Barbara Wold graduated with a B. S. in zoology from Arizona State University in 1973. She was inspired by laboratory work with zoology professor Shelby Gerking and developmental biologist Jerry Justus, and lectures with professor emerita Kathleen Church. While at ASU, Wold became interested in understanding the informational code that regulates gene expression. She also met her husband, geophysicist Lawrence "Larry" Burdick. Wold received a Ph.D. in molecular developmental biology from the California Institute of Technology in 1978, studying genome structure and gene regulation during embryo development. She was appointed as a postdoctoral research fellow at Columbia University College of Physicians and Surgeons in 1978. There she developed methods for assaying cis-regulatory element function.
Career
In 1981, Wold returned to Caltech as an assistant professor in the Biology department. She was promoted to associate professor in 1988 and full professor in 1996, holding the position until 2002. She became Bren Professor of Molecular Biology as of 2003. Wold helped to found the L. K. Whittier Gene Expression Center at Caltech in 1999, with Stephen Quake and Mel Simon, collaborating with the Human Genome Project. She has also been involved in establishing the Center for Biological Circuit Design at Caltech. She has been an advisor to the National Institutes of Health and the Department of Energy in the area of genomics. Wold was director of the Beckman Institute at Caltech from 2001 to 2011, succeeding founding director Harry B. Gray. As of January 30, 2012, she was succeeded as director by David A. Tirrell.
Research
Barbara Wold has published more than sixty papers in the areas of developmental biology and genetics. Throughout her career, Wold has focused on exploring the architecture and logic of gene regulatory networks, in an effort to understand the mechanisms that drive cell state transitions in the development and differentiation of individual cells. In particular, she has investigated the ways in which these differentiation mechanisms are encoded in DNA, and furthermore, how they are executed via transcription. Beginning with undifferentiated precursor cells, Wold and her lab have focused particularly on transitions from mesodermal cells in early development to fully developed skeletal muscle and cardiac muscle in animals, primarily through the use of mouse models. In addition, she is interested in the transitions in cell development which lead to tumorigenesis. Wold and her lab have used various techniques, including genome-wide and proteome-wide assays, wet-bench genomic technology, and computational methods, many of which they have developed in conjunction with other researchers, to study skeletal muscle development, degeneration and regeneration. She has also used such techniques as microarray gene expression analysis, global protein/DNA interaction measures, mass spectrometry-based proteomics, and comparative genomics. In collaboration with others, her lab has also pioneered a modification of mass spectrometry and dual-affinity apitope tagging that enables efficient and accurate classification of multi-protein complexes. Much of Wold's recent work focuses on biological information processing, developing and using new techniques such as ultra-high-throughput DNA sequencing techniques to computationally model the inputs and outputs of gene networks. She studies embryonic development and regeneration in vertebrates, examining transcriptional networks and using comparative genomics to model mouse, human and dog genomes. This work is leading to increased understanding of direct transcriptional regulation and of post-transcriptional and translational mechanisms and their mediation by microRNAs. Wold's goal is a deep understanding of biological circuit design and the mechanisms of genetics and cell development. To this end, Wold seeks to use her research to contribute to the development of the international reference transcriptome and regulatory element databases. Wold's lab has recently been concerned with human disease genomics. In particular, they are looking into diseases such as Alzheimer's, cancer, and musculoskeletal disorders.
