Mahmud K.K. Shivji

Mammalian DNA nucleotide excision repair reconstituted with purified protein components

Nucleotide excision repair is the principal way by which human cells remove UV damage from DNA. Human cell extracts were fractionated to locate active components, including xeroderma pigmentosum (XP) and ERCC factors. The incision reaction was then reconstituted with the purified proteins RPA, XPA, TFIIH (containing XPB and XPD), XPC, UV-DDB, XPG, partially purified ERCC1/XPF complex, and a factor designated IF7. UV-DDB (related to XPE protein) stimulated repair but was not essential. ERCC1- and XPF-correcting activity copurified with an ERCC1-binding polypeptide of 110 kDa that was absent in XP-F cell extract. Complete repair synthesis was achieved by combining these factors with DNA polymerase epsilon, RFC, PCNA, and DNA ligase I. The reconstituted core reaction requires about 30 polypeptides.

Proliferating cell nuclear antigen is required for DNA excision repair.

Fractionation of extracts from human cell lines allows nucleotide excision repair of damaged DNA to be resolved into discrete incision and polymerization stages. Generation of incised intermediates depends on the XP-A protein, a polypeptide that recognizes sites of damaged DNA, and on the human single-stranded DNA-binding protein HSSB. The proliferating cell nuclear antigen (PCNA) is required for the DNA synthesis that converts the nicked intermediates to completed repair events. This need for PCNA implies that repair synthesis is carried out by DNA polymerase delta or epsilon. The ability to visualize repair intermediates in the absence of PCNA facilitates dissection of the multiprotein reaction that leads to incision of damaged DNA in a major pathway of cellular defense against mutagens.

Full-length archaeal Rad51 structure and mutants: Mechanisms for RAD51 assembly and control by BRCA2

To clarify RAD51 interactions controlling homologous recombination, we report here the crystal structure of the full‐length RAD51 homolog from Pyrococcus furiosus. The structure reveals how RAD51 proteins assemble into inactive heptameric rings and active DNA‐bound filaments matching three‐dimensional electron microscopy reconstructions. A polymerization motif (RAD51‐PM) tethers individual subunits together to form assemblies. Subunit interactions support an allosteric ‘switch’ promoting ATPase activity and DNA binding roles for the N‐terminal domain helix–hairpin–helix (HhH) motif. Structural and mutational results characterize RAD51 interactions with the breast cancer susceptibility protein BRCA2 in higher eukaryotes. A designed P.furiosus RAD51 mutant binds BRC repeats and forms BRCA2‐dependent nuclear foci in human cells in response to γ‐irradiation‐induced DNA damage, similar to human RAD51. These results show that BRCA2 repeats mimic the RAD51‐PM and imply analogous RAD51 interactions with RAD52 and RAD54. Both BRCA2 and RAD54 may act as antagonists and chaperones for RAD51 filament assembly by coupling RAD51 interface exchanges with DNA binding. Together, these structural and mutational results support an interface exchange hypothesis for coordinated protein interactions in homologous recombination.

The BRC Repeats of BRCA2 Modulate the DNA Binding Selectivity of RAD51

The breast cancer susceptibility protein, BRCA2, is essential for recombinational DNA repair. BRCA2 delivers RAD51 to double-stranded DNA (dsDNA) breaks through interaction with eight conserved, approximately 35 amino acid motifs, the BRC repeats. Here we show that the solitary BRC4 promotes assembly of RAD51 onto single-stranded DNA (ssDNA), but not dsDNA, to stimulate DNA strand exchange. BRC4 acts by blocking ATP hydrolysis and thereby maintaining the active ATP-bound form of the RAD51-ssDNA filament. Single-molecule visualization shows that BRC4 does not disassemble RAD51-dsDNA filaments but rather blocks nucleation of RAD51 onto dsDNA. Furthermore, this behavior is manifested by a domain of BRCA2 comprising all eight BRC repeats. These results establish that the BRC repeats modulate RAD51-DNA interaction in two opposing but functionally reinforcing ways: targeting active RAD51 to ssDNA and prohibiting RAD51 nucleation onto dsDNA. Thus, BRCA2 recruits RAD51 to DNA breaks and, we propose, the BRC repeats regulate DNA-binding selectivity.

Disruption of the developmentally regulated Rev3l gene causes embryonic lethality

The REV3 gene encodes the catalytic subunit of DNA polymerase (pol) zeta, which can replicate past certain types of DNA lesions [1]. Saccharomyces cerevisiae rev3 mutants are viable and have lower rates of spontaneous and DNA-damage-induced mutagenesis [2]. Reduction in the level of Rev31, the presumed catalytic subunit of mammalian pol zeta, decreased damage-induced mutagenesis in human cell lines [3]. To study the function of mammalian Rev31, we inactivated the gene in mice. Two exons containing conserved DNA polymerase motifs were replaced by a cassette encoding G418 resistance and beta-galactosidase, under the control of the Rev3l promoter. Surprisingly, disruption of Rev3l caused mid-gestation embryonic lethality, with the frequency of Rev3l(-/-) embryos declining markedly between 9.5 and 12.5 days post coitum (dpc). Rev3l(-/-) embryos were smaller than their heterozygous littermates and showed retarded development. Tissues in many areas were disorganised, with significantly reduced cell density. Rev3l expression, traced by beta-galactosidase staining, was first detected during early somitogenesis and gradually expanded to other tissues of mesodermal origin, including extraembryonic membranes. Embryonic death coincided with the period of more widely distributed Rev3l expression. The data demonstrate an essential function for murine Rev31 and suggest that bypass of specific types of DNAlesions by pol zeta is essential for cell viability during embryonic development in mammals.

Cip1 inhibits DNA replication but not PCNA-dependent nucleotide excision-repair

BACKGROUNDnDNA that is damaged by ultraviolet (UV) light is repaired predominantly by nucleotide excision-repair, a process requiring the DNA polymerase auxiliary factor PCNA. UV-irradiation also induces the production of Cip1 protein via activation of p53. Cip1 is an inhibitor of the cyclin-dependent kinases, which are required for the cell cycle to proceed through the G1/S-phase transition and initiate DNA replication. Inhibition by Cip1 probably causes the block to initiation of DNA replication that is seen in irradiated cells. Cip1 also directly inhibits the function of PCNA during DNA synthesis. As nucleotide excision-repair requires PCNA, the physiological relevance of PCNA inhibition by Cip1 is currently unclear.nnnRESULTSnWe show that nucleotide excision-repair of UV-damaged DNA occurs in extracts of Xenopus eggs, and that this reaction is PCNA-dependent. The repair reaction is not inhibited by Cip1, even when the level of PCNA is reduced 100-fold so that it becomes limiting for DNA repair. By contrast, Cip1 strongly suppresses the function of PCNA in replicative DNA synthesis under these conditions.nnnCONCLUSIONSnCip1 can potentially inhibit DNA replication in Xenopus egg extracts by inhibiting the cyclin-dependent kinase function required for the initiation of replication forks, and also by inhibiting PCNA function. The inhibition of PCNA is selective for its function in DNA replication, however, as Cip1 does not affect PCNA function in nucleotide excision-repair. The induction of Cip1 in response to DNA damage, therefore, allows repair to continue in the genome under conditions in which replication is severely inhibited.

The Evolutionarily Conserved Zinc Finger Motif in the Largest Subunit of Human Replication Protein A Is Required for DNA Replication and Mismatch Repair but Not for Nucleotide Excision Repair

The largest subunit of the replication protein A (RPA) contains an evolutionarily conserved zinc finger motif that lies outside of the domains required for binding to single-stranded DNA or forming the RPA holocomplex. In previous studies, we showed that a point mutation in this motif (RPAm) cannot support SV40 DNA replication. We have now investigated the role of this motif in several steps of DNA replication and in two DNA repair pathways. RPAm associates with T antigen, assists the unwinding of double-stranded DNA at an origin of replication, stimulates DNA polymerases α and δ, and supports the formation of the initial short Okazaki fragments. However, the synthesis of a leading strand and later Okazaki fragments is impaired. In contrast, RPAm can function well during the incision step of nucleotide excision repair and in a full repair synthesis reaction, with either UV-damaged or cisplatin-adducted DNA. Two deletion mutants of the Rpa1 subunit (eliminating amino acids 1–278 or 222–411) were not functional in nucleotide excision repair. We report for the first time that wild type RPA is required for a mismatch repair reaction in vitro. Neither the deletion mutants nor RPAm can support this reaction. Therefore, the zinc finger of the largest subunit of RPA is required for a function that is essential for DNA replication and mismatch repair but not for nucleotide excision repair.

A region of human BRCA2 containing multiple BRC repeats promotes RAD51-mediated strand exchange

Human BRCA2, a breast and ovarian cancer suppressor, binds to the DNA recombinase RAD51 through eight conserved BRC repeats, motifs of ∼30 residues, dispersed across a large region of the protein. BRCA2 is essential for homologous recombination in vivo, but isolated BRC repeat peptides can prevent the assembly of RAD51 into active nucleoprotein filaments in vitro, suggesting a model in which BRCA2 sequesters RAD51 in undamaged cells, and promotes recombinase function after DNA damage. How BRCA2 might fulfill these dual functions is unclear. We have purified a fragment of human BRCA2 (BRCA2BRC1–8) with 1127 residues spanning all 8 BRC repeats but excluding the C-terminal DNA-binding domain (BRCA2CTD). BRCA2BRC1–8 binds RAD51 nucleoprotein filaments in a ternary complex, indicating it may organize RAD51 on DNA. Human RAD51 is relatively ineffective in vitro at strand exchange between homologous DNA molecules unless non-physiological ions like NH4+ are present. In an ionic milieu more typical of the mammalian nucleus, BRCA2BRCI–8 stimulates RAD51-mediated strand exchange, suggesting it may be an essential co-factor in vivo. Thus, the human BRC repeats, embedded within their surronding sequences as an eight-repeat unit, mediate homologous recombination independent of the BRCA2CTD through a previously unrecognized role in control of RAD51 activity.

Resistance of human nucleotide excision repair synthesis in vitro to p21Cdn1

The p21Cdn1 protein (cip1/waf1/sdi1) plays an important role as an inhibitor of mammalian cell proliferation in response to DNA damage. By interacting with and inhibiting the function of cyclin-Cdk complexes, p21 can block entry into S phase. p21 can also directly inhibit replicative DNA synthesis by binding to the DNA polymerase sliding clamp factor PCNA. When cells are damaged and p21 is induced, DNA nucleotide excision repair (NER) continues, even though this pathway is PCNA-dependent. We investigated features of p21-resistant NER using human cell extracts. A direct end-labelling approach was used to measure the excision of damaged oligonucleotides by NER and no inhibition by p21 was found. By contrast, filling of the ∼30u2009nt gaps created by NER could be inhibited by pre-binding p21 to PCNA, but only when gap filling was uncoupled from incision. Binding p21 to PCNA could also inhibit filling of model 30u2009nt gaps by both purified DNA polymerases δ and ε. When p21 was incubated in a cell extract before addition of PCNA, inhibition of repair synthesis was gradually relieved with time. This incubation gives p21 the opportunity to associate with other targets. As p21 blocks association of DNA polymerases with PCNA but does not prevent loading of PCNA onto DNA, repair gap filling can occur rapidly as soon as p21 dissociates from PCNA. A synthetic PCNA-binding p21 peptide was an efficient inhibitor of NER synthesis in cell extracts.

Definition of a Short Region of XPG Necessary for TFIIH Interaction and Stable Recruitment to Sites of UV Damage

ABSTRACT XPG is the human endonuclease that cuts 3′ to DNA lesions during nucleotide excision repair. Missense mutations in XPG can lead to xeroderma pigmentosum (XP), whereas truncated or unstable XPG proteins cause Cockayne syndrome (CS), normally yielding life spans of <7 years. One XP-G individual who had advanced XP/CS symptoms at 28 years has been identified. The genetic, biochemical, and cellular defects in this remarkable case provide insight into the onset of XP and CS, and they reveal a previously unrecognized property of XPG. Both of this individuals XPG alleles produce a severely truncated protein, but an infrequent alternative splice generates an XPG protein lacking seven internal amino acids, which can account for his very slight cellular UV resistance. Deletion of XPG amino acids 225 to 231 does not abolish structure-specific endonuclease activity. Instead, this region is essential for interaction with TFIIH and for the stable recruitment of XPG to sites of local UV damage after the prior recruitment of TFIIH. These results define a new functional domain of XPG, and they demonstrate that recruitment of DNA repair proteins to sites of damage does not necessarily lead to productive repair reactions. This observation has potential implications that extend beyond nucleotide excision repair.