Howard Prentice

Human muscle neural cell adhesion molecule (N-CAM): Identification of a muscle-specific sequence in the extracellular domain

cDNA clones encoding neural cell adhesion molecule (N-CAM) mRNAs of 6.7, 5.2, and 4.3 kb from human skeletal muscle cells were isolated. A 6.7 kb mRNA encodes a transmembrane N-CAM isoform, present predominantly in mononucleate myoblasts, that shows sequence homology with chick brain N-CAM-140 and is down-regulated during myotube formation. In contrast, the 5.2 and 4.3 kb mRNAs encode nontransmembrane N-CAM isoforms that greatly increase during myoblast fusion. Furthermore, a discrete muscle-specific sequence domain (MSD1) was detected in the extracellular coding regions of the 5.2 and 4.3 kb mRNAs. This encodes a unique run of 37 amino acids and is not expressed in 7.2 and 6.7 kb mRNAs from human or chick brain or in the corresponding 6.7 kb muscle transcript. The MSD1 is also absent from chick and mouse brain mRNAs of 4.0 and 2.9 kb. These results show that diversity in N-CAM primary structure can be found in the extracellular domain in a tissue-specific manner.

Role of taurine in the central nervous system

Taurine demonstrates multiple cellular functions including a central role as a neurotransmitter, as a trophic factor in CNS development, in maintaining the structural integrity of the membrane, in regulating calcium transport and homeostasis, as an osmolyte, as a neuromodulator and as a neuroprotectant. The neurotransmitter properties of taurine are illustrated by its ability to elicit neuronal hyperpolarization, the presence of specific taurine synthesizing enzyme and receptors in the CNS and the presence of a taurine transporter system. Taurine exerts its neuroprotective functions against the glutamate induced excitotoxicity by reducing the glutamate-induced increase of intracellular calcium level, by shifting the ratio of Bcl-2 and Bad ratio in favor of cell survival and by reducing the ER stress. The presence of metabotropic taurine receptors which are negatively coupled to phospholipase C (PLC) signaling pathway through inhibitory G proteins is proposed, and the evidence supporting this notion is also presented.

Oxidation of zinc finger transcription factors: Physiological consequences

Redox-sensitive cysteine residues are present in the interaction domains of many protein complexes. There are examples in all of the major categories of transcription factors, including basic region, leucine zipper, helix-loop-helix, and zinc finger. Zinc finger structures require at least two zinc-coordinated cysteine sulfhydryl groups, and oxidation or alkylation of these can eliminate DNA-binding and transcriptional functions. We review here the evidence for oxidation of zinc finger cysteines, the pathways and reactive oxygen intermediates involved, and the functional and physiological consequences of these reactions. Despite skepticism that the strongly reducing intracellular environment would permit significant oxidation of cysteine residues within zinc finger transcription factors, there is compelling evidence that oxidation occurs both in vitro and in vivo. Early reports demonstrating reversible oxidation of zinc-coordinated cysteines with loss of binding function in vitro were shown to reflect accurately the changes in intact cells, and these in turn have been shown to correlate with physiological changes. In particular, the accumulation of oxidized Spl zinc fingers during aging, and estrogen receptors in tamoxifen-resistant breast cancers are dramatic examples of what may be a general sensitivity of zinc finger factors to changes in the redox state of the cell.

Nerve growth factor-induced changes in neural cell adhesion molecule (N-CAM) in PC12 cells.

The effects of nerve growth factor (NGF) on the expression of neural cell adhesion molecule (N‐CAM) in PC12 cells were determined. A quantitative immunoassay was used to show that NGF induces a 4‐ to 5‐fold increase in relative N‐CAM levels over a 3‐day period. This increase could not be mimicked by cholera toxin suggesting that it is not a simple consequence of morphological differentiation. The changes in N‐CAM levels induced by NGF were accompanied by changes in N‐CAM molecular forms. The 140‐kd N‐CAM species is the major N‐CAM expressed by naive PC12 cells, while NGF‐treated cultures express N‐CAM species of 180 kd and 140 kd. Northern analysis showed that naive cells express a 6.7‐kd N‐CAM mRNA species only, while NGF‐treated cultures express both a 6.7‐kb and a 7.2‐kb transcript. As the 6.7‐kb and 7.2‐kb mRNAs are alternative spliced transcripts of a single gene, this result shows that NGF can activate a neuron‐specific splicing mechanism. This is the first description of control of N‐CAM expression by a growth factor.

Protective function of taurine in glutamate‐induced apoptosis in cultured neurons

Previously, we showed that taurine protects neurons against glutamate‐induced excitotoxicity by inhibiting the glutamate‐induced increase of [Ca2+]i. In this study, we report that taurine prevents glutamate‐induced chromosomal condensation, indicating that taurine inhibits glutamate‐induced apoptosis. We found that Bcl‐2 was down‐regulated while Bax was up‐regulated by glutamate treatment, and these changes were prevented in the presence of taurine. We have also shown that taurine inhibits glutamate‐induced activation of calpain. Furthermore, calpastatin, a specific calpain inhibitor, also prevented glutamate‐induced cell death. Here we propose the mechanisms underlying glutamate‐induced apoptosis and taurines inhibition of glutamate‐induced apoptosis to be as follows: glutamate stimulation induces [Ca2+]i elevation, which in turn activates calpain; activation of calpain leads to a reduction of Bcl‐2:Bax ratios; with decreased Bcl‐2:Bax ratios Bax homodimers form, Bax homodimerization, and translocation to the mitochondria result in the release of cytochrome c; released cytochrome c in turn activates a downstream caspase cascade leading to apoptosis. The antiapoptotic function of taurine is due to its inhibition of glutamate‐induced membrane depolarization.

Mechanisms of Neuronal Protection against Excitotoxicity, Endoplasmic Reticulum Stress, and Mitochondrial Dysfunction in Stroke and Neurodegenerative Diseases

In stroke and neurodegenerative disease, neuronal excitotoxicity, caused by increased extracellular glutamate levels, is known to result in calcium overload and mitochondrial dysfunction. Mitochondrial deficits may involve a deficiency in energy supply as well as generation of high levels of oxidants which are key contributors to neuronal cell death through necrotic and apoptotic mechanisms. Excessive glutamate receptor stimulation also results in increased nitric oxide generation which can be detrimental to cells as nitric oxide interacts with superoxide to form the toxic molecule peroxynitrite. High level oxidant production elicits neuronal apoptosis through the actions of proapoptotic Bcl-2 family members resulting in mitochondrial permeability transition pore opening. In addition to apoptotic responses to severe stress, accumulation of misfolded proteins and high levels of oxidants can elicit endoplasmic reticulum (ER) stress pathways which may also contribute to induction of apoptosis. Two categories of therapeutics are discussed that impact major pro-death events that include induction of oxidants, calcium overload, and ER stress. The first category of therapeutic agent includes the amino acid taurine which prevents calcium overload and is also capable of preventing ER stress by inhibiting specific ER stress pathways. The second category involves N-methyl-D-aspartate receptor (NMDA receptor) partial antagonists illustrated by S-Methyl-N, N-diethyldithiocarbamate sulfoxide (DETC-MeSO), and memantine. DETC-MeSO is protective through preventing excitotoxicity and calcium overload and by blocking specific ER stress pathways. Another NMDA receptor partial antagonist is memantine which prevents excessive glutamate excitation but also remarkably allows maintenance of physiological neurotransmission. Targeting of these major sites of neuronal damage using pharmacological agents is discussed in terms of potential therapeutic approaches for neurological disorders.

Taurine protection of PC12 cells against endoplasmic reticulum stress induced by oxidative stress.

BackgroundTaurine is a free amino acid present in high concentrations in a variety of organs of mammalians. As an antioxidant, taurine has been found to protect cells against oxidative stress, but the underlying mechanism is still unclear.MethodsIn this report, we present evidence to support the conclusion that taurine exerts a protective function against endoplasmic reticulum (ER) stress induced by H2O2 in PC 12 cells. Oxidative stress was introduced by exposure of PC 12 cells to 250 uM H2O2 for 4 hours.ResultsIt was found that the cell viability of PC 12 cells decreased with an increase of H2O2 concentration ranging from approximately 76% cell viability at 100 uM H2O2 down to 18% at 500 uM H2O2. At 250 uM H2O2, cell viability was restored to 80% by taurine at 25 mM. Furthermore, H2O2 treatment also caused a marked reduction in the expression of Bcl-2 while no significant change of Bax was observed. Treatment with taurine restored the reduced expression of Bcl-2 close to the control level without any obvious effect on Bax. Furthermore, taurine was also found to suppress up-regulation of GRP78, GADD153/CHOP and Bim induced by H2O2, suggesting that taurine may also exert a protective function against oxidative stress by reducing the ER stress.ConclusionIn summary, taurine was shown to protect PC12 cells against oxidative stress induced by H2O2. ER stress was induced by oxidative stress and can be suppressed by taurine.

The Upregulation of Cognate and Inducible Heat Shock Proteins in the Anoxic Turtle Brain

Because heat shock proteins (HSPs) have an important protective function against ischemia/anoxia in mammalian brain, the authors investigated the expression of Hsp72 and Hsc73 in the anoxia-surviving turtle brain. Unlike the mammalian brain, high levels of Hsp72 were found in the normoxic turtle brain. Hsp72 levels were significantly increased by 4 hours of anoxia, remained constant until 8 hours, and then decreased to baseline at 12 hours. By contrast, Hsc73 was progressively increased throughout 12 hours of anoxia. This differential expression suggests different protective roles: Hsp72 in the initial downregulatory transition phase, and Hsc73 in maintaining neural network integrity during the long-term hypometabolic phase.

Taurine and central nervous system disorders.

In the present era, investigators seek to find therapeutic interventions that are multifaceted in their mode of action. Such targets provide the most advantageous routes for addressing the multiplicity of pathophysiological avenues that lead to neuronal dysfunction and death observed in neurological disorders and neurodegenerative diseases. Taurine, an endogenous amino acid, exhibits a plethora of physiological functions in the central nervous system. In this review, we describe the mode of action of taurine and its clinical application in the neurological diseases: Alzheimer’s disease, Parkinson’s disease and Huntington’s disease.

Suppression of reactive oxygen species production enhances neuronal survival in vitro and in vivo in the anoxia-tolerant turtle Trachemys scripta

Hypoxia‐ischemia with reperfusion is known to cause reactive oxygen species‐related damage in mammalian systems, yet, the anoxia tolerant freshwater turtle is able to survive repeated bouts of anoxia/reoxygenation without apparent damage. Although the physiology of anoxia tolerance has been much studied, the adaptations that permit survival of reoxygenation stress have been largely ignored. In this study, we examine ROS production in the turtle striatum and in primary neuronal cultures, and examine the effects of adenosine (AD) on cell survival and ROS. Hydroxyl radical formation was measured by the conversion of salicylate to 2,3‐dihydroxybenzoic acid (2,3‐DHBA) using microdialysis; reoxygenation after 1 or 4 h anoxia did not result in increased ROS production compared with basal normoxic levels, nor did H2O2 increase after anoxia/reoxygenation in neuronally enriched cell cultures. Blockade of AD receptors increased both ROS production and cell death in vitro, while AD agonists decreased cell death and ROS. As turtle neurons proved surprisingly susceptible to externally imposed ROS stress (H2O2), we propose that the suppression of ROS formation, coupled to high antioxidant levels, is necessary for reoxygenation survival. As an evolutionarily selected adaptation, the ability to suppress ROS formation could prove an interesting path to investigate new therapeutic targets in mammals.