Aβ_1–40 was purchased from AnaSpec (San Jose, CA) or W. M. Keck Biotechnology Resource Laboratory (New Haven, CT). BSA was obtained from EMD Chemicals (Gibbstown, NJ). Thioflavin T, RPMI 1640 medium, fetal bovine serum (FBS), hydrocortisone, gelatin, and Calcein-AM were obtained from Sigma (St. Louis, MO). CS-C Medium and other CS-C culture reagents were obtained from Cell Systems (Kirkland, WA). Collagen was obtained from PureCol INAMED (Fremont, CA).

Lyophilized Aβ_1–40 was stored desiccated at -20°C until preparation of monomer or fibril as described previously 6. Briefly, Aβ_1–40 was reconstituted (2 mg/ml) in 50 mM NaOH and pre-existing aggregates were removed by size exclusion chromatography on a Superdex 75 HR10/30 column (GE Healthcare, Piscataway, NJ) equilibrated in 40 mM Tris-HCl (pH 8.0). Isolated monomer was used fresh or stored at 4°C for up to 24 h. To prepare fibrils, isolated monomeric Aβ_1–40 (100–200 μM) was agitated vigorously at 25°C in the presence of 250 mM NaCl and 40 mM Tris-HCl (pH 8.0) for 24–30 h. Fibrils were evaluated via thioflavin T fluorescence, isolated via centrifugation (15 min, 18,000 × g), resuspended in 40 mM Tris-HCl (pH 8.0), and stored at 4°C for up to 1 week.

As described previously 6, thioflavin T fluorescence was monitored for samples containing 10 μM thioflavin T solution in 40 mM Tris-HCl (pH 8.0). Fluorescence was measured on an LS-45 luminescence spectrometer (Perkin-Elmer, Waltham, MA) with excitation at 450 nm. Fluorescence (F) was taken as the integrated area under the emission curve (470–500 nm) with baseline (thioflavin T, BSA) subtraction.

Aβ_1–40 monomer was diluted to 20 μM in 40 mM Tris-HCl (pH 8.0) containing 150 mM NaCl and incubated in the absence (control) or presence of 20–80 μM BSA at 25°C and under vigorous agitation (vortex, 500 rpm). Reaction progress was monitored via thioflavin T fluorescence following dilution of an aliquot into 10 μM thioflavin T, and results are reported as the change in thioflavin T fluorescence (ΔF) with time. Subsequent to the final fluorescence measurement, aggregate size was assessed for undiluted samples via hydrodynamic radius (R_H) measurements. Experiments in which thioflavin T fluorescence and R_H were measured for BSA subjected to aggregation conditions in the absence of Aβ_1–40 monomer served as a negative control and ascertained the negligible contribution of BSA to these signals.

As described previously 6, aggregate size was assessed via R_H measurements using a DynaPro MSX DLS instrument (Wyatt Technology, Santa Barbara, CA) to assimilate auto-correlated light intensity data for calculation of translational diffusion coefficients that could be converted to R_H using the Stokes-Einstein equation. R_H was assessed from the intensity-weighted histogram calculated via data regulation with Dynamics software (Wyatt Technology).

Aβ_1–40 fibrils were diluted in 40 mM Tris-HCl (pH 8.0) containing thioflavin T and incubated for 15 min in the absence (control) or presence of BSA. To initiate growth, Aβ_1–40 monomer was added for final concentrations of 40 μM monomer, 2 μM fibril, 0–10 μM BSA, and 10 μM thioflavin T. Reactions were incubated at 25°C without agitation, and the incorporation of monomer into growing fibrils was monitored via thioflavin T fluorescence. Experiments in which thioflavin T fluorescence of 40 μM Aβ_1–40 monomer was monitored in the absence of fibrils confirmed that monomer self-assembly did not occur under these experimental conditions. In addition, experiments in which thioflavin T fluorescence of 2 μM Aβ_1–40 fibrils was monitored without addition of monomer served as negative controls and reflected the stability of fibrils. Results are reported as the change in thioflavin T fluorescence (ΔF) with time, and elongation rates were determined by linear regression of this data.

ACBRI 376 primary human brain microvascular endothelial cells (HBMVECs) (Cell Systems, Kirkland, WA) and the human pre-monocytic cell line THP-1 (American Type Culture Collection, Rockville, MD) were maintained and prepared for experiments as described previously 6. Endothelial cells (passage 4–8) were seeded (5 × 10⁵–6 × 10⁵ cells/ml) onto coated (2.0% gelatin, 100 μg/ml collagen) 96-well flat-bottom culture plates and sustained until confluence in CS-C Serum Free Medium supplemented with hydrocortisone (550 nM). THP-1 cells maintained in supplemented RPMI 1640 medium containing 10% FBS were fluorescently labelled for adhesion experiments via incubation with Calcein-AM followed by resuspension in Dulbecco's PBS (D-PBS) (2 × 10⁵ cells/ml).

Confluent HBMVEC monolayers were treated for 24 h with Aβ_1–40 monomer aggregated in the absence (positive control) or presence of BSA. Reaction products were diluted into culture medium containing hydrocortisone for a final Aβ_1–40 concentration of 5 μM. Parallel treatment with an equivalent dilution of BSA or buffer served as negative controls. As described previously for adhesion assays 6, activated monolayers were washed and incubated with Calcein-labelled THP-1 cells (2 × 10⁴cells/well) for 30 min (37°C, 5% CO₂). Nonadherent cells were removed by gentle washing (D-PBS). The number of adherent cells was assessed by Calcein fluorescence employing a Synergy 2 microplate reader (BioTek Instruments, Inc., Winooski, VT) equipped with an excitation filter of 485 ± 10 nm and an emission filter of 528 ± 10 nm and using baseline (D-PBS) subtraction. Results are reported as the percentage of adherent cells [(100%)·(Cells_adherent/Cells_initial)].

Statistical analysis was performed with a one-way ANOVA using GraphPad Prism 5 software (San Diego, CA). Dunnett's test was used for multiple comparisons. P < 0.05 was considered significant. Linear regression was assessed using the coefficient of determination, r².

To assess the effect of BSA on Aβ_1–40 fibril assembly from monomeric peptide, monomer aggregation was induced by continuous agitation in the presence of ratios of BSA to Aβ_1–40 monomer ranging from equimolar to 4-fold excess. The formation of aggregated β-sheet structure was monitored using thioflavin T fluorescence. To ensure that the presence of BSA did not impede detection of Aβ aggregates, it was confirmed that the thioflavin T fluorescence of pre-formed Aβ_1–40 fibrils was not reduced in the presence of BSA. These results indicate that BSA does not compete with thioflavin T for binding to fibrils nor does it sequester thioflavin T to prevent its binding to fibrils.

As shown in Figure 1, 20 μM Aβ_1–40 monomer incubated in the absence of BSA exhibited the characteristic lag, indicative of nucleus formation, followed by rapid aggregate growth and concluding with a plateau as equilibrium was reached. BSA-induced changes in Aβ_1–40 monomer aggregation were assessed by evaluating both extension of the lag time and reduction of the plateau fluorescence level. When BSA was present at equimolar concentrations with Aβ_1–40 monomer, the lag time was nearly doubled (Figure 1, Table 1), suggesting that BSA can intervene at early points along the self-assembly pathway. As the concentration of BSA was increased to a level 2-fold in excess of Aβ_1–40 monomer, the lag time was further extended by almost 2.5-fold and the equilibrium plateau was reduced, indicating that at higher concentrations BSA can reduce the quantity of aggregated Aβ. When Aβ_1–40 monomer was agitated in the presence of a 4-fold excess of BSA, nearly complete inhibition was observed over the 4.5 h period. BSA subjected to aggregation conditions in the absence of Aβ_1–40 monomer exhibited negligible change in thioflavin T fluorescence. These results illustrate the ability of BSA to abrogate Aβ_1–40 monomer aggregation at concentrations in excess of Aβ_1–40 monomer and further demonstrate the dose-dependent nature of this inhibition as BSA concentrations approach stoichiometric ratios with Aβ_1–40.

To determine whether BSA is capable of interacting with pre-formed Aβ_1–40 aggregates to inhibit later stages of Aβ_1–40 assembly, the growth of Aβ_1–40 fibrils was assessed following pre-incubation in the presence of BSA at ratios of BSA to Aβ_1–40 fibril ranging from substoichiometric to 5-fold excess, where fibril concentrations are expressed in monomer units. Fibril growth was induced via addition of Aβ_1–40 monomer, and the incorporation of monomer into growing fibrils was monitored as the change in thioflavin T fluorescence. Thioflavin T may itself act as both an indicator and an inhibitor of Aβ self-assembly. However, at stoichiometric ratios that exceed those included within fibril elongation reactions thioflavin T has been observed to have no effect upon the formation of Aβ fibrils from monomeric peptide 14. In addition, the absence of inhibitory activity by thioflavin T within the Aβ fibril elongation assay has been experimentally confirmed for the conditions employed (data not shown).

As shown in Figure 2, steady growth was observed when 2 μM Aβ_1–40 fibril was incubated with 40 μM Aβ_1–40 monomer (Figure 2). This uninhibited rate of fibril growth was compared to the rate of growth observed in the presence of BSA to determine the extent of inhibition. Aβ_1–40 fibrils pre-incubated in the presence of BSA at a level 5-fold in excess of monomeric units within Aβ_1–40 fibrils exhibited a much slower rate of growth (Figure 2) and therefore significant inhibition (Table 1), confirming that BSA is able to prevent the addition of Aβ_1–40 monomer to pre-formed Aβ_1–40 fibrils. Pronounced inhibition was also evident when BSA was present at concentrations equimolar to monomeric units within Aβ_1–40 fibrils. Further reduction in the concentration of BSA to a substoichiometric ratio of 1:4 BSA:Aβ_1–40 fibril continued to inhibit fibril growth at lower but still significant levels. These results illustrate the ability of BSA to modulate the growth of pre-formed Aβ_1–40 aggregates in a dose-dependent manner and, in contrast to BSA inhibition of monomer aggregation, demonstrate the strength of this inhibition at substoichiometic BSA concentrations.

To assess the effect of BSA upon the physiological activity of Aβ_1–40 aggregates, brain endothelial cells, which are in direct and continuous contact with circulating serum proteins, were selected. Aβ_1–40 has been previously observed to stimulate HBMVECs for increased adhesion of both THP-1 monocytes 61516 and primary human peripheral blood monocytes 616 via a mechanism that involves Aβ recognition of the receptor for advanced glycation end products 1516. The ability of BSA to attenuate this Aβ-induced adhesion in HBMVECs was explored.

When HBMVEC monolayers were treated with 5 μM Aβ_1–40 aggregates formed in the absence of BSA, a 2.3-fold increase in adhesion of THP-1 monocytes relative to untreated control monolayers was observed (Figure 3). This result is similar to that reported previously 6. Aβ_1–40 aggregates formed in the presence of a 2-fold excess of BSA stimulated an even more pronounced 2.9-fold increase in adhesion of THP-1 monocytes, despite the decreased thioflavin T fluorescence observed under these aggregation conditions (Figure 1). In contrast, when Aβ_1–40 aggregates were formed in the presence of a 4-fold excess of BSA, a smaller increase in THP-1 adhesion of only 1.5-fold was observed. BSA treatment of endothelial monolayers in the absence of Aβ made an insignificant contribution to the observed changes in adhesion. These results demonstrate that inhibition of in vitro Aβ_1–40 monomer aggregation by BSA is not paralleled by a dose-dependent decrease in physiological activity.

Previous studies revealed that the size of Aβ_1–40 aggregates determines their ability to stimulate endothelial monolayers for monocyte adhesion. The most pronounced increases in adhesion were observed for small soluble aggregates exhibiting R_H values of 20–40 nm. Physiological activity decreased as aggregate size increased to 100 nm, and aggregates exceeding 100 nm increased endothelial adhesion only modestly 6. A similar inverse correlation was also observed for Aβ_1–40 stimulation of endothelial permeability 7. Thus, it was speculated that the differential effect of BSA on the physiological activity of Aβ_1–40 aggregate preparations might be related to differences in the resulting aggregate size.

DLS was employed to evaluate R_H for aggregates formed in the presence and absence of BSA as well as BSA subjected to aggregation conditions in the absence of Aβ_1–40 monomer. Aβ_1–40 monomer incubated in the absence of BSA yielded aggregates with an R_H of 140 nm (Figure 4B) that produced, as expected, a moderate but pronounced increase in endothelial adhesion (Figure 3). While addition of BSA at a concentration 2-fold in excess of Aβ_1–40 monomer yielded less aggregated peptide (Figure 1), these aggregates exhibited a smaller R_H of 34 nm (Figure 4C) and were thus capable of eliciting higher physiological activity (Figure 3). In contrast, Aβ_1–40 aggregations performed in the presence of a 4-fold excess of BSA yielded little aggregated peptide (Figure 1) and exhibited a hydrodynamic radius of 3.4 nm (Figure 4D). This peak may be ascribed to BSA, as an identical peak was observed when BSA was subjected to aggregation conditions in the absence of Aβ_1–40 monomer (Figure 4A). Due to the exponential relationship between scattered light and aggregate size, this BSA peak would obscure detection of Aβ monomer or aggregates exhibiting R_H smaller than 3.4 nm. Thus, it may be deduced that following aggregation in the presence of a 4-fold excess of BSA, Aβ_1–40 exists primarily as monomeric or oligomeric structures. However, a lower intensity peak at 22 nm (Figure 4D) indicates the presence of a small population of soluble aggregates with high physiological activity, which likely accounts for the modest increase in adhesion observed for this Aβ_1–40 aggregate preparation (Figure 3). Together, these results demonstrate that the enhanced physiological activity observed for partially inhibited monomer aggregations correlates with an increase in the population of small soluble Aβ_1–40 aggregates.