserved C-terminal fragment lacking the typical DNA binding motif, exhibited non-specific DNA binding behaviour. The two polypeptide fragments, on their own do not catalyze DNA relaxation reaction. The relaxation activity is restored when both the fragments are mixed in vitro reconstituting the enzyme function. These results along with the DNA interaction pattern of the proteins implicate an essential role for the C-terminal region in single-strand DNA passage between the two transesterification reactions catalyzed by the N-terminal domain.     

Characterization of a catalytically slow AP lyase activity in DNA polymerase gamma and other family A DNA polymerases

Mitochondrial DNA polymerase gamma (pol gamma) is active in base excision repair of AP (apurinic/apyrimidinic) sites in DNA. Usually AP site repair involves cleavage on the 5' side of the deoxyribose phosphate by AP endonuclease. Previous experiments suggested that DNA pol gamma acts to catalyze the removal of a 5'-deoxyribose phosphate (dRP) group in addition to playing the conventional role of a DNA polymerase. We confirm that DNA pol gamma is an active dRP lyase and show that other members of the family A of DNA polymerases including Escherichia coli DNA pol I also possess this activity. The dRP lyase reaction proceeds by formation of a covalent enzyme-DNA intermediate that is converted to an enzyme-dRP intermediate following elimination of the DNA. Both intermediates can be cross-linked with NaBH(4). For both DNA pol gamma and the Klenow fragment of pol I, the enzyme-dRP intermediate is extremely stable. This limits the overall catalytic rate of the dRP lyase, so that family A DNA polymerases, unlike pol beta, may only be able to act as dRP lyases in repair of AP sites when they occur at low frequency in DNA.     

Spectroscopic studies of the structural domains of mammalian DNA beta-polymerase

The 8- and 31-kDa fragments of beta-polymerase, prepared by controlled proteolysis as described (Kumar, A., Widen, S. G., Williams, K. R., Kedar, P., Karpel, R. L., and Wilson, S. H. (1990) J. Biol. Chem. 265, 2124-2131), constitute domains that are structurally and functionally dissimilar. There is little disruption of secondary structure upon proteolysis of the intact enzyme, as suggested from CD spectra of the fragments. beta-Polymerase is capable of binding both single- and double-stranded nucleic acids: the 8-kDa fragment binds specifically to single-stranded lattices, whereas the 31-kDa domain displays affinity exclusively for double-stranded polynucleotides. These domains are connected by a highly flexible protease-hypersensitive segment that may allow the coordinate functioning of the two binding activities in the intact protein. beta-Polymerase binds to poly(ethenoadenylic acid) with higher affinity, similar cooperativity, but lesser salt dependence than the 8-kDa fragment. Under physiological conditions, the intact enzyme displays greater binding free energy for single-stranded polynucleotides than the 8-kDa fragment, suggesting that the latter may carry a truncated binding site. Binding of double-stranded calf thymus DNA brings about a moderate quenching of the Tyr and Trp fluorescence emission of both the 31-kDa fragment and beta-polymerase and induces a 6-nm blue shift in the Trp emission maximum of the intact enzyme, but not in the fragment. This latter result is likely due to a change in the relative orientation of the 8- and 31-kDa domains in the intact protein upon interaction with double-stranded DNA; alternatively, the binding mode of intact protein may differ from that of the fragment. Simultaneous interaction of both domains with polynucleotides most likely does not occur since double-stranded DNA binding to the 31-kDa domain of intact beta-polymerase induces the displacement of single-stranded polynucleotides from the 8-kDa domain. These results are evaluated in light of the role of beta-polymerase in DNA repair.     

Structural insights into the functions of the FANCM-FAAP24 complex in DNA repair

Fanconi anemia (FA) is a genetically heterogeneous disorder associated with deficiencies in the FA complementation group network. FA complementation group M (FANCM) and FA-associated protein 24 kDa (FAAP24) form a stable complex to anchor the FA core complex to chromatin in repairing DNA interstrand crosslinks. Here, we report the first crystal structure of the C-terminal segment of FANCM in complex with FAAP24. The C-terminal segment of FANCM and FAAP24 both consist of a nuclease domain at the N-terminus and a tandem helix-hairpin-helix (HhH)₂ domain at the C-terminus. The FANCM-FAAP24 complex exhibits a similar architecture as that of ApXPF. However, the variations of several key residues and the electrostatic property at the active-site region render a catalytically inactive nuclease domain of FANCM, accounting for the lack of nuclease activity. We also show that the first HhH motif of FAAP24 is a potential binding site for DNA, which plays a critical role in targeting FANCM-FAAP24 to chromatin. These results reveal the mechanistic insights into the functions of FANCM-FAAP24 in DNA repair.