Motivation: Biological networks change in response to genetic and environmental cues. Changes are reflected in the abundances of biomolecules, the composition of protein complexes and other descriptors of the biological state. Methods to infer the dynamic state of a cell would have great value for understanding how cells change over time to accomplish biological goals. Results: A new method predicts the dynamic state of protein complexes in a cell, with protein expression inferred from transcription profile time courses and protein complexes inferred by joint analysis of protein co-expression and protein–protein interaction maps. Two algorithmic advances are presented: a new method, DHAC (Dynamical Hierarchical Agglomerative Clustering), fo...
Proteins combine in various ways to execute different essential functions. Cellular processes are en...
Background: Time-course gene expression profiles are frequently used to provide insight into the cha...
Background Cells react to changing intra- and extracellular signals by dynamically modulating compl...
Most biological systems consist of several subcomponents which interact with each other. These inter...
Identification of protein complex is very important for revealing the underlying mechanism of biolog...
The identification of temporal protein complexes would make great contribution to our knowledge of t...
Despite the rapid accumulation of systems-level biological data, understanding the dynamic nature of...
Powerful new methods, such as expression profiles using cDNA arrays, have been used to monitor chang...
Dynamics of protein-protein interactions (PPIs) reveals the recondite principles of biological proce...
DoctorCells execute their functions through dynamic operations of biological networks. Dynamic netwo...
Clustering time course gene expression data allows one to explore functional co-regulation of genes ...
Abstract Background Cellular systems are highly dynamic and responsive to cues from the environment....
We address the problem of finding large-scale functional and structural relationships between genes,...
<p>Protein interaction network representation of human protein complexes containing at least one sup...
The topology of metabolic or protein-protein interaction networks has been an extensively studied su...
Proteins combine in various ways to execute different essential functions. Cellular processes are en...
Background: Time-course gene expression profiles are frequently used to provide insight into the cha...
Background Cells react to changing intra- and extracellular signals by dynamically modulating compl...
Most biological systems consist of several subcomponents which interact with each other. These inter...
Identification of protein complex is very important for revealing the underlying mechanism of biolog...
The identification of temporal protein complexes would make great contribution to our knowledge of t...
Despite the rapid accumulation of systems-level biological data, understanding the dynamic nature of...
Powerful new methods, such as expression profiles using cDNA arrays, have been used to monitor chang...
Dynamics of protein-protein interactions (PPIs) reveals the recondite principles of biological proce...
DoctorCells execute their functions through dynamic operations of biological networks. Dynamic netwo...
Clustering time course gene expression data allows one to explore functional co-regulation of genes ...
Abstract Background Cellular systems are highly dynamic and responsive to cues from the environment....
We address the problem of finding large-scale functional and structural relationships between genes,...
<p>Protein interaction network representation of human protein complexes containing at least one sup...
The topology of metabolic or protein-protein interaction networks has been an extensively studied su...
Proteins combine in various ways to execute different essential functions. Cellular processes are en...
Background: Time-course gene expression profiles are frequently used to provide insight into the cha...
Background Cells react to changing intra- and extracellular signals by dynamically modulating compl...