David Antonetti
Roger W Kittendorf Research Professor of Ophthalmology and Visual Sciences
Professor of Ophthalmology and Visual Sciences
Professor of Molecular and Integrative Physiology and Associate Chair in Laboratory Research
Kellogg Eye Center
1000 Wall St
Ann Arbor, Michigan 48105
[email protected]

Available to mentor

David Antonetti
Professor
  • About
  • Links
  • Qualifications
  • Center Memberships
  • Research Overview
  • Recent Publications
  • About

    Dr. Antonetti received his PhD in Cellular and Molecular Biology at The Penn State College of Medicine under the direction of Dr. Leonard Jim Jefferson and was a post-doctoral fellow in Cellular and Molecular Physiology at the Joslin Diabetes Center at Harvard Medical School under the direction of Dr. C. Ronald Kahn. Upon returning to Penn State, he was one of the first to bring high-level signal transduction expertise to the problem of diabetic retinopathy and the blood-retinal barrier. Over the last 20 years, he has become one of the world’s leading experts in mechanisms of vascular permeability in diabetic retinopathy, the role of the blood retinal barrier in normal physiology, and the molecular mechanisms that underlie angiogenesis and neovascularization. These efforts have allowed him to develop new experimental treatments that show promising pre-clinical results. He has received awards including the Jules Francois Prize for Young Investigator at Ophthalmologia Beligica, the Hinkle Society Mid-career Translational Research Award, and the Most Inspirational Teacher Award for graduate education at Penn State. He held the very prestigious Jules and Doris Stein Professorship from Research to Prevent Blindness for the allotted 5 years. Currently he is the inaugural Roger W. Kittendorf Research Professor of Ophthalmology and Visual Sciences. Dr. Antonetti is the Scientific Director at the Kellogg Eye Center contributing to establishing the direction and management of preclinical vision research for the Department. His work has been noted by presentations at key meetings such as the American Diabetes Association, the International Symposium of the Blood-Brain Barrier, Gordon Research Conferences, and the International Symposium on Signal Transduction at the Blood-Brain and Blood-Retina Barriers. Of particular note, his translational impact has been recognized by clinicians by his presentations at the American Uveitis Society, the American Academy of Ophthalmology, the ARVO Vision Innovation and Venture forum, and the University of Pittsburgh, Washington University, and Trinity College in Dublin.

    Links
    • My Profile at U Michigan
    Qualifications
    • Post-Doctoral Research
      Joslin Diabetes Center, Harvard, Boston, 1996
    • Ph.D.
      Pennsylvania State College of Medicine, Hershey, PA
    Center Memberships
    • Center Member
      Caswell Diabetes Institute
    Research Overview

    Our long-term goal is to contribute to the development of novel treatments to prevent or reverse the debilitating loss of vision from diabetes and stroke.

    The tight junction complex contributes an essential role in multi-cellular organisms by helping to create defined environments between tissues. Tight junctions create a tight seal between cells controlling the flux of fluids, proteins and even ions across tissue barriers. These barriers provide an essential function in a variety of tissues including the intestine, lung and kidneys. Our laboratory is specifically interested in the tight junction complex in specialized regions of the vasculature that help to create the blood-brain and blood-retinal barrier. The tight junctions that connect the endothelial cells in the brain and retina are needed for normal neural function and contribute to the neurovascular unit. This vascular barrier may be compromised in a variety of disease states.

    Diabetic retinopathy is the leading cause of visual loss in working age adults and is characterized by increased vascular permeability, leading to edema, or fluid accumulation, in the retina. Our laboratory works to understand the cellular and molecular basis for this change in vascular permeability by exploring the changes in the tight junction complex that controls the blood-retinal barrier. Our laboratory utilizes biochemical approaches such as mass spectrometry, cell biology techniques such as mutational analysis in vascular endothelial cell culture, and transgenic mouse studies in models of diabetic retinopathy, in order to understand the mechanisms by which diabetes alters the tight junctions in the blood-retinal barrier. Much of this research has centered on understanding how growth factors and cytokines signal to the tight junction complex and regulate vascular permeability. Our laboratory was one of the first to identify phosphorylation of junctional protein occludin as a regulator of barrier properties. Our recent studies demonstrate that a transgenic mouse models expressing point mutants preventing this phosphorylation preserves the retinal vascular barrier during diabetes and importantly, prevents vision loss. Future studies will explore the intimate relationship between the retinal blood vessels and neural function to better understand the neurovascular unit.

    Recent Publications See All Publications
    • Journal Article
      Imaging Modalities for Assessing the Vascular Component of Diabetic Retinal Disease: Review and Consensus for an Updated Staging System.
      Tan T-E, Jampol LM, Ferris FL, Tadayoni R, Sadda SR, Chong V, Domalpally A, Blodi BL, Duh EJ, Curcio CA, Antonetti DA, Dutta S, Levine SR, Sun JK, Gardner TW, Wong TY. Ophthalmol Sci, 2024 4 (3): 100449 DOI:10.1016/j.xops.2023.100449
      PMID: 38313399
    • Journal Article
      Disheveled-1 Interacts with Claudin-5 and Contributes to Norrin-Induced Endothelial Barrier Restoration.
      Díaz-Coránguez M, González-González L, Wang A, Liu X, Antonetti DA. Cells, 2023 Oct 4; 12 (19): DOI:10.3390/cells12192402
      PMID: 37830616
    • Journal Article
      Delineating effects of angiopoietin-2 inhibition on vascular permeability and inflammation in models of retinal neovascularization and ischemia/reperfusion.
      Canonica J, Foxton R, Garrido MG, Lin C-M, Uhles S, Shanmugam S, Antonetti DA, Abcouwer SF, Westenskow PD. Front Cell Neurosci, 2023 17: 1192464 DOI:10.3389/fncel.2023.1192464
      PMID: 37377777
    • Proceeding / Abstract / Poster
      Diabetes renders photoreceptors susceptible to ischemia-reperfusion injury
      Abcouwer SF, Lin C-M, Hager H, Shanmugam S, Dreffs A, Antonetti DA. INVESTIGATIVE OPHTHALMOLOGY & VISUAL SCIENCE, 2023 64 (8):
    • Proceeding / Abstract / Poster
      Norrin prevents visual loss in diabetic rats
      Dreffs A, Lin C-M, Coranguez MD, Sheskey S, Antonetti DA. INVESTIGATIVE OPHTHALMOLOGY & VISUAL SCIENCE, 2023 64 (8):
    • Journal Article
      Transgenic animal models to explore and modulate the blood brain and blood retinal barriers of the CNS.
      Goncalves A, Antonetti DA. Fluids Barriers CNS, 2022 Nov 1; 19 (1): 86 DOI:10.1186/s12987-022-00386-0
      PMID: 36320068
    • Journal Article
      Thrombolytic tPA-induced hemorrhagic transformation of ischemic stroke is mediated by PKCβ phosphorylation of occludin.
      Goncalves A, Su EJ, Muthusamy A, Zeitelhofer M, Torrente D, Nilsson I, Protzmann J, Fredriksson L, Eriksson U, Antonetti DA, Lawrence DA. Blood, 2022 Jul 28; 140 (4): 388 - 400. DOI:10.1182/blood.2021014958
      PMID: 35576527
    • Journal Article
      Thrombolytic tPA-induced hemorrhagic transformation of ischemic stroke is mediated by PKCβ phosphorylation of occludin.
      Goncalves A, Su EJ, Muthusamy A, Zeitelhofer M, Torrente D, Nilsson I, Protzmann J, Fredriksson L, Eriksson U, Antonetti DA, Lawrence DA. Blood, 2022 Jan 28; 140 (4): 388 - 400.