Characterization of Primary Esophageal/Gastro-esophageal Junction Cancer Xenograft Models and their Effectiveness in Studying Chemosensitivity

Dodbiba, Lorin

18 June 2014

Primary esophageal (E) and gastro-esophageal junction (GEJ) cancer xenografts have the potential to become useful pre-clinical models of disease. In this study, we determined that p16 negative tumors that have not been exposed to neo-adjuvant chemo-radiation have higher engraftment chances. Morphological features and expression of certain molecular markers (p53, p16, Ki-67, EGFR, Her-2/neu) suggest that no major changes occur between primary tumors and xenografts or between early passage and late passage xenografts. Global gene expression data supported these results but revealed that approximately 2000 genes differed significantly between passage one xenografts and human tumors. Most of these genes, however, might coincide with stromal signals present in patient tumors but absent in xenografts. Primary E/GEJ cancer xenografts also showed a wide range of chemosensitivities to cisplatin-paclitaxel treatment, confirming the usefulness of these models in drug testing. These models also revealed potential ways to interrogate tumor initiating cell (TIC) dynamics after chemotherapy.

primary tumour xenografts

esophageal cancer

gastro-esophageal junction cancer

engraftment

0992

0307

0379

Auger Electron-emitting Radioimmunotherapeutic (RIT) Agent Specific for Leukemic Stem Cells

Gao, Jin Hua

04 July 2013

Objective: CSL360 is a chimeric IgG1 mAb recognizing CD123+/CD131- LSCs responsible for acute myeloid leukemia (AML). The in vitro targeting properties of 111In-labeled CSL360 modified with nuclear localization sequence (NLS) were evaluated in AML cells. Methods: 111In-NLS-CSL360 was constructed and its binding affinity, cellular uptake and nuclear importation were analyzed on CD123+ cells. Cytotoxicity was evaluated by clonogenic assays on AML cells (CD123+/CD131-). Results: 111In-NLS-CSL360 exhibited preserved binding to CD123. High cellular and nuclear uptake was observed at 266 nM after 24 hour of incubation. Nuclear uptake of 111In-NLS-CSL360 (266 nM) was 2.0-fold higher than 111In-CSL360 (266 nM) after 24 hour of incubation. Clonogenic survival (CS) of AML cells was reduced to 27.5 ± 4.1%. The nuclear uptake and cytotoxicity were reduced when pre-exposed to unlabeled CSL360, indicating 111In-NLS-CSL360 was CD123-specific. Conclusion: 111In-NLS-CSL360 could be a promising radioimmunotherapeutic agent specific for LSCs.

auger electron radioimmunotherapy

acute myeloid leukemia

leukemic stem cells

CD123

111-indium

0491

0992

0756

Auger Electron-emitting Radioimmunotherapeutic (RIT) Agent Specific for Leukemic Stem Cells

Gao, Jin Hua

04 July 2013

Objective: CSL360 is a chimeric IgG1 mAb recognizing CD123+/CD131- LSCs responsible for acute myeloid leukemia (AML). The in vitro targeting properties of 111In-labeled CSL360 modified with nuclear localization sequence (NLS) were evaluated in AML cells. Methods: 111In-NLS-CSL360 was constructed and its binding affinity, cellular uptake and nuclear importation were analyzed on CD123+ cells. Cytotoxicity was evaluated by clonogenic assays on AML cells (CD123+/CD131-). Results: 111In-NLS-CSL360 exhibited preserved binding to CD123. High cellular and nuclear uptake was observed at 266 nM after 24 hour of incubation. Nuclear uptake of 111In-NLS-CSL360 (266 nM) was 2.0-fold higher than 111In-CSL360 (266 nM) after 24 hour of incubation. Clonogenic survival (CS) of AML cells was reduced to 27.5 ± 4.1%. The nuclear uptake and cytotoxicity were reduced when pre-exposed to unlabeled CSL360, indicating 111In-NLS-CSL360 was CD123-specific. Conclusion: 111In-NLS-CSL360 could be a promising radioimmunotherapeutic agent specific for LSCs.

auger electron radioimmunotherapy

acute myeloid leukemia

leukemic stem cells

CD123

111-indium

0491

0992

0756

The Role of Fatty Acid Synthase Over-expression in Human Breast Cancer

Hopperton, Kathryn

20 November 2012

Fatty acid synthase (FAS) is over-expressed in many human cancers and its activity is required for cancer cell survival. To understand why FAS is over-expressed, we compared in breast cancer cells the utilization of fatty acids synthesized endogenously by FAS to those supplied exogenously in the culture medium. We found that endogenously synthesized fatty acids are esterified to the same lipid and phospholipid classes in the same proportions as those derived exogenously and that some endogenous fatty acids are excreted. Thus, FAS over-expression in cancer does not fulfill a specific requirement for endogenously synthesized fatty acids. We next investigated whether lipogenic activity mediated by FAS was, instead, involved in the maintenance of high glycolytic activity in cancer cells. By culturing breast cancer and non-cancer cells in anoxic conditions, we increased glycolysis 2-3 fold but observed no concomitant increase in lipogenesis. More research is needed to understand why FAS is over-expressed in cancer.

fatty acid synthase

breast cancer

cancer metabolism

aerobic glycolysis

0570

0992

SATB2 is a Modulator of p63(alpha) in Cancer and Development

Chung, Jacky

14 August 2013

p63(alpha) belongs to the p53-family of proteins and has full-length (TA) as well as truncated ((delta)N) p63(alpha) isoforms. Previous studies have shown that TA and (delta)Np63(alpha) play multiple roles in cancer and development. In cancer, (delta)Np63(alpha)-mediated transcriptional repression promotes oncogenesis while transactivation by TAp63(alpha) is critical during development. Despite their importance, little is known regarding how TA or (delta)Np63(alpha) is regulated and factors influencing the function of p63(alpha) have yet to be identified. Here, I identify Special AT-rich Binding Protein 2 (SATB2) as a protein that forms a complex with and modulates the function of p63(alpha). SATB2 is detected in multiple head and neck squamous cell carcinoma (HNSCC) cell lines that also show overexpression of (delta)Np63(alpha). Histological analysis on tumor specimens revealed that SATB2 is predominantly expressed in advanced-stage HNSCC cancers. SATB2 increases DNA-binding capabilities of (delta)Np63(alpha), augmenting (delta)Np63(alpha) repression of apoptotic gene expression. Knockdown of SATB2 in HNSCC cells sensitizes cancer cells towards chemotherapy- and radiation-induced apoptosis. These results indicate that SATB2 functions as a co-factor and promotes the transrepression function of (delta)Np63(alpha) in HNSCC. In addition to examining the role of SATB2 in HNSCC, I also investigated the effect of SATB2 on the ability of TAp63(alpha) to induce gene expression. In particular, perp has been shown to be a critical downstream target of p63 during development. ChIP analysis revealed that while SATB2 increases TAp63(alpha)-binding to apoptotic gene promoters, SATB2 decreases TAp63(alpha) localization on the perp promoter and inhibits p63(alpha)-mediated perp induction. SATB2 more readily interacts with human disease-associated p63(alpha) mutations that are found in the SAM domain, further inhibiting transcriptional properties of these mutants. Together, my results suggest that SATB2 is an important modulator of p63(alpha) in cancer and development.

p63

SATB2

Squamous Cell Carcinoma

Ectoderm Development

0992

0307

0379

0369

A Novel Lipid-based Nanotechnology Platform For Biomedical Imaging And Breast Cancer Chemotherapy

Shuhendler, Adam Jason

15 August 2013

A novel, lipid-based platform nanotechnology has been designed to overcome limitations of in vivo fluorescent imaging, multidrug resistance (MDR) phenotypes hindering breast cancer chemotherapy, and shortcomings of magnetic resonance imaging (MRI) thermometry. Using this platform, three nanoparticle systems have been developed: QD-SLN (quantum dot-loaded solid lipid nanoparticles), DMsPLN (doxorubicin and mitomycin C co-loaded polymer-lipid hybrid nanoparticles), and HLN (hydrogel-lipid hybrid nanoparticles). Stealth, near-infrared emitting QD-SLN were developed for deep tissue fluorescence imaging, which were capable of extending the depth of penetration beyond 2 cm, with near complete probe clearance and good tolerability in vivo. The QD-SLN was used to evaluate the biodistribution of non-targeted SLN and actively targeted RGD-conjugated SLN. Non-targeted SLN accumulated in breast tumors and evaded liver uptake. The RGD-SLN showed prolonged retention in breast tumor neovasculature at the cost of lesser tumor accumulation due to enhanced liver uptake. With this information, a long circulating, non-targeted DMsPLN with a synergistic cancer chemotherapeutic combination of doxorubicin and mitomycin C was formulated to overcome MDR, enhancing breast cancer chemotherapy. Extensive tumor cell uptake and perinuclear trafficking of DMsPLN overcame the MDR phenotype of breast tumor cells in vitro. The DMsPLN provided the most efficacious chemotherapy reported in literature against aggressive mouse mammary tumors in vivo with significant reduction in whole animal and cardiotoxicity as compared to clinically applied liposomal doxorubicin. In establishing our tumor models, the impact of Matrigel™ on the tumor microenvironment was investigated, demonstrating altered tumor vascular and lymphatic anatomy and physiology, and significantly impacting nanomedicines assessment in mouse models of cancer. In all in vivo studies, tumors were established without use of Matrigel™. To guide thermotherapy of solid tumors, a novel HLN was formulated for use in MRI thermometry, presenting the first contrast agent capable of indicating a tunable, absolute two-point temperature window. In using specific limitations of therapeutic and imaging modalities to inform rational nanoparticle design, this lipid-based platform nanotechnology has extended the application of fluorescence imaging in vivo, enhanced the utility of nanoparticulate chemotherapeutics against breast cancer independent of MDR status, and provided novel functionality for MRI thermometry.

Nanotechnology

Breast Cancer

Multidrug Resistance

MRI Thermometry

In Vivo Fluorescence Imaging

Integrin Receptor Targeting

0541

0992

0572

Integrative Preoteomic Analysis of Cell Line Conditioned Media and Pancreatic Juice for the Identification of Candidate Pancreatic Cancer Biomarkers

Makawita, Shalini

04 September 2012

Novel serological biomarkers to aid in the detection and clinical management of pancreatic cancer patients are urgently needed. In the present study, we performed in-depth proteomic analysis of conditioned media from six pancreatic cancer cell lines (MIA-PaCa2, PANC1, BxPc3, CAPAN1, CFPAC1 and SU.86.86), the normal pancreatic ductal epithelial cell line HPDE, and pancreatic juice samples from cancer patients for identification of novel biomarker candidates. Using 2D-LC-MS/MS, a total of 3479 non-redundant proteins were identified with ≥2 peptides. Subsequent label-free protein quantification and integrative analysis of the biological fluids resulted in the generation of candidate biomarkers, of which five proteins were shown to be significantly elevated in plasma from pancreatic cancer patients in a preliminary assessment. Further verification of two of the proteins in ~200 serum samples demonstrated the ability of these proteins to significantly improve the area under the receiver operating characteristic curve of CA19.9 from 0.84 to 0.91.

Pancreatic Cancer

Proteomics

Serum Biomarkers

Mass Spectrometry

Cell Line Conditioned Media

Pancreatic Juice

Bioinformatics

0992

A Systematic Review and Appraisal of International Early Breast Cancer Guidelines for Systemic Therapy, and a Global Physician Survey Examining Practice Patterns by Resource Setting: Potential Implications for International Health Policy

Gandhi, Sonal

19 July 2012

Breast cancer is a growing international health epidemic, and patients in low and middle income countries (LMCs) have worse outcomes than those in high income countries. High quality, well-implemented guidelines help improve patient outcomes, but are often not resource-sensitive, and support therapies that may not be feasible in LMCs. A systematic review to address the content, quality, and resource-sensitivity of international breast cancer guidelines was completed. Also, a survey of global physicians evaluated the impact of resource setting on practice patterns and guideline use. Guideline use did not appear to be directed by quality (which was variable across guidelines) or resource-sensitivity (found in few guidelines). However, practice patterns were found to vary by resource setting and by continent, often due to the cost of certain therapies. In order for guidelines to better impact global breast cancer outcomes, they need to be of higher quality, more resource-sensitive, and better implemented.

breast cancer

guidelines

adjuvant

therapy

international

global

practice

policy

low and middle income

resources

0992

0564

0769

A Journey down the Cell Death Pathway of Mitochondria-targeted Chlorambucil

Mourtada, Rida

26 November 2012

Our lab recently demonstrated that retargeting an alkylating agent, chlorambucil (Cbl), to the mitochondrion is a viable strategy to restore drug activity and overcome drug resistance in cancer. The mechanism of action of the mitochondria-targeted chlorambucil (mt-Cbl) was studied using a cervical carcinoma model. It was discovered that mt-Cbl bound to mitochondrial DNA and various mitochondrial proteins. A ρ° model revealed that the toxicity of mt-Cbl is largely dependent on its protein targets. Damage induced by mt-Cbl was found to result in the activation of several modes of caspase-independent cell death including necrosis. In contrast, Cbl was found to only activate caspase-dependent cell death that is highly sensitive to caspase inhibition. These results illustrate that the ability of mt-Cbl to activate various orthogonal cell death pathways is what allows mt-Cbl to bypass several drug resistance mechanisms, thus making mitochondrial retargeting a lucrative strategy for future anticancer drug development.

Mitochondria

Cancer

Mitochondria Penetrating Peptide

Chlorambucil

Cell Death

Necrosis

0992

0572

0307

Investigation into the Role of CBL-B in Leukemogenesis and Migration

Badger-Brown, Karla Michelle

15 September 2011

CBL proteins are E3 ubiquitin ligases and adaptor proteins. The mammalian homologs – CBL, CBL-B and CBL-3 show broad tissue expression; accordingly, the CBL proteins play roles in multiple cell types. We have investigated the function of the CBL-B protein in hematopoietic cells and fibroblasts. The causative agent of chronic myeloid leukemia (CML) is BCR-ABL. This oncogenic fusion down-modulates CBL-B protein levels, suggesting that CBL-B regulates either the development or progression of CML. To assess the involvement of CBL-B in CML, bone marrow transduction and transplantation (BMT) studies were performed. Recipients of BCR-ABL-infected CBL-B(-/-) cells succumbed to a CML-like myeloproliferative disease with a longer latency than the wild-type recipients. Peripheral blood white blood cell numbers were reduced, as were splenic weights. Yet despite the reduced leukemic burden, granulocyte numbers were amplified throughout the animals. As well, CBLB(-/-) bone marrow (BM) cells possessed defective BM homing capabilities. From these results we concluded that CBL-B negatively regulates granulopoiesis and that prolonged latency in our CBL-B(-/-) BMT animals was a function of perturbed homing.To develop an in vitro model to study CBL-B function we established mouse embryonic fibroblasts (MEFs) deficient in CBL-B expression. Transduction of the wild-type and CBL-B-deficient MEFs with BCR-ABL did not confer transformation; nevertheless, the role of CBL-B in fibroblasts was evaluated. The CBL-B(-/-) MEFs showed enhanced chemotactic migration toward serum in both Transwell migration and time-lapse video microscopy studies. The biochemical response to serum was extensively evaluated leading to the development of a model. We predict that CBL-B deficiency either: (a) augments GRB2-associated binding protein 2 (GAB2) phosphorylation leading to enhanced extracellular signal-regulated kinase (ERK) and protein kinase B (PKB / Akt) signaling, or (b) alleviates negative control of Vav3 resulting in stimulation of Rho effectors. In either case, our results reveal a negative regulatory role for CBL-B in fibroblast migration. The two studies detailed herein expand our knowledge of CBL-B function. They strongly suggest that CBL-B can modulate granulocyte proliferation and point toward a role for CBL-B in the motility of numerous cell types.

cancer

myeloproliferative disease

BCR-ABL

CBL-B

fibroblasts

migration

chronic myeloid leukemia

bone marrow transplantation

0992