Phase separation of Polycomb-repressive complex 1 is governed by a charged disordered region of CBX2.

Mammalian development requires effective mechanisms to repress genes whose expression would generate inappropriately specified cells. The Polycomb-repressive complex 1 (PRC1) family complexes are central to maintaining this repression. These include a set of canonical PRC1 complexes, each of which contains four core proteins, including one from the CBX family. These complexes have been shown previously to reside in membraneless organelles called Polycomb bodies, leading to speculation that canonical PRC1 might be found in a separate phase from the rest of the nucleus. We show here that reconstituted PRC1 readily phase-separates into droplets in vitro at low concentrations and physiological salt conditions. This behavior is driven by the CBX2 subunit. Point mutations in an internal domain of Cbx2 eliminate phase separation. These same point mutations eliminate the formation of puncta in cells and have been shown previously to eliminate nucleosome compaction in vitro and generate axial patterning defects in mice. Thus, the domain of CBX2 that is important for phase separation is the same domain shown previously to be important for chromatin compaction and proper development, raising the possibility of a mechanistic or evolutionary link between these activities.

CAT7 and cat7l Long Non-coding RNAs Tune Polycomb Repressive Complex 1 Function during Human and Zebrafish Development.

The essential functions of polycomb repressive complex 1 (PRC1) in development and gene silencing are thought to involve long non-coding RNAs (lncRNAs), but few specific lncRNAs that guide PRC1 activity are known. We screened for lncRNAs, which co-precipitate with PRC1 from chromatin and found candidates that impact polycomb group protein (PcG)-regulated gene expression in vivo A novel lncRNA from this screen, CAT7, regulates expression and polycomb group binding at the MNX1 locus during early neuronal differentiation. CAT7 contains a unique tandem repeat domain that shares high sequence similarity to a non-syntenic zebrafish analog, cat7l Defects caused by interference of cat7l RNA during zebrafish embryogenesis were rescued by human CAT7 RNA, enhanced by interference of a PRC1 component, and suppressed by interference of a known PRC1 target gene, demonstrating cat7l genetically interacts with a PRC1. We propose a model whereby PRC1 acts in concert with specific lncRNAs and that CAT7/cat7l represents convergent lncRNAs that independently evolved to tune PRC1 repression at individual loci.

Single-molecule imaging reveals target-search mechanisms during DNA mismatch repair.

The ability of proteins to locate specific targets among a vast excess of nonspecific DNA is a fundamental theme in biology. Basic principles governing these search mechanisms remain poorly understood, and no study has provided direct visualization of single proteins searching for and engaging target sites. Here we use the postreplicative mismatch repair proteins MutSα and MutLα as model systems for understanding diffusion-based target searches. Using single-molecule microscopy, we directly visualize MutSα as it searches for DNA lesions, MutLα as it searches for lesion-bound MutSα, and the MutSα/MutLα complex as it scans the flanking DNA. We also show that MutLα undergoes intersite transfer between juxtaposed DNA segments while searching for lesion-bound MutSα, but this activity is suppressed upon association with MutSα, ensuring that MutS/MutL remains associated with the damage-bearing strand while scanning the flanking DNA. Our findings highlight a hierarchy of lesion- and ATP-dependent transitions involving both MutSα and MutLα, and help establish how different modes of diffusion can be used during recognition and repair of damaged DNA.

The unstructured linker arms of Mlh1-Pms1 are important for interactions with DNA during mismatch repair.

DNA mismatch repair (MMR) models have proposed that MSH (MutS homolog) proteins identify DNA polymerase errors while interacting with the DNA replication fork. MLH (MutL homolog) proteins (primarily Mlh1-Pms1 in baker's yeast) then survey the genome for lesion-bound MSH proteins. The resulting MSH-MLH complex formed at a DNA lesion initiates downstream steps in repair. MLH proteins act as dimers and contain long (20-30 nm) unstructured arms that connect two terminal globular domains. These arms can vary between 100 and 300 amino acids in length, are highly divergent between organisms, and are resistant to amino acid substitutions. To test the roles of the linker arms in MMR, we engineered a protease cleavage site into the Mlh1 linker arm domain of baker's yeast Mlh1-Pms1. Cleavage of the Mlh1 linker arm in vitro resulted in a defect in Mlh1-Pms1 DNA binding activity, and in vivo proteolytic cleavage resulted in a complete defect in MMR. We then generated a series of truncation mutants bearing Mlh1 and Pms1 linker arms of varying lengths. This work revealed that MMR is greatly compromised when portions of the Mlh1 linker are removed, whereas repair is less sensitive to truncation of the Pms1 linker arm. Purified complexes containing truncations in Mlh1 and Pms1 linker arms were analyzed and found to have differential defects in DNA binding that also correlated with the ability to form a ternary complex with Msh2-Msh6 and mismatch DNA. These observations are consistent with the unstructured linker domains of MLH proteins providing distinct interactions with DNA during MMR.

Visualizing one-dimensional diffusion of eukaryotic DNA repair factors along a chromatin lattice.

DNA-binding proteins survey genomes for targets using facilitated diffusion, which typically includes a one-dimensional (1D) scanning component for sampling local regions. Eukaryotic proteins must accomplish this task while navigating through chromatin. Yet it is unknown whether nucleosomes disrupt 1D scanning or eukaryotic DNA-binding factors can circumnavigate nucleosomes without falling off DNA. Here we use single-molecule microscopy in conjunction with nanofabricated curtains of DNA to show that the postreplicative mismatch repair protein complex Mlh1-Pms1 diffuses in 1D along DNA via a hopping/stepping mechanism and readily bypasses nucleosomes. This is the first experimental demonstration that a passively diffusing protein can traverse stationary obstacles. In contrast, Msh2-Msh6, a mismatch repair protein complex that slides while maintaining continuous contact with DNA, experiences a boundary upon encountering nucleosomes. These differences reveal important mechanistic constraints affecting intranuclear trafficking of DNA-binding proteins.

A mutation in the putative MLH3 endonuclease domain confers a defect in both mismatch repair and meiosis in Saccharomyces cerevisiae.

Interference-dependent crossing over in yeast and mammalian meioses involves the mismatch repair protein homologs MSH4-MSH5 and MLH1-MLH3. The MLH3 protein contains a highly conserved metal-binding motif DQHA(X)(2)E(X)(4)E that is found in a subset of MLH proteins predicted to have endonuclease activities (Kadyrov et al. 2006). Mutations within this motif in human PMS2 and Saccharomyces cerevisiae PMS1 disrupted the endonuclease and mismatch repair activities of MLH1-PMS2 and MLH1-PMS1, respectively (Kadyrov et al. 2006, 2007; Erdeniz et al. 2007). As a first step in determining whether such an activity is required during meiosis, we made mutations in the MLH3 putative endonuclease domain motif (-D523N, -E529K) and found that single and double mutations conferred mlh3-null-like defects with respect to meiotic spore viability and crossing over. Yeast two-hybrid and chromatography analyses showed that the interaction between MLH1 and mlh3-D523N was maintained, suggesting that the mlh3-D523N mutation did not disrupt the stability of MLH3. The mlh3-D523N mutant also displayed a mutator phenotype in vegetative growth that was similar to mlh3Delta. Overexpression of this allele conferred a dominant-negative phenotype with respect to mismatch repair. These studies suggest that the putative endonuclease domain of MLH3 plays an important role in facilitating mismatch repair and meiotic crossing over.