8 research outputs found
Multiscale Simulations of Self-Assembling Peptides: Surface and Core Hydrophobicity Determine Fibril Stability and Amyloid Aggregation
Assemblies of peptides
and proteins through specific
intermolecular
interactions set the basis for macroscopic materials found in nature.
Peptides provide easily tunable hydrogen-bonding interactions, which
can lead to the formation of ordered structures such as highly stable
β-sheets that can form amyloid-like supramolecular peptide nanofibrils
(PNFs). PNFs are of special interest, as they could be considered
as mimics of various fibrillar structures found in nature. In their
ability to serve as supramolecular scaffolds, they could mimic certain
features of the extracellular matrix to provide stability, interact
with pathogens such as virions, and transduce signals between the
outside and inside of cells. Many PNFs have been reported that reveal
rich bioactivities. PNFs supporting neuronal cell growth or lentiviral
gene transduction have been studied systematically, and their material
properties were correlated to bioactivities. However, the impact of
the structure of PNFs, their dynamics, and stabilities on their unique
functions is still elusive. Herein, we provide a microscopic view
of the self-assembled PNFs to unravel how the amino acid sequence
of self-assembling peptides affects their secondary structure and
dynamic properties of the peptides within supramolecular fibrils.
Based on sequence truncation, amino acid substitution, and sequence
reordering, we demonstrate that peptide–peptide aggregation
propensity is critical to form bioactive β-sheet-rich structures.
In contrast to previous studies, a very high peptide aggregation propensity
reduces bioactivity due to intermolecular misalignment and instabilities
that emerge when fibrils are in close proximity to other fibrils in
solution. Our multiscale simulation approach correlates changes in
biological activity back to single amino acid modifications. Understanding
these relationships could lead to future material discoveries where
the molecular sequence predictably determines the macroscopic properties
and biological activity. In addition, our studies may provide new
insights into naturally occurring amyloid fibrils in neurodegenerative
diseases
Multiscale Simulations of Self-Assembling Peptides: Surface and Core Hydrophobicity Determine Fibril Stability and Amyloid Aggregation
Assemblies of peptides
and proteins through specific
intermolecular
interactions set the basis for macroscopic materials found in nature.
Peptides provide easily tunable hydrogen-bonding interactions, which
can lead to the formation of ordered structures such as highly stable
β-sheets that can form amyloid-like supramolecular peptide nanofibrils
(PNFs). PNFs are of special interest, as they could be considered
as mimics of various fibrillar structures found in nature. In their
ability to serve as supramolecular scaffolds, they could mimic certain
features of the extracellular matrix to provide stability, interact
with pathogens such as virions, and transduce signals between the
outside and inside of cells. Many PNFs have been reported that reveal
rich bioactivities. PNFs supporting neuronal cell growth or lentiviral
gene transduction have been studied systematically, and their material
properties were correlated to bioactivities. However, the impact of
the structure of PNFs, their dynamics, and stabilities on their unique
functions is still elusive. Herein, we provide a microscopic view
of the self-assembled PNFs to unravel how the amino acid sequence
of self-assembling peptides affects their secondary structure and
dynamic properties of the peptides within supramolecular fibrils.
Based on sequence truncation, amino acid substitution, and sequence
reordering, we demonstrate that peptide–peptide aggregation
propensity is critical to form bioactive β-sheet-rich structures.
In contrast to previous studies, a very high peptide aggregation propensity
reduces bioactivity due to intermolecular misalignment and instabilities
that emerge when fibrils are in close proximity to other fibrils in
solution. Our multiscale simulation approach correlates changes in
biological activity back to single amino acid modifications. Understanding
these relationships could lead to future material discoveries where
the molecular sequence predictably determines the macroscopic properties
and biological activity. In addition, our studies may provide new
insights into naturally occurring amyloid fibrils in neurodegenerative
diseases
Multiscale Simulations of Self-Assembling Peptides: Surface and Core Hydrophobicity Determine Fibril Stability and Amyloid Aggregation
Assemblies of peptides
and proteins through specific
intermolecular
interactions set the basis for macroscopic materials found in nature.
Peptides provide easily tunable hydrogen-bonding interactions, which
can lead to the formation of ordered structures such as highly stable
β-sheets that can form amyloid-like supramolecular peptide nanofibrils
(PNFs). PNFs are of special interest, as they could be considered
as mimics of various fibrillar structures found in nature. In their
ability to serve as supramolecular scaffolds, they could mimic certain
features of the extracellular matrix to provide stability, interact
with pathogens such as virions, and transduce signals between the
outside and inside of cells. Many PNFs have been reported that reveal
rich bioactivities. PNFs supporting neuronal cell growth or lentiviral
gene transduction have been studied systematically, and their material
properties were correlated to bioactivities. However, the impact of
the structure of PNFs, their dynamics, and stabilities on their unique
functions is still elusive. Herein, we provide a microscopic view
of the self-assembled PNFs to unravel how the amino acid sequence
of self-assembling peptides affects their secondary structure and
dynamic properties of the peptides within supramolecular fibrils.
Based on sequence truncation, amino acid substitution, and sequence
reordering, we demonstrate that peptide–peptide aggregation
propensity is critical to form bioactive β-sheet-rich structures.
In contrast to previous studies, a very high peptide aggregation propensity
reduces bioactivity due to intermolecular misalignment and instabilities
that emerge when fibrils are in close proximity to other fibrils in
solution. Our multiscale simulation approach correlates changes in
biological activity back to single amino acid modifications. Understanding
these relationships could lead to future material discoveries where
the molecular sequence predictably determines the macroscopic properties
and biological activity. In addition, our studies may provide new
insights into naturally occurring amyloid fibrils in neurodegenerative
diseases
Highly Stable, Ultrasmall Polymer-Grafted Nanobins (usPGNs) with Stimuli-Responsive Capability
Highly
stable and stimuli/pH-responsive ultrasmall polymer-grafted
nanobins (usPGNs) have been developed by grafting a small amount (10
mol %) of short (4.3 kDa) cholesterol-terminated poly(acrylic acid)
(Chol-PAA) into an ultrasmall unilamellar vesicle (uSUV). The usPGNs
are stable against fusion and aggregation over several weeks, exhibiting
over 10-fold enhanced cargo retention in biologically relevant media
at pH 7.4 in comparison with the parent uSUV template. Coarse-grained
molecular dynamics (CGMD) simulations confirm that the presence of
the cholesterol moiety can greatly stabilize the lipid bilayer. They
also show extended PAA chain conformations that can be interpreted
as causing repulsion between colloidal particles, thus stabilizing
them against fusion. Notably, CGMD predicted a clustering of the Chol-PAA
chains on the lipid bilayer under acidic conditions due to intra-
and interchain hydrogen bonding, leading to the destabilization of
local membrane areas. This explains the experimental observation that
usPGNs can be triggered to release a significant amount of cargo upon
acidification to pH 5. These developments put the lipid-bilayer-embedded
Chol-PAA in stark contrast with traditional poly(acrylic acid) systems
where the molar mass (<i>M</i><sub>n</sub>) of the polymer
chains must exceed 16.5 kDa to achieve stimuli-responsive changes
in conformation. They also distinguish the small usPGNs from the much-larger
polymer-caged nanobin platform where the Chol-PAA chains must be covalently
cross-linked to engender stimuli-responsive behaviors
Highly Stable, Ultrasmall Polymer-Grafted Nanobins (usPGNs) with Stimuli-Responsive Capability
Highly
stable and stimuli/pH-responsive ultrasmall polymer-grafted
nanobins (usPGNs) have been developed by grafting a small amount (10
mol %) of short (4.3 kDa) cholesterol-terminated poly(acrylic acid)
(Chol-PAA) into an ultrasmall unilamellar vesicle (uSUV). The usPGNs
are stable against fusion and aggregation over several weeks, exhibiting
over 10-fold enhanced cargo retention in biologically relevant media
at pH 7.4 in comparison with the parent uSUV template. Coarse-grained
molecular dynamics (CGMD) simulations confirm that the presence of
the cholesterol moiety can greatly stabilize the lipid bilayer. They
also show extended PAA chain conformations that can be interpreted
as causing repulsion between colloidal particles, thus stabilizing
them against fusion. Notably, CGMD predicted a clustering of the Chol-PAA
chains on the lipid bilayer under acidic conditions due to intra-
and interchain hydrogen bonding, leading to the destabilization of
local membrane areas. This explains the experimental observation that
usPGNs can be triggered to release a significant amount of cargo upon
acidification to pH 5. These developments put the lipid-bilayer-embedded
Chol-PAA in stark contrast with traditional poly(acrylic acid) systems
where the molar mass (<i>M</i><sub>n</sub>) of the polymer
chains must exceed 16.5 kDa to achieve stimuli-responsive changes
in conformation. They also distinguish the small usPGNs from the much-larger
polymer-caged nanobin platform where the Chol-PAA chains must be covalently
cross-linked to engender stimuli-responsive behaviors
Highly Stable, Ultrasmall Polymer-Grafted Nanobins (usPGNs) with Stimuli-Responsive Capability
Highly
stable and stimuli/pH-responsive ultrasmall polymer-grafted
nanobins (usPGNs) have been developed by grafting a small amount (10
mol %) of short (4.3 kDa) cholesterol-terminated poly(acrylic acid)
(Chol-PAA) into an ultrasmall unilamellar vesicle (uSUV). The usPGNs
are stable against fusion and aggregation over several weeks, exhibiting
over 10-fold enhanced cargo retention in biologically relevant media
at pH 7.4 in comparison with the parent uSUV template. Coarse-grained
molecular dynamics (CGMD) simulations confirm that the presence of
the cholesterol moiety can greatly stabilize the lipid bilayer. They
also show extended PAA chain conformations that can be interpreted
as causing repulsion between colloidal particles, thus stabilizing
them against fusion. Notably, CGMD predicted a clustering of the Chol-PAA
chains on the lipid bilayer under acidic conditions due to intra-
and interchain hydrogen bonding, leading to the destabilization of
local membrane areas. This explains the experimental observation that
usPGNs can be triggered to release a significant amount of cargo upon
acidification to pH 5. These developments put the lipid-bilayer-embedded
Chol-PAA in stark contrast with traditional poly(acrylic acid) systems
where the molar mass (<i>M</i><sub>n</sub>) of the polymer
chains must exceed 16.5 kDa to achieve stimuli-responsive changes
in conformation. They also distinguish the small usPGNs from the much-larger
polymer-caged nanobin platform where the Chol-PAA chains must be covalently
cross-linked to engender stimuli-responsive behaviors
Highly Stable, Ultrasmall Polymer-Grafted Nanobins (usPGNs) with Stimuli-Responsive Capability
Highly
stable and stimuli/pH-responsive ultrasmall polymer-grafted
nanobins (usPGNs) have been developed by grafting a small amount (10
mol %) of short (4.3 kDa) cholesterol-terminated poly(acrylic acid)
(Chol-PAA) into an ultrasmall unilamellar vesicle (uSUV). The usPGNs
are stable against fusion and aggregation over several weeks, exhibiting
over 10-fold enhanced cargo retention in biologically relevant media
at pH 7.4 in comparison with the parent uSUV template. Coarse-grained
molecular dynamics (CGMD) simulations confirm that the presence of
the cholesterol moiety can greatly stabilize the lipid bilayer. They
also show extended PAA chain conformations that can be interpreted
as causing repulsion between colloidal particles, thus stabilizing
them against fusion. Notably, CGMD predicted a clustering of the Chol-PAA
chains on the lipid bilayer under acidic conditions due to intra-
and interchain hydrogen bonding, leading to the destabilization of
local membrane areas. This explains the experimental observation that
usPGNs can be triggered to release a significant amount of cargo upon
acidification to pH 5. These developments put the lipid-bilayer-embedded
Chol-PAA in stark contrast with traditional poly(acrylic acid) systems
where the molar mass (<i>M</i><sub>n</sub>) of the polymer
chains must exceed 16.5 kDa to achieve stimuli-responsive changes
in conformation. They also distinguish the small usPGNs from the much-larger
polymer-caged nanobin platform where the Chol-PAA chains must be covalently
cross-linked to engender stimuli-responsive behaviors
Highly Stable, Ultrasmall Polymer-Grafted Nanobins (usPGNs) with Stimuli-Responsive Capability
Highly
stable and stimuli/pH-responsive ultrasmall polymer-grafted
nanobins (usPGNs) have been developed by grafting a small amount (10
mol %) of short (4.3 kDa) cholesterol-terminated poly(acrylic acid)
(Chol-PAA) into an ultrasmall unilamellar vesicle (uSUV). The usPGNs
are stable against fusion and aggregation over several weeks, exhibiting
over 10-fold enhanced cargo retention in biologically relevant media
at pH 7.4 in comparison with the parent uSUV template. Coarse-grained
molecular dynamics (CGMD) simulations confirm that the presence of
the cholesterol moiety can greatly stabilize the lipid bilayer. They
also show extended PAA chain conformations that can be interpreted
as causing repulsion between colloidal particles, thus stabilizing
them against fusion. Notably, CGMD predicted a clustering of the Chol-PAA
chains on the lipid bilayer under acidic conditions due to intra-
and interchain hydrogen bonding, leading to the destabilization of
local membrane areas. This explains the experimental observation that
usPGNs can be triggered to release a significant amount of cargo upon
acidification to pH 5. These developments put the lipid-bilayer-embedded
Chol-PAA in stark contrast with traditional poly(acrylic acid) systems
where the molar mass (<i>M</i><sub>n</sub>) of the polymer
chains must exceed 16.5 kDa to achieve stimuli-responsive changes
in conformation. They also distinguish the small usPGNs from the much-larger
polymer-caged nanobin platform where the Chol-PAA chains must be covalently
cross-linked to engender stimuli-responsive behaviors