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Purdue University
School of Chemical Engineering
GRADUATE SEMINAR SERIES
Dr. Jeremiah Zartman
Department of Chemical and Biomolecular Engineering
University Notre Dame
“Engineering Approaches to Investigate the Regulation of Epithelial Growth
and Homeostasis”
Tuesday, November 17 2015
3:00 - 4:15 p.m.
FRNY G140
Reception at 2:30 p.m. in Henson Atrium
Abstract: The revolution in molecular biology within the last few decades has led to the identification of multiple,
diverse inputs into the mechanisms governing the measurement and regulation of organ size. In general, organ size and homeostasis is controlled by both intrinsic, genetic mechanisms as well as extrinsic, physiological factors. Examples of the former include
the spatiotemporal regulation of organ size by morphogen gradients, and instances of the latter include the regulation of organ development by endocrine hormones, oxygen availability, nutritional status and the mechanics of the microenvironment. However, integrated
model platforms, either of in vitro experimental systems amenable to high- resolution imaging or
in silico computational models that incorporate both extrinsic and intrinsic mechanisms are lacking. Here, I will discuss collaborative efforts to bridge the gap between traditional assays employed in developmental biology and computational models through
quantitative approaches. These interdisciplinary efforts are being applied to develop integrated models of epithelial growth and homeostasis in the larval wing imaginal disc of the fruit fly, due to the wealth of previous genetic knowledge for the system.
In particular, I will discuss our current understanding of how intrinsic and extrinsic factors impact the spatiotemporal dynamics and possible functional roles of calcium signaling in development and homeostasis using a combination of microfluidics devices,
organ culture and computational modeling of signal transduction. An integrated model of intrinsic and extrinsic growth control is expected to provide greater insight into how cells communicate to coordinate tissue-level responses.
Bio: Dr. Jeremiah Zartman received his Bachelors degree from the University of Colorado at Boulder with a dual
major in Chemical Engineering and Engineering Physics in 2004. In 2009 he obtained his Ph.D. in Chemical and Biomolecular Engineering under the supervision of Prof. Stanislav Shvartsman at Princeton University as a Princeton Hertz Fellow. From 2009-2011, he
worked as post-doctoral research in the lab of Prof. Konrad Basler, University of Zurich, in Molecular Life Sciences as an EMBO Long-term Post-doctoral Fellow. Since 2012, Dr. Zartman has led a research group at the University of Notre Dame. The lab focuses
on the integration of computational and experimental approaches toward the development and function of multicellular systems as well as the development of advanced in vivo screening approaches for target discovery in cancer and regenerative medicine.