Novel Therapeutic Strategies for Pancreatic Cancer

Quinn, Bridget A.

01 January 2014

Pancreatic cancer is a devastating disease that leaves patients with a very poor prognosis and few therapeutic options. Many of the treatment options available are the same that have been used for almost 2 decades. There is a dire need for both novel treatments for this disease as well as novel strategies of treatment. This body of work will introduce and provide evidence in support of a novel combination therapy for pancreatic cancer treatment, a novel strategy of modifying currently used chemotherapeutics for pancreatic cancer therapy, and a novel transgenic preclinical mouse model of pancreatic cancer. Sabutoclax, an antagonist of the anti-apoptotic Bcl-2 proteins, and Minocycline, a commonly used antibiotic, show potent synergy when used in combination in both pancreatic cancer cells and in multiple immune-deficient and immune-competent mouse models of pancreatic cancer. Sabutoclax alone is capable of inducing cell cycle arrest and apoptosis in cells and its cytotoxicity is enhanced significantly when combined with Minocycline. This combination results in the loss of Stat3 activation both in vitro and in vivo, which is essential for its toxicity. It also inhibits tumor growth and prolongs survival in the KPC transgenic mouse model of pancreatic cancer. Also presented here are studies that demonstrate efficacy in vivo of modified versions of Gemcitabine and Paclitaxel. These drugs are linked to a peptide that shows specificity for the EphA2 receptor, which is overexpressed on the surface of pancreatic cancer cells and only minimally on normal cells. This peptide results in increased cellular uptake of drug, as it is bypassing its normal mechanism of entry. These normal mechanisms are often dysregulated in cancer, leading to decreased uptake and drug resistance. The use of these modified drugs show significantly increased tumor growth inhibition as compared to the parent drug alone. Finally, we provide data on the characterization of a novel transgenic mouse model of pancreatic cancer. This model, the Pan Met View (PMV) mouse, combines the commonly used KPC transgenic mouse model of pancreatic cancer and a mouse that expresses a Luciferase reporter gene under the control of the cancer-specific promoter, CCN1. Our data shows that double transgenic PMV mice can now be used to follow primary tumor and metastasis development in real time by Bioluminescent imaging (BLI) through disease progression and potentially therapy. This strategy will enhance the use of genetically engineered mouse models (GEMMS) to study cancer initiation and progression with potential to non-invasively monitor therapy. These chapters present novel and exciting data that have the potential to open multiple avenues of translational study and result in significant advances in pancreatic cancer therapy.

Medical Cell Biology

Medical Genetics

Neoplasms

Oncology

Translational Medical Research

Platelet Transcriptome Heterogeneity: A Role for RNA Uptake in Vascular Health and Disease

Clancy, Lauren R.

22 August 2017

As our understanding of the platelet’s systemic role continues to expand beyond hemostasis and thrombosis, interrogation of the platelet’s ability to affect diverse biological processes is required. Studies of the platelet’s non-traditional roles have focused on developing our understanding of the platelet’s relation to specific disease phenotypes as well as elucidation of platelet characteristics, content, and function. The generic content, traditional function and heterogeneity of platelets have long been accepted; more ambiguous and controversial has been how these factors are interrelated. Investigation of platelet content revealed the presence of biologically functional RNA in anucleated platelets, the correlation of platelet RNA to distinct phenotypes, and the ability of platelets to transfer RNA to other vascular cells; however how these processes occur is unclear. To further interrogate platelet RNA processes, we utilized sorting and RNA sequencing to develop platelet subpopulation transcriptome profiles. We found that platelet heterogeneity extends to the platelet transcriptome: distinct RNA profiles exist dependent on platelet size. We hypothesized that this RNA heterogeneity is the result of RNA transfer between platelets and vascular cells. Using in vitro and in vivo modeling, we were able to show the novel ability of platelets to take up RNA from vascular cells, correlating to the unique functional profile associated with small platelet transcriptomes. These findings reveal a role for platelet RNA transfer in platelet RNA heterogeneity, with potential correlation to platelet functional diversity previously proposed. The ability of the platelet to bidirectionally transfer RNA within circulation has implications for vascular health and beyond.

Platelets

RNA

RNA uptake

Biology

Cell Biology

Translational Medical Research

Toward Independent Home Use of Brain-Computer Interfaces: A Decision Algorithm for Selection of Potential End-Users

Kübler, Andrea, Holz, Elisa Mira, Sellers, Eric W., Vaughan, Theresa M.

01 January 2015

Noninvasive brain-computer interfaces (BCIs) use scalp-recorded electrical activity from the brain to control an application. Over the past 20 years, research demonstrating that BCIs can provide communication and control to individuals with severe motor impairment has increased almost exponentially. Although considerable effort has been dedicated to offline analysis for improving signal detection and translation, far less effort has been made to conduct online studies with target populations. Thus, there remains a great need for both long-term and translational BCI studies that include individuals with disabilities in their own homes. Completing these studies is the only sure means to answer questions about BCI utility and reliability. Here we suggest an algorithm for candidate selection for electroencephalographic (EEG)-based BCI home studies. This algorithm takes into account BCI end-users and their environment and should assist in study design and substantially improve subject retention rates, thereby improving the overall efficacy of BCI home studies. It is the result of a workshop at the Fifth International BCI Meeting that allowed us to leverage the expertise of multiple research laboratories and people from multiple backgrounds in BCI research.

feasibility study

rehabilitation

reproducibility of results

translational medical research

Psychology

SURFACE-INITIATED POLYMERIZATIONS FOR THE RAPID SORTING OF RARE CANCER CELLS

Lilly, Jacob L.

01 January 2016

Cancer metastasis directly accounts for an estimated 90% of all cancer related deaths and is correlated with the presence of malignant cells in systemic circulation. This observed relationship has prompted efforts to develop a fluid biopsy, with the goal of detecting these rare cells in patient peripheral blood as surrogate markers for metastatic disease as a partial replacement or supplement to tissue biopsies. Numerous platforms have been designed, yet these have generally failed to support a reliable fluid biopsy due to poor performance parameters such as low throughput, low purity of enriched antigen positive cells, and insufficiently low detection thresholds to detect poor expressed surface markers of target cell populations. This work describes the development of a rapid cell sorting technology called Antigen Specific Lysis (ASL) based on photo-crosslinked polymer encapsulation to isolate tumor cells in suspension. In the first study, we characterize the chemical and structural properties of the surface-initiated polymer films formed directly on mammalian cell surfaces. Coated populations are shown to remain highly viable after coating formation. Biomolecular transport is examined though film coatings on cellular substrates using fluorescent, time-resolved confocal microscopy and diffusivity estimates are generated for these materials. In the next study, a lysis-based cell isolation platform is described in which marker positive cells can be specifically coated in a heterogeneous cell suspension. Anionic surfactants lyse virtually 100% of uncoated cells while fully encapsulated cells remain protected, and are then easily collected by centrifugation. We report that purified cells are released from polymeric coatings to yield viable and functional populations. We monitor cell response throughout the isolation process by multiple techniques, and report viability >80% after the sorting process. Lastly, we examine the response of process yield on the level of photoinitiator loading on target populations. Streptavidin-fluorochrome loading was quantitatively assessed on a panel of markers, both epithelial and mesenchymal, on representative model breast and lung cancer cells. We report that ASL is fundamentally capable of achieving 50-60% yield which is promising for fluid biopsy applications. Finally, both EpCAM and metastatic targeting strategies are then compared to covalently biotinylated samples to inform future robust targeting strategies.

cancer

cell sorting

photopolymerization

thin films

surface coatings

cell encapsulation

Biomaterials

Polymer Science

Translational Medical Research

Sildenafil and celecoxib interact to kill breast cancer cells

Binion, Brittany

01 January 2014

Breast cancer is the second most commonly diagnosed cancer among American women and is responsible for the second highest number of cancer-related deaths. Targeted therapeutic agents sildenafil, a phosphodiesterase type 5 inhibitor, and celecoxib, a cyclooxygenase-2 inhibitor, have been used individually in conjunction with other chemotherapeutic agents to enhance cell killing in a variety of cancers. Sildenafil when combined with traditional chemotherapeutic drugs, such as the taxanes and anthracyclines, or celecoxib combined with traditional hormone therapies have been used to increase cytotoxicity and cell killing. The data presented here demonstrates that the novel combination of sildenafil and celecoxib work together to enhance cell killing in both receptor positive and triple negative breast cancer through the induction of autophagy, ER stress, as well as both intrinsic and extrinsic apoptosis.

sildenafil

celcoxib

BT474

BT549

breast cancer

Cancer Biology

Neoplasms

Translational Medical Research

Targeting Autophagy in Multiple Myeloma

Dai, Yun

01 January 2015

Apoptosis (Type I) and autophagy (Type II) represent two major forms of programmed cell death. Numerous anticancer agents employed in standard chemotherapy or novel targeted therapy induce both apoptosis and autophagy. Of note, a cytoprotective autophagic response often counteracts apoptosis triggered by such agents, potentially contributing to drug-resistance. Mechanistically, autophagy and apoptosis share molecular regulatory mechanisms primarily governed by the Bcl-2 family proteins. However, since autophagy acts as the double-edge sword in cancer, whether autophagy should be inhibited or activated in cancer treatment remains the subject of debate. Here we report a) a novel autophagy-targeted strategy that targeting the adaptor SQSTM1/p62 induces “inefficient” autophagy due to cargo-loading failure and converts cytoprotective autophagic response to apoptosis via the BH3-only protein NBK/Bik (Part 1); and b) a new mechanism for acquired drug-resistance in which the BH3-only protein Bim acts as a dual-agent regulating both autophagy and apoptosis (Part 2).

apoptosis

autophagy

targeted therapy

drug-resistance

SQSTM1/p62

NBK/Bik

Bim

Translational Medical Research

INTRODUCING NOVEL COMBINATORIAL TARGETED THERAPIES IN MULTIPLE TYPES OF CANCER

Tavallai, Mehrad

01 January 2016

The cancers of liver, colon and breast are amongst the top five most prevalent and most fatal worldwide. As the Raf/MEK/ERK pathway is frequently deregulated in hepatocellular carcinoma (HCC), sorafenib, a Raf kinase inhibitor, became the first systemic therapy approved for the treatment of patients with HCC. However, sorafenib only produced modest effects with low response rates in the clinic. Similarly, regorafenib, which was approved for the treatment of metastatic colorectal cancer (CRC), has had a poor response rate in the clinic. Since phosphodiesterase type 5 has been reported to be overexpressed in HCC and CRC, we hypothesized that sildenafil, a phosphodiesterase type 5 inhibitor, could enhance the toxicities of sorafenib and regorafenib in HCC and CRC cells, respectively. Our in vitro data indicated that the drugs interacted strongly to kill cancer cells via induction of ER stress, autophagy and apoptosis. In accordance with these findings, our in vivo data demonstrated a significant reduction in tumor growth. The second study in this manuscript was conducted based on the growing body of evidence about the significant contribution of EGFR and JAK/STAT signaling to the breast tumorigenesis. Our preliminary in vitro data demonstrated that the concurrent inhibition of these two pathways by lapatinib, a dual ERBB1/2 inhibitor, and ruxolitinib, a JAK1/2 inhibitor, synergistically killed breast cancer cells of all types, including the resistant triple negative subtype. Our mechanistic studies showed that the combination of ruxolitinib and lapatinib triggered cytotoxic mitophagy, and autophagy-dependent activation of BAX and BAK leading to the mitochondrial dysfunction.

Targeted Therapy

Sorafenib

Regorafenib

PDE5 inhibitors

Ruxolitinib

Lapatinib

Cancer Biology

Translational Medical Research

Characterizing the Oncogenic Properties of C-terminal Binding Protein

Sumner, Evan T

01 January 2016

The paralogous C-terminal binding proteins (CtBP) 1 and 2 are evolutionarily conserved transcriptional coregulators that target and disrupt the expression of several genes essential for multiple cellular processes critical to regulating tumor formation. CtBP’s ability to govern the transcription of genes necessary for apoptosis, tumor suppression, invasion/migration and EMT gives rise to its oncogenic activities. Both isoforms of CtBP are found to be overexpressed in cancers including colorectal, pancreatic, ovarian, and breast, with higher levels correlating to lower overall median survival. Although multiple lines of evidence suggest CtBP plays a role in tumorigenesis, it has never been formally characterized as an oncogene. For this reason, the goal of this dissertation was to design a set of experiments to determine the transforming ability of CtBP2 in vitro using both murine and human fibroblast and in vivo using the Apcmin/+ mouse model of cancer. Specifically, we demonstrate that overexpression of CtBP2 alone can drive transformation of NIH3T3 cells leading to loss of contact inhibition, increased x invasion/migration, and anchorage independent growth. In addition, CtBP2 was found to cooperate with the large T-antigen (LT) component of the simian virus 40 (SV40) to lead to transformation of murine embryonic fibroblasts (MEFs) and with both LT and small T-antigen (ST) to induce migration/invasion and anchorage-independent growth in BJ human foreskin fibroblasts. To confirm the role of Ctbp2 in a mouse tumor model with Ctbp overexpression, we bred Apcmin/+ mice to Ctbp2 heterozygous (Ctbp2+/-) mice, which otherwise live normal lifespans. CtBP is a known target of the APC tumor suppressor and is thus stabilized in APC mutated human colon cancers and is found in high levels in Apcmin/+ polyps. Remarkably, removing an allele of Ctbp2 doubled the median survival of Apcmin/+ mice (P <0.001) and reduced polyp formation to near undetectable levels. These data suggest the importance of CtBP2 in driving cellular transformation and identify it as a potential target for prevention or therapy in APC mutant backgrounds.

Cancer Biology

Molecular Genetics

Oncology

Translational Medical Research

Radioprotective Cerium Oxide Nanoparticles: Molecular Imaging Investigations of CONPs’ Pharmacokinetics, Efficacy, and Mechanisms of Action

McDonagh, Philip R, III

01 January 2016

Cerium oxide nanoparticles (CONPs) are being investigated for several anti-oxidant applications in medicine. One of their most promising applications is as a radioprotective drug, an area of research in need due to the severe side effects from radiation therapy. In this work, the potential of CONPs as a radioprotective drug is examined using four criteria: favorable biodistribution/pharmacokinetics, low toxicity, ability to protect normal tissue from radiation damage, and lack of protection of tumor. The mechanisms of action of CONPs are also studied. Biodistribution was determined in radiolabeled CONPs with surface coatings including citrate, dextran T10-amine (DT10-NH2), dextran T10-polyethylene glycol (DT10-PEG), dextran T10-sulfobetaine (DT10-SB) and poly(acrylic acid) (PAA), and compared to uncoated. 89Zr was incorporated into CONPs for positron emission tomography (PET) imaging and ex vivo tissue analysis in tumor bearing mice. Compared to uncoated [89Zr]CONPs, coated [89Zr]CONPs showed improved biodistribution, including significantly enhanced renal clearance of PAA- [89Zr]CONPs. The toxicity of CONPs was evaluated in vitro and in vivo, with low toxicity at therapeutic doses. After clinically mimetic radiation therapy, pre-treatment of mice with coated and uncoated CONPs showed greater than 50% reduction of cell death in normal colon tissue, comparable to the clinically available radioprotective drug amifostine. Tumor control after irradiation of spontaneous colon tumors was unchanged with PAA-CONP pre-treatment, while citrate, DT10-PEG, and uncoated CONP pre-treatment had slightly less tumor control. Xenograft tumors were irradiated after pH normalizing treatment with sodium bicarbonate and PAA-CONP pre-treatment. Treatment of these tumors showed slightly less tumor control than irradiation alone or PAA-CONP plus irradiation, demonstrating that the acidic pH of the tumor microenvironment may be the basis of preventing CONPs’ radioprotective properties in tumor. These studies show that, among the variations of CONPs tested, PAA-CONP shows the most promise for its good biodistribution and quick clearance, low toxicity, ability to protect normal tissue, and lack of protection of tumor, meeting all the criteria set forth for an ideal radioprotective drug. Further studies on the effects of pH on CONPs actions may further elucidate their mechanisms of action, advancing them as a candidate for use as a radioprotective drug during radiation therapy.

cerium oxide nanoparticles

nanomedicine

molecular imaging

PET imaging

pharmacokinetics

radioprotection

Nanomedicine

Translational Medical Research

NEW INSIGHTS INTO POST-SEPSIS MUSCLE WEAKNESS ELUCIDATED USING A NOVEL ANIMAL MODEL

Steele, Allison M.

01 January 2017

Sepsis is a severe life-threatening critical illness that damages multiple physiological systems. After hospital discharge, more than 70% of severe sepsis survivors report profound weakness which significantly impacts quality of life. Such weakness gives rise to new limitations of daily living, which ultimately leads to loss of independence in many patients. Despite wide recognition of this serious issue by clinicians and researchers alike, the mechanisms contributing to chronic skeletal muscle dysfunction after sepsis are not well understood. Lack of progress in this field is largely due to the absence of an appropriate animal model; current models are either too mild to induce muscle weakness or too severe and cause death within a few days. As such, this dissertation work first focused on establishing a clinically-relevant animal model of sepsis which yields surviving mice with chronic skeletal muscle weakness (Aim 1). This aim involved refining the cecal slurry injection model of polymicrobial sepsis in young adult animals, as well as optimizing the timing, duration, and dose of multiple therapeutic agents. The resulting resuscitation protocol was adapted for use in late-middle-aged animals, and muscle strength was evaluated using an ex vivo system which confirmed significant muscle weakness in sepsis survivors, long after sepsis was resolved. Next, using this novel model, we sought to characterize sepsis-induced long-term muscle dysfunction at the molecular level (Aim 2). The first set of experiments under this aim was designed to identify the primary global mechanism(s) (i.e. atrophy, polyneuropathy, and/or myopathy) responsible for muscle weakness in sepsis survivors. Analysis of the force-frequency curves and specific force measurements led to the conclusion that myopathy is the primary cause. Electron micrograph observation, functional assays, and protein analysis then showed that sepsis survivors’ skeletal muscles are characterized by profound mitochondrial abnormalities and oxidative damage. Collectively, these studies demonstrate that long-term muscle weakness is apparent in sepsis-surviving animals, and the functional decline is associated with unresolved mitochondrial damage and dysfunction. This work suggests that medical treatments beyond targeting muscle wasting alone could allow sepsis survivors to regain function and return to productive lives.

Mitochondria

Muscle weakness

Myopathy

Oxidative damage

Sepsis

Critical Care

Musculoskeletal Diseases

Translational Medical Research