Calpain inhibitors, but not caspase inhibitors, prevent actin proteolysis and DNA fragmentation during apoptosis.

Apoptosis, or programmed cell death, involves a cascade of regulatory events leading to the activation of specific proteases. However, the key substrates for these proteases remain to be identified. We previously demonstrated that levels of five unidentified polypeptides were specifically increased in neurons from embryonic chicken ciliary ganglia undergoing apoptosis by trophic deprivation. Here we show by microsequencing of two of these polypeptides that they are fragments of actin. One of them represents cleavage of actin at the site of interaction with DNase I. The same actin fragments are also found at early stages of apoptosis in chicken and rat dorsal root ganglion neurons, chicken spinal motoneurons and rat thymocytes. Actin fragmentation may play a role in the apoptotic process, since calpain inhibitors I and II both inhibit neuronal death and suppress actin fragmentation. In contrast, caspase (ICE family) inhibitors, though effective in delaying neuronal death, do not prevent actin cleavage or DNA fragmentation. These results indicate a key role for calpain-like proteases in neuronal programmed cell death and suggest that actin fragmentation in the cell is correlated with subsequent DNA fragmentation.

Expression of two neuronal markers, growth-associated protein 43 and neuron-specific enolase, in rat glial cells.

Recent studies have revealed that proteins such as growth-associated protein 43 (GAP-43) and neuron-specific enolase (NSE), believed for many years to be expressed exclusively in neurons, are also present in glial cells under some circumstances. Here we present an overview of these observations. GAP-43 is expressed both in vitro and in vivo transiently in immature rat oligodendroglial cells of the central nervous system, in Schwann cell precursors, and in non-myelin-forming Schwann cells of the peripheral nervous system. GAP-43 mRNA is also present in oligodendroglial cells and Schwann cells, indicating that GAP-43 is synthesized in these cells. GAP-43 is also expressed in type 2 astrocytes (stellate-shaped astrocytes) and in some reactive astrocytes but not in type 1 astrocytes (flat protoplasmic astrocytes). These results suggest that GAP-43 plays a more general role in neural plasticity during development of the central and peripheral nervous systems. NSE enzymatic activity and protein and mRNA have been detected in rat cultured oligodendrocytes at levels comparable to those of cultured neurons. NSE expression increases during the differentiation of oligodendrocyte precursors into oligodendrocytes. In vivo, NSE protein is expressed in differentiating oligodendrocytes and is repressed in fully mature adult cells. The upregulation of NSE in differentiating oligodendrocytes coincides with the formation of large amounts of membrane structures and of protoplasmic processes. Similarly, NSE becomes detectable in glial neoplasms and reactive glial cells at the time when these cells undergo morphological changes. The expression of the glycolytic isozyme NSE in these cells, which do not normally contain it, could reflect a response to higher energy demands. This expression may also be related to the neurotrophic and neuroprotective properties demonstrated for this enolase isoform. NSE activity and protein and mRNA have also been found in cultured rat type 1-like astrocytes but at much lower levels than in neurons and oligodendrocytes. Thus GAP-43 and NSE should be used with caution as neuron-specific markers in studies of normal and pathological neural development.

Trophic action of pharmacological substances with a guanidine group on mouse neuroblastoma cells and chick ganglionic neurons in culture.

A series of substances (designated CTQ compounds) with a guanidine group have been synthesized and tested for their ability to promote neuronal survival and neurite outgrowth. Mouse neuroblastoma clonal cell lines grown in serum-containing medium for 10 days as well as primary cultures of embryonic chicken ganglion neurons grown in serum-free defined medium for 1 or 2 days have been used for the experiments. Among the various CTQ compounds (CTQ1-CTQ20) tested, only CTQ8 exerted positive neurotrophic effects on these peripheral neuronal cells. At a concentration of 10(-4) M, CTQ8 enhanced neuritogenesis of neuroblastoma cells. However, the most striking influence of CTQ8 was its promoting effect (6- to 10-fold) on the survival of chicken ciliary and dorsal root ganglionic neurons at concentrations ranging from 10(-3) M to 5 x 10(-4) M.

A comparative study of the distribution of alpha- and gamma-enolase subunits in cultured rat neural cells and fibroblasts.

We report the presence and distribution of alpha (ubiquitous) and gamma (neuron-specific) subunits of the dimeric glycolytic enzyme enolase (2-phospho-D-glycerate hydrolase) in cultured neural cells. The gamma gamma enolase is found in vivo at high levels only in neurons and neuroendocrine cells. Neuronal cells in culture also contain relatively high levels of alpha gamma and gamma gamma enolase. Here we show, by enzymatic and immunological techniques, that the gamma subunit also is expressed in cultured rat astrocytes and meningeal fibroblasts and, as we previously reported, in oligodendrocytes. Both neuron-specific isoforms alpha gamma and gamma gamma are expressed in all these cells, but the alpha alpha isoform accounts for the major part of total enolase activity. The sum of alpha gamma and gamma gamma enolase activities increases with time in culture. i.e. maturation processes, reaching the highest level in oligodendrocytes (40% of total enolase activity) and 15 and 10% of total enzymatic activity in astrocytes and fibroblasts, respectively. The gamma enolase transcripts were found not only in cultured neuronal cells but also in cultured oligodendrocytes astrocytes, and meningeal fibroblasts. Our data indicate that neuron-specific enolase should be used with caution as a specific marker for neuronal cell differentiation.

Basic fibroblast growth factor (bFGF) injection activates the glial reaction in the injured adult rat brain.

Reactive gliosis is a reaction of glial cells to trauma which is characterized by a phenotypic modification of astrocytes, as well as by a proliferation and a migration of some of these cells to form a glial scar. This scar is currently considered as a physical impediment to neuronal regrowth but it may also be involved in wound healing since the astrocytes beside microglia play a phagocytic role in the clearance of post-traumatic debris. Growth factors are released in the area of the injury and at least some of them could be involved in gliosis. In order to test directly this possibility, we have injected one of them, the basic fibroblast growth factor (bFGF), into several brain areas (cortex, striatum, hippocampus or corpus callosum) of adult 2-month-old rats in the absence of lesion. A glial reaction was observed after 3 days and was maximum after 7 days. It was characterized by an increase in astrocyte proliferation and in glial fibrillary acidic protein (GFAP) expression, resulting in a higher number of GFAP-positive cells per surface unit, and by an increase in the size and branching of the astroglial processes. The GFAP mRNA levels were also strongly increased following the bFGF injection. These effects resemble the reactive gliosis observed after lesion and suggest that bFGF is actually involved in the triggering of glial reactions which follow brain injury. In further experiments, bFGF was injected in the site of electrolytic lesions made in the same various parts of the brain. These injections did not increase significantly the normal reactive gliosis induced by the lesion alone, but it accelerated some of the effects. It also resulted in a higher labeling index and GFAP mRNA levels were strongly enhanced after a 3-day-post-operative delay. This last observation strengthens the idea that one of the main factors driving the astrogliosis is the bFGF normally released in and around the site of the lesion.

Expression of the neuron-specific enolase gene by rat oligodendroglial cells during their differentiation.

We have examined the regulation of neuron-specific gamma-enolase gene (NSE) expression in oligodendrocytes at various steps of their differentiation/maturation. We have demonstrated for the first time that NSE is expressed in oligodendroglial cells in vitro and in vivo, and only at a certain stage of differentiation. A heterogeneity of the gamma subunit was observed in cultured oligodendrocytes and the same one was found in adult rat brain. The level of gamma mRNA increased when precursor cells differentiated into oligodendrocytes. By contrast, no significant change in alpha-enolase gene expression was observed. High NSE (gamma gamma and alpha gamma) enolase activity was detected in cultured oligodendrocytes. Treatment with basic fibroblast growth factor, which stimulates the proliferation of oligodendrocyte precursor cells and reversibly blocks their differentiation, resulted in lower alpha gamma- and gamma gamma-enolase activities in these cells, but it enhanced alpha alpha-enolase activity slightly. These data indicate that gamma-enolase gene expression is associated with the differentiation of the oligodendrocytes and that it is repressed in adult fully mature cells.

Influence of basic fibroblast growth factor and astroglial cells on the ultrastructure of developing rat brain neuronal precursors in vitro.

We have examined the ultrastructural aspect of neuronal precursors derived from 14-day-old rat embryos during their development under various culture conditions. Cells maintained in serum-free medium which have developed for 1 week in vitro present ultrastructural features of young neurons. They contain many free ribosomes and microtubules, but few other organelles and incompletely developed Golgi apparatus. In the presence of basic fibroblast growth factor (bFGF), besides cells remaining in aggregates and displaying morphological features of undifferentiated cells, dispersed neuroblasts underwent accelerated ultrastructural maturation. They present well-developed Golgi apparatus, axodendritic synapses and dense-core vesicles already after 3 days in culture. By contrast, in the presence of astroglial-conditioned medium a more homogeneous population developed showing ultrastructural features of relatively mature neurons. However, the neuronal precursors acquired the most mature ultrastructural aspect when they were cocultured with astroglial cells. The neuronal cell bodies contain highly developed Golgi complexes, well-differentiated ergastoplasm and Niss1 body formations, while in the complex neurite network much more numerous mature synapses with clear and dense-core vesicles are visible. These observations indicate that a combination of soluble factors and membrane-bound factors is essential for extensive ultrastructural development of neuronal precursors in vitro. Another finding was that in these cultured neurons neurofilaments (NF) were never seen, while NF protein subunits were found. These data suggest that the polymerization of the three NF subunits into intermediate filaments might need particular cellular factors which probably do not exist under our in vitro conditions.

Synthesis of specific proteins in trophic factor-deprived neurons undergoing apoptosis.

Apoptosis, also known as programmed cell death, is a mechanism used by different tissues to regulate their cell content. In the nervous system, this process is supposed to adjust the final number of neurons to the number of the target cells they are innervating. The demonstration that, in several systems in vitro and in vivo, neuronal apoptosis can be prevented by inhibiting RNA or protein synthesis suggests that an activation of gene expression is required in the cells that are going to die. The genes involved and their products, named "killer proteins," are not known in the superior vertebrates. In order to identify such proteins, we have used and characterized an in vitro model consisting of neurons derived from 8-day-old embryonic chicken ciliary ganglia. RNA and protein synthesis inhibitors can prevent the death of these neurons when they are deprived of trophic support. Comparing the synthesis of proteins in trophic-supported neurons with that in trophic-deprived neurons by the use of two-dimensional polyacrylamide gel electrophoresis, we have observed that several proteins were overexpressed reproducibly in the apoptotic cells. We found that all these proteins are localized in the nucleus, suggesting that they may be transcription regulators.

Proliferation of neuronal precursor cells from the central nervous system in culture.

Studies over the past ten years have revealed that neuronal precursors from the central nervous system of chick, rat and mouse embryos are able to divide in culture and that their proliferation is enhanced by several nervous tissue extracts as well as by growth factors, hormones and various other molecules. In this article we present an overview of this subject. It has been found that neuronal precursors from chick embryo cerebral hemispheres proliferate in culture during the first week and that those from 6 day-old chick embryos possess the highest proliferative activity. Neuronal precursors from fetal rat cerebral cortex and spinal cord can also proliferate in vitro. The highest proliferative activity was observed between 24 and 48 h. Brain and meningeal extracts have been shown to stimulate the proliferation of chick neuroblasts. Moreover, RNAs, purine nucleotides, purine bases and transferrin present in these extracts are able to reinduce the proliferation of these cells. Other investigations have indicated that several hormones and growth factors stimulate the proliferation of rat and mouse neuronal precursors. Acidic and basic fibroblast growth factors are potent mitogens for these cells. Nerve growth factor, epidermal growth factor and insulin-like growth factor also affect the growth of the neuroblasts. The reported in vitro observations are discussed in relation to the physiological role of these molecules during neuronal proliferation in brain development.

Expression of neuromodulin (GAP-43) and its regulation by basic fibroblast growth factor during the differentiation of O-2A progenitor cells.

In a recent work we have shown that neuromodulin (Nm, also known as GAP-43), a protein kinase C substrate, previously believed to be expressed exclusively in neurons, is also present in glial cells. Here we investigated the expression of Nm and its mRNA in O-2A glial progenitor cells (common precursor for oligodendrocytes and type-2 astrocytes) during their development in secondary culture and under the influence of basic fibroblast growth factor (bFGF). The different stages of oligodendrocyte development were characterized by the expression of surface markers: A2B5, which identifies O-2A glial precursor cells, and O4 and galactocerebroside (GC), which characterize later developmental stages. The number of cells expressing Nm (about 90% at culture initiation) decreased rapidly during the first 2 days and reached a plateau at around 30-40%. The level of Nm mRNA followed a similar kinetic. Immunocytochemistry demonstrated that at 4 days in vitro about 25-30% cells were A2B5+, 30-40% Nm+, a high percentage (60-70%) O4+, and 35-40% GC+. Nearly all of the morphologically immature A2B5+ cells expressed also the Nm antigen, very few of the O4+ cells still expressed Nm and almost no cells expressed both GC and Nm. Most O4+ cells developed a typical oligodendrocyte morphology and were essentially GC+. This study also showed that in the presence of serum, the A2B5+ Nm+ and O4+ Nm+ (GC-) cells retained their bipotentiality and differentiated into GFAP+ (glial fibrillary acidic protein) Nm+ type-2 astrocytes. The bFGF was found to stimulate the proliferation of Nm+ 0-2A precursor cells and to increase the level of Nm mRNA. At 4 days under this culture condition, the predominant cell type was A2B5+ and Nm+. Only 25-35% of the cells were O4+, but 90-95% of them were Nm+. Very few GC+ cells were visible in the presence of bFGF, but 20-40% of them were Nm+. These data indicate that Nm is essentially associated to glial O-2A precursor cells and further confirm that bFGF blocks the differentiation of these cells. It is suggested that Nm plays a role in the plasticity (developmental potential) of the bipotential 0-2A progenitor cells.

Autoradiographic studies of rat astroglial cell proliferation in vitro with and without treatment with basic fibroblast growth factor.

Using specific autoradiographic methods, cell cycle parameters of untreated and basic fibroblast growth factor (bFGF)-treated astroglial cells from newborn rats grown in primary culture were directly measured. The mode of proliferation was also analysed. In untreated cultures, S phase duration (Ts = 6.9-13.1 h) and cell cycle time (Tc = 10-18 h) can be modified by about a factor of 2 depending on the culture conditions (serum-supplemented or defined medium, thyroid hormone concentration). However, growth fraction (GF = 0.15) and the ratio Ts/Tc remain stable. With increasing days in vitro (DIV) (DIV 7-DIV 20), Ts (7.8-10.6 h) and Tc (10-21 h) are prolonged and GF (0.14-0.06) decreases, probably due to cell maturation. In general, astroglial cells proliferate exponentially with a GF < 1, but stop proliferating about 30-36 h after the last feeding, probably caused by exhaustion of the medium. However, after refeeding they continue to proliferate. As opposed to in vivo, no transition of non-proliferating cells into the GF occurs. After addition of bFGF, GF increases (e.g. GF at DIV 7 = 0.43), but Ts and Tc are not influenced at DIV 7 and 12. At DIV 20, bFGF additionally shortens Ts and Tc, thereby producing values of Ts, Tc and GF like 'younger' cultures. However, the revitalizing effect on 'mature' cells is only transitory. In general, bFGF leads to a single re-entry of G0 cells into the GF. Thereafter, bFGF does not affect the mode of proliferation.

Mitogenic growth factors regulate differentially early gene mRNA expression: a study on two clones of 3T3 fibroblasts.

The relationship between cell proliferation and mRNA levels of the immediate early genes c-fos, c-jun, and jun B has been investigated in two clones of 3T3 fibroblasts (D1-3T3 and N2-3T3) upon treatment with basic fibroblast growth factor (bFGF), thrombin, phorbol 12-myristate 13-acetate (PMA) and dibutyryl cyclic AMP (Bt2cAMP). The 3T3-derived clone D1-3T3 almost stops dividing upon serum deprivation, while the N2-3T3 clone does not. The proliferation of the two clones was stimulated by thrombin and PMA and inhibited by Bt2cAMP. Basic FGF stimulated the growth of D1-3T3 but partly inhibited that of N2-3T3 cells. In spite of variable mitogenic response, immediate early genes, c-fos, c-jun, jun B, and c-myc, were induced by the growth factors and by PMA in both cell clones. In our experimental conditions the early gene mRNAs were expressed independently; i.e., the expression of one protooncogene had no bearing on the expression of the other. The cell growth was not directly related to the expression of a particular protooncogene mRNA. Data are presented showing that early gene mRNA expression induced by bFGF or thrombin was not mediated by protein kinase C activation while thrombin-induced mitosis was. Basic FGF induced a part of c-jun mRNA expression, but not mitosis, through a pertussis toxin-sensitive mechanism.

Phosphorylation of the MARCKS protein (P87), a major protein kinase C substrate, is not an obligatory step in the mitogenic signaling pathway of basic fibroblast growth factor in rat oligodendrocytes.

Basic fibroblast growth factor (bFGF) is a well-characterized peptide hormone that has mitogenic activity for various cell types and elicits a characteristic set of responses on the cell types investigated. In this report we confirmed that bFGF is a potent mitogen for rat brain-derived oligodendrocyte (OL) precursor cells as well as for differentiated OL in secondary culture. bFGF was shown to induce expression of the protooncogene c-fos in OL. The role of protein kinase C (PKC) in mediating bFGF-stimulated proliferation as well as c-fos expression in OL was investigated. The PKC activator phorbol 12-myristate 13-acetate (PMA) stimulated c-fos expression but did not trigger cell proliferation. When PKC was down-regulated by pretreatment of OL with PMA for 20 h, the bFGF-mediated stimulations of OL proliferation and c-fos mRNA expression were still observed, whereas the induction of c-fos mRNA by PMA was totally inhibited. These data demonstrate that the bFGF mitogenic signaling pathway in OLs does not require PKC. On the other hand, bFGF was found to stimulate specifically the phosphorylation of a limited number of PKC substrates in oligodendroglial cells, including the MARCKS protein. The bFGF-dependent phosphorylation of MARCKS protein was totally inhibited when PKC was first down-regulated, indicating that the phosphorylation of this protein is PKC dependent. Tryptic digestion of the phosphorylated MARCKS protein revealed that bFGF stimulated specifically the phosphorylation of the MARCKS protein on a single phosphopeptide. We provide evidence that bFGF also stimulated fatty acylation of the MARCKS protein, which might explain the observed specific bFGF-dependent phosphorylation of this protein in OL. We propose that bFGF-dependent fatty acylation and phosphorylation of the MARCKS protein are not essential for the transduction of the bFGF mitogenic signal but are probably linked to differentiation processes elicited by bFGF on OL.

Influence of basic fibroblast growth factor on the development of cholinoceptive neurons from fetal rat cerebrum in culture.

Neuronal cells from cerebral hemispheres of 14-day-old rats were grown for 6 days in a serum-free, chemically defined medium. About 95-98 and 3% of these cells were neurofilament and acetylcholinesterase (AChE)-positive, respectively. The addition of basic fibroblast growth factor (bFGF) at three developmental stages, i.e. at 4 h, 2 and 4 days resulted in an increase (about 2-fold) of the number of AChE-positive neurons. The enzyme reaction was present in the cell body as well as in the fibers, which often ramified extensively under the influence of bFGF. Treatment with bFGF after the 2nd day of culture had no or only a low stimulatory effect. Our findings indicate that bFGF affects the development of AChE-containing neurons, i.e. cholinoceptive neurons from rat cerebrum.

Characterization of astroglial cell proliferation in vitro and in vivo.

On the basis of experimental set-ups in vitro and in vivo and by making use of specific autoradiographical techniques, the following data on the proliferation of astrocytes from newborn rats in vitro and unpretreated rats and mice in vivo could be obtained: (i) The commonly employed immunohistochemical staining techniques in vitro are not applicable in tissue sections. (ii) In vivo, astrocytes show increasing durations of cell cycle (tc) as well as S phase (ts) prenatally until about birth. A similar trend can be observed in vitro. However, the absolute values for ts and tc can be substantially modified depending on the culture conditions. (iii) As regards the mode of proliferation, astrocytes in vitro grow exponentially and without transition of quiescent cells from the non-growth fraction into the growth fraction (GF). In contrast, astrocytes in vivo exhibit steady-state growth and continuous recruitment of proliferating cells from the non-GF. These differences show that there is a need for further in vivo-experiments when studying new strategies in the treatment of gliomas.

Establishment of pure neuronal cultures from fetal rat spinal cord and proliferation of the neuronal precursor cells in the presence of fibroblast growth factor.

A primary culture system of nearly pure neuronal cells from 14-day-old fetal rat spinal cord has been developed by combining a preplating step, the use of a chemically defined serum-free medium, and borated polylysine-coated dishes that prevented the formation of cell aggregates. About 98% of the cells were found to be immunostained with neuron-specific enolase antibodies, confirming their neuronal nature. The cultures are composed essentially of a population of non-motoneurons and contain few motoneurons, characterized by their large size and multipolar aspect, the presence of acetylcholinesterase (AChE), and the intense immunoreaction for growth-associated protein GAP-43. Neuronal precursor cells are also present in these cultures and proliferate during the first 3 days. The addition of bovine brain basic fibroblast growth factor (bFGF) stimulates their proliferation over a period of 2 days, as determined by measurement of [125I]iododeoxyuridine incorporation and by immunocytochemical reaction after bromodeoxyuridine incorporation into nuclei. The proliferating cells were characterized as neurons by immunostaining against neuron-specific enolase. Recombinant human bFGF and bovine brain acidic FGF (aFGF) exerted similar effects. Other growth factors, including epidermal growth factor (EGF), transforming growth factor beta 1 (TGF-beta 1), and thrombin, were without effect on the proliferative activity of these neuronal cells. bFGF has no effect on the survival of motoneurons and on the fiber outgrowth of the whole neuronal population. However, bFGF affects the development of bipolar AChE-positive neurons, probably belonging to the non-motoneuron population. The data indicate that bFGF and aFGF are mitogens for neuroblasts from rat spinal cord in culture and that bFGF influences the development of a subpopulation of spinal neurons that are AChE-positive.

A rapid purification method for neurogranin, a brain specific calmodulin-binding protein kinase C substrate.

A rapid purification method is reported for bovine brain neurogranin, a calmodulin-binding protein kinase C (PKC) substrate. This method takes advantage of the fact that the protein remains soluble in 2.5% perchloric acid (PCA) and that it binds to a calmodulin-Sepharose column in the absence of calcium: Other PKC substrate proteins that remain to be identified were also found to share these two properties, suggesting that a class of calmodulin-binding PKC substrates may exist in the brain.

Proliferation of chick embryo neuroblasts grown in the presence of horse serum requires exogenous transferrin.

We have previously shown that neuroblasts from cerebral hemispheres of 6-day-old chick embryos are able to proliferate when grown in the presence of fetal calf serum. We report here that in the presence of horse serum alone the proliferative rate of neuroblasts is strongly reduced. A high proliferative rate is restored upon the addition of bovine transferrin and to a lesser extent with added FeSO4 or hemin. These findings suggest that the transferrin of horse serum cannot be used by chick neuroblasts in vitro, while bovine transferrin exogenously added is active in promoting cell proliferation. We propose that the stimulatory activity of the fetal calf serum is due to bovine transferrin, since when this serum is fractionated by gel filtration, the fractions that stimulate the proliferation of neuroblasts grown in the presence of horse serum are located in the molecular weight area of transferrin, and they do contain transferrin as seen by immunoblotting with a specific anti-transferrin antibody.

Biologically active basic fibroblast growth factor migrates at 27 kD in "non-denaturing" SDS-polyacrylamide gel electrophoresis.

Using mild conditions of SDS-PAGE, i.e. no heating of the sample, and the PhastSystem (Pharmacia), we found that bFGF, either natural bovine or recombinant human migrated at a 27 kD position in addition to the classical 18 kD one. By the cell-blot technique, we found that the biological activity toward rat astroblasts and 3T3 mouse fibroblasts was always restricted to the 27 kD band. Partial heat denaturation experiments revealed a close correlation between the remaining biological activity of bFGF in solution and the ratio of the 27 kD band versus the 18 kD band seen on SDS gels. These observations suggest that the bFGF which is biologically active in solution migrates at an apparent Mr of 27 kD in our conditions of electrophoresis, keeping its biological activity after electrophoresis, and the molecules which are inactive (denatured) in solution migrate at 18 kD and remain inactive. These experimental conditions, in which the biological activity appears to be preserved, could be referred to as "non-denaturing SDS-polyacrylamide gel electrophoresis" and could be useful, associated to cell-blot, for the search and characterization of new growth factors active on cells in culture.