Gary A. Banker

An electron microscopic study of the development of axons and dendrites by hippocampal neurons in culture. I. Cells which develop without intercellular contacts

We have studied the processes which are elaborated by hippocampal neurons in dissociated cell culture. Nerve cells, which were obtained from fetal rats at 18 to 20 days of gestation, were plated at very low density onto polylysine-treated coverslips and were maintained in serum- free medium. Under such conditions, some cells develop without contacting any neighboring neurons or glial cells. Examples of such isolated cells which had developed for 1 week in culture were studied first by light microscopy, then they were sectioned parallel to the substratum so that all portions of the cell and its processes could be examined by electron microscopy. Dendrites and axons could be clearly distinguished by both light and electron microscopy. Dendrites were rather thick at the base but tapered rapidly to a minimum diameter of about 0.5 micron and contained polyribosomes throughout their length. Axons, which were several times longer than the dendrites, were thinner at the origin, tapered much less, and were essentially ribosome-free. These ultrastructural differences were particularly obvious at branch points, where cytoplasmic organelles tend to accumulate. Clusters of polyribosomes were invariably present at dendritic branch points, but they were never observed at axonal branch points. The axons most commonly arose from the proximal portion of a dendrite rather than directly from the cell body as they typically do in situ. These observations show that the fundamental differences in form and in the distribution of ribosomes between axons and dendrites can be established in cell culture. Contact with afferent fibers or with target cells during the period of process outgrowth is unnecessary for the expression of these features of axonal and dendritic differentiation.

MAP2 is localized to the dendrites of hippocampal neurons which develop in culture

The distribution of the microtubule-associated protein MAP2 in cultured hippocampal neurons was studied using immunocytochemistry with monoclonal antibodies. MAP2 was preferentially localized to dendritic, but not axonal, processes even in single isolated cells which developed without making intercellular contacts. Hence regional differences in the molecular composition of the neuronal cytoskeleton can develop independently of cell interactions. The presence of MAP2 may be a useful marker for identifying dendrites in cell culture.

The expression and distribution of the microtubule-associated proteins tau and microtubule-associated protein 2 in hippocampal neurons in the rat in situ and in cell culture

Using a monoclonal antibody against the microtubule-associated protein tau we compared the distribution and the biochemical maturation of this protein in hippocampal pyramidal neurons in the rat in tau and in culture. In tissue sections from mature animals tau was localized heterogeneously within neurons. It was concentrated in axons; dendrites and somata showed little or no staining. In hippocampal cultures ranging from 12 h to 4 weeks in vitro tau was present in neurons but not in glial cells, as it is in situ. Within cultured neurons, however, tau was not compartmentalized but was present throughout the dendrites, axons and somata. Immunoblotting experiments showed that the biochemical maturation of tau that occurs in situ also failed to occur in culture. The young form of tau persisted, and the adult forms did not develop. In contrast the biochemical maturation and the compartmentalization of microtubule-associated protein 2 occurred normally in hippocampal cultures. These results show that the biochemical maturation and the intraneuronal compartmentalization of these two microtubule-associated proteins are independently controlled. Despite the non-restricted distribution of tau in hippocampal neurons in culture, and despite the presence of only the immature isoform which has a lessened stimulatory effect on microtubule polymerization, axons and dendrites appear to grow normally and to exhibit appropriate functional properties.

Protein synthesis and processing in cytoplasmic microdomains beneath postsynaptic sites on CNS neurons

AbstractRecent studies have shown that protein synthetic machinery consisting of polyribosomes and associated membranous cisterns is selectively localized beneath synaptic sites on neurons. In the present paper, the role of this machinery in neuronal function will be considered. We will:1.Summarize the studies that characterize the polyribosomes and define their associations with membranous cisterns. Taken together, these observations suggest the existence of a system for the synthesis and posttranslational processing of proteins at individual synaptic sites;2.Review the evidence that the protein synthetic machinery is particularly prominent during the initial formation of synaptic contacts (during early development), and during lesion-induced synaptogenesis in mature animals. These observations have led to the hypothesis that the polyribosomes produce proteins that play a role in the formation of the synaptic junction;3.Review evidence that supports the hypothesis that there is a local synthesis of protein within dendrites, as well as local glycosylation;4.Describe the evidence suggesting that at least some of the protein constituents of the synaptic junction itself are synthesized locally; and5.Descibe our studies that reveal a mechanism for selective dendritic transport of RNA; this transport mechanism permits the delivery of RNA to postsynaptic sites throughout the dendritic arbor. We will advance the hypothesis that neurons position protein synthetic machinery together with the mRNAs that are appropriate for particular synapses beneath synaptic contact regions. At the synaptic site, this machinery could then direct the synthesis of particular proteins that are critical for synapse formation or maintenance. The positioning of protein synthetic machinery at postsynaptic sites permits a rapid local regulation of the production of key proteins by events at individual synapses.

Protein synthesis and processing in cytoplasmic microdomains beneath postsynaptic sites on CNS neurons - A mechanism for establishing and maintaining a mosaic postsynaptic receptive surface

AbstractRecent studies have shown that protein synthetic machinery consisting of polyribosomes and associated membranous cisterns is selectively localized beneath synaptic sites on neurons. In the present paper, the role of this machinery in neuronal function will be considered. We will:1.Summarize the studies that characterize the polyribosomes and define their associations with membranous cisterns. Taken together, these observations suggest the existence of a system for the synthesis and posttranslational processing of proteins at individual synaptic sites;2.Review the evidence that the protein synthetic machinery is particularly prominent during the initial formation of synaptic contacts (during early development), and during lesion-induced synaptogenesis in mature animals. These observations have led to the hypothesis that the polyribosomes produce proteins that play a role in the formation of the synaptic junction;3.Review evidence that supports the hypothesis that there is a local synthesis of protein within dendrites, as well as local glycosylation;4.Describe the evidence suggesting that at least some of the protein constituents of the synaptic junction itself are synthesized locally; and5.Descibe our studies that reveal a mechanism for selective dendritic transport of RNA; this transport mechanism permits the delivery of RNA to postsynaptic sites throughout the dendritic arbor. We will advance the hypothesis that neurons position protein synthetic machinery together with the mRNAs that are appropriate for particular synapses beneath synaptic contact regions. At the synaptic site, this machinery could then direct the synthesis of particular proteins that are critical for synapse formation or maintenance. The positioning of protein synthetic machinery at postsynaptic sites permits a rapid local regulation of the production of key proteins by events at individual synapses.

The establishment of polarity by hippocampal neurons: The relationship between the stage of a cell's development in situ and its subsequent development in culture☆

Neurons removed from the embryonic hippocampus and placed into culture develop structurally and functionally distinct axonal and dendritic processes. The central issue addressed in this study concerns the extent to which the sequence of events which results in the differentiation of neurites by hippocampal neurons in culture is influenced by the cells state of development in situ. [3H]thymidine was administered to pregnant rats either on Embryonic Day 15 (E15) or on E18.5 to label hippocampal neurons at known stages of their development. All fetuses were sacrificed on E19. Some of the fetal brains were sectioned and examined by autoradiography to determine the location of labeled cells in the hippocampus. The remaining brains were used to prepare hippocampal cell cultures. Neurons labeled at E18.5 remained confined to the ventricular zone at E19. Those labeled at E15 had completed their migration to the cortical plate. Other data suggest that the former cells had not yet initiated process outgrowth, while the latter cells had begun to elaborate both axons and dendrites. When introduced into culture, both populations of cells developed axons and dendrites and both compartmentalized MAP2 to the dendritic domain. Moreover, despite marked differences in their developmental state at the time of introduction into culture, both underwent the same sequence of developmental events leading to axonal and dendritic development. In a few cases cells that incorporated [3H]thymidine in situ at E18.5 apparently underwent mitosis in culture. These neurons also developed axons and dendrites appropriately. These results indicate that hippocampal neurons become polarized in culture, even if they have never developed axons or dendrites in situ, and do so as efficiently as cells that have become polarized before being placed into culture. Moreover, they indicate that the same sequence of events leading to the establishment of polarity occurs for hippocampal neurons with different developmental histories prior to culturing.

The Process of Reinnervation of CNS Neurons: Evidence for Local Synthesis of Synaptic Constituents at Postsynaptic Sites

When neuronal connections are interrupted as a result of injury, complete reconstruction requires not only the regrowth of axons, but also successful reconnection of the growing axons with their targets. A great deal has been learned recently about the regulation of axon growth; relatively little is known however, about how reinnervation is regulated. In large measure, our ignorance about the process of reinnervation is because successful regeneration of CNS axons is so rare. For this reason, situations where reinnervation does occur are of special interest.