Project description:Complex conformational dynamics are essential for the chaperone function of heat shock protein 90 (Hsp90), including transient, ATP-biased N-domain dimerization establishing ATPase competence. Biochemical data demonstrate that the intrinsic, but weak, ATP hydrolyzing activity of Hsp90 is markedly enhanced by the co-chaperone Aha1. However, cellular concentration of Aha1 is substoichiometric relative to Hsp90. In cells, interaction of this important co-chaperone with Hsp90 is up-regulated by posttranslational modifications (PTMs), including phosphorylation of a highly conserved tyrosine (Y313 in Hsp90a). Here we use chemical cross-linking with mass spectrometry to explore the the impacts of a phosphomimetic mutation (Y313E) and binding of a non-hydrolyzable ATP analog (AMP-PNP),on the structure Hsp90a and its interaction with Aha1.

Project description:The ring-shaped cohesin complex is thought to fulfil its roles in sister chromatid cohesion, genome stability and gene regulation by topologically encircling DNAs. The ring is formed by two Structural Maintenance of Chromosome (SMC) subunits, whose ATPase heads are linked by a kleisin subunit. Additional components, including the Mis4Scc2/NIPL cohesin loader, engage the kleisin. Here, we visualize a DNA gripping intermediate during cohesin loading onto DNA by cryo-electron microscopy. ATP-dependent head engagement creates an interaction surface onto which Mis4Scc2/NIPL clamps the DNA. We use biophysical tools to establish the order of events during cohesin loading. DNA first traverses an N-terminal kleisin gate that was opened by ATP binding and closed again as the loader locks the DNA. Ensuing ATP hydrolysis and head disengagement, assisted by Mis4Scc2/NIPL, will complete DNA entry. A conserved kleisin N-terminal tail guides the DNA on its trajectory to successful topological DNA entry into the cohesin ring.

Project description:Yeast vacuoles, equivalent to lysosomes in other eukaryotes, are important acidic degradative organelles as well as storage compartments and signaling hubs. To perform these functions, they rely on important protein complexes, including the V-ATPase, responsible for organelle acidification. In this study, we used cross-linking mass spectrometry to characterize the protein complexes of isolated vacuoles. We were able to detect many known protein-protein interactions, including known protein complexes, as well as undescribed ones. Among these, we identified the uncharacterized TLDc domain-containing protein Rtc5 as a novel interactor of the V-ATPase. We show that Rtc5 localizes to the vacuole membrane depending on N-myristoylation and on its interactions with the V-ATPase. We further analyzed the influence of this protein, and the second yeast TLDc domain-containing protein, Oxr1, on V-ATPase function. We find that both Rtc5 and Oxr1 promote the disassembly of the vacuolar V-ATPase in vivo, counteracting the role of the assembly chaperone, the RAVE complex. Finally, Oxr1 is necessary for the retention in the late Golgi complex of an organelle-specific subunit of the V-ATPase. Collectively, our results shed light on the in vivo roles of yeast TLDc domain-containing proteins in relation to the V-ATPase, highlighting the multifaceted regulation of this crucial protein complex.

Project description:Cross-linking mass spectrometry data for integrative structural analyses of the Smc5/6 holo-complex from budding yeast. Electron microscopy, crosslinking mass spectrometry, and computational modeling reveal that while the complex shares an overall organization with other SMC complexes, it possesses several strikingly different features.

Project description:Ubiquitination controls most cellular processes, and its deregulation is associated to many pathologies. The Nse1 subunit in the Smc5/6 complex contains a RING domain with ubiquitin E3 ligase activity and important functions in genome integrity. However, Nse1-dependent ubiquitin targets remain largely unknown. Here, we use label-free quantitative proteomics to analyse the nuclear ubiquitinome of nse1 RING mutant cells. Our results show that Nse1 impacts on the ubiquitination of several proteins involved in DNA damage tolerance, ribosome biogenesis and metabolism that, importantly, extend beyond canonical functions of the Smc5/6 complex in chromosome segregation. In addition, our analysis uncovers an unexpected connection between Nse1 and Pol I ubiquitination. Specifically, Nse1 promotes the ubiquitination of K408 and K410 in Rpa190, the largest subunit of Pol I, to induce its degradation. We propose that this mechanism contributes to Smc5/6-dependent rDNA disjunction in response to transcriptional elongation defects.

Project description:The DNA damage response (DDR) acts as a barrier to malignant transformation and is often impaired during tumorigenesis. Exploiting the impaired DDR can be a promising therapeutic strategy; however, the mechanisms of inactivation and corresponding biomarkers are incompletely understood. Starting from an unbiased screening approach, we identified the SMC5-SMC6 Complex Localization Factor 2 (SLF2) as a regulator of the DDR and biomarker for a B-cell lymphoma (BCL) patient subgroup with an adverse prognosis. SLF2-deficiency leads to loss of DDR factors including CLSPN and consequently impairs CHK1 activation. In line with this mechanism, genetic deletion of Slf2 drives lymphomagenesis in vivo. Tumor cells lacking SLF2 are characterized by a high level of DNA damage, which leads to alterations of the post-translational SUMOylation pathway as a safeguard. The resulting co-dependency confers synthetic lethality to a clinically applicable SUMOylation inhibitor (SUMOi), and inhibitors of the DDR pathway act highly synergistic with SUMOi. Together, our results identify SLF2 as a DDR regulator and reveal co-targeting of the DDR and SUMOylation as a promising strategy for the treatment of aggressive lymphoma.

Project description:The DNA damage response (DDR) acts as a barrier to malignant transformation and is often impaired during tumorigenesis. Exploiting the impaired DDR can be a promising therapeutic strategy; however, the mechanisms of inactivation and corresponding biomarkers are incompletely understood. Starting from an unbiased screening approach, we identified the SMC5-SMC6 Complex Localization Factor 2 (SLF2) as a regulator of the DDR and biomarker for a B-cell lymphoma (BCL) patient subgroup with an adverse prognosis. SLF2-deficiency leads to loss of DDR factors including CLSPN and consequently impairs CHK1 activation. In line with this mechanism, genetic deletion of Slf2 drives lymphomagenesis in vivo. Tumor cells lacking SLF2 are characterized by a high level of DNA damage, which leads to alterations of the post-translational SUMOylation pathway as a safeguard. The resulting co-dependency confers synthetic lethality to a clinically applicable SUMOylation inhibitor (SUMOi), and inhibitors of the DDR pathway act highly synergistic with SUMOi. Together, our results identify SLF2 as a DDR regulator and reveal co-targeting of the DDR and SUMOylation as a promising strategy for the treatment of aggressive lymphoma.

Project description:The essential functions of the conserved Smc5/6 complex remain elusive. To uncover its roles in genome maintenance, we established Saccharomyces cerevisiae cell cycle-regulated alleles that enable restriction of Smc5/6 components to S or G2/M. Unexpectedly, the essential functions of Smc5/6 segregated fully and selectively to G2/M. Genetic screens that became possible with generated alleles identified processes that crucially rely on Smc5/6 specifically in G2/M: metabolism of DNA recombination structures triggered by endogenous replication stress, and replication through natural pausing sites located in late-replicating regions. In the first process, Smc5/6 modulates remodeling of recombination intermediates, cooperating with dissolution activities. In the second, Smc5/6 prevents chromosome fragility and toxic recombination instigated by prolonged pausing and the fork protection complex, Tof1-Csm3. Our results thus dissect Smc5/6 essential roles, and reveal that combined defects in DNA damage tolerance and pausing site-replication cause recombination-mediated DNA lesions, which we propose to drive developmental and cancer-prone disorders. BrdU incorporation profiles by ssDNA-BrdU IP on chip have been generated as described (Katou et al., 2003). Protein binding profiles by ChIP-chip analysis were generated as described (Bermejo et al., 2009). Labeled probes were hybridized to Affymetrix S.cerevisiae Tiling 1.0 (P/N 900645) arrays and processed with TAS software.

Project description:In developing B cells the immunoglobulin heavy chain (IgH) locus is thought to move from repressive to permissive chromatin compartments to facilitate its scheduled rearrangement. In mature B cells, maintenance of allelic exclusion has been proposed to involve recruitment of the non-productive IgH allele to pericentromeric heterochromatin. Here we used an allele-specific chromosome conformation capture combined with sequencing (4C-seq) approach to unambigously follow the individual IgH alleles in mature B lymphocytes. Despite their physical and functional difference, productive and non-productive IgH alleles in B cells and unrearranged IgH alleles in T cells share many chromosomal contacts and largely reside in active chromatin. In brain, however, the locus resides in a different, repressive environment. We conclude that IgH adopts a lymphoid-specific nuclear location that is however unrelated to maintenance of allelic exclusion. We additionally find that in mature B cells - but not in T cells – the distal VH regions of both IgH alleles position themselves away from active chromatin. This, we speculate, may help to restrict enhancer activity to the productively rearranged VH promoter element. Allele specific analysis of the nuclear organization of the IgH locus in resting and activated B cells and T cells and fetal brain cells

Project description:Activating signal co-integrator complex (ASCC) supports diverse genome maintenance and gene expression processes. Its ASCC3 subunit is an unconventional nucleic acid helicase, harboring tandem Ski2-like NTPase/helicase cassettes crucial for ASCC functions. Presently, the molecular mechanisms underlying ASCC3 helicase activity and regulation remain unresolved. Here, we present cryogenic electron microscopy, DNA-protein cross-linking/mass spectrometry as well as in vitro and cellular functional analyses of the ASCC3-ASC1/TRIP4 sub-module of ASCC. Unlike the related spliceosomal SNRNP200 RNA helicase, ASCC3 can thread substrates through both helicase cassettes. ASC1 docks on ASCC3 via a zinc finger domain and stimulates the helicase by positioning a C-terminal ASC1-homology domain next to the C-terminal helicase cassette of ASCC3, likely assisting the DNA exit. ASC1 binds ASCC3 mutually exclusively with the dealkylase, ALKBH3, directing ASCC for specific ASCC-dependent processes. Our findings define ASCC3-ASC1/TRIP4 as a tunable motor module of ASCC that encompasses two cooperating ATPase/helicase units functionally expanded by ASC1/TRIP4.