I. Drug Resistance Due to Limited Drug Distribution Although our laboratory has shifted from studies of Pgp and ABCG2 in recent years to a focus on epigenetic therapies, we remain convinced that limited drug distribution likely contributes to drug resistance, and that there are likely diverse etiologies of limited drug distribution, one of which may be drug efflux pumps. This straightforward question cannot be answered: does restricted drug distribution play a role in cancer chemotherapy drug resistance? Numerous small trials measuring drug concentrations in tumor tissue, or pharmacodynamic imaging studies of labeled drug, suggest a wide range of drug distribution in cancer. We too observed variable uptake of a drug surrogate, sestamibi, in lung cancer. Nowhere is the issue of drug distribution more relevant than in the brain, where drug uptake is limited by the need to cross the blood brain barrier (BBB). Crossing the BBB requires an active process and evasion of the multidrug transporters ABCG2 and ABCB1, among other regulators of brain capillary endothelium. GRN1005 in CNS Metastases from Breast Cancer We have participated in a clinical trial of GRN1005, a novel drug conjugate that consists of three molecules of paclitaxel linked to a peptide that binds the LRP receptor. The conjugate was developed to cross the Blood Brain Barrier via transcytosis after binding the LRP receptor. Active drug is thought to be released in tumor cells when intracellular esterases cleave GRN1005 and release the free paclitaxel (107). Additionally, this conjugate is thought to evade the multidrug efflux transporters. GRN1005 (now ANG1005) was licensed by Geron Pharmaceuticals to conduct registration studies in glioblastoma and breast cancer after a positive signal in Phase I testing. We originally planned to participate in both a multi-institutional trial in breast cancer and to conduct a pilot trial that would include surgical resection of breast or lung cancer that had metastasized to the brain, to study the access of GNR1005 to metastatic lesions. Soon after the study opened, Geron announced that GRN1005 had failed to meet its first interim efficacy analysis - 0 responses among the first 30 patients accrued at 550 mg/m2 (whereas 4 of 13 patients (31%) had objective responses at 650 mg/m2). The trial was abruptly closed without further accrual; the multi-site PIs learned of this decision after the fact. However, review of data after the closure decision revealed that data were missing in 10 patients, and that the excessive toxicity that had led to the dose reduction to 550 mg/m2 included neutropenia in the absence of GCSF support. Geron returned the license for the drug to its original developer, Angiochem. Given our interest in this field, and our observation of activity of the agent in several NCI patients, we argued for and were allowed to keep open the NCI sub-study including FLT-PET imaging. We currently have one patient on study for over 8 months with a confirmed major response to GRN1005. II. A Novel Agent for Drug Resistant Cancers While there are multiple FDA-approved agents for renal cell cancer (RCC), all have a limited efficacy duration. To develop novel agents that would overcome or circumvent drug resistance without directly targeting drug efflux mechanisms, we collaborated with the NCI drug screen to identify com-pounds with particular activity in RCC in vitro and in xenografts (108,109). Although DNA appears to be the target for these compounds, they are unique as assessed by informatics evaluation. A lead compound, DMS612, was selected for Phase I, first in human studies carried out at the NCI (we serve as coordinating center), University of Pittsburgh, and Hershey Medical Center. We have tested 2 schedules - a day 1, 8, and 15 schedule that had cumulative thrombocytopenia as dose limiting toxicity, but minimal other toxicity. Two responses were observed; we are now studying a second schedule - day 1,2 administration every 21 days. Christophe Redon in the laboratory of William Bonner performed gamma-H2AX staining, documenting DNA damage in peripheral blood mononuclear cells and hair follicle cells, showing a dose response curve. DNA damage was more obvious in plucked hair bulbs than in PBMCs, appearing earlier and in greater numbers. While in PBMCs the signal at 3 mg/m2 was about 25% of that at 9 mg/m2 after 24 h, in the hair bulbs, it was 65%. In addition, damage was apparent earlier in the hair bulbs. Interestingly, DNA damage, as reflected by expression of gamma-H2AX, appeared to correlate with myelosuppression incidence and severity, supporting a hypothesis that DNA damage is biologically relevant to the mechanisms of action. Going Forward with DMS612 We plan to study DMS612 in the Phase II setting, first in RCC, using the day 1, 2 schedule. We will examine gamma-H2AX staining in hair follicles, PBMCs, and in tumor tissue where accessible. We recognize developing a novel agent in RCC will be challenging, since four VEGFR tyrosine kinase inhibitors, two mTOR inhibitors, and bevacizumab are approved by the FDA. We would argue that those agents have mechanistic overlap, and that agents with new mechanisms of action are needed since no existing therapy is curative. Further, the new immune checkpoint inhibitors may renew interest in immunogenic cell death inducers such as cytotoxic therapy (110). CTEP will support the trial in their Phase II centers and investigators have agreed to participate. Additional positive data could lead to studies in other tumor types. A potential selective biomarker was identified by Yves Pommier, who found that variants of a gene encoding a DNA repair protein, ATAD5, predicted cell sensitivity to DMS612. We have gathered samples from patients enrolled on the DMS612 Phase I study to perform ATAD5 sequencing. III. In collaboration with Dr. Tito Fojo, we have continued our efforts to characterize tumor growth kinetics and to evaluate whether those growth kinetics can be used to aid drug development. Dr. Wilfred Stein works on this highly productive project that may offer a paradigm shift for how drug effects can be assessed.

Agency
National Institute of Health (NIH)
Institute
National Cancer Institute (NCI)
Type
Investigator-Initiated Intramural Research Projects (ZIA)
Project #
1ZIABC010620-12
Application #
9153612
Study Section
Project Start
Project End
Budget Start
Budget End
Support Year
12
Fiscal Year
2015
Total Cost
Indirect Cost
Name
Basic Sciences
Department
Type
DUNS #
City
State
Country
Zip Code
Fojo, Antonio Tito; Bates, Susan E (2014) Clinical trial results: a clinical trial bazaar! Oncologist 19:313-4
Burotto, Mauricio; Wilkerson, Julia; Stein, Wilfred et al. (2014) Continuing a cancer treatment despite tumor growth may be valuable: sunitinib in renal cell carcinoma as example. PLoS One 9:e96316
Rubin, Eric H; Allen, Jeffrey D; Nowak, Jan A et al. (2014) Developing precision medicine in a global world. Clin Cancer Res 20:1419-27
Fojo, Antonio Tito; Bates, Susan E; Chabner, Bruce A (2013) Clinical trial results: Sharing results, speeding discoveries. Oncologist 18:779
Blagoev, Krastan B; Wilkerson, Julia; Stein, Wilfred D et al. (2013) Sunitinib does not accelerate tumor growth in patients with metastatic renal cell carcinoma. Cell Rep 3:277-81
Fojo, Tito; Bates, Susan (2013) Mechanisms of resistance to PARP inhibitors--three and counting. Cancer Discov 3:20-3
Amiri-Kordestani, Laleh; Basseville, Agnes; Kurdziel, Karen et al. (2012) Targeting MDR in breast and lung cancer: discriminating its potential importance from the failure of drug resistance reversal studies. Drug Resist Updat 15:50-61
Shaffer, Brian C; Gillet, Jean-Pierre; Patel, Chirayu et al. (2012) Drug resistance: still a daunting challenge to the successful treatment of AML. Drug Resist Updat 15:62-9
Stein, Wilfred D; Wilkerson, Julia; Kim, Sindy T et al. (2012) Analyzing the pivotal trial that compared sunitinib and IFN-? in renal cell carcinoma, using a method that assesses tumor regression and growth. Clin Cancer Res 18:2374-81
Sissung, Tristan M; Troutman, Sarah M; Campbell, Tessa J et al. (2012) Transporter pharmacogenetics: transporter polymorphisms affect normal physiology, diseases, and pharmacotherapy. Discov Med 13:19-34

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