Michael H. B. Stowell, PhD
Affiliations: | University of Colorado, Boulder, Boulder, CO, United States |
Area:
Structure and Mechanism at the Chemical SynapseWebsite:
http://dosequis.colorado.edu/Google:
"Michael Stowell"Bio:
https://www.proquest.com/openview/b7f585f2a00907bdb830362c6f8f202f/1
Structure and Mechanism at the Chemical Synapse.> Our research is focused on molecular and supramolecular structures that facilitate communication between neurons at the chemical synapse. We are particularly interested in the architectural arrangement of signaling molecules and characterizing the ways in which such molecular assemblies are formed and undergo changes during synaptic transmission and modulation. Our approach is to investigate individual proteins using x-ray and electron crystallographic methods, and combine this information with 3-D reconstructions of large assemblies along with tomographic analysis of the intact chemical synapse.
Our long-term goal is to construct a dynamic molecular and architectural map for the chemical synapse that will help to understand synaptic formation, transmission and plasticity. Ion channel structure and mechanism. Several ion channels are being studied with the goal of determining their molecular mechanism of their action. These include voltage gated channels responsible for propagation and termination of action potentials, calcium channels involved in signal amplification and ligand gated ion channels involved in signal detection and modulation. Using x-ray crystallography and electron microscopy, our goal is to elucidate the high resolution structural elements of these channels in various states. Synaptic architecture, dynamics, and plasticity. Using electron tomographic methods we have begun to study the architecture of the chemical synapse in cultured neurons. Our first goal is to establish the common architectural elements present at the synapse and to identify the molecules involved using specific antibody labeling or genetic tagging. Subsequently, we will investigate the dynamic processes involved in synaptic transmission by stimulating individual neurons and cryogenic trapping them at defined time points post excitation. Ultimately we plan to study long-term, stimulation dependent, synaptic changes in the hope of gaining insight into the architectural elements underlying synaptic plasticity. Formation and mechanisms of supramolecular assemblies. Supramolecular organization and assembly of biomolecules occurs throughout biology. We are interested in supramolecular protein assemblies such as the channel clustering proteins rapsyn and PSD95, and the self assembling GTPase dynamin. The interests and goals of these projects are twofold. First, to understand the role of supramolecular organization and assembly in maintaining and modulating synaptic transmission. And second, the potential of such biomolecular systems to serve as templates for nanomolecular assembly and patterning of materials.
(Show less)
Mean distance: 18.79 (cluster 51) | S | N | B | C | P |
Cross-listing: Chemistry Tree
Parents
Sign in to add mentor| Sunney I. Chan | grad student | 1997 | Caltech (Chemistry Tree) | |
| Douglas C. Rees | grad student | 1997 | Caltech (Chemistry Tree) | |
| (Ekmageion) | ||||
| Yoshinori Fujiyoshi | post-doc | Kyoto University | ||
| Nigel Unwin | post-doc | Cambridge | ||
Children
Sign in to add trainee| Takashi Daniel Yoshida Kozai | research assistant | 2002-2005 | University of Pittsburgh |
| Christopher P. Arthur | grad student | 2007 | CU Boulder |
| Thomas Z. Armel | grad student | 2009 | CU Boulder |
| Hsin-Jui Wu | grad student | 2013 | CU Boulder |
Publications
|
You can help our author matching system! If you notice any publications incorrectly attributed to this author, please sign in and mark matches as correct or incorrect. |
| Maity K, Heumann JM, McGrath AP, et al. (2020) cryo-EM Structure of Rice OSCA1.2 Elucidates the Mechanical Basis of Membrane Hyperosmolality Gating in Plants Biophysical Journal. 118: 211a |
| Adams DJ, Arthur CP, Stowell MH. (2015) Architecture of the Synaptophysin/Synaptobrevin Complex: Structural Evidence for an Entropic Clustering Function at the Synapse. Scientific Reports. 5: 13659 |
| Basta T, Wu HJ, Morphew MK, et al. (2014) Self-assembled lipid and membrane protein polyhedral nanoparticles. Proceedings of the National Academy of Sciences of the United States of America. 111: 670-4 |
| Pieper U, Schlessinger A, Kloppmann E, et al. (2013) Coordinating the impact of structural genomics on the human α-helical transmembrane proteome. Nature Structural & Molecular Biology. 20: 135-8 |
| Arthur CP, Dean C, Pagratis M, et al. (2010) Loss of synaptotagmin IV results in a reduction in synaptic vesicles and a distortion of the Golgi structure in cultured hippocampal neurons. Neuroscience. 167: 135-42 |
| Arthur CP, Stowell MH. (2007) Structure of synaptophysin: a hexameric MARVEL-domain channel protein. Structure (London, England : 1993). 15: 707-14 |
| Arthur CP, Serrell DB, Pagratis M, et al. (2007) Electron tomographic methods for studying the chemical synapse. Methods in Cell Biology. 79: 241-57 |
| Yeh AP, McMillan A, Stowell MH. (2006) Rapid and simple protein-stability screens: application to membrane proteins. Acta Crystallographica. Section D, Biological Crystallography. 62: 451-7 |
| Tierney ML, Osborn KE, Milburn PJ, et al. (2004) Phylogenetic conservation of disulfide-linked, dimeric acetylcholine receptor pentamers in southern ocean electric rays. The Journal of Experimental Biology. 207: 3581-90 |
| Marks B, Stowell MH, Vallis Y, et al. (2001) GTPase activity of dynamin and resulting conformation change are essential for endocytosis. Nature. 410: 231-5 |