We have examined the development of microglia in the rat retina, using a peroxidase-conjugated lectin derived from Griffonia simplicifolia. Retinas were studied from animals aged from E(embryonic day)12, just after the invagination of the optic cup and prior to the closure of the optic fissure, to adulthood. The lectin also proved a sensitive label for the endothelial cells of the developing retina. Our results provide some support for the view that microglia are derived from the monocyte-macrophage series of blood cells. At E12, most labeled cells were found at the vitreal surface, suggesting that they had come from the hyaloid circulation, while some had entered the retina and appeared to be migrating towards its ventricular surface. From E14 to early postnatal ages, most labeled cells had processes and resembled the amoeboid microglial cells described in silver carbonate staining studies (Ling, 1982). The number of labeled cells rose from about 700 to E14 to a peak of about 27,000 at P(postnatal day)7, and fell to about 19,600 by P12. As early as E16, a regularity was apparent in the distribution of microglial cells over the surface of the retina, the cells tending to avoid each other. Microglial cells are found throughout the thickness of the very young retina, but as the layers of the retina differentiate, they are increasingly restricted to the inner half of the retina. Our findings indicate that microglia enter the retina well before the period of neuronal death, making it unlikely that they invade the retina solely in response to cell death. Our results confirm however that, once in the retina, microglia become associated with, and appear to phagocytose, the pyknotic debris which appears during the period of neuronal death. They also become closely associated with the retinal vasculature. In the adult, the intensity of the labeling of microglia was much reduced. Those cells which were labeled appeared more differentiated, resembling the “resting microglia” described in earlier studies.
In this study the development of ameboid microglia and resting microglia in the retina of the albino rabbit has been examined by means of a lectin derived from Griffonia simplicifolia. Ameboid microglia are present in the retina as early as E12, when the optic fissure is in the process of closure, and appear to be concentrated initially at the vitreal surface. At E14 many ameboid microglia can be seen to extend processes to the ventricular surface of the cytoblast layer, but in subsequent ages these cells are rare and ameboid microglia are largely confined to the ganglion cell layer, inner plexiform layer, and occasionally the developing inner nuclear layer. By adult life, mature (or resting) microglia are confined to the inner plexiform and ganglion cell layers. Numbers of microglia increase steadily throughout fetal life from a mean of 400 at E14, the earliest age quantified, to a peak of 28,600 at E30. There is a small postnatal drop in numbers to 17,150 at P9. Microglia could only be labelled faintly in animals older than P11, but analysis of two adult (P130) retinas with adequate labelling suggested that numbers rise to a value of about 23,800 at this age. Ameboid microglia thus appear in the retina 11 days prior to the onset of axon loss in the optic nerve (about E23) and 14 days prior to the beginning of the period of reduction of retinal ganglion cell numbers (about E26). The present findings indicate that while some microglial precursors may enter the retina in response to debris generated during the natural retinal ganglion cell death period, most enter the retina well before this period. Also, microglia present a uniform density distribution with apparently regular spacing as early as E16, so the uniform regular distribution cannot simply be the consequence of regularly distributed pyknotic figures as previously suggested.
We have examined the topography of the cerebral cortex of the Australian echidna (Tachyglossus aculeatus), using Nissl and myelin staining, immunoreactivity for parvalbumin, calbindin, and nonphosphorylated neurofilament protein (SMI-32 antibody), and histochemistry for acetylcholinesterase (AChE) and NADPH diaphorase. Myelinated fibers terminating in layer IV of the cortex were abundant in the primary sensory cortical areas (areas S1, R, and PV of somatosensory cortex; primary visual cortex) as well as the frontal cortex. Parvalbumin immunoreactivity was particularly intense in the neuropil and somata of somatosensory regions (S1, R, and PV areas) but was poor in motor cortex. Immunoreactivity with the SMI-32 antibody was largely confined to a single sublayer of layer V pyramidal neurons in discrete subregions of the somatosensory, visual, and auditory cortices, as well as a large field in the frontal cortex (Fr1). Surprisingly, SMI-32 neurons were absent from the motor cortex. In AChE preparations, S1, R, V1, and A regions displayed intense reactivity in supragranular layers. Our findings indicate that there is substantial regional differentiation in the expanded frontal cortex of this monotreme. Although we agree with many of the boundaries identified by previous authors in this unusual mammal (Abbie [1940] J. Comp. Neurol. 72:429-467), we present an updated nomenclature for cortical areas that more accurately reflects findings from functional and chemoarchitectural studies.
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