Research Interests
Development of the nervous system, Neuroscience
Research Focus Teams
Cancer, Diabetes, Autism, Alzheimer’s
Departments
Contact
Email: auld [at] zoology.ubc.ca
Office Phone: 604–822–1977
Office number: 3358
Publications
Lab Website
Internationally recognized for her research in neuroscience, cell and developmental biology, Auld earned her BSc in Microbiology from UBC and her PhD from the University of Toronto. She has twice served as UBC Science’s Associate Dean for Faculty Affairs, leading equity and diversity initiatives across the Faculty and at the university level.
During her terms as associate dean, Auld led a comprehensive survey of the Faculty’s working climate, coordinated external department reviews, oversaw faculty recruiting, promotion and tenure, and peer review of teaching initiatives. Auld also worked closely with units to develop important policies around faculty mentoring, workload, and maternal, parental and adoptive leaves.
Auld’s research has been published in top journals including Cell and Neuron. She has held continuous operating grants from both CIHR and NSERC for the past two decades and was awarded an HHMI International Scholarship. She has successfully supervised five post-doctoral fellows, 18 PhD and MSc students, and 48 undergraduate research students. Auld has taught core courses in cell physiology, developmental biology, and neuroscience at the undergraduate and graduate levels.
After a post-doctoral work at the University of California, Berkeley, she joined UBC as an assistant professor in 1994 and was promoted to associate professor (2001) and to professor (2007).
My research program investigates the roles that glia play in the development and function of the nervous system. Glia are known to fulfill a number of important functions during nervous system development. Glia help guide axon guidance, separate axons bundles in nerves and finally wrap and insulate their associated axons and nerves. The molecules and mechanisms that mediate these roles of glia are not well understood. Yet knowing how glia function is important given the essential role that glia play in the nervous systems of all animals. Any mutation or disease that disrupts glial cell function or development results in disruption of nervous system function and can lead to paralysis or death of the animal.
One approach to study molecular and cellular interactions that occur between glia and neurons during development is to use a model system. The organism of choice for these studies is the fruit-fly, Drosophila melanogaster, because of the powerful genetic tools that can be applied to study the molecular interactions that occur during nervous system development. There are many parallels between the glia in of vertebrates and Drosophila and we have shown that many of the same molecular cues are conserved. For instance, we have shown that the glia of the peripheral nervous system in Drosophila are strikingly similar to the vertebrate peripheral glia (non-myeliating Schwann cells) in terms of morphology, developmental dynamics and molecular composition. We have shown that disruptions in the glia of the peripheral nervous system can lead to loss of nervous system function, neurodegeneration and death in Drosophila.
We use a combination of genetics, molecular and cell biology with high resolution microscopy to study the glial proteins that are expressed during the development of the nervous system. We are using the advantages of Drosophila genetics to manipulate glial genes that disrupt the formation of the peripheral nervous system. We are interested in multiple aspects of glial cell development and function:
1. What are the mechanisms drive the glial cells to ensheathe/wrap their associated axons?
2. What proteins allow for the formation of the glial based blood-brain barrier?
3. How do the glial layers interact with each other and the overlying ECM to support the peripheral nerve sheath and integrity?
Glia-ECM interactions
Glia express a wide range of extracellular matrix (ECM) receptors and these are conserved in non-myelinating glia in many animals. We are testing how these ECM receptors function to drive glial sheath development and support the maintenance of the peripheral nerves as the animal moves.
Glia-glia communication
Glia make extensive contacts with neurons and other glia. But the mechanisms and function of contact between the different glia layers is not well known. We are asking how the glial layers of the Drosophila peripheral nervous system communicate during sheath formation and maintenance of the nerve .
Tricellular & Septate Junctions
Glia and epithelial cells form permeability barriers in Drosophila through both septate junctions between two cells and at the corners of cells, at the tricellular junction. We study the protein components and mechanisms that underlie the formation of these junctions in both glial and epithelial cells.