Abstract

The promise of molecular targeted therapy for cancer is to provide selective killing of tumor cells while sparing normal cells. Targeted therapy, however, requires that the oncogenic pathways activated in tumor cells can be defined, and that selective inhibitors can be found to abrogate these pathways. One major limitation to targeted therapeutic approaches is that many oncogenic pathways, especially those involving transcription factors, cannot be directly inhibited with small molecule compounds. An alternative approach is to use small molecule inhibitors that target basic cellular processes, such as the cell cycle, which merely arrest normal cells, but which in combination with activation of particular oncogenic pathways result in synthetic-lethal combinations. Cyclin-dependent kinases (CDKs) are a conserved family of protein kinases that play a central role in regulating the eukaryotic cell cycle. CDK1 and CDK2 are thought to be particularly important for driving the major cell cycle events in normal and neoplastic mammalian cells and these kinases might therefore be important targets for cancer therapy. The overall hypothesis that is being tested is whether inhibition of different CDKs can result in selective killing of tumor versus normal cells. (1) We seek to determine the genetic context in which cells are rendered especially sensitive to CDK inhibitors, resulting in cell death or another abortive cell cycle program. (2) We seek to determine how MYC oncogene over- expression sensitizes to cell death following CDK1 inhibition. (3) We seek to understand the molecular basis for cell death induced by CDK inhibition. To accomplish our goals we will utilize two complementary approaches to address this question. Both conventional small-molecule CDK inhibitors as well as a chemical-genetic approach will be employed to identify the genetic context in which CDK inhibitors may prove to be useful therapeutics. Our hypothesis, if confirmed, will significantly improve our understanding of how CDK inhibitors may be useful to target specific oncogenic pathways and should lead to novel therapeutics for cancer.

Public Health Relevance

Normal cellular proliferation requires an orderly progression through the cell cycle that involves multiple regulatory enzymes. In contrast, cancer cells proliferate inappropriately and without end resulting in a tumor mass. Since tumor cells proliferate inappropriately, precise inhibition of the cell cycle may lead to the death of tumor cells while normal cells may be spared. The goal of this proposal is to determine if selective inhibition of cell cycle regulatory enzymes, known as cyclin-dependent kinases (CDKs), can cause the arrest or perhaps death of tumor cells. The knowledge gained from these studies will facilitate the development of new therapeutics that target tumor cells with particular genetic changes by precisely inhibiting the cell division cycle.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Cancer Institute (NCI)
Type
Research Project (R01)
Project #
5R01CA136717-03
Application #
8220841
Study Section
Cancer Molecular Pathobiology Study Section (CAMP)
Program Officer
Arya, Suresh
Project Start
2010-04-19
Project End
2015-01-31
Budget Start
2012-02-01
Budget End
2013-01-31
Support Year
3
Fiscal Year
2012
Total Cost
$361,902
Indirect Cost
$125,546

  Institution

Name
University of California San Francisco
Department
Internal Medicine/Medicine
Type
Schools of Medicine
DUNS #
094878337
City
San Francisco
State
CA
Country
United States
Zip Code
94143

  Publications

Anderton, Brittany; Camarda, Roman; Balakrishnan, Sanjeev et al. (2017) MYC-driven inhibition of the glutamate-cysteine ligase promotes glutathione depletion in liver cancer. EMBO Rep 18:569-585
Wang, Eric S; Reyes, Nichole A; Melton, Collin et al. (2015) Fas-Activated Mitochondrial Apoptosis Culls Stalled Embryonic Stem Cells to Promote Differentiation. Curr Biol 25:3110-8
Lawson, Devon A; Bhakta, Nirav R; Kessenbrock, Kai et al. (2015) Single-cell analysis reveals a stem-cell program in human metastatic breast cancer cells. Nature 526:131-5
Brondfield, Sam; Umesh, Sushma; Corella, Alexandra et al. (2015) Direct and indirect targeting of MYC to treat acute myeloid leukemia. Cancer Chemother Pharmacol 76:35-46
Huskey, Noelle E; Guo, Tingxia; Evason, Kimberley J et al. (2015) CDK1 inhibition targets the p53-NOXA-MCL1 axis, selectively kills embryonic stem cells, and prevents teratoma formation. Stem Cell Reports 4:374-89
Martins, Maria M; Zhou, Alicia Y; Corella, Alexandra et al. (2015) Linking tumor mutations to drug responses via a quantitative chemical-genetic interaction map. Cancer Discov 5:154-67
Horiuchi, Dai; Anderton, Brittany; Goga, Andrei (2014) Taking on challenging targets: making MYC druggable. Am Soc Clin Oncol Educ Book :e497-502
Benjamin, Daniel I; Louie, Sharon M; Mulvihill, Melinda M et al. (2014) Inositol phosphate recycling regulates glycolytic and lipid metabolism that drives cancer aggressiveness. ACS Chem Biol 9:1340-50
Lim, Lionel; Balakrishnan, Asha; Huskey, Noelle et al. (2014) MicroRNA-494 within an oncogenic microRNA megacluster regulates G1/S transition in liver tumorigenesis through suppression of mutated in colorectal cancer. Hepatology 59:202-15
Cheng, Christine K; Gustafson, W Clay; Charron, Elizabeth et al. (2012) Dual blockade of lipid and cyclin-dependent kinases induces synthetic lethality in malignant glioma. Proc Natl Acad Sci U S A 109:12722-7

Showing the most recent 10 out of 17 publications