Novel molecular imaging platform for monitoring oncological kinases

Recent advances in oncology have lead to identification of a plethora of alterations in signaling pathways that are critical to oncogenesis and propagation of malignancy. Among the biomarkers identified, dysregulated kinases and associated changes in signaling cascade received the lion's share of scientific attention and have been under extensive investigations with goal of targeting them for anti-cancer therapy. Discovery of new drugs is immensely facilitated by molecular imaging technology which enables non-invasive, real time, dynamic imaging and quantification of kinase activity. Here, we review recent development of novel kinase reporters based on conformation dependent complementation of firefly luciferase to monitor kinase activity. Such reporter system provides unique insights into the pharmacokinetics and pharmacodynamics of drugs that modulate kinase signaling and have a huge potential in drug discovery, validation, and drug-target interactions

Synthesis and Investigation of a Radioiodinated F3 Peptide Analog as a SPECT Tumor Imaging Radioligand

A radioiodinated derivative of the tumor-homing F3 peptide, (N-(2-{3-[125I]Iodobenzoyl}aminoethyl)maleimide-F3Cys peptide, [125I]IBMF3 was developed for investigation as a SPECT tumor imaging radioligand. For this purpose, we custom synthesized a modified F3 peptide analog (F3Cys) incorporating a C-terminal cysteine residue for site-specific attachment of a radioiodinated maleimide conjugating group. Initial proof-of-concept Fluorescence studies conducted with AlexaFluor 532 C5 maleimide-labeled F3Cys showed distinct membrane and nuclear localization of F3Cys in MDA-MB-435 cells. Additionally, F3Cys conjugated with NIR fluorochrome AlexaFluor 647 C2 maleimide demonstrated high tumor specific uptake in melanoma cancer MDA-MB-435 and lung cancer A549 xenografts in nude mice whereas a similarly labeled control peptide did not show any tumor uptake. These results were also confirmed by ex vivo tissue analysis. No-carrier-added [125I]IBMF3 was synthesized by a radioiododestannylation approach in 73% overall radiochemical yield. In vitro cell uptake studies conducted with [125I]IBMF3 displayed a 5-fold increase in its cell uptake at 4 h when compared to controls. SPECT imaging studies with [125I]IBMF3 in tumor bearing nude mice showed clear visualization of MDA-MB-435 xenografts on systemic administration. These studies demonstrate a potential utility of F3 peptide-based radioligands for tumor imaging with PET or SPECT techniques

Enhancing Akt Imaging through Targeted Reporter Expression

The serine/threonine kinase PKB/Akt is a key mediator of survival and resistance to cancer therapy. Pharmacologic inhibition of Akt and its biologic sequelae may significantly impact the treatment of cancer. The use of molecular imaging technologies has contributed significantly to drug discovery research with an emphasis on drug efficacy, the mechanism of action, and target validation studies. We constructed a genetically engineered hybrid bioluminescent Akt reporter (BAR) molecule that reports on Akt serine/threonine kinase activity. Based on the fact that Akt is recruited to the plasma membrane on activation, we here describe a modified version of this reporter molecule (myristoylated and palmitoylated bioluminescent Akt reporter [MyrPalm-BAR]), which is membrane bound and whose bioluminescence activity can be used to monitor Akt activity at the cell membrane. Using changes in Akt activation status with small molecule inhibitors of Akt, we demonstrated that the membrane-targeted Akt reporter was more sensitive and quantitative. In addition, inhibition of upstream signaling kinases such as epidermal growth factor receptor and phosphatidylinositol 3-kinase activity resulted in changes in Akt activity that were quantitatively monitored by bioluminescence imaging. Based on these results, we propose that the membrane-associated Akt reporter may be better suited for identification of novel compounds that modulate the Akt pathway by high-throughput screening

A Small-Molecule Furin Inhibitor Inhibits Cancer Cell Motility and Invasiveness1

Furin, a member the proprotein convertase (PC) family, processes inactive precursor proteins to functional proteins within the Golgi/trans-Golgi network secretory pathway. Furin and other PC family members (furin/PCs) activate proteins vital to proper physiological functioning, including growth factors and hormones, receptors, plasma proteins, and matrix metalloproteases (MMPs). Additionally, the expression and activity of furin/PC are necessary for processing substrates important for cell transformation and tumor progression, metastasis, and angiogenesis. Furin processing of the remodeling protease membrane type-1 matrix metalloproteinase (MT1-MMP) enhances cellular motility and invasiveness, contributing to aggression and metastatic potential cancer cells. Whereas overexpression and activity of furin/PC exacerbate the cancer phenotype, inhibition of its activity decreases or nullifies furin/PC-mediated effects, and thus, inhibition of furin may be a viable route to cancer therapy. Recently, we identified a small-molecule inhibitor of furin, named B3, by high-throughput screening with a Ki and IC50 of 12µM. Here, we show that this cell-permeable, small-molecule compound inhibits furin-mediated cleavage of proMT1-MMP, resulting in decreased MMP-2 activation and cell motility in CHO cells expressing proMT1-MMP. Additionally, this molecule inhibited proMT1-MMP processing, complete MMP-2 maturation, and invasiveness of human fibrosarcoma cells (HT1080)

Enhancing Akt Imaging through Targeted Reporter Expression

The serine/threonine kinase PKB/Akt is a key mediator of survival and resistance to cancer therapy. Pharmacologic inhibition of Akt and its biologic sequelae may significantly impact the treatment of cancer. The use of molecular imaging technologies has contributed significantly to drug discovery research with an emphasis on drug efficacy, the mechanism of action, and target validation studies. We constructed a genetically engineered hybrid bioluminescent Akt reporter (BAR) molecule that reports on Akt serine/threonine kinase activity. Based on the fact that Akt is recruited to the plasma membrane on activation, we here describe a modified version of this reporter molecule (myristoylated and palmitoylated bioluminescent Akt reporter [MyrPalm-BAR]), which is membrane bound and whose bioluminescence activity can be used to monitor Akt activity at the cell membrane. Using changes in Akt activation status with small molecule inhibitors of Akt, we demonstrated that the membrane-targeted Akt reporter was more sensitive and quantitative. In addition, inhibition of upstream signaling kinases such as epidermal growth factor receptor and phosphatidylinositol 3-kinase activity resulted in changes in Akt activity that were quantitatively monitored by bioluminescence imaging. Based on these results, we propose that the membrane-associated Akt reporter may be better suited for identification of novel compounds that modulate the Akt pathway by high-throughput screening

Molecular Imaging of Akt Enables Early Prediction of Response to Molecular Targeted Therapy12

Development of noninvasive, real-time molecular imaging tools to assess responsiveness of a given therapy may be a critical component of the success of individualized therapy approach for patients. Toward this, we have previously developed and validated molecular sensors for Akt and caspase-3 activity, and in this report, we have explored the utility of these reporters in assessing the responsiveness of tumors to a combination of gemcitabine (Gem) and cetuximab (Cet) delivered in two opposite schedules. We found that human head and neck cancer (UMSCC1) xenografts responded significantly better in a schedule where cetuximab was administered after gemcitabine when compared with the schedule of cetuximab followed by gemcitabine. Wilcoxon two-sample tests suggested that the difference in tumor volumes in two schedules became significant on day 7 (P > .05 on day 4, and P < .05 on days 7 and 10), and the difference in activity of Akt in two schedules became significant on day 4 (P < .05 on days 4, 6, and 10). Using Akt reporter activity and cubic spline interpolation, the distinction between the two schedules could be detected 2 days before using the tumor volume, suggesting that molecular imaging of Akt may allow early prediction of therapy responsiveness. We did not observe a significant difference between the two schedules in the caspase-3 activity. In summary, this proof-of-concept study provides a basis for using molecular imaging of Akt as an early indicator of therapeutic efficacy