We report a quantitative survey of the population of amacrine cells present in the retina of the rabbit. The cells' dendritic shape and level of stratification were visualized by a photochemical method in which a fluorescent product was created within an individual cell by focal irradiation of that cell's nucleus. A systematically random sample of 261 amacrine cells was examined. Four previously known amacrine cells were revealed at their correct frequencies. Our central finding is that the heterogeneous collection of other amacrine cells is broadly distributed among at least 22 types: only one type of amacrine cell makes up more than 5% of the total amacrine cell population. With these results, the program of identification and classification of retinal neurons begun by Cajal is nearing completion. The complexity encountered has implications both for the retina and for the many regions of the central nervous system where less is known.
We report a survey of the population of ganglion cells in the rabbit retina. A random sample of 301 neurons in the ganglion cell layer was targeted for photofilling, a method in which the arbors of the chosen neurons are revealed by diffusion of a photochemically induced fluorescent product from their somas. An additional 129 cells were labeled by microinjection of Lucifer yellow. One hundred and thirty-eight cells were visualized by expression of the gene encoding a green fluorescent protein, introduced by particle-mediated gene transfer. One hundred and sixty-six cells were labeled by particle-mediated introduction of DiI. In the total population of 734 neurons, we could identify 11 types of retinal ganglion cell. An analysis based on retinal coverage shows that this number of ganglion cell types would not exceed the available total number of ganglion cells. Although some uncertainties remain, this sample appears to account for the majority of the ganglion cells present in the rabbit retina. Some known physiological types could easily be mapped onto structural types, but half of them could not; a large set of poorly known codings of the visual input is transmitted to the brain.
Amacrine cells of the rabbit retina were studied by ''photofilling,'' a photochemical method in which a fluorescent product is created within an individual cell by focal irradiation of the nucleus; and by Golgi impregnation. The photofilling method is quantitative, allowing an estimate of the frequency of the cells. The Golgi method shows their morphology in better detail. The photofilled sample consisted of 261 cells that were imaged digitally in throughfocus series from a previous study (MacNeil and Masland [1998] Neuron 20:971-982). The Golgi material consisted of 49 retinas that were stained as wholemounts. Eleven of these subsequently were cut in vertical section. Of the many hundreds of cells stained, digital through-focus series were recorded for 208 of the Golgi-impregnated cells. The two methods were found to confirm one another: Most cells revealed by photofilling were recognized easily by Golgi staining, and vice versa. The greater resolution of the Golgi method allowed a more precise description of the cells and several types of amacrine cell were redefined. Two new types were identified. The two methods, taken together, provide an essentially complete accounting of the populations of amacrine cells present in the rabbit retina. Many of them correspond to amacrine cells that have been described in other mammalian species, and these homologies are reviewed.
The population of bipolar cells in the rabbit retina was studied using Golgi impregnation and photocatalyzed filling of single cells with dihydrorhodamine, a quantitative sampling technique. The Golgi method revealed the morphology and stratification of cells in detail. The photofilling method allowed us to estimate the frequency of the cell types. From a sample of 243 Golgi-impregnated bipolar cells and 107 photofilled cells, we identified 1 type of rod bipolar cell and 12 types of cone bipolar cells. An analysis based on retinal coverage indicates that this number of types could be contained within the number of bipolar cells known to exist. The dendrites of most cone bipolars contacted all the cones within the individual cone bipolar cell's dendritic field. Types of bipolar cell were encountered at roughly similar frequency, without any one type predominating. The rabbit retina thus contains about a dozen parallel and roughly equipotent through-pathways.
Autophagy is a highly regulated and evolutionarily conserved process of cellular self-digestion. Recent evidence suggests that this process plays an important role in regulating T cell homeostasis. In this study, we have utilized Rag1−/− blastocyst complementation and in vitro embryonic stem (ES) cell differentiation to address the role of Beclin 1, one of the key autophagic proteins, in lymphocyte development. Beclin 1-deficient Rag 1−/− chimeras displayed a dramatic reduction in thymic cellularity compared to control mice. Using ESC differentiation in vitro, we found that the inability to maintain normal thymic cellularity is likely caused by impaired maintenance of thymocyte progenitors. Interestingly, despite drastically reduced thymocyte numbers, the peripheral T cell compartment of Beclin 1-deficient Rag 1−/− chimeras is largely normal. Peripheral T cells displayed normal in vitro proliferation despite significantly reduced numbers of autophagosomes. In addition, these chimeras had greatly reduced numbers of early B cells in the bone marrow compared to controls. However, the peripheral B cell compartment was not dramatically impacted by Beclin 1 deficiency. Collectively, our results suggest that Beclin 1 is required for maintenance of undifferentiated/early lymphocyte progenitor populations. In contrast, Beclin 1 is largely dispensable for the initial generation and function of the peripheral T and B cell compartments. This indicates that normal lymphocyte development involves Beclin 1-dependent early-stage, and distinct, Beclin 1-independent, late stage processes.
Acetylcholine (ACh) in the vertebrate retina affects the response properties of many ganglion cells, including those that display directional selectivity. Three beta and eight alpha subunits of neuronal nicotinic acetylcholine receptors (nAChRs) have been purified and antibodies have been raised against many of them. Here we describe biochemical and immunocytochemical studies of nAChRs in the rabbit retina. Radioimmunoassay and Western blot analysis demonstrated that many of the nAChRs recognized by a monoclonal antibody (mAb210) contain beta2 subunits, some of which are in combination with alpha3 and possibly other subunits. MAb210-immunoreactive cells in the inner nuclear layer (INL) were 7-14 microm in diameter and were restricted to the innermost one or two tiers of cells, although occasional cells were found in the middle of the INL. At least 60% of the cells in the ganglion cell layer (GCL) in the visual streak displayed mAb210 immunoreactivity; these neurons ranged from 7-18 microm in diameter. The dendrites of cells in both the INL and GCL could sometimes be followed until they entered one of two dense, poorly defined, bands of processes in the inner plexiform layer (IPL) that overlap the arbors of the cholinergic starburst cells. Parvalbumin and serotonin-positive neurons did not exhibit nAChR immunoreactivity. Although the level of receptor expression appeared to be low, mAb210 immunoreactivity was observed in some of the ChAT-positive (starburst) amacrine cells.
Extrarite sual areas on the banks of the middle suprasylvian sulcus were inactivated by cooling to assess the behavioral contribution of this cortical region to the extraction of a stationa figure from a moving mask. Cooling blocked figure-ground separation when the mask was moving but had no influence when the mask was static. This difference provides strong evidence that the areas nding the middle suprasylvian sulcus contribute to the neural separation of stationary from moving visual stimuli.Lesion studies have shown that the visual cortex of cats and monkeys is composed of several regions, each of which plays one or more specific roles in visual processing and cognition (1). This functional division ofcortex is related to the multiple visual maps and to the unique patterns of connections each region possesses (2). In the present study we used cooling to reversibly inactivate the middle suprasylvian (MS) cortex in the behaving cat to investigate the contribution of this cortical region in solving a complex visual perceptual problem that involves movement. Our belief that motion processing is one function of MS cortex is based on the facts that (i) many neurons in this region are highly sensitive to simple motion (3-6) and respond well to differential motion (7); (ii) there is a systematic representation of movement direction (8); and (iii) permanent lesions interfere with movement velocity discrimination (9). By extension, the purported homologous (1) cortical area V5, or MT, contributes in a similar way to vision in primates (10-14). However, most previous behavioral studies have examined motion processing in the absence of any other potentially interactive features. This situation is akin to the rather simple process of identifying the coherence, direction, or speed of flight of a flock of birds in a clear sky. However, under natural conditions there is typically relative motion between figures and either complex foregrounds or complex backgrounds. Our cats were trained to solve a discrimination in which stimuli composed of two geometrical outline patterns are partially obscured by either a moving grid pattern or a moving, nonsystematically arrayed pattern comprised of variable spatial frequencies. In this task the figure remains stationary and the mask moves coherently in the standard directions of up and down. This task is akin to identifying an object either behind a moving mesh (e.g., chain-link fence) or in a wind-driven black-snow storm. Our results show that (i) motion is a visual cue useful to cats for separating a static figure from a moving foreground mask and that the-MS cortex plays a critical role in this separation, and (ii) the perceptual deficits in vision induced by the cooling of this region are completely reversible. EXPERIMENTAL METHODS Three cats (S, Sd, and V) were trained to discriminate between an outline figure I and an outline figure 0 obscured by a multiline grid mask that oscillated up and down across the figures (Fig. 2D). In two ofthe cats (Sd and V) the optic chiasm an...
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