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Related Concept Videos

Protein Networks02:26

Protein Networks

An organism can have thousands of different proteins, and these proteins must cooperate to ensure the health of an organism. Proteins bind to other proteins and form complexes to carry out their functions. Many proteins interact with multiple other proteins creating a complex network of protein interactions.
These interactions can be represented through maps depicting protein-protein interaction networks, represented as nodes and edges. Nodes are circles that are representative of a protein,...
Protein Networks02:26

Protein Networks

An organism can have thousands of different proteins, and these proteins must cooperate to ensure the health of an organism. Proteins bind to other proteins and form complexes to carry out their functions. Many proteins interact with multiple other proteins creating a complex network of protein interactions.
These interactions can be represented through maps depicting protein-protein interaction networks, represented as nodes and edges. Nodes are circles that are representative of a protein,...
Protein-protein Interfaces02:04

Protein-protein Interfaces

Many proteins form complexes to carry out their functions, making protein-protein interactions (PPIs) essential for an organism's survival. Most PPIs are stabilized by numerous weak noncovalent chemical forces. The physical shape of the interfaces determines the way two proteins interact. Many globular proteins have closely-matching shapes on their surfaces, which form a large number of weak bonds. Additionally, many PPIs occur between two helices or between a surface cleft and a polypeptide...
Enzyme Kinetics01:19

Enzyme Kinetics

Enzymes speed up reactions by lowering the activation energy of the reactants. The speed at which the enzyme turns reactants into products is called the rate of reaction. Several factors impact the rate of reaction, including the number of available reactants. Enzyme kinetics is the study of how an enzyme changes the rate of a reaction.
Scientists typically study enzyme kinetics with a fixed amount of enzyme in the controlled environment of a test tube. When more reactant, or substrate, is...
Enzymes02:34

Enzymes

Inside living organisms, enzymes act as catalysts for many biochemical reactions involved in cellular metabolism. The role of enzymes is to reduce the activation energies of biochemical reactions by forming complexes with its substrates. The lowering of activation energies favor an increase in the rates of biochemical reactions.
Enzyme deficiencies can often translate into life-threatening diseases. For example, a genetic abnormality resulting in the deficiency of the enzyme G6PD...
Introduction to Enzyme Kinetics01:19

Introduction to Enzyme Kinetics

Enzyme kinetics studies the rates of biochemical reactions. Scientists monitor the reaction rates for a particular enzymatic reaction at various substrate concentrations. Additional trials with inhibitors or other molecules that affect the reaction rate may also be performed.
The experimenter can then plot the initial reaction rate or velocity (Vo) of a given trial against the substrate concentration ([S]) to obtain a graph of the reaction properties. For many enzymatic reactions involving a...

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Network-based function prediction and interactomics: the case for metabolic enzymes.

S C Janga1, J Javier Díaz-Mejía, G Moreno-Hagelsieb

  • 1MRC Laboratory of Molecular Biology, Hills Road, Cambridge CB20QH, United Kingdom. sarath@mrc-lmb.cam.ac.uk

Metabolic Engineering
|July 27, 2010
PubMed
Summary
This summary is machine-generated.

Determining protein function is challenging. Network-based methods, integrating diverse interactions, offer complementary insights to homology, improving functional annotation for uncharacterized proteins.

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JUMPn: A Streamlined Application for Protein Co-Expression Clustering and Network Analysis in Proteomics

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Area of Science:

  • Bioinformatics
  • Computational Biology
  • Genomics

Background:

  • High-throughput sequencing generates vast amounts of DNA data, necessitating efficient methods for protein functional annotation.
  • Traditional functional annotation relies heavily on amino-acid sequence similarity, which has limitations as homology detection reaches its maximum.
  • Homologous proteins can diverge in function, and pairwise comparisons fail to detect distant evolutionary relationships.

Purpose of the Study:

  • To review the current state of network-based approaches for protein function prediction.
  • To highlight the challenges and successes of these computational methods.
  • To emphasize the potential of network-based strategies for annotating uncharacterized proteins.

Main Methods:

  • Exploiting protein context within cellular networks for functional inference.
  • Integrating diverse types of functional interactions to enhance prediction accuracy and coverage.
  • Building upon traditional homology-based approaches with network analysis.

Main Results:

  • Network-based methods provide complementary insights to homology-driven approaches.
  • These techniques can address the 'moonlighting' phenomenon, assigning multiple functions to proteins.
  • Integration of diverse interactions boosts confidence and coverage in functional predictions.

Conclusions:

  • Network-based functional inference is crucial for understanding uncharacterized proteins in the era of big data.
  • These methods improve our understanding of protein interplay and cellular function.
  • The time is opportune to leverage network-based approaches for genomic database enrichment.