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Neurodegeneration and Pore
(36 References)
Xiong, Z. Q., W. Qian, et al. (2003). "Formation of complement membrane attack complex in mammalian cerebral cortex evokes seizures and neurodegeneration." J Neurosci 23(3): 955-60.
The complement system consists of >30 proteins that interact in a carefully regulated manner to destroy invading bacteria and prevent the deposition of immune complexes in normal tissue. This complex system can be activated by diverse mechanisms proceeding through distinct pathways, yet all converge on a final common pathway in which five proteins assemble into a multimolecular complex, the membrane attack complex (MAC). The MAC inserts into cell membranes to form a functional pore, resulting in ion flux and ultimately osmotic lysis. Immunohistochemical evidence of the MAC decorating neurons in cortical gray matter has been identified in multiple CNS diseases, yet the deleterious consequences, if any, of MAC deposition in the cortex of mammalian brain in vivo are unknown. Here we demonstrate that the sequential infusion of individual proteins of the membrane attack pathway (C5b6, C7, C8, and C9) into the hippocampus of awake, freely moving rats induced both behavioral and electrographic seizures as well as cytotoxicity. The onset of seizures occurred during or shortly after the infusion of C8/C9. Neither seizures nor cytotoxicity resulted from the simultaneous infusion of all five proteins premixed in vitro. The requirement for the sequential infusion of all five proteins together with the temporal relationship of seizure onset to infusions of C8/C9 implies that the MAC was formed in vivo and triggered both seizures and cytotoxicity. Deposition of the complement MAC in cortical gray matter may contribute to epileptic seizures and cell death in diverse diseases of the human brain.
Moreira, P. I., M. S. Santos, et al. (2003). "Increased vulnerability of brain mitochondria in diabetic (Goto-Kakizaki) rats with aging and amyloid-beta exposure." Diabetes 52(6): 1449-56.
This study evaluated the respiratory indexes (respiratory control ratio [RCR] and ADP/O ratio), mitochondrial transmembrane potential (DeltaPsim), repolarization lag phase, repolarization level, ATP/ADP ratio, and induction of the permeability transition pore of brain mitochondria isolated from normal Wistar and GK diabetic rats of different ages (1.5, 12, and 24 months of age). The effect of amyloid beta-peptides, 50 micromol/l Abeta(25-35) or 2 micromol/l Abeta(1-40), on mitochondrial function was also analyzed. Aging of diabetic mice induced a decrease in brain mitochondrial RCR, ADP/O, and ATP/ADP ratios but induced an increase in the repolarization lag phase. Brain mitochondria from older diabetic rats were more prone to the induction of the permeability transition pore, i.e., mitochondria from 24-month-old diabetic rats accumulated much less Ca(2+) (20 micromol/l) than those isolated from 12-month-old rats (50 micromol/l) or 1.5-month-old rats (100 micromol/l). In the presence of 50 micromol/l Abeta(25-35) or 2 micromol/l Abeta(1-40), age-related mitochondrial effects were potentiated. These results indicate that diabetes-related mitochondrial dysfunction is exacerbated by aging and/or by the presence of neurotoxic agents such as amyloid beta-peptides, supporting the idea that diabetes and aging are risk factors for the neurodegeneration induced by these peptides.
Ozaki, M., T. Hashikawa, et al. (2002). "Degeneration of pontine mossy fibres during cerebellar development in weaver mutant mice." Eur J Neurosci 16(4): 565-74.
In weaver mutant mice, substitution of an amino acid residue in the pore region of GIRK2, a subtype of the G-protein-coupled inwardly rectifying K+ channel, changes the properties of the homomeric channel to produce a lethal depolarized state in cerebellar granule cells and dopaminergic neurons in substantia nigra. Degeneration of these types of neurons causes strong ataxia and Parkinsonian phenomena in the mutant mice, respectively. On the other hand, the mutant gene is also expressed in various other brain regions, in which the mutant may have effects on neuronal survival. Among these regions, we focused on the pontine nuclei, the origin of the pontocerebellar mossy fibres, projecting mainly into the central region of the cerebellar cortex. The results of histological analysis showed that by P9 the number of neurons in the nuclei was reduced in the mutant to about one half and by P18 to one third of those in the wild type, whereas until P7 the number were about the same in wild-type and weaver mutant mice. Three-dimensional reconstruction of the nuclei showed a marked reduction in volume and shape of the mutant nuclei, correlating well with the decrease in neuronal number. In addition, DiI (a lipophilic tracer dye) tracing experiments revealed retraction of pontocerebellar mossy fibres from the cerebellar cortex after P5. From these results, we conclude that projecting neurons in the pontine nuclei, as well as cerebellar granule cells and dopaminergic neurons in substantia nigra, strongly degenerate in weaver mutant mice, resulting in elimination of pontocerebellar mossy fibres during cerebellar development.
Moreira, P. I., M. S. Santos, et al. (2002). "Effect of amyloid beta-peptide on permeability transition pore: a comparative study." J Neurosci Res 69(2): 257-67.
A potentially central factor in neurodegeneration is the permeability transition pore (PTP). Because of the tissue-specific differences in pore properties, we directly compared isolated brain and liver mitochondria responses to the neurotoxic A beta peptides. For this purpose, the following parameters were examined: mitochondrial membrane potential (Delta Psi m), respiration, swelling, ultrastructural morphology, and content of cytochrome c. Both peptides, A beta(25-35) (50 microM) and A beta(1-40) (2 microM), had a similar toxicity, exacerbating the effects of Ca(2+), although, per se, they did not induce (PTP). In liver mitochondria, A beta led to a drop in Delta Psi m and potentiated matrix swelling and disruption induced by Ca(2+). In contrast, brain mitochondria, exposed to the same conditions, demonstrated a higher capacity to accumulate Ca(2+) before the Delta Psi m drop and a slight increase of mitochondrial swelling compared with liver mitochondria. Furthermore, mitochondrial respiratory state 3 was depressed in the presence of A beta, whereas state 4 was unaltered, resulting in an uncoupling of respiration. In both types of mitochondria, A beta did not affect the content of cytochrome c. The Delta Psi m drop was reversed when Ca(2+) was removed by EGTA or when ADP plus oligomycin was present. Pretreatment with cyclosporin A or ADP plus oligomycin prevented the deleterious effects promoted by A beta and/or Ca(2+). It can be concluded that brain and liver mitochondria show a different susceptibility to the deleterious effect of A beta peptide, brain mitochondria being more resistant to the potentiation by A beta of Ca(2+)-induced PTP.
Horn, T. F., G. Wolf, et al. (2002). "Nitric oxide promotes intracellular calcium release from mitochondria in striatal neurons." Faseb J 16(12): 1611-22.
Overproduction of nitric oxide by NMDA receptor stimulation is implicated in calcium deregulation and neurodegeneration of striatal neurons. We investigated the involvement of nitric oxide (NO) in inducing intracellular calcium release and in modifying calcium transients evoked by NMDA. NO application (4-10 microM) reversibly and repeatedly increased the intracellular calcium concentration [Ca2+]i in Fura-2- or fluo-3-loaded cultured mouse striatal neurons. NO-induced [Ca2+]i responses persisted in the absence of extracellular calcium, indicating that Ca2+ was released from intracellular stores. The source of calcium was distinct from [Ca2+]i-activated (ruthenium red and ryanodine sensitive) or IP3-activated (thapsigargin-sensitive) Ca2+ stores and was not dependent on cGMP production because a cell permeant analog, 8-bromo-cGMP, did not increase basal [Ca2+]i. Glucose removal potentiated the NO-induced release of [Ca2+]i. In contrast, pretreatment with either the mitochondrial uncoupler carbonyl cyanide m-chlorophenylhydrazone or cyclosporin A, a blocker of the mitochondrial permeability transition pore, prevented the [Ca2+]i increase after NO. The rise in [Ca2+]i during NO exposure was preceded by a decrease in mitochondrial membrane potential that was partly reversible during washout. Repeated applications of NMDA induced irreversible [Ca2+]i responses in a subpopulation of striatal cells that were greatly reduced by the NOS inhibitor N omega-nitro-l-arginine. Calcium transients were prolonged by conjoint application of NMDA and NO. We conclude that NMDA-evoked [Ca2+]i transients are modulated by endogenous NO production, which leads to release of calcium from the mitochondrial pool. An NO-activated mitochondrial permeability transition pore may lead to cell death after overstimulation of NMDA receptors.
Friberg, H. and T. Wieloch (2002). "Mitochondrial permeability transition in acute neurodegeneration." Biochimie 84(2-3): 241-50.
Acute neurodegeneration in man is encountered during and following stroke, transient cardiac arrest, brain trauma, insulin-induced hypoglycemia and status epilepticus. All these severe clinical conditions are characterized by neuronal calcium overload, aberrant cell signaling, generation of free radicals and elevation of cellular free fatty acids, conditions that favor activation of the mitochondrial permeability transition pore (mtPTP). Cyclosporin A (CsA) and its analog N-methyl-valine-4-cyclosporin A (MeValCsA) are potent blockers of the mtPTP and protect against neuronal death following excitotoxicity and oxygen glucose deprivation. Also, CsA and MeValCsA diminish cell death following cerebral ischemia, trauma, and hypoglycemia. Here we present data that strongly imply the mtPT in acute neurodegeneration in vivo. Compounds that readily pass the blood-brain-barrier (BBB) and block the mtPT may be neuroprotective in stroke.
Preston, E., J. Webster, et al. (2001). "Characteristics of sustained blood-brain barrier opening and tissue injury in a model for focal trauma in the rat." J Neurotrauma 18(1): 83-92.
Minor stab wounding of rodent brain by needle or razor blade is a standard model for immunohistochemical investigations of secondary neuronal degeneration and scarring. Opening of the blood-brain barrier (BBB) to plasma molecules and inflammatory cells is integral to the secondary injury process. To facilitate quantitative study of these BBB phenomena, we tested the utility of a stereotaxic wire knife as a minimally invasive way for modeling of focal trauma and bleeding in brain parenchyma and substantial, reproducible BBB damage. Adult rats were anesthetized, and through a skull burr hole, the 0.3-mm dia guide cannula housing a laterally extendable tungsten wire (0.13 mm dia) was inserted into the right striatum. A layering of horizontal disk-like cuts (3 mm dia) was made, producing a cylindrical lesion of approximately 18 mm3 volume, approximately 2.7% of the cerebral hemisphere. Transfer constants (Ki) for blood to brain permeation of [3H]sucrose measured from 30 min to 2 weeks postlesion showed sustained BBB leakiness; for example, mean Ki +/- SEM (nL.g(-1) x s(-1)) for a standard, matrix-dissected forebrain sample enclosing the lesion were 7.2 +/- 1.2 (day 1 postlesion), 8.1 +/-1.4 (day 3), 5.4 +/- 0.8 (day 14) compared with values for contralateral nonlesioned forebrain ranging from 1.3 +/- 0.05 to 1.6 +/- 0.3 (n = 3-4 samples per time point). Analysis of the simultaneous transport of [14C]sucrose (MW = 342 Da) and [3H]inulin (MW approximately 5,000) showed significantly larger upward increments in Ki for sucrose than inulin, indicating a pore-like opening mechanism. Significant edema was measured 3 days postlesion. A reactive glial response was indicated by an increase in S100beta by 6 h and a glial scar forming around the lesion by 7 days. Secondary brain injury was indicated by a 10% loss of hemisphere mass, measured at 2 months. The wire knife enabled tailoring of interstitial trauma with a minimum of extraneous injury and supported reproducible measurements of sustained BBB injury using relatively few animals.
McGeoch, J. E. and G. Guidotti (2001). "Batten disease and the control of the Fo subunit c pore by cGMP and calcium." Eur J Paediatr Neurol 5 Suppl A: 147-50.
Subunit c of ATP synthase functions as a high conductance ion channel, tightly regulated by calcium. We have suggested that the pathogenesis of Batten syndromes involving overaccumulation of subunit c are linked to the protein's ion channel function. In normal electrically excitable tissue the channel could act as a pacer setting nodal voltage via control of cation entry. The channel conductance is controlled by voltage, calcium, cyclic nucleotides and polyamines. We discuss the pathogenic role that subunit c could play in the electrically excitable tissues of retina, brain and heart where Batten neurodegeneration is seen. Focus is given to potential links between subunit c and the known mutant gene products in the Batten diseases, the process of apoptosis, and the requirement of the growing brain for gradients of cGMP, a ligand of the subunit c channel.
Liu, W., R. Liu, et al. (2001). "Role of polyamine metabolism in kainic acid excitotoxicity in organotypic hippocampal slice cultures." J Neurochem 79(5): 976-84.
Polyamines are ubiquitous cations that are essential for cell growth, regeneration and differentiation. Increases in polyamine metabolism have been implicated in several neuropathological conditions, including excitotoxicity. However, the precise role of polyamines in neuronal degeneration is still unclear. To investigate mechanisms by which polyamines could contribute to excitotoxic neuronal death, the present study examined the role of the polyamine interconversion pathway in kainic acid (KA) neurotoxicity using organotypic hippocampal slice cultures. Treatment of cultures with N1,N(2)-bis(2,3-butadienyl)-1,4-butanediamine (MDL 72527), an irreversible inhibitor of polyamine oxidase, resulted in a partial but significant neuronal protection, especially in CA1 region. In addition, this pre-treatment also attenuated KA-induced increase in levels of lipid peroxidation, cytosolic cytochrome C release and glial cell activation. Furthermore, pre-treatment with a combination of cyclosporin A (an inhibitor of the mitochondrial permeability transition pore) and MDL 72527 resulted in an additive and almost total neuronal protection against KA toxicity, while the combination of MDL 72527 and EUK-134 (a synthetic catalase/superoxide dismutase mimetic) did not provide additive protection. These data strongly suggest that the polyamine interconversion pathway partially contributes to KA-induced neurodegeneration via the production of reactive oxygen species.
Hossmann, K. A., U. Oschlies, et al. (2001). "Electron microscopic investigation of rat brain after brief cardiac arrest." Acta Neuropathol (Berl) 101(2): 101-13.
Rats were submitted to 10-min cardiac arrest, followed by resuscitation and survival for 1 day, 3 days or 1 week. Five regions of interest (CA1 and CA3 sector of hippocampus, dentate gyrus, reticular nucleus of thalamus and parietal cortex) where studied by light and electron microscopy at each of the survival times, and compared with non-ischemic control rats. Cell counts revealed delayed neuronal loss of about 30% after 3 days in both CA1 and CA3 sectors. Ischemic cell changes consisting of cytoplasmic condensation and nuclear pyknosis appeared in these regions on day 7 and --to a lesser degree-- also affected dentate gyrus, the reticular nucleus of thalamus and cerebral cortex. Ultrastructural alterations were evaluated using an ultrastructural injury catalogue. In all brain regions similar, although quantitatively differently expressed, changes occurred except ribosomal disaggregation, which was restricted to neurons of hippocampal CA1 sector on the first day after cardiac arrest. Progressive alterations included swelling of mitochondria and endoplasmic reticulum, which was most pronounced in CA1 and CA3 sectors of hippocampus, as well as chromatin aggregation and alterations of neuronal volume, which affected mainly the granule cells of dentate gyrus. Other alterations, such as osmiophilic inclusions or the formation of nuclear pore complexes, were transient with a maximum on the first day after cardiac arrest. Treatment with the free-radical scavenger alpha-phenyl-N-tert-butyl nitrone (PBN) suppressed the formation of nuclear pores but otherwise did not markedly change the morphological outcome. In comparison to previous studies of global brain ischemia induced by arterial inflow occlusion of the same duration, the present data demonstrate remarkable preservation of tissue integrity in CA1 sector but also distinct changes in brain regions considered to be resistant to ischemic injury. Morphological alterations of brain after cardiac arrest do not follow the established pattern of selective vulnerability.
Ghribi, O., D. A. DeWitt, et al. (2001). "Cyclosporin A inhibits Al-induced cytochrome c release from mitochondria in aged rabbits." J Alzheimers Dis 3(4): 387-391.
Neurodegenerative diseases including Alzheimer's disease are characterized by a progressive and selective neuronal loss via an apoptosis mechanism, and there is a growing body of evidence which supports a central role of mitochondria in this apoptotic cell death. Release of cytochrome c from the mitochondria to the cytosol is considered a critical step in apoptosis. Here we report that aluminum maltolate induces cytochrome c translocation into the cytosol as early as 3 hours in aged but not in young rabbit hippocampus. Pretreatment with cyclosporin A, an inhibitor of the mitochondria permeability transition pore (MTP), blocks cytochrome crelease. Therefore, it appears that aluminum maltolate-induced cytochrome c release results from opening of the MTP. This effect implicates aging as a prerequisite factor, since the MTP does not open in young animals. Mitochondrial injury thus may represent a primary initiator of neurodegeneration.
Brown, R. C. and V. Papadopoulos (2001). "Role of the peripheral-type benzodiazepine receptor in adrenal and brain steroidogenesis." Int Rev Neurobiol 46: 117-43.
The peripheral-type benzodiazepine receptor (PBR) has been demonstrated to be critical for steroidogenesis in all steroid-producing tissues. Here, we review the identification and characterization of the PBR, the evidence pointing to its function as a cholesterol pore involved in transporting cholesterol from the cytoplasm of steroid-producing cells into the inner mitochondrial membrane where it is metabolized, and the known mechanisms regulating its function. We present data on the functions of the PBR in the adrenal gland, a classical steroidogenic tissue, and in the brain, which has only recently been proven to be steroidogenic. Finally, we discuss other potential roles for the PBR in pathological conditions, including cancer, neurodegeneration, and neurotoxicity, and a broader role for the PBR in mediating intracellular cholesterol transport/compartmentalization, which may or may not be linked to steroid biosynthesis.
Toescu, E. C., N. Myronova, et al. (2000). "Age-related structural and functional changes of brain mitochondria." Cell Calcium 28(5-6): 329-38.
Normal ageing is associated with a gradual decline in the capacity of various cell types, including neurones, to respond to metabolic stress and return to the resting state. An important factor in the decrease of this 'homeostatic reserve' is the gradual, age-dependent impairment of mitochondrial function. In this article we review some of the major structural and functional changes in mitochondria associated with ageing. Apart from the increased mutations in mitochondrial DNA and the evidence for increased oxidative stress with ageing, we also discuss, in some detail, the importance of the mitochondrial membrane structure and composition (in particular lipid composition) for mitochondrial function in general and during ageing. Although some of the neurodegenerative diseases are also associated with some degree of mitochondrial dysfunction, it is not yet clear if these changes are due to the underlining process of normal, physiological ageing or due to the specific pathophysiologic agents responsible for the neurodegenerative processes. Furthermore, we are proposing that there are important differences between normal ageing and neurodegeneration.
Sattler, R. and M. Tymianski (2000). "Molecular mechanisms of calcium-dependent excitotoxicity." J Mol Med 78(1): 3-13.
Excitotoxicity is thought to be a major mechanism contributing to neurodegeneration during central nervous system ischemia, trauma, and other neurological disorders. Briefly, synaptic overactivity leads to the excessive release of glutamate, the major excitatory neurotransmitter in the mammalian central nervous system. Glutamate activates a number of postsynaptic cell membrane receptors, which upon activation open their associated ion channel pore to produce ion influx or efflux. This leads to a disturbance of the intracellular ionic environment, the best characterized feature of which is the influx of sodium, chloride, and Ca2+. An excess of Ca2+ ions then activates intracellular Ca2+-dependent signaling cascades that eventually lead to neuronal cell death. Despite intensive research in the field of Ca2+-dependent neurotoxicity the precise molecular mechanisms leading to cell death remain poorly understood. In particular, the question of the precise relationship between Ca2+ loading and neurotoxicity has been controversial. Many glutamate receptors are clustered and localized at the postsynaptic density. Recently, increasing knowledge of the molecular composition of the postsynaptic density has allowed us to extend our understanding of the molecular mechanisms of Ca2+-dependent excitotoxicity and to propose that distinct, membrane receptor-specific, neurotoxic signaling pathways transduce Ca2+-dependent excitotoxicity. These findings may have significant implications in the search for precisely targeted therapeutic drugs for a range of neurological disorders.
Lawson, K. (2000). "Potassium channel openers as potential therapeutic weapons in ion channel disease." Kidney Int 57(3): 838-45.
The opening of potassium (K+) channels, causing hyperpolarization of the cell membrane, is a physiological means of decreasing cell excitability. Thus, drugs with this property will demonstrate a broad clinical potential. The identification of synthetic molecules that evoke physiological responses (for example smooth muscle relaxation) by the opening of K+ channels led to a new direction in the pharmacology of ion channels. The term "potassium channel openers" was initially associated with a group of chemically diverse agents (for example, cromakalim, pinacidil, nicorandil) that evoke K+ efflux through adenosine 5'-triphosphate (ATP)-sensitive K+ channels (KATP). This finding initiated a search to identify molecules that specifically open other K+ channel subtypes (for example large conductance calcium-activated K+ channels [BKCa]). K+ channel opening properties have been demonstrated in a diverse range of synthetic chemical structures and endogenous substances. Second generation KATP channel openers (KATPCOs) demonstrate heterogeneous pharmacology indicative of independent sites of action for the different agents. Successful cloning of the KATP channel has shed light on the heterogeneity of the structure targeted by KATPCOs. Expression of the actions of KATPCOs involves three isoforms of the sulfonylurea (SUR) receptor (which forms the beta subunit of the KATP channel). The distribution of the SUR isoforms (and potential of identifying new isoforms) provides unique targets for the development of selective KATPCOs giving focused therapeutic approaches to clinical conditions for example cardiac ischemia, urinary incontinence, neurodegeneration, obesity and autoimmune diseases. BKCa channels are found in a diverse array of tissues and due to voltage and Ca sensitivity may work as a negative feedback process. A variety of small synthetic molecules (for example, NS004, fenamates) and natural product-derived compounds (DHS-I, maxikdiol) have been identified as selective BKCa channel openers which should have a profound impact in controlling diseases. The discovery of numerous variants of the alpha subunit (ion conductance pore) and beta subunit (contributes biophysical and pharmacological properties) complex of the BKCa channel gives potential to target specific tissues with selective openers. Little is known, however, about the site(s) of interaction of openers of these channels. The discovery of K+ channel subtype-specific openers and their evaluation in different diseases will determine the degree to which these channels (KATP, BKCa), or their isoforms, represent realistic therapeutic targets. Drugs already marketed that open K+ channels were discovered empirically, and most have serious safety and efficacy problems. New scientific methods, utilizing molecular insight, are implicating K+ channel dysfunction in numerous disease states and are identifying new targets for the future generation of K+ channel opening drugs.
Jordan, J., M. F. Galindo, et al. (2000). "Veratridine induces apoptotic death in bovine chromaffin cells through superoxide production." Br J Pharmacol 130(7): 1496-504.
The molecular mechanisms involved in veratridine-induced chromaffin cell death have been explored. We have found that exposure to veratridine (30 microM, 1 h) produces a delayed cellular death that reaches 55% of the cells 24 h after veratridine exposure. This death has the features of apoptosis as DNA fragmentation can be observed. Calcium ions play an important role in veratridine-induced chromaffin cell death because the cell permeant Ca(2+) chelator BAPTA-AM and extracellular Ca(2+) removal completely prevented veratridine-induced toxicity. Following veratridine treatment, there is a decrease in mitochondrial function and an increase in superoxide anion production. Veratridine-induced increase in superoxide production was blocked by tetrodotoxin (TTX; 10 microM), extracellular Ca(2+) removal and the mitochondrial permeability transition pore blocker cyclosporine A (10 microM). Veratridine-induced death was prevented by different antioxidant treatments including catalase (100 IU ml(-1)), N-acetyl cysteine (100 microM), allopurinol (100 microM) or vitamin E (50 microM). Veratridine-induced DNA fragmentation was prevented by TTX (10 microM). Veratridine produced a time-dependent increase in caspase activity that was prevented by Ca(2+) removal and TTX (10 microM). In addition, calpain and caspases inhibitors partially prevented veratridine-induced death. These results indicate that chromaffin cells share with neurons the molecular machinery involved in apoptotic death and might be considered a good model to study neuronal death during neurodegeneration.
Vieira, H. L. and G. Kroemer (1999). "Pathophysiology of mitochondrial cell death control." Cell Mol Life Sci 56(11-12): 971-6.
Mitochondria have been recently recognized to play a major role in the control of apoptosis or programmed cell death. Permeabilization of mitochondrial membranes, a decisive feature of early cell death, is regulated by members of the Bcl-2 family which interact with the permeability transition pore complex (PTPC). Thus, the cytoprotective oncoprotein Bcl-2 stabilizes the mitochondrial membrane barrier function, whereas the tumor suppressor protein Bax permeabilizes mitochondrial membranes. The regulation of membrane permeabilization is intertwined with that of the bioenergetic and redox functions of mitochondria. The implications of alterations in the composition of the PTPC and in mitochondrial function for the pathophysiology of cancer (reduced apoptosis) and neurodegeneration (enhanced apoptosis) are discussed.
Tatton, W. G. (1999). "Apoptotic mechanisms in neurodegeneration: possible relevance to glaucoma." Eur J Ophthalmol 9 Suppl 1: S22-9.
Deprenyl, a monoamine oxidase inhibitor used in the treatment of Parkinson's disease, along with its primary metabolite desmethyldeprenyl (DES) have been shown to reduce neuronal apoptosis by a mechanism that requires gene transcription and involves the maintenance of mitochondrial membrane potential. This review article explores the mechanisms by which DES maintains mitochondrial membrane potential. Mediated by GAPDH binding, DES increases mitochondrial BCL-2 and BCL-xL levels and decreases BAX levels thereby preventing the permeability transition pore (PTP) form opening and preventing apoptotic degradation. The favorable effects of deprenyl on neuronal apoptosis suggests the therapeutic potential of designing compounds with the capacity to alter the configurations of pro-apoptosis or anti-apoptotic proteins.
Jung, H., E. Y. Lee, et al. (1999). "Age-related changes in ultrastructural features of cathepsin B- and D-containing neurons in rat cerebral cortex." Brain Res 844(1-2): 43-54.
The present study examines age-related changes in the subcellular localization of cathepsin B (cath B) and cathepsin D (cath D), as well as morphological features of the cathepsin-immunoreactive (ir) neurons in rat cerebral cortex. Sprague-Dawley rats were studied at 3 and 26 months. By immunoelectron microscopy cath B- or cath D-immunoreactivities were found in many, but not all, pyramidal neurons. In young rat cerebral cortical neurons, cath B was observed not only in lysosomal systems such as multivesicular bodies, dense bodies, and lipofuscin granules, but also in extralysosomal sites. By contrast, cath D was confined mainly to lysosomal systems in young rats. In aged rats, cath B showed a similar pattern in its subcellular localization compared to the young control, but some of the dense bodies containing cath B was closely apposed to the outer nuclear envelope. These cells exhibited a relatively normal appearance. Regardless of subcellular localization, approximately 10% of cath B-ir neurons displayed ultrastructural disturbances presumed to indicate an early stage of degeneration. The nucleus was indented, nuclear boundary was indistinct, nuclear pore structures appeared separately with high frequency, and the endoplasmic reticulum appeared to be affected. In addition to its presence in lysosomal structures, cath D-immunoreactivity in aged cerebral cortex was noted prominently in the cytosol as diffuse granules. About 37% of cath D-ir cells showed this age-related change. Among the neurons with the diffusely scattered form of cath D, approximately 70% of cells exhibited the degenerating features. These cells were characterized by large amounts of diffuse cath D, reduced cellular size, loss of the nuclear boundary, scattered nuclear pore structures, an often fragmentation of the nucleus, disturbances of endoplasmic reticular system, and in advanced stages, condensed nucleus and poor preservation of almost cytoplasmic organelles. Though some of these features were also found in cath B-ir neurons, findings of overt degeneration, such as fragmented and condensed nuclei and impaired almost cytoplasmic organelles, were generally not observed in cath B-ir neurons. In addition, lipofuscin aggregates containing cath D were observed frequently in the extracellular space close to sites of ruptured plasma membrane, whereas in the sections stained with anti-cath B antibodies, large-sized lipofuscin aggregates showed only very weak or no cath B-immunoreactivity at all. Taken together, the present results suggest that cath D and cath B may be regulated differently and play their specific roles in the aging of the brain, especially, the change in location of cath D from the lysosomal system to the cytosol in the aged brain may play an important role in age-related cell death.
Greenamyre, J. T., G. MacKenzie, et al. (1999). "Mitochondrial dysfunction in Parkinson's disease." Biochem Soc Symp 66: 85-97.
The cause of Parkinson's disease (PD) is unknown, but reduced activity of complex I of the electron-transport chain has been implicated in the pathogenesis of both mitochondrial permeability transition pore-induced Parkinsonism and idiopathic PD. We developed a novel model of PD in which chronic, systemic infusion of rotenone, a complex-I inhibitor, selectively kills dopaminergic nerve terminals and causes retrograde degeneration of substantia nigra neurons over a period of months. The distribution of dopaminergic pathology replicates that seen in PD, and the slow time course of neurodegeneration mimics PD more accurately than current models. Our model should enhance our understanding of neurodegeneration in PD. Metabolic impairment depletes ATP, depresses Na+/K(+)-ATPase activity, and causes graded neuronal depolarization. This relieves the voltage-dependent Mg2+ block of the N-methyl-D-aspartate (NMDA) subtype of the glutamate receptor, which is highly permeable to Ca2+. Consequently, innocuous levels of glutamate become lethal via secondary excitotoxicity. Mitochondrial impairment also disrupts cellular Ca2+ homoeostasis. Moreover, the facilitation of NMDA-receptor function leads to further mitochondrial dysfunction. To a large part, this occurs because Ca2+ entering neurons through NMDA receptors has 'privileged' access to mitochondria, where it causes free-radical production and mitochondrial depolarization. Thus there may be a feed-forward cycle wherein mitochondrial dysfunction causes NMDA-receptor activation, which leads to further mitochondrial impairment. In this scenario, NMDA-receptor antagonists may be neuroprotective.
Cassarino, D. S. and J. P. Bennett, Jr. (1999). "An evaluation of the role of mitochondria in neurodegenerative diseases: mitochondrial mutations and oxidative pathology, protective nuclear responses, and cell death in neurodegeneration." Brain Res Brain Res Rev 29(1): 1-25.
There is mounting evidence for mitochondrial involvement in neurodegenerative diseases including Alzheimer's and Parkinson's disease and amyotrophic lateral sclerosis. Mitochondrial DNA mutations, whether inherited or acquired, lead to impaired electron transport chain (ETC) functioning. Impaired electron transport, in turn, leads to decreased ATP production, formation of damaging free-radicals, and altered calcium handling. These toxic consequences of ETC dysfunction lead to further mitochondrial damage including oxidation of mitochondrial DNA, proteins, and lipids, and opening of the mitochondrial permeability transition pore, an event linked to cell death in numerous model systems. Although protective nuclear responses such as antioxidant enzymes and bcl-2 may be induced to combat these pathological changes, such a vicious cycle of increasing oxidative damage may insidiously damage neurons over a period of years, eventually leading to neuronal cell death. This hypothesis, a synthesis of the mitochondrial mutations and oxidative stress hypotheses of neurodegeneration, is readily tested experimentally, and clearly points out many potential therapeutic targets for preventing or ameliorating these diseases.
Campbell, D. B., J. B. North, et al. (1999). "Tottering mouse motor dysfunction is abolished on the Purkinje cell degeneration (pcd) mutant background." Exp Neurol 160(1): 268-78.
Tottering (tg) mice inherit a recessive mutation of the calcium channel alpha 1A subunit gene, which encodes the pore-forming protein of P/Q-type voltage-sensitive calcium channels and is predominantly expressed in cerebellar granule and Purkinje neurons. The phenotypic consequences of the tottering mutation include ataxia, polyspike discharges, and an intermittent motor dysfunction best described as paroxysmal dystonia. These dystonic episodes induce c-fos mRNA expression in the cerebellar circuitry, including cerebellar granule and Purkinje neurons, deep cerebellar nuclei, and the postsynaptic targets of the deep nuclei. Cellular abnormalities associated with the mutation include hyperarborization of brainstem nucleus locus ceruleus axons and abnormal expression of L-type calcium channels in cerebellar Purkinje cells. Here, the role of these two distinct neural pathways in the expression of tottering mouse intermittent dystonia was assessed. Lesion of locus ceruleus axons with the neurotoxin N-(2-chloroethyl)-N-ethyl-2-bromobenzyl-amine (DSP-4) did not affect the frequency of tottering mouse dystonic episodes. In contrast, removal of cerebellar Purkinje cells with the Purkinje cell degeneration (pcd) mutation by generation of tg/tg; pcd/pcd double mutant mice completely eliminated tottering mouse dystonia. Further, the c-fos expression pattern of tg/tg; pcd/pcd double mutants following restraint was indistinguishable from that of wild-type mice, suggesting that the pcd lesion eliminated an essential link in this abnormal neural network. These data suggest that the cerebellar cortex, where the mutant gene is abundantly expressed, contributes to the expression of tottering mouse dystonic episodes.
Berman, S. B. and T. G. Hastings (1999). "Dopamine oxidation alters mitochondrial respiration and induces permeability transition in brain mitochondria: implications for Parkinson's disease." J Neurochem 73(3): 1127-37.
Both reactive dopamine metabolites and mitochondrial dysfunction have been implicated in the neurodegeneration of Parkinson's disease. Dopamine metabolites, dopamine quinone and reactive oxygen species, can directly alter protein function by oxidative modifications, and several mitochondrial proteins may be targets of this oxidative damage. In this study, we examined, using isolated brain mitochondria, whether dopamine oxidation products alter mitochondrial function. We found that exposure to dopamine quinone caused a large increase in mitochondrial resting state 4 respiration. This effect was prevented by GSH but not superoxide dismutase and catalase. In contrast, exposure to dopamine and monoamine oxidase-generated hydrogen peroxide resulted in a decrease in active state 3 respiration. This inhibition was prevented by both pargyline and catalase. We also examined the effects of dopamine oxidation products on the opening of the mitochondrial permeability transition pore, which has been implicated in neuronal cell death. Dopamine oxidation to dopamine quinone caused a significant increase in swelling of brain and liver mitochondria. This was inhibited by both the pore inhibitor cyclosporin A and GSH, suggesting that swelling was due to pore opening and related to dopamine quinone formation. In contrast, dopamine and endogenous monoamine oxidase had no effect on mitochondrial swelling. These findings suggest that mitochondrial dysfunction induced by products of dopamine oxidation may be involved in neurodegenerative conditions such as Parkinson's disease and methamphetamine-induced neurotoxicity.
Womack, M., K. Thompson, et al. (1998). "Elevated intracellular calcium levels in cerebellar granule neurons of weaver mice." Neuroreport 9(15): 3391-5.
Weaver mice carry a mutation in the pore domain of the Girk2 (Kcnj6) gene. The mutation causes GIRK2 containing channels to lose ion selectivity and to become constitutively active. It is not known how this alteration in ion channel activity causes in cerebellar granule cells the defects in neurite extension, cell migration and induction of cell death that are characteristic of weaver mice. One possibility is that the mutation causes an inability to regulate intracellular calcium levels properly. We tested this hypothesis by measuring intracellular calcium levels in granule cells and Purkinje cells in slices from the cerebellum of weaver mice. We report here that weaver mice have increases in resting calcium levels in their granule cells, which may account for the multiple effects of the weaver mutation upon these cells.
Han, M. F., Q. Y. Her, et al. (1998). "Nuclear pore changes and absence of apoptosis in lumbar dorsal root ganglion neurons of doxorubicin-intoxicated rats." J Uoeh 20(2): 115-25.
Doxorubicin (DXR) produces degeneration of neurons in the lumbar dorsal root ganglion (DRG) in rats. Light microscopic studies, which included the terminal deoxynucleotidyl transferase-mediated deoxyuridine triphosphate-biotin nick end labeling method, and electron microscopic observation revealed that the moderate nuclear and remarkable cytoplasmic degeneration of DRG neurons of Sprague-Dawley rats after intravenous administration of 8 mg/kg of DXR was cell necrosis, not apoptosis. In some neurons, mostly dark and usually with moderate degrees of nuclear degenerative changes, the nuclear pores were decreased in number and obscure 14 and 20 days after DXR administration. DXR enters presumably the nucleus and is partly removed through the nuclear pores. However, the diameters of nuclear pores were similar in DXR-intoxicated and control rats. The changes in nuclear pores of neurons in DXR intoxication, which to our knowledge has not been previously studied, are considered to be part of the degenerative or necrotic changes of DRG neurons.
Dove, L. S., L. C. Abbott, et al. (1998). "Whole-cell and single-channel analysis of P-type calcium currents in cerebellar Purkinje cells of leaner mutant mice." J Neurosci 18(19): 7687-99.
The leaner (tgla) mutation in mice results in severe ataxia and an overt neurodegeneration of the cerebellum. Positional cloning has revealed that the tgla mutation occurs in a gene encoding the voltage-activated calcium channel alpha1A subunit. The alpha1A subunit is highly expressed in the cerebellum and is thought to be the pore-forming subunit of P- and Q-type calcium channels. In this study we used both whole-cell and single-channel patch-clamp recordings to examine the functional consequences of the tgla mutation on P-type calcium currents. High-voltage-activated (HVA) calcium currents were recorded from acutely dissociated cerebellar Purkinje cells of homozygous leaner (tgla/tgla) and age-matched wild-type (+/+) mice. In whole cell recordings, we observed a marked reduction of peak current density in tgla/tgla Purkinje cells (-35.0 +/- 1.8 pA/pF) relative to that in +/+ (-103.1 +/- 5.9 pA/pF). The reduced whole-cell current in tgla/tgla cells was accompanied by little to no alteration in the voltage dependence of channel gating. In both genotypes, HVA currents were predominantly of the omega-agatoxin-IVA-sensitive P-type. Cell-attached patch-clamp recordings revealed no differences in single-channel conductance between the two genotypes and confirmed the presence of three distinct conductance levels (9, 13-14, and 17-18 pS) in cerebellar Purkinje cells. Analysis of patch open-probability (NPo) revealed a threefold reduction in the open-probability of channels in tgla/tgla patches (0.04 +/- 0.01) relative to that in +/+ (0.13 +/- 0.02), which may account for the reduced whole-cell current in tgla/tgla Purkinje cells. These results suggest that the tgla mutation can alter native P-type calcium channels at the single-channel level and that these alterations may contribute to the neuropathology of the leaner phenotype.
Waldmann, R., G. Champigny, et al. (1995). "Functional degenerin-containing chimeras identify residues essential for amiloride-sensitive Na+ channel function." J Biol Chem 270(20): 11735-7.
The highly selective, amiloride-sensitive Na+ channel is formed of three homologous subunits termed alpha, beta, and gamma. The three subunits exhibit similarities with Caenorhabditis elegans proteins called degenerins involved in sensory touch transduction and, when mutated, in neurodegeneration. Swelling of neurons observed in neurodegeneration suggests an involvement of ion transport, but the channel function of degenerins has not yet been demonstrated. We used chimeras to study the functional relationship between the epithelial sodium channel and the degenerin Mec-4. Exchange of the hydrophobic domains of the Na+ channel alpha subunit by those of Mec-4 results in a functional ion channel with changed pharmacology for amiloride and benzamil and changed selectivity, conductance, gating, and voltage dependence. All of these differences were also obtained by exchanging Ser-589 and Ser-593 in the second transmembrane region by the corresponding residues of Mec-4, suggesting that these two residues are essential for the ionic pore function of the channel.
Treinin, M. and M. Chalfie (1995). "A mutated acetylcholine receptor subunit causes neuronal degeneration in C. elegans." Neuron 14(4): 871-7.
Neurotoxicity through abnormal activation of membrane channels is a potential cause of neurodegenerative disease. Here we show that a gain-of-function mutation, deg.3(u662), leads to the degeneration of a small set of neurons in the nematode C. elegans. The deg.3 gene encodes a nicotinic acetylcholine receptor alpha subunit, which in the region of transmembrane domain II is most similar to the neuronal alpha 7 subunits from rat and chicken. The u662 mutation changes a residue in the second transmembrane domain, the domain thought to form the channel pore. A similar change in the equivalent amino acid in the chick protein produces channels that desensitize slowly. Channel hyperactivity may underlie the degenerations seen in the C. elegans deg.3(u662) mutants, since antagonists of nicotinic acetylcholine receptors suppress the deg-3(u662) mutant phenotypes.
Ohara, I., R. Tabuchi, et al. (1995). "Decline of taste sensitivity in protein deficient adult rats." Physiol Behav 57(5): 921-6.
The influence of dietary protein levels on taste sensitivity was studied in adult rats. Low protein diets of 0.0, 2.5, or 5.0% purified egg protein (PEP) were fed to animals for 28 days. Two bottle choice preference tests between aqueous solutions of either 2, 9, 17, or 86 mM sodium chloride and deionized water were conducted in an ascending order on days 14, 16, 18, and 20. Urine samples were collected for zinc and creatinine analysis. Blood samples were also collected for measuring serum zinc and creatinine concentrations. Scanning electron microscopy was performed to observe rats' tongue epithelia. Protein free diet group showed significantly lower taste sensitivity and renal reabsorption rate than other protein containing diet groups, while serum zinc and creatinine concentrations, and creatinine clearance were not affected by dietary protein level. Degeneration of filiform papillae and imperforation of taste pore of fungiform papillae were observed in protein free diet group. This experiment implies at least 2.5% dietary protein is required to manifest normal taste function in the adult.
Garcia-Anoveros, J., C. Ma, et al. (1995). "Regulation of Caenorhabditis elegans degenerin proteins by a putative extracellular domain." Curr Biol 5(4): 441-8.
BACKGROUND: Rare, dominant mutations in the degenerin genes of Caenorhabditis elegans (deg-1, mec-4 and mec-10) cause neuronal degeneration. The extensive sequence similarity between degenerins and mammalian genes that encode subunits of the amiloride-sensitive sodium channel from kidney, colon and lung suggests that the C. elegans degenerins form ion channels. As mec-4 and mec-10 are needed for the reception of gentle touch stimuli, they may contribute to a mechanosensory ion channel. All the dominant degeneration-causing mutations in the C. elegans degenerin genes affect equivalent residues in a hydrophobic region that is structurally similar to the H5 domain of several ion channels, and so could form the channel lining. Increased channel activity may underlie the resulting degeneration, in which the affected cells vacuolate and swell. RESULTS: We now demonstrate that a missense change in a predicted extracellular region of the proteins encoded by deg-1 and mec-4 causes cell death similar to that caused by the dominant mutations. The missense mutation lies within a 22 amino-acid region found in all the C. elegans degenerins for which the sequences have been published, but not in the similar mammalian proteins. Deletion of nine amino acids surrounding the mutation site in mec-4 also causes neuronal degeneration. The degeneration-causing mutations in either the predicted pore-lining or the predicted extracellular regions of deg-1 are suppressed by additional, dominantly acting mutations that substitute larger for smaller residues within the channel lining. CONCLUSIONS: Our data suggest that the putative extracellular domain negatively regulates degenerin activity, perhaps by gating the channel. As this region is only found in the C. elegans proteins, it may allow more rapid regulation of the nematode channels, which may be needed for them to function in mechanosensation. The suppressor mutations, by adding larger amino acids to the putative pore lining, could prevent degeneration by blocking the pore of a multisubunit channel.
Dahlin, L. B. (1995). "Prevention of macrophage invasion impairs regeneration in nerve grafts." Brain Res 679(2): 274-80.
The importance of cell invasion for regeneration in nerve segments was investigated in rats. The regeneration distance of axons in predegenerated nerve segments was compared to the outgrowth in nerve segments where cell invasion had been prevented. A 10 mm long nerve segment, which was predegenerated (preserved or impaired blood circulation) or kept in a Millipore chamber (pore size 0.22 microns), was sutured as a nerve graft at the contralateral side three days or two weeks after the initial procedure. At two weeks immunocytochemical staining and routine histologic analysis revealed pronounced myelin breakdown and presence of ED1 and ED2 positive macrophages in the predegenerated nerve segment. Nerve segments, which were kept in the Millipore chamber, showed no invasion of macrophages and the myelin sheaths were preserved. The regeneration distances of axons in the nerve segments, evaluated with the pinch reflex test, were significantly longer in the predegenerated nerve segments compared to the nerve segments kept in Millipore chambers. Nerve grafts, which were taken from predegenerated nerves with intact blood circulation, showed the longest regeneration distances. It is suggested that the regeneration process can be impaired in nerve segments where cell and macrophage invasion as well as myelin breakdown are prevented and that preservation of the blood circulation during the degeneration process is important.
Hong, K. and M. Driscoll (1994). "A transmembrane domain of the putative channel subunit MEC-4 influences mechanotransduction and neurodegeneration in C. elegans." Nature 367(6462): 470-3.
Aberrant ion channel activity plays a causative role in several human disorders. Inappropriately regulated channel activity also appears to be the basis for neurodegeneration induced by dominant mutations of Caenorhabditis elegans mec-4 (mec-4(d)), a member of the degenerin gene family postulated to encode a subunit of a mechanosensory channel. The degenerin gene family has been defined by two C. elegans genes, mec-4 and deg-1, which can mutate to gain-of-function alleles that induce degeneration of specific groups of neurons. A related mammalian gene, rat alpha-rENaC, induces an amiloride-sensitive Na+ current when introduced to Xenopus oocytes, strongly suggesting that degenerin genes encode ion channel proteins. Deduced amino-acid sequences of the degenerins include two predicted membrane-spanning domains. Here we show that conserved amino acids within the second membrane-spanning domain (MSDII) are critical for MEC-4 activity and that specific substitutions within MSDII, whether encoded in cis or in trans to a mec-4(d) mutation, block or delay the onset of degeneration. Remarkably, MSDII from two other family members, C. elegans deg-1 and rat alpha-rENaC, can functionally substitute for MEC-4 MSDII in chimaeric proteins. Our results support a structural model for a mechanosensory channels in which multiple MEC-4 subunits are oriented such that MSDII lines the channel pore, and a neurodegeneration model in which aberrant ion flow through this channel is a key event.
White, F. V., A. D. Toews, et al. (1989). "Lipid metabolism during early stages of Wallerian degeneration in the rat sciatic nerve." J Neurochem 52(4): 1085-92.
We examined changes in biosynthetic capacity of sciatic nerve during the early stages of Wallerian degeneration, utilizing a model that permits exclusion of nonresident cells from degenerating nerve. Sciatic nerve segments were placed in either 5-microns pore (allowing infiltration of nonresident cells) or 0.22-microns pore (excluding nonresident cells) Millipore diffusion chambers and then implanted in the peritoneal cavity of the same 32-34-day-old rat. At times up to 7 days postsurgery, nerve segments from the chambers, as well as control segments from the contralateral sciatic nerve, were removed and their capacity to incorporate radioactive precursors into lipids and proteins assayed in vitro. In nerve segments from both the 0.22- and 5-microns pore chambers, incorporation of [14C]acetate into total lipids was decreased relative to control by 50% at 12 h postsurgery and by 85% at day 3. This decreased incorporation of [14C]acetate reflects primarily decreased de novo synthesis of cholesterol and of fatty acyl residues incorporated into glycerolipids and sphingolipids. There was a preferentially decreased synthesis of cerebrosides and cholesterol (components enriched in myelin) relative to other lipids, while cholesterol esters and free fatty acids (products of membrane degradation) accounted for a greater proportion of the greatly reduced levels of total lipid label. In contrast to [14C]acetate, incorporation of [3H]glycerol into lipids was increased up to fourfold, relative to control, 1 day after nerve transection.(ABSTRACT TRUNCATED AT 250 WORDS)
Ohi, T., J. F. Poduslo, et al. (1985). "Quantitative method for detection of blood-nerve barrier alterations in experimental animal models of neuropathy." Exp Neurol 90(2): 365-72.
A solid phase radioimmunoassay was developed for measuring albumin concentrations in both endoneurium and serum, which were normalized to total endoneurium and serum protein to obtain a blood-nerve barrier index (BNB-index). The BNB-index in experimental lead neuropathy demonstrated barrier dysfunction beginning at 6 weeks of 4% lead carbonate ingestion and at 14 weeks was 5.2 times that of pair-fed controls. These data, therefore, confirmed investigations that indicated a gradual alteration of the BNB beginning at 6 weeks and were based on (i) direct measurement of endoneurial albumin concentration by densitometry after sodium dodecyl sulfate-pore gradient electrophoresis and (ii) intravenous injection of 125I-albumin (J. F. Poduslo, P. A. Low, A. J. Windebank, P. J. Dyck, C. T. Berg, and J. D. Schmeltzer, 1982. J. Neurosci. 2: 1507-1514). The BNB-index after crush injury was 2.2 times that of control nerves at 24 h and gradually decreased toward normal values but was still 1.6 times that of controls at 70 days, a value consistent with the prolonged time course for complete repair. The BNB-index, therefore, can be used to evaluate BNB alterations quantitatively in animal models of neuropathy. Furthermore, we suggest that the BNB-index can also be used on biopsied, neuropathic, human sural nerve for evaluation of blood-nerve barrier abnormality.
Beuche, W. and R. L. Friede (1984). "The role of non-resident cells in Wallerian degeneration." J Neurocytol 13(5): 767-96.
Wallerian degeneration was studied in the phrenic or sciatic nerves of mice following transplantation into Millipore diffusion chambers of 0.22 micron pore size which were implanted in the peritoneal cavity and kept for up to eight weeks. This method positively eliminates the access of nonresident cells to the tissue, at the same time providing proper conditions for tissue survival. Such nerves showed no proliferation of Schwann cells and no evidence for their active role in the removal or digestion of myelin. Schwann cells rejected their sheaths and the latter persisted for weeks, leading either to sheath distension (the sheath becoming wider and thinner) or to collapse (the sheath becoming thicker, collapsing upon the empty axis cylinder). The outer envelope of Schwann cytoplasm separated into pseudopodia rich in microtubules. Sheath rejection led to a slow decay of the myelin in the absence of active phagocytosis. There was profuse fibroblastic proliferation from the epineurium and perineurium, from which cells migrated into the chambers developing fatty change. No evidence was found to link the fatty change in fibroblasts to sheath decay. Diffusion chambers of 5.0 micron pore size were invaded by leukocytes and monocytes. Nerves kept in such chambers showed active phagocytosis of myelin leading to its removal, similar to Wallerian degeneration in situ. Phagocytes were shown to attack selectively the rejected myelin sheaths, distinguishing the latter from the surviving Schwann cells, even though both structures derive from the same cell. The activity of phagocytes in digesting myelin was mediated by a signal which diminished in intensity with time; there was very little active phagocytosis of myelin in nerves that had been predegenerated in 0.22 micron pore chambers. Various modifications of the experiment, including studies with co-cultured peritoneal macrophages or bone marrow, indicate a need for additional activating factors to induce myelin phagocytosis.
Ide, C. and B. L. Munger (1980). "The cytologic composition of primate laryngeal chemosensory corpuscles." Am J Anat 158(2): 193-209.
The present study defines the cellular composition of chemosensory corpuscles (taste buds) present in the mucosa overlying the arytenoid cartilages of the larynx in serial sections studied by electron microscopy. Three cell types can be defined in such chemosensory corpuscles. Basal cells are relatively undifferentiated in terms of cytologic characteristics and have been identified presumptively as the stem cells for differentiation of the other two cell types. Sustentacular or supporting cells are characterized by the presence of apical electron-opaque granules that apparently are extruded into the lumen of the pore, and are, thus, the source of the electron-opaque extracellular material present between the microvilli protruding from the apex of the cells into the chemosensory corpuscle pore. The chemosensory cells are characterized by the presence of synaptic specializations with appended nerve fibers at the base of the cell, the presence of specific cytoplasmic secretory granules, as well as numerous clusters of typical synaptic vesicles, and apical microvilli that extend into the pore of the corpuscle. Other cell profiles encountered in chemosensory corpuscles are cells in various stages of degeneration or transition, to one of the other cell types, from undifferentiated basal cells. Two types of synaptic specializations have been identified as being associated with chemosensory cells. The first is characterized by an increased electron-opacity of the respective plasma membranes of nerve fiber and chemosensory cell. In this situation numerous synaptic vesicles usually are present in the cytoplasm of the chemosensory cell subjacent to the membrane densities. A second type of synaptic association is characterized by the presence of subsurface cisterns of agranular endoplasmic reticulum in the cytoplasm of the chemosensory cell, and numerous synaptic vesicles often are present in the axoplasm of the subjacent neurite, suggesting a reciprocal synapse. These findings are interpreted to indicate that only one cell type is specialized for transducing chemical signals into neural activity and that this cell is modulated by activity of the nervous system.