Your search keyword '"Foltman M"' showing total 13 results

1. A key role for Ctf4 in coupling the MCM2-7 helicase to DNA polymerase α within the eukaryotic replisome

Author

Gambus, A. Van Deursen, F. Polychronopoulos, D. Foltman, M. Jones, R.C. Edmondson, R.D. Calzada, A. Labib, K.

Abstract

The eukaryotic replisome is a crucial determinant of genome stability, but its structure is still poorly understood. We found previously that many regulatory proteins assemble around the MCM2-7 helicase at yeast replication forks to form the replisome progression complex (RPC), which might link MCM2-7 to other replisome components. Here, we show that the RPC associates with DNA polymerase α that primes each Okazaki fragment during lagging strand synthesis. Our data indicate that a complex of the GINS and Ctf4 components of the RPC is crucial to couple MCM2-7 to DNA polymerase α. Others have found recently that the Mrc1 subunit of RPCs binds DNA polymerase epsilon, which synthesises the leading strand at DNA replication forks. We show that cells lacking both Ctf4 and Mrc1 experience chronic activation of the DNA damage checkpoint during chromosome replication and do not complete the cell cycle. These findings indicate that coupling MCM2-7 to replicative polymerases is an important feature of the regulation of chromosome replication in eukaryotes, and highlight a key role for Ctf4 in this process. © 2009 European Molecular Biology Organization | All Rights Reserved.

Published

2009

2. Central Role of the Actomyosin Ring in Coordinating Cytokinesis Steps in Budding Yeast.

Author

Foltman M and Sanchez-Diaz A

Abstract

Eukaryotic cells must accurately transfer their genetic material and cellular components to their daughter cells. Initially, cells duplicate their chromosomes and subsequently segregate them toward the poles. The actomyosin ring, a crucial molecular machinery normally located in the middle of the cells and underneath the plasma membrane, then physically divides the cytoplasm and all components into two daughter cells, each ready to start a new cell cycle. This process, known as cytokinesis, is conserved throughout evolution. Defects in cytokinesis can lead to the generation of genetically unstable tetraploid cells, potentially initiating uncontrolled proliferation and cancer. This review focuses on the molecular mechanisms by which budding yeast cells build the actomyosin ring and the preceding steps involved in forming a scaffolding structure that supports the challenging structural changes throughout cytokinesis. Additionally, we describe how cells coordinate actomyosin ring contraction, plasma membrane ingression, and extracellular matrix deposition to successfully complete cytokinesis. Furthermore, the review discusses the regulatory roles of Cyclin-Dependent Kinase (Cdk1) and the Mitotic Exit Network (MEN) in ensuring the precise timing and execution of cytokinesis. Understanding these processes in yeast provides insights into the fundamental aspects of cell division and its implications for human health.

Published

2024

3. TOR Complex 1: Orchestrating Nutrient Signaling and Cell Cycle Progression.

Author

Foltman M and Sanchez-Diaz A

Subjects

Animals, Mechanistic Target of Rapamycin Complex 1 metabolism, Saccharomyces cerevisiae metabolism, Nutrients, Cell Cycle genetics, Mammals metabolism, Signal Transduction, Saccharomyces cerevisiae Proteins metabolism

Abstract

The highly conserved TOR signaling pathway is crucial for coordinating cellular growth with the cell cycle machinery in eukaryotes. One of the two TOR complexes in budding yeast, TORC1, integrates environmental cues and promotes cell growth. While cells grow, they need to copy their chromosomes, segregate them in mitosis, divide all their components during cytokinesis, and finally physically separate mother and daughter cells to start a new cell cycle apart from each other. To maintain cell size homeostasis and chromosome stability, it is crucial that mechanisms that control growth are connected and coordinated with the cell cycle. Successive periods of high and low TORC1 activity would participate in the adequate cell cycle progression. Here, we review the known molecular mechanisms through which TORC1 regulates the cell cycle in the budding yeast Saccharomyces cerevisiae that have been extensively used as a model organism to understand the role of its mammalian ortholog, mTORC1.

Published

2023

4. TOR complex 1 negatively regulates NDR kinase Cbk1 to control cell separation in budding yeast.

Author

Foltman M, Mendez I, Bech-Serra JJ, de la Torre C, Brace JL, Weiss EL, Lucas M, Queralt E, and Sanchez-Diaz A

Subjects

Phosphorylation, Anaphase, Cell Separation, Mechanistic Target of Rapamycin Complex 1, Saccharomycetales

Abstract

The target of rapamycin (TOR) signalling pathway plays a key role in the coordination between cellular growth and the cell cycle machinery in eukaryotes. The underlying molecular mechanisms by which TOR might regulate events after anaphase remain unknown. We show for the first time that one of the 2 TOR complexes in budding yeast, TORC1, blocks the separation of cells following cytokinesis by phosphorylation of a member of the NDR (nuclear Dbf2-related) protein-kinase family, the protein Cbk1. We observe that TORC1 alters the phosphorylation pattern of Cbk1 and we identify a residue within Cbk1 activation loop, T574, for which a phosphomimetic substitution makes Cbk1 catalytically inactive and, indeed, reproduces TORC1 control over cell separation. In addition, we identify the exocyst component Sec3 as a key substrate of Cbk1, since Sec3 activates the SNARE complex to promote membrane fusion. TORC1 activity ultimately compromises the interaction between Sec3 and a t-SNARE component. Our data indicate that TORC1 negatively regulates cell separation in budding yeast by participating in Cbk1 phosphorylation, which in turn controls the fusion of secretory vesicles transporting hydrolase at the site of division., Competing Interests: The authors have declared that no competing interests exist., (Copyright: © 2023 Foltman et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.)

Published

2023

5. PP2A-Cdc55 phosphatase regulates actomyosin ring contraction and septum formation during cytokinesis.

Author

Moyano-Rodríguez Y, Vaquero D, Vilalta-Castany O, Foltman M, Sanchez-Diaz A, and Queralt E

Subjects

Chitin Synthase metabolism, Chromosome Segregation physiology, Phosphorylation physiology, Saccharomyces cerevisiae Proteins metabolism, Saccharomycetales metabolism, Actomyosin metabolism, Cytokinesis physiology

Abstract

Eukaryotic cells divide and separate all their components after chromosome segregation by a process called cytokinesis to complete cell division. Cytokinesis is highly regulated by the recruitment of the components to the division site and through post-translational modifications such as phosphorylations. The budding yeast mitotic kinases Cdc28-Clb2, Cdc5, and Dbf2-Mob1 phosphorylate several cytokinetic proteins contributing to the regulation of cytokinesis. The PP2A-Cdc55 phosphatase regulates mitosis counteracting Cdk1- and Cdc5-dependent phosphorylation. This prompted us to propose that PP2A-Cdc55 could also be counteracting the mitotic kinases during cytokinesis. Here we show that in the absence of Cdc55, AMR contraction and the primary septum formation occur asymmetrically to one side of the bud neck supporting a role for PP2A-Cdc55 in cytokinesis regulation. In addition, by in vivo and in vitro assays, we show that PP2A-Cdc55 dephosphorylates the chitin synthase II (Chs2 in budding yeast) a component of the Ingression Progression Complexes (IPCs) involved in cytokinesis. Interestingly, the non-phosphorylable version of Chs2 rescues the asymmetric AMR contraction and the defective septa formation observed in cdc55∆ mutant cells. Therefore, timely dephosphorylation of the Chs2 by PP2A-Cdc55 is crucial for proper actomyosin ring contraction. These findings reveal a new mechanism of cytokinesis regulation by the PP2A-Cdc55 phosphatase and extend our knowledge of the involvement of multiple phosphatases during cytokinesis., (© 2022. The Author(s).)

Published

2022

6. Cell polarity protein Spa2 coordinates Chs2 incorporation at the division site in budding yeast.

Author

Foltman M, Filali-Mouncef Y, Crespo D, and Sanchez-Diaz A

Subjects

Saccharomyces cerevisiae cytology, Cell Polarity, Chitin Synthase metabolism, Cytokinesis, Cytoskeletal Proteins metabolism, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins metabolism

Abstract

Deposition of additional plasma membrane and cargoes during cytokinesis in eukaryotic cells must be coordinated with actomyosin ring contraction, plasma membrane ingression and extracellular matrix remodelling. The process by which the secretory pathway promotes specific incorporation of key factors into the cytokinetic machinery is poorly understood. Here, we show that cell polarity protein Spa2 interacts with actomyosin ring components during cytokinesis. Spa2 directly binds to cytokinetic factors Cyk3 and Hof1. The lethal effects of deleting the SPA2 gene in the absence of either Cyk3 or Hof1 can be suppressed by expression of the hypermorphic allele of the essential chitin synthase II (Chs2), a transmembrane protein transported on secretory vesicles that makes the primary septum during cytokinesis. Spa2 also interacts directly with the chitin synthase Chs2. Interestingly, artificial incorporation of Chs2 into the cytokinetic machinery allows the localisation of Spa2 at the site of division. In addition, increased Spa2 protein levels promote Chs2 incorporation at the site of division and primary septum formation. Our data indicate that Spa2 is recruited to the cleavage site to co-operate with the secretory vesicle system and particular actomyosin ring components to promote the incorporation of Chs2 into the so-called 'ingression progression complexes' during cytokinesis in budding yeast.

Published

2018

7. Studying the Role of the Mitotic Exit Network in Cytokinesis.

Author

Foltman M and Sanchez-Diaz A

Subjects

Actin Cytoskeleton metabolism, Actomyosin metabolism, Anaphase, Mitosis, Saccharomyces cerevisiae metabolism, Signal Transduction, Cell Cycle Proteins metabolism, Cyclin-Dependent Kinases metabolism, Cytokinesis, Protein Tyrosine Phosphatases metabolism, Saccharomyces cerevisiae cytology, Saccharomyces cerevisiae Proteins metabolism

Abstract

In budding yeast cells, cytokinesis is achieved by the successful division of the cytoplasm into two daughter cells, but the precise mechanisms of cell division and its regulation are still rather poorly understood. The Mitotic Exit Network (MEN) is the signaling cascade that is responsible for the release of Cdc14 phosphatase leading to the inactivation of the kinase activity associated to cyclin-dependent kinases (CDK), which drives exit from mitosis and a rapid and efficient cytokinesis. Mitotic CDK impairs the activation of MEN before anaphase, and activation of MEN in anaphase leads to the inactivation of CDK, which presents a challenge to determine the contribution that each pathway makes to the successful onset of cytokinesis. To determine CDK and MEN contribution to cytokinesis irrespectively of each other, here we present methods to induce cytokinesis after the inactivation of CDK activity in temperature sensitive mutants of the MEN pathway. An array of methods to monitor the cellular events associated with the successful cytokinesis is included.

Published

2017

8. Ingression Progression Complexes Control Extracellular Matrix Remodelling during Cytokinesis in Budding Yeast.

Author

Foltman M, Molist I, Arcones I, Sacristan C, Filali-Mouncef Y, Roncero C, and Sanchez-Diaz A

Subjects

Actomyosin metabolism, Biocatalysis, Catalytic Domain, Cell Division, Chitin biosynthesis, Models, Biological, Protein Binding, Saccharomyces cerevisiae Proteins chemistry, Saccharomyces cerevisiae Proteins metabolism, Cytokinesis, Extracellular Matrix metabolism, Saccharomycetales cytology, Saccharomycetales metabolism

Abstract

Eukaryotic cells must coordinate contraction of the actomyosin ring at the division site together with ingression of the plasma membrane and remodelling of the extracellular matrix (ECM) to support cytokinesis, but the underlying mechanisms are still poorly understood. In eukaryotes, glycosyltransferases that synthesise ECM polysaccharides are emerging as key factors during cytokinesis. The budding yeast chitin synthase Chs2 makes the primary septum, a special layer of the ECM, which is an essential process during cell division. Here we isolated a group of actomyosin ring components that form complexes together with Chs2 at the cleavage site at the end of the cell cycle, which we named 'ingression progression complexes' (IPCs). In addition to type II myosin, the IQGAP protein Iqg1 and Chs2, IPCs contain the F-BAR protein Hof1, and the cytokinesis regulators Inn1 and Cyk3. We describe the molecular mechanism by which chitin synthase is activated by direct association of the C2 domain of Inn1, and the transglutaminase-like domain of Cyk3, with the catalytic domain of Chs2. We used an experimental system to find a previously unanticipated role for the C-terminus of Inn1 in preventing the untimely activation of Chs2 at the cleavage site until Cyk3 releases the block on Chs2 activity during late mitosis. These findings support a model for the co-ordinated regulation of cell division in budding yeast, in which IPCs play a central role.

Published

2016

9. Synchronization of the Budding Yeast Saccharomyces cerevisiae.

Author

Foltman M, Molist I, and Sanchez-Diaz A

Subjects

Cell Cycle Proteins metabolism, Flow Cytometry, GTP-Binding Proteins metabolism, Hydroxyurea pharmacology, Mating Factor, Nocodazole pharmacology, Peptides metabolism, Saccharomyces cerevisiae drug effects, Cell Cycle drug effects, Saccharomyces cerevisiae physiology

Abstract

A number of model organisms have provided the basis for our understanding of the eukaryotic cell cycle. These model organisms are generally much easier to manipulate than mammalian cells and as such provide amenable tools for extensive genetic and biochemical analysis. One of the most common model organisms used to study the cell cycle is the budding yeast Saccharomyces cerevisiae. This model provides the ability to synchronise cells efficiently at different stages of the cell cycle, which in turn opens up the possibility for extensive and detailed study of mechanisms regulating the eukaryotic cell cycle. Here, we describe methods in which budding yeast cells are arrested at a particular phase of the cell cycle and then released from the block, permitting the study of molecular mechanisms that drive the progression through the cell cycle.

Published

2016

10. Studying Protein-Protein Interactions in Budding Yeast Using Co-immunoprecipitation.

Author

Foltman M and Sanchez-Diaz A

Subjects

Protein Binding, Fungal Proteins metabolism, Immunoprecipitation methods, Protein Interaction Mapping methods, Saccharomycetales metabolism

Abstract

Understanding protein-protein interactions and the architecture of protein complexes in which they work is essential to identify their biological role. Protein co-immunoprecipitation (co-IP) is an invaluable technique used in biochemistry allowing the identification of protein interactors. Here, we describe in detail an immunoaffinity purification protocol as a one-step or two-step immunoprecipitation from budding yeast Saccharomyces cerevisiae cells to subsequently detect interactions between proteins involved in the same biological process.

Published

2016

11. Eukaryotic replisome components cooperate to process histones during chromosome replication.

Author

Foltman M, Evrin C, De Piccoli G, Jones RC, Edmondson RD, Katou Y, Nakato R, Shirahige K, and Labib K

Subjects

Amino Acid Motifs, Amino Acid Sequence, Binding Sites, Chromatin metabolism, Chromosomal Proteins, Non-Histone chemistry, Chromosomal Proteins, Non-Histone genetics, DNA-Binding Proteins genetics, DNA-Binding Proteins metabolism, DNA-Directed DNA Polymerase genetics, G1 Phase, High Mobility Group Proteins genetics, High Mobility Group Proteins metabolism, Histone Chaperones metabolism, Molecular Sequence Data, Multienzyme Complexes genetics, Protein Binding, Protein Structure, Tertiary, Protein Subunits genetics, Protein Subunits metabolism, Replication Origin, Replication Protein C genetics, Replication Protein C metabolism, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins chemistry, Saccharomyces cerevisiae Proteins genetics, Transcriptional Elongation Factors genetics, Transcriptional Elongation Factors metabolism, Chromosomal Proteins, Non-Histone metabolism, Chromosomes metabolism, DNA Replication, DNA-Directed DNA Polymerase metabolism, Histones metabolism, Multienzyme Complexes metabolism, Saccharomyces cerevisiae Proteins metabolism

Abstract

DNA unwinding at eukaryotic replication forks displaces parental histones, which must be redeposited onto nascent DNA in order to preserve chromatin structure. By screening systematically for replisome components that pick up histones released from chromatin into a yeast cell extract, we found that the Mcm2 helicase subunit binds histones cooperatively with the FACT (facilitiates chromatin transcription) complex, which helps to re-establish chromatin during transcription. FACT does not associate with the Mcm2-7 helicase at replication origins during G1 phase but is subsequently incorporated into the replisome progression complex independently of histone binding and uniquely among histone chaperones. The amino terminal tail of Mcm2 binds histones via a conserved motif that is dispensable for DNA synthesis per se but helps preserve subtelomeric chromatin, retain the 2 micron minichromosome, and support growth in the absence of Ctf18-RFC. Our data indicate that the eukaryotic replication and transcription machineries use analogous assemblies of multiple chaperones to preserve chromatin integrity., (Copyright © 2013 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2013

12. Inn1 and Cyk3 regulate chitin synthase during cytokinesis in budding yeasts.

Author

Devrekanli A, Foltman M, Roncero C, Sanchez-Diaz A, and Labib K

Subjects

Alleles, Amino Acid Sequence, Biocatalysis, Cell Proliferation, Chitin Synthase chemistry, Genes, Dominant genetics, Genes, Fungal genetics, Genes, Suppressor, Molecular Sequence Data, Mutant Proteins metabolism, Mutation genetics, Protein Binding genetics, Protein Structure, Secondary, Protein Structure, Tertiary, Saccharomyces cerevisiae Proteins chemistry, Suppression, Genetic, Cell Cycle Proteins metabolism, Chitin Synthase metabolism, Cytokinesis, Microtubule-Associated Proteins metabolism, Saccharomyces cerevisiae cytology, Saccharomyces cerevisiae enzymology, Saccharomyces cerevisiae Proteins metabolism

Abstract

The chitin synthase that makes the primary septum during cell division in budding yeasts is an important therapeutic target with an unknown activation mechanism. We previously found that the C2-domain of the Saccharomyces cerevisiae Inn1 protein plays an essential but uncharacterised role at the cleavage site during cytokinesis. By combining a novel degron allele of INN1 with a point mutation in the C2-domain, we screened for mutations in other genes that suppress the resulting defect in cell division. In this way, we identified 22 dominant mutations of CHS2 (chitin synthase II) that map to two neighbouring sites in the catalytic domain. Chs2 in isolated cell membranes is normally nearly inactive (unless protease treatment is used to bypass inhibition); however, the dominant suppressor allele Chs2-V377I has enhanced activity in vitro. We show that Inn1 associates with Chs2 in yeast cell extracts. It also interacts in a yeast two-hybrid assay with the N-terminal 65% of Chs2, which contains the catalytic domain. In addition to compensating for mutations in the Inn1 C2-domain, the dominant CHS2 alleles suppress cytokinesis defects produced by the lack of the Cyk3 protein. Our data support a model in which the C2-domain of Inn1 acts in conjunction with Cyk3 to regulate the catalytic domain of Chs2 during cytokinesis. These findings suggest novel approaches for developing future drugs against important fungal pathogens.

Published

2012

13. A key role for Ctf4 in coupling the MCM2-7 helicase to DNA polymerase alpha within the eukaryotic replisome.

Author

Gambus A, van Deursen F, Polychronopoulos D, Foltman M, Jones RC, Edmondson RD, Calzada A, and Labib K

Subjects

Cell Cycle, Chromosomal Proteins, Non-Histone, DNA metabolism, Minichromosome Maintenance Complex Component 7, Protein Binding, Saccharomyces cerevisiae cytology, Saccharomyces cerevisiae genetics, Cell Cycle Proteins metabolism, DNA Polymerase I metabolism, DNA Replication, DNA-Binding Proteins metabolism, Fungal Proteins metabolism, Nuclear Proteins metabolism, Saccharomyces cerevisiae metabolism, Saccharomyces cerevisiae Proteins metabolism

Abstract

The eukaryotic replisome is a crucial determinant of genome stability, but its structure is still poorly understood. We found previously that many regulatory proteins assemble around the MCM2-7 helicase at yeast replication forks to form the replisome progression complex (RPC), which might link MCM2-7 to other replisome components. Here, we show that the RPC associates with DNA polymerase alpha that primes each Okazaki fragment during lagging strand synthesis. Our data indicate that a complex of the GINS and Ctf4 components of the RPC is crucial to couple MCM2-7 to DNA polymerase alpha. Others have found recently that the Mrc1 subunit of RPCs binds DNA polymerase epsilon, which synthesises the leading strand at DNA replication forks. We show that cells lacking both Ctf4 and Mrc1 experience chronic activation of the DNA damage checkpoint during chromosome replication and do not complete the cell cycle. These findings indicate that coupling MCM2-7 to replicative polymerases is an important feature of the regulation of chromosome replication in eukaryotes, and highlight a key role for Ctf4 in this process.

Published

2009