Interaction studies of muts and mutl with DNA containing the major cisplatin lesion and its mismatched counterpart under equilibrium and nonequilibrium conditions

The DNA mismatch repair (MMR) system participates in cis‐diamminedichloroplatinum (II) (cisplatin) cytotoxicity through signaling of cisplatin DNA lesions by yet unknown molecular mechanisms. It is thus of great interest to determine whether specialized function of MMR proteins could be associated with cisplatin DNA damage. The major cisplatin 1,2‐d(GpG) intrastrand crosslink and compound lesions arising from misincorporation of a mispaired base opposite either platinated guanine of the 1,2‐d(GpG) adduct are thought to be critical lesions for MMR signaling. Previously, we have shown that cisplatin compound lesion with a mispaired thymine opposite the 3′ platinated guanine triggers new Escherichia coli MutS ATP‐dependent biochemical activities distinguishable from those encountered with DNA mismatch consistent with a role of this lesion in MMR‐dependent signaling mechanism. In this report, we show that the major cisplatin 1,2‐d(GpG) intrastrand crosslink does not confer novel MutS postrecognition biochemical activity as studied by surface plasmon resonance spectroscopy. A fast rate of MutS ATP‐dependent dissociation prevents MutL recruitment to the major cisplatin lesion in contrast to cisplatin compound lesion which authorized MutS‐dependent recruitment of MutL with a dynamic of ternary complex formation distinguishable from that encountered with DNA mismatch substrate. We conclude that the mode of cisplatin DNA damage recognition by MutS and the nature of MMR post‐recognition events are lesion‐dependent and suggest that MMR signaling through the major cisplatin lesion is unlikely to occur. © 2013 Wiley Periodicals, Inc. Biopolymers 99: 636–647, 2013.     

Formation of a DNA mismatch repair complex mediated by ATP

The mismatch repair proteins, MutS and MutL, interact in a DNA mismatch and ATP-dependent manner to activate downstream events in repair. Here, we assess the role of ATP binding and hydrolysis in mismatch recognition by MutS and the formation of a ternary complex involving MutS and MutL bound to a mismatched DNA. We show that ATP reduces the affinity of MutS for mismatched DNA and that the modulation of DNA binding affinity by nucleotide is even more pronounced for MutS E694A, a protein that binds ATP but is defective for ATP hydrolysis. Despite the ATP hydrolysis defect, E694A, like WT MutS, undergoes rapid, ATP-dependent dissociation from a DNA mismatch. Furthermore, MutS E694A retains the ability to interact with MutL on mismatched DNA. The recruitment of MutL to a mismatched DNA by MutS is also observed for two mutant MutL proteins, E29A, defective for ATP hydrolysis, and R266A, defective for DNA binding. These results suggest that ATP binding in the absence of hydrolysis is sufficient to trigger formation of a MutS sliding clamp. However, recruitment of MutL results in the formation of a dynamic ternary complex that we propose is the intermediate that signals subsequent repair steps requiring ATP hydrolysis.     

Mismatch repair factor MSH2-MSH3 binds and alters the conformation of branched DNA structures predicted to form during genetic recombination

Genetic studies in Saccharomyces cerevisiae predict that the mismatch repair (MMR) factor MSH2-MSH3 binds and stabilizes branched recombination intermediates that form during single strand annealing and gene conversion. To test this model, we constructed a series of DNA substrates that are predicted to form during these recombination events. We show in an electrophoretic mobility shift assay that S. cerevisiae MSH2-MSH3 specifically binds branched DNA substrates containing 3' single-stranded DNA and that ATP stimulates its release from these substrates. Chemical footprinting analyses indicate that MSH2-MSH3 specifically binds at the double-strand/single-strand junction of branched substrates, alters its conformation and opens up the junction. Therefore, MSH2-MSH3 binding to its substrates creates a unique nucleoprotein structure that may signal downstream steps in repair that include interactions with MMR and nucleotide excision repair factors.     

DNA错配修复蛋白MutS和MutL的相互作用研究

MutL 和 MutS 是DNA错配修复系统中起关键作用的修复蛋白. 利用基因融合技术高效表达了MutL 和 MutS融合蛋白,并利用它们发展了一种研究二者相互作用的简便方法. 融合蛋白MutL-GFP (Trx-His6-GFP-(Ser-Gly)6-MutL),MutL-Strep tagⅡ (Trx-His6-(Ser-Gly)6-Strep tagⅡ-(Ser-Gly)6-MutL) 和 MutS (Trx-His6-(Ser-Gly)6-MutS) 被构建并在大肠杆菌中高效表达. 收集菌体细胞、超声波破碎后离心取上清进行SDS-聚丙烯酰胺凝胶电泳 (SDS-PAGE) 分析,结果表明有与预期分子质量相应的诱导表达条带出现,其表达量约占全细胞蛋白的30％且以可溶形式存在. 利用固定化金属离子配体亲和层析柱分别纯化融合蛋白,其纯度达到90％. 通过将MutS蛋白固定的方法研究两种MutL融合蛋白分别与MutS之间的相互作用. 结果表明：只有MutS蛋白与含有错配碱基DNA分子结合后才与MutL蛋白发生相互作用. 通过检测MutL融合蛋白标记的绿色荧光信号或酶学显色信号来鉴定相互作用的发生. 建立的融合分子系统方法也为研究其他的蛋白质或生物大分子之间的相互作用提供了一个技术平台.     

Functional interaction between MutL and 3′-5′ Exonuclease X in Escherichia coli

Exonuclease X is a 3′-5′ distributive exonuclease that functions in DNA recombination and repair. It undergoes multiple rounds of binding, hydrolysis, and release to degrade long substrate molecules and thus is very inefficient. In order to identify a cofactor that elevates the excision activity of ExoX, we screened many proteins involved in repair and recombination. We observed that MutL greatly promoted the exonuclease activity of ExoX, and then verified the interaction between MutL and ExoX using SPR and Far-Western analysis. This promotion is independent of ATP and the DNA-binding activity of MutL. We constructed two deletion mutants to analyze this interaction and its regulation of ExoX activity, and found that this functional interaction with ExoX is mainly due to ionic interactions with the N-terminus of MutL. This adds a new role to MutL and gives a clue to MutL’s possible regulation on other DnaQ family exonuclease members.     

Structure of the MutL C-terminal domain: a model of intact MutL and its roles in mismatch repair

MutL assists the mismatch recognition protein MutS to initiate and coordinate mismatch repair in species ranging from bacteria to humans. The MutL N-terminal ATPase domain is highly conserved, but the C-terminal region shares little sequence similarity among MutL homologs. We report here the crystal structure of the Escherichia coli MutL C-terminal dimerization domain and the likelihood of its conservation among MutL homologs. A 100-residue proline-rich linker between the ATPase and dimerization domains, which generates a large central cavity in MutL dimers, tolerates sequence substitutions and deletions of one-third of its length with no functional consequences in vivo or in vitro. Along the surface of the central cavity, residues essential for DNA binding are located in both the N- and C-terminal domains. Each domain of MutL interacts with UvrD helicase and is required for activating the helicase activity. The DNA-binding capacity of MutL is correlated with the level of UvrD activation. A model of how MutL utilizes its ATPase and DNA-binding activities to mediate mismatch-dependent activation of MutH endonuclease and UvrD helicase is proposed.     

Analysis of the quaternary structure of the MutL C-terminal domain

The dimeric DNA mismatch repair protein MutL has a key function in communicating mismatch recognition by MutS to downstream repair processes. Dimerization of MutL is mediated by the C-terminal domain, while activity of the protein is modulated by the ATP-dependent dimerization of the highly conserved N-terminal domain. Recently, a crystal structure analysis of the Escherichia coli MutL C-terminal dimerization domain has been reported and a model for the biological dimer was proposed. In this model, dimerization is mediated by the internal (In) subdomain comprising residues 475-569. Here, we report a computational analysis of all protein interfaces observed in the crystal structure and suggest that the biological dimer interface is formed by a hydrophobic surface patch of the external (Ex) subdomain (residues 432-474 and 570-615). Moreover, sequence analysis revealed that this surface patch is conserved among the MutL proteins. To test this hypothesis, single and double-cysteine variants of MutL were generated and tested for their ability to be cross-linked with chemical cross-linkers of various size. Finally, deletion of the C-terminal residues 605-615 abolished homodimerization. The biochemical data are fully compatible with a revised model for the biological dimer, which has important implications for understanding the heterodimerization of eukaryotic MutL homologues, modeling the MutL holoenzyme and predicting protein-protein interaction sites.     

DNA mismatch correction in Haemophilus influenzae: characterization of MutL, MutH and their interaction

Haemophilus influenzae DNA mismatch repair proteins, MutS, MutL and MutH, are functionally characterized in this study. Introduction of mutS, mutL and mutH genes of H. influenzae resulted in complementation of the mismatch repair activity of the respective mutant strains of Escherichia coli to varying levels. DNA binding studies using H. influenzae MutH have shown that the protein is capable of binding to any DNA sequence non-specifically in a co-operative and metal independent manner. Presence of MutL and ATP in the binding reaction resulted in the formation of a more specific complex, which indicates that MutH is conferred specificity for binding hemi-methylated DNA through structural alterations mediated by its interaction with MutL. To study the role of conserved amino acids Ile213 and Leu214 in the helix at the C-terminus of MutH, they were mutated to alanine. The mutant proteins showed considerably reduced DNA binding and nicking, as well as MutL-mediated activation. MutH failed to nick HU bound DNA whereas MboI and Sau3AI, which have the same recognition sequence as MutH, efficiently cleaved the substrate. MutS ATPase activity was found to be reduced two-fold in presence of covalently closed circular duplex containing a mismatched base pair whereas, the activity was regained upon linearization of the circular duplex. This observation possibly suggests that the MutS clamps are trapped in the closed DNA heteroduplex. These studies, therefore, serve as the basis for a detailed investigation of the structure-function relationship among the protein partners of the mismatch repair pathway of H. influenzae.     

In vitro studies of DNA mismatch repair proteins

The ability to monitor and characterize DNA mismatch repair activity in various mammalian cells is important for understanding mechanisms involved in mutagenesis and tumorigenesis. Since mismatch repair proteins recognize mismatches containing both normal and chemically altered or damaged bases, in vitro assays must accommodate a variety of mismatches in different sequence contexts. Here we describe the construction of DNA mismatch substrates containing G:T or O⁶meG:T mismatches, the purification of recombinant native human MutSα (MSH2–MSH6) and MutLα (MLH1–PMS2) proteins, and in vitro mismatch repair and excision assays that can be adapted to study mismatch repair in nuclear extracts from mismatch repair proficient and deficient cells.