Full-field electroretinograms were recorded from five normal human subjects using white light (mean luminance: 250 cd/m2) sine wave stimuli at different frequencies and contrasts. In agreement with previous studies, we found that the amplitude of the fundamental component displayed a dip at about 12 Hz, coinciding with a maximum in the second harmonic component, indicating frequency doubling of the responses. By including measurements at different contrasts, we were able to recognize two (sine-like and transient) response components. We found that the waveform of the transient response was relatively frequency independent. An algorithm to separate the two components was developed. The interaction between these two components can explain the frequency-doubled responses around 12 Hz. The sine-like component is more linear and prominent in the low-frequency region, whereas the transient seems to be more nonlinear and prominent in the high-frequency region.

Mammalian retinae express multiple connexins that mediate the metabolic and electrical coupling of various cell types. In retinal neurons, only connexin36, connexin45, connexin50, and connexin57 have been described so far. Here, we present an analysis of a novel retinal connexin, connexin30.2 (Cx30.2), and its regulation in the mouse retina. To analyze the expression of Cx30.2, we used a transgenic mouse line in which the coding region of Cx30.2 was replaced by lacZ reporter DNA. We detected the lacZ signal in the nuclei of neurons located in the inner nuclear layer and the ganglion cell layer (GCL). In this study, we focused on the GCL and characterized the morphology of the Cx30.2-expressing cells. Using immunocytochemistry and intracellular dye injections, we found six different types of Cx30.2-expressing ganglion cells: one type of ON-OFF, three types of OFF, and two types of ON ganglion cells; among the latter was the RGA1 type. We show that RGA1 cells were heterologously coupled to numerous displaced amacrine cells. Our results suggest that these gap junction channels may be heterotypic, involving Cx30.2 and a connexin yet unidentified in the mouse retina. Gap junction coupling can be modulated by protein kinases, a process that plays a major role in retinal adaptation. Therefore, we studied the protein kinase–induced modulation of coupling between RGA1 and displaced amacrine cells. Our data provide evidence that coupling of RGA1 cells to displaced amacrine cells is mediated by Cx30.2 and that the extent of this coupling is modulated by protein kinase C.

The bird visual system includes a substantial projection, of unknown function, from a midbrain nucleus to the contralateral retina. Every centrifugal, or efferent, neuron originating in the midbrain nucleus makes synaptic contact with the soma of a single unique amacrine cell, the target cell (TC). By labeling efferent neurons in the midbrain, we have been able to identify their terminals in retinal slices and make patch-clamp recordings from TCs. TCs generate Na+-based action potentials (APs) triggered by spontaneous EPSPs originating from multiple classes of presynaptic neurons. Exogenously applied glutamate elicited inward currents having the mixed pharmacology of NMDA, kainate, and inward rectifying AMPA receptors. Exogenously applied GABA elicited currents entirely suppressed by GABAzine and therefore mediated by GABAA receptors. Immunohistochemistry showed the vesicular glutamate transporter, vGluT2, to be present in the characteristic synaptic boutons of efferent terminals, whereas the GABA synthetic enzyme, GAD, was present in much smaller processes of intrinsic retinal neurons. Extracellular recording showed that exogenously applied GABA was directly excitatory to TCs and, consistent with this, NKCC, the Cl− transporter often associated with excitatory GABAergic synapses, was identified in TCs by antibody staining. The presence of excitatory retinal input to TCs implies that TCs are not merely slaves to their midbrain input; instead, their output reflects local retinal activity and descending input from the midbrain.

We present a series of experiments exploring the effect of chromaticity on reaction time (RT) for a variety of stimulus conditions, including chromatic and luminance contrast, luminance, and size. The chromaticity of these stimuli was varied along a series of vectors in color space that included the two chromatic-opponent-cone axes, a red–green (L–M) axis and a blue–yellow [S − (L + M)] axis, and intermediate noncardinal orientations, as well as the luminance axis (L + M). For Weber luminance contrasts above 10–20%, RTs tend to the same asymptote, irrespective of chromatic direction. At lower luminance contrast, the addition of chromatic information shortens the RT. RTs are strongly influenced by stimulus size when the chromatic stimulus is modulated along the [S − (L + M)] pathway and by stimulus size and adaptation luminance for the (L–M) pathway. RTs are independent of stimulus size for stimuli larger than 0.5 deg. Data are modeled with a modified version of Pieron’s formula with an exponent close to 2, in which the stimulus intensity term is replaced by a factor that considers the relative effects of chromatic and achromatic information, as indexed by the RMS (square-root of the cone contrast) value at isoluminance and the Weber luminance contrast, respectively. The parameters of the model reveal how RT is linked to stimulus size, chromatic channels, and adaptation luminance and how they can be interpreted in terms of two chromatic mechanisms. This equation predicts that, for isoluminance, RTs for a stimulus lying on the S-cone pathway are higher than those for a stimulus lying on the L–M-cone pathway, for a given RMS cone contrast. The equation also predicts an asymptotic trend to the RT for an achromatic stimulus when the luminance contrast is sufficiently large.

The ability to extract form information from a visual scene, for object recognition or figure–ground segregation, is a fundamental visual system function. Many studies of nonhuman primates have addressed the neural mechanisms involved in global form processing, but few have sought to demonstrate this ability behaviorally. In this study, we probed global visual processing in macaque monkeys (Macaca nemestrina) using classical Kanizsa illusory shapes as an assay of global form perception. We trained three monkeys on a “similarity match-to-sample” form discrimination task, first with complete forms embedded in fields of noncontour-inducing “pacman” elements. We then tested them with classic Kanizsa illusory shapes embedded in fields of randomly oriented elements. Two of the three subjects reached our criterion performance level of 80% correct or better on four of five illusory test conditions, demonstrating clear evidence of Kanizsa illusory form perception; the third subject mastered three of five conditions. Performance limits for illusory form discrimination were obtained by manipulating support ratio and by measuring threshold for discriminating “fat” and “thin” illusory squares. Our results indicate that macaque monkeys are capable of global form processing similarly to humans and that the perceptual mechanisms for “filling-in” contour gaps exist in macaques as they do in humans.