INVESTIGADORES
SCHULZ Erica Patricia
artículos
Título:
Sub-Nanoscale Surface Ruggedness Provides a Water-Tight Seal for Exposed Regions in Soluble Protein Structure
Autor/es:
ERICA SCHULZ; MARISA FRECHERO; GUSTAVO APPIGNANESI; ARIEL FERNÁNDEZ
Revista:
PLOS ONE
Editorial:
PUBLIC LIBRARY SCIENCE
Referencias:
Lugar: San Francisco; Año: 2010 vol. 5 p. 1 - 6
ISSN:
1932-6203
Resumen:
Soluble proteins must maintain backbone hydrogen bonds (BHBs) water-tight to ensure structural integrity. This protection
is often achieved by burying the BHBs or wrapping them through intermolecular associations. On the other hand, water has
low coordination resilience, with loss of hydrogen-bonding partnerships carrying significant thermodynamic cost. Thus, a
core problem in structural biology is whether natural design actually exploits the water coordination stiffness to seal the
backbone in regions that are exposed to the solvent. This work explores the molecular design features that make this type
of seal operative, focusing on the side-chain arrangements that shield the protein backbone. We show that an efficient
sealing is achieved by adapting the sub-nanoscale surface topography to the stringency of water coordination: an exposed
BHB may be kept dry if the local concave curvature is small enough to impede formation of the coordination shell of a
penetrating water molecule. Examination of an exhaustive database of uncomplexed proteins reveals that exposed BHBs
invariably occur within such sub-nanoscale cavities in native folds, while this level of local ruggedness is absent in other
regions. By contrast, BHB exposure in misfolded proteins occurs with larger local curvature promoting backbone hydration
and consequently, structure disruption. These findings unravel physical constraints fitting a spatially dependent least-action
for water coordination, introduce a molecular design concept, and herald the advent of water-tight peptide-based materials
with sufficient backbone exposure to remain flexible.an exposed
BHB may be kept dry if the local concave curvature is small enough to impede formation of the coordination shell of a
penetrating water molecule. Examination of an exhaustive database of uncomplexed proteins reveals that exposed BHBs
invariably occur within such sub-nanoscale cavities in native folds, while this level of local ruggedness is absent in other
regions. By contrast, BHB exposure in misfolded proteins occurs with larger local curvature promoting backbone hydration
and consequently, structure disruption. These findings unravel physical constraints fitting a spatially dependent least-action
for water coordination, introduce a molecular design concept, and herald the advent of water-tight peptide-based materials
with sufficient backbone exposure to remain flexible.. Examination of an exhaustive database of uncomplexed proteins reveals that exposed BHBs
invariably occur within such sub-nanoscale cavities in native folds, while this level of local ruggedness is absent in other
regions. By contrast, BHB exposure in misfolded proteins occurs with larger local curvature promoting backbone hydration
and consequently, structure disruption. These findings unravel physical constraints fitting a spatially dependent least-action
for water coordination, introduce a molecular design concept, and herald the advent of water-tight peptide-based materials
with sufficient backbone exposure to remain flexible.