Byunghee Yoo

Detection of in vivo enzyme activity with CatalyCEST MRI.

CatalyCEST MRI compares the detection of an enzyme‐responsive chemical exchange saturation transfer (CEST) agent with the detection of an unresponsive “control” CEST agent that accounts for other conditions that influence CEST. The purpose of this study was to investigate the feasibility of in vivo catalyCEST MRI.

GLP-1R–Targeting Magnetic Nanoparticles for Pancreatic Islet Imaging

Noninvasive assessment of pancreatic β-cell mass would tremendously aid in managing type 1 diabetes (T1D). Toward this goal, we synthesized an exendin-4 conjugated magnetic iron oxide–based nanoparticle probe targeting glucagon-like peptide 1 receptor (GLP-1R), which is highly expressed on the surface of pancreatic β-cells. In vitro studies in βTC-6, the β-cell line, showed specific accumulation of the targeted probe (termed MN-Ex10-Cy5.5) compared with nontargeted (termed MN-Cy5.5). In vivo magnetic resonance imaging showed a significant transverse relaxation time (T2) shortening in the pancreata of mice injected with the MN-Ex10-Cy5.5 probe compared with control animals injected with the nontargeted probe at 7.5 and 24 h after injection. Furthermore, ΔT2 of the pancreata of prediabetic NOD mice was significantly higher than that of diabetic NOD mice after the injection of MN-Ex10-Cy5.5, indicating the decrease of probe accumulation in these animals due to β-cell loss. Of note, ΔT2 of prediabetic and diabetic NOD mice injected with MN-Cy5.5 was not significantly changed, reflecting the nonspecific mode of accumulation of nontargeted probe. We believe our results point to the potential for using this agent for monitoring the disease development and response of T1D to therapy.

Combining miR-10b–Targeted Nanotherapy with Low-Dose Doxorubicin Elicits Durable Regressions of Metastatic Breast Cancer

The therapeutic promise of microRNA (miRNA) in cancer has yet to be realized. In this study, we identified and therapeutically exploited a new role for miR-10b at the metastatic site, which links its overexpression to tumor cell viability and proliferation. In the protocol developed, we combined a miR-10b-inhibitory nanodrug with low-dose anthracycline to achieve complete durable regressions of metastatic disease in a murine model of metastatic breast cancer. Mechanistic investigations suggested a potent antiproliferative, proapoptotic effect of the nanodrug in the metastatic cells, potentiated by a cell-cycle arrest produced by administration of the low-dose anthracycline. miR-10b was overexpressed specifically in cells with high metastatic potential, suggesting a role for this miRNA as a metastasis-specific therapeutic target. Taken together, our results implied the existence of pathways that regulate the viability and proliferation of tumor cells only after they have acquired the ability to grow at distant metastatic sites. As illustrated by miR-10b targeting, such metastasis-dependent apoptotic pathways would offer attractive targets for further therapeutic exploration.

Combination treatment with theranostic nanoparticles for glioblastoma sensitization to TMZ.

PurposeTumor resistance to chemotherapeutic drugs is one of the major obstacles in the treatment of glioblastoma multiforme (GBM). In this study, we attempted to modulate tumor response to chemotherapy by combination treatment that included experimental (small interference RNA (siRNA), chlorotoxin) and conventional (temozolomide, TMZ) therapeutics.ProceduressiRNA therapy was used to silence O6-methylguanine methyltransferase (MGMT), a key factor in brain tumor resistance to TMZ. For targeting of tumor cells, we used chlorotoxin (CTX), a peptide with antitumoral properties. siRNA and CTX were conjugated to iron oxide nanoparticles (NP) that served as the drug carrier and allowed the means to monitor the changes in tumor volume by magnetic resonance imaging (MRI).ResultsTheranostic nanoparticles (termed CTX-NP-siMGMT) were internalized by T98G glioblastoma cells in vitro leading to enhancement of TMZ toxicity. Combination treatment of mice bearing orthotopic tumors with CTX-NP-siMGMT and TMZ led to significant retardation of tumor growth, which was monitored by MRI.ConclusionsWhile our results demonstrate that siRNA delivery by targeted nanoparticles resulted in modulating tumor response to chemotherapy in GBM, they also point to a significant contribution of CTX to tumor cell death.

Detecting Enzyme Activities with Exogenous MRI Contrast Agents

This review focuses on exogenous magnetic resonance imaging (MRI) contrast agents that are responsive to enzyme activity. Enzymes can catalyze a change in water access, rotational tumbling time, the proximity of a (19)F-labeled ligand, the aggregation state, the proton chemical-exchange rate between the agent and water, or the chemical shift of (19)F, (31)P, (13)C or a labile (1)H of an agent, all of which can be used to detect enzyme activity. The variety of agents attests to the creativity in developing enzyme-responsive MRI contrast agents.

Detection of miRNA expression in intact cells using activatable sensor oligonucleotides.

We describe a technology for the profiling of miRNA expression in intact cells. The technology is based on sensor oligonucleotides that are cleavable, completely complementary to a target miRNA, and dual-labeled with a fluorescent dye and a quencher. Upon entering the cell, the sensor oligonucleotide binds its specific miRNA target through complementary base-pairing. This triggers assembly of the endogenous RNA Induced Silencing Complex (RISC) around the miRNA-sensor duplex and cleavage of the sensor oligonucleotide, resulting in separation between the dye and quencher, and a fluorescence turn-on. In the presented feasibility studies, we focus on a specific miRNA (miR-10b) implicated in breast cancer metastasis. Using a human breast adenocarcinoma cell line, we illustrate the application of this technology for miRNA detection with nanomolar sensitivity in both a cell-free system and intact cells.

Targeted imaging of breast tumor progression and therapeutic response in a human uMUC-1 expressing transgenic mouse model.

The ability to monitor breast cancer initiation and progression on the molecular level would provide an effective tool for early diagnosis and therapy. In the present study, we focused on the underglycosylated MUC‐1 tumor antigen (uMUC‐1), which is directly linked to tumor progression from pre‐malignancy to advanced malignancy in breast cancer and has been identified as the independent predictor of local recurrence and tumor response to chemotherapy. We investigated whether changes in uMUC‐1 expression during tumor development and therapeutic intervention could be monitored non‐invasively using molecular imaging approach with the uMUC‐1‐specific contrast agent (MN‐EPPT) detectable by magnetic resonance and fluorescence optical imaging. This was done in mice that express human uMUC‐1 tumor antigen (MMT mice) and develop spontaneous mammary carcinoma in a stage‐wise fashion. After the injection of MN‐EPPT there was a significant reduction in average T2 relaxation times of the mammary fat pad between pre‐malignancy and cancer. In addition, T2 relaxation times were already altered at pre‐malignant state in these mice compared to non‐tumor bearing mice. This indicated that targeting uMUC‐1 could be useful for detecting pre‐malignant transformation in the mammary fat pad. We also probed changes in uMUC‐1 expression with MN‐EPPT during therapy with doxorubicin (Dox). We observed that tumor delta‐T2s were significantly reduced by treatment with Dox indicating lower accumulation of MN‐EPPT. This correlated with a lower level of MUC‐1 expression in the Dox‐treated tumors, as confirmed by immunoblotting. Our study could provide a very sensitive molecular imaging approach for monitoring tumor progression and therapeutic response.

Therapy targeted to the metastatic niche is effective in a model of stage IV breast cancer

Treatment of stage IV metastatic breast cancer patients is limited to palliative options and represents an unmet clinical need. Here, we demonstrate that pharmacological inhibition of miRNA-10b - a master regulator of metastatic cell viability – leads to elimination of distant metastases in a mouse model of metastatic breast cancer. This was achieved using the miRNA-10b inhibitory nanodrug, MN-anti-miR10b, which consists of magnetic nanoparticles, conjugated to LNA-based miR-10b antagomirs. Intravenous injection of MN-anti-miR10b into mice bearing lung, bone, and brain metastases from breast cancer resulted in selective accumulation of the nanodrug in metastatic tumor cells. Weekly treatments of mice with MN-anti-miR-10b and low-dose doxorubicin resulted in complete regression of pre-existing distant metastases in 65% of the animals and a significant reduction in cancer mortality. These observations were supported by dramatic reduction in proliferation and increase in apoptosis in metastatic sites. On a molecular level, we observed a significant increase in the expression of HOXD10, which is a known target of miRNA-10b. These results represent first steps into the uncharted territory of therapy targeted to the metastatic niche.

Lanthanide-Mediated Dephosphorylation Used for Peptide Cleavage during Solid Phase Peptide Synthesis

Lanthanide(III) ions can accelerate the hydrolysis of phosphomonoesters and phosphodiesters in neutral aqueous solution. In this paper, lanthanide-mediated dephosphorylation has been applied in aqueous media as an orthogonal cleavage condition that can be employed in conventional solid phase peptide synthesis (SPPS). A phosphorylated polymeric support for SPPS was developed using Boc chemistry. The cleavage of resin-bound phosphates was investigated with the addition of Eu(III), Yb(III), acid or base, a mixture of solvents or different temperatures. To demonstrate the utility of this approach for SPPS, a peptide sequence was synthesized on a phosphorylated polymeric support and quantitatively cleaved with lanthanide ions in neutral aqueous media. The protecting groups for side chains were retained during peptide cleavage using lanthanide ions. This new methodology provides a mild orthogonal cleavage condition of phosphoester as a linker during SPPS.

Predictive imaging of chemotherapeutic response in a transgenic mouse model of pancreatic cancer

The underglycosylated mucin 1 tumor antigen (uMUC1) is a biomarker that forecasts the progression of adenocarcinomas. In this study, we evaluated the utility of a dual‐modality molecular imaging approach based on targeting uMUC1 for monitoring chemotherapeutic response in a transgenic murine model of pancreatic cancer (KCM triple transgenic mice). An uMUC1‐specific contrast agent (MN‐EPPT) was synthesized for use with magnetic resonance imaging (MRI) and fluorescence optical imaging. It consisted of dextran‐coated iron oxide nanoparticles conjugated to the near infrared fluorescent dye Cy5.5 and to a uMUC1‐specific peptide (EPPT). KCM triple transgenic mice were given gemcitabine as chemotherapy while control animals received saline injections following the same schedule. Changes in uMUC1 levels following chemotherapy were monitored using T2‐weighted MRI and optical imaging before and 24 hr after injection of the MN‐EPPT. uMUC1 expression in tumors from both groups was evaluated by histology and qRT‐PCR. We observed that the average delta‐T2 in the gemcitabine‐treated group was significantly reduced compared to the control group indicating lower accumulation of MN‐EPPT, and correspondingly, a lower level of uMUC1 expression. In vivo optical imaging confirmed the MRI findings. Fluorescence microscopy of pancreatic tumor sections showed a lower level of uMUC1 expression in the gemcitabine‐treated group compared to the control, which was confirmed by qRT‐PCR. Our data proved that changes in uMUC1 expression after gemcitabine chemotherapy could be evaluated using MN‐EPPT‐enhanced in vivo MR and optical imaging. These results suggest that the uMUC1‐targeted imaging approach could provide a useful tool for the predictive assessment of therapeutic response.