Background
Atherosclerosis is a leading cause of morbidity and mortality worldwide [
1]. Despite substantial advances in understanding and treatment of conventional risk factors, the prevalence of diseases associated with atherosclerosis keeps growing. It remains clinically challenging to identify asymptomatic individuals at high risk for developing acute complications of atherosclerosis. A main focus has therefore been assigned to develop non-invasive imaging approaches for plaque characterization. Radioisotope-based molecular imaging has emerged at the forefront of methods for identifying biological aspects of atherosclerotic plaques and assessing hallmarks involved in plaque vulnerability, which are not possible to capture with morphometric imaging. However, the selection of a suitable molecular target in rupture-prone plaques remains a major challenge with this approach [
2].
Monocyte-derived macrophages are the first inflammatory cells to invade atherosclerotic lesions and are recognized as key pathophysiologic agents in atherosclerosis [
3‐
5]. They are involved at multiple stages of plaque development and are therefore increasingly gaining importance as imaging targets in atherosclerosis. However, macrophages are a heterogeneous population of cells, and different subsets could be either pro- or anti-atherosclerotic [
6,
7]. Distinct macrophage phenotypes can be assessed by the expression of different surface biomarkers and chemokine receptors [
6‐
11].
Certain macrophage subtypes express carbohydrate-binding receptors, e.g., mannose receptor (MR, CD206) [
6,
7], which is a highly effective endocytic C-type lectin receptor (175 kDa). High expression of MR was reported on macrophages located in the fibrous cap of plaques, whereas apoptotic macrophages of the lipid core have shown only low expression [
12]. Therefore, effective targeting of macrophages using MR-specific radioconjugates is a potential approach for imaging atherosclerotic plaques.
Recently, nanobodies (Nbs) against macrophage mannose receptor (MMR) have been developed, and their potential as in vivo diagnostic tracers for non-invasive imaging a subpopulation of tumour-infiltrating macrophages [
13,
14] and joint inflammation in rheumatoid arthritis [
15] have been well documented.
Nbs, which are derived from camelid heavy chain-only antibodies, are the smallest available antigen-binding fragments [
16]. Their small size (~ 15 kDa) is favourable for rapid localization at the target tissue and clearance from circulation via kidneys, which results in high target-to-background signal ratios in a short time [
16]. Consequently, imaging with Nb-based radioconjugates can be carried out as early as 1 h post-injection (p.i.), enabling the use of short-lived radioisotopes, e.g., Gallium-68 (
68Ga).
In the present study, our objective was to evaluate the potential of 68Ga-NOTA-anti-MMR Nb for selectively targeting MR-positive (MR+) macrophages and non-invasively imaging atherosclerotic plaques. This approach might pave the way for better understanding the role of MR+ macrophages in plaque progression and rupture in patients. After investigating the in vivo biodistribution and specificity of 68Ga-NOTA-anti-MMR Nb in wildtype mice, a thorough assessment as a tracer for non-invasive in vivo nuclear molecular imaging of atherosclerotic lesions was performed in apolipoprotein E-knockout (ApoE-KO) mice.
Methods
Animal model
For biodistribution and in vivo specificity studies, female C57BL/6 mice (5 weeks old, 18–21 g weight, from Charles River Laboratories) referred to as wildtype were used. Adult ApoE-KO mice (Apoetm1Unc, female, 28 weeks old, 28–32 g weight, from Jackson laboratory) were used for in vivo and ex vivo imaging studies. ApoE-KO mice were on high fat diet (42% calories from fat, E 15721-347 from ssniff Spezialdiäten GmbH) for 20 weeks. Age-matched female C57BL/6 mice were used as controls. Control mice were fed a normal chow diet.
Preparation of the radiotracer
The anti-MMR Nb 3.49, cross-reactive for both the mouse (K
D = 12 nM) and human (K
D = 1.8 nM) homologue of MR [
14], was conjugated with the bifunctional chelator 2-S-(4-isothiocyanatobenzyl)-1,4,7-triazacyclononane-N,N′,N″-triacetic acid (p-SCN-Bn-NOTA, Macrocyclics) as described elsewhere [
17]. A solution of NOTA-anti-MMR Nb was labelled with
68Ga at room temperature. Briefly, 25 μl (55.25 μg) of NOTA-anti-MMR Nb solution was incubated with 2.275 ml (~ 400 MBq) of
68Ga eluate (in 0.05 M HCl) and 200 μl of sodium acetate buffer (2 M, pH 5) for 15 min. Radiochemical purity (RCP) of the tracer was determined by radio-instant thin layer chromatography (radio-ITLC) using 0.1 M sodium citrate (pH 5) as the mobile phase.
For further animal studies, the radiotracer was purified using a PD-10 column (GE Healthcare) preconditioned with 25 ml of phosphate-buffered saline (PBS).
In vitro binding specificity assay
Fresh peripheral blood mononuclear cells (PBMC) were isolated from healthy human donor blood using standard Ficoll-Paque density-gradient (Amersham Biosciences). CD14-positive monocytes were isolated from PBMCs using positive selection technology (MACS technology; Miltenyi Biotec). Isolated cells were plated in 12-well dishes (106 cells/dish) for attachment using Monocyte Attachment Medium, according to the manufacturer’s protocol (C28051, PromoCell). Subsequent differentiation was performed by incubating the cells with M1 or M2-Macrophage Generation Medium DXF (C-28055 or C-28056, PromoCell). M1-activation of macrophages was achieved by addition of IFN-ɣ (50 ng/ml, C-60724, PromoCell) and LPS (100 ng/ml, Sigma-Aldrich), and M2a-activation of M2-macrophages was achieved by addition of 20 ng/ml IL-4 stimulatory factor, according to manufacturer’s protocol (C-61420A, PromoKine). Differentiated cells were incubated with 10 nM 68Ga-NOTA-anti-MMR Nb for 30 min at room temperature in order to avoid receptor internalization. One set of M2a dishes was co-incubated with a 1000-fold excess amount of non-labelled NOTA-anti-MMR Nb referred as M2a-blocked. After incubation, media were removed from cell dishes. Cells were washed and detached using Macrophage Detachment Solution DXF (C-41330, PromoCell). Cell solutions were transferred into fraction tubes. A fraction of cell suspensions was used for cell counting. The radioactivity of the remaining cells was measured in an automated gamma counter (PerkinElmer 2480 WIZARD2). The uptake was calculated as cell-associated radioactivity.
Biodistribution and in vivo binding specificity studies
Two groups (n = 5 per group) of wildtype mice were injected intravenously (i.v.) with 8–10 MBq of 68Ga-NOTA-anti-MMR Nb (3–4 μg) to assess blood clearance and overall biodistribution of the tracer. One group was co-injected with a 100-fold excess amount of non-labelled NOTA-anti-MMR Nb and are referred to as the blocked group. The mice were sacrificed by a high dose of Pentobarbital (Narcoren) 1 h p.i. Blood was collected by heart puncture and organs and tissues were excised. The samples were put in pre-weighed plastic vials. The samples were weighed, and their radioactivity was measured in the gamma counter against a standard of known activity. The uptake in tissue and organs was calculated as percentage of injected activity per gram of tissue (% IA/g) corrected for decay. For the gastrointestinal tract and the carcass, percentage of injected activity per gram of whole sample was calculated (% IA/g).
In vivo imaging (PET/CT study)
Two groups of mice, ApoE-KO (n = 15) and control (n = 6), were used for in vivo and ex vivo imaging studies. Mice were kept fully sedated with 1.5–2% isoflurane during injections and PET/CT imaging. Images were acquired using the Inveon small animal PET/CT scanner (Siemens, Knoxville, TN, USA) 1 h after i.v. injection of 68Ga-NOTA-anti-MMR Nb (8–10 MBq, 3–4 μg). Briefly, CT anatomic images were acquired (80 kV, 500 μA) with a pixel size of 0.1 mm. After CT imaging, static PET images were acquired with an acquisition time of 20 min. Images were reconstructed as single frames using Siemens Inveon software, employing a 3-dimensional ordered subsets expectation maximum algorithm (OSEM3D) without scatter and attenuation correction. A group of ApoE-KO mice (n = 4), referred to as the ApoE-KO blocked group, was co-injected with blocking dose (100-fold excess) of non-labelled NOTA-anti-MMR Nb. For quantification of vascular uptake, circular regions of interest (ROIs) were placed on axial PET/CT images of the thoracic and abdominal aortas and signal intensities were recorded as kBq/cc. ROIs were identified by the same person with their centres at the point of local maximum 68Ga-NOTA-anti-MMR Nb uptake.
Ex vivo imaging (autoradiography and Sudan-IV staining)
After PET/CT scans, mice were euthanized with an overdose of isoflurane. The whole length of the aortas (from the sinotubular junction to the iliac bifurcation) was excised using a dissection microscope (Zeiss Stemi DV4 SPOT) [
18]. The radioactivity of the dissected aortic tissues was measured in the gamma counter. After radioactivity measurements, the adventitial tissue on the aortas was removed by careful dissection. The aortas of ApoE-KO non-blocked (
n = 9), ApoE-KO blocked (
n = 4) and control (
n = 4) mice were kept intact and longitudinally exposed to phosphor imaging plates (Fuji Imaging Plate, Fujifilm). Radioactivity signals were collected for 1 h. The imaging plates were scanned, autoradiographs were obtained with a phosphor imaging system (Raytest, Straubenhardt, Germany) and images were analysed for count densities. ROIs were placed on the whole aorta to measure total quantum level (QL) units contained in that area. In addition, ROIs were placed over normal aortic tissue to calculate signal intensities per unit area (QL/mm
2) of normal aortic tissue.
After autoradiography, aortas were opened longitudinally, mounted en face on a black wax surface to expose the luminal side and stained with Sudan-IV for neutral lipids using a previously published method [
18]. The images of en face stained aortas were used to measure the whole aorta and lesional surface areas. Briefly, the outer border of the whole aortas as well as each Sudan-IV stained plaque surface was encircled manually and their areas (mm
2) were measured using the public domain software ImageJ (National Institutes of Health (NIH), USA) [
18]. Data were used to calculate autoradiographic signal intensity (QL/mm
2) in the whole aorta, in normal aortic tissue and in plaques.
Immunofluorescence staining and confocal microscopy
For immunofluorescence staining, 10-μm-thick cross-sections were prepared from excised aortas of ApoE-KO (
n = 2) and control (
n = 2) mice. Parallel sections were immunostained as previously described [
19]. Briefly, slides were fixed with acetone, rehydrated in PBS, blocked with 10% donkey serum and incubated for 3 h with primary antibodies diluted with 2.5% bovine serum albumin (BSA). Primary antibodies include rat anti-mouse CD68 (clone FA-11, Bio-Rad) for macrophages and goat anti-mouse CD206 antibody (clone MR5D3, Bio-Rad) for MR. Corresponding secondary antibodies were conjugated with Alexa 488 and Cy5. DAPI was used to stain DNA. For negative controls, staining was performed without primary antibodies. Stained sections were analysed using a SP8 confocal laser scanning microscope (Leica, Mannheim, Germany).
Statistics
Data are expressed as mean ± standard deviation. The Mann-Whitney U test was used to compare the variables. A p value ≤ 0.05 was considered significant. Statistical analysis was done using SPSS Statistics software (version 24.0.0, IBM Company, Chicago, IL, USA).
Discussion
The macrophage population of atherosclerotic plaques is heterogeneous. Beside previously reported M1 and M2 macrophages, the presence of unique macrophage phenotypes has also been demonstrated in atherosclerotic lesions [
6,
7]. MR
+ macrophages were first reported by Bouhlel et al. in human carotid plaques [
22]. Based on recent findings representing predominant expression of MR in fibrous cap of atherosclerotic plaques [
23,
24], MR has been proposed as a potential target biomarker to identify culprit lesions. However, the exact role of alternative macrophages in atherosclerosis and their contribution to plaque vulnerability is still a matter of debate [
25,
26].
Chinetti-Gbaguidi et al. have reported that IL-4-polarized CD68
+MR
+ macrophages express high levels of receptors involved in phagocytosis but show low capacity to ingest native and oxidized lipoproteins in vitro. The ability of these macrophage populations to clear apoptotic cells without accumulating lipids suggests that they may have beneficial roles in stabilizing atherosclerotic lesions [
12]. On the other hand, the presence of M2 (CD68
+CD163
+) but not M1 macrophages in the fibrous cap near the rupture site of the asymptomatic thrombotic plaques in human carotid artery was reported by Mauriello et al., suggesting that alternative macrophages might also modulate the process of plaque rupture [
27]. A high density of MR
+ macrophages was also reported by Tahara et al. in high-risk plaques obtained from subjects who had experienced sudden cardiac death [
28]. Furthermore, matrix metalloproteinase-9 (MMP-9, which is the most dominantly present MMP in atherosclerotic plaques) is produced by M2 rather than M1 macrophages [
29,
30]. It has been reported that the rupture of carotid plaques is significantly associated with MMP-9 expression in the lesions [
31]
. As MMP-9 is capable of degrading type IV collagen [
32] and triggering plaque rupture, the M2 macrophage phenotype may have a predominant role in plaque instability. In addition, the recently described MR
+ M4 macrophages were reported to have potential pro-atherogenic roles in vulnerable plaques. They produce MMP12, an enzyme which may also be involved in the degradation of fibrous caps and hence the destabilization of atherosclerotic lesions [
33‐
35]. Motivated by the above mentioned findings, we aimed to investigate the feasibility of imaging MR expression in atherosclerotic lesions of a murine model using radiolabelled anti-MMR Nb-based radiotracers.
In the previous study, we were not able to evaluate the relevance of the technetium-99m (
99mTc)-labelled anti-MMR3.49 Nb for atherosclerosis and no positive correlation was found between plaque burden and
99mTc-anti-MMR3.49 Nb uptake. As confirmed by immunofluorescence staining, the absence of
99mTc-anti-MMR3.49 Nb uptake in the plaques corroborated with the absence of MR expression in the lesions [
36]. However, we warned for MR expression in the adventitial tissue. In the current study, however, the presence of MR
+ macrophages, which were mainly located in the fibrous cap and in the shoulder regions of the atherosclerotic plaques, was confirmed by immunofluorescence staining. Corroborating with our previous observation, remarkable MR expression was observed in the adventitia of the aortas isolated from both ApoE-KO and control mice. The presence of macrophages in the adventitia of normal arteries has previously been reported [
10,
24]. The adventitia underlying atherosclerotic plaques showed more MR expression compared to plaque-free areas of aorta segments isolated from ApoE-KO and control mice, which could be explained by the presence of adventitial cellular infiltration related to atheroma [
9,
37]. Compared to
99mTc, the short half-life of the
68Ga matches better with the fast blood clearance and target localization of the anti-MMR Nb. In addition, because of its inherently higher sensitivity and considerably better spatial resolution, PET may improve the imaging of atherosclerotic lesions compared with SPECT.
Despite the small dimension of the lesions, they were successfully visualized in the aortas of ApoE-KO mice using a small animal PET/CT scanner, 1 h p.i. of 68Ga-NOTA-anti-MMR Nb. In order to evaluate the specific signal from MR expression in the atherosclerotic plaques, the adventitial tissue on the aortas was removed by careful dissection for ex vivo autoradiography studies. The tracer uptake on ex vivo autoradiographic images was co-localized with Sudan-IV-positive areas corresponding to atherosclerotic plaques. Since the extent of atherosclerosis affecting the intimal surface along the aortas was not the same in all animals, the autoradiographic signals were normalized to the area of plaques, measured after Sudan-IV staining.
MR has been adopted as a biomarker to identify rupture-prone atherosclerotic plaques, and different targeted nuclear imaging probes have been developed with the aim of visualizing MR expression in the lesions. The feasibility of
18F-labelled D-mannose (2-deoxy-2-[
18F]fluoro-d-mannose,
18F-FDM) for imaging of atherosclerotic lesions was reported by Tahara et al. [
28]. They demonstrated that
18F-FDM uptake is not inferior to that of
18F-FDG for imaging of plaque inflammation [
28]. The
68Ga-labelled NOTA-coupled mannosylated human serum albumin was reported by Kim et al. as a radiotracer for non-invasive detection of M2 macrophages in vulnerable atherosclerotic plaques [
38]. Recently, we demonstrated the feasibility of
111In-tilmanocept for non-invasive in vivo targeting of plaque inflammation in ApoE-KO mouse model [
39]. Although the success of these radiotracers for in vivo visualization of atherosclerotic plaques has been well documented—due to the fact that mannose is an isomer of glucose,
18F-FDM as well as other above mentioned mannosylated radiotracers may be taken up by all macrophages (similarly to
18F-FDG) and thus may be unsuitable for discrimination between different phenotypes. In the present study, however, our objective was to assess the potential of an anti-MMR Nb for specific targeting of MR
+ macrophages and in vivo imaging of atherosclerotic plaques in ApoE-KO mice.
Radiotracers based on anti-MMR Nbs have been well evaluated for imaging tumour-infiltrating macrophages [
13,
14] and joint inflammation in rheumatoid arthritis animal models [
15]. The specificity of the tracers to MR has also been confirmed in MR-KO mice [
13,
14].
68Ga-NOTA-anti-MMR Nb has also been thoroughly investigated in a rabbit model of atherosclerosis [
40]. Using a clinical PET/MR scanner, a gradual increase in signal intensity was observed in the aortas of atherosclerotic rabbits as disease progressed, confirming translatability to other animal species.
This study has some limitations. Regardless of its sufficient expression by macrophages located in atherosclerotic plaques for in vivo imaging, MR is also expressed by some cells in adventitia which causes a non-negligible background signal when using 68Ga-NOTA-anti-MMR Nb. The presence of MR+ cells in several abdominal area organs might also have hampered the in vivo detection of radiotracer uptake in the abdominal aorta, due to the small size of the mouse body. Although we were able to evaluate the relevance of MR targeting with 68Ga-NOTA-anti-MMR Nb in ApoE-KO mouse model of atherosclerosis, whether 68Ga-NOTA-anti-MMR Nb also accumulates in complex human atherosclerotic plaques needs to be validated in future studies.