Báo cáo khoa học: Quenched hydrogen ⁄deuterium exchange NMR characterization of amyloid-b peptide aggregates formed in the presence of Cu2+ or Zn2+ ppt

Our results suggest that Ab in complex with either Cu2+or Zn2+ can attain an aggregation-prone b-strand–turn–b-strand motif, similar to the motif found in fibrils, but where the metal bin

characterization of amyloid-b peptide aggregates

Anders Olofsson1, Malin Lindhagen-Persson1, Monika Vestling1, A Elisabeth Sauer-Eriksson2and Anders O¨ hman2

1 Department of Medical Biochemistry and Biophysics, Umea˚ University, Sweden

2 Department of Chemistry, Umea˚ University, Sweden

Introduction

Abnormal protein assemblies in form of amyloid are

linked to more than 25 different syndromes, of which

the neurodegenerative disorder Alzheimer’s disease (AD) is the most well-known example [1] The main

Keywords

Alzheimer’s disease; amyloid-b peptide;

Cu 2+ ; H ⁄ D exchange NMR; Zn 2+

Correspondence

A O ¨ hman, Department of Chemistry, Umea˚

University, SE-901 87 Umea˚, Sweden

Fax: +46 90 786 5944

Tel: +46 90 786 5919

E-mail: anders.ohman@chem.umu.se

A Olofsson, Department of Medical

Biochemistry and Biophysics, Umea˚

University, SE-901 87 Umea˚, Sweden

Fax: +46 90 786 5944

Tel: +46 90 786 5921

E-mail: anders.olofsson@medchem.umu.se

(Received 10 March 2009, revised 4 May

2009, accepted 26 May 2009)

doi:10.1111/j.1742-4658.2009.07113.x

Alzheimer’s disease, a neurodegenerative disorder causing synaptic impair-ment and neuronal cell death, is strongly correlated with aggregation of the amyloid-b peptide (Ab) Divalent metal ions such as Cu2+ and Zn2+ are known to significantly affect the rate of aggregation and morphology of

Ab assemblies in vitro and are also found at elevated levels within cerebral plaques in vivo The present investigation characterized the architecture of the aggregated forms of Ab(1–40) and Ab(1–42) in the presence or absence

of either Cu2+ or Zn2+ using quenched hydrogen⁄ deuterium exchange combined with solution NMR spectroscopy The NMR analyses provide a quantitative and residue-specific structural characterization of metal-induced Ab aggregates, showing that both the peptide sequence and the type of metal ion exert an impact on the final architecture Common features among the metal-complexed peptide aggregates are two solvent-protected regions with an intervening minimum centered at Asn27, and a solvent-accessible N-terminal region, Asp1–Lys16 Our results suggest that

Ab in complex with either Cu2+or Zn2+ can attain an aggregation-prone b-strand–turn–b-strand motif, similar to the motif found in fibrils, but where the metal binding to the N-terminal region guides the peptide into

an assembly distinctly different from the fibril form

Structured digital abstract

l MINT-7102414 , MINT-7102427 : Abeta (uniprotkb: P05067 ) and Abeta (uniprotkb: P05067 ) bind ( MI:0407 ) by fluorescence technologies ( MI:0051 )

l MINT-7103341 , MINT-7103348 : Abeta (uniprotkb: P05067 ) and Abeta (uniprotkb: P05067 ) bind ( MI:0407 ) by atomic force microscopy ( MI:0872 )

l MINT-7102371 , MINT-7102380 : Abeta (uniprotkb: P05067 ) and Abeta (uniprotkb: P05067 ) bind ( MI:0407 ) by circular dichroism ( MI:0016 )

l MINT-7102390 , MINT-7102399 : Abeta (uniprotkb: P05067 ) and Abeta (uniprotkb: P05067 ) bind ( MI:0407 ) by biophysical ( MI:0013 )

l MINT-7103367 , MINT-7103374 : Abeta (uniprotkb: P05067 ) and Abeta (uniprotkb: P05067 ) bind ( MI:0407 ) by nuclear magnetic resonance ( MI:0077 )

Abbreviations

AD, Alzheimer’s disease; AFM, atomic force microscopy; Ab, amyloid-b peptide; H ⁄ D, hydrogen ⁄ deuterium; ThT, thioflavin T.

protein component of the plaques found in patients

with AD is the amyloid-b peptide (Ab) This is a

proteolytic excision product derived from the

signifi-cantly larger amyloid precursor protein, representing

an ensemble of peptides of various lengths, each of

which has distinguishing biophysical properties

Frag-ments of 39–43 residues are all clinically relevant, but

the most abundant are Ab(1–40) and Ab(1–42) [2]

The fold and mode of assembly of Abs are

deter-mined by their primary sequences in combination with

the chemical properties of the solvent Abs assemble

via several different routes into aggregates ranging in

size from dimers [3] to smaller oligomers [4–7],

protofi-brils [8,9], and fully mature amyloid fibers Elucidation

of amyloid fiber and aggregate structures, as well as

their path of formation, is crucial to understanding the

pathological process of AD Although the size,

insolu-bility and noncrystalline behavior of fibers and

aggre-gates make conventional structural studies difficult,

extensive solid-state and solution-state NMR

investiga-tions of both Ab(1–40) and Ab(1–42) fibrils have

dem-onstrated that the peptides stack perpendicularly along

the fibril axis via a parallel in-register assembly of a

b-strand–turn–b-strand motif, forming a characteristic

cross-b structure with a highly solvent-protected core

of two intermolecular b-sheets [10–13] X-ray

micro-crystallography of short Ab fragments has revealed

very tight packing of side chains within the cross-b

structure [14]

The aggregation properties of Abs are strongly

affected by their affinities for certain metal ions [15–

19] Elevated concentrations of Cu2+, Zn2+ and Fe2+

are found within deposited plaques in vivo [20], and

both Cu2+and Zn2+affect the toxicity of Ab [21–25]

The in vivo effect of metals can be complex [26,27],

and the presence of Cu2+, Zn2+or Ca2+ significantly

accelerates aggregation of Ab in vitro [19,28,29] The

binding of Cu2+and Zn2+to monomeric Ab has been

extensively studied and occurs via three histidines

(His6, His13, and His14) and a fourth ligand suggested

to be either Tyr10 [30–32], Glu11 [33], or the

N-termi-nus [34,35] A weaker binding site for zinc, involving

Asp23–Lys28, has also been identified [35] Ab

assem-blies formed in the presence of metals are not

charac-terized as amyloid, because they lack tinctorial

properties and fibrillar morphology, and they can be

completely dissociated using chelating agents or by a

slight increases in pH [19,28] Interesting parallels can

be drawn between these assemblies and the diffuse

pla-ques found in AD patients, which also lack fibrillar

morphology and which are largely solubilized by

che-lating agents [36] Intriguingly, it appears that metal

binding induces a fold that effectively protects against

further propagation into fibrillar form [37] and that removal of the bound metals causes dissociation of the peptide aggregates rather than further assembly into amyloid Identification of structural differences between the fibrillar and the metal-bound aggregate forms is therefore of interest with respect to under-standing the mode of assembly and pinpointing the mechanism by which metals guide the path of aggre-gation away from the fibrillar trail

The present investigation assessed how the growth and architecture of Ab(1–40) and Ab(1–42) aggregates are affected by the presence or absence of Cu2+ or

Zn2+, using turbidity measurements, thioflavin T (ThT) fluorescence, CD spectroscopy, atomic force microscopy (AFM), and, in particular, a very powerful quenched hydrogen⁄ deuterium (H ⁄ D) exchange NMR method Although this NMR method was developed and utilized for studies of amyloid fibrils [12,38–43], it

is equally applicable to the quantitative and residue-specific identification of the core structures in metal-bound Ab aggregates Significant structural changes with an overall less protected structure were observed

in the metal-complexed Ab aggregates as compared with the Ab fibrils Differences were also identified between Cu2+-bound and Zn2+-bound aggregates and between Ab(1–40) and Ab(1–42) aggregates, indicating that both the type of bound metal and the peptide sequence dictate the mode of peptide assembly

Results and Discussion

Ab aggregation in the presence of Cu2+and Zn2+ Turbidity measurements showed that the aggregation rates of both Ab(1–40) and Ab(1–42) were significantly increased in the presence of either Cu2+ or Zn2+ (Fig 1A), in agreement with previous investigations [19,28,44,45] Both Ab(1–40) and Ab(1–42) reached a plateau where aggregation was essentially complete after 40 min (Fig 1A) It is noteworthy that the pla-teau values for both peptides were considerably higher when Zn2+ was added, suggesting a different mode of assembly within the metal-induced aggregates Addi-tion of EDTA to our samples efficiently reversed the aggregation and reduced the intensity to background levels (Fig 1A), which parallels previous findings [19,28] During the time of the analysis, no detectable turbidity was observed for either Ab(1–40) or Ab(1–42)

in the absence of divalent metals, i.e when EDTA was included in the reaction mixture SDS⁄ PAGE and gel filtration analysis of the EDTA-containing samples confirmed that Ab was present in its monomeric form (data not shown)

The amount of amyloid or amyloid-like structure

within the different Ab assemblies was quantified by

ThT fluorescence To ensure that trace amounts of

divalent metals did not affect the formation and

analy-sis of the fibril samples, a chelator in a two-fold molar

excess of the peptide was present in all experiments on

fibrillar samples With Cu2+ present, approximately

10% of the normal fibrillar ThT signal for both

Ab(1–40) and Ab(1–42) aggregates was detected,

whereas Zn2+-induced aggregates resulted in a larger

ThT response, corresponding to approximately 40% of

the fibrillar counterpart (Fig 1B)

A considerable change between the spectra from

metal-complexed Ab aggregates and from fibrils was

detected using CD spectroscopy (Fig 1C) The spectra

from the metal-complexed peptides were characteristic

for aggregated samples, and suggest a lower degree of

secondary structure content as compared with the

spectra from the fibril samples The CD measurements

were carried out at two different protein

concentra-tions (50 and 100 lm) to ensure that the results were

not biased by the inherent light scattering of

aggre-gates (data shown only for 50 lm)

All forms of aggregates were examined using AFM

(Fig 2) The results were in accordance with previous

investigations in which aggregates formed in the

pres-ence of a molar excess of divalent metal ions failed to

attain the classic morphology of amyloid fibrils [37,46]

The aggregates of Ab(1–40) and Ab(1–42) formed in

the presence of a chelating agent gave rise to the

clas-sic fibrillar morphology, with an average fibril

diame-ter of about 7 nm It is well known that Ab(1–40) and

Ab(1–42) fibrils consist of bundles of thinner filaments, each having a cross-section of about 3 nm [47] This was most clearly seen within the Ab(1–42) variant (Fig 2F), which also had a twinned ultrastructure For both Ab(1–40) and Ab(1–42), the presence of divalent metal ions efficiently inhibited fibril formation and, as expected, resulted in more amorphous aggregates It was not, however, possible to morphologically distin-guish aggregates formed in the presence of Cu2+from those formed in the presence of Zn2+

Taken together, these results suggest that Ab aggre-gates formed in the presence of Cu2+or Zn2+are less compact than fibrillar complexes and are assembled from Abs with altered secondary structure The results

of ThT analysis suggest that Zn2+-complexed Ab may tolerate assembly into a more fibrillar-like fold, whereas Cu2+more efficiently prevents formation of a fibrillar assembly Furthermore, all metal-bound Ab aggregates could be efficiently converted to monomers through the addition of a chelating agent, suggesting that their mode of assembly is different from that of the fibrillar forms

Quenched H⁄ D exchange NMR on Ab assemblies The use of quenched H⁄ D exchange in combination with NMR spectroscopy is a highly useful technique with which to efficiently pinpoint the solvent accessibil-ity of individual amide protons within peptide assem-blies in a residue-specific and quantitative manner, thereby providing detailed structural information [12,38–43] In this study, aggregates of Ab(1–40) and

Fig 1 Abs were characterized by using (A) turbidity measurements, (B) a ThT assay, and (C) CD spectroscopy (A) Turbidity measurements

on samples containing 50 l M Ab(1–40) (solid line) and Ab(1–42) (broken lines) were started immediately after the addition of Cu 2+ [(iii) and (iv)], Zn 2+ [(i) and (ii)] or EDTA [(v) and (vi)] and continued for 164 min After 100 min, 400 l M EDTA was added, and the absorbance was measured for an additional 64 min (B) ThT analysis of aggregated Ab samples containing 100 l M Ab(1–40) and Ab(1–42) in the presence of

Cu 2+ (light gray bars), Zn 2+ (open bars), or EDTA (dark gray bars) The respective emissions of the fibrillar forms of Ab(1–40) and Ab(1–42) were set to 100% intensity (C) Far-UV CD spectra from samples containing 50 l M Ab(1–40) (solid lines) or Ab(1–42) (broken lines), either

in the form of aggregates formed in the presence of Cu2+[(i) and (iii)] or Zn2+[(ii) and (iv)], or as fibrils formed in the presence of EDTA [(v) and (vi)].

Ab(1–42) peptides in the presence of Cu2+, Zn2+ or

EDTA were investigated The chelating agent EDTA

was used to remove trace amounts of divalent metals

that may affect fibril formation H⁄ D exchange was

carried out by preincubating samples in D2O for 24 h

before analysis The length of incubation ensures

detection of only those amide protons that are

pro-tected as a result of hydrogen bonding within

second-ary structure elements or because they are deeply

buried in the core of the fibril [12,13]

Samples verified by AFM and ThT analysis to

con-tain the fibrillar forms of Ab(1–40) and Ab(1–42)

(fibrils formed in the presence of EDTA) displayed

amide protection patterns with two bell-shaped

pro-tected regions (Fig 3C,F) Ab(1–40) fibrils showed

partial to full protection for Glu3–Ser26 and Gly29–

Val40, separated by exposed residues in the turn region

centered at Asn27–Lys28 (Fig 3C), whereas the

pro-tection pattern of the fibrillar form of Ab(1–42) included residues Phe4–Arg5, Tyr10–Ser26, and Gly29–Ala42 (Fig 3F) The degree of protection in the N-terminal region of Ab(1–42) is notably lower than

in Ab(1–40) These results are similar to those of our recently published investigations on Ab(1–40) and Ab(1–42) fibrils [12,13]; the small differences observed are probably due to the use of different growth condi-tions during fibril preparation [150 mm NaCl (pH 7.4) and 1 mm EDTA versus 50 mm NaCl (pH 7.0) in the previous investigations] The protection patterns observed are in good agreement with current models extrapolated from solid-state NMR data [10,48], dou-ble compensatory mutagenesis combined with H⁄ D exchange NMR [11], and cysteine scanning mutagene-sis [49], where the Abs (which form two b-strands with

a turn region involving Val24–Ala30) stack in an in-register parallel arrangement to form the fibril [10,48] (Fig 4) The pattern for Ab(1–40) fibrils also fits well with our recent report, in which a new general method

to quantitatively determine the exchange rates of amide protons within fibrils is described and applied to fibrils formed by Ab(1–40) [43]

The presence of either Cu2+ or Zn2+ during aggre-gate⁄ fibril growth had a significant impact on the solvent protection pattern for both Ab(1–40) and Ab(1–42) When compared to the protection ratios in the absence of metal (Fig 3C,F), the overall protection ratio in the presence of metal was significantly reduced (Fig 3A,B,D,E) In the metal-complexed aggregates, the Asp1–Lys16 region essentially lacks solvent protec-tion This is reasonable, as metal binding occurs within the first 14 residues, inducing a low degree of second-ary structure [33,50] However, the remaining parts of both Ab(1–40) and Ab(1–42) still display two fairly well-protected bell-shaped regions with an intervening minimum centered on Asn27 This is strong evidence that metal-complexed Ab aggregates attain a b-strand-turn–b-strand structural arrangement similar to the structural arrangement within mature fibrils (Fig 4) The metal-complexed Ab(1–40) aggregates also show pronounced differences from the fibrillar form in the C-terminal region as well as in the turn region of the peptide Assuming a fibril-like structural arrangement

in which two protofilaments formed from stacked pep-tides are laterally assembled, the N-terminal metal-binding region of the peptide will be in close proximity

to both the C-terminal and turn residues, possibly interfering with these regions This explains how an altered conformation in the N-terminal region upon metal binding can affect sections of the molecule closer

to the C-terminus (see the fibril cross-section in Fig 4) Furthermore, differences in solvent protection are

A

B

C

D

E

F

Fig 2 Tapping mode AFM images of recombinant Ab(1–40) and

Ab(1–42) aggregates (A–C) Morphology of Ab(1–40) in the

pres-ence of Cu 2+ , Zn 2+ , and EDTA, respectively (D–F) Morphology of

Ab(1–42) in the presence of Cu 2+ , Zn 2+ , and EDTA, respectively.

Scale bar: 1 lm.

observed between the Cu2+-induced and Zn2+-induced

aggregates, reflecting the differences in metal-binding

properties of Ab [26,30,33–35] Zn2+ significantly

reduces the overall protection, in particular for residues

close to the turn region (Fig 3B) For Zn2+-induced

Ab(1–40) aggregates, the solvent-protected residues

include Leu17–Glu22 and Ile31–Val36 (Fig 3B),

whereas in Cu2+-induced Ab(1–40) aggregates, Leu17–

Gly25 and Lys28–Val36 are protected (Fig 3A)

The increased solvent accessibility of the turn region

within Zn2+-induced Ab(1–40) aggregates correlates

well with a proposed second weak binding site for

Zn2+involving Asp23–Lys28 in the turn region [35]

Comparison of the solvent protection pattern of

Cu2+-induced and Zn2+-induced Ab(1–42) aggregates

(Fig 3D,E) with Ab(1–42) fibrils (Fig 3F) reveals a

reduced overall level of protection and completely

exposed residues in the N-terminal region The

solvent-protected residues in the Ab(1–42)

metal-complexed aggregates (Leu17–Glu22⁄ Asp23 and Ile31–

Ile41) form two characteristic bell-shaped regions,

suggesting a mode of assembly similar to that of the

fibrillar samples Figure 3D,E demonstrates that there

is no significant difference in solvent exposure in the turn regions of Ab(1–42) aggregates formed in the presence of either Cu2+ or Zn2+ The C-terminal region in the Ab(1–42) aggregates is affected by metals

to a lesser extent than the C-terminal region of the Ab(1–40) aggregates, suggesting they are assembled in

a way that places the C-terminal residues in the aggre-gate core This is similar to the arrangement found in Ab(1–42) fibrils, where the C-terminal residues strengthen the hydrophobic interactions within the core of the fibrillar fold via a shift in the protofilament assembly that positions the C-terminal residues of Ab(1–42) in a more hydrophobic environment [10,48] (Fig 4)

Implications for aggregate⁄ fibril formation Although the properties of fibrils and metal-bound aggregates of Abs differ significantly, the H⁄ D protec-tion patterns of metal-bound Ab aggregates still sug-gest a partly preserved b-strand–turn–b-strand fold similar to the fibrillar form (Fig 3) The metal-induced

Ab aggregates have fewer protected residues and a

A

B

C

D

E

F

Fig 3 Solvent protection ratios for the backbone amide protons of Ab(1–40) and Ab(1–42) aggregates Protection is defined as the ratio of the observed intensity after a 24 h preincubation period in D2O over the intensity in a completely protonated sample (defined as 100%) (A–C) Solvent protection ratios for Ab(1–40) aggregates in the presence of Cu2+, Zn2+, and EDTA, respectively (D–F) Ratios for Ab(1–42) aggregates in the presence of Cu 2+ , Zn 2+ , and EDTA, respectively Rings correspond to 0% protection, and crosses represent residues that exchange too quickly to be detected Error bars indicate the experimental uncertainty of the measurements.

lower degree of solvent protection than fibrils,

suggest-ing that formation of b-strands and subsequently

fibrils is hindered, and that fewer intermolecular

inter-actions are needed for assembly This scenario would

explain the high aggregation rates observed in the

tur-bidity measurements (Fig 1A) The pronounced lack

of H⁄ D protection close to the known metal-binding

site within the N-terminal regions of both Ab(1–40)

and Ab(1–42) clearly shows that only the protected

C-terminal regions are involved in the assembly

How-ever, assembly in the presence of metals is unlikely to involve the same intermolecular interactions as within fibrils, as removal of the metals causes dissociation into monomers instead of the continued assembly into amyloid fibrils expected from a more fibril-like fold One speculative explanation of this behavior is that, in the presence of metals, the peptides assemble into an array with b-strand–turn–b-strand motifs (Fig 4) stacked in an antiparallel fashion, distinctly different from the parallel assembly within fibrils This sugges-tion is supported by previous observasugges-tions that peptide fragments of Ab preferably stack in an antiparallel fashion along the fibril axis [14,51–53]

In conclusion, our results support the previous notion that metal binding by the N-terminal residues (Asp1– Lys16) prevents assembly into a fibrillar structure On the basis of our quenched H⁄ D exchange NMR data,

we propose that both Cu2+-induced and Zn2+-induced

Ab aggregates assemble via a b-strand–turn–b-strand motif, resembling the motif found in fibrils

Experimental procedures

Isotope-enriched chemicals were purchased from Cambridge Isotope Laboratories (Andover, MA, USA) All peptides,

were obtained in lyophilized form from Alexotech AB (Umea˚, Sweden) (http://www.alexotech.com) Reagents and buffers were purchased from Sigma-Aldrich (St Louis, MO, USA), unless otherwise stated

Sample preparation

Lyophilized Ab(1–40) and Ab(1–42) were briefly dissolved

in 10 mm NaOH, sonicated for 30 s, and centrifuged (10 min at 12 000 g) to remove residual oligomeric species,

as previously described [54] This treatment efficiently monomerizes the peptides and facilitates dilution in 20 mm Tris (pH 7.4) and 150 mm NaCl (for turbidity measure-ments) or 10 mm Tris (pH 7.4) and 150 mm NaCl (for ThT assay and CD spectroscopy) to a peptide concentration of either 50 or 100 lm, with a two-fold molar excess of CuCl2, ZnCl2, or EDTA Fibrils⁄ aggregates were formed by incu-bating the samples for 14 days at 37C with agitation

Turbidity measurements

Turbidity was measured by recording the absorbance

at 405 nm Measurements on samples containing 50 lm Ab(1–40) and Ab(1–42) were started immediately after the addition of Cu2+, Zn2+, or EDTA, and thereafter recorded for 164 min The samples were kept still at room tempera-ture except from 5 s before each measurement Each mea-surement was performed in triplicate After 100 min,

A

B

C

D

E

F

Fig 4 The determined solvent protection ratios for residues within

Ab(1–40) and Ab(1–42) aggregates are mapped onto corresponding

dimer of two cross-b units taken from cross-sections of the

Ab(1–40) and Ab(1–42) fibril (aggregate) models, respectively The

color code is varied between the following extremes: navy blue for

complete, and red for no solvent protection Residues with no

pro-tection ratios available are depicted in gray Cu 2+ is shown in

brown, and Zn 2+ in bluish gray (A–C) Protection ratios of Ab(1–40)

in the presence of Cu2+, Zn2+, and EDTA, respectively (D–F)

Pro-tection ratios for Ab(1–42) in presence of Cu 2+ , Zn 2+ , and EDTA,

respectively The image was prepared in MOLMOL [55].

400 lm EDTA was added to all wells and the absorbance

was measured for an additional 64 min

ThT analysis

Samples containing 100 lm aggregated Abs were mixed

with 10 lm ThT and 50 lm phosphate buffer (pH 6.5) in a

10 mm quartz cuvette Emission intensities were recorded

Co., Ltd., Tokyo, Japan), with excitation and emission

wavelengths of 450 and 482 nm, respectively, and a 3 nm

bandwidth for both emission and excitation Each

measure-ment was performed in triplicate

CD spectroscopy

Far-UV CD spectra were collected on samples containing

either 50 or 100 lm Ab, using a JASCO J-810

200 and 250 nm, and averaged over 10 scans with a

band-width of 1 nm, a response time of 1 s, a pitch of 0.5 nm,

and a scan rate of 20 nmÆs)1, in a 2 mm quartz cuvette

AFM

A portion of each Ab aggregate sample was diluted in

water to approximately 1 lm peptide and applied to freshly

cleaved ruby red mica (Goodfellow, Cambridge, UK) The

material was allowed to adsorb for 30 s, and then washed

with distilled water three times and air dried AFM analysis

was performed using a Nanoscope IIIa multimode atomic

force microscope (Digital Instruments, Santa Barbara,

USA) in tapping mode in air A silicon probe was oscillated

at abount 280 kHz, and images were collected at an

opti-mized scan rate corresponding to 1 Hz

Quenched H⁄ D exchange NMR

Lyophilized15N-labelled Ab(1–40) and Ab(1–42) (obtained

monomerized as described above, and this was followed by

addition of 10· buffer (20 mm Tris, pH 7.4, 150 mm NaCl)

to a final peptide concentration of 500 lm A two-fold

molar excess of either ZnCl2, CuCl2 or EDTA was added

to each sample Fibril⁄ aggregate solutions were prepared

130 r.p.m.) and recovered by centrifugation (2 min at

13 000 g), and each was then split into two; one half was

preincubated in D2O for 24 h (by dissolving the pellet 30

times in 20 mm Tris, pD 7.0, 150 mm NaCl and a two-fold

molar excess of ZnCl2, CuCl2, or EDTA), and one served

as a fully protonated reference sample At the end of the

incubation period and immediately prior to NMR analysis,

the Ab assemblies were recovered by short centrifugation

steps (13 000 g) and subsequently dissociated into

optimized solution of hexafluoroisopropanol as described in [12], with the addition of 2 mm diethylenetriamine penta-acetic acid as chelating agent NMR data were recorded and analyzed as previously described [12,13], resulting in residue-specific solvent protection ratios for the backbone amide protons within Ab(1–40) and Ab(1–42) aggregates Observed ratios were mapped onto models of the various aggregates These models are based on our previous fibril models [12,13], the model of Ab(9–40) by Tycko et al [10], the solution structure of Ab(1–16) with and without bound

Zn2+[33], and the proposed filament packing arrangement for Ab(1–42) [10,48] Modifications and energy minimiza-tion were performed in molmol [55] and swiss-pdbviewer [56], respectively

Acknowledgements

We thank R Tycko for kindly providing us with the coordinates of the Ab(9–40) amyloid model This work was supported by the Magn Bergvalls Foundation, Carl Trygger Foundation, Alzheimerfonden, Socialsty-relsen, Hja¨rnfonden, A˚ke Wibergs Foundation, Bern-hard och Signe Ba¨ckstro¨ms stiftelse, O E och Edla Johanssons vetenskapliga stiftelse, Go¨ran Gustafssons Foundation, Swedish Research Science Council, Ernst Schering Foundation, Centre for Biomedical Engineer-ing at Wrocaw University of Technology, Gun och Bertil Stohnes stiftelse, Loo och Hans Ostermans stift-else fo¨r geriatrisk forskning and patients’ association FAMY⁄ AMYL

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