Immunohistochemical localization of cathepsin D and a possible role of melanocytes during tail resorption in tadpoles of a tropical toad

Programmed cell death during anuran tail resorption is primarily brought about by apoptosis. Cathepsin D, a lysosomal aspartyl protease, is involved in the death of tail tissues. Thus, anuran tail resorption presents an ideal model to study cathepsin‐mediated cell death during vertebrate development. Present study describes the trend of specific activity of cathepsin D in the tail of different developmental stages and immunohistochemical localization of cathepsin D in the tail tissues of the common Asian toad, Duttaphrynus melanostictus. Cathepsin D was involved in programmed cell death in epidermis, muscle, spinal cord, and blood cells in the resorbing tail. Interestingly, it was also involved in the pre‐resorbing tail before visible tail resorption which indicates initiation of cell death even before actually the tail resorbs. Melanocytes were found to be one of the causative agents in degrading tail tissues and were associated with the degradation of muscle, epidermis and spinal cord of the resorbing tail. J. Morphol. 2012. © 2012 Wiley Periodicals, Inc.     

Hedgehog signaling controls dorsoventral patterning, blastema cell proliferation and cartilage induction during axolotl tail regeneration

Tail regeneration in urodeles requires the coordinated growth and patterning of the regenerating tissues types, including the spinal cord, cartilage and muscle. The dorsoventral (DV) orientation of the spinal cord at the amputation plane determines the DV patterning of the regenerating spinal cord as well as the patterning of surrounding tissues such as cartilage. We investigated this phenomenon on a molecular level. Both the mature and regenerating axolotl spinal cord express molecular markers of DV progenitor cell domains found during embryonic neural tube development, including Pax6, Pax7 and Msx1. Furthermore, the expression of Sonic hedgehog (Shh) is localized to the ventral floor plate domain in both mature and regenerating spinal cord. Patched1 receptor expression indicated that hedgehog signaling occurs not only within the spinal cord but is also transmitted to the surrounding blastema. Cyclopamine treatment revealed that hedgehog signaling is not only required for DV patterning of the regenerating spinal cord but also had profound effects on the regeneration of surrounding, mesodermal tissues. Proliferation of tail blastema cells was severely impaired, resulting in an overall cessation of tail regeneration, and blastema cells no longer expressed the early cartilage marker Sox9. Spinal cord removal experiments revealed that hedgehog signaling, while required for blastema growth is not sufficient for tail regeneration in the absence of the spinal cord. By contrast to the cyclopamine effect on tail regeneration, cyclopamine-treated regenerating limbs achieve a normal length and contain cartilage. This study represents the first molecular localization of DV patterning information in mature tissue that controls regeneration. Interestingly, although tail regeneration does not occur through the formation of somites, the Shh-dependent pathways that control embryonic somite patterning and proliferation may be utilized within the blastema, albeit with a different topography to mediate growth and patterning of tail tissues during regeneration.     

Apoptosis in the developing zebrafish embryo.

Apoptosis is a major part of the normal development of many organ systems and tissues. The zebrafish (Danio rerio) has become a useful model for studying early development, and recent advances in techniques used to label apoptotic cells have made it possible to visualize apoptotic cells in this model system. We have used the in situ terminal deoxynucleotidyl transferase (TdT)-mediated dUTP nick-end labeling (TUNEL) to describe the temporal and spatial distribution of apoptotic cells during normal development of the zebrafish embryo from 12 to 96 h postfertilization. By counting labeled apoptotic cells, we have demonstrated transient high rates of cell death in various structures during development, and we have correlated these peaks with previously described developmental changes in these structures. Our analysis has focused on the nervous system and associated sensory organs including the olfactory organ, retina, lens, cornea, otic vesicle, lateral line organs, and Rohon-Beard neurons. Apoptosis is also described in other non-neural structures such as the notochord, somites, muscle, tailbud, and fins.     

Nicotine protects against arachidonic-acid-induced caspase activation, cytochrome c release and apoptosis of cultured spinal cord neurons

Hydrolysis of membrane phospholipids of spinal cord neurons is one of the first events initiated in spinal cord trauma. In this process, free fatty acids, and in particular arachidonic acid, are released. Exposure of spinal cord neurons to free arachidonic acid can compromise cell survival and initiate apoptotic cell death. In order to determine potential mechanisms of apoptosis induced by arachidonic acid, activation of caspases -3, -8, and -9, as well as the release of cytochrome c into the cytoplasm were measured in cultured spinal cord neurons exposed to 10 microM of this fatty acid. In addition, because nicotine can exert a variety of neuroprotective effects, we hypothesized that it can prevent arachidonic acid induced apoptosis of spinal cord neurons. To study this hypothesis, spinal cord neurons were pretreated with nicotine (10 microM for 2 h) before arachidonic acid exposure and caspase activation as well as markers of apoptotic cell death were studied. Treatment of spinal cord neurons with arachidonic acid for up to 24 h significantly increased cytoplasmic levels of cytochrome c, induced caspase activation and induced DNA laddering, a hallmark of apoptotic cell death. Nicotine pretreatment markedly attenuated all these effects. In addition, antagonist studies suggest that the alpha7 nicotinic receptor is primarily responsible for these anti-apoptotic effects of nicotine. These results indicate that nicotine can exert potent neuroprotective effects by inhibiting arachidonic acid induced apoptotic cascades of spinal cord neurons.     

p53- and Bax-Mediated Apoptosis in Injured Rat Spinal Cord

Spinal cord injury (SCI) induces a series of endogenous biochemical changes that lead to secondary degeneration, including apoptosis. p53-mediated mitochondrial apoptosis is likely to be an important mechanism of cell death in spinal cord injury. However, the signaling cascades that are activated before DNA fragmentation have not yet been determined. DNA damage-induced, p53-activated neuronal cell death has already been identified in several neurodegenerative diseases. To determine DNA damage-induced, p53-mediated apoptosis in spinal cord injury, we performed RT-PCR microarray and analyzed 84 DNA damaging and apoptotic genes. Genes involved in DNA damage and apoptosis were upregulated whereas anti-apoptotic genes were downregulated in injured spinal cords. Western blot analysis showed the upregulation of DNA damage-inducing protein such as ATM, cell cycle checkpoint kinases, 8-hydroxy-2′-deoxyguanosine (8-OHdG), BRCA2 and H2AX in injured spinal cord tissues. Detection of phospho-H2AX in the nucleus and release of 8-OHdG in cytosol were demonstrated by immunohistochemistry. Expression of p53 was observed in the neurons, oligodendrocytes and astrocytes after spinal cord injury. Upregulation of phospho-p53, Bax and downregulation of Bcl2 were detected after spinal cord injury. Sub-cellular distribution of Bax and cytochrome c indicated mitochondrial-mediated apoptosis taking place after spinal cord injury. In addition, we carried out immunohistochemical analysis to confirm Bax translocation into the mitochondria and activated p53 at Ser³⁹². Expression of APAF1, caspase 9 and caspase 3 activities confirmed the intrinsic apoptotic pathway after SCI. Activated p53 and Bax mitochondrial translocation were detected in injured spinal neurons. Taken together, the in vitro data strengthened the in vivo observations of DNA damage-induced p53-mediated mitochondrial apoptosis in the injured spinal cord.     

BCL-2 and BAX protect adult mice from lethal Sindbis virus infection but do not protect spinal cord motor neurons or prevent paralysis

Cellular proteins that regulate apoptotic cell death can modulate the outcome of Sindbis virus (SV) encephalitis in mice. Both endogenous and overexpressed BCL-2 and BAX proteins protect newborn mice from fatal SV infection by blocking apoptosis in infected neurons. To determine the effects of these cellular factors on the course of infection in older animals, a more neurovirulent SV vector (dsNSV) was constructed from a viral strain that causes both prominent spinal cord infection with hind-limb paralysis and death in weanling mice. This vector has allowed assessment of the effects of BCL-2 and BAX on both mortality and paralysis in these hosts. Similar to newborn hosts, weanling mice infected with dsNSV encoding BCL-2 or BAX survived better than animals infected with control viruses. This finding indicates that BCL-2 and BAX both protect neurons that mediate host survival. Neither cellular factor, however, could suppress the development of hind-limb paralysis or prevent the degeneration of motor neurons in the lumbar spinal cord. Infection of BAX knockout mice with dsNSV demonstrated that endogenous BAX also enhances the survival of animals but has no effect on paralysis. These findings for the spinal cord are consistent with earlier data showing that dying lumbar motor neurons do not exhibit an apoptotic morphology. Thus, divergent cell death pathways are activated in different target populations of neurons during neurovirulent SV infection of weanling mice.     

Total sialic acid profile in regressing and remodelling organs during the metamorphosis of marsh frog (Pelophylax ridibundus Pallas 1771)

This study aimed to investigate the functional relationship of sialic acid in regressing and remodelling organs such as the tail, small intestine and liver during the metamorphosis of Pelophylax ridibundus. For this purpose, four groups were composed according to developmental periods by considering Gosner's criteria (1964). Our findings showed that the sialic acid content of the larval tail has an opposite profile to cell death process. Although the sialic acid content of the small intestine and liver did not change evidently during metamorphosis, it increased after the completion of metamorphosis. Frog tail extensively exhibited cell death process and decreased proliferative activity and underwent complete degeneration during metamorphic climax. In spite of increased apoptotic index, a decreased sialic acid level in the tail tissues during climax can be the indication of a death cell removal process. However, the intestine and the liver included both cell death and proliferative process and remodelling in their adult forms. Thus, their sialic acid profiles during metamorphosis were different from the tail's profile. These data show that sialic acid may be an indicator of the presence of some cellular events during metamorphosis and that it can have different roles in the developmental process depending on the organ's fate throughout metamorphosis. Copyright © 2012 John Wiley & Sons, Ltd.     

Trk neurotrophin receptor-like proteins in the teleost Dicentrarchus labrax

In recent years, data have accumulated suggesting that the role of neurotrophins and Trk receptors may not be limited to the nervous system, and the presence of these substances has been detected in a variety of vertebrate and invertebrate non-nervous tissues. This study was designed to map the expression of immunoreactivity (IR) for Trk-like proteins in alevins of the teleost Dicentrarchus labrax, with particular emphasis on non-nervous structures. We used antibodies against specific epitopes of the intracellular domain of these proteins, a region that is highly conserved in phylogeny. Trk-like IR was seen in segregate cell populations of the nervous system, and non-nervous tissues. In the central nervous system TrkA-like and TrkC-like IR was abundant, whereas TrkB-like IR was restricted to a low number of brain areas. Expression of Trk-like protein IR was observed in the peripheral nervous system and sensory organs, with the exception of the lateral line organ. Outside the nervous system, TrkA-like IR was mainly found in different epithelia, TrkB-like IR in the endocrine and digestive system, and TrkC-like IR in the cardiovascular and immune systems. The gills showed IR for all three Trk-like proteins, whereas they were absent from the gonads. Furthermore, scattered cells positive for Trk-like proteins were found in most of the investigated tissues. The distribution of Trk-like IR in this teleost is compared with that of mammals and birds, which it often paralleled, and the possible role of neurotrophins and Trk-like receptor proteins in different non-neuronal tissues is discussed.     

A morphological and immunohistochemical study of programmed cell death in Botryllus schlosseri (Tunicata,Ascidiacea)

The blastogenic cycle of the colonial ascidian Botryllus schlosseri concludes in a phase of selective cell and zooid death called takeover. Every week, all asexually derived parental zooids synchronously regress over a 30-h period and are replaced by a new generation. Here we document the sequential ultrastructural changes which accompany cell death during zooid degeneration. The principal mode of visceral cell death during takeover occurred by apoptosis, the majority of cells condensing and fragmenting into multiple membrane-bounded apoptotic bodies. Cytoplasmic organelles (mitochondria, basal bodies, striated rootlets) within apoptotic bodies retained ultrastructural integrity. Dying cells and fragments were then swiftly ingested by specialized blood macrophages or intraepithelial phagocytes and subsequently underwent secondary necrotic lysis. Certain organs (stomach, intestine) displayed a combination of necrotic and apoptotic changes. Lastly, the stomach, which demonstrated some of the earliest regressive changes, exhibited intense cytoplasmic immunostaining with a monoclonal antibody to ubiquitin at the onset of takeover. Affinity-purified rabbit antiserum against sodium dodecyl sulfate-denatured ubiquitin detected a characteristic 8.6-kDa mono-ubiquitin band by Western blot analysis. Collectively, these findings raise the possibility that cell death during takeover is a dynamic process which requires active participation of cells in their own destruction.     

Apoptosis in larval and frog skin of Rana pipiens,R. catesbeiana,and Ceratophrys ornata

Apoptosis (programmed cell death) occurs during normal development of anurans in organs such as gills, gut, and tail. For example, apoptotic cells have been reported in the luminal epithelium along the length of the digestive tract of both larvae and frogs; however, timing of the peak number of such cells varies in different species. The purpose of the present study was to ascertain whether apoptosis also varies by species during metamorphic restructuring of the skin (as larval epithelium is replaced by adult epidermis). To determine this, cross‐sections of dorsal skin from representative larval stages and frogs of Rana pipiens, R. catesbeiana, and Ceratophrys ornata were incubated with monoclonal antibody against active caspase‐3, one of the main enzymes in the apoptotic cascade. We observed apoptotic cells in the epidermis of the skin of the three species and found that such cells were more numerous in larval stages than in frogs and more abundant in the two ranid species than in C. ornata. These results contribute to our understanding of metamorphic changes in anuran skin. J. Morphol. 275:51–56, 2014. © 2013 Wiley Periodicals, Inc.     

2001 Warkany lecture: to die or not to die, the role of apoptosis in normal and abnormal mammalian development

Cell death is a common and reproducible feature of the development of many mammalian tissues/organs. Two well-known examples of programmed cell death (PCD) are the cell deaths associated with fusion of the neural folds and removal of interdigital mesenchymal cells during digit formation. Like normal development, abnormal development is also associated with increased cell death in tissues/organs that develop abnormally after exposure to a wide variety of teratogens. At least in some instances, teratogens induce cell death in areas of normal PCD, suggesting that there is a link between programmed and teratogen-induced cell death. Although researchers recognized early on that cell death is an integral part of both normal and abnormal development, little was known about the mechanisms of cell death. In 1972, Kerr et al. ('72) showed conclusively that cell deaths, induced in a variety of contexts, followed a reproducible pattern, which they termed apoptosis. The next breakthrough came in the 1980s when Horvitz and his colleagues identified specific cell death genes (ced) that controlled PCD in the roundworm, Caenorhabditis elegans (C. elegans). Identification of ced genes in the roundworm quickly led to the isolation of their mammalian homologues. Subsequent research in the 1990s led to the identification of a cadre of proteins controlling cell death in mammals, i.e., receptors/ligands, caspases, cytochrome c, Apaf-1, Bcl-2 family proteins, and IAPs. Two major pathways of apoptosis have now been elucidated, the receptor-mediated and the mitochondrial apoptotic pathways. The latter pathway, induced by a wide variety of toxic agents, is activated by the release of cytochrome c from mitochondria. Cytochrome c then facilitates the activation of a caspase cascade involving caspase-9 and -3. Activation of these caspases results in the cleavage of a variety of cellular proteins leading to the orderly demise of the cell. Work from my laboratory in the last 5 years has shown that teratogens, such as hyperthermia, 4-hydroperoxycyclophosphamide, and staurosporine, induce cell death in day 9 mouse embryos by activating the mitochondrial apoptotic pathway, i.e., mitochondrial release of cytochrome c, activation of caspase-9 and -3, inactivation of poly (ADP-ribose) polymerase (PARP), and systematic degradation of DNA. Our work, as well as the work of others, has also shown that different tissues within the early post implantation mammalian embryo are differentially sensitive to the cell death inducing potential of teratogens, from exquisite sensitivity of cells in the developing central nervous system to complete resistance of cells in the developing heart. More importantly, we have shown that the resistance of heart cells is directly related to the failure to activate the mitochondrial apoptotic pathway in these cells. Thus, whether a cell dies in response to a teratogen and therefore contributes to the pathogenesis culminating in birth defects, depends, at least in part, by the cell's ability to regulate the mitochondrial apoptotic pathway. Future research aimed at understanding this regulation should provide insight not only into the mechanism of teratogen-induced cell death but also the role of cell death in the genesis of birth defects.     

Specific association of c-Jun-like immunoreactivity but not c-Jun p39 with normal and induced programmed cell death in the chick embryo

We have examined c-Jun protein expression by immunocytochemistry in normal and pathologically induced cell death by focusing primarily on the developing neuromuscular system of the chick embryo. Several commercially available antibodies against c-Jun were used in combination with the TUNEL technique or propidium iodide staining for detection of cells undergoing programmed cell death (PCD). Among these, a rabbit polyclonal antibody raised against the amino acids 91-105 mapping to the amino terminal domain of mouse c-Jun p39 (c-Jun/sc45) transiently immunostained the cytoplasm of dying spinal cord motoneurons at a time coincident with naturally occurring motoneuron death. Late apoptotic bodies were devoid of c-Jun/sc45 immunoreactivity. A monoclonal antibody directed against a region corresponding to the amino acids 26-175 of c-Jun p39 (c-Jun/mAB) did not specifically immunostain dying neurons, but, rather, showed nuclear immunolabeling in almost all healthy motoneurons. Experimentally induced programmed death of motoneurons by means of early limb bud ablation, axotomy, or in ovo injection of the neurotoxin beta-bungarotoxin increased the number of dying cells showing positive c-Jun/sc45 immunoreactivity. Immunoelectron microscopy with c-Jun/sc45 antibody showed that the signal was present in the cytoplasm without a specific association with organelles, and was also present in large lysosome-like dense bodies inside neuritic profiles. Similar findings were obtained in different types of cells undergoing normal or experimentally induced PCD. These include dorsal root ganglion neurons, Schwann cells, muscle cells, neural tube and neural crest cells during the earliest stages of spinal cord development, and interdigital mesenchymal cells of hindlimbs. In all these cases, cells showed morphological and histochemical characteristics of apoptotic-like PCD. By contrast, motoneurons undergoing necrotic cell death induced by the excitotoxin N-methyl-D-aspartate did not show detectable c-Jun/sc45 immunoreactivity, although they displayed an increase in nuclear c-Jun/mAB immunostaining. In Western blot analysis of spinal cord extracts, c-Jun/sc45 antibody weakly detected a 39-kD band, corresponding to c-Jun, and more strongly detected two additional bands of 66 and 45 kD which followed developmental changes coincident with naturally occurring or experimentally stimulated apoptotic motoneuron death. By contrast, c-Jun/mAB only recognized a single p39 band as expected for c-Jun, and did not display changes associated with neuronal apoptosis. From these data, we conclude that the c-Jun/sc45 antibody recognizes apoptosis-related proteins associated with the early stages of morphological PCD in a variety of neuronal and non-neuronal cells, and that c-Jun/sc45 is a reliable marker for a variety of developing cells undergoing programmed cell death.     

The Loss of the Expression of α Catenin, the 102 kD Cadherin Associated Protein, in Central Nervous Tissues during Development

A monoclonal antibody specific for α catenin, the 102kD cadherin-associated protein, has been characterized and used to describe the expression and distribution pattern of α catenin in adult mice and mouse embryos. This monoclonal antibody recognized an epitope in the middle part of the α catenin molecule of various vertebrate species, and bound to neither vinculin nor αN catenin, which are cytoskeletal proteins with sequence similarity to α catenin. At the early mouse embryo stage (neurulae stage) α catenin was expressed and concentrated at cell-to-cell contact sites together with various types of cadherins in all tissues. In embryos at 12.5 days of gestation, the α catenin expression was gradually diminished selectively in central nervous tissues such as brain and spinal cord, and in most of the adult central nervous tissues the α catenin expression was hardly detected. In adult non-nervous tissues most of the cells examined expressed α catenin. Especially in well-polarized tissues such as epithelial cells, α catenin appeared to be highly concentrated at cell-to-cell adherens junctions where cadherins act as adhesion molecules.
This loss of α catenin expression in central nervous tissues was observed not only in mice but also in other vertebrate species such as fish and newt, suggesting that this phenomenon has important implications from the view point of nervous tissue development.     

RNAi knockdown of Par-4 inhibits neurosynaptic degeneration in ALS-linked mice

Evidence from human amyotrophic lateral sclerosis (ALS) patients and ALS-linked Cu/Zn superoxide dismutase (Cu/Zn-SOD) transgenic mice bearing the mutation of glycine to alanine at position 93 (G93A) suggests that the pro-apoptotic protein prostate apoptosis response-4 (Par-4) might be a critical link in the chain of events leading to motor neuron degeneration. We now report that Par-4 is enriched in synaptosomes and post-synaptic density from the ventral horn of the spinal cord. Levels of Par-4 in synaptic compartments increased significantly during rapid and slow declining stages of muscle strength in hSOD1 G93A mutant mice. In the pre-muscle weakness stage, hSOD1 G93A mutation sensitized synaptosomes from the ventral horn of the spinal cord to increased levels of Par-4 expression following excitotoxic and apoptotic insults. In ventral spinal synaptosomes, Par-4-mediated production of pro-apoptotic cytosolic factor(s) was significantly enhanced by the hSOD1 G93A mutation. RNA interference (RNAi) knockdown of Par-4 inhibited mitochondrial dysfunction and caspase-3 activation induced by G93A mutation in synaptosomes from the ventral horn of the spinal cord, and protected spinal motor neurons from apoptosis. These results identify the synapse as a crucial cellular site for the cell death promoting actions of Par-4 in motor neurons, and suggest that targeted inhibition of Par-4 by RNAi may prove to be a neuroprotective strategy for motor neuron degeneration.     

A Perspective on Neuronal Cell Death Signaling and Neurodegeneration

Although neuronal cell death through apoptotic pathways represents a common feature of dysferopathies, the canonical apoptotic changes familiar from nonneuronal cells are late events. Loss of neuronal function occurs at a much early time, when synaptic-based neuronal connectivity fails. In this context, apoptotic pathways may normally serve a cleanup role, rather than a pathogenic one. Reframing the consideration of cell death in the nervous system to include the early stages of axonal degeneration provides a better understanding of the roles played by various apoptotic signaling pathways in neurodegenerative diseases. Focusing on disease-specific mechanisms that initiate the sequence that eventually leads to neuronal loss should facilitate development of therapies that preserve neuronal function and neuronal numbers.     

Up-regulation of neural stem cell markers suggests the occurrence of dedifferentiation in regenerating spinal cord

Following tail amputation in urodele amphibians, an ependymal tube, that resembles a developing neural tube, forms from ependymal cells that migrate from the cord stump and elongates by cell proliferation. Expression of the keratin pair 8 and 18 has been observed in the developing urodele nervous system and is maintained in the ependymal cells of the mature cord. We show here that expression of these keratins is not unique to urodeles, but is also observed in the radial glia of the human spinal cord, suggesting that these proteins might play a role both in neural development and regeneration. Analysis of their expression in the regenerating spinal cord following tail amputation shows that their expression, as well as that of glial fibrillary acidic protein (GFAP), is maintained in the ependymal tube during regeneration, though differences in their levels of expression are observed along the anteroposterior axis and appear to be related to the progression of morphogenesis. In addition, we show that following tail amputation the ependymal tube expresses the neural stem cell markers nestin and vimentin, which are undetectable in normal urodele spinal cord. This up-regulation of neural stem cell markers shows that the ependymal cells undergo a phenotypic change. Whereas maintenance of keratin and GFAP expression in the adult ependyma may reflect a higher plasticity of these cells in adult urodeles than in other vertebrates, re-expression of markers of early neural development suggests the occurrence of a dedifferentiation process in the spinal cord in response to injury.Edited by J. Campos-Ortega     

Generation of electromotor neurons in Sternarchus albifrons: differences between normally growing and regenerating spinal cord

This study examines the regulation of the number of electromotor neurons during postnatal growth of the spinal cord in the gymnotiform teleost Sternarchus albifrons. It specifically asks whether a large overproduction of electromotor neurons and a wave of cell death, similar to those occurring during spinal cord regeneration in this species, play a role in the on-going growth at the caudal tip of the normal spinal cord. Neurons are produced from ependymal precursors at the caudal end of the spinal cord during both normal growth in the adult and regeneration of the spinal cord in this species. Previous studies have demonstrated that during spinal cord regeneration after amputation of the tail in Sternarchus, there is an initial massive (up to fivefold) overproduction of electromotor neurons, followed by a wave of cell death which reduces the number of these neurons to the normal level. In the present study, transverse sections through the caudalmost spinal segment of normal adult Sternarchus were examined. Proceeding rostrally from the caudal tip of the cord, the number of electromotor neurons increases monotonically to reach the normal number at a site 4-5 mm rostral to the caudal tip. Neither a massive overproduction of electromotor neurons nor a wave of neuronal death are observed during on-going growth of the normal spinal cord. The mechanisms by which the neuronal number is modulated are therefore different in the on-going normal growth of spinal cord versus regeneration of spinal cord in this species.     

Specific association of c‐Jun‐like immunoreactivity but not c‐Jun p39 with normal and induced programmed cell death in the chick embryo

We have examined c‐Jun protein expression by immunocytochemistry in normal and pathologically induced cell death by focusing primarily on the developing neuromuscular system of the chick embryo. Several commercially available antibodies against c‐Jun were used in combination with the TUNEL technique or propidium iodide staining for detection of cells undergoing programmed cell death (PCD). Among these, a rabbit polyclonal antibody raised against the amino acids 91‐105 mapping to the amino terminal domain of mouse c‐Jun p39 (c‐Jun/sc45) transiently immunostained the cytoplasm of dying spinal cord motoneurons at a time coincident with naturally occurring motoneuron death. Late apoptotic bodies were devoid of c‐Jun/sc45 immunoreactivity. A monoclonal antibody directed against a region corresponding to the amino acids 26‐175 of c‐Jun p39 (c‐Jun/mAB) did not specifically immunostain dying neurons, but, rather, showed nuclear immunolabeling in almost all healthy motoneurons. Experimentally induced programmed death of motoneurons by means of early limb bud ablation, axotomy, or in ovo injection of the neurotoxin β‐bungarotoxin increased the number of dying cells showing positive c‐Jun/sc45 immunoreactivity. Immunoelectron microscopy with c‐Jun/sc45 antibody showed that the signal was present in the cytoplasm without a specific association with organelles, and was also present in large lysosome‐like dense bodies inside neuritic profiles. Similar findings were obtained in different types of cells undergoing normal or experimentally induced PCD. These include dorsal root ganglion neurons, Schwann cells, muscle cells, neural tube and neural crest cells during the earliest stages of spinal cord development, and interdigital mesenchymal cells of hindlimbs. In all these cases, cells showed morphological and histochemical characteristics of apoptotic‐like PCD. By contrast, motoneurons undergoing necrotic cell death induced by the excitotoxin N‐methyl‐D ‐aspartate did not show detectable c‐Jun/sc45 immunoreactivity, although they displayed an increase in nuclear c‐Jun/mAB immunostaining. In Western blot analysis of spinal cord extracts, c‐Jun/sc45 antibody weakly detected a 39‐kD band, corresponding to c‐Jun, and more strongly detected two additional bands of 66 and 45 kD which followed developmental changes coincident with naturally occurring or experimentally stimulated apoptotic motoneuron death. By contrast, c‐Jun/mAB only recognized a single p39 band as expected for c‐Jun, and did not display changes associated with neuronal apoptosis. From these data, we conclude that the c‐Jun/sc45 antibody recognizes apoptosis‐related proteins associated with the early stages of morphological PCD in a variety of neuronal and nonneuronal cells, and that c‐Jun/sc45 is a reliable marker for a variety of developing cells undergoing programmed cell death. © 1999 John Wiley & Sons, Inc. J Neurobiol 38: 171–190, 1999