Kerstin S. Wendt

Cohesin mediates transcriptional insulation by CCCTC-binding factor

Cohesin complexes mediate sister-chromatid cohesion in dividing cells but may also contribute to gene regulation in postmitotic cells. How cohesin regulates gene expression is not known. Here we describe cohesin-binding sites in the human genome and show that most of these are associated with the CCCTC-binding factor (CTCF), a zinc-finger protein required for transcriptional insulation. CTCF is dispensable for cohesin loading onto DNA, but is needed to enrich cohesin at specific binding sites. Cohesin enables CTCF to insulate promoters from distant enhancers and controls transcription at the H19/IGF2 (insulin-like growth factor 2) locus. This role of cohesin seems to be independent of its role in cohesion. We propose that cohesin functions as a transcriptional insulator, and speculate that subtle deficiencies in this function contribute to ‘cohesinopathies’ such as Cornelia de Lange syndrome.

Cohesin is required for higher-order chromatin conformation at the imprinted IGF2-H19 locus

Cohesin is a chromatin-associated protein complex that mediates sister chromatid cohesion by connecting replicated DNA molecules. Cohesin also has important roles in gene regulation, but the mechanistic basis of this function is poorly understood. In mammalian genomes, cohesin co-localizes with CCCTC binding factor (CTCF), a zinc finger protein implicated in multiple gene regulatory events. At the imprinted IGF2-H19 locus, CTCF plays an important role in organizing allele-specific higher-order chromatin conformation and functions as an enhancer blocking transcriptional insulator. Here we have used chromosome conformation capture (3C) assays and RNAi–mediated depletion of cohesin to address whether cohesin affects higher order chromatin conformation at the IGF2-H19 locus in human cells. Our data show that cohesin has a critical role in maintaining CTCF–mediated chromatin conformation at the locus and that disruption of this conformation coincides with changes in IGF2 expression. We show that the cohesin-dependent, higher-order chromatin conformation of the locus exists in both G1 and G2 phases of the cell cycle and is therefore independent of cohesins function in sister chromatid cohesion. We propose that cohesin can mediate interactions between DNA molecules in cis to insulate genes through the formation of chromatin loops, analogous to the cohesin mediated interaction with sister chromatids in trans to establish cohesion.

Crystal structure of the APC10/DOC1 subunit of the human anaphase-promoting complex.

The anaphase-promoting complex (APC), or cyclosome, is a cell cycle-regulated ubiquitin ligase that controls progression through mitosis and the G1 phase of the cell cycle. The APC is composed of at least 11 subunits; no structure has been determined for any of these subunits. The subunit APC10/DOC1, a one-domain protein consisting of 185 amino acids, has a conserved core (residues 22–161) that is homologous to domains found in several other putative ubiquitin ligases and, therefore, may play a role in ubiquitination reactions. Here we report the crystal structure of human APC10 at 1.6 Å resolution. The core of the protein is formed by a β-sandwich that adopts a jellyroll fold. Unexpectedly, this structure is highly similar to ligand-binding domains of several bacterial and eukaryotic proteins, such as galactose oxidase and coagulation factor Va, raising the possibility that APC10 may function by binding a yet unidentified ligand. We further provide biochemical evidence that the C-terminus of APC10 binds to CDC27/APC3, an APC subunit that contains multiple tetratrico peptide repeats.

Identification of a Subunit of a Novel Kleisin-β/SMC Complex as a Potential Substrate of Protein Phosphatase 2A

Protein phosphatase 2A (PP2A) holoenzymes consist of a catalytic C subunit, a scaffolding A subunit, and one of several regulatory B subunits that recruit the AC dimer to substrates. PP2A is required for chromosome segregation, but PP2As substrates in this process remain unknown. To identify PP2A substrates, we carried out a two-hybrid screen with the regulatory B/PR55 subunit. We isolated a human homolog of C. elegans HCP6, a protein distantly related to the condensin subunit hCAP-D2, and we named this homolog hHCP-6. Both C. elegans HCP-6 and condensin are required for chromosome organization and segregation. HCP-6 binding partners are unknown, whereas condensin is composed of the structural maintenance of chromosomes proteins SMC2 and SMC4 and of three non-SMC subunits. Here we show that hHCP-6 becomes phosphorylated during mitosis and that its dephosphorylation by PP2A in vitro depends on B/PR55, suggesting that hHCP-6 is a B/PR55-specific substrate of PP2A. Unlike condensin, hHCP-6 is localized in the nucleus in interphase, but similar to condensin, hHCP-6 associates with chromosomes during mitosis. hHCP-6 is part of a complex that contains SMC2, SMC4, kleisin-beta, and the previously uncharacterized HEAT repeat protein FLJ20311. hHCP-6 is therefore part of a condensin-related complex that associates with chromosomes in mitosis and may be regulated by PP2A.

How cohesin and CTCF cooperate in regulating gene expression.

Cohesin is a DNA-binding protein complex that is essential for sister chromatid cohesion and facilitates the repair of damaged DNA. In addition, cohesin has important roles in regulating gene expression, but the molecular mechanisms of this function are poorly understood. Recent experiments have revealed that cohesin binds to the same sites in mammalian genomes as the zinc finger transcription factor CTCF. At a few loci CTCF has been shown to function as an enhancer-blocking transcriptional insulator, and recent observations indicate that this function depends on cohesin. Here we review what is known about the roles of cohesin and CTCF in regulating gene expression in mammalian cells, and we discuss how cohesin might mediate the insulator function of CTCF.

The Suv39h–HP1 histone methylation pathway is dispensable for enrichment and protection of cohesin at centromeres in mammalian cells

Sister chromatids are physically connected by cohesin complexes. This sister chromatid cohesion is essential for the biorientation of chromosomes on the mitotic and meiotic spindle. In many species, cohesion between chromosome arms is partly dissolved in prophase of mitosis, whereas cohesion is protected at centromeres until the onset of anaphase. In vertebrates, the protein Sgo1, protein phosphatase 2A, and several other proteins are required for protection of centromeric cohesin in early mitosis. In fission yeast, the recruitment of heterochromatin protein Swi6/HP1 to centromeres by the histone-methyltransferase Clr4/Suv39h is required for enrichment of cohesin at centromeres already in interphase. We have tested if the Suv39h–HP1 histone methylation pathway is also required for enrichment and mitotic protection of cohesin at centromeres in mammalian cells. We show that cohesin and HP1 proteins partially colocalize at mitotic centromeres but that cohesin localization is not detectably altered in mouse embryonic fibroblasts that lack Suv39h genes and in which HP1 proteins can, therefore, not be properly enriched in pericentric heterochromatin. Our data indicate that the Suv39h–HP1 pathway is not essential for enrichment and mitotic protection of cohesin at centromeres in mammalian cells.

Crystal structure of the carboxyltransferase subunit of the bacterial sodium ion pump glutaconyl-coenzyme A decarboxylase

Glutaconyl‐CoA decarboxylase is a biotin‐dependent ion pump whereby the free energy of the glutaconyl‐CoA decarboxylation to crotonyl‐CoA drives the electrogenic transport of sodium ions from the cytoplasm into the periplasm. Here we present the crystal structure of the decarboxylase subunit (Gcdα) from Acidaminococcus fermentans and its complex with glutaconyl‐CoA. The active sites of the dimeric Gcdα lie at the two interfaces between the mono mers, whereas the N‐terminal domain provides the glutaconyl‐CoA‐binding site and the C‐terminal domain binds the biotinyllysine moiety. The Gcdα catalyses the transfer of carbon dioxide from glutaconyl‐CoA to a biotin carrier (Gcdγ) that subsequently is decarboxylated by the carboxybiotin decarboxylation site within the actual Na+ pump (Gcdβ). The analysis of the active site lead to a novel mechanism for the biotin‐dependent carboxy transfer whereby biotin acts as general acid. Furthermore, we propose a holoenzyme assembly in which the water‐filled central channel of the Gcdα dimer lies co‐axial with the ion channel (Gcdβ). The central channel is blocked by arginines against passage of sodium ions which might enter the central channel through two side channels.