4 research outputs found
Dynamics and Interactions of a 29 kDa Human Enzyme Studied by Solid-State NMR
Solid-state
NMR has been employed for characterization of a broad
range of biomacromolecules and supramolecular assemblies. However,
because of limitations in sensitivity and resolution, the size of
the individual monomeric units has rarely exceeded 15 kDa. As such,
enzymes, which are often more complex and comprise long peptide chains,
have not been easily accessible, even though manifold desirable information
could potentially be provided by solid-state NMR studies. Here, we
demonstrate that more than 1200 backbone and side-chain chemical shifts
can be reliably assessed from minimal sample quantities for a 29 kDa
human enzyme of the carbonic anhydrase family, giving access to its
backbone dynamics and intermolecular interactions with a small-molecule
inhibitor. The possibility of comprehensive assessment of enzymes
in this molecular-weight regime without molecular-tumbling-derived
limitations enables the study of residue-specific properties important
for their mode of action as well as for pharmacological interference
in this and many other enzymes
Unveiling the Dynamic Self-Assembly of a Recombinant Dragline-Silk-Mimicking Protein
Despite the considerable
interest in the recombinant production
of synthetic spider silk fibers that possess mechanical properties
similar to those of native spider silks, such as the cost-effectiveness,
tunability, and scalability realization, is still lacking. To address
this long-standing challenge, we have constructed an artificial spider
silk gene using Golden Gate assembly for the recombinant bacterial
production of dragline-mimicking silk, incorporating all the essential
components: the N-terminal domain, a 33-residue-long major-ampullate-spidroin-inspired
segment repeated 16 times, and the C-terminal domain (N16C). This
designed silk-like protein was successfully expressed in Escherichia coli, purified, and cast into films from
formic acid. We produced uniformly 13C–15N-labeled N16C films and employed solid-state magic-angle spinning
nuclear magnetic resonance (NMR) for characterization. Thus, we could
demonstrate that our bioengineered silk-like protein self-assembles
into a film where, when hydrated, the solvent-exposed layer of the
rigid, β-nanocrystalline polyalanine core undergoes a transition
to an α-helical structure, gaining mobility to the extent that
it fully dissolves in water and transforms into a highly dynamic random
coil. This hydration-induced behavior induces chain dynamics in the
glycine-rich amorphous soft segments on the microsecond time scale,
contributing to the elasticity of the solid material. Our findings
not only reveal the presence of structurally and dynamically distinct
segments within the film’s superstructure but also highlight
the complexity of the self-organization responsible for the exceptional
mechanical properties observed in proteins that mimic dragline silk
Rational Design of α‑Helix-Stabilized Exendin‑4 Analogues
Exendin-4 (Ex4) is a potent glucagon-like
peptide-1 receptor agonist,
a drug regulating the plasma glucose level of patients suffering from
type 2 diabetes. The molecule’s poor solubility and its readiness
to form aggregates increase the likelihood of unwanted side effects.
Therefore, we designed Ex4 analogues with improved structural characteristics
and better water solubility. Rational design was started from the
parent 20-amino acid, well-folded Trp cage (TC) miniprotein and involved
the step-by-step N-terminal elongation of the TC head, resulting in
the 39-amino acid Ex4 analogue, E19. Helical propensity coupled to
tertiary structure compactness was monitored and quantitatively analyzed
by electronic circular dichroism and nuclear magnetic resonance (NMR)
spectroscopy for the 14 peptides of different lengths. Both <sup>15</sup>N relaxation- and diffusion-ordered NMR measurements were established
to investigate the inherent mobility and self-association propensity
of Ex4 and E19. Our designed E19 molecule has the same tertiary structure
as Ex4 but is more helical than Ex4 under all studied conditions;
it is less prone to oligomerization and has preserved biological activity.
These conditions make E19 a perfect lead compound for further drug
discovery. We believe that this structural study improves our understanding
of the relationship between local molecular features and global physicochemical
properties such as water solubility and could help in the development
of more potent Ex4 analogues with improved pharmacokinetic properties
Phosphorylation as Conformational Switch from the Native to Amyloid State: Trp-Cage as a Protein Aggregation Model
The 20 residue long Trp-cage miniprotein
is an excellent model
for both computational and experimental studies of protein folding
and stability. Recently, great attention emerged to study disease-related
protein misfolding, aggregation, and amyloid formation, with the aim
of revealing their structural and thermodynamic background. Trp-cage
is sensitive to both environmental and structure-modifying effects.
It aggregates with ease upon structure destabilization, and thus it
is suitable for modeling aggregation and amyloid formation. Here,
we characterize the amyloid formation of several sequence modified
and side-chain phosphorylated Trp-cage variants. We applied NMR, circular
dichroism (CD) and Fourier transform infrared (FTIR) spectroscopies,
molecular dynamics (MD) simulations, and transmission electron microscopy
(TEM) in conjunction with thioflavin-T (ThT) fluorescence measurements
to reveal the structural consequences of side-chain phosphorylation.
We demonstrate that the native fold is destabilized upon serine phosphorylation,
and the resultant highly dynamic structures form amyloid-like ordered
aggregates with high intermolecular β-structure content. The
only exception is the D9S(P) variant, which follows an alternative
aggregation process by forming thin fibrils, presenting a CD spectrum
of PPII helix, and showing low ThT binding capability. We propose
a complex aggregation model for these Trp-cage miniproteins. This
model assumes an additional aggregated state, a collagen triple helical
form that can precede amyloid formation. The phosphorylation of a
single serine residue serves as a conformational switch, triggering
aggregation, otherwise mediated by kinases in cell. We show that Trp-cage
miniprotein is indeed a realistic model of larger globular systems
of composite folding and aggregation landscapes and helps us to understand
the fundamentals of deleterious protein aggregation and amyloid formation