Profile
BIOGRAPHY
Maria Cristina Aspromonte is currently Assistant Professor (RTDa) in Biochemistry (SSD BIO/10) at the Department of Biomedical Sciences of the University of Padua (Italy).
ACADEMIC POSITION
Assistant professor
since (03/2023)
DEGREES
- 2021 – PhD in Developmental Medicine and Health Planning Sciences
University of Padova – Italy - 2015 – MSc (Laura Magistrale) in General Biology
University of Sannio – Italy - 2014 – Maestrado em Biologia Celular e Molecular (“double degree” program)
Universidade de Coimbra – Portugal - 2012 – BSc (Laura Magistrale) in Biology –
University of Sannio – Italy
LANGUAGES
English
Italian
(Upper Advanced)
(Native)
Publications
2024
Journal Articles
1.
Maria Cristina Aspromonte; Maria Victoria Nugnes; Federica Quaglia; Adel Bouharoua; Silvio C.E. Tosatto; Damiano Piovesan; Vasileios Sagris; Vasilis J. Promponas; Anastasia Chasapi; Erzsébet Fichó; Galo E. Balatti; Gustavo Parisi; Martín González Buitrón; Gabor Erdos; Matyas Pajkos; Zsuzsanna Dosztányi; Laszlo Dobson; Alessio Del Conte; Damiano Clementel; Edoardo Salladini; Emanuela Leonardi; Fatemeh Kordevani; Hamidreza Ghafouri; Luiggi G. Tenorio Ku; Alexander Miguel Monzon; Carlo Ferrari; Zsófia Kálmán; Juliet F. Nilsson; Jaime Santos; Carlos Pintado-Grima; Salvador Ventura; Veronika Ács; Rita Pancsa; Mariane Goncalves Kulik; Miguel A. Andrade-Navarro; Pedro José Barbosa Pereira; Sonia Longhi; Philippe Le Mercier; Julian Bergier; Peter Tompa; Tamas Lazar
DisProt in 2024: improving function annotation of intrinsically disordered proteins Journal Article
In: Nucleic Acids Research, vol. 52, no. D1, pp. D434 – D441, 2024, ISSN: 03051048, (Cited by: 15; All Open Access, Gold Open Access).
@article{Aspromonte2024D434,
title = {DisProt in 2024: improving function annotation of intrinsically disordered proteins},
author = { Maria Cristina Aspromonte and Maria Victoria Nugnes and Federica Quaglia and Adel Bouharoua and Silvio C.E. Tosatto and Damiano Piovesan and Vasileios Sagris and Vasilis J. Promponas and Anastasia Chasapi and Erzsébet Fichó and Galo E. Balatti and Gustavo Parisi and Martín González Buitrón and Gabor Erdos and Matyas Pajkos and Zsuzsanna Dosztányi and Laszlo Dobson and Alessio Del Conte and Damiano Clementel and Edoardo Salladini and Emanuela Leonardi and Fatemeh Kordevani and Hamidreza Ghafouri and Luiggi G. Tenorio Ku and Alexander Miguel Monzon and Carlo Ferrari and Zsófia Kálmán and Juliet F. Nilsson and Jaime Santos and Carlos Pintado-Grima and Salvador Ventura and Veronika Ács and Rita Pancsa and Mariane Goncalves Kulik and Miguel A. Andrade-Navarro and Pedro José Barbosa Pereira and Sonia Longhi and Philippe Le Mercier and Julian Bergier and Peter Tompa and Tamas Lazar},
url = {https://www.scopus.com/inward/record.uri?eid=2-s2.0-85176208048&doi=10.1093%2fnar%2fgkad928&partnerID=40&md5=fc34ce08667ff42029fdb54d5142c08f},
doi = {10.1093/nar/gkad928},
issn = {03051048},
year = {2024},
date = {2024-01-01},
journal = {Nucleic Acids Research},
volume = {52},
number = {D1},
pages = {D434 – D441},
publisher = {Oxford University Press},
abstract = {DisProt (URL: https://disprot.org) is the gold standard database for intrinsically disordered proteins and regions, providing valuable information about their functions. The latest version of DisProt brings significant advancements, including a broader representation of functions and an enhanced curation process. These improvements aim to increase both the quality of annotations and their coverage at the sequence level. Higher coverage has been achieved by adopting additional evidence codes. Quality of annotations has been improved by systematically applying Minimum Information About Disorder Experiments (MIADE) principles and reporting all the details of the experimental setup that could potentially influence the structural state of a protein. The DisProt database now includes new thematic datasets and has expanded the adoption of Gene Ontology terms, resulting in an extensive functional repertoire which is automatically propagated to UniProtKB. Finally, we show that DisProt’s curated annotations strongly correlate with disorder predictions inferred from AlphaFold2 pLDDT (predicted Local Distance Difference Test) confidence scores. This comparison highlights the utility of DisProt in explaining apparent uncertainty of certain well-defined predicted structures, which often correspond to folding-upon-binding fragments. Overall, DisProt serves as a comprehensive resource, combining experimental evidence of disorder information to enhance our understanding of intrinsically disordered proteins and their functional implications. © The Author(s) 2023. Published by Oxford University Press on behalf of Nucleic Acids Research.},
note = {Cited by: 15; All Open Access, Gold Open Access},
keywords = {},
pubstate = {published},
tppubtype = {article}
}
DisProt (URL: https://disprot.org) is the gold standard database for intrinsically disordered proteins and regions, providing valuable information about their functions. The latest version of DisProt brings significant advancements, including a broader representation of functions and an enhanced curation process. These improvements aim to increase both the quality of annotations and their coverage at the sequence level. Higher coverage has been achieved by adopting additional evidence codes. Quality of annotations has been improved by systematically applying Minimum Information About Disorder Experiments (MIADE) principles and reporting all the details of the experimental setup that could potentially influence the structural state of a protein. The DisProt database now includes new thematic datasets and has expanded the adoption of Gene Ontology terms, resulting in an extensive functional repertoire which is automatically propagated to UniProtKB. Finally, we show that DisProt’s curated annotations strongly correlate with disorder predictions inferred from AlphaFold2 pLDDT (predicted Local Distance Difference Test) confidence scores. This comparison highlights the utility of DisProt in explaining apparent uncertainty of certain well-defined predicted structures, which often correspond to folding-upon-binding fragments. Overall, DisProt serves as a comprehensive resource, combining experimental evidence of disorder information to enhance our understanding of intrinsically disordered proteins and their functional implications. © The Author(s) 2023. Published by Oxford University Press on behalf of Nucleic Acids Research.
2.
Hamidreza Ghafouri; Tamas Lazar; Alessio Del Conte; Luiggi G. Tenorio Ku; Peter Tompa; Silvio C.E. Tosatto; Alexander Miguel Monzon; Maria C. Aspromonte; Pau Bernadó; Belén Chaves-Arquero; Lucia Beatriz Chemes; Damiano Clementel; Tiago N. Cordeiro; Carlos A. Elena-Real; Michael Feig; Isabella C. Felli; Carlo Ferrari; Julie D. Forman-Kay; Tiago Gomes; Frank Gondelaud; Claudiu C. Gradinaru; Tâp Ha-Duong; Teresa Head-Gordon; Pétur O. Heidarsson; Giacomo Janson; Gunnar Jeschke; Emanuela Leonardi; Zi Hao Liu; Sonia Longhi; Xamuel L. Lund; Maria J. Macias; Pau Martin-Malpartida; Davide Mercadante; Assia Mouhand; Gabor Nagy; María Victoria Nugnes; José Manuel Pérez-Cañadillas; Giulia Pesce; Roberta Pierattelli; Damiano Piovesan; Federica Quaglia; Sylvie Ricard-Blum; Paul Robustelli; Amin Sagar; Edoardo Salladini; Lucile Sénicourt; Nathalie Sibille; João M.C. Teixeira; Thomas E. Tsangaris; Mihaly Varadi
PED in 2024: improving the community deposition of structural ensembles for intrinsically disordered proteins Journal Article
In: Nucleic Acids Research, vol. 52, no. D1, pp. D536 – D544, 2024, ISSN: 03051048, (Cited by: 12; All Open Access, Gold Open Access).
@article{Ghafouri2024D536,
title = {PED in 2024: improving the community deposition of structural ensembles for intrinsically disordered proteins},
author = { Hamidreza Ghafouri and Tamas Lazar and Alessio Del Conte and Luiggi G. Tenorio Ku and Peter Tompa and Silvio C.E. Tosatto and Alexander Miguel Monzon and Maria C. Aspromonte and Pau Bernadó and Belén Chaves-Arquero and Lucia Beatriz Chemes and Damiano Clementel and Tiago N. Cordeiro and Carlos A. Elena-Real and Michael Feig and Isabella C. Felli and Carlo Ferrari and Julie D. Forman-Kay and Tiago Gomes and Frank Gondelaud and Claudiu C. Gradinaru and Tâp Ha-Duong and Teresa Head-Gordon and Pétur O. Heidarsson and Giacomo Janson and Gunnar Jeschke and Emanuela Leonardi and Zi Hao Liu and Sonia Longhi and Xamuel L. Lund and Maria J. Macias and Pau Martin-Malpartida and Davide Mercadante and Assia Mouhand and Gabor Nagy and María Victoria Nugnes and José Manuel Pérez-Cañadillas and Giulia Pesce and Roberta Pierattelli and Damiano Piovesan and Federica Quaglia and Sylvie Ricard-Blum and Paul Robustelli and Amin Sagar and Edoardo Salladini and Lucile Sénicourt and Nathalie Sibille and João M.C. Teixeira and Thomas E. Tsangaris and Mihaly Varadi},
url = {https://www.scopus.com/inward/record.uri?eid=2-s2.0-85181761325&doi=10.1093%2fnar%2fgkad947&partnerID=40&md5=0ad51562357f3e5f603d744e02f8729a},
doi = {10.1093/nar/gkad947},
issn = {03051048},
year = {2024},
date = {2024-01-01},
journal = {Nucleic Acids Research},
volume = {52},
number = {D1},
pages = {D536 – D544},
publisher = {Oxford University Press},
abstract = {The Protein Ensemble Database (PED) (URL: https://proteinensemble.org) is the primary resource for depositing structural ensembles of intrinsically disordered proteins. This updated version of PED reflects advancements in the field, denoting a continual expansion with a total of 461 entries and 538 ensembles, including those generated without explicit experimental data through novel machine learning (ML) techniques. With this significant increment in the number of ensembles, a few yet-unprecedented new entries entered the database, including those also determined or refined by electron paramagnetic resonance or circular dichroism data. In addition, PED was enriched with several new features, including a novel deposition service, improved user interface, new database cross-referencing options and integration with the 3D-Beacons network—all representing efforts to improve the FAIRness of the database. Foreseeably, PED will keep growing in size and expanding with new types of ensembles generated by accurate and fast ML-based generative models and coarse-grained simulations. Therefore, among future efforts, priority will be given to further develop the database to be compatible with ensembles modeled at a coarse-grained level. © The Author(s) 2023. Published by Oxford University Press on behalf of Nucleic Acids Research.},
note = {Cited by: 12; All Open Access, Gold Open Access},
keywords = {},
pubstate = {published},
tppubtype = {article}
}
The Protein Ensemble Database (PED) (URL: https://proteinensemble.org) is the primary resource for depositing structural ensembles of intrinsically disordered proteins. This updated version of PED reflects advancements in the field, denoting a continual expansion with a total of 461 entries and 538 ensembles, including those generated without explicit experimental data through novel machine learning (ML) techniques. With this significant increment in the number of ensembles, a few yet-unprecedented new entries entered the database, including those also determined or refined by electron paramagnetic resonance or circular dichroism data. In addition, PED was enriched with several new features, including a novel deposition service, improved user interface, new database cross-referencing options and integration with the 3D-Beacons network—all representing efforts to improve the FAIRness of the database. Foreseeably, PED will keep growing in size and expanding with new types of ensembles generated by accurate and fast ML-based generative models and coarse-grained simulations. Therefore, among future efforts, priority will be given to further develop the database to be compatible with ensembles modeled at a coarse-grained level. © The Author(s) 2023. Published by Oxford University Press on behalf of Nucleic Acids Research.
3.
Federica Quaglia; Anastasia Chasapi; Maria Victoria Nugnes; Maria Cristina Aspromonte; Emanuela Leonardi; Damiano Piovesan; Silvio C.E. Tosatto
Best practices for the manual curation of intrinsically disordered proteins in DisProt Journal Article
In: Database, vol. 2024, 2024, ISSN: 17580463, (Cited by: 1; All Open Access, Gold Open Access).
@article{Quaglia2024,
title = {Best practices for the manual curation of intrinsically disordered proteins in DisProt},
author = { Federica Quaglia and Anastasia Chasapi and Maria Victoria Nugnes and Maria Cristina Aspromonte and Emanuela Leonardi and Damiano Piovesan and Silvio C.E. Tosatto},
url = {https://www.scopus.com/inward/record.uri?eid=2-s2.0-85188297172&doi=10.1093%2fdatabase%2fbaae009&partnerID=40&md5=df4fca19479789139b3fd19bb35c817f},
doi = {10.1093/database/baae009},
issn = {17580463},
year = {2024},
date = {2024-01-01},
journal = {Database},
volume = {2024},
publisher = {Oxford University Press},
abstract = {The DisProt database is a resource containing manually curated data on experimentally validated intrinsically disordered proteins (IDPs) and intrinsically disordered regions (IDRs) from the literature. Developed in 2005, its primary goal was to collect structural and functional information into proteins that lack a fixed three-dimensional structure.Today, DisProt has evolved into a major repository that not only collects experimental data but also contributes to our understanding of the IDPs/IDRs roles in various biological processes, such as autophagy or the life cycle mechanisms in viruses or their involvement in diseases (such as cancer and neurodevelopmental disorders). DisProt offers detailed information on the structural states of IDPs/IDRs, including state transitions, interactions and their functions, all provided as curated annotations. One of the central activities of DisProt is the meticulous curation of experimental data from the literature. For this reason, to ensure that every expert and volunteer curator possesses the requisite knowledge for data evaluation, collection and integration, training courses and curation materials are available. However, biocuration guidelines concur on the importance of developing robust guidelines that not only provide critical information about data consistency but also ensure data acquisition.This guideline aims to provide both biocurators and external users with best practices for manually curating IDPs and IDRs in DisProt. It describes every step of the literature curation process and provides use cases of IDP curation within DisProt. © The Author(s) 2024. Published by Oxford University Press.},
note = {Cited by: 1; All Open Access, Gold Open Access},
keywords = {},
pubstate = {published},
tppubtype = {article}
}
The DisProt database is a resource containing manually curated data on experimentally validated intrinsically disordered proteins (IDPs) and intrinsically disordered regions (IDRs) from the literature. Developed in 2005, its primary goal was to collect structural and functional information into proteins that lack a fixed three-dimensional structure.Today, DisProt has evolved into a major repository that not only collects experimental data but also contributes to our understanding of the IDPs/IDRs roles in various biological processes, such as autophagy or the life cycle mechanisms in viruses or their involvement in diseases (such as cancer and neurodevelopmental disorders). DisProt offers detailed information on the structural states of IDPs/IDRs, including state transitions, interactions and their functions, all provided as curated annotations. One of the central activities of DisProt is the meticulous curation of experimental data from the literature. For this reason, to ensure that every expert and volunteer curator possesses the requisite knowledge for data evaluation, collection and integration, training courses and curation materials are available. However, biocuration guidelines concur on the importance of developing robust guidelines that not only provide critical information about data consistency but also ensure data acquisition.This guideline aims to provide both biocurators and external users with best practices for manually curating IDPs and IDRs in DisProt. It describes every step of the literature curation process and provides use cases of IDP curation within DisProt. © The Author(s) 2024. Published by Oxford University Press.
2023
Journal Articles
4.
Suzi A. Aleksander; James Balhoff; Seth Carbon; J. Michael Cherry; Harold J. Drabkin; Dustin Ebert; Marc Feuermann; Pascale Gaudet; Nomi L. Harris; David P. Hill; Raymond Lee; Huaiyu Mi; Sierra Moxon; Christopher J. Mungall; Anushya Muruganugan; Tremayne Mushayahama; Paul W. Sternberg; Paul D. Thomas; Kimberly Van Auken; Jolene Ramsey; Deborah A. Siegele; Rex L. Chisholm; Petra Fey; Maria Cristina Aspromonte; Maria Victoria Nugnes; Federica Quaglia; Silvio Tosatto; Michelle Giglio; Suvarna Nadendla; Giulia Antonazzo; Helen Attrill; Gil Dos Santos; Steven Marygold; Victor Strelets; Christopher J. Tabone; Jim Thurmond; Pinglei Zhou; Saadullah H. Ahmed; Praoparn Asanitthong; Diana Luna Buitrago; Meltem N. Erdol; Matthew C. Gage; Mohamed Ali Kadhum; Kan Yan Chloe Li; Miao Long; Aleksandra Michalak; Angeline Pesala; Armalya Pritazahra; Shirin C. C. Saverimuttu; Renzhi Su; Kate E. Thurlow; Ruth C Lovering; Colin Logie; Snezhana Oliferenko; Judith Blake; Karen Christie; Lori Corbani; Mary E. Dolan; Li Ni; Dmitry Sitnikov; Cynthia Smith; Alayne Cuzick; James Seager; Laurel Cooper; Justin Elser; Pankaj Jaiswal; Parul Gupta; Sushma Naithani; Manuel Lera-Ramirez; Kim Rutherford; Valerie Wood; Jeffrey L. De Pons; Melinda R. Dwinell; G. Thomas Hayman; Mary L. Kaldunski; Anne E. Kwitek; Stanley J. F. Laulederkind; Marek A. Tutaj; Mahima Vedi; Shur-Jen Wang; Peter D’Eustachio; Lucila Aimo; Kristian Axelsen; Alan Bridge; Nevila Hyka-Nouspikel; Anne Morgat; Stacia R. Engel; Kalpana Karra; Stuart R. Miyasato; Robert S. Nash; Marek S. Skrzypek; Shuai Weng; Edith D. Wong; Erika Bakker; Tanya Z. Berardini; Leonore Reiser; Andrea Auchincloss; Ghislaine Argoud-Puy; Marie-Claude Blatter; Emmanuel Boutet; Lionel Breuza; Cristina Casals-Casas; Elisabeth Coudert; Anne Estreicher; Maria Livia Famiglietti; Arnaud Gos; Nadine Gruaz-Gumowski; Chantal Hulo; Florence Jungo; Philippe Le Mercier; Damien Lieberherr; Patrick Masson; Ivo Pedruzzi; Lucille Pourcel; Sylvain Poux; Catherine Rivoire; Shyamala Sundaram; Alex Bateman; Emily Bowler-Barnett; Hema Bye-A-Jee; Paul Denny; Alexandr Ignatchenko; Rizwan Ishtiaq; Antonia Lock; Yvonne Lussi; Michele Magrane; Maria J. Martin; Sandra Orchard; Pedro Raposo; Elena Speretta; Nidhi Tyagi; Kate Warner; Rossana Zaru; Alexander D. Diehl; Juancarlos Chan; Stavros Diamantakis; Daniela Raciti; Magdalena Zarowiecki; Malcolm Fisher; Christina James-Zorn; Virgilio Ponferrada; Aaron Zorn; Sridhar Ramachandran; Leyla Ruzicka; Monte Westerfield
The Gene Ontology knowledgebase in 2023 Journal Article
In: Genetics, vol. 224, no. 1, 2023, ISSN: 00166731, (Cited by: 557; All Open Access, Hybrid Gold Open Access).
@article{Aleksander2023,
title = {The Gene Ontology knowledgebase in 2023},
author = { Suzi A. Aleksander and James Balhoff and Seth Carbon and J. Michael Cherry and Harold J. Drabkin and Dustin Ebert and Marc Feuermann and Pascale Gaudet and Nomi L. Harris and David P. Hill and Raymond Lee and Huaiyu Mi and Sierra Moxon and Christopher J. Mungall and Anushya Muruganugan and Tremayne Mushayahama and Paul W. Sternberg and Paul D. Thomas and Kimberly Van Auken and Jolene Ramsey and Deborah A. Siegele and Rex L. Chisholm and Petra Fey and Maria Cristina Aspromonte and Maria Victoria Nugnes and Federica Quaglia and Silvio Tosatto and Michelle Giglio and Suvarna Nadendla and Giulia Antonazzo and Helen Attrill and Gil Dos Santos and Steven Marygold and Victor Strelets and Christopher J. Tabone and Jim Thurmond and Pinglei Zhou and Saadullah H. Ahmed and Praoparn Asanitthong and Diana Luna Buitrago and Meltem N. Erdol and Matthew C. Gage and Mohamed Ali Kadhum and Kan Yan Chloe Li and Miao Long and Aleksandra Michalak and Angeline Pesala and Armalya Pritazahra and Shirin C. C. Saverimuttu and Renzhi Su and Kate E. Thurlow and Ruth C Lovering and Colin Logie and Snezhana Oliferenko and Judith Blake and Karen Christie and Lori Corbani and Mary E. Dolan and Li Ni and Dmitry Sitnikov and Cynthia Smith and Alayne Cuzick and James Seager and Laurel Cooper and Justin Elser and Pankaj Jaiswal and Parul Gupta and Sushma Naithani and Manuel Lera-Ramirez and Kim Rutherford and Valerie Wood and Jeffrey L. De Pons and Melinda R. Dwinell and G. Thomas Hayman and Mary L. Kaldunski and Anne E. Kwitek and Stanley J. F. Laulederkind and Marek A. Tutaj and Mahima Vedi and Shur-Jen Wang and Peter D'Eustachio and Lucila Aimo and Kristian Axelsen and Alan Bridge and Nevila Hyka-Nouspikel and Anne Morgat and Stacia R. Engel and Kalpana Karra and Stuart R. Miyasato and Robert S. Nash and Marek S. Skrzypek and Shuai Weng and Edith D. Wong and Erika Bakker and Tanya Z. Berardini and Leonore Reiser and Andrea Auchincloss and Ghislaine Argoud-Puy and Marie-Claude Blatter and Emmanuel Boutet and Lionel Breuza and Cristina Casals-Casas and Elisabeth Coudert and Anne Estreicher and Maria Livia Famiglietti and Arnaud Gos and Nadine Gruaz-Gumowski and Chantal Hulo and Florence Jungo and Philippe Le Mercier and Damien Lieberherr and Patrick Masson and Ivo Pedruzzi and Lucille Pourcel and Sylvain Poux and Catherine Rivoire and Shyamala Sundaram and Alex Bateman and Emily Bowler-Barnett and Hema Bye-A-Jee and Paul Denny and Alexandr Ignatchenko and Rizwan Ishtiaq and Antonia Lock and Yvonne Lussi and Michele Magrane and Maria J. Martin and Sandra Orchard and Pedro Raposo and Elena Speretta and Nidhi Tyagi and Kate Warner and Rossana Zaru and Alexander D. Diehl and Juancarlos Chan and Stavros Diamantakis and Daniela Raciti and Magdalena Zarowiecki and Malcolm Fisher and Christina James-Zorn and Virgilio Ponferrada and Aaron Zorn and Sridhar Ramachandran and Leyla Ruzicka and Monte Westerfield},
url = {https://www.scopus.com/inward/record.uri?eid=2-s2.0-85164785564&doi=10.1093%2fgenetics%2fiyad031&partnerID=40&md5=d315a8c84634510d971d9d805f26769d},
doi = {10.1093/genetics/iyad031},
issn = {00166731},
year = {2023},
date = {2023-01-01},
journal = {Genetics},
volume = {224},
number = {1},
publisher = {Oxford University Press},
abstract = {The Gene Ontology (GO) knowledgebase (http://geneontology.org) is a comprehensive resource concerning the functions of genes and gene products (proteins and noncoding RNAs). GO annotations cover genes from organisms across the tree of life as well as viruses, though most gene function knowledge currently derives from experiments carried out in a relatively small number of model organisms. Here, we provide an updated overview of the GO knowledgebase, as well as the efforts of the broad, international consortium of scientists that develops, maintains, and updates the GO knowledgebase. The GO knowledgebase consists of three components: (1) the GO - a computational knowledge structure describing the functional characteristics of genes; (2) GO annotations - evidence-supported statements asserting that a specific gene product has a particular functional characteristic; and (3) GO Causal Activity Models (GO-CAMs) - mechanistic models of molecular "pathways"(GO biological processes) created by linking multiple GO annotations using defined relations. Each of these components is continually expanded, revised, and updated in response to newly published discoveries and receives extensive QA checks, reviews, and user feedback. For each of these components, we provide a description of the current contents, recent developments to keep the knowledgebase up to date with new discoveries, and guidance on how users can best make use of the data that we provide. We conclude with future directions for the project. © 2023 The Author(s). Published by Oxford University Press on behalf of The Genetics Society of America.},
note = {Cited by: 557; All Open Access, Hybrid Gold Open Access},
keywords = {},
pubstate = {published},
tppubtype = {article}
}
The Gene Ontology (GO) knowledgebase (http://geneontology.org) is a comprehensive resource concerning the functions of genes and gene products (proteins and noncoding RNAs). GO annotations cover genes from organisms across the tree of life as well as viruses, though most gene function knowledge currently derives from experiments carried out in a relatively small number of model organisms. Here, we provide an updated overview of the GO knowledgebase, as well as the efforts of the broad, international consortium of scientists that develops, maintains, and updates the GO knowledgebase. The GO knowledgebase consists of three components: (1) the GO – a computational knowledge structure describing the functional characteristics of genes; (2) GO annotations – evidence-supported statements asserting that a specific gene product has a particular functional characteristic; and (3) GO Causal Activity Models (GO-CAMs) – mechanistic models of molecular “pathways”(GO biological processes) created by linking multiple GO annotations using defined relations. Each of these components is continually expanded, revised, and updated in response to newly published discoveries and receives extensive QA checks, reviews, and user feedback. For each of these components, we provide a description of the current contents, recent developments to keep the knowledgebase up to date with new discoveries, and guidance on how users can best make use of the data that we provide. We conclude with future directions for the project. © 2023 The Author(s). Published by Oxford University Press on behalf of The Genetics Society of America.
5.
Emanuela Leonardi; Maria Cristina Aspromonte; Denise Drongitis; Elisa Bettella; Lucia Verrillo; Roberta Polli; Meriel McEntagart; Laura Licchetta; Robertino Dilena; Stefano D’Arrigo; Claudia Ciaccio; Silvia Esposito; Vincenzo Leuzzi; Annalaura Torella; Demetrio Baldo; Fortunato Lonardo; Giulia Bonato; Serena Pellegrin; Franco Stanzial; Renata Posmyk; Ewa Kaczorowska; Miryam Carecchio; Monika Gos; Sylwia Rzońca-Niewczas; Maria Giuseppina Miano; Alessandra Murgia
Expanding the genetics and phenotypic spectrum of Lysine-specific demethylase 5C (KDM5C): a report of 13 novel variants Journal Article
In: European Journal of Human Genetics, vol. 31, no. 2, pp. 202 – 215, 2023, ISSN: 10184813, (Cited by: 5; All Open Access, Green Open Access).
@article{Leonardi2023202,
title = {Expanding the genetics and phenotypic spectrum of Lysine-specific demethylase 5C (KDM5C): a report of 13 novel variants},
author = { Emanuela Leonardi and Maria Cristina Aspromonte and Denise Drongitis and Elisa Bettella and Lucia Verrillo and Roberta Polli and Meriel McEntagart and Laura Licchetta and Robertino Dilena and Stefano D’Arrigo and Claudia Ciaccio and Silvia Esposito and Vincenzo Leuzzi and Annalaura Torella and Demetrio Baldo and Fortunato Lonardo and Giulia Bonato and Serena Pellegrin and Franco Stanzial and Renata Posmyk and Ewa Kaczorowska and Miryam Carecchio and Monika Gos and Sylwia Rzońca-Niewczas and Maria Giuseppina Miano and Alessandra Murgia},
url = {https://www.scopus.com/inward/record.uri?eid=2-s2.0-85142646250&doi=10.1038%2fs41431-022-01233-4&partnerID=40&md5=56692e2c9b3994a0703776134808e698},
doi = {10.1038/s41431-022-01233-4},
issn = {10184813},
year = {2023},
date = {2023-01-01},
journal = {European Journal of Human Genetics},
volume = {31},
number = {2},
pages = {202 – 215},
publisher = {Springer Nature},
abstract = {Lysine-specific demethylase 5C (KDM5C) has been identified as an important chromatin remodeling gene, contributing to X-linked neurodevelopmental disorders (NDDs). The KDM5C gene, located in the Xp22 chromosomal region, encodes the H3K4me3-me2 eraser involved in neuronal plasticity and dendritic growth. Here we report 30 individuals carrying 13 novel and one previously identified KDM5C variants. Our cohort includes the first reported case of somatic mosaicism in a male carrying a KDM5C nucleotide substitution, and a dual molecular finding in a female carrying a homozygous truncating FUCA1 alteration together with a de novo KDM5C variant. With the use of next generation sequencing strategies, we detected 1 frameshift, 1 stop codon, 2 splice-site and 10 missense variants, which pathogenic role was carefully investigated by a thorough bioinformatic analysis. The pattern of X-chromosome inactivation was found to have an impact on KDM5C phenotypic expression in females of our cohort. The affected individuals of our case series manifested a neurodevelopmental condition characterized by psychomotor delay, intellectual disability with speech disorders, and behavioral features with particular disturbed sleep pattern; other observed clinical manifestations were short stature, obesity and hypertrichosis. Collectively, these findings expand the current knowledge about the pathogenic mechanisms leading to dysfunction of this important chromatin remodeling gene and contribute to a refinement of the KDM5C phenotypic spectrum. © 2022, This is a U.S. Government work and not under copyright protection in the US; foreign copyright protection may apply.},
note = {Cited by: 5; All Open Access, Green Open Access},
keywords = {},
pubstate = {published},
tppubtype = {article}
}
Lysine-specific demethylase 5C (KDM5C) has been identified as an important chromatin remodeling gene, contributing to X-linked neurodevelopmental disorders (NDDs). The KDM5C gene, located in the Xp22 chromosomal region, encodes the H3K4me3-me2 eraser involved in neuronal plasticity and dendritic growth. Here we report 30 individuals carrying 13 novel and one previously identified KDM5C variants. Our cohort includes the first reported case of somatic mosaicism in a male carrying a KDM5C nucleotide substitution, and a dual molecular finding in a female carrying a homozygous truncating FUCA1 alteration together with a de novo KDM5C variant. With the use of next generation sequencing strategies, we detected 1 frameshift, 1 stop codon, 2 splice-site and 10 missense variants, which pathogenic role was carefully investigated by a thorough bioinformatic analysis. The pattern of X-chromosome inactivation was found to have an impact on KDM5C phenotypic expression in females of our cohort. The affected individuals of our case series manifested a neurodevelopmental condition characterized by psychomotor delay, intellectual disability with speech disorders, and behavioral features with particular disturbed sleep pattern; other observed clinical manifestations were short stature, obesity and hypertrichosis. Collectively, these findings expand the current knowledge about the pathogenic mechanisms leading to dysfunction of this important chromatin remodeling gene and contribute to a refinement of the KDM5C phenotypic spectrum. © 2022, This is a U.S. Government work and not under copyright protection in the US; foreign copyright protection may apply.