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J Biol Chem, Vol. 274, Issue 46, 32970-32974, November 12, 1999
From the Amyloid- Amyloid plaques are a central feature of Alzheimer's disease
pathology and are considered to be a major factor in neuronal cell loss
(1, 2). Ultrastructurally, plaques are fibrous masses composed
primarily of the 40-42-residue amyloid- The observation that A Peptide Synthesis and Labeling--
Amyloid- Secondary Structure Analysis--
The effects of TMAO (Sigma)
and glycerol (BDH) on A Electron and Atomic Force Microscopy--
A
For tapping mode atomic force microscopy (TMAFM) studies, the peptides
were dissolved in 25 mM phosphate buffer (pH 7) and then
adjusted to the desired TMAO or glycerol content to a final peptide
concentration of 2.5 µM. Approximately 10 µl of the
peptide solution was transferred to a piece of freshly cleaved mica
glued to a steel AFM sample mount. The sample was then immediately
sealed in the TMAFM liquid cell, and the cell was filled with buffer solution. TMAFM imaging was conducted at room temperature using a
combination contact/tapping mode liquid cell fitted to a Digital Instruments Nanoscope IIIA MultiMode scanning probe microscope. All
images were acquired using 120-µm oxide-sharpened silicon nitride
V-shaped cantilevers (type DNP-S, Digital Instruments Inc., Santa
Barbara, CA) at a scan rate of ~2 Hz and a sampling rate of 256 or
512 points/scan line. Prior to use, the AFM tips were exposed to UV
irradiation to remove adventitious organic contaminants from the tip
surface. While a priori determination of the appropriate
drive frequency is difficult owing to viscous coupling between the
cantilever and the fluid medium, which gives rise to multiple broad
resonance peaks, optimal imaging was achieved at a cantilever drive
frequency of ~8.9 kHz.
Solubility Measurements--
The aggregation state of A Circular dichroism was used to evaluate the effects of the
naturally occurring osmolyte TMAO and glycerol on A Glycerol is a nonphysiological model of osmolyte activity, and we
therefore investigated the effect of TMAO, which is found in
vivo and acts to maintain correctly folded proteins in several species (17). TMAO produced a similar random coil-to-
Manipulating the Amyloid-
Aggregation Pathway with
Chemical Chaperones*
,
**
,**, and§§
Centre for Research in Neurodegenerative
Diseases, the § Department of Chemical Engineering and
Applied Chemistry, the ¶ Institute for Biometerials and Biomedical
Engineering, the Department of Medical Biophysics, and the
** Ontario Cancer Institute, University of Toronto, Toronto,
Ontario M5S 3H2, Canada
ABSTRACT
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS AND DISCUSSION
REFERENCES
(A) assembly into fibrillar
structures is a defining characteristic of Alzheimer's disease that is
initiated by a conformational transition from random coil to -sheet
and a nucleation-dependent aggregation process. We have
investigated the role of organic osmolytes as chemical chaperones in
the amyloid pathway using glycerol to mimic the effects of naturally
occurring molecules. Osmolytes such as the naturally occurring
trimethylamine N-oxide and glycerol correct folding defects
by preferentially hydrating partially denatured proteins and
entropically stabilize native conformations and polymeric states.
Trimethylamine N-oxide and glycerol were found to rapidly
accelerate the A random coil-to--sheet conformational change
necessary for fiber formation. This was accompanied by an immediate
conversion of amorphous unstructured aggregates into uniform globular
and possibly nucleating structures. Osmolyte-facilitated changes in
A hydration also affected the final stages of amyloid formation and
mediated transition from the protofibrils to mature fibers that are
observed in vivo. These findings suggest that hydration
forces can be used to control fibril assembly and may have implications
for the accumulation of A within intracellular compartments such as
the endoplasmic reticulum and in vitro modeling of the
amyloid pathway.
INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS AND DISCUSSION
REFERENCES
(A)1 peptide. A is
derived by endoproteolysis of the integral membrane amyloid precursor
protein that results in secretion of the peptide by normal cellular
pathways as well as intracellular accumulation. Under pathogenic
conditions, A self-associates into a well defined supramolecular
fibril with high -sheet content (3). A polymerization is
considered to be a two-stage process initiated by the association of
individual A monomers into small nucleating "seeds" that is accompanied by a transition from a predominately random coil to an
amyloidogenic -sheet conformation (4, 5). Subsequent to nucleation,
the A seeds assemble in a chain-like manner to yield an intermediate
protofibrillar structure (6-8), which may represent a common element
of all amyloid fibrils (9, 10). Protofibril conversion into the
ramified fibrils observed in vivo can be affected by factors
such as the amyloid-binding apoE, which is an Alzheimer's disease risk
factor (11); the relative quantity of the more amyloidogenic A
species (4); and other chaperone elements that may control A
self-association.
is generated within intracellular
compartments, including the endoplasmic reticulum (12-15), which is
the quality control site for protein folding, has prompted us to
investigate the role of chemical chaperones in the A folding pathway. Under stress conditions or exposure to denaturants, heat shock
proteins and chemical chaperones assist in stabilizing correctly folded
proteins. Through a process known as osmotic remediation (16), chemical
chaperones or organic osmolytes, including carbohydrates, free amino
acids, or methylamines (e.g. trimethylamine
N-oxide (TMAO)), effectively control protein folding through
a preferential hydration of exposed polypeptide backbone and side
chains of partially unfolded structures (17). Chemical agents such as
glycerol and polyethylene glycol mimic these hydration effects, which
creates a thermodynamically unstable state due to the unfavorable
entropic changes associated with the increased ordering of bound water molecules (18). This can be rectified by folding of the protein into
its native conformation, which sequesters the exposed groups and
excludes the osmolytes from the protein domain. As a result, the free
energy of the native conformation is substantially lower than the
unfolded state, which is demonstrated by the ability of glycerol to
correct misfolded proteins within the endoplasmic reticulum (19).
Hydration effects are equally important in protein polymerization where
osmolytes are excluded through increased protein-protein interactions
and can, for example, enhance the assembly and stability of
microtubules (20). The preferential assembly of protein polymer
subunits such as A and tubulin is a product of their unique
structure, which results in the fibrous aggregate being the lowest
energy conformer. Our findings indicate that similar forces contribute
to the initiation of the A random coil-to--sheet transition and
stabilization of the resulting aggregates. These observations suggest
that chemical chaperones may be useful in modeling amyloid plaque
formation and may have some bearing on the cellular events involved in
fibril formation.
EXPERIMENTAL PROCEDURES
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS AND DISCUSSION
REFERENCES
peptide residues
1-40 (A40) was synthesized and purified as described previously
(21). Peptides were examined immediately following dissolution in
aqueous buffer and following prolonged incubation at high concentration
to promote small protofibrillar -sheet aggregates. A40 was
labeled for fluorescence studies using
N,N'-dimethyl-N-(iodoacetyl)-N'-(7-nitrobenz-2-oxa-1,3-diazol-4-yl)ethylenediamine (Molecular Probes, Inc.) as described (22).
N'-(7-Nitrobenz-2-oxa-1,3-diazol-4-yl)ethylenediamine (NBD)-labeled peptide was purified by gel filtration chromatography and
disaggregated in 10% hexafluoro-2-propanol, and stock solutions were
stored at 
20 °C.
conformation were determined by CD. Peptides
were dissolved to a final concentration of 50 µM in
distilled water or 10 mM phosphate buffer (pH 7). Peptide
solutions were combined with the TMAO at concentrations ranging from 50 to 150 µM and with glycerol ranging from 1.2 to 6 M (10-50% by volume). Spectra were collected following a
10-min equilibration period and after 48-72 h of incubation at room
temperature. Spectra were acquired on a Jasco Model J-715
spectropolarimeter in a 0.1-cm path length cell over a wavelength range
of 190-250 nm with a 1.0-nm bandwidth, 0.1-nm resolution, 1-s response
time, and 20 nm/min scan rate. All spectra were corrected by
subtraction of any contributions from buffer, glycerol, TMAO or
polyethylene glycol.
aggregates were
examined by phosphotungstic acid negative staining and platinum/carbon
shadowing techniques as described previously (17). For shadowing
studies, the samples were atomized onto freshly cleaved mica,
immediately plunged into liquid nitrogen, and lyophilized to eliminate
drying artifacts that could be caused by changes in peptide
concentration. Dried preparations were platinum-coated in an Edwards
E12E4 coater and viewed on a Hitachi H-7000 electron microscope
operated with an accelerating voltage of 75 kV.
under
the various solvent conditions was examined by high speed
centrifugation and assay of the soluble material using the fluorescent
labeled peptide as indicator. Solutions containing 0.1 µM
NBD-labeled A40 and 10 µM unlabeled peptide were
combined in 25 mM phosphate buffer (pH 7) containing from 0 to 6.0 M glycerol. NBD-labeled A40 fluorescence spectra were acquired; the samples were centrifuged in a Beckman Airfuge at
maximum velocity (135,000 × g) for 30 min; and the
fluorescence spectra of the supernatants were measured. Spectra of
control samples containing only A40 were collected and subtracted
from the NBD-labeled A40 fluorescence to correct for the effects of light scattering. Steady-state fluorescence was measured at room temperature using a Photon Technology International QM-1 fluorescence spectrophotometer equipped with excitation intensity correction. Emission spectra from 500 to 600 nm were collected (
ex = 478 nm, 0.1 s/nm, 8-nm band pass for excitation and emission) using a
0.2 × 1-cm path length, 0.5-ml cuvette. To determine the effects of glycerol on the fluorescent probe, unconjugated NBD at 0.1 µM was measured under comparable conditions.
RESULTS AND DISCUSSION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS AND DISCUSSION
REFERENCES
conformation. When dissolved in aqueous buffers, A40 initially exhibits a random coil conformation indicative of an unordered structure (Fig.
1A). Consistent with previous
reports, the conformational changes of A from random coil to
-sheet (21) and subsequent fibril formation (23) can take from hours
to days depending on the particular peptide batch and incubation
conditions. In contrast, adjusting the solution to 1.2 M
glycerol (10%, v/v) resulted in an immediate folding of the peptide
into the amyloid-associated -conformer. Increasing the glycerol
level to 3 or 6 M (25-50%, v/v) produced a linear
increase in the -sheet content as measured by the minima intensity
at 218 nm (Fig. 1A). These effects were not due to increased peptide concentration caused by immiscibility in glycerol since CD
studies conducted in which A concentrations were doubled (from 50 to
100 µM) to replicate the 50% glycerol conditions
revealed no change in the random coil structure of A40 (data not
shown). A similar change was observed for A40 that had been
preincubated to form -sheet aggregates, which represent the early
stages of fibril formation. In this case, elevating glycerol
concentrations proportionally increased the preexisting -sheet
content, but to a slightly lesser quantitative degree as compared with
the random coil-to--sheet conformational change (Fig.
1B). Identical results were obtained under all conditions in
the presence of a low molecular mass (400 Da) polyethylene glycol at
varying concentrations (data not shown). These results indicate that
changes in protein hydration by chemical chaperones rapidly accelerate
the conformational transition required for amyloid formation.
View larger version (14K):
[in a new window]
Fig. 1.
A, CD of A 40 demonstrating the
immediate conversion from random coil to a -sheet conformation with
increasing glycerol concentrations; B, conformational
transitions of an incubated or "aged" A40 comparable to the
protofibril state indicating a similar effect of increasing the
-sheet content induced by glycerol-mediated solvation effects.
Spectra are of the A peptide in buffer (------) and in the presence
of 1.2 M (- · -), 3.0 M (- - - ),
or 6.0 M (····) glycerol. mdegs,
millidegrees.
-sheet transition as that seen with glycerol, but at significantly lower concentrations of 50-150 µM (corresponding to molar
ratios of 1:1 and 1:3 peptide/TMAO) (Fig.
2A). Similar to glycerol, TMAO increased the quantity of the -conformation with the preincubated peptide, which initially displayed a folded and aggregated structure (data not shown). The increases in -sheet conformation by both TMAO
and glycerol were found to be roughly linear as determined by the
absorption at 218 nm (Fig. 2B). However, at the higher concentrations of TMAO, the proportion of the -conformation appeared to be approaching a plateau. These findings suggest that TMAO is a more
active compound in controlling the folding and aggregation state of
A, which may reflect a more potent effect of this osmolyte in an
in vivo setting.
View larger version (11K):
[in a new window]
Fig. 2.
A, CD of A 40 demonstrating the
immediate conversion from random coil to a -sheet conformation with
increasing concentrations of TMAO. Control A in buffer only (------)
and A/TMAO at molar ratios of 1:1 (- · -), 1:1.5 (- - -),
and 1:3 (····) are indicated. B, proportional
increases in the -sheet conformation as measured by the absorption
at 218 nm in the presence of TMAO (
) and glycerol (
) with A
initially in the random conformation and following preincubation prior
to the addition of glycerol (
). mdegs,
millidegrees.
The morphological changes associated with the -sheet conformation
were assessed by TMAFM performed directly in aqueous buffer. TMAFM of
A in the absence of the chemical chaperones revealed irregular
aggregate rafts with an approximate thickness of 10 nm (Fig.
3A). The presence of
aggregates was unexpected since it is generally assumed that the random
coil conformation corresponds to a fully solvated and soluble A
monomer. Since the samples were not pretreated to remove small peptide
aggregates (e.g. submicron filtration), these minor
components could be present and serve as nuclei for nonspecific
precipitation. Alternatively, the amorphous deposits may be due to
adsorption of A to the mica substrate used for TMAFM. The addition
of either TMAO or glycerol at concentrations that produced the random
coil-to--sheet transition, as confirmed by CD, resulted in a
complete conversion of the amorphous A aggregates to a mixture of
protofibrils and small ellipsoidal particles (Fig. 3, B and
C). The protofibrils varied in length and displayed a globular axial periodicity of ~100 Å that was comparable to their average diameter. These were morphologically similar to previously reported protofibrils (7, 8). However, judging from wider field scans,
the ellipsoid aggregates predominated with dimensions of 50 × 60 × 15 Å (Fig. 3C, arrow). We noted that
these dimensions are slightly overestimated due to convolution of the
AFM tip shape with the aggregate shape.
|
Given an experimentally determined volume of ~45,500 Å3,
these ellipsoid particles represent A tetramers or pentamers based on a calculated volume of ~10,000 Å3 for an A
(residues 1-42) molecule folded into a two-stranded -sheet. These
may represent an aggregate of the A dimer that has been shown to be
stable under similar aqueous conditions (24). Comparable structures
have been observed by AFM (25, 26) and have been termed A-derived
diffusible ligands, which may represent the most neurotoxic species
(27). The position of these small aggregates on the amyloid pathway is
presently unclear. A straightforward explanation would be that there is
a linear relationship where these are the progenitors of the
protofibrils that are generated by the direct polymerization of the
ellipsoid aggregates. Alternatively, they may represent a side reaction
with A monomers shuttling between these and the protofibrils.
Assembly of the nucleating aggregates to form protofibrils is
considered to be the slow kinetic phase of the amyloid pathway (28).
This is followed by the thermodynamic phase with the transition to
compacted amyloid fibrils, a process that may also be affected by
osmolyte-induced hydration. Previous AFM and negative stain electron
microscopy studies have defined protofibrils as truncated and highly
flexible fibrillar structures that are the precursors to plaque-related
fibrils (6, 7, 8). Following preincubation of a concentrated A40
solution, we have observed similar aggregates of similar morphology
using platinum/carbon shadowing techniques (Fig.
4A). Such protofibrils ranged
in length from 1 to 100 nm and were poorly contrasted, suggesting that
they have a low profile. The addition of glycerol resulted in a rapid
conversion to straight compacted fibrils that extended over several
hundred nanometers (Fig. 4B) and occasionally displayed
helical twisting (arrowheads). Exposure to chemical
chaperones such as glycerol also significantly improved the image
contrast of the fibrils, presumably as a result of their compaction
into more defined tubular assemblies. Although some curved
protofibril-like structures remained following glycerol treatment,
there was a complete conversion to the longer fibrils following several
hours of incubation (data not shown). Elongation occurred at a
significantly greater pace as compared with the several days required
to convert A protofibrils in the absence of the glycerol
chaperone.
|
To obtain a quantitative measure of aggregation under our experimental
conditions, centrifugation was employed using A labeled with the
fluorescent probe NBD. Our previous fluorescence resonance energy
transfer studies have indicated that the low concentrations of the
fluorophore-labeled A do not interfere with the kinetics of fibril
formation or the morphology of the resulting aggregates (22). In the
current study, similar peptide solutions containing excess unlabeled
(10 µM) and NBD-labeled (0.1 µM) A were
used. Prior to centrifugation, the fluorescence intensity increased linearly with increasing concentrations of glycerol, with the fluorescence at 6 M glycerol being approximately twice that
of the buffer-only sample (Fig. 5). This
increase was due to glycerol-induced changes in the quantum yield of
NBD as shown by the response of the unconjugated label under these
conditions. Following centrifugation, a 97% decrease in fluorescence
was observed, indicating that the peptides are almost completely
aggregated. This was the case for the glycerol-containing samples as
well as the initial aqueous solution, which is consistent with the
amorphous aggregates observed by AFM. This is likely due to the fact
that the samples were not pretreated, for example, by filtration to
remove nonspecific aggregates, which would have allowed examination of
the more direct conversion of soluble monomer to A aggregate.
However, the results presented here with untreated samples suggest that
the conversion to the -sheet particles, which are induced by
solvation changes, may involve a shuttling of monomers from the
unordered structure to the nucleating aggregates. An analogous
situation may occur with the diffuse-to-senile plaque A
interconversion that is seen in vivo, and the use of
chemical chaperones may be useful in modeling this aspect of the
amyloid pathway.
|
Cumulatively, these results demonstrate that changes in the solvation
state of the A peptide affect several aspects of the amyloidogenic
pathway. In general terms, amyloid fibrils are initiated by the
destabilization of a normal cellular protein that leads to a partially
unfolded intermediate. This can be accelerated by point mutations, as
has been shown for lysozyme (29) and transthyretin (30), which are
deposited as systemic plaques. If uncorrected, the unfolded
intermediate will ultimately assemble into the -sheet aggregates
that initiate fibril formation. It has been proposed that chemical
chaperones may, in part, regulate amyloid formation by stabilizing the
lower energy native conformer to reduce the levels of unfolded proteins
that are required for the amyloidogenic pathway. This is consistent
with the observation that naturally occurring organic osmolytes inhibit
the conversion of the cellular prion protein (PrPC) to the
protease-resistant and amyloid-forming PrPSC associated
with transmissible encephalopathies (31, 32). Similar stabilization by
glycerol of misfolded mutant transmembrane proteins within the
endoplasmic reticulum has been demonstrated for the chloride
transporter associated with cystic fibrosis (33, 34) and aquaporins
related to nephrogenic diabetes (35).
Although stabilizing native conformations of larger proteins can affect
amyloid formation, it is likely that A does not have a conventional
conformation and may therefore exist in an unfolded and possibly
amorphous state. Therefore, if unchecked by cellular control elements,
the peptide will gradually deposit as diffuse and eventually senile
plaques. Our results indicate that solvation changes induced by
chemical chaperones such as the naturally occurring TMAO and the
in vitro model provided by glycerol rapidly accelerate the
major steps in the amyloidogenic pathway. These include both the early
nucleation and conformational events as well as the protofibril-to-fiber conversion. This may be unique to proteins that
normally exist in polymeric forms as shown by chemical
chaperone-mediated assembly of tubulin into microtubules and their
subsequent resistance to urea denaturation (20). The significance of
our findings is that they reveal additional contributors to A fibril
formation and therefore provide an additional tool to manipulate this
pathway. Such information could potentially be used to develop or
accelerate cellular models of A aggregation and the assessment of
agents that modulate fibril formation.
| |
FOOTNOTES |
|---|
* This work was supported in part by grants from the Medical Research Council of Canada (to P. E. F., A. C., and C. M. Y.), the Ontario Mental Health Foundation and the Scottish Rite Charitable Foundation of Canada (to P. E. F.), Neurochem, Inc. (to P. E. F., and D.-S. Y.), and the Connaught Foundation (to C. M. Y.).The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
Supported by studentships from the National Sciences and
Engineering Research Council and the Medical Research Council of Canada.
§§ To whom correspondence should be addressed: Centre for Research in Neurodegenerative Diseases, University of Toronto, 6 Queen's Park Crescent West, Toronto, Ontario M5S 3H2, Canada. Tel.: 416-978-0101; Fax: 416-978-1878; paul.fraser{at}utoronto.ca.
| |
ABBREVIATIONS |
|---|
The abbreviations used are:
A, amyloid-;
TMAO, trimethylamine N-oxide;
NBD, N'-(7-nitrobenz-2-oxa-1,3-diazol-4-yl)ethylenediamine;
TMAFM, tapping mode atomic force microscopy;
AFM, atomic force
microscopy.
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS AND DISCUSSION
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) as compared with the supernatant
fluorescence following centrifugation (