Headshot of Dr.Linda M. Boland

Dr. Linda M. Boland

Professor of Biology
Associate Provost for Faculty
  • Profile

    Living cells are watery bags of chemicals surrounded by a membrane made of a double layer of lipids.  Ion channels are proteins that regulate the movement of ions from one side of the lipid bilayer to the other, thereby controlling the electrical activity of neurons.  A better understanding of how ion channels work is essential to understanding how the nervous system operates.

    Our research interests are framed around two general themes. First, how is ion channel function modified by changes in the cellular environment? Specifically, we are investigating how bioactive lipids, derived from the cellular membrane itself, or naturally occurring steroid hormones, alter the function of voltage-gated ion channels. The ion channels do not work the same way all the time -- their function is dependent upon various endogenous modulators. We aim to understand how and why this interaction occurs, and determine the physiological significance of the changes in ion channel function. These changes impact nerve cell communication and processes such as learning and memory as well as the function of brain and heart in certain disease states. Second, we are interested in how ion channels in different life forms relate to one another, both structurally and physiologically. How did cellular excitability evolve and what molecular adaptations in ion channel structure and function were required to support electrical activity of cells and eventually allow the development of a nervous system? By studying ion channels cloned from the genome of sponges and jellyfish, we can better understand the evolutionary changes that have occurred in ion channel structure and function.

    Current Projects

    • How membrane lipids impact ion channel function
    • Developing and testing a digital and open source amplifier for electrophysiology
    • The impact of ion channel regulation on action potential firing 

    Current University of Richmond Research Students

    • Nina Price (’23)
    • Ian Shogren (’24)

    University of Richmond Graduates (Partial List)

    • Herberth Balsells (D.O.)
    • Julian Butler (medical school)
    • Rachel Deitz (M.D./M.P.H)
    • Michelle Drzewiecki Gontasz (M.D.)
    • Jean Patrick Gonzales (graduate school)
    • Bridgette Heine (graduate school)
    • Robert Heler (Ph.D.)
    • Elizabeth Leggett (graduate school)
    • Shriraj Patel (medical school)
    • Ariana Prinzbach (medical school)
    • Hannah Small (graduate school)
    • Erica Yamamoto (D.O.)
    Expand All
    • Grants and Fellowships

      Current:
      National Institutes of Health (NIH)

      Previous:
      American Physiological Society Research Career Enhancement Award
      Extreme Science and Engineering Discovery Environment (XSEDE) high performance computing resources
      Mednick Fellowship
      National Institutes of Health (NIH)
      National Science Foundation (NSF) Major Research Instrumentation Grant
      Research Grant from the Thomas and Kate Jeffress Memorial Trust

    • Awards

      Arts and Sciences Outstanding Research Mentor Award

    • Presentations

      Baker, V.L. and L.M. Boland. (2023) Maximizing your sabbatical: An integrated approach to purposeful planning, reflection, and re-entry. Webinar for the National Center for Faculty Development and Diversity (NCFDD).


      Boyd, D.E., N.L. Chick, L.M. Boland, F. Lozada, K.A. Troyer, P. Hanstedt (2023) Holistic support for mid-career faculty. AAC&U Annual Meeting on Reclaiming Liberal Education.


      Boland, L.M. and V.L. Baker (2022) Reimagining the sabbatical: Resources for faculty developers. POD Network (Educational Development) Conference.


      Boyd, D., N. Chick, L.M. Boland, K. Troyer, P. Hanstedt, F. Lozada (January – May, 2022) Mid-Career Advancement Pathways Program. A cross-institutional program developed for the Associated Colleges of the South to support mid-career faculty professional development.


      Small, H.E.*, A. Corbin-Leftwich, C. Villalba-Galea, L.M. Boland (2017) Using excitable oocytes to investigate the role of potassium channels in action potentials. Faculty for Undergraduate Neuroscience, Society for Neuroscience


      Sinnott, J.*, B. Heine*, and L.M. Boland (2017) Investigating the effect of TREK activation by arachidonic acid. Annual Biomedical Research Conference for Minority Students


      Small, H.E.*, A. Corbin-Leftwich, C. Villalba-Galea, L.M. Boland (2017) Investigating the modulation of action potentials using excitable oocytes. Beckman Scholars Conference


      Heine, B.*, J. Sinnott*, L.M. Boland (2017) Investigating the effect of AKAP on TREK-1 activation by arachidonic acid. Central Virginia Chapter of the Society for Neuroscience

  • Publications
    Journal Articles

    * indicates undergraduate student co-author

    Baker, V.L. and L.M. Boland (2023) Harnessing the Power of the Sabbatical: Providing Strategic Guidance to Faculty Developers. Journal of Faculty Development 37(3): 48-53.

    Boland, L. M. and V.L. Baker (Forthcoming). Faculty re-engagement: A sabbatical planning guide to support productivity and well-being. In A Toolkit for Mid-Career Academics: Cultivating Career Advancement (Editors: Vicki L Baker, Aimee LaPointe Terosky, & Laura Gail Lunsford).  Routledge (Taylor & Francis Group).

    Boyd, D., N. Chick, L.M. Boland, K. Troyer (Forthcoming). A consortial approach to mid-career faculty development. In A Toolkit for Mid-Career Academics: Cultivating Career Advancement (Editors: Vicki L Baker, Aimee LaPointe Terosky, & Laura Gail Lunsford).  Routledge (Taylor & Francis Group).

    Shogren, I.S.K*, J.P. Gonzales*, and L.M. Boland (2023) An affordable three-dimensional (3D) printed recording chamber for two-electrode voltage clamp electrophysiology. The Journal of Undergraduate Neuroscience Education, 21(2):A91-A96.

    Corbin-Leftwich, A.*, H. E. Small*, H. Robinson*, C. Villalba-Galea, L.M. Boland. (2018) A Xenopus oocyte model system to study action potentials. Journal of General Physiology  doi:10.1085/jgp.201812146

    Sparks, J.T., G. Botsko, D.R. Swale, L.M. Boland, S.S. Patel*, J.C. Dickens. (2018) Proteins mediating reception and transduction in chemosensory neurons in mosquitoes. Frontiers in Physiology 9:1309. doi: 10.3389/fphys.2018.01309.

    Tang, Q-Y., T.C. Larry*, K. Hendra*, E. Yamamoto*, J. Bell, M. Cui, D.E. Logothetis, and L.M. Boland. (2015) Mutations in nature conferred a high affinity phosphatidylinositol 4,5-bisphosphate-binding site in vertebrate inwardly rectifying potassium channels. Journal of Biological Chemistry 290: 16517-16529. doi: 10.1074/jbc.M115.640409

    H. Yuan, C. Gao, Y. Chen, M. Jia, J. Geng, H. Zhang, Y. Zhan, L. M. Boland, H. An. (2013) Divalent cations modulate TMEM16A calcium-activated chloride channels by a common mechanism. Journal of Membrane Biology 246:893-902.

    Heler R.*, J.K. Bell, and L.M. Boland (2013) Homology model and targeted mutagenesis identify critical residues for arachidonic acid inhibition of Kv4 channels. Channels 7:1-11

    Wells, G.D.*, Q-Y Tang, R. Heler*, G.J. Tompkins-MacDonald, E.N. Pritchard*, S.P. Leys, D.E. Logothetis, and L.M. Boland (2012) A unique alkaline pH-regulated and fatty acid-activated tandem pore domain (K2P) potassium channel from a marine sponge. Journal of Experimental Biology 215: 2435-2444.

    Boland, L.M., M. M. Drzewiecki*, G. Timoney*, and E. Casey* (2009) Inhibitory effects of polyunsaturated fatty acids on Kv4 potassium channels. American Journal of Physiology (Cell Physiology) 296:C1003-C1014.

    Tompkins-MacDonald, G.J., W.J. Gallin, O. Sakarya, B. Degnan, S.P. Leys and L.M. Boland. (2009)  Expression of a Poriferan potassium channel: Insights into the evolution of ion channels in metazoans.  Journal of Experimental Biology.

    Boland, L.M. and M.M. Drzewiecki.* (2008) Polyunsaturated fatty acid modulation of voltage-gated ion channels.  Cell Biochemistry and Biophysics 52:59-84.