Molecular logic of neocortical projection neuron specification, development and diversity.

The sophisticated circuitry of the neocortex is assembled from a diverse repertoire of neuronal subtypes generated during development under precise molecular regulation. In recent years, several key controls over the specification and differentiation of neocortical projection neurons have been identified. This work provides substantial insight into the 'molecular logic' underlying cortical development and increasingly supports a model in which individual progenitor-stage and postmitotic regulators are embedded within highly interconnected networks that gate sequential developmental decisions. Here, we provide an integrative account of the molecular controls that direct the progressive development and delineation of subtype and area identity of neocortical projection neurons.

Manipulation of neural precursors in situ: induction of neurogenesis in the neocortex of adult mice.

Over the past three decades, research exploring potential neuronal replacement therapies have focused on replacing lost neurons by transplanting cells or grafting tissue into diseased regions of the brain. Over most of the past century of modern neuroscience, it was thought that the adult brain was completely incapable of generating new neurons. However, in the last decade, the development of new techniques has resulted in an explosion of new research showing that neurogenesis, the birth of new neurons, normally occurs in two limited and specific regions of the adult mammalian brain, and that there are significant numbers of multipotent neural precursors in many parts of the adult mammalian brain. Recent findings from our lab demonstrate that it is possible to induce neurogenesis de novo in the adult mammalian brain, particularly in the neocortex where it does not normally occur, and that it may become possible to manipulate endogenous multipotent precursors in situ to replace lost or damaged neurons. Elucidation of the relevant molecular controls may allow the development of neuronal replacement therapies for neurodegenerative disease and other CNS injuries that do not require transplantation of exogenous cells.

Specific neurotrophic factors support the survival of cortical projection neurons at distinct stages of development.

Repair of specific neuronal circuitry in the neocortex may be possible via neural precursor transplantation or manipulation of endogenous precursors in situ. These approaches will almost certainly require a detailed understanding of the mechanisms that control survival and differentiation of specific neuronal lineages. Such analysis has been hampered by the overwhelming diversity of neuronal types intermixed in neocortex and the inability to isolate individual lineages. To elucidate stage-specific controls over the survival of individual lineages of cortical neurons, we purified immature callosal projection neurons (CPN) at distinct stages of development from embryonic and postnatal mouse cortex by retrograde fluorescence labeling, followed by fluorescence-activated cell sorting. Purified CPN survive well in culture, acquire stage-specific projection neuron morphologies, and express appropriate neurotransmitters and growth factor receptors. Purified CPN are dependent on exogenous trophic support for survival in a stage-specific manner. Survival of postnatal day 2 (P2) to P3 and P6-P7 CPN is promoted by overlapping but distinct sets of neurotrophic factors, whereas embryonic day 19 CPN show less specificity of dependence on peptide factors. These studies demonstrate for the first time the stage-specific control by peptide growth factors over the survival of a specific cortical neuronal lineage. Such information may be critical for the future goal of directed differentiation of transplanted or endogenous precursors toward cellular repair of complex cortical circuitry.

Transplanted neuroblasts differentiate appropriately into projection neurons with correct neurotransmitter and receptor phenotype in neocortex undergoing targeted projection neuron degeneration.

Reconstruction of complex neocortical and other CNS circuitry may be possible via transplantation of appropriate neural precursors, guided by cellular and molecular controls. Although cellular repopulation and complex circuitry repair may make possible new avenues of treatment for degenerative, developmental, or acquired CNS diseases, functional integration may depend critically on specificity of neuronal synaptic integration and appropriate neurotransmitter/receptor phenotype. The current study investigated neurotransmitter and receptor phenotypes of newly incorporated neurons after transplantation in regions of targeted neuronal degeneration of cortical callosal projection neurons (CPNs). Donor neuroblasts were compared to the population of normal endogenous CPNs in their expression of appropriate neurotransmitters (glutamate, aspartate, and GABA) and receptors (kainate-R, AMPA-R, NMDA-R. and GABA-R), and the time course over which this phenotype developed after transplantation. Transplanted immature neuroblasts from embryonic day 17 (E17) primary somatosensory (S1) cortex migrated to cortical layers undergoing degeneration, differentiated to a mature CPN phenotype, and received synaptic input from other neurons. In addition, 23.1 +/- 13.6% of the donor-derived neurons extended appropriate long-distance callosal projections to the contralateral S1 cortex. The percentage of donor-derived neurons expressing appropriate neurotransmitters and receptors showed a steady increase with time, reaching numbers equivalent to adult endogenous CPNs by 4-16 weeks after transplantation. These results suggest that previously demonstrated changes in gene expression induced by synchronous apoptotic degeneration of adult CPNs create a cellular and molecular environment that is both permissive and instructive for the specific and appropriate maturation of transplanted neuroblasts. These experiments demonstrate, for the first time, that newly repopulating neurons can undergo directed differentiation with high fidelity of their neurotransmitter and receptor phenotype, toward reconstruction of complex CNS circuitry.

Induction of neurogenesis in the neocortex of adult mice.

Neurogenesis normally only occurs in limited areas of the adult mammalian brain--the hippocampus, olfactory bulb and epithelium, and at low levels in some regions of macaque cortex. Here we show that endogenous neural precursors can be induced in situ to differentiate into mature neurons, in regions of adult mammalian neocortex that do not normally undergo any neurogenesis. This differentiation occurs in a layer- and region-specific manner, and the neurons can re-form appropriate corticothalamic connections. We induced synchronous apoptotic degeneration of corticothalamic neurons in layer VI of anterior cortex of adult mice and examined the fates of dividing cells within cortex, using markers for DNA replication (5-bromodeoxyuridine; BrdU) and progressive neuronal differentiation. Newly made, BrdU-positive cells expressed NeuN, a mature neuronal marker, in regions of cortex undergoing targeted neuronal death and survived for at least 28 weeks. Subsets of BrdU+ precursors expressed Doublecortin, a protein found exclusively in migrating neurons, and Hu, an early neuronal marker. Retrograde labelling from thalamus demonstrated that BrdU+ neurons can form long-distance corticothalamic connections. Our results indicate that neuronal replacement therapies for neurodegenerative disease and CNS injury may be possible through manipulation of endogenous neural precursors in situ.

Neocortical neurons lacking the protein-tyrosine kinase B receptor display abnormal differentiation and process elongation in vitro and in vivo.

The spatial and temporal expression of the protein-tyrosine kinase B (TrkB) receptor and its ligands has been correlated with the development of the neocortex. Activation of the receptor has been associated with neocortical neuronal survival, differentiation, connectivity and neurotransmitter release. Although such findings suggest an important role for TrkB signaling in corticogenesis, conclusive evidence from targeted gene deletion ("knockout"; TrkB -/-) mice has been limited, due in part to the neonatal lethality of most of these mutant mice and the confounding variables associated with the poor health of those few surviving slightly longer postnatally. In the present study, the effects of TrkB signaling on the survival, differentiation and integration of neocortical neurons was directly investigated in vitro and in vivo. First, we conducted a neuron-specific immunocytochemical analysis of TrkB -/- mice to determine whether early cortical structure and patterns of histogenesis were normal or perturbed. We then employed in vitro and in vivo approaches to extend the life of TrkB -/- neocortical neurons beyond the period possible in TrkB -/- mutant mice themselves: (i) dissociated cell culture to directly compare the developmental potential of TrkB -/-, +/- and +/+ neurons; and (ii) neural transplantation into homochronic wild-type recipients to investigate the cell-autonomous effects of the receptor knockout on the differentiation, growth and integration of neocortical neurons. These latter experiments allowed, for the first time, study of the survival and differentiation potential of TrkB -/- neocortical neurons beyond the initial stages of corticogenesis. Direct comparison of brains of TrkB -/-, +/- and +/+ littermates immunocytochemically labeled with antibodies to microtubule-associated protein-2, neurofilament and beta-tubulin III revealed subtle anatomical anomalies in the mutant mice. These anomalies include abnormally diffuse microtubule-associated protein-2 positive neurons just dorsal to the corpus callosum, and heterotopic aggregations of postmitotic neurons in the subventricular zones of the ganglionic eminences, both suggesting delayed neuronal migration and differentiation. Cell culture experiments revealed substantially reduced survival by TrkB -/- neocortical neurons, and a significant reduction in neurite outgrowth by surviving TrkB -/- neurons. In experiments where prelabeled embryonic or neonatal TrkB -/- neocortical neurons were transplanted into the cerebral cortices of neonatal wild-type recipients, a similar quantitatively significant defect in the formation of dendrites, as well as reduced integration of TrkB -/- neocortical neurons, was also evident. These findings demonstrate cell-autonomous abnormalities in the development of neocortical neurons from TrkB -/- mice, and the subtle, but potentially critical, role of protein-tyrosine kinase B signaling in neocortical neuronal survival, differentiation and connectivity.

Targeted neuronal death affects neuronal replacement and vocal behavior in adult songbirds.

In the high vocal center (HVC) of adult songbirds, increases in spontaneous neuronal replacement correlate with song changes and with cell death. We experimentally induced death of specific HVC neuron types in adult male zebra finches using targeted photolysis. Induced death of a projection neuron type that normally turns over resulted in compensatory replacement of the same type. Induced death of the normally nonreplaced type did not stimulate their replacement. In juveniles, death of the latter type increased recruitment of the replaceable kind. We infer that neuronal death regulates the recruitment of replaceable neurons. Song deteriorated in some birds only after elimination of replaceable neurons. Behavioral deficits were transient and followed by variable degrees of recovery. This raises the possibility that induced neuronal replacement can restore a learned behavior.

Neural precursor differentiation following transplantation into neocortex is dependent on intrinsic developmental state and receptor competence.

Reconstruction of neocortical circuitry by transplantation of neural precursors, or by manipulation of endogenous precursors, may depend critically upon both local microenvironmental control signals and the intrinsic competence of populations of precursors to appropriately respond to external molecular controls. Dependence on the developmental state of donor or endogenous precursor cells in achieving appropriate differentiation, integration, and connectivity is not clearly understood. Recent studies have demonstrated the ability to generate expandable, often clonal neural precursors at various stages of development. Transplantation of a variety of these precursors suggests that precursor differentiation and integration within the central nervous system (CNS) may depend directly on the level of cellular maturation, with less differentiated, earlier stage precursors offering more flexible but less efficient integration and more differentiated, later stage precursors offering more efficient differentiation to specific phenotypes. To further investigate this hypothesis within neocortex, we used the relatively immature HiB5 multipotent neural precursor cell line derived from embryonic day 16 hippocampus, which is less mature than precursor types that have demonstrated neuronal differentiation in adult neocortex. HiB5 cells labeled fluorescently, radioactively, and genetically were transplanted into murine neocortex under three different conditions expected to offer varying levels of instructive and permissive microenvironmental signals: (1) the developing cortex in utero; (2) regions of adult neocortex undergoing targeted pyramidal neuronal degeneration in which developmental signals are upregulated and in which later stage precursors and immature neurons undergo directed pyramidal neuron differentiation; or (3) the intact adult neocortex. Differentiation and integration of transplanted cells were examined histologically and immunocytochemically by morphology and using neuronal- and glial-specific markers. We found that these precursors underwent differentiation toward cortical neuron phenotypes with characteristic morphologies when transplanted in utero, but failed to do so under either of the adult conditions. HiB5 precursors demonstrated highly immature characteristics in vitro, consistently expressing neuroepithelial but not glial or neuronal markers. Under all conditions, donor cells survived and migrated 1-2 mm from the injection track 2 to 4 weeks after transplantation. HiB5 neural precursors transplanted into the developing cortex of embryonic mice in utero migrated within the cortex, integrated well into the host parenchyma, and differentiated toward morphologically diverse, neuronal phenotypes. HiB5 cells transplanted into the intact cortex of adult mice survived, but did not show neuronal differentiation. In contrast to slightly later stage neural precursors and embryonic neurons used in previous transplantation studies, the HiB5 cells also failed to undergo neuronal differentiation after transplantation into regions undergoing induced apoptotic neuronal degeneration in adult cortex. These results suggested that these early hippocampal-derived precursors might not be fully competent to respond to later stage differentiation and/or survival signals important in neocortex and known to be upregulated in regions undergoing targeted neuronal apoptosis, including the TrkB neurotrophin receptor ligands BDNF and NT-4/5. We investigated this hypothesis and found that undifferentiated HiB5 cells lack catalytic trkB neurotrophin receptors at the mRNA and protein levels, while confirming that they express trkC receptors under the same conditions. Taken together, these findings support a progressive sequence of neural precursor differentiation and a spectrum of competence by precursors to respond to instructive microenvironmental signals. (ABSTRACT TRUNCATED)

Mature astrocytes transform into transitional radial glia within adult mouse neocortex that supports directed migration of transplanted immature neurons.

Neuronal migration is an essential step in normal mammalian neocortical development, and the expression of defined cellular and molecular signals within the developing cortical microenvironment is likely crucial to this process. Therapy via transplanted or manipulated endogenous precursors for diseases which involve neuronal loss may depend critically on whether newly incorporated cells can actively migrate to repopulate areas of neuronal loss within the adult brain. Previous studies demonstrated that embryonic neurons and multipotent precursors transplanted into the neocortex of adult mice undergoing targeted apoptosis of pyramidal neurons migrate long distances into neuron-deficient regions, undergo directed differentiation, accept afferent synaptic input, and make appropriate long-distance projections. The experiments presented here: (1) use time-lapse digital confocal imaging of neuronal migration in living slice cultures to assess cellular mechanisms utilized by immature neurons during such long distance migration, and (2) identify changes within the host cortical astroglial population that may contribute to this migration. Prelabeled embryonic day 17 mouse neocortical neurons were transplanted into adult mouse primary somatosensory cortex undergoing targeted apoptotic degeneration of callosal projection neurons. Four to 7 days following transplantation, living slice cultures containing the region of transplanted cells were prepared and observed. Sequential time-lapse images were recorded using a video-based digital confocal microscope. Transplanted cells displayed bipolar morphologies characteristic of migrating neuroblasts and moved in a saltatory manner with mean rates of up to 14 microm/h. To investigate whether a permissive glial phenotype may provide a potential substrate for this directed form of neuronal migration, slice cultures were immunostained with the RC2 monoclonal antibody, which identifies radial glia that act as a substrate for neuronal migration during corticogenesis. RC2 does not label mature stellate astrocytes, which express glial fibrillary acidic protein (GFAP). RC2 expression was observed in glial cells closely apposed to migrating donor neurons within the slice cultures. The timing and specificity of RC2 expression was examined immunocytochemically at various times following transplantation. RC2 immunostaining within regions of neuronal degeneration was transient, with peak staining between 3 and 7 days following transplantation. Strongly RC2-immunoreactive cells that did not express GFAP were found within these regions, but not in distant cortical regions or within control brains. RC2-positive cells were identified in recipient transgenic mice which express beta-galactosidase under a glial specific promoter. Coexpression of RC2 and beta-galactosidase identified these cells as host astroglia. These results demonstrate that adult cortical astrocytes retain the capacity to reexpress an earlier developmental phenotype that may partially underlie the observed active migration of transplanted neurons and neural precursors. Further understanding of these processes could allow directed migration of transplanted or endogenous precursors toward therapeutic cellular repopulation and complex circuit reconstruction in neocortex and other CNS regions.

Mena is required for neurulation and commissure formation.

Mammalian enabled (Mena) is a member of a protein family thought to link signal transduction pathways to localized remodeling of the actin cytoskeleton. Mena binds directly to Profilin, an actin-binding protein that modulates actin polymerization. In primary neurons, Mena is concentrated at the tips of growth cone filopodia. Mena-deficient mice are viable; however, axons projecting from interhemispheric cortico-cortical neurons are misrouted in early neonates, and failed decussation of the corpus callosum as well as defects in the hippocampal commissure and the pontocerebellar pathway are evident in the adult. Mena-deficient mice that are heterozygous for a Profilin I deletion die in utero and display defects in neurulation, demonstrating an important functional role for Mena in regulation of the actin cytoskeleton.

Differentiation of transplanted neural precursors varies regionally in adults striatum.

In the current experiments, we address the emerging hypothesis that transplanted neural precursor cells can respond to local microenvironmental signals in the post-developmental brain and exhibit patterns of differentiation that depend critically on specific location within the brain. HiB5 precursor cells were transplanted into adult mouse cortex, corpus callosum, and multiple positions in striatum, and assessed for differentiation by morphology and immunocytochemistry. Our results indicate that the likelihood of both neuronal and glial differentiation of transplanted precursors depends on proximity to the medial striatum or subventricular zone of the adult host, supporting the concept that microenvironmental signals can critically affect the differentiation fate of neural precursors, and suggesting the potential to manipulate such signals in the adult brain.

Cortical interneurons upregulate neurotrophins in vivo in response to targeted apoptotic degeneration of neighboring pyramidal neurons.

Intercellular signals provided by growth and neurotrophic factors play a critical role during neurogenesis and as part of cellular repopulation strategies directed toward reconstruction of complex CNS circuitry. Local signals influence the differentiation of transplanted and endogenous neurons and neural precursors, but the cellular sources and control over expression of these molecules remain unclear. We have previously examined microenvironmental control in neocortex over neuron and neural precursor migration and differentiation following transplantation, using an approach of targeted apoptotic neuronal degeneration to specific neuronal populations in vivo. Prior results suggested the hypothesis that upregulated or reexpressed developmental signal molecules, produced by degenerating pyramidal neurons and/or by neighboring neurons or nonneuronal cells, may be responsible for observed events of directed migration, differentiation, and connectivity by transplanted immature neurons and precursors. To directly investigate this hypothesis, we analyzed the gene expression of candidate and control neurotrophins, growth factors, and receptors within regions of targeted neuronal cell death, first by quantitative Northern blot analysis and then by in situ hybridization combined with immunocytochemical analysis. The genes for BDNF, NT-4/5, trkB receptors, and to a lesser extent NT-3 were upregulated specifically within the regions of neocortex undergoing targeted neuronal degeneration and specifically during the period of ongoing pyramidal neuron apoptosis. Upregulation occurred during the same 3-week period as the previously investigated cellular events of directed migration, differentiation, and integration. No upregulation was seen in panels of control neurotrophins, growth factors, and receptors that are not as developmentally regulated in cortex or that are thought to have primary actions in other CNS regions. In situ hybridization and immunocytochemistry revealed that BDNF mRNA expression was upregulated specifically by local interneurons adjacent to degenerating pyramidal neurons. These findings suggest specific effects of targeted apoptosis on neurotrophin and other gene expression via mechanisms, including intercellular signaling between degenerating pyramidal neurons and surrounding interneurons. Further understanding of these and other controls over neocortical projection neuron differentiation may provide insight regarding normal neocortical development, intercellular signaling induced by apoptosis, and toward reconstruction and cellular repopulation of complex neocortical and other CNS circuitry.

Multipotent neural precursors can differentiate toward replacement of neurons undergoing targeted apoptotic degeneration in adult mouse neocortex.

Neurons undergoing targeted photolytic cell death degenerate by apoptosis. Clonal, multipotent neural precursor cells were transplanted into regions of adult mouse neocortex undergoing selective degeneration of layer II/III pyramidal neurons via targeted photolysis. These precursors integrated into the regions of selective neuronal death; 15 +/- 7% differentiated into neurons with many characteristics of the degenerated pyramidal neurons. They extended axons and dendrites and established afferent synaptic contacts. In intact and kainic acid-lesioned control adult neocortex, transplanted precursors differentiated exclusively into glia. These results suggest that the microenvironmental alterations produced by this synchronous apoptotic neuronal degeneration in adult neocortex induced multipotent neural precursors to undergo neuronal differentiation which ordinarily occurs only during embryonic corticogenesis. Studying the effects of this defined microenvironmental perturbation on the differentiation of clonal neural precursors may facilitate identification of factors involved in commitment and differentiation during normal development. Because photolytic degeneration simulates some mechanisms underlying apoptotic neurodegenerative diseases, these results also suggest the possibility of neural precursor transplantation as a potential cell replacement or molecular support therapy for some diseases of neocortex, even in the adult.

Embryonic neurons transplanted to regions of targeted photolytic cell death in adult mouse somatosensory cortex re-form specific callosal projections.

In the neocortex, the effectiveness of potential transplantation therapy for diseases involving neuronal loss may depend upon whether donor neurons can reestablish the precise long-distance projections that form the basis of sensory, motor, and cognitive function. During corticogenesis, the formation of these connections is affected by tropic factors, extracellular matrix, structural pathways, and developmental cell death. Previous studies demonstrated that embryonic neurons and multipotent neural precursors transplanted into neocortex or mice undergoing photolytically induced, synchronous, apoptotic neuronal degeneration selectively migrate into these regions, where they differentiate into pyramidal neurons and accept afferent synaptic input. The experiments presented here assess whether embryonic neurons transplanted into regions of somatosensory cortex undergoing targeted cell death differentiate further and develop long-distance axons and whether this outgrowth is target specific. Neocortical neurons from Gestational Day 17 mouse embryos were dissociated, prelabeled with fluorescent nanospheres and a lipophilic dye (DiI or PKH), and transplanted into adult mouse primary somatosensory cortex (S1) undergoing apoptotic degeneration of callosal projection neurons. Donor neurons selectively migrated into and differentiated within regions of targeted neuronal death in lamina II/III over a 2-week period, in agreement with our prior studies. To detect possible projections made by donor neurons 2, 4, 6, 8, or 10 weeks following transplantation, the retrogradely transported dye fluorogold (FG) was stereotaxically injected into contralateral S1, ipsilateral secondary somatosensory cortex (S2), or ipsilateral thalamus. Ten weeks following transplantation, 21 +/- 5% of the labeled donor neurons were labeled by FG injections into contralateral S1, demonstrating that donor neurons sent projections to the distant area, the original target of host neurons undergoing photolytically induced cell death. No donor neurons were labeled with FG injections into ipsilateral S2 or thalamus, nearby targets of other subpopulations of neurons in S1. These data indicate that in the adult neocortex: (1) transplanted immature neurons are capable of extending long-distance projections between hemispheres through the mature white matter of the corpus callosum and (2) these projections are formed with specificity to replace projections by neurons undergoing synchronous degeneration. These experiments provide an experimental system with which to test factors affecting such outgrowth and connectivity. Taken together, these results suggest that the reconstruction and repair of cortical circuitry responsible for sensory, motor, or cognitive function may be possible in the mature neocortex, if donor neurons or precursor cells are provided with the correct combination of local and distant signals within an appropriately permissive host environment.

Targeted neocortical cell death in adult mice guides migration and differentiation of transplanted embryonic neurons.

Local expression of cellular and molecular signals is required for normal neuronal migration and differentiation during neocortical development and during periods of plasticity in the adult brain. We have previously shown that neonatal and juvenile mice that induction of apoptotic degeneration in neocortical pyramidal neurons by targeted photolysis provides an altered environment that directs migration and differentiation of transplanted embryonic neurons. Here we employ the same paradigm in adult mice to test whether targeted photolysis induces the reexpression in the mature brain of developmental signals that control migration, differentiation and integration of embryonic neurons. We examined both the time course of migration and the morphologic and immunocytochemical differentiation of embryonic neurons transplanted into regions of targeted photolytic cell death. Pyramidal neurons in neocortical lamina II/III underwent photolytically induced apoptosis after retrograde incorporation of the photoactive chromophore chlorine e6 and transdural exposure to 674 nm near-infrared laser energy. Embryonic day 17 neocortical neurons were prelabeled with fluorescent nanospheres and the lipophilic dye PKH26, transplanted into regions of ongoing neuronal degeneration in adult mice, and examined histologically and immunocytochemically. Transplanted neurons began migration into regions of neuronal death within 3 d and differentiated into large pyramidal neurons similar to those degenerating. In contrast, neurons transplanted into intact cortex did not migrate, and they differentiate into small presumptive interneurons. Migration up to 430 microM in experimental mice was complete by 2 weeks; approximately 45% of the donor neurons migrated greater than 3 SDs beyond the mean for neurons transplanted into intact neocortex of age-matched adult hosts. Following migration, dendrites and axons of many donor neurons were properly oriented toward the pial surface and corpus callosum, indicating integration into the host parenchyma. Neurofilament and neuron-specific enolase staining further support appropriate differentiation and integration. These results indicate that signals guiding neuronal migration and differentiation in neocortex are reexpressed in adult mice well beyond the period of corticogenesis within regions of targeted photolytic cell death. Elucidating the molecular mechanisms underlying these events by comparison with adjacent unperturbed regions will contribute to efforts toward future therapeutic transplantation and control over endogenous plasticity.

Multipotent neural progenitor or stem-like cells may be uniquely suited for therapy for some neurodegenerative conditions.

Multipotent neural progenitors or stem cells (or cells which mimic their behavior) are capable of differentiating along multiple central nervous system (CNS) cell-type lineages, neuronal and glial. They can engraft as integral members of normal structures throughout the host CNS without disturbing other neurobiological processes. By exploiting their basic biologic properties, these cells may be able to disseminate therapeutic gene products in a sustained, direct fashion throughout the CNS. In addition, they may replace dysfunctional neurons and glia in both a site-specific and global manner. They may play a therapeutic role in neurodegenerative conditions that occur both during development and in the mature brain. The ability of neural stem cells to respond to neurogenic cues not only when they occur during their normal developmental expression but even when induced or "reactivated" at later stages following injury, may entrance their utility in reconstituting damaged CNS regions. Thus, these vehicles may overcome many of the limitations of viral and non-neural cellular vectors, as well as pharmacologic and genetic interventions. The feasibility of this broadly applicable neural stem cell-based strategy has been demonstrated in a number of murine models of neurodegenerative disease. The focus of this review will be our recent observation of a possible tropism of such cells for neurodegenerative environments.

Apoptotic mechanisms in targeted neuronal cell death by chromophore-activated photolysis.

Apoptosis influences early development and later refinement in adult tissues. Experiments in which embryonic neurons or multipotent neural precursor cells are transplanted into regions of neuronal degeneration following targeted photolytic cell death show similar regulation of neuronal migration and differentiation. In those experiments, transplanted cells sought to restore normal cytoarchitecture by preferential migration into neuron deficient regions, assumption of pyramidal morphology, and early process elongation. Control transplants into intact and kainic acid lesioned cortex failed to elicit similar responses. We investigated the possibility that mechanisms of neuronal death common to apoptosis and targeted photolysis could explain the similar developmental influences. We assessed the pathways of cellular injury and eventual cell death in neuroblastoma and PC12 cell cultures labeled with nanospheres carrying the chromophore NH4-chlorin e6 and subjected to photoactivation (1) pharmacologically by scavengers of singlet oxygen and inhibitors of lysosomal proteases, (2) histologically by electron, fluorescence, and light microscopy, and (3) biochemically with binding of cellular DNA by propridium iodide, 3'-OH DNA end terminal labeling, and gel electrophoresis. We found that nanospheres were incorporated into lysosomes, and exposure to light energy led to singlet oxygen (1O2) production and cell death within both neuroblastoma and PC-12 cell lines. Scavengers of 1O2 prevented cell toxicity, while inactivation of lysosomal proteases reduced cell death. Morphologically, degenerating cells revealed release of proteases from lysosomes and disruption of cytoskeletal proteins. Apoptotic characteristics including early loss of cell adhesion, plasma membrane blebbing, and nuclear condensation and convolution were observed. Biochemically, DNA fragmentation was present in cells stained with propridium iodide and observed by 3'-OH end terminal labeling and gel electrophoresis. Thus, cells targeted by photolytically generated 1O2 undergo a form of cell autolysis whose final common pathway is apoptotic. The slow, nonnecrotic process of targeted neuronal cell death in vivo may activate many of the same physiological cues activated by programmed cell death during normal development and during organizational refinement in the adult vertebrate nervous system. This may potentially explain the migration and differentiation of neocortical neurons and neural precursors transplanted into these regions of neuronal degeneration.

Transplanted neocortical neurons migrate selectively into regions of neuronal degeneration produced by chromophore-targeted laser photolysis.

Selective degeneration of neocortical callosal pyramidal neurons by noninvasive laser illumination was used for directed studies of neocortical transplantation, to test the hypothesis that transplanted embryonic neurons may seek to restore normal cytoarchitecture within an appropriately permissive local environment. At long wavelengths that penetrate through tissue without major absorption, photolysis can cause extremely selective degeneration to desired subpopulations of targeted neurons in vivo (Macklis and Madison, 1991; Madison and Macklis, 1993). Cell death is geographically defined and slowly progressive, allowing control over the anatomical substrate for transplantation. Targeting occurs by retrograde incorporation of cytolytic chromophores that are activated by specific-wavelength light. Intermixed neurons, glia, axons, blood vessels, and connective tissue remain intact. Degeneration was effected within neocortical lamina II/III of neonatal mouse pups following targeting in utero or early postnatally with photoactive nanospheres. Total neuron density was reduced typically by 25-30% within defined areas, with approximately 60% loss of large projection neurons and no change in the number of small, presumptive interneurons. Embryonic day 17 neocortical cell suspensions, which included recently postmitotic neurons destined to form lamina II/III, were transplanted lateral to these regions of ongoing neuron degeneration in juvenile mice. Cellular injections spanned laminae II-V, to provide donor neurons with both lateral and laminar choice for possible migration and integration. Donor cells were labeled in vitro with unique fluorescent and electron-dense nanospheres that allowed distinct identification of donor cells at both light and electron microscopic levels. Control experiments included neocortical transplants into intact age-matched hosts, into hosts with kainic acid lesions to neocortex, or distant to the region of photolytic neuronal degeneration; embryonic cerebellar transplants to the regions of selective photolytic degeneration; and grafts of hypoosmotically lysed neocortical cells to lesioned regions. After survival times of 1 hr to 12 weeks, labeled neurons were identified morphologically and positions were digitized for qualitative and quantitative analysis of position and specificity of migration and cellular integration; electron microscopy was used to confirm further the donor identities of migrated neurons. Neurons placed near host zones of photolytic neuron degeneration migrated up to 780 microns specifically within these zones; approximately 44% of donor neurons migrated significantly beyond the injection site to enter these regions. Migration and integration did not occur in normal, unaffected deeper layers IV-VI of these experimental mice, or in the normal lamina II/III bordering the transplantation site on the side opposite the neuron-deficient region. Control grafts of all five types revealed only minimal local spread without laminar preference.(ABSTRACT TRUNCATED AT 400 WORDS)