Commissural connections of the cat periaqueductal gray matter studied with anterograde and retrograde tract-tracing techniques

The commissural connections of the periaqueductal gray matter were investigated by light and electron microscopy by using the anterograde tracer Phaseolus vulgaris leucoagglutinin and the retrograde tracer horseradish peroxidase. In the first group of seven animals (1-7), single injections of Phaseolus vulgaris leucoagglutinin were performed iontophoretically (4.5 mu A for 30 min) into various subdivisions of the periaqueductal gray matter. On light microscopic examination, injection sites were characterized by several immunolabeled neurons of different sizes and morphology, with the cytoplasm, nucleus and neuronal processes intensely stained. Many labeled fibers turned from injection sites toward all contralateral periaqueductal gray matter subdivisions, but anterograde labeling was densest in the regions homotopic to those injected. Commissural fibers bore along their course many en passant boutons of different sizes and morphology, and gave off spine-like processes, at the end of which one terminal bouton was observed. Labeled fibers branched into numerous collaterals which ended in a terminal array of 10-20 en passant and en grappe boutons. At the electron microscopic level, commissural axons were observed in close proximity to the cytoplasmic membranes of cells. Axon terminals formed symmetric or asymmetric synapses mainly on dendritic shafts of neurons and rarely on vesicle-containing profiles. Horseradish peroxidase experiments were carried out in four cats (1-4). The tracer was injected iontophoretically into different regions of the periaqueductal gray matter of three cats (1-3). Retrogradely labeled neurons giving rise to commissural connections had a morphology similar to that of polygonal, triangular and fusiform cells described in previous Golgi studies. The perikaryal cross-sectional area of commissural neurons was smaller than that of neurons projecting outside the periaqueductal gray matter (mean value of commissural neurons 149.77 mu m(2) vs 261.19 mu m(2) for projecting neurons), which were retrogradely labeled by pressure-injecting horseradish peroxidase into several targets of periaqueductal gray matter (4). Moreover, since the distribution of sizes of the two populations of the periaqueductal gray matter overlapped in the range of 90-300 mu m(2), a considerable number of projecting neurons were as small as commissural neurons. The present results suggest that commissural fibers could reciprocally connect zones of the periaqueductal gray matter with similar functions, and originate from small and medium-sized neurons, some of which are also projecting neurons.