Hernan G. Garcia obtained a Bachelor’s Degree in Physics from the University of Buenos Aires, Argentina in 2003. He then moved to Caltech where he obtained a PhD in Physics in 2011 working in the laboratory of Rob Phillips. From 2011 to 2014 he took a postdoctoral position in the Physics Department at Princeton University in the laboratory of Thomas Gregor first as a Dicke Fellow and later as a Burroughs Wellcome Fund Career Award at the Scientific Interface Fellow. Since 2015 he has been an Assistant Professor in the Department of Molecular & Cell Biology and the Department of Physics at UC Berkeley.
An abiding mystery in the study of living matter is how a single cell develops into a multicellular organism. As this cell divides, its progeny read the program encoded on their DNA and adopt different fates becoming familiar cell types such as those found in muscle, liver and our brains. We now know that the decisions that cells make during development are not so much based on which genes to express, but rather on when, where and how to express them. Despite advances in determining the identities of the molecules that mediate these decisions we are still incapable of predicting how simple physical parameters such as the number, position and affinity of binding sites for these molecules on the DNA determine developmental fates. We use the fruit fly, one of the classic model systems for embryonic development, together with a combination of new technologies, quantitative experiments, and statistical mechanics in order to provide new insights about cellular decision making during development. In particular, we aim to link the specification of macroscopic body parts in an organism to the non-equilibrium molecular-scale processes inside single cells. The ultimate goal of this interdisciplinary research is to produce a predictive understanding of developmental programs which will enable the rational control of biological size, shape and function.