Events Archive
2009
Individualizing the Axilla: The Next Frontier
Knapp Center for Biomedical Discovery (KCBD) 900 E, University of Chicago
Aberrant Wnt Signaling in Basal-like Breast Cancer
Knapp Center for Biomedical Discovery (KCBD) 900 E, University of Chicago
The Human Genome Project: Its Impact on Science and Medicine
Biological Sciences Learning Center, Room 001, University of Chicago
IGSB/GGSB Seminar Series
KCBD, Room 1103, University of Chicago
Reconstructing History with Genomic-Scale Data Sets, with Application to South Asia
Cummings Life Science Center 101, University of Chicago
Anti-Angiogenic PEDF in Hepatic Steatosis & HCC
KCBD- Room 1103, University of Chicago
Regulatory genomics approaches to investigate transcription control in Drosophila
KCBD, Room 1103, University of Chicago
A p53-Regulated Apoptotic Gene Signature Influences Response to Therapy
Knapp Center for Biomedical Discovery, Room 1103 9, University of Chicago
GENETIC CONTRIBUTIONS TO PROSTATE CANCER INITIATION AND PROGRESS
Biological Sciences Learning Center (BSLC) 924 E., University of Chicago
High-Throughput Cellular Screening
1001 University Place, Room 118AB NorthShore University HealthSystems Evanston, IL
Decoding the human epigenome
Cummings Life Science Center, Room W101 920 E. 58t, University Of Chicago
Is Systems Biology Becoming a Data Intensive Science? Assuming So, Are You Ready?
Knapp Center for Biomedical Discovery, Room 1103 9, University of Chicago
IGSB/GGSB Seminar Series | December 08, 2009
KCBD, Room 1103, University of Chicago
Phys-bio for Bioenergy, Biomedical and Material Sciences Research
KCBD, Room 1103, University of Chicago
Latest News
A Comprehensive Nuclear Receptor Network for Breast Cancer Cells
In breast cancer, nuclear receptors (NRs) play a prominent role in governing gene expression, have prognostic utility, and are therapeutic targets. We built a regulatory map for 24 NRs, six chromatin state markers, and 14 breast-cancer-associated transcription factors (TFs) that are expressed in the breast cancer cell line MCF-7.
The inner workings of the circadian clock
Center Investigator Michael Rust and colleagues reveals the biochemical mechanisms that allow the oscillations of the cyanobacterial biological clock to be tuned to changes in the environment while simultaneously maintaining a robust 24-hour period.