Jeungphill Hanne

Cascading MutS and MutL sliding clamps control DNA diffusion to activate mismatch repair

Mismatched nucleotides arise from polymerase misincorporation errors, recombination between heteroallelic parents and chemical or physical DNA damage. Highly conserved MutS (MSH) and MutL (MLH/PMS) homologues initiate mismatch repair and, in higher eukaryotes, act as DNA damage sensors that can trigger apoptosis. Defects in human mismatch repair genes cause Lynch syndrome or hereditary non-polyposis colorectal cancer and 10–40% of related sporadic tumours. However, the collaborative mechanics of MSH and MLH/PMS proteins have not been resolved in any organism. We visualized Escherichia coli (Ec) ensemble mismatch repair and confirmed that EcMutS mismatch recognition results in the formation of stable ATP-bound sliding clamps that randomly diffuse along the DNA with intermittent backbone contact. The EcMutS sliding clamps act as a platform to recruit EcMutL onto the mismatched DNA, forming an EcMutS–EcMutL search complex that then closely follows the DNA backbone. ATP binding by EcMutL establishes a second long-lived DNA clamp that oscillates between the principal EcMutS–EcMutL search complex and unrestricted EcMutS and EcMutL sliding clamps. The EcMutH endonuclease that targets mismatch repair excision only binds clamped EcMutL, increasing its DNA association kinetics by more than 1,000-fold. The assembly of an EcMutS–EcMutL–EcMutH search complex illustrates how sequential stable sliding clamps can modulate one-dimensional diffusion mechanics along the DNA to direct mismatch repair.

Dynamic control of strand excision during human DNA mismatch repair

Significance The ensemble interactions between the human mismatch repair (MMR) components during mismatch-dependent DNA excision repair remain poorly characterized. We have detailed these interactions in real time to reveal new dynamic collaborations between the four evolutionarily conserved components that ultimately result in a complete MMR event. Our observations demonstrate the stochastic nature of an essential genome maintenance system that ultimately results in robust repair events. Mismatch repair (MMR) is activated by evolutionarily conserved MutS homologs (MSH) and MutL homologs (MLH/PMS). MSH recognizes mismatched nucleotides and form extremely stable sliding clamps that may be bound by MLH/PMS to ultimately authorize strand-specific excision starting at a distant 3′- or 5′-DNA scission. The mechanical processes associated with a complete MMR reaction remain enigmatic. The purified human (Homo sapien or Hs) 5′-MMR excision reaction requires the HsMSH2–HsMSH6 heterodimer, the 5′ → 3′ exonuclease HsEXOI, and the single-stranded binding heterotrimer HsRPA. The HsMLH1–HsPMS2 heterodimer substantially influences 5′-MMR excision in cell extracts but is not required in the purified system. Using real-time single-molecule imaging, we show that HsRPA or Escherichia coli EcSSB restricts HsEXOI excision activity on nicked or gapped DNA. HsMSH2–HsMSH6 activates HsEXOI by overcoming HsRPA/EcSSB inhibition and exploits multiple dynamic sliding clamps to increase tract length. Conversely, HsMLH1–HsPMS2 regulates tract length by controlling the number of excision complexes, providing a link to 5′ MMR.

An Efficient Site-Specific Method for Irreversible Covalent Labeling of Proteins with a Fluorophore

Fluorophore labeling of proteins while preserving native functions is essential for bulk Förster resonance energy transfer (FRET) interaction and single molecule imaging analysis. Here we describe a versatile, efficient, specific, irreversible, gentle and low-cost method for labeling proteins with fluorophores that appears substantially more robust than a similar but chemically distinct procedure. The method employs the controlled enzymatic conversion of a central Cys to a reactive formylglycine (fGly) aldehyde within a six amino acid Formylglycine Generating Enzyme (FGE) recognition sequence in vitro. The fluorophore is then irreversibly linked to the fGly residue using a Hydrazinyl-Iso-Pictet-Spengler (HIPS) ligation reaction. We demonstrate the robust large-scale fluorophore labeling and purification of E.coli (Ec) mismatch repair (MMR) components. Fluorophore labeling did not alter the native functions of these MMR proteins in vitro or in singulo. Because the FGE recognition sequence is easily portable, FGE-HIPS fluorophore-labeling may be easily extended to other proteins.

Widespread nuclease contamination in commonly used oxygen-scavenging systems

These observations suggested that DNA binding and/or aggregation, nuclease and other contaminants should be removed from the OSS before use in DNA-SM analysis. We developed a straightforward Superose 6 size-exclusion chromatography purification method for PCDa that takes advantage of the enzyme’s large reported size, with 12 α-dimer (23.3 kDa) and β-dimer (26.6 kDa) subunits4 (Supplementary Notes 5 and 6). The majority of nuclease activity eluted as an ~40-kDa protein, with a slightly higher molecular weight shoulder at ~100 kDa (Fig. 1b and Supplementary Fig. 6), whereas peak PCD enzyme activity corresponded with the αβ-subunits, eluting at 417 kDa (Fig. 1b and Supplementary Figs. 6 and 7). The pooled PCD fractions (43–51) were free of nuclease activity and did not inhibit several DNA metabolic reactions even at high concentrations (100 nM; Supplementary Figs. 5 and 8–10 and Supplementary Note 7). Using SM photobleaching analysis, we counted and analyzed the number of Cy3 spots on a 3,429-μm2 image area as a function of irradiation time at different PCD concentrations (Fig. 1c–e and Supplementary Fig. 11). We observed a PCD concentration–dependent increase in Cy3 half-life, in which Cy3 fluorescence loss at 10 nM PCD was negligible after 4 min of irradiation (Fig. 1c and Supplementary Fig. 11). An extended analysis suggested an apparent photobleaching rate constant of 10 nM PCD (kpb = 0.016 ± 0.003 min –1; s.e. from the fitting) that resulted in an estimated halflife of Cy3 of ~2,600 s (43 min) (Fig. 1e), which substantially exceeds observations from most SM kinetic studies5. Moreover, we observed very little ‘blinking’ of Cy3, similar to previous reports3, suggesting a remarkable additional stability that is capable of enhancing SM analysis (data not shown). Finally, GODaCATa and PCDa are the most common OSS enzymes used in SM DNA and RNA analysis. Our surveys strongly suggest that these enzymes could influence SM observations as a result of multiple contaminants. We recommend the use of commercial PCDb or purified PCDa, as outlined here for DNAor RNA-based SM studies (Fig. 1 and Supplementary Fig. 5). Although the commercial CATc preparation is relatively free of nuclease, there does not seem to be a commercial GOD product or method of purification that will provide a nucleasefree OSS with these enzymes.

Retroviral intasomes search for a target DNA by 1D diffusion which rarely results in integration.

Retroviruses must integrate their linear viral cDNA into the host genome for a productive infection. Integration is catalysed by the retrovirus-encoded integrase (IN), which forms a tetramer or octamer complex with the viral cDNA long terminal repeat (LTR) ends termed an intasome. IN removes two 3′-nucleotides from both LTR ends and catalyses strand transfer of the recessed 3′-hydroxyls into the target DNA separated by 4–6 bp. Host DNA repair restores the resulting 5′-Flap and single-stranded DNA (ssDNA) gap. Here we have used multiple single molecule imaging tools to determine that the prototype foamy virus (PFV) retroviral intasome searches for an integration site by one-dimensional (1D) rotation-coupled diffusion along DNA. Once a target site is identified, the time between PFV strand transfer events is 470 ms. The majority of PFV intasome search events were non-productive. These observations identify new dynamic IN functions and suggest that target site-selection limits retroviral integration.

Repair of Oxidative DNA Base Damage in the Host Genome Influences the HIV Integration Site Sequence Preference

Host base excision repair (BER) proteins that repair oxidative damage enhance HIV infection. These proteins include the oxidative DNA damage glycosylases 8-oxo-guanine DNA glycosylase (OGG1) and mutY homolog (MYH) as well as DNA polymerase beta (Polβ). While deletion of oxidative BER genes leads to decreased HIV infection and integration efficiency, the mechanism remains unknown. One hypothesis is that BER proteins repair the DNA gapped integration intermediate. An alternative hypothesis considers that the most common oxidative DNA base damages occur on guanines. The subtle consensus sequence preference at HIV integration sites includes multiple G:C base pairs surrounding the points of joining. These observations suggest a role for oxidative BER during integration targeting at the nucleotide level. We examined the hypothesis that BER repairs a gapped integration intermediate by measuring HIV infection efficiency in Polβ null cell lines complemented with active site point mutants of Polβ. A DNA synthesis defective mutant, but not a 5′dRP lyase mutant, rescued HIV infection efficiency to wild type levels; this suggeted Polβ DNA synthesis activity is not necessary while 5′dRP lyase activity is required for efficient HIV infection. An alternate hypothesis that BER events in the host genome influence HIV integration site selection was examined by sequencing integration sites in OGG1 and MYH null cells. In the absence of these 8-oxo-guanine specific glycosylases the chromatin elements of HIV integration site selection remain the same as in wild type cells. However, the HIV integration site sequence preference at G:C base pairs is altered at several positions in OGG1 and MYH null cells. Inefficient HIV infection in the absence of oxidative BER proteins does not appear related to repair of the gapped integration intermediate; instead oxidative damage repair may participate in HIV integration site preference at the sequence level.

Dynamic unwrapping of nucleosomes by HsRAD51 that includes sliding and rotational motion of histone octamers

Wrapping of genomic DNA into nucleosomes poses thermodynamic and kinetic barriers to biological processes such as replication, transcription, repair and recombination. Previous biochemical studies have demonstrated that in the presence of adenosine triphosphate (ATP) the human RAD51 (HsRAD51) recombinase can form a nucleoprotein filament (NPF) on double-stranded DNA (dsDNA) that is capable of unwrapping the nucleosomal DNA from the histone octamer (HO). Here, we have used single molecule Förster Resonance Energy Transfer (smFRET) to examine the real time nucleosome dynamics in the presence of the HsRAD51 NPF. We show that oligomerization of HsRAD51 leads to stepwise, but stochastic unwrapping of the DNA from the HO in the presence of ATP. The highly reversible dynamics observed in single-molecule trajectories suggests an antagonistic mechanism between HsRAD51 binding and rewrapping of the DNA around the HO. These stochastic dynamics were independent of the nucleosomal DNA sequence or the asymmetry created by the presence of a linker DNA. We also observed sliding and rotational oscillations of the HO with respect to the nucleosomal DNA. These studies underline the dynamic nature of even tightly associated protein–DNA complexes such as nucleosomes.

MutS homolog sliding clamps shield the DNA from binding proteins

Sliding clamps on DNA consist of evolutionarily conserved enzymes that coordinate DNA replication, repair, and the cellular DNA damage response. MutS homolog (MSH) proteins initiate mismatch repair (MMR) by recognizing mispaired nucleotides and in the presence of ATP form stable sliding clamps that randomly diffuse along the DNA. The MSH sliding clamps subsequently load MutL homolog (MLH/PMS) proteins that form a second extremely stable sliding clamp, which together coordinate downstream MMR components with the excision-initiation site that may be hundreds to thousands of nucleotides distant from the mismatch. Specific or nonspecific binding of other proteins to the DNA between the mismatch and the distant excision-initiation site could conceivably obstruct the free diffusion of these MMR sliding clamps, inhibiting their ability to initiate repair. Here, we employed bulk biochemical analysis, single-molecule fluorescence imaging, and mathematical modeling to determine how sliding clamps might overcome such hindrances along the DNA. Using both bacterial and human MSH proteins, we found that increasing the number of MSH sliding clamps on a DNA decreased the association of the Escherichia coli transcriptional repressor LacI to its cognate promoter LacO. Our results suggest a simple mechanism whereby thermal diffusion of MSH sliding clamps along the DNA alters the association kinetics of other DNA-binding proteins over extended distances. These observations appear generally applicable to any stable sliding clamp that forms on DNA.