BLM–DNA2–RPA–MRN and EXO1–BLM–RPA–MRN constitute two DNA end resection machineries for human DNA break repair

Repair of dsDNA breaks requires processing to produce 3′-terminated ssDNA. We biochemically reconstituted DNA end resection using purified human proteins: Bloom helicase (BLM); DNA2 helicase/nuclease; Exonuclease 1 (EXO1); the complex comprising MRE11, RAD50, and NBS1 (MRN); and Replication protein A (RPA). Resection occurs via two routes. In one, BLM and DNA2 physically and specifically interact to resect DNA in a process that is ATP-dependent and requires BLM helicase and DNA2 nuclease functions. RPA is essential for both DNA unwinding by BLM and enforcing 5′ → 3′ resection polarity by DNA2. MRN accelerates processing by recruiting BLM to the end. In the other, EXO1 resects the DNA and is stimulated by BLM, MRN, and RPA. BLM increases the affinity of EXO1 for ends, and MRN recruits and enhances the processivity of EXO1. Our results establish two of the core machineries that initiate recombinational DNA repair in human cells

Mutations in the MutSα interaction interface of MLH1 can abolish DNA mismatch repair

MutLα, a heterodimer of MLH1 and PMS2, plays a central role in human DNA mismatch repair. It interacts ATP-dependently with the mismatch detector MutSα and assembles and controls further repair enzymes. We tested if the interaction of MutLα with DNA-bound MutSα is impaired by cancer-associated mutations in MLH1, and identified one mutation (Ala128Pro) which abolished interaction as well as mismatch repair activity. Further examinations revealed three more residues whose mutation interfered with interaction. Homology modelling of MLH1 showed that all residues clustered in a small accessible surface patch, suggesting that the major interaction interface of MutLα for MutSα is located on the edge of an extensive β-sheet that backs the MLH1 ATP binding pocket. Bioinformatic analysis confirmed that this patch corresponds to a conserved potential protein–protein interaction interface which is present in both human MLH1 and its E.coli homologue MutL. MutL could be site-specifically crosslinked to MutS from this patch, confirming that the bacterial MutL–MutS complex is established by the corresponding interface in MutL. This is the first study that identifies the conserved major MutLα–MutSα interaction interface in MLH1 and demonstrates that mutations in this interface can affect interaction and mismatch repair, and thereby can also contribute to cancer development

Functions of MutLα, Replication Protein A (RPA), and HMGB1 in 5′-Directed Mismatch Repair*

A purified system comprised of MutSα, MutLα, exonuclease 1 (Exo1), and replication protein A (RPA) (in the absence or presence of HMGB1) supports 5′-directed mismatch-provoked excision that terminates after mismatch removal. MutLα is not essential for this reaction but enhances excision termination, although the basis of this effect has been uncertain. One model attributes the primary termination function in this system to RPA, with MutLα functioning in a secondary capacity by suppressing Exo1 hydrolysis of mismatch-free DNA (Genschel, J., and Modrich, P. (2003) Mol. Cell 12, 1077–1086). A second invokes MutLα as the primary effector of excision termination (Zhang, Y., Yuan, F., Presnell, S. R., Tian, K., Gao, Y., Tomkinson, A. E., Gu, L., and Li, G. M. (2005) Cell 122, 693–705). In the latter model, RPA provides a secondary termination function, but together with HMGB1, also participates in earlier steps of the reaction. To distinguish between these models, we have reanalyzed the functions of MutLα, RPA, and HMGB1 in 5′-directed mismatch-provoked excision using purified components as well as mammalian cell extracts. Analysis of extracts derived from A2780/AD cells, which are devoid of MutLα but nevertheless support 5′-directed mismatch repair, has demonstrated that 5′-directed excision terminates normally in the absence of MutLα. Experiments using purified components confirm a primary role for RPA in terminating excision by MutSα-activated Exo1 but are inconsistent with direct participation of MutLα in this process. While HMGB1 attenuates excision by activated Exo1, this effect is distinct from that mediated by RPA. Assay of extracts derived from HMGB1+/+ and HMGB1−/− mouse embryo fibroblast cells indicates that HMGB1 is not essential for mismatch repair

A common core for binding single-stranded DNA: structural comparison of the single-stranded DNA-binding proteins (SSB) from E. coli and human mitochondria

The crystal structure of the DNA-binding domain of E. coli SSB ( EcoSSB) has been determined to a resolution of 2.5 Å. This is the first reported structure of a prokaryotic SSB. The structure of the DNA-binding domain of the E. coli protein is compared to that of the human mitochondrial SSB ( HsmtSSB). In spite of the relatively low sequence identity between them, the two proteins display a high degree of structural similarity. EcoSSB crystallises with two dimers in the asymmetric unit, unlike HsmtSSB which contains only a dimer. This is probably a consequence of the different polypeptide chain lengths in the EcoSSB heterotetramer. Crucial differences in the dimer-dimer interface of EcoSSB may account for the inability of EcoSSB and HsmtSSB to form cross-species heterotetramers, in contrast to many bacterial SSBs

PMS2 endonuclease activity has distinct biological functions and is essential for genome maintenance

The DNA mismatch repair protein PMS2 was recently found to encode a novel endonuclease activity. To determine the biological functions of this activity in mammals, we generated endonuclease-deficient Pms2 E702K knock-in mice. Pms2 EK/EK mice displayed increased genomic mutation rates and a strong cancer predisposition. In addition, class switch recombination, but not somatic hypermutation, was impaired in Pms2 EK/EK B cells, indicating a specific role in Ig diversity. In contrast to Pms2 −/− mice, Pms2 EK/EK male mice were fertile, indicating that this activity is dispensable in spermatogenesis. Therefore, the PMS2 endonuclease activity has distinct biological functions and is essential for genome maintenance and tumor suppression