Identification of personalized adaptive response mechanisms in breast cancer by information theory and proteomics
Overview
Project Name
Identification of personalized adaptive response mechanisms in breast cancer by information theory and proteomics
Project Summary
Over the past decade the accumulation of large-scale systems level data sets has occurred at an accelerating pace. Unfortunately, to date this massive accumulation of biological and medical information has rarely translated into truly efficacious therapies that dramatically alter the course of disease. Clearly new informatics approaches are needed that will enable the identification of transformative therapeutics. Therefore, the central goal of this proposal is to develop an experimental-theoretical approach that defines, with high accuracy, the altered protein network structures present in each cancer malignancy. We propose to integrate quantitative mass spectrometry-based protein and protein phosphorylation measurements with surprisal analysis, a thermodynamic-based information theory approach, to resolve altered protein network structure in each malignancy. An altered network in each patients’ tumor may comprise several distinct, sometimes rewired, protein subnetworks that drive the molecular imbalance in cancer tissue. Identification of unbalanced subnetworks will highlight molecular nodes that will be targeted in each patient to either restore the basal, non-transformed state or to decrease tumor cell viability. To demonstrate the ability of this approach to define unbalanced subnetworks and their associated therapeutic targets, the proposal is divided into three phases with increasing complexity and physiological relevance. In the first phase, RTK networks in breast cancer cell lines representing different subtypes will be stimulated with natural ligands to induce well characterized unbalanced processes to validate the ability of surprisal analysis to identify these networks. In the second phase, unbalanced processes present in the basal, unstimulated state of each cell line will be defined. Therapeutic targeting of these processes, alone or in combination, at high and low dose, will be performed to assess the effect of complete vs. incomplete inhibition. Unbalanced processes mediating the development of therapeutic resistance during long-term low-dose treatment will be quantified at various time points to predict combination therapies to abrogate resistance. Finally, surprisal analysis will be used to identify unbalanced processes in vivo associated with chemotherapeutic resistance in triple negative breast cancer patient derived xenograft tumors. Nodes in these imbalanced networks will be targeted to decrease tumor viability. Combination with chemotherapy may sensitize even further the tumor cells to treatment. Through these efforts we aim to demonstrate the ability of this combined proteomic-surprisal analysis strategy to rationally design, with high-precision, patient-specific drug cocktails that prevent drug resistance development.
Investigators
Investigators
Forest White, PhD
Forest White is a Professor in the Department of Biological Engineering at the Massachusetts Institute of Technology (MIT). After receiving his Ph.D. from Florida State University in 1997 and completing a post-doc at the University of Virginia from 1997-1999, he joined MDS Proteomics as a Senior Research Scientist and developed phosphoproteomics capabilities for the company. In July 2003 he joined the Department of Biological Engineering at MIT. Research in the White lab is focused on understanding how protein phosphorylation-mediated signaling networks regulate normal and pathophysiological cell biology. Specific applications include novel drug target discovery in glioblastoma, analysis of mechanisms underlying therapeutic resistance and metastasis in cancer, and mechanisms underlying development of neurodegenerative diseases as well as Type II diabetes. This research is supported by grants from the National Institutes of Health and various pharmaceutical companies. In addition to his appointment in the Department of Biological Engineering, Forest is co-Chair of the Biological Engineering Graduate Program, a member of the Center for Precision Cancer Medicine, the Koch Institute for Integrative Cancer Research, and the Center for Environmental Health Sciences at MIT.
Nataly Kravchenko-Balasha, PhD
Nataly Kravchenko-Balasha is an Assistant Professor at the Hebrew University of Jerusalem. She is a systems and cancer biologist with experience in biophysical modeling of biological systems. She received her B.Sc. in Mathematics and Biology and PhD in Biochemistry from the Hebrew University of Jerusalem, where she characterized the reorganization of gene and protein networks in cancer progression, and the influence of that reorganization on cancer cell death, metabolism and drug treatments. During her postdoctoral training in biophysics and theoretical chemistry at the California Institute of Technology, Dr. Kravchenko-Balasha implemented the thermodynamic-based information-theoretic surprisal analysis in tumorigenesis, which beforehand was utilized only in chemistry, physics and engineering. The implementation of surprisal analysis in biology was motivated by the aim to create a quantitative, compact and predictive framework for understanding of non-equilibrium biological processes, often viewed as ‘complex’ biological phenomena. Her current interests lie in developing quantitative approaches to understand the dynamics of altered protein signaling networks in healthy and diseased tissues and to accelerate rational design of patient-specific cancer therapies. Additionally Dr. Kravchenko-Balasha combines theoretical modeling with quantitative experimental studies to study biophysics of cell-cell / cell-environment communication and cell migration.