Structure of an XRCC1 BRCT domain: a new protein-protein interaction module.

The BRCT domain (BRCA1 C-terminus), first identified in the breast cancer suppressor protein BRCA1, is an evolutionarily conserved protein-protein interaction region of approximately 95 amino acids found in a large number of proteins involved in DNA repair, recombination and cell cycle control. Here we describe the first three-dimensional structure and fold of a BRCT domain determined by X-ray crystallography at 3.2 A resolution. The structure has been obtained from the C-terminal region of the human DNA repair protein XRCC1, and comprises a four-stranded parallel beta-sheet surrounded by three alpha-helices, which form an autonomously folded domain. The compact XRCC1 structure explains the observed sequence homology between different BRCT motifs and provides a framework for modelling other BRCT domains. Furthermore, the established structure of an XRCC1 BRCT homodimer suggests potential protein-protein interaction sites for the complementary BRCT domain in DNA ligase III, since these two domains form a stable heterodimeric complex. Based on the XRCC1 BRCT structure, we have constructed a model for the C-terminal BRCT domain of BRCA1, which frequently is mutated in familial breast and ovarian cancer. The model allows insights into the effects of such mutations on the fold of the BRCT domain.     

A comparison of BRCT domains involved in nonhomologous end-joining: introducing the solution structure of the BRCT domain of polymerase lambda

Three of the four family X polymerases, DNA polymerase lambda, DNA polymerase mu, and TdT, have been associated with repair of double-strand DNA breaks by nonhomologous end-joining. Their involvement in this DNA repair process requires an N-terminal BRCT domain that mediates interaction with other protein factors required for recognition and binding of broken DNA ends. Here we present the NMR solution structure of the BRCT domain of DNA polymerase lambda, completing the structural portrait for this family of enzymes. Analysis of the overall fold of the polymerase lambda BRCT domain reveals structural similarity to the BRCT domains of polymerase mu and TdT, yet highlights some key sequence and structural differences that may account for important differences in the biological activities of these enzymes and their roles in nonhomologous end-joining. Mutagenesis studies indicate that the conserved Arg57 residue of Pol lambda plays a more critical role for binding to the XRCC4-Ligase IV complex than its structural homolog in Pol mu, Arg43. In contrast, the hydrophobic Leu60 residue of Pol lambda contributes less significantly to binding than the structurally homologous Phe46 residue of Pol mu. A third leucine residue involved in the binding and activity of Pol mu, is nonconservatively replaced by a glutamine in Pol lambda (Gln64) and, based on binding and activity data, is apparently unimportant for Pol lambda interactions with the NHEJ complex. In conclusion, both the structure of the Pol lambda BRCT domain and its mode of interaction with the other components of the NHEJ complex significantly differ from the two previously studied homologs, Pol mu and TdT.     

BRCT domains: Easy as one,two, three

BRCA1 C-terminal (BRCT) domains are integral signaling modules in the DNA damage response (DDR). Aside from their established roles as phospho-peptide binding modules, BRCT domains have been implicated in phosphorylation-independent protein interactions, DNA binding and poly(ADP-ribose) (PAR) binding. These numerous functions can be attributed to the diversity in BRCT domain structure and architecture, where domains can exist as isolated single domains or assemble into higher order homo- or hetero-domain complexes. In this review, we incorporate recent structural and biochemical studies to demonstrate how structural features allow single and tandem BRCT domains to attain a high degree of functional diversity.Key words: BRCT domain, DNA repair, phosphorylation, phospho-peptide interaction, protein interaction, DNA binding, DNA damage response     

BRCT domains

BRCA1 C-terminal (BRCT) domains are integral signaling modules in the DNA damage response (DDR). Aside from their established roles as phospho-peptide binding modules, BRCT domains have been implicated in phosphorylation-independent protein interactions, DNA binding and poly(ADP-ribose) (PAR) binding. These numerous functions can be attributed to the diversity in BRCT domain structure and architecture, where domains can exist as isolated single domains or assemble into higher order homo- or hetero- domain complexes. In this review, we incorporate recent structural and biochemical studies to demonstrate how structural features allow single and tandem BRCT domains to attain a high degree of functional diversity.     

1.15 A crystal structure of the X. tropicalis Spred1 EVH1 domain suggests a fourth distinct peptide-binding mechanism within the EVH1 family

The recently described Spred protein family has been implicated in the modulation of receptor tyrosine kinase signalling. We report the crystal structure of the Enabled/vasodilator-stimulated phosphoprotein homology-1 (EVH1) domain from Xenopus tropicalis Spred1, solved to 1.15 A resolution. This structure confirms that the Spred EVH1 adopts the pleckstrin-homology fold, with a similar secondary structure to Enabled. A translation of one of the peptide-binding groove beta-strands narrows this groove, whilst one end of the groove shows structural flexibility. We propose that Spred1 will bind peptides that are less proline-rich than other EVH1 domains, with conformational changes indicating an induced fit.     

Linking up and interacting with BRCT domains

BRCT domains are present in an ever expanding family of proteins that includes many DNA repair and checkpoint proteins. The most prominent member of the BRCT family is BRCA1, mutations in which are responsible for a high proportion of breast and ovarian cancers. BRCT domains act as protein–protein interaction modules and facilitate the formation of hetero- and homo-oligomers. The domains occur either singly or in pairs, with up to eight domains in a single protein. When in pairs the domains are separated by a short inter-BRCT linker. Numerous crystal structures have been determined for BRCT domains from a range of different proteins, which indicate that the overall structure of the BRCT domains is generally well conserved. In contrast, the positions and structures of the linker regions are more varied, as are the roles of the linkers. Here, we describe the protein–protein interactions involving three different inter-BRCT linker regions, those of DNA ligase IV (LigIV), Schizosaccharomyces pombe Crb2 and human 53BP1.     

Specificity of protein interactions mediated by BRCT domains of the XRCC1 DNA repair protein

Protein interactions critical to DNA repair and cell cycle control systems are often coordinated by modules that belong to a superfamily of structurally conserved BRCT domains. Because the mechanisms of BRCT interactions and their significance are not well understood, we sought to define the affinity and specificity of those BRCT modules that orchestrate base excision repair and single-strand break repair. Common to these pathways is the essential XRCC1 DNA repair protein, which interacts with at least nine other proteins and DNA. Here, we characterized the interactions of four purified BRCT domains, two from XRCC1 and their two partners from DNA ligase IIIalpha and poly(ADP-ribosyl) polymerase 1. A monoclonal antibody was selected that recognizes the ligase IIIalpha BRCT domain, but not the other BRCT domains, and was used to capture the relevant ligase IIIalpha BRCT complex. To examine the assembly states of isolated BRCT domains and pairwise domain complexes, we used size-exclusion chromatography coupled with on-line light scattering. This analysis indicated that isolated BRCT domains form homo-oligomers and that the BRCT complex between the C-terminal XRCC1 domain and the ligase IIIalpha domain is a heterotetramer with 2:2 stoichiometry. Using affinity capture and surface plasmon resonance methods, we determined that specific heteromeric interactions with high nanomolar dissociation constants occur between pairs of cognate BRCT domains. A structural model for a XRCC1 x DNA ligase IIIalpha heterotetramer is proposed as a core base excision repair complex, which constitutes a scaffold for higher order complexes to which other repair proteins and DNA are brought into proximity.     

The BARD1 C-terminal domain structure and interactions with polyadenylation factor CstF-50

The BARD1 N-terminal RING domain binds BRCA1 while the BARD1 C-terminal ankyrin and tandem BRCT repeat domains bind CstF-50 to modulate mRNA processing and RNAP II stability in response to DNA damage. Here we characterize the BARD1 structural biochemistry responsible for CstF-50 binding. The crystal structure of the BARD1 BRCT domain uncovers a degenerate phosphopeptide binding pocket lacking the key arginine required for phosphopeptide interactions in other BRCT proteins. Small angle X-ray scattering together with limited proteolysis results indicates that ankyrin and BRCT domains are linked by a flexible tether and do not adopt a fixed orientation relative to one another. Protein pull-down experiments utilizing a series of purified BARD1 deletion mutants indicate that interactions between the CstF-50 WD-40 domain and BARD1 involve the ankyrin-BRCT linker but do not require ankyrin or BRCT domains. The structural plasticity imparted by the ANK-BRCT linker helps to explain the regulated assembly of different protein BARD1 complexes with distinct functions in DNA damage signaling including BARD1-dependent induction of apoptosis plus p53 stabilization and interactions. BARD1 architecture and plasticity imparted by the ANK-BRCT linker are suitable to allow the BARD1 C-terminus to act as a hub with multiple binding sites to integrate diverse DNA damage signals directly to RNA polymerase.     

The RRM domain in GW182 proteins contributes to miRNA-mediated gene silencing

Proteins of the GW182 family interact with Argonaute proteins and are required for miRNA-mediated gene silencing. These proteins contain two structural domains, an ubiquitin-associated (UBA) domain and an RNA recognition motif (RRM), embedded in regions predicted to be unstructured. The structure of the RRM of Drosophila melanogaster GW182 reveals that this domain adopts an RRM fold, with an additional C-terminal α-helix. The helix lies on the β-sheet surface, generally used by these domains to bind RNA. This, together with the absence of aromatic residues in the conserved RNP1 and RNP2 motifs, and the lack of general affinity for RNA, suggests that the GW182 RRM does not bind RNA. The domain may rather engage in protein interactions through an unusual hydrophobic cleft exposed on the opposite face of the β-sheet. We further show that the GW182 RRM is dispensable for P-body localization and for interaction of GW182 with Argonaute-1 and miRNAs. Nevertheless, its deletion impairs the silencing activity of GW182 in a miRNA target-specific manner, indicating that this domain contributes to silencing. The conservation of structural and surface residues suggests that the RRM domain adopts a similar fold with a related function in insect and vertebrate GW182 family members.     

Thermal and chemical denaturation of the BRCT functional module of human 53BP1

BRCTs are protein-docking modules involved in eukaryotic DNA repair. They are characterized by low sequence homology with generally well-conserved structure organization. In a considerable number of proteins, a pair of BRCT structural repeats occurs, connected with inter-BRCT linkers, variable in length, sequence and structure. Linkers may separate and control the relative position of BRCT domains as well as protect and stabilize the hydrophobic inter-BRCT interface region. Their vital role in protein function has been demonstrated by recent findings associating missense mutations in the inter-repeat linker region of the BRCT domain of BRCA1 (BRCA1-BRCT) to hereditary breast/ovarian cancer. The interaction of 53BP1 with the core domain of the p53 tumor suppressor involves the C-terminal BRCT repeat as well as the inert-BRCT linker of the tandem BRCT domain of 53BP1 (53BP1-BRCT). High-accuracy differential scanning calorimetry (DSC) and circular dichroism (CD) have been employed to characterize the heat-induced unfolding of 53BP1-BRCT domain. The calorimetric results provide evidence for unfolding to an intermediate, only partly unfolded state, which, based on the CD results, retains the secondary structural characteristics of the native protein. A direct comparison with the corresponding thermal processes for BRAC1-BRCT and BARD1-BRCT provides evidence that the observed behavior is analogous to BRCA1-BRCT even though the two domains differ substantially in the linker structure. Moreover, chemical denaturation experiments of the untagged 53BP1-BRCT and comparison with BRCA1 and BARD1 BRCTs show that no clear association can be drawn between the structural organization of the inter-BRCT linkers and the overall stability of the BRCT domains.     

Rap1 affects the length and heterogeneity of human telomeres

Telomere length is controlled in part by cis-acting negative regulators that limit telomere extension by telomerase. In budding yeast, the major telomere length regulator scRap1 binds to telomeric DNA and acts to inhibit telomere elongation in cis. Because the human Rap1 ortholog hRap1 does not bind to telomeric DNA directly but is recruited to telomeres by TRF2, we examined its role in telomere length control. The data are consistent with hRap1 being a negative regulator of telomere length, indicating functional conservation. Deletion mapping confirmed that hRap1 is tethered to telomeres through interaction of its C terminus with TRF2. The telomere length phenotypes of hRap1 deletion mutants implicated both the BRCT and Myb domain as protein interaction domains involved in telomere length regulation. By contrast, scRap1 binds to telomeres with its Myb domains and uses its C terminus to recruit the telomere length regulators Rif1 and Rif2. Together, our data show that although the role of Rap1 at telomeres has been largely conserved, the domains of Rap1 have undergone extensive functional changes during eukaryotic evolution. Surprisingly, hRap1 alleles lacking the BRCT domain diminished the heterogeneity of human telomeres, indicating that hRap1 also plays a role in the regulation of telomere length distribution.     

Solution structure of polymerase mu's BRCT Domain reveals an element essential for its role in nonhomologous end joining

The solution structure and dynamics of the BRCT domain from human DNA polymerase mu, implicated in repair of chromosome breaks by nonhomologous end joining (NHEJ), has been determined using NMR methods. BRCT domains are typically involved in protein-protein interactions between factors required for the cellular response to DNA damage. The pol mu BRCT domain is atypical in that, unlike other reported BRCT structures, the pol mu BRCT is neither part of a tandem grouping, nor does it appear to form stable homodimers. Although the sequence of the pol mu BRCT domain has some unique characteristics, particularly the presence of >10% proline residues, it forms the characteristic alphabetaalpha sandwich, in which three alpha helices are arrayed around a central four-stranded beta-sheet. The structure of helix alpha1 is characterized by two solvent-exposed hydrophobic residues, F46 and L50, suggesting that this element may play a role in mediating interactions of pol mu with other proteins. Consistent with this argument, mutation of these residues, as well as the proximal, conserved residue R43, specifically blocked the ability of pol mu to efficiently work together with NHEJ factors Ku and XRCC4-ligase IV to join noncomplementary ends together in vitro. The structural, dynamic, and biochemical evidence reported here identifies a functional surface in the pol mu BRCT domain critical for promoting assembly and activity of the NHEJ machinery. Further, the similarity between the interaction regions of the BRCT domains of pol mu and TdT support the conclusion that they participate in NHEJ as alternate polymerases.     

Solution structure and backbone dynamics of the human DNA ligase IIIalpha BRCT domain.

BRCT (BRCA1 carboxyl terminus) domains are found in a number of DNA repair enzymes and cell cycle regulators and are believed to mediate important protein-protein interactions. The DNA ligase IIIalpha BRCT domain partners with the distal BRCT domain of the DNA repair protein XRCC1 (X1BRCTb) in the DNA base excision repair (BER) pathway. To elucidate the mechanisms by which these two domains can interact, we have determined the solution structure of human ligase IIIalpha BRCT (L3[86], residues 837-922). The structure of L3[86] consists of a beta2beta1beta3beta4 parallel sheet with a two-alpha-helix bundle packed against one face of the sheet. This fold is conserved in several proteins having a wide range of activities, including X1BRCTb [Zhang, X. D., et al. (1998) EMBO J. 17, 6404-6411]. L3[86] exists as a dimer in solution, but an insufficient number of NOE restraints precluded the determination of the homodimer structure. However, 13C isotope-filtered and hydrogen-deuterium exchange experiments indicate that the N-terminus, alpha1, the alpha1-beta2 loop, and the three residues following alpha2 are involved in forming the dimer interface, as similarly observed in the structure of X1BRCTb. NOE and dynamic data indicate that several residues (837-844) in the N-terminal region appear to interconvert between helix and random coil conformations. Further studies of other BRCT domains and of their complexes are needed to address how these proteins interact with one another, and to shed light on how mutations can lead to disruption of function and ultimately disease.     

含磷酸结合口袋的BRCT结构域功能位点预测

BRCT( BRCA1 C-terminus)是真核生物DNA损伤修复系统重要的信号传导和蛋白靶向结构域.为了探讨含磷酸结合口袋的BRCT与磷酸化配体结合的机制,对XRCC1 BRCT1、PTIP BRCT4、ECT2 BRCT1和TopBP1BRCT1进行了结构保守性和表面静电势分析.结果显示,4个BRCT的磷酸结合口袋周围所存在的结构保守并带正电势的沟槽很可能是其功能位点,并且类似的沟槽在含磷酸结合口袋的BRCT中普遍存在.沟槽两侧及底部均带有极性氨基酸残基,两侧带正电荷,而底部疏水.这说明沟槽与配体的结合以静电和疏水相互作用为主.沟槽主要位于单个BRCT中,而且4个BRCT的沟槽在形状和电荷分布上都不同,说确明BRCT配体特异性主要由单个BRCT决定.磷酸结合口袋位于沟槽中心,说明沟槽可能同时结合磷酸化残基的N端和C端附近残基.     

Solution NMR structure of VF0530 from Vibrio fischeri reveals a nucleic acid-binding function

Protein domain family PF09905 (DUF2132) is a family of small domains of unknown function that are conserved in a wide range of bacteria. Here we describe the solution NMR structure of the 80-residue VF0530 protein from Vibrio fischeri, the first structural representative from this protein domain family. We demonstrate that the structure of VF0530 adopts a unique four-helix motif that shows some similarity to the C-terminal double-stranded DNA (dsDNA) binding domain of RecA, as well as other nucleic acid binding domains. Moreover, gel shift binding data indicate a potential dsDNA binding role for VF0530.     

Structure and function of the Rad9-binding region of the DNA-damage checkpoint adaptor TopBP1

TopBP1 is a scaffold protein that coordinates activation of the DNA-damage-checkpoint response by coupling binding of the 9-1-1 checkpoint clamp at sites of ssDNA, to activation of the ATR–ATRIP checkpoint kinase complex. We have now determined the crystal structure of the N-terminal region of human TopBP1, revealing an unexpected triple-BRCT domain structure. The arrangement of the BRCT domains differs significantly from previously described tandem BRCT domain structures, and presents two distinct sites for binding phosphopeptides in the second and third BRCT domains. We show that the site in the second but not third BRCT domain in the N-terminus of TopBP1, provides specific interaction with a phosphorylated motif at pSer387 in Rad9, which can be generated by CK2.