Your search keyword '"Bean, Daniel M."' showing total 4 results

1. DGLinker: flexible knowledge-graph prediction of disease–gene associations

Author

Barcelona Supercomputing Center, Hu, Jiajing, Lepore, Rosalba, Dobson, Richard J B, Al-Chalabi, Ammar, Bean, Daniel M., Iacoangeli, Alfredo, Barcelona Supercomputing Center, Hu, Jiajing, Lepore, Rosalba, Dobson, Richard J B, Al-Chalabi, Ammar, Bean, Daniel M., and Iacoangeli, Alfredo

Abstract

As a result of the advent of high-throughput technologies, there has been rapid progress in our understanding of the genetics underlying biological processes. However, despite such advances, the genetic landscape of human diseases has only marginally been disclosed. Exploiting the present availability of large amounts of biological and phenotypic data, we can use our current understanding of disease genetics to train machine learning models to predict novel genetic factors associated with the disease. To this end, we developed DGLinker, a webserver for the prediction of novel candidate genes for human diseases given a set of known disease genes. DGLinker has a user-friendly interface that allows non-expert users to exploit biomedical information from a wide range of biological and phenotypic databases, and/or to upload their own data, to generate a knowledge-graph and use machine learning to predict new disease-associated genes. The webserver includes tools to explore and interpret the results and generates publication-ready figures. DGLinker is available at https://dglinker.rosalind.kcl.ac.uk. The webserver is free and open to all users without the need for registration., Peer Reviewed, Postprint (published version)

Published

2021

2. Spinal motor neuron protein supersaturation patterns are associated with inclusion body formation in ALS

Author

Ciryam, Prajwal, Lambert-Smith, Isabella, Bean, Daniel M, Freer, Rosie, Cid, Fernando, Gaetano Tartaglia, Gian, Saunders, Darren N, Wilson, Mark R, Oliver, Stephen, Morimoto, Richard, Dobson, Christopher M, Vendruscolo, Michele, Favrin, Giorgio, Yerbury, Justin J, Ciryam, Prajwal, Lambert-Smith, Isabella, Bean, Daniel M, Freer, Rosie, Cid, Fernando, Gaetano Tartaglia, Gian, Saunders, Darren N, Wilson, Mark R, Oliver, Stephen, Morimoto, Richard, Dobson, Christopher M, Vendruscolo, Michele, Favrin, Giorgio, and Yerbury, Justin J

Abstract

Amyotrophic lateral sclerosis (ALS) is a heterogeneous degenerative motor neuron disease linked to numerous genetic mutations in apparently unrelated proteins. These proteins, including SOD1, TDP-43, and FUS, are highly aggregation-prone and form a variety of intracellular inclusion bodies that are characteristic of different neuropathological subtypes of the disease. Contained within these inclusions are a variety of proteins that do not share obvious characteristics other than coaggregation. However, recent evidence from other neurodegenerative disorders suggests that disease-affected biochemical pathways can be characterized by the presence of proteins that are supersaturated, with cellular concentrations significantly greater than their solubilities. Here, we show that the proteins that form inclusions of mutant SOD1, TDP-43, and FUS are not merely a subset of the native interaction partners of these three proteins, which are themselves supersaturated. To explain the presence of coaggregating proteins in inclusions in the brain and spinal cord, we observe that they have an average supersaturation even greater than the average supersaturation of the native interaction partners in motor neurons, but not when scores are generated from an average of other human tissues. These results suggest that inclusion bodies in various forms of ALS result from a set of proteins that are metastable in motor neurons, and thus prone to aggregation upon a disease-related progressive collapse of protein homeostasis in this specific setting.

Published

2017

3. Spinal motor neuron protein supersaturation patterns are associated with inclusion body formation in ALS

Author

Ciryam, Prajwal, Lambert-Smith, Isabella, Bean, Daniel M, Freer, Rosie, Cid, Fernando, Gaetano Tartaglia, Gian, Saunders, Darren N, Wilson, Mark R, Oliver, Stephen, Morimoto, Richard, Dobson, Christopher M, Vendruscolo, Michele, Favrin, Giorgio, Yerbury, Justin J, Ciryam, Prajwal, Lambert-Smith, Isabella, Bean, Daniel M, Freer, Rosie, Cid, Fernando, Gaetano Tartaglia, Gian, Saunders, Darren N, Wilson, Mark R, Oliver, Stephen, Morimoto, Richard, Dobson, Christopher M, Vendruscolo, Michele, Favrin, Giorgio, and Yerbury, Justin J

Abstract

Amyotrophic lateral sclerosis (ALS) is a heterogeneous degenerative motor neuron disease linked to numerous genetic mutations in apparently unrelated proteins. These proteins, including SOD1, TDP-43, and FUS, are highly aggregation-prone and form a variety of intracellular inclusion bodies that are characteristic of different neuropathological subtypes of the disease. Contained within these inclusions are a variety of proteins that do not share obvious characteristics other than coaggregation. However, recent evidence from other neurodegenerative disorders suggests that disease-affected biochemical pathways can be characterized by the presence of proteins that are supersaturated, with cellular concentrations significantly greater than their solubilities. Here, we show that the proteins that form inclusions of mutant SOD1, TDP-43, and FUS are not merely a subset of the native interaction partners of these three proteins, which are themselves supersaturated. To explain the presence of coaggregating proteins in inclusions in the brain and spinal cord, we observe that they have an average supersaturation even greater than the average supersaturation of the native interaction partners in motor neurons, but not when scores are generated from an average of other human tissues. These results suggest that inclusion bodies in various forms of ALS result from a set of proteins that are metastable in motor neurons, and thus prone to aggregation upon a disease-related progressive collapse of protein homeostasis in this specific setting.

Published

2017

4. Spinal motor neuron protein supersaturation patterns are associated with inclusion body formation in ALS

Author

Ciryam, Prajwal, Lambert-Smith, Isabella, Bean, Daniel M, Freer, Rosie, Cid, Fernando, Gaetano Tartaglia, Gian, Saunders, Darren N, Wilson, Mark R, Oliver, Stephen, Morimoto, Richard, Dobson, Christopher M, Vendruscolo, Michele, Favrin, Giorgio, Yerbury, Justin J, Ciryam, Prajwal, Lambert-Smith, Isabella, Bean, Daniel M, Freer, Rosie, Cid, Fernando, Gaetano Tartaglia, Gian, Saunders, Darren N, Wilson, Mark R, Oliver, Stephen, Morimoto, Richard, Dobson, Christopher M, Vendruscolo, Michele, Favrin, Giorgio, and Yerbury, Justin J

Abstract

Amyotrophic lateral sclerosis (ALS) is a heterogeneous degenerative motor neuron disease linked to numerous genetic mutations in apparently unrelated proteins. These proteins, including SOD1, TDP-43, and FUS, are highly aggregation-prone and form a variety of intracellular inclusion bodies that are characteristic of different neuropathological subtypes of the disease. Contained within these inclusions are a variety of proteins that do not share obvious characteristics other than coaggregation. However, recent evidence from other neurodegenerative disorders suggests that disease-affected biochemical pathways can be characterized by the presence of proteins that are supersaturated, with cellular concentrations significantly greater than their solubilities. Here, we show that the proteins that form inclusions of mutant SOD1, TDP-43, and FUS are not merely a subset of the native interaction partners of these three proteins, which are themselves supersaturated. To explain the presence of coaggregating proteins in inclusions in the brain and spinal cord, we observe that they have an average supersaturation even greater than the average supersaturation of the native interaction partners in motor neurons, but not when scores are generated from an average of other human tissues. These results suggest that inclusion bodies in various forms of ALS result from a set of proteins that are metastable in motor neurons, and thus prone to aggregation upon a disease-related progressive collapse of protein homeostasis in this specific setting.

Published

2017