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2. ATPase-Dependent Control of the Mms21 SUMO Ligase during DNA Repair

Author

Bermúdez-López, M. (Marcelino), Pociño-Merino, I. (Irene), Sanchez, H. (Humberto), Bueno, A. (Andrés), Guasch, C. (Clàudia), Almedawar, S. (Seba), Bru-Virgili, S. (Sergi), Garí, E. (Eloi), Wyman, C. (Claire), Reverter, D. (David), Colomina, N. (Neus), Torres-Rosell, J. (Jordi), Bermúdez-López, M. (Marcelino), Pociño-Merino, I. (Irene), Sanchez, H. (Humberto), Bueno, A. (Andrés), Guasch, C. (Clàudia), Almedawar, S. (Seba), Bru-Virgili, S. (Sergi), Garí, E. (Eloi), Wyman, C. (Claire), Reverter, D. (David), Colomina, N. (Neus), and Torres-Rosell, J. (Jordi)

Abstract

Modification of proteins by SUMO is essential for the maintenance of genome integrity. During DNA replication, the Mms21-branch of the SUMO pathway counteracts recombination intermediates at damaged replication forks, thus facilitating sister chromatid disjunction. The Mms21 SUMO ligase docks to the arm region of the Smc5 protein in the Smc5/6 complex; together, they cooperate during recombinational DNA repair. Yet how the activity of the SUMO ligase is controlled remains unknown. Here we show that the SUMO ligase and the chromosome disjunction functions of Mms21 depend on its docking to an intact and active Smc5/6 complex, indicating that the Smc5/6-Mms21 complex operates as a large SUMO ligase in vivo. In spite of the physical distance separating the E3 and the nucleotide-binding domains in Smc5/6, Mms21-dependent sumoylation requires binding of ATP to Smc5, a step that is part of the ligase mechanism that assists Ubc9 function. The communication is enabled by the presence of a conserved disruption in the coiled coil domain of Smc5, pointing to potential conformational changes for SUMO ligase activation. In accordance, scanning force microscopy of the Smc5-Mms21 heterodimer shows that the molecule is physically remodeled in an ATP-dependent manner. Our results demonstrate that the ATP-binding activity of the Smc5/6 complex is coordinated with its SUMO ligase, through the coiled coil domain of Smc5 and the physical remodeling of the molecule, to promote sumoylation and chromosome disjunction during DNA repair.

Published
2015
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3. ATPase-Dependent Control of the Mms21 SUMO Ligase during DNA Repair

Author

Bermudez-Lopez, M, Pocino-Merino, I, Sanchez, H, Bueno, A, Guasch, C, Almedawar, S, Bru-Virgili, S, Gari, E, Wyman, C.L., Reverter, D, Colomina, N, Torres-Rosell, J, Bermudez-Lopez, M, Pocino-Merino, I, Sanchez, H, Bueno, A, Guasch, C, Almedawar, S, Bru-Virgili, S, Gari, E, Wyman, C.L., Reverter, D, Colomina, N, and Torres-Rosell, J

Abstract

Modification of proteins by SUMO is essential for the maintenance of genome integrity. During DNA replication, the Mms21-branch of the SUMO pathway counteracts recombination intermediates at damaged replication forks, thus facilitating sister chromatid disjunction. The Mms21 SUMO ligase docks to the arm region of the Smc5 protein in the Smc5/6 complex; together, they cooperate during recombinational DNA repair. Yet how the activity of the SUMO ligase is controlled remains unknown. Here we show that the SUMO ligase and the chromosome disjunction functions of Mms21 depend on its docking to an intact and active Smc5/6 complex, indicating that the Smc5/6-Mms21 complex operates as a large SUMO ligase in vivo. In spite of the physical distance separating the E3 and the nucleotide-binding domains in Smc5/6, Mms21-dependent sumoylation requires binding of ATP to Smc5, a step that is part of the ligase mechanism that assists Ubc9 function. The communication is enabled by the presence of a conserved disruption in the coiled coil domain of Smc5, pointing to potential conformational changes for SUMO ligase activation. In accordance, scanning force microscopy of the Smc5-Mms21 heterodimer shows that the molecule is physically remodeled in an ATP-dependent manner. Our results demonstrate that the ATP-binding activity of the Smc5/6 complex is coordinated with its SUMO ligase, through the coiled coil domain of Smc5 and the physical remodeling of the molecule, to promote sumoylation and chromosome disjunction during DNA repair.

Published
2015

7. Crucial role of the NSE1 RING domain in Smc5/6 stability and FANCM-independent fork progression.

Author

Lorite NP, Apostolova S, Guasch-Vallés M, Pryer A, Unzueta F, Freire R, Solé-Soler R, Pedraza N, Dolcet X, Garí E, Agell N, Taylor EM, Colomina N, and Torres-Rosell J

Subjects
Humans, Cell Line, Chromosomal Proteins, Non-Histone metabolism, Chromosomal Proteins, Non-Histone genetics, DNA Helicases, Mutation, Protein Domains, Protein Stability, Carrier Proteins genetics, Carrier Proteins metabolism, Cell Cycle Proteins metabolism, Cell Cycle Proteins genetics, DNA Replication, Genomic Instability
Abstract

The Smc5/6 complex is a highly conserved molecular machine involved in the maintenance of genome integrity. While its functions largely depend on restraining the fork remodeling activity of Mph1 in yeast, the presence of an analogous Smc5/6-FANCM regulation in humans remains unknown. We generated human cell lines harboring mutations in the NSE1 subunit of the Smc5/6 complex. Point mutations or truncations in the RING domain of NSE1 result in drastically reduced Smc5/6 protein levels, with differential contribution of the two zinc-coordinating centers in the RING. In addition, nse1-RING mutant cells display cell growth defects, reduced replication fork rates, and increased genomic instability. Notably, our findings uncover a synthetic sick interaction between Smc5/6 and FANCM and show that Smc5/6 controls fork progression and chromosome disjunction in a FANCM-independent manner. Overall, our study demonstrates that the NSE1 RING domain plays vital roles in Smc5/6 complex stability and fork progression through pathways that are not evolutionary conserved., (© 2024. The Author(s).)

Published
2024
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8. Cyclin D1-Cdk4 regulates neuronal activity through phosphorylation of GABAA receptors.

Author

Pedraza N, Monserrat MV, Ferrezuelo F, Torres-Rosell J, Colomina N, Miguez-Cabello F, Párraga JP, Soto D, López-Merino E, García-Vilela C, Esteban JA, Egea J, and Garí E

Subjects
Animals, Mice, Rats, gamma-Aminobutyric Acid, Mice, Knockout, Neurons, Phosphorylation, Cyclin D1 genetics, Receptors, GABA-A genetics, Cyclin-Dependent Kinase 4 genetics
Abstract

Nuclear Cyclin D1 (Ccnd1) is a main regulator of cell cycle progression and cell proliferation. Interestingly, Ccnd1 moves to the cytoplasm at the onset of differentiation in neuronal precursors. However, cytoplasmic functions and targets of Ccnd1 in post-mitotic neurons are unknown. Here we identify the α4 subunit of gamma-aminobutyric acid (GABA) type A receptors (GABA A Rs) as an interactor and target of Ccnd1-Cdk4. Ccnd1 binds to an intracellular loop in α4 and, together with Cdk4, phosphorylates the α4 subunit at threonine 423 and serine 431. These modifications upregulate α4 surface levels, increasing the response of α4-containing GABA A Rs, measured in whole-cell patch-clamp recordings. In agreement with this role of Ccnd1-Cdk4 in neuronal signalling, inhibition of Cdk4 or expression of the non-phosphorylatable α4 decreases synaptic and extra-synaptic currents in the hippocampus of newborn rats. Moreover, according to α4 functions in synaptic pruning, CCND1 knockout mice display an altered pattern of dendritic spines that is rescued by the phosphomimetic α4. Overall, our findings molecularly link Ccnd1-Cdk4 to GABA A Rs activity in the central nervous system and highlight a novel role for this G 1 cyclin in neuronal signalling., (© 2023. The Author(s).)

Published
2023
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9. Ubiquitin proteomics identifies RNA polymerase I as a target of the Smc5/6 complex.

Author

Ibars E, Codina-Fabra J, Bellí G, Casas C, Tarrés M, Solé-Soler R, Lorite NP, Ximénez-Embún P, Muñoz J, Colomina N, and Torres-Rosell J

Subjects
Amino Acid Sequence, Proteomics, Cell Cycle Proteins metabolism, RNA, Ubiquitin-Protein Ligases genetics, Ubiquitin-Protein Ligases metabolism, RNA Polymerase I metabolism, Ubiquitin
Abstract

Ubiquitination controls numerous cellular processes, and its deregulation is associated with many pathologies. The Nse1 subunit in the Smc5/6 complex contains a RING domain with ubiquitin E3 ligase activity and essential functions in genome integrity. However, Nse1-dependent ubiquitin targets remain elusive. Here, we use label-free quantitative proteomics to analyze the nuclear ubiquitinome of nse1-C274A RING mutant cells. Our results show that Nse1 impacts the ubiquitination of several proteins involved in ribosome biogenesis and metabolism that, importantly, extend beyond canonical functions of Smc5/6. In addition, our analysis suggests a connection between Nse1 and RNA polymerase I (RNA Pol I) ubiquitination. Specifically, Nse1 and the Smc5/6 complex promote ubiquitination of K408 and K410 in the clamp domain of Rpa190, a modification that induces its degradation in response to blocks in transcriptional elongation. We propose that this mechanism contributes to Smc5/6-dependent segregation of the rDNA array, the locus transcribed by RNA Pol I., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2023 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published
2023
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10. Antitumor Effects of Ral-GTPases Downregulation in Glioblastoma.

Author

Cemeli T, Guasch-Vallés M, Ribes-Santolaria M, Ibars E, Navaridas R, Dolcet X, Pedraza N, Colomina N, Torres-Rosell J, Ferrezuelo F, Herreros J, and Garí E

Subjects
Animals, Cell Proliferation, Down-Regulation, GTP Phosphohydrolases, Humans, Mice, Glioblastoma genetics
Abstract

Glioblastoma (GBM) is the most common tumor in the central nervous system in adults. This neoplasia shows a high capacity of growth and spreading to the surrounding brain tissue, hindering its complete surgical resection. Therefore, the finding of new antitumor therapies for GBM treatment is a priority. We have previously described that cyclin D1-CDK4 promotes GBM dissemination through the activation of the small GTPases RalA and RalB. In this paper, we show that RalB GTPase is upregulated in primary GBM cells. We found that the downregulation of Ral GTPases, mainly RalB, prevents the proliferation of primary GBM cells and triggers a senescence-like response. Moreover, downregulation of RalA and RalB reduces the viability of GBM cells growing as tumorspheres, suggesting a possible role of these GTPases in the survival of GBM stem cells. By using mouse subcutaneous xenografts, we have corroborated the role of RalB in GBM growth in vivo. Finally, we have observed that the knockdown of RalB also inhibits cell growth in temozolomide-resistant GBM cells. Overall, our work shows that GBM cells are especially sensitive to Ral-GTPase availability. Therefore, we propose that the inactivation of Ral-GTPases may be a reliable therapeutic approach to prevent GBM progression and recurrence.

Published
2022
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11. Post-Translational Modifications of PCNA: Guiding for the Best DNA Damage Tolerance Choice.

Author

Bellí G, Colomina N, Castells-Roca L, and Lorite NP

Abstract

The sliding clamp PCNA is a multifunctional homotrimer mainly linked to DNA replication. During this process, cells must ensure an accurate and complete genome replication when constantly challenged by the presence of DNA lesions. Post-translational modifications of PCNA play a crucial role in channeling DNA damage tolerance (DDT) and repair mechanisms to bypass unrepaired lesions and promote optimal fork replication restart. PCNA ubiquitination processes trigger the following two main DDT sub-pathways: Rad6/Rad18-dependent PCNA monoubiquitination and Ubc13-Mms2/Rad5-mediated PCNA polyubiquitination, promoting error-prone translation synthesis (TLS) or error-free template switch (TS) pathways, respectively. However, the fork protection mechanism leading to TS during fork reversal is still poorly understood. In contrast, PCNA sumoylation impedes the homologous recombination (HR)-mediated salvage recombination (SR) repair pathway. Focusing on Saccharomyces cerevisiae budding yeast, we summarized PCNA related-DDT and repair mechanisms that coordinately sustain genome stability and cell survival. In addition, we compared PCNA sequences from various fungal pathogens, considering recent advances in structural features. Importantly, the identification of PCNA epitopes may lead to potential fungal targets for antifungal drug development.

Published
2022
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12. Sumoylation of Smc5 Promotes Error-free Bypass at Damaged Replication Forks.

Author

Zapatka M, Pociño-Merino I, Heluani-Gahete H, Bermúdez-López M, Tarrés M, Ibars E, Solé-Soler R, Gutiérrez-Escribano P, Apostolova S, Casas C, Aragon L, Wellinger R, Colomina N, and Torres-Rosell J

Subjects
Chromatids genetics, Chromosomes genetics, DNA genetics, DNA Damage genetics, DNA Repair genetics, Saccharomyces cerevisiae genetics, Cell Cycle Proteins genetics, DNA Replication genetics, Saccharomyces cerevisiae Proteins genetics, Sumoylation genetics
Abstract

Replication of a damaged DNA template can threaten the integrity of the genome, requiring the use of various mechanisms to tolerate DNA lesions. The Smc5/6 complex, together with the Nse2/Mms21 SUMO ligase, plays essential roles in genome stability through undefined tasks at damaged replication forks. Various subunits within the Smc5/6 complex are substrates of Nse2, but we currently do not know the role of these modifications. Here we show that sumoylation of Smc5 is targeted to its coiled-coil domain, is upregulated by replication fork damage, and participates in bypass of DNA lesions. smc5-KR mutant cells display defects in formation of sister chromatid junctions and higher translesion synthesis. Also, we provide evidence indicating that Smc5 sumoylation modulates Mph1-dependent fork regression, acting synergistically with other pathways to promote chromosome disjunction. We propose that sumoylation of Smc5 enhances physical remodeling of damaged forks, avoiding the use of a more mutagenic tolerance pathway., (Copyright © 2019 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published
2019
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13. DNA activates the Nse2/Mms21 SUMO E3 ligase in the Smc5/6 complex.

Author

Varejão N, Ibars E, Lascorz J, Colomina N, Torres-Rosell J, and Reverter D

Subjects
Cell Cycle Proteins genetics, Cell Cycle Proteins metabolism, DNA Damage, DNA, Fungal genetics, DNA, Fungal metabolism, Enzyme Activation, Multiprotein Complexes genetics, Multiprotein Complexes metabolism, SUMO-1 Protein genetics, SUMO-1 Protein metabolism, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins genetics, Saccharomyces cerevisiae Proteins metabolism, Sumoylation, Ubiquitin-Protein Ligases genetics, Ubiquitin-Protein Ligases metabolism, Cell Cycle Proteins chemistry, DNA, Fungal chemistry, Multiprotein Complexes chemistry, SUMO-1 Protein chemistry, Saccharomyces cerevisiae chemistry, Saccharomyces cerevisiae Proteins chemistry, Ubiquitin-Protein Ligases chemistry
Abstract

Modification of chromosomal proteins by conjugation to SUMO is a key step to cope with DNA damage and to maintain the integrity of the genome. The recruitment of SUMO E3 ligases to chromatin may represent one layer of control on protein sumoylation. However, we currently do not understand how cells upregulate the activity of E3 ligases on chromatin. Here we show that the Nse2 SUMO E3 in the Smc5/6 complex, a critical player during recombinational DNA repair, is directly stimulated by binding to DNA Activation of sumoylation requires the electrostatic interaction between DNA and a positively charged patch in the ARM domain of Smc5, which acts as a DNA sensor that subsequently promotes a stimulatory activation of the E3 activity in Nse2. Specific disruption of the interaction between the ARM of Smc5 and DNA sensitizes cells to DNA damage, indicating that this mechanism contributes to DNA repair. These results reveal a mechanism to enhance a SUMO E3 ligase activity by direct DNA binding and to restrict sumoylation in the vicinity of those Smc5/6-Nse2 molecules engaged on DNA., (© 2018 The Authors.)

Published
2018
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14. Analysis of SUMOylation in the RENT Complex by Fusion to a SUMO-Specific Protease Domain.

Author

Colomina N, Guasch C, and Torres-Rosell J

Subjects
Cell Cycle Proteins genetics, Cloning, Molecular methods, Cysteine Endopeptidases genetics, DNA, Fungal genetics, DNA, Fungal isolation & purification, Mutagenesis, Site-Directed methods, Nuclear Proteins genetics, Polymerase Chain Reaction methods, Protein Tyrosine Phosphatases genetics, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae Proteins genetics, Silent Information Regulator Proteins, Saccharomyces cerevisiae genetics, Sirtuin 2 genetics, Small Ubiquitin-Related Modifier Proteins genetics, Sumoylation, Transformation, Genetic, Cell Cycle Proteins metabolism, Cysteine Endopeptidases metabolism, Nuclear Proteins metabolism, Protein Tyrosine Phosphatases metabolism, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins metabolism, Silent Information Regulator Proteins, Saccharomyces cerevisiae metabolism, Sirtuin 2 metabolism, Small Ubiquitin-Related Modifier Proteins metabolism
Abstract

Protein sumoylation is a reversible posttranslational modification that controls multiple processes during cell cycle progression. Frequently, SUMO synergistically targets various subunits in a protein complex to modulate its function, leading to what has been defined as protein group sumoylation. Different subunits in the RENT (regulator of nucleolar silencing and telophase) complex, including Net1, Sir2, and Cdc14, can be coupled to SUMO, making it difficult to ascertain the role of this modification. Here we describe a method to downregulate sumoylation in RENT, consisting in the fusion of a catalytic domain of the Ulp1 SUMO protease (Ulp Domain; UD) to the C-terminus of members in the complex using epitope tags as linkers. Targeting of the UD to specific loci can be simplified by transformation of PCR-amplified cassettes. The presence of the UD in the complex allows the concurrent downregulation of sumoylated species in the RENT complex, what can be easily monitored by pull-down of SUMO conjugates. This methodology can be applied to other protein complexes exhibiting group sumoylation.

Published
2017
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15. Cytoplasmic cyclin D1 regulates cell invasion and metastasis through the phosphorylation of paxillin.

Author

Fusté NP, Fernández-Hernández R, Cemeli T, Mirantes C, Pedraza N, Rafel M, Torres-Rosell J, Colomina N, Ferrezuelo F, Dolcet X, and Garí E

Subjects
Animals, Cell Line, Tumor, Cell Membrane metabolism, Cyclin D1 deficiency, Cyclin-Dependent Kinase 4 metabolism, Down-Regulation genetics, Fibroblasts metabolism, Gene Knockdown Techniques, HEK293 Cells, Humans, Mice, Neoplasm Invasiveness, Neoplasm Metastasis, Phosphorylation, Phosphoserine metabolism, Protein Binding, Rats, Substrate Specificity, rac1 GTP-Binding Protein metabolism, Cyclin D1 metabolism, Cytoplasm metabolism, Neoplasms metabolism, Neoplasms pathology, Paxillin metabolism
Abstract

Cyclin D1 (Ccnd1) together with its binding partner Cdk4 act as a transcriptional regulator to control cell proliferation and migration, and abnormal Ccnd1·Cdk4 expression promotes tumour growth and metastasis. While different nuclear Ccnd1·Cdk4 targets participating in cell proliferation and tissue development have been identified, little is known about how Ccnd1·Cdk4 controls cell adherence and invasion. Here, we show that the focal adhesion component paxillin is a cytoplasmic substrate of Ccnd1·Cdk4. This complex phosphorylates a fraction of paxillin specifically associated to the cell membrane, and promotes Rac1 activation, thereby triggering membrane ruffling and cell invasion in both normal fibroblasts and tumour cells. Our results demonstrate that localization of Ccnd1·Cdk4 to the cytoplasm does not simply act to restrain cell proliferation, but constitutes a functionally relevant mechanism operating under normal and pathological conditions to control cell adhesion, migration and metastasis through activation of a Ccnd1·Cdk4-paxillin-Rac1 axis.

Published
2016
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16. The Aurora-B-dependent NoCut checkpoint prevents damage of anaphase bridges after DNA replication stress.

Author

Amaral N, Vendrell A, Funaya C, Idrissi FZ, Maier M, Kumar A, Neurohr G, Colomina N, Torres-Rosell J, Geli MI, and Mendoza M

Subjects
Actomyosin metabolism, Adenosine Triphosphatases metabolism, Chromatin metabolism, Chromosomal Proteins, Non-Histone metabolism, DNA Topoisomerases, Type II metabolism, DNA-Binding Proteins metabolism, Histone Acetyltransferases metabolism, Hydroxyurea pharmacology, Microbial Viability drug effects, Models, Biological, Multiprotein Complexes metabolism, Saccharomyces cerevisiae drug effects, Saccharomyces cerevisiae ultrastructure, Spindle Apparatus drug effects, Spindle Apparatus metabolism, Anaphase drug effects, Aurora Kinases metabolism, Cell Cycle Checkpoints drug effects, DNA Replication drug effects, Saccharomyces cerevisiae cytology, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins metabolism, Stress, Physiological drug effects
Abstract

Anaphase chromatin bridges can lead to chromosome breakage if not properly resolved before completion of cytokinesis. The NoCut checkpoint, which depends on Aurora B at the spindle midzone, delays abscission in response to chromosome segregation defects in yeast and animal cells. How chromatin bridges are detected, and whether abscission inhibition prevents their damage, remain key unresolved questions. We find that bridges induced by DNA replication stress and by condensation or decatenation defects, but not dicentric chromosomes, delay abscission in a NoCut-dependent manner. Decatenation and condensation defects lead to spindle stabilization during cytokinesis, allowing bridge detection by Aurora B. NoCut does not prevent DNA damage following condensin or topoisomerase II inactivation; however, it protects anaphase bridges and promotes cellular viability after replication stress. Therefore, the molecular origin of chromatin bridges is critical for activation of NoCut, which plays a key role in the maintenance of genome stability after replicative stress.

Published
2016
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17. ATPase-dependent control of the Mms21 SUMO ligase during DNA repair.

Author

Bermúdez-López M, Pociño-Merino I, Sánchez H, Bueno A, Guasch C, Almedawar S, Bru-Virgili S, Garí E, Wyman C, Reverter D, Colomina N, and Torres-Rosell J

Subjects
Adenosine Triphosphate metabolism, Binding Sites, Cell Cycle Proteins chemistry, Cell Cycle Proteins metabolism, Chromatids metabolism, Chromatids ultrastructure, DNA Damage, DNA Replication, DNA, Fungal chemistry, Protein Binding, Protein Interaction Domains and Motifs, Protein Multimerization, SUMO-1 Protein chemistry, SUMO-1 Protein metabolism, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins chemistry, Saccharomyces cerevisiae Proteins metabolism, Signal Transduction, Sumoylation, Ubiquitin-Conjugating Enzymes genetics, Ubiquitin-Conjugating Enzymes metabolism, Ubiquitin-Conjugating Enzyme UBC9, Cell Cycle Proteins genetics, DNA, Fungal metabolism, Gene Expression Regulation, Fungal, Recombinational DNA Repair, SUMO-1 Protein genetics, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae Proteins genetics
Abstract

Modification of proteins by SUMO is essential for the maintenance of genome integrity. During DNA replication, the Mms21-branch of the SUMO pathway counteracts recombination intermediates at damaged replication forks, thus facilitating sister chromatid disjunction. The Mms21 SUMO ligase docks to the arm region of the Smc5 protein in the Smc5/6 complex; together, they cooperate during recombinational DNA repair. Yet how the activity of the SUMO ligase is controlled remains unknown. Here we show that the SUMO ligase and the chromosome disjunction functions of Mms21 depend on its docking to an intact and active Smc5/6 complex, indicating that the Smc5/6-Mms21 complex operates as a large SUMO ligase in vivo. In spite of the physical distance separating the E3 and the nucleotide-binding domains in Smc5/6, Mms21-dependent sumoylation requires binding of ATP to Smc5, a step that is part of the ligase mechanism that assists Ubc9 function. The communication is enabled by the presence of a conserved disruption in the coiled coil domain of Smc5, pointing to potential conformational changes for SUMO ligase activation. In accordance, scanning force microscopy of the Smc5-Mms21 heterodimer shows that the molecule is physically remodeled in an ATP-dependent manner. Our results demonstrate that the ATP-binding activity of the Smc5/6 complex is coordinated with its SUMO ligase, through the coiled coil domain of Smc5 and the physical remodeling of the molecule, to promote sumoylation and chromosome disjunction during DNA repair.

Published
2015
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18. A SUMO-dependent step during establishment of sister chromatid cohesion.

Author

Almedawar S, Colomina N, Bermúdez-López M, Pociño-Merino I, and Torres-Rosell J

Subjects
Cell Cycle Proteins physiology, Chromosomal Proteins, Non-Histone physiology, DNA Damage, Recombinant Fusion Proteins metabolism, Saccharomyces cerevisiae Proteins physiology, Cell Cycle Proteins metabolism, Chromatids metabolism, Chromosomal Proteins, Non-Histone metabolism, Chromosome Segregation physiology, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae Proteins metabolism, Sumoylation
Abstract

Cohesin is a protein complex that ties sister DNA molecules from the time of DNA replication until the metaphase to anaphase transition. Current models propose that the association of the Smc1, Smc3, and Scc1/Mcd1 subunits creates a ring-shaped structure that entraps the two sister DNAs. Cohesin is essential for correct chromosome segregation and recombinational repair. Its activity is therefore controlled by several posttranslational modifications, including acetylation, phosphorylation, sumoylation, and site-specific proteolysis. Here we show that cohesin sumoylation occurs at the time of cohesion establishment, after cohesin loading and ATP binding, and independently from Eco1-mediated cohesin acetylation. In order to test the functional relevance of cohesin sumoylation, we have developed a novel approach in budding yeast to deplete SUMO from all subunits in the cohesin complex, based on fusion of the Scc1 subunit to a SUMO peptidase Ulp domain (UD). Downregulation of cohesin sumoylation is lethal, and the Scc1-UD chimeras have a failure in sister chromatid cohesion. Strikingly, the unsumoylated cohesin rings are acetylated. Our findings indicate that SUMO is a novel molecular determinant for the establishment of sister chromatid cohesion, and we propose that SUMO is required for the entrapment of sister chromatids during the acetylation-mediated closure of the cohesin ring., (Copyright © 2012 Elsevier Ltd. All rights reserved.)

Published
2012
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19. The critical size is set at a single-cell level by growth rate to attain homeostasis and adaptation.

Author

Ferrezuelo F, Colomina N, Palmisano A, Garí E, Gallego C, Csikász-Nagy A, and Aldea M

Subjects
G1 Phase, HSP40 Heat-Shock Proteins genetics, HSP40 Heat-Shock Proteins metabolism, Homeostasis, Kinetics, Saccharomyces cerevisiae chemistry, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins genetics, Saccharomyces cerevisiae Proteins metabolism, Cell Cycle, Saccharomyces cerevisiae cytology, Saccharomyces cerevisiae growth & development
Abstract

Budding yeast cells are assumed to trigger Start and enter the cell cycle only after they attain a critical size set by external conditions. However, arguing against deterministic models of cell size control, cell volume at Start displays great individual variability even under constant conditions. Here we show that cell size at Start is robustly set at a single-cell level by the volume growth rate in G1, which explains the observed variability. We find that this growth-rate-dependent sizer is intimately hardwired into the Start network and the Ydj1 chaperone is key for setting cell size as a function of the individual growth rate. Mathematical modelling and experimental data indicate that a growth-rate-dependent sizer is sufficient to ensure size homeostasis and, as a remarkable advantage over a rigid sizer mechanism, it reduces noise in G1 length and provides an immediate solution for size adaptation to external conditions at a population level.

Published
2012
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20. Translokin (Cep57) interacts with cyclin D1 and prevents its nuclear accumulation in quiescent fibroblasts.

Author

Ruiz-Miró M, Colomina N, Fernández RM, Garí E, Gallego C, and Aldea M

Subjects
Animals, Cell Cycle Proteins, Cells, Cultured, Cyclin-Dependent Kinase 4 metabolism, Fibroblasts cytology, Humans, Mice, Mice, Knockout, Retinoblastoma Protein metabolism, Carrier Proteins metabolism, Cell Cycle physiology, Cell Nucleus metabolism, Cyclin D1 metabolism, Fibroblasts metabolism
Abstract

Nuclear accumulation of cyclin D1 because of altered trafficking or degradation is thought to contribute directly to neoplastic transformation and growth. Mechanisms of cyclin D1 localization in S phase have been studied in detail, but its control during exit from the cell cycle and quiescence is poorly understood. Here we report that translokin (Tlk), a microtubule-associated protein also termed Cep57, interacts with cyclin D1 and controls its nucleocytoplasmic distribution in quiescent cells. Tlk binds to regions of cyclin D1 also involved in binding to cyclin-dependent kinase 4 (Cdk4), and a fraction of cyclin D1 associates to the juxtanuclear Tlk network in the cell. Downregulation of Tlk levels results in undue nuclear accumulation of cyclin D1 and increased Cdk4-dependent phosphorylation of pRB under quiescence conditions. In turn, overexpression of Tlk prevents proper cyclin D1 accumulation in the nucleus of proliferating cells in an interaction-dependent manner, inhibits Cdk4-dependent phosphorylation of pRB and hinders cell cycle progression to S phase. We propose that the Tlk acts as a key negative regulator in the pathway that drives nuclear import of cyclin D1, thus contributing to prevent pRB inactivation and to maintain cellular quiescence., (© 2011 John Wiley & Sons A/S.)

Published
2011
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21. The transcriptional network activated by Cln3 cyclin at the G1-to-S transition of the yeast cell cycle.

Author

Ferrezuelo F, Colomina N, Futcher B, and Aldea M

Subjects
Chromatin Immunoprecipitation, Cyclins genetics, DNA, Fungal metabolism, Databases, Genetic, Gene Expression Profiling, Genes, Fungal genetics, Genetic Variation, Likelihood Functions, Oligonucleotide Array Sequence Analysis, Promoter Regions, Genetic genetics, Protein Binding, Reproducibility of Results, Saccharomyces cerevisiae Proteins genetics, Transcription Factors metabolism, Transcription, Genetic, Cyclins metabolism, G1 Phase genetics, Gene Expression Regulation, Fungal, Gene Regulatory Networks genetics, S Phase genetics, Saccharomyces cerevisiae cytology, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae Proteins metabolism
Abstract

Background: The G1-to-S transition of the cell cycle in the yeast Saccharomyces cerevisiae involves an extensive transcriptional program driven by transcription factors SBF (Swi4-Swi6) and MBF (Mbp1-Swi6). Activation of these factors ultimately depends on the G1 cyclin Cln3., Results: To determine the transcriptional targets of Cln3 and their dependence on SBF or MBF, we first have used DNA microarrays to interrogate gene expression upon Cln3 overexpression in synchronized cultures of strains lacking components of SBF and/or MBF. Secondly, we have integrated this expression dataset together with other heterogeneous data sources into a single probabilistic model based on Bayesian statistics. Our analysis has produced more than 200 transcription factor-target assignments, validated by ChIP assays and by functional enrichment. Our predictions show higher internal coherence and predictive power than previous classifications. Our results support a model whereby SBF and MBF may be differentially activated by Cln3., Conclusions: Integration of heterogeneous genome-wide datasets is key to building accurate transcriptional networks. By such integration, we provide here a reliable transcriptional network at the G1-to-S transition in the budding yeast cell cycle. Our results suggest that to improve the reliability of predictions we need to feed our models with more informative experimental data.

Published
2010
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22. Whi3 regulates morphogenesis in budding yeast by enhancing Cdk functions in apical growth.

Author

Colomina N, Ferrezuelo F, Vergés E, Aldea M, and Garí E

Subjects
Actins metabolism, Cell Cycle physiology, Cytoskeleton metabolism, RNA-Binding Proteins genetics, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins genetics, cdc42 GTP-Binding Protein, Saccharomyces cerevisiae metabolism, CDC28 Protein Kinase, S cerevisiae metabolism, Cyclin B metabolism, Cyclins metabolism, RNA-Binding Proteins metabolism, Saccharomyces cerevisiae growth & development, Saccharomyces cerevisiae Proteins metabolism
Abstract

The Whi3 protein is associated with the endoplasmic reticulum, interacts with Cdc28, the budding-yeast Cdk, binds the mRNA of cyclin CLN3 and prevents accumulation of the Cdc28-Cln3 in the nucleus until late G(1). Besides its function as a cell size regulator, Whi3 is strictly required for filamentous growth. Here we show that emerging buds in Whi3-deficient cells are considerably rounder than in wild-type cells, indicating that Whi3 is required to maintain apical growth during S phase. This defect was not suppressed by deletion of CLB2, which is involved in switching from polar to isotropic bud growth, indicating that the observed phenotype is not the result of Whi3 acting solely as a negative regulator of cyclin Clb2. However, Cdc28 did not properly accumulate at the bud tip during S phase in whi3Delta cells, and their elongation defects were suppressed by CLN2 overexpression, suggesting a positive function for Whi3 in a Cdk-cyclin-dependent step required for apical growth. Additionally, the actin cytoskeleton was perturbed in Whi3-deficient cells, and WHI3 showed genetic interactions with actin patch components. Our results point to Whi3 as a key modulator of apical growth effectors to coordinate cell cycle events and morphogenesis. We propose that Whi3 is required for the apical localization of Cdc28-Cln1,2 complexes during bud growth and thereby, to promote the activation of Cdc42 and its effectors in the bud apex.

Published
2009
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23. Whi3, a developmental regulator of budding yeast, binds a large set of mRNAs functionally related to the endoplasmic reticulum.

Author

Colomina N, Ferrezuelo F, Wang H, Aldea M, and Garí E

Subjects
Cytoplasm metabolism, Exocytosis, Genome, Fungal, Models, Biological, Multigene Family, Mutation, Oligonucleotide Array Sequence Analysis, Protein Binding, RNA, Messenger metabolism, Temperature, Endoplasmic Reticulum metabolism, Gene Expression Regulation, Fungal, RNA-Binding Proteins metabolism, RNA-Binding Proteins physiology, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins metabolism, Saccharomyces cerevisiae Proteins physiology, Saccharomycetales metabolism
Abstract

Whi3 is an RNA-binding protein associated with the endoplasmic reticulum (ER) that binds the CLN3 mRNA and plays a key role in the efficient retention of cyclin Cln3 at the ER. In the present work, we have identified new Whi3-associated mRNAs by a genomic approach. A large and significant number of these Whi3 targets encode for membrane and exocytic proteins involved in processes such as transport and cell wall biogenesis. Consistent with the genomic data, we have observed that cell wall integrity is compromised in Whi3-deficient cells and found strong genetic interactions between WHI3 and the cell integrity pathway. Whi3-associated mRNAs are enriched in clusters of the tetranucleotide GCAU, and mutation of the GCAU clusters in the CLN3 mRNA caused a reduction in its association to Whi3, suggesting that these sequences may act as cis-determinants for binding. Our data suggest that Whi3 is involved in the regulation and/or localization of a large subset of mRNAs functionally related to the ER and, since it is important for different molecular processes such as cytoplasmic retention or exocytic traffic of proteins, we propose that Whi3 is a general modulator of protein fate in budding yeast.

Published
2008
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24. Control of cell cycle and cell growth by molecular chaperones.

Author

Aldea M, Garí E, and Colomina N

Subjects
Saccharomycetales physiology, Cell Cycle physiology, Cell Enlargement, Cell Proliferation, Molecular Chaperones physiology, Saccharomycetales cytology, Saccharomycetales growth & development
Abstract

Cells adapt their size to both intrinsic and extrinsic demands and, among them, those that stem from growth and proliferation rates are crucial for cell size homeostasis. Here we revisit mechanisms that regulate cell cycle and cell growth in budding yeast. Cyclin Cln3, the most upstream activator of Start, is retained at the endoplasmic reticulum in early G(1) and released by specific chaperones in late G(1) to initiate the cell cycle. On one hand, these chaperones are rate-limiting for release of Cln3 and cell cycle entry and, on the other hand, they are required for key biosynthetic processes. We propose a model whereby the competition for specialized chaperones between growth and cycle machineries could gauge biosynthetic rates and set a critical size threshold at Start.

Published
2007
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25. Cyclin Cln3 is retained at the ER and released by the J chaperone Ydj1 in late G1 to trigger cell cycle entry.

Author

Vergés E, Colomina N, Garí E, Gallego C, and Aldea M

Subjects
Adenosine Triphosphatases genetics, Adenosine Triphosphatases metabolism, Amino Acid Sequence, Cell Cycle, Cell Nucleus metabolism, Cyclins chemistry, Cyclins genetics, Endoplasmic Reticulum metabolism, G1 Phase, HSP40 Heat-Shock Proteins genetics, HSP70 Heat-Shock Proteins genetics, HSP70 Heat-Shock Proteins metabolism, Models, Molecular, Molecular Sequence Data, Ploidies, Protein Structure, Tertiary, Saccharomyces cerevisiae cytology, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins chemistry, Saccharomyces cerevisiae Proteins genetics, Sequence Homology, Amino Acid, Cyclins metabolism, HSP40 Heat-Shock Proteins metabolism, Saccharomyces cerevisiae Proteins metabolism
Abstract

G1 cyclin Cln3 plays a key role in linking cell growth and proliferation in budding yeast. It is generally assumed that Cln3, which is present throughout G1, accumulates passively in the nucleus until a threshold is reached to trigger cell cycle entry. We show here that Cln3 is retained bound to the ER in early G1 cells. ER retention requires binding of Cln3 to the cyclin-dependent kinase Cdc28, a fraction of which also associates to the ER. Cln3 contains a chaperone-regulatory Ji domain that counteracts Ydj1, a J chaperone essential for ER release and nuclear accumulation of Cln3 in late G1. Finally, Ydj1 is limiting for release of Cln3 and timely entry into the cell cycle. As protein synthesis and ribosome assembly rates compromise chaperone availability, we hypothesize that Ydj1 transmits growth capacity information to the cell cycle for setting efficient size/ploidy ratios.

Published
2007
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26. TOR regulates the subcellular localization of Ime1, a transcriptional activator of meiotic development in budding yeast.

Author

Colomina N, Liu Y, Aldea M, and Garí E

Subjects
Antibiotics, Antineoplastic pharmacology, Blotting, Northern, Blotting, Western, Carbon chemistry, Cell Division, Cell Nucleus metabolism, Cyclin G, Cyclins metabolism, Cytoplasm metabolism, Flow Cytometry, Glutamine chemistry, Glutamine metabolism, Microscopy, Fluorescence, Models, Biological, Nitrogen chemistry, Plasmids metabolism, Promoter Regions, Genetic, Quaternary Ammonium Compounds pharmacology, Signal Transduction, Sirolimus pharmacology, Time Factors, Meiosis, Nuclear Proteins biosynthesis, Nuclear Proteins physiology, Saccharomyces cerevisiae Proteins biosynthesis, Saccharomyces cerevisiae Proteins physiology, Saccharomycetales metabolism, Transcription Factors biosynthesis, Transcription Factors physiology, Transcriptional Activation
Abstract

The transcriptional activator Ime1 is a key regulator of meiosis and sporulation in budding yeast. Ime1 is controlled at different levels by nutrients and cell-type signals. Previously, we have proposed that G(1) cyclins would transmit nutritional signals to the Ime1 pathway by preventing the accumulation of Ime1 within the nucleus. We show here that nutritional signals regulate the subcellular localization of Ime1 through the TOR pathway. The inactivation of TOR with rapamycin promotes the nuclear accumulation and stabilization of Ime1, with consequent induction of early meiotic genes. On the contrary, the activation of TOR by glutamine induces the relocalization of Ime1 to the cytoplasm. Thus, TOR may sense optimal nitrogen- and carbon-limiting conditions to modulate Ime1 function. Besides TOR, ammonia induces an independent mechanism that prevents the accumulation of Ime1 in the nucleus. Both TOR and ammonia regulate Ime1 localization in the absence of Cdk1 activity and therefore use mechanisms different from those exerted by G(1) cyclins. Integration of independent mechanisms into a single early controlling step, such as the nuclear accumulation of Ime1, may help explain why yeast cells execute the meiotic program only when the appropriate internal and external conditions are met together.

Published
2003
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27. The Cln3 cyclin is down-regulated by translational repression and degradation during the G1 arrest caused by nitrogen deprivation in budding yeast.

Author

Gallego C, Garí E, Colomina N, Herrero E, and Aldea M

Subjects
Gene Expression Regulation, Fungal, Saccharomyces cerevisiae, Transcription Factors biosynthesis, Cyclins biosynthesis, Down-Regulation, Fungal Proteins biosynthesis, G1 Phase physiology, Nitrogen deficiency, Protein Biosynthesis, Saccharomyces cerevisiae Proteins
Abstract

Nutrients are among the most important trophic factors in all organisms. When deprived of essential nutrients, yeast cells use accumulated reserves to complete the current cycle and arrest in the following G1 phase. We show here that the Cln3 cyclin, which has a key role in the timely activation of SBF (Swi4-Swi6)- and MBF (Mbp1-Swi6)-dependent promoters in late G1, is down-regulated rapidly at a post-transcriptional level in cells deprived of the nitrogen source. In addition to the fact that Cln3 is degraded faster by ubiquitin-dependent mechanisms, we have found that translation of the CLN3 mRNA is repressed approximately 8-fold under nitrogen deprivation conditions. As a consequence, both SBF- and MBF-dependent expression is strongly down-regulated. Mainly because of their transcriptional dependence on SBF, and perhaps with the contribution of similar post-transcriptional mechanisms to those found for Cln3, the G1 cyclins Cln1 and 2 become undetectable in starved cells. The complete loss of Cln cyclins and the sustained presence of the Clb-cyclin kinase inhibitor Sic1 in starved cells may provide the molecular basis for the G1 arrest caused by nitrogen deprivation.

Published
1997
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