Background
Alzheimer’s disease (AD) is a chronic neurodegenerative disease characterized, among other neuropathological features, by the accumulation, aggregation and deposition of beta-amyloid peptides (Aβ peptides) in the brain[
1,
2]. Aβ peptides form oligomers, aggregates and plaques which are thought to contribute to synaptic dysfunction, neuroinflammation and neurodegenerative pathology in Alzheimer’s disease[
1‐
4].
Mechanistic studies have generated a substantial body of evidence that brain accumulation of Aβ peptides is not solely due to their increased production in the brain, but also to reduced brain clearance and/or increased uptake from peripheral circulation[
5,
6]. Both latter processes are controlled by the polarized blood-brain barrier (BBB) receptors and transporters[
7‐
10]. Blood-borne Aβ is taken up into the brain by the luminally-expressed endothelial receptor for advanced glycation end-products (RAGE)[
11,
12], whereas its brain efflux/clearance is largely mediated by the abluminal low-density lipoprotein receptor-related protein 1 (LRP1)[
5,
6,
13,
14]. A soluble form of LRP1 (sLRP1) is the major endogenous peripheral Aβ 'sink' that sequesters some 70 to 90% of plasma Aβ peptides[
5]. Recent evidence also implicated key ABC family BBB transporters in Aβ trafficking between brain and circulatory compartments; luminal efflux transporter ABCG2 has been shown to prevent blood-borne Aβ from entry into the brain[
8,
15,
16], whereas BBB P-glycoprotein/ABCB1's role in the brain clearance of Aβ has been demonstrated in both
in vitro and transgenic AD models[
16‐
20]. It is important to note that shuttling of Aβ across the BBB occurs by receptor/transporter-mediated processes that require the intact tertiary structure of the peptide that interacts with the carrier receptor(s).
Aβ brain intake and brain clearance have been studied using radioisotope-labeled Aβ peptides injected systemically or stereotactically into the brain, and by monitoring their appearance in various compartments, including cerebral spinal fluid (CSF)[
21]. A molecular imaging tracer, [
11C]-Pittsburgh compound B (PiB), which binds to Aβ plaques, has been used in small-animal and human PET (positron-emission tomography) imaging studies to monitor Aβ plaque load and its clearance in response to treatment[
22]. The purpose of this study protocol is to demonstrate the utility of a simple and accessible
in vivo optical imaging method for studying Aβ trafficking across the BBB in experimental animals in a dynamic, prospective fashion not achievable with radioactive tracers. Using this method, we demonstrated differences in Aβ trafficking across the BBB in animals deficient in two major ABC efflux pumps, mdr-1 P-glycoprotein/Abcb1 and Abcg2.
Methods and design
Materials
Synthetic human Aβ1-40 and scrambled Aβ40-1 peptides were purchased from Biopeptides Co., Inc (San Diego, CA, USA). Cy5.5 labeling kits (Cy5.5™ Mono NHS ester) and ECL Plus reagent kits were purchased from Amersham Biosciences/GE Healthcares (Buckinghamshire, UK). A mouse monoclonal anti-Aβ antibody 6E10 was purchased from the Covance Inc (Montreal, QC, Canada), and a goat anti-mouse secondary antibody conjugated with Alexa 568 and a HRP-conjugated donkey anti-mouse IgG antibody were purchased from the Santa Cruz Biotech Inc (Santa Cruz, CA, USA). Fluorescein-labeled lectin, Ulex europeaus agglutinin (UEA-I), was purchased from Vector Laboratories Inc (Burlington, ON, Canada). Fetal bovine serum (FBS) was purchased from Hyclone Inc (Logan, Utah, USA). Dulbecco’s phosphate-buffered saline (1X) (PBS) was purchased from GIBCO/Invitrogen (Invitrogen Inc., Grand Island, NY, USA). Autoradiography films were purchased from Mandel Scientific (Guelph, ON, Canada).
Aβ peptides preparation and labeling
Aβ
1-40 peptide used in this study for optical imaging/tracking is the most abundant Aβ peptide found in the cerebral vasculature and is more soluble than Aβ
1-42 peptide. Aβ
1-40 peptides (1 mg/vial) were dissolved in 250 μL of 10 mM NaOH, and then 12.5 μL of 1 M HEPES [4-(2-hydroxyethyl)-1-piperazineethanesulfonic acid] was added to bring the pH to 8.0. The peptides were divided into 2 tubes (0.5 mg/tube) and kept at −80°C. Because Aβ peptides are commonly present as beta sheet structure in solution, Western blot analyses of the mixtures were performed, and the majority of the peptides (>95%) were monomers with a small proportion of dimers (data not shown). Aβ
1-40 or scrambled Aβ
40-1 peptides (0.5 mg, molecular weight 4329.86D) were labeled with the near-infrared fluorescent dye Cy5.5 (molecular weight 1128.42D) using the labeling kit (Cy5.5™ Mono NHS ester) as per manufacturer’s instructions[
8].
Cy5.5 is a monofunctional dye with absorbance at 675 nm, extinction maximum of 250,000 M-1 cm-1, and emission maximum of 694 nm. The functional group commonly used for labelling peptides and proteins is the primary amino group provided by lysine or the N-terminal amino group. The labelling with Cy5.5 NHS ester utilizes acylation reaction at the amino group. The N-terminal amino group and two lysine residues present in both Aβ1-40 and scrambled Aβ40-1 peptides may be accessible to labelling with Cy5.5 dye. Thus, Aβ1-40 peptides can be efficiently labelled with Cy5.5 and then purified free from unincorporated dye for optical imaging. The Cy5.5-labeled peptide can be either injected into the systemic circulation or into the brain to monitor its transport across the BBB.
Aβ peptides (0.5 mg peptide) were added to 40 μL of carbonate buffer (pH 9.1) and 20 μL of Cy5.5 NHS Ester dye (200 μg in DMSO) and incubated in the dark with rotation at room temperature for at least 2 h. The molecular weight of a labeled Aβ peptide is up to 7715 Dalton. The labeled peptides were purified using a column Microcon Ultracel YM-3 (Regenerated cellulose 3000 MWCO, Millipore Corp., Bedford, MA, USA) to remove unincorporated Cy5.5. The amount of labeled peptides was quantified using a BCA Protein Assay kit (Thermo Scientific, Rockford, IL, USA) following the manufacturer’s instructions and the labeling efficiency was determined by the BioTek FL × 800 microplate reader (673 nm for excitation and 692 nm for emission). The labeling efficiency/molar ratio was two-three Cy5.5 molecules per Aβ peptide, and was the same for Aβ1-40 and the scrambled Aβ40-1. The purified Aβ peptides (100 μg in 100 μL) were diluted with 100 μL saline to a final volume of 200 μL and injected intravenously into mice.
Aβ-Cy5.5 conjugate stability in serum
To evaluate Aβ-Cy5.5 conjugate stability in serum, the labeled peptide (5-μL volume containing ~1 μg Aβ) was added to either 35 μL of (non-inactivated) FBS or 35 μL of 1 × PBS (1: 8 dilution) and incubated at 37°C for 0, 0.5, 1, 2, 4, 6, and 8 hours, respectively. The peptides (4 μL) from each of the above reactions (40 μL/reaction) were added to the loading buffer, boiled for 10 min, and resolved on a 16% Tricine-SDS-PAGE as described[
23]. The tricine-SDS-PAGE gel was scanned in the optical imager; the peptides in the gel were then transferred to a PVDF membrane for immuno-blotting[
8]. A mouse monoclonal anti-human Aβ antibody 6E10 (1:1000 dilution) and the secondary HRP-conjugated donkey anti-mouse IgG antibody (1:5000 dilution) were used for immunodetection. ECL plus detection reagents were applied to the blots and the blots were exposed to autoradiography films.
Animals
The experiments with animals have been approved by the Animal Care Committee of the National Research Council of Canada - Ottawa (NRC). Wild-type (wt), mdr-1a/b (Abcb1a/b) knockout (Abcb1KO), and Abcg2-KO mice of FVB background were purchased from the Taconic Farms Inc (New York, USA) and maintained in the NRC Animal Facility at Ottawa. Pairs of adult wild-type mice and Abcb1-KO and pairs of adult wild-type and Abcg2-KO mice of the same body weight and same sex were matched for injections and imaging experiments. After initial testing of fluorescence signal with various injected doses of Cy5.5-labeld Aβ peptides, the optimal dose selected for the experiments was 100 μg of labelled peptide in 200-μL volume. The mice were injected via tail vein with free Cy5.5 dye (~78 μg in 200 μL volume) or Cy5.5-labeled Aβ1-40 (100 μg in 200 μL volume) or Aβ40-1 peptides (100 μg in 200 μL volume) and were imaged in eXplore Optix 670 (GE Healthcare Systems/ART Inc) at different time-points after the injection as described below.
Time-domain in vivo optical imaging
One week before the experiments, animals were placed in cages with bedding that, if ingested, does not produce
in vivo autofluorescence. The animals were anesthetized with inhaled isoflurane (4% for induction and 1.5% for maintenance) and the fur was shaved from the head and dorsal side of the body. The labeled peptides (100 μg) or Cy5.5 free dye (~78 μg) were injected intravenously (i.v.) via the tail vein. The animals were imaged at 2, 4, 6, and 8 h post-injection using the time-domain optical imager eXplore Optix 670 (GE Healthcare Systems/ART Inc). The imaging protocols were described in detail previously[
8,
24‐
27].
Briefly, each animal was positioned on a platform (dorsal side facing up) that was then placed on a heated plate (at 36°C) in the imaging system. The whole-body scan or selected region of interest (ROI) scan (i.e., head) was performed as described[
25,
27]. In all imaging experiments, a 670-nm pulsed laser diode with a repetition frequency of 80 MHz and a time resolution of 12 ps was used for excitation. The fluorescence emission at 700 nm was collected by a highly sensitive photomultiplier tube offset by 3 mm for diffuse optical topography reconstruction. The optical imager uses a Time-Correlated Single Photon Counting (TCSPC) detection system coupled with a pulsed laser source. Images are built point per point in a raster scan fashion. The combination of a raster-scanning approach with a pulsed laser excitation reduces background and allows for depth probing. A pulsed light source and time-resolved detection allows the system to resolve the nanosecond timescale of fluorescence emission. Each scanned point acquired with the system contains a photon time-of-flight distribution (also called a Temporal Point Spread Function or TPSF). Laser power and counting time per pixel were optimized at 60 mW and 0.5 seconds, respectively. The values remained constant during the entire experiment. The raster scan interval was 1.5 mm and was held constant during the acquisition of each frame, and 1,024 points were scanned for each ROI. The data were thus recorded as TPSF and the images were reconstructed as fluorescence concentration maps. Average fluorescence concentration data from ROI placed around the heads were subsequently analyzed using the software ART Optix Optiview (ART Inc., Montreal, QC, Canada). The software normalizes all images obtained in the same experimental run (i.e., paired animals, same injected solution) to the same fluorescent scale (expressed in arbitrary units). After the last scan, the mice were cardiac-punctured and then perfused transcardially with 50-mL cold saline with a peristaltic ISMATECH pump (IDEX Health & Science GmbH. Germany) at 5 mL/min for 10 min to wash out the remaining blood and circulating fluorescence. Brains were then extracted and scanned
ex-
vivo for fluorescence concentration
Immunohistochemistry
To demonstrate the presence of Aβ peptides in the brain, the brains extracted at the end of the imaging protocol were frozen-sectioned at 10 μm and immunostained with a mouse monoclonal anti-human Aβ antibody 6E10 and a goat anti-mouse secondary antibody conjugated with Alexa 568 as described[
3,
4,
8]. The sections were also counter-stained with fluorescein-labeled lectin,
Ulex europeaus agglutinin (UEA-I), as described[
28] to visualize cerebral vessels.
Statistical analysis
The fluorescent concentrations in mouse brains were compared by one-way ANOVA followed by Newman-Keuls post-hoc test.
Discussion
This study describes the application of prospective in vivo optical imaging protocols to study brain accumulation of systemically injected Aβ peptides in wild-type and animals deficient in specific transporters previously implicated in Aβ transport across the blood-brain barrier.
Radio-labeled [
125I]-or [
3H]-Aβ peptides have been used to study their BBB transport in animal models. The labelled peptides are either injected intravenously to analyze brain uptake or intra-cerebrally to investigate their clearance from the brain; animals are sacrificed at different time points and the radioactivity is determined in desired compartments.
In vivo molecular imaging approaches that ‘track’ Aβ peptides non-invasively are dynamic methods that can be used for assessing Aβ levels in response to treatments. Notably, PET imaging with [C
11]-PiB [
N-methyl-[11C]2-(4-methylaminophenyl)-6-hydroxybenzothiazole] has been used for quantitative assessment of brain Aβ load in Alzheimer’s patients[
34] and in APP/PS1 mouse[
22]. Apart from requiring ‘on-site’ radioisotope labeling and access to expensive PET equipment, this approach is not applicable for ‘tracking’ peripheral Aβ peptides. Optical molecular imaging/tracking of Aβ peptides functionalized with the near-infrared imaging tracer is a viable alternative that can provide high sensitivity in experimental setting, although it does not have the quantification capabilities of PET. Among
in vivo optical imaging systems, time-domain optical imaging has a clear advantage over Continuous Wavelength (CW) systems in that its pulsed laser source can penetrate skull to excite the fluorescent tracer in deep tissues. In contrast to CW systems where emitted light is collected by a CCD camera that cannot resolve the depth of the signal, with time-resolved imaging platform each collected photon retains time-of-flight distribution (also called a Temporal Point Spread Function or TPSF) from which depth (optical tomography), fluorescence concentration and fluorescence lifetime can be extracted[
24‐
27]. This and other studies[
35,
36] have shown that this imaging method is a useful non-invasive approach to investigate Aβ transport, distribution, and clearance from the brain that complements other imaging approaches.
The aberrant transport and clearance of Aβ peptides across the BBB, mediated by a spectrum of receptors and transporters including RAGE, LRP-1, and members of ABC family, contributes to Aβ accumulation in the brain and in the cerebral vasculature[
7,
37,
38]. ABC family members MDR-1 P-glycoprotein/ABCB1 and ABCG2/BCRP are two major drug efflux transporters located at the luminal surface of the BBB[
39,
40]. In mice, mdr-1a (Abcb1a) is the primary drug efflux transporter expressed at the BBB; while mdr-1b (Abcb1b) is the main isoform detected in the brain parenchyma[
41]. Murine mdr-1 P-glycoprotein is encoded by both
mdr-
1a (
Abcb1a) and
mdr-
1b (
Abcb1b), which share 90% sequence homology and have 80% homology to human
MDR1 (
ABCB1). The mdr-1a/b (Abcb1a/b) double knockout completely eliminates mdr-1-mediated transport activity at the BBB. Several published studies[
8,
15‐
20] presented the evidence that inhibition or deficiency of Abcg2 or mdr-1 P-glycoprotein increases Aβ intake in cell models and reduces brain Aβ clearance in animal models.
To further evaluate the roles of Abcb1 and Abcg2 in Aβ trafficking across the BBB, we developed the non-invasive optical imaging method for ‘tracking’ systemically injected fluorescently-labeled Aβ peptides in Abcb1
-KO and Abcg2
-KO mice. For the purpose of
in vivo tracking Aβ peptides were conjugated to the near-infrared optical fluorescence tracer Cy5.5. Since Aβ degrading proteases including insulin degrading enzyme (IDE), angiotensin converting enzyme (ACE) and neprilysin[
42,
43] are active in the blood and can contribute to Aβ degradation, the stability of Cy5.5-Aβ conjugates in serum over 8 hours was confirmed
ex-
vivo, proving that the optical signal in imaging experiments originated predominantly from intact Cy5.5-Aβ conjugates. Imaging assessment of the whole-body biodistribution and elimination kinetics of Cy5.5-Aβ peptides, demonstrated similar elimination kinetics in wild-type and KO animals; the majority of peripheral tracer was eliminated by 2–4 h after the injection. This is in agreement with previous studies that reported the circulation half-life of injected [
125I]-Aβ peptides of about 35–45 min; ~81% of the injected Aβ was cleared from blood by 60 min after administration in adult monkey[
32,
33,
44].
Head ROI imaging protocols were initiated 2 hours after tracer injection, allowing 3–4 circulation half-lives; therefore, measured head fluorescence concentration was primarily indicative of the brain-accumulated/retained tracer, with small contribution of circulating tracer. In both Abcb1
-KO and Abcg2
-KO animals, brain tracer concentration was higher than in the wild-type animals at 2 hours, suggesting that any of the following processes or their combination might have been altered in knockout animals: a) the rate of Aβ brain influx was increased; b) the rate of Aβ brain elimination was slower; and c) Aβ binding/uptake into brain vessels was increased. Based on the current data, we cannot exclude any of these processes being responsible for the observed tracer concentration differences at 2 hours after injection. However, given the relatively short circulation half-life of Aβ, we can assume that imaging measurements between 2 and 8 hours after injection reflect predominantly brain elimination kinetics of Aβ. Brain-injected [
125I]-Aβ
1-40 peptide has been shown to clear rapidly via receptor-mediated transport with
t1/2 of 25 minutes[
45]. A single photon emission computed tomography (SPECT) study in squirrel monkeys[
46], demonstrated a bi-phasic brain clearance of intracerebrally microinfused [
123I]-Aβ
1-40, with short t
1/2 ranging from 1.1 ~ 2.7 hours and accompanying plasma appearance of [
123I]-Aβ
1-40, suggesting active brain-to-blood transport. Comparisons of Aβ fluorescence decay curves between 2 and 8 h in wild-type and ABC-transporter knock-out animals indicated similar fluorescence decay (elimination) kinetics within the range of clearance rates described by Bading
et al[
46]. Due to limited number of imaging time-points and the study design, it was not possible to discern whether the observed elimination kinetics of Aβ are due to active reverse transport across the BBB or to the interstitial fluid bulk-flow clearance.
Whereas lack of Abcg2 in this study did not appear to affect the rate of Aβ elimination from the brain, it resulted in higher initial accumulation of injected Aβ, suggesting that it has a role in either limiting brain access of circulating Aβ or mediating fast brain elimination phase of Aβ, or both. In agreement with our observations, a recent study[
15] using the
in situ brain perfusion technique showed that GF120918, a dual inhibitor of Abcb1 and Abcg2, strongly enhanced the uptake of [
3H]-Aβ
1-40 in the brains of Abcb1-deficient mice, but not in the brains of Abcb1/Abcg2-deficient mice. ABCG2 is up-regulated in human AD brain with cerebral amyloid angiopathy (CAA)[
8] where it modulates Aβ-induced vascular oxidative stress[
33,
47].
Similarly, the deficiency of mdr-1/P-glcoprotein significantly increased brain accumulation of systemically injected Aβ but also slightly accelerated its elimination from the brain. This observation is consistent with some previously reported studies. Deposition of Aβ peptides has been found to inversely correlate with MDR-1 P-glycoprotein/ABCB1 expression in the brains of elderly non-demented humans as well as in the brains of Alzheimer’s patients[
37,
48,
49]. In addition, Aβ was found to down-regulate BBB mdr-1 P-glycoprotein (Abcb1) expression in mice[
50]. Cirrito and colleagues[
17] demonstrated that Aβ removal from the brain was partially mdr-1-dependent in mdr-1a/b KO mice. Furthermore, restoration of mdr-1 P-glycoprotein/Abcb1 at the BBB by PXR (Pregnane X Receptor) agonist reduced brain Aβ load in a mouse model of Alzheimer's disease[
18].
The definitive interpretation of data provided in this study is confounded by possible activation of compensatory mechanisms in knock-out animals. For example, the Abcb1/P-glycoprotein-null mice were found to have lower brain expression of LRP-1 compared to wild-type mice[
17]. We found no compensatory changes in Abcb1a/mdr-1a and Abcb1b/mdr-1b expression in the brains of Abcg2
-KO mice (data not shown); however, we cannot ascertain whether other Aβ transporters (i.e., RAGE, LRPs) were specifically affected in brain endothelial cells in Abcb1- or Abcg2
-KO animals.
Pharmacological studies using selective inhibitors of BBB transporters in cell systems[
15,
20] provided strong evidence that both ABCB1/MDR-1 P-glycoprotein and ABCG2 have the capacity to interact with and shuttle Aβ across cellular membranes.
In vivo imaging studies, including ours presented here, support this notion and provide means for dynamic analyses of integrative influences of BBB transporters on Aβ trafficking in and out of the brain.
In summary, this study protocol describes potential application of time-domain prospective
in vivo imaging in assessing BBB trafficking of systemically injected compounds, including Aβ peptides, labeled with near-infrared fluorescent imaging tracers. The protocol is particularly useful in assessing BBB trafficking of such compounds in animals exhibiting modifications of various BBB transporters, such as for example gene knock-out or over-expression of ABC-family of efflux pumps. Similarly, this imaging method can be used to evaluate kinetics of brain elimination of intra-cerebrally-injected compounds as recently described in our study on FcRn-mediated brain elimination of fluorescently-labeled macromolecules[
51].
Competing interests
The authors declare that they have no competing interests.
Authors’ contributions
WZ conceived and designed the experiments, performed data analyses and prepared the figures, wrote and revised the manuscript. HX carried out most of the experiments and analyzed the data. AJ and KP assisted HX in performing the experiments. DC conducted brain tissue sections and IHC. HL and EB conducted in vitro Aβ stability assay. DF prepared and analyzed some of optical images. DS conceived the project and contributed to data analyses, figure preparation, writing and revising the manuscript. All authors have read and approved the final version of the manuscript.