Nerve growth factor and neuronal cell death

The regulation of neuronal cell death by the neuronotrophic factor, nerve growth factor (NGF), has been described during neural development and following injury to the nervous system. Also, reduced NGF activity has been reported for the aged NGF-responsive neurons of the sympathetic nervous system and cholinergic regions of the central nervous system (CNS) in aged rodents and man. Although there is some knowledge of the molecular structure of the NGF and its receptor, less is known as to the mechanism of action of NGF. Here, a possible role for NGF in the regulation of oxidant--antioxidant balance is discussed as part of a molecular explanation for the known effects of NGF on neuronal survival during development, after injury, and in the aged CNS.     

Nerve growth factor has both mitogenic and antimitogenic activity

The present study demonstrates that nerve growth factor (NGF) possesses both antimitogenic and mitogenic activities. To this end, we have employed clonal PC12 rat pheochromocytoma cells and two PC12 variant sublines, U2 and U7. When PC12 cells are exposed to NGF in culture media that are otherwise either permissive (15% serum) or restrictive (1% serum) for proliferation, neuronal differentiation occurs and mitosis ceases. Variant lines of PC12 cells have been selected that continue to proliferate in the presence of NGF in permissive medium but which nevertheless retain NGF receptors and certain NGF responses. In contrast to the parent PC12 cells, when such variants were exposed to NGF in growth-restrictive media, cell proliferation was markedly stimulated. The mitogenic activity of NGF was detectable at 0.1 ng/ml (4 pM) and was maximal at 3 ng/ml (100 pM). Possible contamination of the NGF preparation by epidermal growth factor (EGF) or mitogenic proteolytic enzymes was ruled out by the use of anti-EGF and diisopropylfluoro-phosphate, respectively. These findings show that NGF shares the capacity to stimulate cell division with a variety of other peptide hormones and suggest that the mitogenic activity of NGF could play a role in development of the peripheral nervous system as well as in promotion of in vivo growth of certain neural crest-derived neoplasms.     

Expression of a mitochondrial peroxiredoxin prevents programmed cell death in Leishmania donovani

Leishmania promastigote cells transmitted by the insect vector get phagocytosed by macrophages and convert into the amastigote form. During development and transformation, the parasites are exposed to various concentrations of reactive oxygen species, which can induce programmed cell death (PCD). We show that a mitochondrial peroxiredoxin (LdmPrx) protects Leishmania donovani from PCD. Whereas this peroxiredoxin is restricted to the kinetoplast area in promastigotes, it covers the entire mitochondrion in amastigotes, accompanied by dramatically increased expression. A similar change in the expression pattern was observed during the growth of Leishmania from the early to the late logarithmic phase. Recombinant LdmPrx shows typical peroxiredoxin-like enzyme activity. It is able to detoxify organic and inorganic peroxides and prevents DNA from hydroxyl radical-induced damage. Most notably, Leishmania parasites overexpressing this peroxiredoxin are protected from hydrogen peroxide-induced PCD. This protection is also seen in promastigotes grown to the late logarithmic phase, also characterized by high expression of this peroxiredoxin. Apparently, the physiological role of this peroxiredoxin is stabilization of the mitochondrial membrane potential and, as a consequence, inhibition of PCD through removal of peroxides.     

Mechanisms of non-apoptotic programmed cell death in diabetes and heart failure

Programmed cell elimination is an important pathological mediator of disease. Multiple pathways to programmed cell death have been delineated, including apoptosis, autophagy and programmed necrosis. Cross-talk between the signaling pathways mediating each process has made it difficult to define specific mechanisms of in vivo programmed cell death. For this reason, many “apoptotic” diseases may involve other death signaling pathways. Recent advances in genetic complementation using mouse knockout models are helping to dissect apoptotic and necrotic cell death in different pathological states. The current state of research in this area is reviewed, focusing upon new findings describing the role of programmed necrosis induced by the mitochondrial permeability transition in mouse models of heart failure and diabetes.Key words: apoptosis, necrosis, mitochondrial permeability transition pore     

Mechanisms of insulin-like growth factor regulation of programmed cell death of developing avian motoneurons

During development of the avian neuromuscular system, lumbar spinal motoneurons (MNs) innervate their muscle targets in the hindlimb coincident with the onset and progression of MN programmed cell death (PCD). Paralysis (activity blockade) of embryos during this period rescues large numbers of MNs from PCD. Because activity blockade also results in enhanced axonal branching and increased numbers of neuromuscular synapses, it has been postulated that following activity blockade, increased numbers of MNs can gain access to muscle-derived trophic agents that prevent PCD. An assumption of the access hypothesis of MN PCD is the presence of an activity-dependent, muscle-derived sprouting or branching agent. Several previous studies of sprouting in the rodent neuromuscular system indicate that insulin-like growth factors (IGFs) are candidates for such a sprouting factor. Accordingly, in the present study we have begun to test whether the IGFs may play a similar role in the developing avian neuromuscular system. Evidence in support of this idea includes the following: (a) IGFs promote MN survival in vivo but not in vitro; (b) neutralizing antibodies against IGFs reduce MN survival in vivo; (c) both in vitro and in vivo, IGFs increase neurite growth, branching, and synapse formation; (d) activity blockade increases the expression of IGF-1 and IGF-2 mRNA in skeletal muscles in vivo; (e) in vivo treatment of paralyzed embryos with IGF binding proteins (IGF-BPs) that interfere with the actions of endogenous IGFs reduce MN survival, axon branching, and synapse formation; (f) treatment of control embryos in vivo with IGF-BPs also reduces synapse formation; and (g) treatment with IGF-1 prior to the major period of cell death (i.e., on embryonic day 6) increases subsequent synapse formation and MN survival and potentiates the survival-promoting actions of brain-derived neurotrophic factor (BDNF) and glial cell-line-derived neurotrophic factor (GDNF) administered during the subsequent 4- to 5-day period of PCD. Collectively, these data provide new evidence consistent with the role of the IGFs as activity-dependent, muscle-derived agents that play a role in regulating MN survival in the avian embryo. © 1998 John Wiley & Sons, Inc. J Neurobiol 36: 379–394, 1998     

Vascular endothelial growth factor inhibits programmed cell death of endothelial cells induced by clinorotation

The principal aim of this study was to investigate short- and long-term effects of clinorotation on human endothelial cells (EA hy 926 cell line) using a three-dimensional random positioning machine. Moreover, the impact of vascular endothelial growth factor (VEGF) was addressed. Immediately, within one hour and after four and twenty-four hours an increase of apoptotic cells was detected. VEGF significantly inhibited the amount of apoptotic endothelial cells (EC). VEGF reduced the amount of fas-positive EC. Moreover, after 24 hours, proliferating EC grew in form of three-dimensional multicellular spheroids and also as monolayers. The initially formed spheroids (maximum diameter 3 mm) remained stable up to the 15th day of clinorotation. Some spheroids revealed tubular structures. In addition, a clear increase of extracellular matrix proteins such as osteopontin and fibronectin was measured. The three-dimensional clinostat represents an important tool for cell biological experiments. VEGF significantly attenuated the changes of endothelial cells induced by simulated weightlessness in a cell protective manner.     

Antibody against single-stranded DNA detects both programmed cell death and drug-induced apoptosis

Cyclophosphamide induced fragmented nuclei in mouse thymic epithelial cells. Agarose gel electrophoresis showed the fragmentation of the DNA extracted from mouse thymus exposed to cyclophosphamide. The cell death induced by cyclophosphamide was considered to be apoptotic. Polyclonal antibody against single-stranded DNA was used immunohistochemically to detect apoptotic cell death in thymic epithelial cells. This antibody also detected programmed cell death in the interdigital necrotic zone of the mouse limb plate on day 14 of gestation, and in the ganglion of the trigeminal nerve on day 13 of gestation. These results show that the antibody specific for single-stranded DNA detected both drug-induced apoptosis and programmed cell death during embryogenesis.     

The 19-kilodalton adenovirus E1B transforming protein inhibits programmed cell death and prevents cytolysis by tumor necrosis factor alpha.

The adenovirus E1A and E1B proteins are required for transformation of primary rodent cells. When expressed in the absence of the 19,000-dalton (19K) E1B protein, however, the E1A proteins are acutely cytotoxic and induce host cell chromosomal DNA fragmentation and cytolysis, analogous to cells undergoing programmed cell death (apoptosis). E1A alone can efficiently initiate the formation of foci which subsequently undergo abortive transformation whereby stimulation of cell growth is counteracted by continual cell death. Cell lines with an immortalized growth potential eventually arise with low frequency. Coexpression of the E1B 19K protein with E1A is sufficient to overcome abortive transformation to produce high-frequency transformation. Like E1A, the tumoricidal cytokine tumor necrosis factor alpha (TNF-alpha) evokes a programmed cell death response in many tumor cell lines by inducing DNA fragmentation and cytolysis. Expression of the E1B 19K protein by viral infection, by transient expression, or in transformed cells completely and specifically blocks this TNF-alpha-induced DNA fragmentation and cell death. Cosegregation of 19K protein transforming activity with protection from TNF-alpha-mediated cytolysis demonstrates that both activities are likely the consequence of the same function of the protein. Therefore, we propose that by suppressing an intrinsic cell death mechanism activated by TNF-alpha or E1A, the E1B 19K protein enhances the transforming activity of E1A and enables adenovirus to evade TNF-alpha-dependent immune surveillance.     

Skin-derived nerve growth factor blocks programmed cell death in the trigeminal ganglia but does not enhance neuron proliferation.

Development of the cutaneous sensory nervous system is dependent on the production of neurotrophic factors, such as nerve growth factor (NGF), by the skin. Limited synthesis of NGF in developing skin is thought to underlie programmed cell death and cause a 50% neuronal loss. This loss does not occur in transgenic mice that overexpress NGF in the skin, which have double the number of neurons (J. Neurosci. 14 (1994) 1422). To determine whether increased NGF blocks neuronal death and/or increases neuronal precursor replication, we analyzed the trigeminal ganglia at embryonic days E12.5, E14.5 and E16.5 using transferase-mediated dUTP nick-end labeling (TUNEL) and bromodeoxyuridine labeling. Results show that excess target-derived NGF causes a major decrease in the percent of TUNEL-labeled neurons without affecting the percent of replicating neurons. Analysis of RNA and protein expression suggests this block in cell death is mediated via the anti-apoptotic protein bcl-2.     

Chlamydia and programmed cell death

Discordant views regarding host cell death induction by Chlamydia are likely owing to the different methods used for evaluation of apoptosis. Apoptotic and non-apoptotic death owing to both caspase-dependent and -independent activation of the Bax protein occur late in the productive growth cycle. Evidence also suggests that Chlamydia inhibits apoptosis during productive growth as part of its intracellular survival strategy. This is in part owing to proteolytic degradation of the BH3-only family of pro-apoptotic proteins in the mitochondrial pathway. Chlamydia also inhibits apoptosis during persistent growth or in phagocytes, but induces apoptosis in T cells, which suggests that apoptosis has an immunomodulatory role in chlamydial infections. The contribution of apoptosis in disease pathogenesis remains a focus for future research.     

The IGF axis and programmed cell death.

Insulin-like growth factors (IGF) are mitogenic peptides that have been implicated as positive regulators of cellular proliferation. In recent years, several studies have suggested an additional role for the IGF axis in the regulation of apoptosis. Signalling through the IGF receptor has been shown to have a potent survival function and protect cells from a variety of apoptotic stimuli. The actions of IGF are regulated by a family of high-affinity IGF binding proteins (IGFBP), which sequester the IGF from the IGF receptor. However, there is some evidence that one of these binding proteins, IGFBP-3, may have its own pro-apoptotic effects that are independent of its ability to modulate IGF bioavailability. In addition, it has been suggested that the tumour suppressor p53, a crucial mediator of apoptosis in response to cellular stress, may elicit several of its apoptotic effects through manipulation of components of the IGF axis. This review summarizes what is currently known about the role of the IGF system in the regulation of apoptosis, highlighting its implications in the context of tumorigenesis.     

Cancer and programmed cell death

A report on the 15th Lorne Cancer Conference, Lorne, Australia, 13-16 February 2003.     

Bcl-xL prevents cell death following growth factor withdrawal by facilitating mitochondrial ATP/ADP exchange

Growth factor withdrawal is associated with a metabolic arrest that can result in apoptosis. Cell death is preceded by loss of outer mitochondrial membrane integrity and cytochrome c release. These mitochondrial events appear to follow a relative increase in mitochondrial membrane potential. This change in membrane potential results from the failure of the adenine nucleotide translocator (ANT)/voltage-dependent anion channel (VDAC) complex to maintain ATP/ADP exchange. Bcl-xL expression allows growth factor-deprived cells to maintain sufficient mitochondrial ATP/ADP exchange to sustain coupled respiration. These data demonstrate that mitochondrial adenylate transport is under active regulation. Efficient exchange of ADP for ATP is promoted by Bcl-xL expression permitting oxidative phosphorylation to be regulated by cellular ATP/ADP levels and allowing mitochondria to adapt to changes in metabolic demand.     

Autoreactive blood cells and programmed cell death in growth and development of protochordates

The tunicate Botryllus is a marine protochordate whose clonal colonies undergo regulated natural transplantations when they come into contact in nature. The outcome of these transplantations (fusion or rejection) is controlled by genes of a highly polymorphic histocompatibility system that resembles in many respects the mammalian major histocompatibility complex (MHC). While fusion or rejection reactions are often completed within 24 hr after transplantation, resorption of one partner of a pair of fused semiallogeneic colonies may occur days to weeks after initial contact. The latter process is similar to the degeneration of old individuals, or zooids, that precedes maturation of each new generation of asexual buds. Here we describe comparisons of in vitro reactions of a) mixtures of cells from allogeneic animals and b) cells taken from animals at the zooid-resorption ("takeover") stage of colony development. In vitro autoreactivity of cells from resorbing colonies may reflect in vivo responses to senescent cells, which in turn may be related to allorecognition events that govern fusion or rejection between colonies.     

CEP-1347/KT7515 prevents motor neuronal programmed cell death and injury-induced dedifferentiation in vivo

CEP-1347, also known as KT7515, a derivative of a natural product indolocarbazole, inhibited motor neuronal death in vitro, inhibited activation of the stress-activated kinase JNK1 (c-jun NH terminal kinase) in cultured spinal motor neurons, but had no effect on the mitogen-activated protein kinase ERK1 in these cells. Results reported here profile the functional activity of CEP-1347/KT7515 in vivo in models of motor neuronal death or dedifferentiation. Application of CEP-1347/KT7515 to the chorioallantoic membrane of embryonic chicks rescued 40% of the lumbar motor neurons that normally die during the developmental period assessed. Peripheral administration of low doses (0.5 and 1 mg/kg daily) of CEP-1347/KT7515 reduced death of motor neurons of the spinal nucleus of the bulbocavernosus in postnatal female rats, with efficacy comparable to testosterone. Strikingly, daily administration of CEP-1347/KT7515 during the 4-day postnatal window of motor neuronal death resulted in persistent long-term motor neuronal survival in adult animals that received no additional CEP-1347/KT7515. In a model of adult motor neuronal dedifferentiation following axotomy, local application of CEP-1347/KT7515 to the transected hypoglossal nerve substantially reduced the loss of choline acetyl transferase immunoreactivity observed 7 days postaxotomy compared to untreated animals. Results from these experiments demonstrate that a small organic molecule that inhibits a signaling pathway associated with stress and injury also reduces neuronal death and degeneration in vivo. © 1998 John Wiley & Sons, Inc. J Neurobiol 35: 361–370, 1998