Membrane conductance of Muller glial cells in proliferative diabetic retinopathy

Background: It is not known whether the membrane features of human Muller cells are altered in proliferative diabetic retinopathy (PDR). We performed a study to investigate the expression of several distinct forms of membrane conductance in Muller glial cells from a patient with PDR compared to cells from healthy donors (control cells). Methods: Muller cells were isolated 2 hours after vitreoretinal surgery in the case of the patient and within 24 hours in the case of the autopsy eyes. Whole-cell voltage-clamp recordings were made. The results for the two groups were compared with the Mann-Whitney U test. Results: As assayed by the whole-cell membrane capacitance, the cells from the patient with PDR showed hypertrophy in comparison to the control cells (mean 85.1 pF [standard deviation (SD) 19.7 pF] vs. 54.3 pF [SD 13.8 pF]). The cells from the patient displayed strong downregulation of inwardly rectifying potassium ion (Kir) currents (mean 0.41 [SD 0.24] pA/pF, compared to 3.43 [SD 1.86] pA/pF for the control cells). The Kir current downregulation was accompanied by a less negative membrane potential (-57.3 mV [SD 16.9 mV], compared with -82.3 mV [SD 5.3 mV] for the control cells). Both the number and the amplitude of voltage-gated sodium ion currents were enhanced in cells from the patient. When P2X(7) receptors were activated by 2'-/3'-O-(4-benzoylbenzoyl)-adenosine triphosphate, cells in both groups displayed opening of a cation conductance and, simultaneously, an increase in currents through calcium ion-activated potassium ion channels. Interpretation: Changes in Muller cell membrane conductance in PDR are similar to those described in proliferative vitreoretinopathy. The downregulation of active Kir channels and the membrane depolarization likely disturb voltage-dependent Muller cell functions, such as regulation of local ion concentrations and uptake of neurotransmitters. The enhanced entry of calcium ions from the extracellular space and the subsequent stimulation of calcium-activated potassium channels support Muffler cell proliferation in PDR.