Structural Dynamics Predominantly Determine the Adaptability of Proteins to Amino Acid Deletions

Banerjee, Anupam; Bahar, İvet

doi:10.3390/ijms24098450

Cited by 1 publication

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References 69 publications

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“…Moreover, cancer and disease-related mutations tend to focus on hinge-like areas [103,104]. Therefore, ENM dynamics is a key predictor of functional impact for point mutations [105,106] as well as for insertions and deletions [107], further discussed below.…”

Section: Lowest-frequency Modes and Evolutionmentioning

confidence: 99%

Are Protein Shape-Encoded Lowest-Frequency Motions a Key Phenotype Selected by Evolution?

Orellana

2023

Applied Sciences

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At the very deepest molecular level, the mechanisms of life depend on the operation of proteins, the so-called “workhorses” of the cell. Proteins are nanoscale machines that transform energy into useful cellular work, such as ion or nutrient transport, information processing, or energy transformation. Behind every biological task, there is a nanometer-sized molecule whose shape and intrinsic motions, binding, and sensing properties have been evolutionarily polished for billions of years. With the emergence of structural biology, the most crucial property of biomolecules was thought to be their 3D shape, but how this relates to function was unclear. During the past years, Elastic Network Models have revealed that protein shape, motion and function are deeply intertwined, so that each structure displays robustly shape-encoded functional movements that can be extraordinarily conserved across the tree of life. Here, we briefly review the growing literature exploring the interplay between sequence evolution, protein shape, intrinsic motions and function, and highlight examples from our research in which fundamental movements are conserved from bacteria to mammals or selected by cancer cells to modulate function.

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Section: Lowest-frequency Modes and Evolutionmentioning

confidence: 99%

Are Protein Shape-Encoded Lowest-Frequency Motions a Key Phenotype Selected by Evolution?

Orellana

2023

Applied Sciences

View full text Add to dashboard Cite

show abstract

Structural Dynamics Predominantly Determine the Adaptability of Proteins to Amino Acid Deletions

Cited by 1 publication

References 69 publications

Are Protein Shape-Encoded Lowest-Frequency Motions a Key Phenotype Selected by Evolution?

Are Protein Shape-Encoded Lowest-Frequency Motions a Key Phenotype Selected by Evolution?

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