Congratulations to Kristen Segars, an MD/PhD candidate in Dr. Trinkaus-Randall’s lab, for her receipt of an F30 grant for her work, “Delayed wound healing in diabetic corneal epithelia: reduction in protein response after injury and uncoordinated cell-cell communication.”
Non-healing corneal injuries affect up to 70% of patients with type 2 diabetes, representing a significant cause of vision loss in this population. Although there are treatments available to improve the symptoms of poorly-healing corneal wounds, the only permanent solution is a corneal transplant, a procedure not readily available worldwide. By examining changes in various proteins involved in the wound healing response at the cellular level, Segars hopes to understand why the corneas of diabetic patients fail to heal effectively.
When an otherwise healthy cornea is injured, cells next to the wound experience a number of changes necessary for coordinated migration and wound closure. One change involves the activation of the purinergic receptor, P2X7, found on the cell surface. When active, P2X7 generates a specific pattern of calcium signaling events that travel from cell to cell through activation of the ion channel Pannexin-1. These propagated signaling events represent cell-cell communication, and ultimately lead to re-arrangement of cytoskeletal proteins and coordinated wound closure. Previous studies have identified aberrant localization and activation of P2X7 in pre-type 2 diabetic models. We have preliminary evidence that the signaling profile of wounded diabetic cells lacks the characteristic P2X7 signaling response. This was confirmed using specific agonists to P2X7, and observing a greatly diminished response in diabetic cells. The goal of this proposal is to uncover how the cell-cell communication events in the P2X7 signaling cascade are regulated, how this regulation is thrown off in diabetic systems, and how this change in regulation affects actin bundling and ultimately cell motility.
Segar’s preliminary data has identified a set of cells that she speculates are controllers or leader cells, as they initiate communication events in neighboring cells, and propagated signaling events are greatly reduced in their absence. Aim 1 will use a machine learning approach to investigate the presence of these leader cells in both diabetic cell culture and corneal models. Aim 1 will also address the role of Pannexin-1 in the generation of a unique leader cell signaling profile. Furthermore, the downstream impact of P2X7/Pannexin-1 signaling will be assessed by using 3D electron microscopy to study actin arrangement in wounded diabetic and control corneas. In Aim 2, the localization of P2X7 and Pannexin-1 protein and mRNA within the cells of corneal samples will be examined. This will yield data regarding both general trends in expression between diabetic and control groups, and differences in expression within a single sample that may explain the functional difference between leader cells and the rest of the epithelial sheet. In addition, Aim 2 will address whether the co-localization of P2X7 and Pannexin-1 proteins (before and after a wound) is necessary for wound repair. Together these Aims will produce significant advances in our understanding of the regulation of the P2X7/Pannexin-1 signaling cascade, alterations at the mRNA, protein, and functional level of this cascade in diabetes, and downstream effects of these aberrations on the actin cytoskeleton.