Abstract
OBJECTIVES
The purpose of this study was to evaluate the feasibility of noninvasive imaging of angiotensin II (AT) receptor upregulation in a mouse model of post-myocardial infarction (MI) heart failure (HF).
BACKGROUND
Circulating AT levels do not reflect the status of upregulation of renin-angiotensin axis in the myocardium, which plays a central role in ventricular remodeling and evolution of HF after MI. Appropriately labeled AT or AT receptor blocking agents should be able to specifically target AT receptors by molecular imaging techniques.
METHODS
AT receptor imaging was performed in 29 mice at various time points after permanent coronary artery ligation or in controls using a fluoresceinated angiotensin peptide analog (APA) and radiolabeled losartan. The APA was used in 19 animals for intravital fluorescence microscopy on a beating mouse heart. Tc-99m losartan was used for in vivo radionuclide imaging and quantitative assessment of AT receptor expression in 10 mice. After imaging, hearts were harvested for pathological characterization using confocal and 2-photon microscopy.
RESULTS
No or little APA uptake was observed in control animals or within infarct regions on days 0 and 1. Distinct uptake occurred in the infarct area at 1 to 12 weeks after MI; the uptake was at maximum at 3 weeks and reduced markedly at 12 weeks after MI. Ultrasonographic examination demonstrated left ventricular remodeling, and pathologic characterization revealed localization of the APA tracer with collagen-producing myofibroblasts. Tc-99m losartan uptake in the infarct region (0.524 ± 0.212% injected dose/g) increased 2.4-fold as compared to uptake in the control animals (0.215 ± 0.129%; p < 0.05).
CONCLUSIONS
The present study demonstrates the feasibility of in vivo molecular imaging of AT receptors in the remodeling myocardium. Noninvasive imaging studies aimed at AT receptor expression could play a role in identification of subjects likely to develop heart failure. In addition, such a strategy could allow for optimization of anti-angiotensin therapy in patients after MI.
It is well established that myocardial, more so than the systemic neurohumoral upregulation, contributes to ventricular remodeling and development of heart failure (HF) after myocardial infarction (MI) (1). In particular, myocardial angiotensin II (AT) type-1 receptor expression is associated with interstitial fibrosis and ventricular dysfunction (2). Transgenic mice with deficient AT type-1 receptor expression exhibit minimal geometric and structural remodeling following MI, and show lesser upregulation of fetal genes, transforming growth factor beta-1, and collagen deposition in comparison with the wild-type animals (3). Clinical use of angiotensin-converting enzyme (ACE) inhibitors and angiotensin receptor blockers in MI retards ventricular remodeling, delays development of HF, reduces rehospitalization for worsening of HF, and improves survival (4–8).
Because myocardial neurohumoral upregulation is associated with ventricular remodeling, we hypothesized that a novel diagnostic strategy targeted at detecting the extent of myocardial AT receptor expression would allow identification of patients at risk of developing HF. In addition, such a strategy should allow optimization of pharmacologic therapy in HF patients. Because subcellular processes are amenable to noninvasive molecular imaging techniques, we labeled an angiotensin peptide analog (APA) with a fluorescent tracer. The APA targeted both angiotensin type-1 and -2 receptors with high affinity (Ki = 3 pmol/l), and optical imaging was performed to determine the myocardial upregulation of AT receptors after MI in an experimental mouse model. To more specifically target AT type-1 receptors, we also radiolabeled losartan, a commonly used AT type-1 receptor blocker, and performed imaging with micro–single-photon emission computed tomograpy and micro-computed tomography.
METHODS
The present study was performed in 29 mice (Table 1). Of these, 19 mice were studied with fluorescent APA; 16 mice were imaged up to 12 weeks after MI and compared with 3 noninfarcted control animals. For radionuclide imaging, technetium-99m (99mTc) losartan was used in 4 mice 3 weeks after MI and 6 noninfarcted control animals (Table 1). Echocardiography was performed for the assessment of left ventricular (LV) dimensions and function in all mice prior to optical imaging. Optical imaging was performed in open chest preparation. Noninvasive radionuclide imaging was performed on mice by micro-single-photon emission computed tomography (SPECT)/micro-computed tomography (CT) coregistration. All animals were sacrificed after optical or nuclear imaging. The myocardial specimens from animals receiving the fluorescent tracer were characterized histologically by localizing the injected probe with confocal and 2-photon microscopy in frozen samples as well as by hematoxylin and eosin staining of paraffinembedded tissue. Myocardial specimens obtained from animals after nuclear imaging were used to determine quantitative uptake of radiolabeled losartan in the myocardium. All experiments were approved by the Institutional Animal Care and Use Committee at the University of California, Irvine and were conducted in accordance with U.S. guidelines on the humane care and use of research animals.
Table 1.
Optical and Nuclear Imaging Groups and Timeline of Imaging
| Post-MI Mice |
|||||||||
|---|---|---|---|---|---|---|---|---|---|
| Tracer | Probe | Control Mice | 0 days | 1 day | 1 week | 3 weeks | 6 weeks | 12 weeks | Total |
| GFP | APA | 3 | 3 | 3 | 3 | 3 | 3 | 1 | 19 |
| 99mTc | Losartan | 6 | 4 | 10 | |||||
APA = angiotensin peptide analog; GFP = green fluorescent protein; MI = myocardial infarction; 99mTc = technetium-99m.
Synthesis of fluorescein APA for optical imaging
The peptidyl resin H-Arg(Pmc)-Val-Tyr(tBu)-Ile-His(Trt)-Pro-Ile-R was synthesized on an Applied Biosystems 433A peptide synthesizer (Applied Biosystems, Foster City, California) starting with Fmoc-Ile-Wang resin. The N-terminus was bromoacetylated using bromoacetic anhydride. The bromoacetylated peptidyl resin was then treated with N-Boc-ethylenediamine. The simultaneous removal of protecting groups and cleavage of the peptide from the resin was carried out in trifluoroacetic acid. Subsequently, trifluoroacetic acid was removed in vacuo, diethyl ether added to the residue, and the precipitated peptide washed with diethyl ether and dried. The crude peptide, fluorescein N-hydroxysuccinimide ester, and N-methylmorpholine were dissolved in dimethylformamide-affording fluorescein APA (Fig. 1A). The reaction product was purified by preparative reversed-phase high performance liquid chromatography. The pure fluorescein APA was analyzed by analytical high performance liquid chromatography and electrospray mass spectrometry.
Figure 1. Structure of Tracers Used for AT Receptor Targeting.
Fluorescent angiotensin peptide analog (APA) (A), technetium Tc-99m losartan (B). AT = angiotensin II.
Synthesis of chelate-coupled losartan-Leu-Diglycoloyl-PEG(4)-Tetraamine and radiolabeling
The optimal pharmacokinetic profile of an imaging agent differs radically from therapeutic drugs in that rapid excretion from blood is advantageous. Because peptides are particularly better suited for targeting in vivo due to a superior biodistribution profile, we introduced peptide characteristics into the losartan pharmacophore. To facilitate a convenient and rapid synthesis, we adopted a solid phase approach where losartan was immobilized on a trityl resin through its tetrazole group. Further replacement of the hydroxyl group by an amino group enabled attachment of amino acids, linkers, and tetracycline chelates by standard peptide synthesis methods. This strategy did also increase the affinity of losartan for AT type-1 receptors. Structure activity data showed that the introduction of the amino acid leucine and a short linker comprising tetraethylene glycol and diglycolic acid between the losartan moiety and the tetra-amine chelate yielded a losartan analog (Fig. 1B) with superior affinity (Ki = 60 pmol/l) to AT receptors compared with losartan (Ki = 10 nmol/l) and an acceptable biodistribution profile with mainly urinary excretion.
Mouse model of HF
Male Swiss Webster mice (weight 20 to 30 g, Charles River, Wilmington, Massachusetts) were anesthetized with pentobarbital (75 mg/kg by intraperitoneal injection) and intubated with a 21-G tube for mechanical ventilation. The electrocardiogram was monitored continuously, and body temperature was maintained throughout the procedure at 36.5°C. Ventilation was maintained at a 250-μl tidal volume and a respiratory rate of 200 breaths/min (MiniVent HSE-HA, Harvard Apparatus, Holliston, Massachusetts). The heart was exposed through the fourth left intercostal thoracotomy, and the left coronary artery was ligated at its second branching point with a 6-0 Prolene suture. After watching the animal carefully for 30 min, the chest was closed using a 6-0 Monocryl suture. The animals were subjected to optical or radionuclide imaging at various time points in follow-up. Before imaging, anesthetized animals were examined by transthoracic echocardiography using a 14-MHz linear probe (Acuson 15L8, Siemens, Malvern, Pennsylvania). B-mode images of LV parasternal long axis and short axis were obtained and digitally analyzed as described previously (9).
Optical imaging using fluorescent APA
Frozen dried aliquot (100 μg) of the compound was dissolved in 200 μl of distilled water. After cannulation of the internal jugular vein, 50 μg of fluorescent APA was injected. Real-time optical imaging was performed from baseline to 30 min as previously described (10) using a fluorescence stereomicroscope (Leica MZ16FA, Leica Microsystems, Heerbrugg, Switzerland) equipped with a charge-coupled device camera (Orca 285, Hamamatsu, Japan). A 470/50-nm bandpass excitation filter was used, and emitted fluorescence was collected through a bandpass filter of 525/50 nm. Images were analyzed using SimplePCI software (Compix, Sewickley, Pennsylvania). In vivo optical imaging was performed on the day of MI, 30 min after coronary ligation (n = 3); day 1 (n = 3); and weeks 1 (n = 3), 3(n = 3),6(n = 3), and 12 (n = 1) after MI in open-chested mice. Fluorescence APA imaging was also performed in 3 unmanipulated control mice.
Radionuclide imaging using radiolabeled losartan
Radiolabeled losartan was used in 4 mice, 3 weeks after MI and 6 unmanipulated age-matched control mice, using a dual-head micro-SPECT gamma camera and a micro-CT (X-SPECT, Gamma Medica, Northridge, California). The SPECT images were acquired in a 64 × 64 matrix, 32 steps at 20 s (0 h) or 120 s (at 4 h) per step at 140-KeV photopeak of 99mTc-losartan with a 15% window using a low-energy, high-resolution parallel collimator. The CT images were acquired without moving the animals. The micro-CT uses an X-ray tube operating at 50 kVp and 0.6 mA, with images captured for 2.5 s per view for 256 views in 360° rotation. Micro-CT images were transferred to a 256 × 256 matrix and micro-CT tomographic studies were fused, facilitating scintigraphic and anatomic information in all tomographic scans in 3 spatial axes. Animals were killed by an overdose of pentobarbital (120 mg/kg) after the imaging experiments. Hearts were carefully extracted and planar images of ex vivo heart were acquired for 15 min in a 128 × 128 matrix using a low-energy, high-resolution, pinhole collimator. Thereafter, each heart was cut into 3 bread-loaf slices (infarct, peri-infarct, and remote areas). The quantitative radiolabeled losartan uptake was determined with a gamma scintillation counter (1480 Wizard 3-inch; Wallac Co., Turku, Finland).
Pathologic characterization of the myocardial tissue
Hearts harvested after the optical imaging experiments were used for histopathologic characterization taking advantage of the intravenously administered fluorescent AT receptor probe. For this purpose, half of the myocardial tissue specimens were snap-frozen. Frozen sections (7 μm) of the heart were cut and examined by confocal microscopy (Axioplan 2, Zeiss, Göttingen, Germany) directly without further preparation. Subsequently, the same myocardial tissue specimens were stained with α-smooth muscle actin (SMA) antibody (Sigma, St. Louis, Missouri) for localization of myofibroblasts. The antibody for SMA was conjugated to a rhodamine-linked secondary antibody. Individual localization of APA and SMA were registered and merged subsequently to investigate colocalization. To further characterize cellular APA uptake, the infarcted myocardial region was also analyzed by 2-photon microscopy. This imaging setup consisted of a mode-locked Ti:Sapphire laser (170-fs pulse width, 76 MHz repetition rate; Mira 900F, Coherent Radiation, Palo Alto, California) pumped by a 5-W Verdi laser (Coherent Radiation). The 800-nm wavelength excitation beam was deflected into the back port of an inverted Axiovert 100 microscope (Zeiss) and scanned across the sample by a personal computer– controlled galvanometer-driven x-y scanner (Series 603X, Cambridge Technology, Watertown, Massachusetts). The beam was then reflected by a short-pass 675-nm dichroic beam splitter (Chroma Technology, Brattleboro, Vermont) and focused onto the sample with a 63×, water-immersion microscope objective (C-Apochromat, numerical aperture = 1.2, Zeiss). The average excitation power entering the microscope was approximately P = 60 mW (corresponding to 5 mW at the sample site). The fluorescence and second harmonic generation signals from the sample were discriminated by a 675-nm short-pass dichroic mirror, transmitted through a short-pass 600-nm filter (CVI Laser, Livermore, California), and further split by secondary long-pass 510-nm dichroic mirror onto 2 photomultiplier tubes with narrow (10-nm bandwidth) bandpass 400-nm filter (Chroma Technology) for second harmonic generation collection and 535-nm (50-nm bandwidth) band-center filter (Chroma Technology) for green fluorescence collection. Images (256 × 256 pixels) were taken at various depths (z), covering an area of 35 × 35 μm2 for the 63× microscope objective. Each acquisition was integrated for 10 s. The remaining half of the myocardial tissue specimens were fixed with 4% phosphate-buffered paraformaldehyde; fixed myocardial tissue specimens were analyzed routinely by hematoxylin and eosin staining.
Statistical analysis
All quantitative results are presented as the mean ± SD. To determine statistical significance of differences, Mann-Whitney test was used and a p value smaller than 0.05 was considered significant.
RESULTS
Real-time optical imaging of myocardial angiotensin receptors in HF
Optical imaging was performed with fluoresceinated APA. Although all infarcts were non-reperfused, the tracer entry in the infarcted myocardium occurred within 3 min and maximized in 20 min (Figs. 2A to 2D). In addition to myocardial localization, coronary arteries and arterioles showed intense uptake of the ligand; the uptake was minimal in the venous tree (Fig. 2E). No uptake of fluorescent APA probe was observed in the infarct area immediately after MI and 1 day after MI. However, distinct APA uptake was observed in the infarct regions at 1 week following MI, which increased substantially by 3 weeks (Fig. 3A). Minimal uptake of fluorescent probe was observed in the remote areas. Subsequently, the uptake in infarct region decreased at 6 weeks after MI and was predominantly seen in the infarct border zone (Fig. 2D). Uptake resolved by the 12th week. Echocardiographic examination demonstrated left ventricular dilation over time indicating progressive cardiac remodeling (Fig. 3B). Unmanipulated control animals receiving fluorescent APA did not show tracer uptake (Fig. 3A).
Figure 2. Optical Imaging of AT Receptors.
Intravital microscopy images show a 3-week old MI in the murine heart failure model from baseline (A), and 3 min (B), and at 20 min (C) after administration of green fluorescent angiotensin peptide analog (APA), demonstrating gradual increase of the fluorescent APA in infarcted region. Fluorescent uptake was maximized at 20 min after intravenous APA injection. The ex vivo image (D), demonstrates APA uptake in the border zone, as thinned out infarct zone has collapsed and is therefore not visible. Panel E shows APA uptake in smooth muscle cell layer of a small coronary artery (vertical arrows) as well as minimal uptake in thinner veins (diagonal arrows)
Figure 3. Evolution of APA Uptake After MI.
Intravital microscopy images demonstrating uptake of fluorescent APA from 6 groups: no infarction, and 0 day, 1 day, 1 week, 3 weeks and 12 weeks after MI (A) The uptake increases from 1 to 3 weeks, and decreases thereafter. Panel B shows the respective echocardio-grams at 1, 3, and 12 weeks, indicating left ventricular dilation and progressive heart failure in these mice with MI.
Pathologic characterization of receptor targeting
Direct localization of systemically administered fluorescent APA probe allowed characterization of binding sites of AT receptors in the myocardial tissue specimens. The APA uptake (green, Figs. 4A and 4B) was almost exclusively localized in cells other than cardiomyocytes. The fluorescently labeled cells in the replacement fibrosis in infarcted and peri-infarcted regions (green, Fig. 4D) stained positively for α-SMA (red, Fig. 4E). These data suggest that binding of the APA occurs, at least in a large part, to myofibroblasts (yellow, Figs. 4D to 4F). Although no uptake was seen in the cardiomyocytes, endothelial cells, or interstitial cells, APA uptake was distinctly observed in the vascular medial layers in arterioles. Two-photon microscopy revealed internalization of the green APA probe within the myofibroblasts and demonstrated intracellular and nuclear localization of the APA (Fig. 4C). Using second harmonic generation imaging, collagen fibers (blue) were seen emanating from the APA-positive cells, which further suggests the myofibroblastic origin of these cells (Fig. 4C).
Figure 4. Pathologic Characterization APA Localization.
The remote zone (A) demonstrates no APA uptake in interstitium (*) or cardiomyocytes (arrows) The cells of nonmyocytic origin demonstrate fluorescent APA uptake in the infarct zone (B), with an enlarged image of cellular uptake (inset) These cells in the infarct region (D, green) also stained positively for smooth muscle actin (SMA) (E, red), showing colocalization (F, yellow), indicating AT receptors (ATR) on myofibroblasts. (C) Ex vivo 2-photon microscopy demonstrated fluorescent APA intracellularly within the myofibroblast (green), with collagen surrounding the myofibroblast using second harmonic generation imaging (blue) Abbreviations as in Figure 1.
Nuclear imaging of angiotensin receptors
For noninvasive imaging of angiotensin receptors, we used radiolabeled losartan, in the 3-week post-MI animals for micro-SPECT/micro-CT imaging; a 3-week post-MI model was chosen for radionuclide imaging because of maximal upregulation of AT receptors observed in the optical imaging experiments. Radiolabeled losartan uptake was compared with unmanipulated control animals (Fig. 5). The combination of micro-SPECT and -CT images allowed for precise localization of myocardial uptake, which was observed in the anterolateral cardiac region. Ex vivo imaging of the explanted hearts demonstrated uptake in the infarct and border territory (Fig. 5C). Quantitative radiotracer uptake in infarcted myocardium, represented as percentage of injected radiotracer uptake per gram of myocardial tissue, was significantly higher than in control hearts (0.52 ± 0.21% vs. 0.21 ± 0.13%, p < 0.05). The mean infarct-to-remote region uptake ratio was 2.4:1. The maximum non-target organ radiation burden was observed in liver and kidney.
Figure 5. Noninvasive Imaging of AT Receptors With Radiolabeled Losartan.
The micro–SPECT and micro-CT images are shown in a control mouse after technetium Tc-99m losartan administration; no uptake in the heart can be seen (A) in the in vivo and ex vivo images. There is only some liver uptake on the bottom left of the SPECT image. (B) In the 3-week post-MI animal, significant radiolabeled losartan uptake is observed in the anterolateral wall (arrows) The infarct uptake on the in vivo image is confirmed in the ex vivo image. The histogram (C) demonstrates significantly (*) higher uptake in the infarcted region (0.524 ± 0.212% ID/g) as compared to control noninfarcted animals (0.215 ± 0.129% ID/g; p < 0.05). ID = injected dose.
DISCUSSION
The pivotal role of the renin-angiotensin system in ventricular remodeling following MI has been established in numerous experimental and clinical studies. More than circulating renin-angiotensin levels, it is the myocardial upregulation of ACE, AT and its receptors, which determine the likelihood of ventricular remodeling (3,11). As such, the use of angiotensin receptor blockers (6,12) and ACE inhibitors (13–15) has resulted in improved survival in patients with manifest and subclinical HF. It has been suggested that maximization of anti-angiotensin therapy, including increase in ACE-inhibitor dose or addition of angiotensin receptor blockers over ACE-inhibitor therapy further reduces morbidity (6,16) and mortality (4) in HF. It is therefore conceivable that accurate assessment of myocardial AT receptor expression should guide optimization of anti-angiotensin therapy. It should also allow periodic evaluation of the efficacy of anti-angiotensin intervention. Current diagnostic imaging of HF remains generally focused on geometric and structural cardiac alterations (17,18), and it can be hypothesized that the ability to visualize interstitial processes at the molecular level, which precede the geometric and functional deterioration of the left ventricle, should help predict the likelihood and rate of remodeling and development of HF (19).
The present study demonstrates the feasibility of in vivo imaging of myocardial angiotensin receptors in an experimental HF model. Currently, as a strategy for prevention of advanced HF, significant emphasis is being placed on the recognition of patients at risk for developing HF, including those with no apparent structural LV abnormality (stage A) and asymptomatic patients with a known structural LV abnormality (stage B) (20). As the current clinical practice allows diagnosis of HF only after the LV has undergone substantial remodeling, development of a technology that actually predicts occurrence of cardiac remodeling is of critical importance. Our immunohistochemical analyses show that binding of the tracer uptake was almost exclusively localized to myofibroblasts; we did not observe APA uptake in cardiomyocytes. Upregulation of AT receptors on myofibroblasts (Fig. 4F) allows for growth factor (such as AT)–induced myofibroblast proliferation and collagen production, which is believed to contribute to healing and the remodeling process following MI (2,21,22). Although angiotensin receptor upregulation in the kidneys has been observed earlier by a carbon-11 labeled AT type-1 antagonist (23), the hypothesis of the role of targeting neurohumoral upregulation for ventricular remodeling has been supported by imaging of renin-angiotensin axis with the help of radiolabeled benzoyl lisinopril (21,24). Dilsizian et al. (24) incubated myocardial specimens explanted from patients undergoing cardiac transplantation for end-stage ischemic cardiomyopathy with F-18 fluoro-benzoyl lisinopril. There was specific binding of radiotracer to ACE; mean binding was 6.6 ± 5.2, compared with 3.4 ± 2.5 luminescence/mm2 in segments pre-incubated with cold lisinopril (p < 0.0001). Further, mean radiotracer binding was 6.3 ± 4.5 in infarcted, 7.6 ± 4.7 in peri-infarcted, and 5.0 ± 1.0 luminescence/mm2 in remote non-infarcted (p < 0.02) segments. The distribution of mast cell chymase was nonuniform in these samples and disparate from ACE. This and the study presented here demonstrate that ACE (and probably AT) upregulation induces the proliferation of myofibroblasts (which have increased angiotensin receptor density) and contributes to collagen deposition. Both studies have also demonstrated that these key steps in the tissue renin-angiotensin cascade involve receptor upregulation of only about 2- to 3-fold. It therefore remains to be seen whether imaging targeted to AT receptors and/or ACE will result in clinically robust imaging strategy.
CONCLUSIONS
The present study explains the development of a diagnostic probe seeking AT receptor upregulation within the myocardium and shows the feasibility of noninvasive radionuclide imaging. The fluorescent angiotensin receptor probe confirms receptor localization on myofibroblasts, which may contribute to the process of interstitial fibrosis. It is proposed that monitoring of angiotensin receptor expression after infarction may predict the evolution of HF. The present study offers a proof of concept, with modest uptake of radiolabeled losartan and it will be necessary to engineer probes with better targeting characteristics for realization of potential clinical application.
Acknowledgments
Supported in part by GE Healthcare (Oslo, Norway) that provided the fluorescent and radiolabeled probes for imaging; the Laser Microbeam and Medical Program (LAMMP) and NIH Biomedical Technology Resource grant #P41-RR01192, both of which supported the optical imaging and analysis; and by DiPalma-Brodsky funds that provided research fellowship support to Dr. Verjans. Drs. Lovhaug, B. Indrevoll, Dr. Bjurgert, L. Peterson, Dr. Kindberg, Dr. Solbakken, and Dr. Cuthbertson are employees of GE Healthcare, Oslo, Norway. H. William Strauss, MD, acted as Guest Editor for this paper.
ABBREVIATIONS AND ACRONYMS
- ACE
angiotensin-converting enzyme
- APA
angiotensin peptide analog
- AT
angiotensin II
- CT
computed tomography
- HF
heart failure
- LV
left ventricle
- MI
myocardial infarction
- SMA
smooth muscle actin
- SPECT
single-photon emission computed tomography
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