Following thorough removal of adhering aqueous humor, we have succeeded in patch clamping the intact rabbit ciliary epithelium in the cell-attached and inside-out excised-patch modes. Rapidly fluctuating currents ("chatter activity') were observed during recordings conducted for as long as 1 h. Chatter activity did not reflect seal instability since interconversion was noted between chatter activity and transitions between stable open and closed states, excision of patches into the bath was associated with substantial shifts in the reversal potential, and chatter activity could be triggered by sustained hyperpolarization, but was insensitive to stretch. The chatter channel was identified as cation-nonselective from the reversal potentials both in the cell-attached and excised-patch modes. The channel's kinetics were similar to those of the cGMP-activated phototransduction channel. The results of PCR amplifications of fragments in cDNA libraries from both human ciliary body and human nonpigmented ciliary epithelial (NPE) cells indicated that human ciliary epithelial cells transcribe message for the retinal phototransduction channel. The possible role of the phototransduction channel in expressing chatter activity was further explored by perfusing preparations with a known activator of that channel (cGMP) and with a known inhibitor (L-cis-diltiazem). Neither agent significantly affected chatter behavior. We conclude that: (1) this is the first demonstration of the feasibility of patch-clamping the intact ciliary epithelium; (2) the NPE cells display chatter activity arising from rapidly fluctuating transitions of a cation-nonselective channel; (3) NPE cells can transcribe message for the cation-nonselective phototransduction channel; and (4) if the observed chatter activity is from a homologue of the photo-transduction channel, the homologue is pharmacologically distinct.