Temporal characterization of microglia, IL-1 beta-like immunoreactivity and astrocytes in the dentate gyrus of hippocampal organotypic slice cultures.

These studies demonstrate that murine hippocampal slice cultures possess neural-immune elements that show responses parallel to comparable in vivo models of neural-immune activation. Using immunocytochemical techniques, this study characterized the phenotypes of specific glial elements and the expression of the cytokine, interleukin-1 (IL-1 beta), in the hippocampal dentate gyrus over a period of 10 days in vitro (DIV). Preparation of organotypic slice cultures of neonatal mouse hippocampus produced cellular damage including axotomy of afferent fibers within the molecular layer of the dentate gyrus. This form of lesion-induced injury caused activation of neural-immune elements in the slice cultures. Staining with the microglial specific biotinylated Griffonia simplicifolia B4-isolectin revealed reactive microglia were most prevalent at 2 DIV and decreased in number from 4 to 10 DIV, whereas the initial population of resting microglia at 2 DIV increased approximately four-fold from 4 to 10 DIV. The presence of a round IL-1 beta-like immunophenotype closely paralleled the temporal and spatial distribution of the reactive form of microglia observed in the dentate gyrus. In addition, between 4 and 10 DIV, some IL-1 beta-like immunoreactive cells exhibited a stellate-like morphology with numerous branching processes, similar to resting microglia. At 2 DIV astrocytes showed minimal labeling with antibodies directed against glial fibrillary acidic protein (GFAP), while from 4 to 10 DIV, a dramatic hypertrophic astrocytic response occurred, resulting in a gliotic scar forming over the entire dentate gyrus. We conclude that neural-immune activation in the hippocampal organotypic slice culture preparation closely parallels similar responses observed in vivo and thus slice cultures represent an excellent model for further studies of neural-immune interactions resulting from lesion-induced injury in the central nervous system.

Cellular and molecular correlates to plasticity during recovery from injury in the developing mammalian brain.

In summary, our studies indicate that the perinatal mammalian brain shows considerable plasticity in response to trauma. Studies carried out both in vivo in the perinatal mouse brain and in vitro in cell line culture and organotypic slice cultures of developing brain tissue, indicate that the cytokine, interleukin-1 beta (IL-1 beta) regulates early healing responses that restore the integrity of the damaged structure and create conditions conducive to the sprouting of new connections involved in plasticity. In response to a lesion placed in the cerebral cortex in a late third trimester embryo, astrocytes form a line that delimits damaged tissue being removed by phagocytic macrophages from tissue that will remain part of the neural parenchyma. By six days after birth, this line of delimiting astrocytes (LDA) appears to become the new glial limiting membrane or glial limitans at the lesion site. A gliotic scar covers the new glial limitans, but no gliosis appears within the neural parenchyma itself. The expression of IL-1 beta is upregulated in astrocytes that form the LDA and is also upregulated in the parenchyma internal to the LDA. Experiments done in vivo where the type 1 interleukin-1 receptor was blocked via injection of interleukin-receptor antagonist protein (IL-ra) indicated that both LDA formation and wound closure were dependent upon interleukin type 1 receptor activation. To test the idea that IL-1 beta could directly influence astrocyte shape and orientation, in vitro studies were carried out on astrocytic C6 glioma cells in culture. IL-1 beta induced changes in cell shape and orientation similar to those seen in in vivo formation of the LDA. Addition of IL-1ra blocked IL-1 beta induced changes in C6 cells. IL-1 beta, then, acting upon its type 1 receptor, regulates astrocytic activities that, in vivo, produce successful healing in the perinatal brain. Studies in organotypic slice cultures of early postnatal mouse hippocampus parallel in vivo studies. Phagocytic cells, in this case, "reactive/activated" microglia, reach peak numbers immediately after injury induced by culture preparation. The round microglia were replaced over 10 days in culture by "resting/ramified" microglia. Over the first 2 days of culture, astrocytes appeared thin and elongated, resembling cells that form the LDA in vivo. Over the next 8 days in cultures, astrocytes underwent hypertrophy to form a gliotic scar over the surface of the culture. The scar resembled that seen external to the LDA after healing in in vivo experiments. IL-1 beta was abundantly expressed throughout the culture period by cells showing a variety of morphologies. Finally, neurite sprouting, an indicator of circuit reorganization and plasticity, occurred rapidly in the hippocampal dentate gyrus in both in vivo and in vitro paradigms. A prenatally placed lesion in the entorhinal cortex that partially deafferents the developing dentate gyrus, induced novel sprouting of the axons of dentate granule cells, the mossy fibers, into the dentate molecular layer. Similar sprouting occurred in vitro in organotypic slice culture of deafferented hippocampus. In culture, sprouting was first observed at the time of onset of astrocyte hypertrophy, indicating that astrocyte derived factors may play a role in regulating circuit reorganization. Viewed together, in vivo and in vitro studies indicate that IL-1 beta upregulation in neural tissue correlates with glial activities that underlie rapid healing and repair in the perinatal brain, and that glial activities associated with deafferentation may play a role in inducing compensatory neurite sprouting and cicuit reorganization.

Factors influencing mossy fiber collateral sprouting in organotypic slice cultures of neonatal mouse hippocampus.

Collateral sprouting of dentate granule cell axons, the mossy fibers, occurs in response to denervation, kindling, or excitotoxic damage to the hippocampus. Organotypic slice culture of rodent hippocampal tissue is a model system for the controlled study of collateral sprouting in vitro. Organotypic roller-tube cultures were prepared from hippocampal slices derived from postnatal day 7 mice. The Timm heavy metal stain and densitometry were used to assay the degree of mossy fiber collateral sprouting in the molecular layer of the hippocampal dentate gyrus. Factors influencing mossy fiber collateral sprouting were time in culture, positional origin of the slice culture along the septotemporal axis of the hippocampus, and presence of attached subicular-entorhinal cortical tissues. Collateral sprouting in the molecular layer was first detected after 6 days in culture and increased steadily thereafter. By 2 weeks considerable sprouting was apparent, and at 3 weeks intense sprouting was observed within the molecular layer. An intrinsic septal-to-temporal gradient of collateral sprouting was apparent at 14 days in culture. To determine whether differential damage to the mossy fibers was the basis for the differences in collateral sprouting along the septotemporal axis, we made complete transections of the mossy fiber projection as it exited the dentate hilus at various levels along the septotemporal axis; no differences were found on subsequent collateral sprouting in the dentate molecular layer. Timm-stained hippocampal cultures with an attached entorhinal cortex, a major source of afferent innervation to the dentate granule cells, displayed significantly less collateral sprouting at 10 days in culture compared to that in cultures from adjacent sections without attached subicular-entorhinal tissues present. Thus, time in culture, position along the septotemporal axis, and presence of afferent cortical tissues influence aberrant neurite collateral sprouting in organotypic slice cultures of neonatal mouse hippocampus.

Mapping the early development of projections from the entorhinal cortex in the embryonic mouse using prenatal surgery techniques.

The purpose of this work was to study the development of specific projections from the postero-lateral cortex during the third trimester of gestation in the mouse. To do this, we labeled undifferentiated lateral cortex with the fluorescent carbocyanine dye, Dil, in the embryonic day (E) 16 mouse embryo using exo utero surgical techniques (Muneoka, Wanek, and Bryant, 1986). Embryos were allowed to develop to term (postnatal day 0, P0) at which time the fiber patterns emanating from the marked regions were studied. Dye placement in the undifferentiated postero-ventral cortex produced labeled fibers in the hippocampal formation. A robust projection of the angular bundle into the CA1 region of the hippocampus was heavily labeled. In addition, in some animals, cortical tracts, such as the anterior commissure, corpus callosum, and a corticotectal tract, were labeled. These tracts have been described previously as scaffolding pathways in the fetal cat (McConnell, Ghosh, and Shatz, 1989), and other vertebrates (Wilson, Ross, Parrett, and Easter, 1990). Dye placement in adjacent, more anterior or dorsal areas showed strong labeling in cortical structures but no labeling in the hippocampal formation. These data indicate that, by birth, the temporal cortex is subdivided along the rostro-caudal axis as entorhinal cortex and perirhinal cortex, and along the dorso-ventral axis, as entorhinal cortex and neocortex. Also, these earliest connections are similar to adult connections in their specificity of target area selection. Therefore, these early, yet specific, connections may play a role int he formation of future connections during postnatal development.