Your search keyword '"Mortuza, Gulnahar B"' showing total 12 results

1. Molecular Basis of the Mechanisms Controlling MASTL

Author

Hermida, Dario, Mortuza, Gulnahar B., Pedersen, Anna-Kathrine, Pozdnyakova, Irina, Nguyen, Tam T. T. N., Maroto, Maria, Williamson, Michael, Ebersole, Tasja, Cazzamali, Giuseppe, Rand, Kasper, Olsen, Jesper, V, Malumbres, Marcos, Montoya, Guillermo, Hermida, Dario, Mortuza, Gulnahar B., Pedersen, Anna-Kathrine, Pozdnyakova, Irina, Nguyen, Tam T. T. N., Maroto, Maria, Williamson, Michael, Ebersole, Tasja, Cazzamali, Giuseppe, Rand, Kasper, Olsen, Jesper, V, Malumbres, Marcos, and Montoya, Guillermo

Published

2020

2. Molecular basis of Tousled-Like Kinase 2 activation

Author

Mortuza, Gulnahar B., Hermida, Dario, Pedersen, Anna-Kathrine, Segura-Bayona, Sandra, López-Méndez, Blanca, Redondo, Pilar, Rüther, Patrick, Pozdnyakova, Irina, Garrote, Ana M, Muñoz, Inés G, Villamor-Payà, Marina, Jauset, Cristina, Olsen, Jesper V., Stracker, Travis H., Montoya, Guillermo, Mortuza, Gulnahar B., Hermida, Dario, Pedersen, Anna-Kathrine, Segura-Bayona, Sandra, López-Méndez, Blanca, Redondo, Pilar, Rüther, Patrick, Pozdnyakova, Irina, Garrote, Ana M, Muñoz, Inés G, Villamor-Payà, Marina, Jauset, Cristina, Olsen, Jesper V., Stracker, Travis H., and Montoya, Guillermo

Abstract

Tousled-like kinases (TLKs) are required for genome stability and normal development in numerous organisms and have been implicated in breast cancer and intellectual disability. In humans, the similar TLK1 and TLK2 interact with each other and TLK activity enhances ASF1 histone binding and is inhibited by the DNA damage response, although the molecular mechanisms of TLK regulation remain unclear. Here we describe the crystal structure of the TLK2 kinase domain. We show that the coiled-coil domains mediate dimerization and are essential for activation through ordered autophosphorylation that promotes higher order oligomers that locally increase TLK2 activity. We show that TLK2 mutations involved in intellectual disability impair kinase activity, and the docking of several small-molecule inhibitors of TLK activity suggest that the crystal structure will be useful for guiding the rationale design of new inhibition strategies. Together our results provide insights into the structure and molecular regulation of the TLKs.

Published

2018

3. Molecular basis of Tousled-Like Kinase 2 activation

Author

Mortuza, Gulnahar B., Hermida, Dario, Pedersen, Anna-Kathrine, Segura-Bayona, Sandra, López-Méndez, Blanca, Redondo, Pilar, Rüther, Patrick, Pozdnyakova, Irina, Garrote, Ana M, Muñoz, Inés G, Villamor-Payà, Marina, Jauset, Cristina, Olsen, Jesper V., Stracker, Travis H., Montoya, Guillermo, Mortuza, Gulnahar B., Hermida, Dario, Pedersen, Anna-Kathrine, Segura-Bayona, Sandra, López-Méndez, Blanca, Redondo, Pilar, Rüther, Patrick, Pozdnyakova, Irina, Garrote, Ana M, Muñoz, Inés G, Villamor-Payà, Marina, Jauset, Cristina, Olsen, Jesper V., Stracker, Travis H., and Montoya, Guillermo

Abstract

Tousled-like kinases (TLKs) are required for genome stability and normal development in numerous organisms and have been implicated in breast cancer and intellectual disability. In humans, the similar TLK1 and TLK2 interact with each other and TLK activity enhances ASF1 histone binding and is inhibited by the DNA damage response, although the molecular mechanisms of TLK regulation remain unclear. Here we describe the crystal structure of the TLK2 kinase domain. We show that the coiled-coil domains mediate dimerization and are essential for activation through ordered autophosphorylation that promotes higher order oligomers that locally increase TLK2 activity. We show that TLK2 mutations involved in intellectual disability impair kinase activity, and the docking of several small-molecule inhibitors of TLK activity suggest that the crystal structure will be useful for guiding the rationale design of new inhibition strategies. Together our results provide insights into the structure and molecular regulation of the TLKs.

Published

2018

4. Electron Microscopy Structural Insights into CPAP Oligomeric Behavior:A Plausible Assembly Process of a Supramolecular Scaffold of the Centrosome

Author

Alvarez-Cabrera, Ana L, Delgado, Sandra, Gil-Carton, David, Mortuza, Gulnahar B, Montoya, Guillermo, Sorzano, Carlos O S, Tang, Tang K, Carazo, Jose M, Alvarez-Cabrera, Ana L, Delgado, Sandra, Gil-Carton, David, Mortuza, Gulnahar B, Montoya, Guillermo, Sorzano, Carlos O S, Tang, Tang K, and Carazo, Jose M

Abstract

Centrosomal P4.1-associated protein (CPAP) is a cell cycle regulated protein fundamental for centrosome assembly and centriole elongation. In humans, the region between residues 897-1338 of CPAP mediates interactions with other proteins and includes a homodimerization domain. CPAP mutations cause primary autosomal recessive microcephaly and Seckel syndrome. Despite of the biological/clinical relevance of CPAP, its mechanistic behavior remains unclear and its C-terminus (the G-box/TCP domain) is the only part whose structure has been solved. This situation is perhaps due in part to the challenges that represent obtaining the protein in a soluble, homogeneous state for structural studies. Our work constitutes a systematic structural analysis on multiple oligomers of HsCPAP(897)(-1338), using single-particle electron microscopy (EM) of negatively stained (NS) samples. Based on image classification into clearly different regular 3D maps (putatively corresponding to dimers and tetramers) and direct observation of individual images representing other complexes of HsCPAP(897-1338) (i.e., putative flexible monomers and higher-order multimers), we report a dynamic oligomeric behavior of this protein, where different homo-oligomers coexist in variable proportions. We propose that dimerization of the putative homodimer forms a putative tetramer which could be the structural unit for the scaffold that either tethers the pericentriolar material to centrioles or promotes procentriole elongation. A coarse fitting of atomic models into the NS 3D maps at resolutions around 20 Å is performed only to complement our experimental data, allowing us to hypothesize on the oligomeric composition of the different complexes. In this way, the current EM work represents an initial step toward the structural characterization of different oligomers of CPAP, suggesting further insights to understand how this protein works, contributing to the elucidation of control mechanisms for centriole biog

Published

2017

5. Electron Microscopy Structural Insights into CPAP Oligomeric Behavior: A Plausible Assembly Process of a Supramolecular Scaffold of the Centrosome

Author

Comunidad de Madrid, Ministerio de Economía y Competitividad (España), Álvarez Cabrera, Ana L., Delgado, Sandra, Gil Carton, David, Mortuza, Gulnahar B., Montoya, Guillermo, Sorzano, Carlos Óscar S., Tang, Tang K., Carazo, José M., Comunidad de Madrid, Ministerio de Economía y Competitividad (España), Álvarez Cabrera, Ana L., Delgado, Sandra, Gil Carton, David, Mortuza, Gulnahar B., Montoya, Guillermo, Sorzano, Carlos Óscar S., Tang, Tang K., and Carazo, José M.

Abstract

Centrosomal P4.1-associated protein (CPAP) is a cell cycle regulated protein fundamental for centrosome assembly and centriole elongation. In humans, the region between residues 897–1338 of CPAP mediates interactions with other proteins and includes a homodimerization domain. CPAP mutations cause primary autosomal recessive microcephaly and Seckel syndrome. Despite of the biological/clinical relevance of CPAP, its mechanistic behavior remains unclear and its C-terminus (the G-box/TCP domain) is the only part whose structure has been solved. This situation is perhaps due in part to the challenges that represent obtaining the protein in a soluble, homogeneous state for structural studies. Our work constitutes a systematic structural analysis on multiple oligomers of HsCPAP897−1338, using single-particle electron microscopy (EM) of negatively stained (NS) samples. Based on image classification into clearly different regular 3D maps (putatively corresponding to dimers and tetramers) and direct observation of individual images representing other complexes of HsCPAP897−1338 (i.e., putative flexible monomers and higher-order multimers), we report a dynamic oligomeric behavior of this protein, where different homo-oligomers coexist in variable proportions. We propose that dimerization of the putative homodimer forms a putative tetramer which could be the structural unit for the scaffold that either tethers the pericentriolar material to centrioles or promotes procentriole elongation. A coarse fitting of atomic models into the NS 3D maps at resolutions around 20 Å is performed only to complement our experimental data, allowing us to hypothesize on the oligomeric composition of the different complexes. In this way, the current EM work represents an initial step toward the structural characterization of different oligomers of CPAP, suggesting further insights to understand how this protein works, contributing to the elucidation of control mechanisms for centriole biogenesis.

Published

2017

6. Electron Microscopy Structural Insights into CPAP Oligomeric Behavior:A Plausible Assembly Process of a Supramolecular Scaffold of the Centrosome

Author

Alvarez-Cabrera, Ana L, Delgado, Sandra, Gil-Carton, David, Mortuza, Gulnahar B, Montoya, Guillermo, Sorzano, Carlos O S, Tang, Tang K, Carazo, Jose M, Alvarez-Cabrera, Ana L, Delgado, Sandra, Gil-Carton, David, Mortuza, Gulnahar B, Montoya, Guillermo, Sorzano, Carlos O S, Tang, Tang K, and Carazo, Jose M

Abstract

Centrosomal P4.1-associated protein (CPAP) is a cell cycle regulated protein fundamental for centrosome assembly and centriole elongation. In humans, the region between residues 897-1338 of CPAP mediates interactions with other proteins and includes a homodimerization domain. CPAP mutations cause primary autosomal recessive microcephaly and Seckel syndrome. Despite of the biological/clinical relevance of CPAP, its mechanistic behavior remains unclear and its C-terminus (the G-box/TCP domain) is the only part whose structure has been solved. This situation is perhaps due in part to the challenges that represent obtaining the protein in a soluble, homogeneous state for structural studies. Our work constitutes a systematic structural analysis on multiple oligomers of HsCPAP(897)(-1338), using single-particle electron microscopy (EM) of negatively stained (NS) samples. Based on image classification into clearly different regular 3D maps (putatively corresponding to dimers and tetramers) and direct observation of individual images representing other complexes of HsCPAP(897-1338) (i.e., putative flexible monomers and higher-order multimers), we report a dynamic oligomeric behavior of this protein, where different homo-oligomers coexist in variable proportions. We propose that dimerization of the putative homodimer forms a putative tetramer which could be the structural unit for the scaffold that either tethers the pericentriolar material to centrioles or promotes procentriole elongation. A coarse fitting of atomic models into the NS 3D maps at resolutions around 20 Å is performed only to complement our experimental data, allowing us to hypothesize on the oligomeric composition of the different complexes. In this way, the current EM work represents an initial step toward the structural characterization of different oligomers of CPAP, suggesting further insights to understand how this protein works, contributing to the elucidation of control mechanisms for centriole biog

Published

2017

7. TRAIP is a PCNA-binding ubiquitin ligase that protects genome stability after replication stress

Author

Hoffmann, Saskia, Smedegaard, Stine, Nakamura, Kyosuke, Mortuza, Gulnahar B, Räschle, Markus, Ibañez de Opakua, Alain, Oka, Yasuyoshi, Feng, Yunpeng, Blanco, Francisco J, Mann, Matthias, Montoya, Guillermo, Groth, Anja, Bekker-Jensen, Simon, Mailand, Niels, Hoffmann, Saskia, Smedegaard, Stine, Nakamura, Kyosuke, Mortuza, Gulnahar B, Räschle, Markus, Ibañez de Opakua, Alain, Oka, Yasuyoshi, Feng, Yunpeng, Blanco, Francisco J, Mann, Matthias, Montoya, Guillermo, Groth, Anja, Bekker-Jensen, Simon, and Mailand, Niels

Abstract

Cellular genomes are highly vulnerable to perturbations to chromosomal DNA replication. Proliferating cell nuclear antigen (PCNA), the processivity factor for DNA replication, plays a central role as a platform for recruitment of genome surveillance and DNA repair factors to replication forks, allowing cells to mitigate the threats to genome stability posed by replication stress. We identify the E3 ubiquitin ligase TRAIP as a new factor at active and stressed replication forks that directly interacts with PCNA via a conserved PCNA-interacting peptide (PIP) box motif. We show that TRAIP promotes ATR-dependent checkpoint signaling in human cells by facilitating the generation of RPA-bound single-stranded DNA regions upon replication stress in a manner that critically requires its E3 ligase activity and is potentiated by the PIP box. Consequently, loss of TRAIP function leads to enhanced chromosomal instability and decreased cell survival after replication stress. These findings establish TRAIP as a PCNA-binding ubiquitin ligase with an important role in protecting genome integrity after obstacles to DNA replication.

Published

2016

8. TRAIP is a PCNA-binding ubiquitin ligase that protects genome stability after replication stress

Author

Hoffmann, Saskia, Smedegaard, Stine, Nakamura, Kyosuke, Mortuza, Gulnahar B, Räschle, Markus, Ibañez de Opakua, Alain, Oka, Yasuyoshi, Feng, Yunpeng, Blanco, Francisco J, Mann, Matthias, Montoya, Guillermo, Groth, Anja, Bekker-Jensen, Simon, Mailand, Niels, Hoffmann, Saskia, Smedegaard, Stine, Nakamura, Kyosuke, Mortuza, Gulnahar B, Räschle, Markus, Ibañez de Opakua, Alain, Oka, Yasuyoshi, Feng, Yunpeng, Blanco, Francisco J, Mann, Matthias, Montoya, Guillermo, Groth, Anja, Bekker-Jensen, Simon, and Mailand, Niels

Abstract

Cellular genomes are highly vulnerable to perturbations to chromosomal DNA replication. Proliferating cell nuclear antigen (PCNA), the processivity factor for DNA replication, plays a central role as a platform for recruitment of genome surveillance and DNA repair factors to replication forks, allowing cells to mitigate the threats to genome stability posed by replication stress. We identify the E3 ubiquitin ligase TRAIP as a new factor at active and stressed replication forks that directly interacts with PCNA via a conserved PCNA-interacting peptide (PIP) box motif. We show that TRAIP promotes ATR-dependent checkpoint signaling in human cells by facilitating the generation of RPA-bound single-stranded DNA regions upon replication stress in a manner that critically requires its E3 ligase activity and is potentiated by the PIP box. Consequently, loss of TRAIP function leads to enhanced chromosomal instability and decreased cell survival after replication stress. These findings establish TRAIP as a PCNA-binding ubiquitin ligase with an important role in protecting genome integrity after obstacles to DNA replication.

Published

2016

9. Structure of p15PAF-PCNA complex and implications for clamp sliding during DNA replication and repair

Author

De Biasio, Alfredo, de Opakua, Alain Ibáñez, Mortuza, Gulnahar B, Molina, Rafael, Cordeiro, Tiago N, Castillo, Francisco, Villate, Maider, Merino, Nekane, Delgado, Sandra, Gil-Cartón, David, Luque, Irene, Diercks, Tammo, Bernadó, Pau, Montoya, Guillermo, Blanco, Francisco J, De Biasio, Alfredo, de Opakua, Alain Ibáñez, Mortuza, Gulnahar B, Molina, Rafael, Cordeiro, Tiago N, Castillo, Francisco, Villate, Maider, Merino, Nekane, Delgado, Sandra, Gil-Cartón, David, Luque, Irene, Diercks, Tammo, Bernadó, Pau, Montoya, Guillermo, and Blanco, Francisco J

Abstract

The intrinsically disordered protein p15(PAF) regulates DNA replication and repair by binding to the proliferating cell nuclear antigen (PCNA) sliding clamp. We present the structure of the human p15(PAF)-PCNA complex. Crystallography and NMR show the central PCNA-interacting protein motif (PIP-box) of p15(PAF) tightly bound to the front-face of PCNA. In contrast to other PCNA-interacting proteins, p15(PAF) also contacts the inside of, and passes through, the PCNA ring. The disordered p15(PAF) termini emerge at opposite faces of the ring, but remain protected from 20S proteasomal degradation. Both free and PCNA-bound p15(PAF) binds DNA mainly through its histone-like N-terminal tail, while PCNA does not, and a model of the ternary complex with DNA inside the PCNA ring is consistent with electron micrographs. We propose that p15(PAF) acts as a flexible drag that regulates PCNA sliding along the DNA and facilitates the switch from replicative to translesion synthesis polymerase binding.

Published

2015

10. XTACC3-XMAP215 association reveals an asymmetric interaction promoting microtubule elongation

Author

Mortuza, Gulnahar B, Cavazza, Tommaso, Garcia-Mayoral, Maria Flor, Hermida, Dario, Peset, Isabel, Pedrero, Juan G, Merino, Nekane, Blanco, Francisco J, Lyngsø, Jeppe, Bruix, Marta, Pedersen, Jan Skov, Vernos, Isabelle, Montoya, Guillermo, Mortuza, Gulnahar B, Cavazza, Tommaso, Garcia-Mayoral, Maria Flor, Hermida, Dario, Peset, Isabel, Pedrero, Juan G, Merino, Nekane, Blanco, Francisco J, Lyngsø, Jeppe, Bruix, Marta, Pedersen, Jan Skov, Vernos, Isabelle, and Montoya, Guillermo

Abstract

chTOG is a conserved microtubule polymerase that catalyses the addition of tubulin dimers to promote microtubule growth. chTOG interacts with TACC3, a member of the transforming acidic coiled-coil (TACC) family. Here we analyse their association using the Xenopus homologues, XTACC3 (TACC3) and XMAP215 (chTOG), dissecting the mechanism by which their interaction promotes microtubule elongation during spindle assembly. Using SAXS, we show that the TACC domain (TD) is an elongated structure that mediates the interaction with the C terminus of XMAP215. Our data suggest that one TD and two XMAP215 molecules associate to form a four-helix coiled-coil complex. A hybrid methods approach was used to define the precise regions of the TACC heptad repeat and the XMAP215 C terminus required for assembly and functioning of the complex. We show that XTACC3 can induce the recruitment of larger amounts of XMAP215 by increasing its local concentration, thereby promoting efficient microtubule elongation during mitosis.

Published

2014

11. XTACC3-XMAP215 association reveals an asymmetric interaction promoting microtubule elongation.

Author

Mortuza, Gulnahar B., Cavazza, T, García-Mayoral, M.F., Hermida, D., Peset, I., Pedrero, J.G., Merino, N., Blanco, F.J., Lyngsø, J, Bruix, M., Pedersen, J.S., Vernos, I., Montoya, G., Mortuza, Gulnahar B., Cavazza, T, García-Mayoral, M.F., Hermida, D., Peset, I., Pedrero, J.G., Merino, N., Blanco, F.J., Lyngsø, J, Bruix, M., Pedersen, J.S., Vernos, I., and Montoya, G.

Published

2014

12. XTACC3-XMAP215 association reveals an asymmetric interaction promoting microtubule elongation

Author

Mortuza, Gulnahar B, Cavazza, Tommaso, Garcia-Mayoral, Maria Flor, Hermida, Dario, Peset, Isabel, Pedrero, Juan G, Merino, Nekane, Blanco, Francisco J, Lyngsø, Jeppe, Bruix, Marta, Pedersen, Jan Skov, Vernos, Isabelle, Montoya, Guillermo, Mortuza, Gulnahar B, Cavazza, Tommaso, Garcia-Mayoral, Maria Flor, Hermida, Dario, Peset, Isabel, Pedrero, Juan G, Merino, Nekane, Blanco, Francisco J, Lyngsø, Jeppe, Bruix, Marta, Pedersen, Jan Skov, Vernos, Isabelle, and Montoya, Guillermo

Abstract

chTOG is a conserved microtubule polymerase that catalyses the addition of tubulin dimers to promote microtubule growth. chTOG interacts with TACC3, a member of the transforming acidic coiled-coil (TACC) family. Here we analyse their association using the Xenopus homologues, XTACC3 (TACC3) and XMAP215 (chTOG), dissecting the mechanism by which their interaction promotes microtubule elongation during spindle assembly. Using SAXS, we show that the TACC domain (TD) is an elongated structure that mediates the interaction with the C terminus of XMAP215. Our data suggest that one TD and two XMAP215 molecules associate to form a four-helix coiled-coil complex. A hybrid methods approach was used to define the precise regions of the TACC heptad repeat and the XMAP215 C terminus required for assembly and functioning of the complex. We show that XTACC3 can induce the recruitment of larger amounts of XMAP215 by increasing its local concentration, thereby promoting efficient microtubule elongation during mitosis.

Published

2014