Jeongsoo Yoo

pH-responsive assembly of gold nanoparticles and "spatiotemporally concerted" drug release for synergistic cancer therapy.

A challenge in using plasmonic nanostructure-drug conjugates for thermo-chemo combination cancer therapy lies in the huge size discrepancy; the size difference can critically differentiate their biodistributions and hamper the synergistic effect. Properly tuning the plasmonic wavelength for photothermal therapy typically results in the nanostructure size reaching ∼100 nm. We report a new combination cancer therapy platform that consists of relatively small 10 nm pH-responsive spherical gold nanoparticles and conjugated doxorubicins. They are designed to form aggregates in mild acidic environment such as in a tumor. The aggregates serve as a photothermal agent that can selectively exploit external light by their collective plasmon modes. Simultaneously, the conjugated doxorubicins are released. The spatiotemporal concertion is confirmed at the subcellular, cellular, and organ levels. Both agents colocalize in the cell nuclei. The conjugates accumulate in cancer cells by the rapid phagocytic actions and effective blockage of exocytosis by the increased aggregate size. They also effectively accumulate in tumors up to 17 times over the control because of the enhanced permeation and retention. The conjugates exhibit a synergistic effect enhanced by nearly an order of magnitude in cellular level. The synergistic effect is demonstrated by the remarkable reductions in both the therapeutically effective drug dosage and the photothermal laser threshold. Using an animal model, effective tumor growth suppression is demonstrated. The conjugates induce apoptosis to tumors without any noticeable damage to other organs. The synergistic effect in vivo is confirmed by qRT-PCR analysis over the thermal stress and drug-induced growth arrest.

89Zr-Labeled Dextran Nanoparticles Allow in Vivo Macrophage Imaging

Tissue macrophages play a critical role both in normal physiology and in disease states. However, because of a lack of specific imaging agents, we continue to have a poor understanding of their absolute numbers, flux rates, and functional states in different tissues. Here, we describe a new macrophage specific positron emission tomography imaging agent, labeled with zirconium-89 ((89)Zr), that was based on a cross-linked, short chain dextran nanoparticle (13 nm). Following systemic administration, the particle demonstrated a vascular half-life of 3.9 h and was found to be located primarily in tissue resident macrophages rather than other white blood cells. Subsequent imaging of the probe using a xenograft mouse model of cancer allowed for quantitation of tumor-associated macrophage numbers, which are of major interest in emerging molecular targeting strategies. It is likely that the material described, which allows the visualization of macrophage biology in vivo, will likewise be useful for a multitude of human applications.

Phage display selection of peptides that home to atherosclerotic plaques: IL-4 receptor as a candidate target in atherosclerosis

Imaging or drug delivery tools for atherosclerosis based on the plaque biology are still insufficient. Here, we attempted to identify peptides that selectively home to atherosclerotic plaques using phage display. A phage library containing random peptides was ex viv screened for binding to human atheroma tissues. After three to four rounds of selection, the DNA inserts of phage clones wer sequenced. A peptide sequence, CRKRLDRNC, was the most frequently occurring one. Intravenously injected phage displaying the CRKRLDRNC peptide was observed to home to atherosclerotic aortic tissues of low‐density lipoprotein receptor‐deficient (Ldlr−/–) mice at higher levels than to normal aortic tissues of wild‐type mice. Moreover, a fluorescein‐ or radioisotope‐conjugated synthetic CRKRLDRNC peptide, but not a control peptide, homed in vivo to atherosclerotic plaques in Ldlr−/– mice, while homing of the peptide to other organs such as brain was minimal. The homing peptide co‐localized with endothelial cells, macrophages and smooth muscle cells a mouse and human atherosclerotic plaques. Homology search revealed that the CRKRLDRNC peptide shares a motif of interleukin‐receptor (IL‐4) that is critical for binding to its receptor. The peptide indeed co‐localized with IL‐4 receptor (IL‐4R) at atherosclerotic plaques. Moreover, the peptide bound to cultured cells expressing IL‐4R on the cell surface and the binding was inhibited by the knock‐down of IL‐4R. These results show that the CRKRLDRNC peptide homes to atherosclerotic plaques through binding to IL‐4R as its target and may be a useful tool for selective drug delivery and molecular imaging of atherosclerosis.

In vivo imaging of tumor apoptosis using histone H1-targeting peptide

In vivo imaging of apoptosis could allow monitoring of tumor response to cancer treatments such as chemotherapy. Using phage display, we identified the CQRPPR peptide, named ApoPep-1(Apoptosis-targeting Peptide-1), that was able to home to apoptotic and necrotic cells in tumor tissue. ApoPep-1 also bound to apoptotic and necrotic cells in culture, while only little binding to live cells was observed. Its binding to apoptotic cells was not dependent on calcium ion and not competed by annexin V. The receptor for ApoPep-1 was identified to be histone H1 that was exposed on the surface of apoptotic cells. In necrotic cells, ApoPep-1 entered the cells and bound to histone H1 in the nucleus. The imaging signals produced during monitoring of tumor apoptosis in response to chemotherapy was enhanced by the homing of a fluorescent dye- or radioisotope-labeled ApoPep-1 to tumor treated with anti-cancer drugs, whereas its uptake of the liver and lung was minimal. These results suggest that ApoPep-1 holds great promise as a probe for in vivo imaging of apoptosis, while histone H1 is a unique molecular signature for this purpose.

In Vivo Biodistribution, PET Imaging, and Tumor Accumulation of 86Y- and 111In-Antimindin/RG-1, Engineered Antibody Fragments in LNCaP Tumor–Bearing Nude Mice

To optimize in vivo tissue uptake kinetics and clearance of engineered monoclonal antibody (mAb) fragments for radiotherapeutic and radiodiagnostic applications, we compared the biodistribution and tumor localization of four 111In- and 86Y-labeled antibody formats, derived from a single antimindin/RG-1 mAb, in a prostate tumor model. The IgG, diabody, single-chain variable domain (scFv), and novel miniantibody formats, composed of the human IgE-CH4 and a modified IgG1 hinge linked to scFv domains, were compared. Methods: Antibodies were first derivatized with the bifunctional chelator CHX-A″-diethylenetriamine pentaacetic acid and then bound to the radiometal to create radiolabeled immunoconjugates. Human LNCaP xenografts were grown in nude mice, and 111In- or 86Y-labeled antibodies were administered intravenously. Tissues were harvested at different times, and the level of antibody deposition was determined by measuring radioactivity. Whole-body small-animal PET of mice receiving 86Y-labeled antibodies was performed at 6 time points and colocalized with simultaneous micro-CT imaging. Results: The biodistributions of 111In and 86Y antibodies were quite similar. The blood, tumor, kidney, and liver tissues contained varying levels of radioactivity. The antibody accumulation in the tumor correlated with molecular size. The IgG steadily increased with time to 24.1 percentage injected dose per gram (%ID/g) at 48 h. The miniantibody accumulated at a similar rate to reach a lower level (14.2 %ID/g) at 48 h but with a higher tumor-to-blood ratio than the IgG. Tumor accumulation of the diabody peaked at 3 h, reaching a much lower level (3.7 %ID/g). A combination of rapid clearance and lower relative affinity of the scFv precluded deposition in the tumor. Small-animal PET results correlated well with the biodistribution results, with similar tumor localization patterns. Conclusion: The larger antibody formats (IgG and miniantibody) gave higher tumor uptake levels than did the smaller formats (diabody and scFv). These larger formats may be more suitable for radioimmunotherapy applications, evidenced by the preclinical efficacy previously shown by a report on the IgG format. The smaller formats were rapidly cleared from circulation, and the diabody, which accumulated in the tumor, may be more suitable for radiodiagnostic applications.

Biarylpyrazolyl Oxadiazole as Potent, Selective, Orally Bioavailable Cannabinoid-1 Receptor Antagonists for the Treatment of Obesity

Since the CB1 cannabinoid receptor antagonist 1 (SR141716, rimonabant) was previously reported to modulate food intake, CB1 antagonism has been considered as a new therapeutic target for the treatment of obesity. In the present study, biarylpyrazole analogues based on a pyrazole core coupled with 1,3,4-oxadiazole were synthesized and tested for CB1 receptor binding affinity. Thorough SAR studies to optimize pyrazole substituents as well as 1,3,4-oxadiazole ring led to several novel CB1 antagonists with IC(50) approximately 1 nM for the CB1 receptor binding. Among these analogues, we identified 2-(4-((1H-1,2,4-triazol-1-yl)methyl)-5-(4-bromophenyl)-1-(2,4-dichlorophenyl)-1H-pyrazol-3-yl)-5-(1-(trifluoromethyl)cyclopropyl)-1,3,4-oxadiazole 43c as a promising precandidate for the development as an antiobesity agent.

Revival of TE2A; a better chelate for Cu(II) ions than TETA?

A highly effective synthetic route for TE2A was developed and the (64)Cu-labeled TE2A complexes showed higher kinetic inertness and faster clearance than most commonly used TETA analogs.

Detection of apoptosis in a rat model of focal cerebral ischemia using a homing peptide selected from in vivo phage display

Focal cerebral ischemia, known as stroke, is caused by a sudden interruption in the blood supply to the brain. We attempted to identify peptides that can home to ischemic stroke tissue and detect the apoptosis of cells. A phage library displaying random peptides was screened for homing peptides to ischemic stroke tissue in a rat transient middle cerebral artery (MCA) occlusion model. After three rounds of in vivo screening, a phage clone displaying the most frequently occurring CLEVSRKNC sequence was selected. The CLEVSRKNC-phage preferentially homed to ischemic stroke tissue after intravenous administration into the MCA occlusion rats. The fluorescein-labeled synthetic CLEVSRKNC peptide, but not a scrambled control peptide, homed to ischemic stroke tissue with a lack of homing to non-ischemic brain tissue. The CLEVSRKNC peptide co-localized with a portion of neuronal cells, rather than with astrocytes, undergoing apoptosis at the penumbra region of stroke lesions. In autoradiographic studies, the uptake of the (131)I-labeled CLEVSRKNC peptide into an ischemic lesion increased at the first day and peaked at the third day after the injury. These results demonstrate that the CLEVSRKNC peptide can home to ischemic stroke tissue, while detecting apoptotic neuronal cells, and suggest it has applications as a targeting moiety for molecular imaging and selective drug delivery to stroke tissue.

New macrobicyclic chelator for the development of ultrastable 64Cu-radiolabeled bioconjugate.

Ethylene cross-bridged cyclam with two acetate pendant arms, ECB-TE2A, is known to form the most kinetically stable (64)Cu complexes. However, its usefulness as a bifunctional chelator is limited because of its harsh radiolabeling conditions. Herein, we report new cross-bridged cyclam chelator for the development of ultrastable (64)Cu-radiolabeled bioconjugates. Propylene cross-bridged TE2A (PCB-TE2A) was successfully synthesized in an efficient way. The Cu(II) complex of PCB-TE2A exhibited much higher kinetic stability than ECB-TE2A in acid decomplexation studies, and also showed high resistance to reduction-mediated demetalation. Furthermore, the quantitative radiolabeling of PCB-TE2A with (64)Cu was achieved under milder conditions compared to ECB-TE2A. Biodistribution studies strongly indicate that the (64)Cu complexes of PCB-TE2A cleared out rapidly from the body with minimum decomplexation.

Identification of a peptide ligand recognizing dysfunctional endothelial cells for targeting atherosclerosis

Targeting ligands to dysfunctional or activated endothelial cells overlying atherosclerotic plaques could provide tools for selective drug delivery to atherosclerotic lesions. To identify peptides selectively targeting dysfunctional endothelial cells, a phage library was screened against tumor necrosis factor-alpha (TNF-alpha) activated bovine aortic endothelial cells (BAECs). Five rounds of biopanning were carried out and the phage clones selected were examined for their DNA inserts. A phage clone displaying the CLWTVGGGC sequence occurred most frequently and was found to bind specifically to TNF-alpha activated BAECs over untreated cells. On the other hand, bindings of the phage clone to human umbilical vein endothelial cells, lymphatic endothelial cells, and epithelial cells were minimal. Flow cytometric and fluorescence microscopic studies showed the preferential binding of the CLWTVGGGC peptide to TNF-alpha activated BAECs compared to untreated cells. In vivo studies demonstrated selective homing and co-localization of the CLWTVGGGC peptide to dysfunctional endothelial cells overlying atherosclerotic plaques in low-density lipoprotein receptor-deficient mice. These results demonstrate that the CLWTVGGGC peptide could specifically recognize dysfunctional endothelial cells at atherosclerotic plaques and be used as a targeting ligand for drug delivery and imaging of atherosclerosis.