Kazuhiro Mawatari

Cystine/glutamate antiporter expression in retinal mu¨ller glial cells: Implications fordl-alpha-aminoadipate toxicity

A cytotoxicity of glutamate or related amino acids (10 mM) mediated by a cystine/glutamate antiporter (system Xc) has recently been demonstrated in N18 neuroblastoma-rat retina hybrid (N18RE105) cells and C6 glioma cells. The antiporter usually transports glutamate outside and cystine inside, thereby maintaining cellular concentrations of glutathione. High concentrations of glutamate inhibit cystine uptake and lead to depletion of cellular levels of glutathione. Among related amino acids, DL-alpha-aminoadipic acid (DL-alpha-AAA), which is well known as a selective gliotoxin in the retina, is also toxic to these cells. However, this does not explain why DL-alpha-AAA acts gliospecifically on the retina. To answer this question we first examined the effects of DL-alpha-AAA on the [35S]cystine uptake with parental N18 neuroblastoma cells and rat retina of the hybrid cells. DL-alpha-AAA showed a competitive inhibition of [35S]cystine uptake in the rat retina but not in the N18 cells. Such a competitive inhibition of cystine uptake by DL-alpha-AAA could also be seen in the carp retina. The cystine uptake with carp retina was mainly Na(+)-independent and Cl(-)-dependent as already described as a characteristic ion dependency of the Xc antiporter. We next examined the effects of exogenous cystine on the glutamate release from the retina. Cystine (1 mM) actually induced a glutamate release approximately twice that of the control. Furthermore, the glutamate release induced by cystine was also Na(+)-independent and Cl(-)-dependent, and was blocked by DL-alpha-AAA. An autoradiogram of [35S]cystine uptake in the carp retina showed typical radial glial Müller cells. A large incorporation of [35S]cystine into retinal glutathione fraction was detected by a high pressure liquid chromatography method during a 1-4-h incubation. A significant or large decrease of retinal levels of glutathione was observed one day ater an intravitreal injection of 8 mumol DL-alpha-AAA or L-alpha-AAA, respectively. Buthionine sulfoximine (2.5 mumol), a specific inhibitor of glutathione synthesis, induced a large decrease of retinal levels of glutathione and a loss of electroretinographic b-wave 20-30 h after treatment. Taken together, our present data with rat and carp retinas strongly indicate that the expression of cystine/glutamate antiporter is enriched in the retina, particularly in the glial Müller cells which have a rapid turnover pool for glutathione. The gliotoxin DL-alpha-AAA inhibits cystine uptake through this antiporter on the glial cells and elicits reduction of cellular levels of glutathione.(ABSTRACT TRUNCATED AT 400 WORDS)

Reactive oxygen species involved in the glutamate toxicity of C6 glioma cells via xc antiporter system.

We recently demonstrated that continuous L-glutamate exposure led to cell death in C6 glioma cells over a period of 24-36 h, due to inhibition of cystine uptake through the cystine/glutamate (XC) antiporter. The antioxidant vitamin E provided protection against this effect, supporting the hypothesis that depletion of glutathione might be responsible, resulting from insufficient cystine uptake. To clarify the content of oxidative stress after glutathione depletion, the present study was done to investigate accumulation and target molecules of reactive oxygen species induced by glutamate treatment. The accumulation of reactive oxygen species was increased three-fold as compared to a control culture. Membrane oxidation, as judged by lipid peroxidation, was increased two-fold after glutamate treatment. Cellular ATP content was significantly reduced by glutamate exposure. For the two cytosolic enzymes examined, activity of glyceraldehyde 3-phosphate dehydrogenase was slightly enhanced by glutamate treatment, while activity of glutamine synthetase was not changed. Impairment of nuclear DNA after glutamate exposure was also revealed by nuclear chromatin condensation with DNA fragmentation. Thus, the multiple targets (membrane, cytoplasm and nuclei) of oxygen radicals in glutamate toxicity through the xc antiporter system were evaluated for the first time. Furthermore, prevention from cell death and from cellular toxicity induced by oxygen radicals could be seen using three specific oxygen radical scavengers, catalase, 3,3,5,5-tetramethyl-pyrroline N-oxide and alpha-phenyl-N-t-butylnitrone, without restoring the glutathione deficit. This indicates that radical scavengers did not interact with the xc antiporter system, but directly scavenged the oxygen radicals. Taken together, the data strongly suggest that O2-, H2O2 and OH accumulate in response to oxidative stress after glutathione depletion, resulting in glutamate cell death of C6 glioma cells.

Early downregulation of IGF-I decides the fate of rat retinal ganglion cells after optic nerve injury

Retinal ganglion cells (RGCs) die by apoptosis after optic nerve injury. A number of reports have separately shown changes in pro-apoptotic proteins such as the Bcl-2 family members following optic nerve injury. However, induction time of these apoptotic signals has not been identified due to different treatments of the optic nerve, and insufficient time intervals for measurements. Therefore, the stream of cell death signals is not well understood. In the present study, we systematically reinvestigated a detailed time course of these cell death/survival signals in the rat retina after optic nerve crush, to determine the signal cascade leading to RGC apoptosis. The most conspicuous changes detected in the retina were the rapid inactivation of phospho-Akt and phospho-Bad proteins 2-3 days after optic nerve damage, and the subsequent gradual activation of Bax protein and caspase-3 activity accompanied by cell loss of RGCs 6 days after nerve injury. Cellular localization of these molecular changes was limited to RGCs. Furthermore, amount of insulin-like growth factor-I (IGF-I), an activator of the phosphatidyl inositol-3-kinase (PI3K)/Akt system, was initially decreased from RGCs 1-2 days just prior to the inactivation of phospho-Akt by optic nerve crush. Conversely, supplementation with IGF-I into the rat retina induced upregulation of phospho-Akt expression and cell survival of RGCs both in vitro and in vivo. Thus, injury to the optic nerve might induce early changes in cellular homeostasis with a plausible loss of trophic support for injured RGCs. Actually, IGF-I drastically enhanced neurite outgrowth from adult rat RGCs via a wortmannin-dependent mechanism in a retinal explant culture. Our data strongly indicate that IGF-I is a key molecule that induces RGC apoptosis or RGC survival and regeneration in the retina during the early stage of optic nerve injury.

Changes of phospho-growth-associated protein 43 (phospho-GAP43) in the zebrafish retina after optic nerve injury: A long-term observation

The major model animal of optic nerve regeneration in fish is goldfish. A closely related zebrafish is the most popular model system for genetic and developmental studies of vertebrate central nervous system. A few challenging works of optic nerve regeneration have been done with zebrafish. However, knowledge concerning the long term of optic nerve regeneration apparently lacks in zebrafish. In the present study, therefore, we followed changes of zebrafish behavior and phosphorylated form of growth-associated protein 43 (phospho-GAP43) expression in the zebrafish retina over 100 days after optic nerve transection. Optomotor response was fast recovered by 20-25 days after axotomy whereas chasing behavior (a schooling behavior) was slowly recovered by 80-100 days after axotomy. The temporal pattern of phospho-GAP43 expression showed a biphasic increase, a short-peak (12 folds) at 1-2 weeks and a long-plateau (4 folds) at 1-2 months after axotomy. The recovery of optomotor response well correlated with projection of growing axons to the tectum, whereas the recovery of chasing behavior well correlated with synaptic refinement of retinotectal topography. The present data strongly suggest that phospho-GAP43 plays an active role in both the early and late stages of optic nerve regeneration in fish.

Role of Purpurin as a Retinol-Binding Protein in Goldfish Retina during the Early Stage of Optic Nerve Regeneration: Its Priming Action on Neurite Outgrowth

Unlike mammals, the fish optic nerve can regenerate after injury. So far, many growth or trophic factors have been shown as an axon-regenerating molecule. However, it is totally unknown what substance regulates or triggers the activity of these factors on axonal elongation. Therefore, we constructed a goldfish retina cDNA library prepared from the retina treated with optic nerve transection 5 d previously, when it was just before regrowing optic axons after injury. A cDNA clone for goldfish purpurin for which expression was upregulated during the early stage of optic nerve regeneration was isolated from the retina cDNA library. Purpurin was discovered as a secretory retinol-binding protein in developing chicken retinas. Levels of purpurin mRNA and protein transiently increased and rapidly decreased 2–5 d and 10 d after axotomy, respectively. Purpurin mRNA was localized to the photoreceptor cells, whereas the protein was diffusely found in all of the retinal layers. A recombinant purpurin alone did not affect any change of neurite outgrowth in explant culture of the control retina, whereas a concomitant addition of the recombinant purpurin and retinol first induced a drastic enhancement of neurite outgrowth. Furthermore, the action of retinol-bound purpurin was effective only in the control (untreated) retinas but not in those primed (treated) with a previous optic nerve transection. Thus, purpurin with retinol is the first candidate molecule of priming neurite outgrowth in the early stage of optic nerve regeneration in fish.

Nitric oxide-cGMP signaling regulates axonal elongation during optic nerve regeneration in the goldfish in vitro and in vivo.

Nitric oxide (NO) signaling results in both neurotoxic and neuroprotective effects in CNS and PNS neurons, respectively, after nerve lesioning. We investigated the role of NO signaling on optic nerve regeneration in the goldfish (Carassius auratus). NADPH diaphorase staining revealed that nitric oxide synthase (NOS) activity was up‐regulated primarily in the retinal ganglion cells (RGCs) 5–40 days after axotomy. Levels of neuronal NOS (nNOS) mRNA and protein also increased in the RGCs alone during this period. This period (5–40 days) overlapped with the process of axonal elongation during regeneration of the goldfish optic nerve. Therefore, we evaluated the effect of NO signaling molecules upon neurite outgrowth from adult goldfish axotomized RGCs in culture. NO donors and dibutyryl cGMP increased neurite outgrowth dose‐dependently. In contrast, a nNOS inhibitor and small interfering RNA, specific for the nNOS gene, suppressed neurite outgrowth from the injured RGCs. Intra‐ocular dibutyryl cGMP promoted the axonal regeneration from injured RGCs in vivo. None of these molecules had an effect on cell death/survival in this culture system. This is the first report showing that NO‐cGMP signaling pathway through nNOS activation is involved in neuroregeneration in fish CNS neurons after nerve lesioning.

Involvement of retinoic acid signaling in goldfish optic nerve regeneration.

Recently, we identified a retina-specific retinol-binding protein, purpurin, as a trigger molecule in the early stage of goldfish optic nerve regeneration. Purpurin protein was secreted by photoreceptors to injured ganglion cells, at 2-5 days after optic nerve injury. Purpurin bound to retinol induced neurite outgrowth in retinal explant cultures and retinoic acid (RA) had a comparable effect on neurite outgrowth. These results indicate that purpurin acts as a retinol transporter and facilitates conversion of retinol to RA. Intracellularly, RA is transported into the nucleus with cellular retinoic acid-binding protein IIb (CRABPIIb) and binds with retinoic acid receptor alpha (RARalpha) as a transcriptional regulator of target genes. Here, we investigated the RA signaling through RA synthesis to RARalpha in the goldfish retina during optic nerve regeneration by RT-PCR. Retinaldehyde dehydrogenase 2 (RALDH2; an RA synthetic enzyme) mRNA was increased by 2.7-fold in the retina at 7-10 days and then gradually decreased until 40 days after nerve injury. In contrast, cytochrome P450 26a1 (CYP26a1; an RA degradative enzyme) mRNA was decreased to less than half in the retina at 5-20 days and then gradually returned to the control level by 40 days after nerve injury. CRABPIIb mRNA was increased by 1.5-fold in the retina at 10 days after axotomy, RARalphaa mRNA was increased by 1.8-fold in the retina at 10 days after axotomy. The cellular changes in the RA signaling molecules after optic nerve injury were almost all located in the ganglion cells, as evaluated by in situ hybridization. The present data described for the first time that RA signaling through RALDH2 and CRABPIIb to RARalpha was serially upregulated in the ganglion cells at 7-10 days just after the purpurin induction. Therefore, we conclude that the triggering action of purpurin on optic nerve regeneration is mediated by RA signaling pathway.

Na,K-ATPase α3 subunit in the goldfish retina during optic nerve regeneration

The goldfish optic nerve can regenerate after injury. To understand the molecular mechanism of optic nerve regrowth, we identified genes whose expression is specifically up‐regulated during the early stage of optic nerve regeneration. A cDNA library constructed from goldfish retina 5 days after transection was screened by differential hybridization with cDNA probes derived from axotomized or normal retina. Of six cDNA clones isolated, one clone was identified as the␣Na,K‐ATPase catalytic subunit α3 isoform by high‐ sequence homology. In northern hybridization, the expression level of the mRNA was significantly increased at 2 days and peaked at 5–10 days, and then gradually decreased and returned to control level by 45 days after optic nerve transection. Both in situ hybridization and immunohistochemical staining have revealed the location of this transient retinal change after optic nerve transection. The increased expression was observed only in the ganglion cell layer and optic nerve fiber layer at 5–20 days after optic nerve transection. In an explant culture system, neurite outgrowth from the retina 7 days after optic nerve transection was spontaneously promoted. A low concentration of ouabain (50–100 nm) completely blocked the spontaneous neurite outgrowth from the lesioned retina. Together, these data indicate that up‐regulation of the Na,K‐ATPase α3 subunit is involved in the regrowth of ganglion cell axons after axotomy.

Tryptophan fluorescence of human hemoglobin. I. Significant change of fluorescence intensity and lifetimes in the T − R transition

Abstract The fluorescence spectra and fluorescence lifetimes due to tryptophan residues in HbA, Hb Chesapeake, NES-des-Arg Hb and Hb Kempsey were determined at room temperature. The fluorescence intensity and apparent fluorescence lifetimes decrease when the deoxy or T structure in HbA changes to the oxy or R structure, while no significant difference was observed in Hb Kempsey. The difference of fluorescence behavior was ascribed to the quaternary conformational transition of T- and R-states.

HSP70, the earliest-induced gene in the zebrafish retina during optic nerve regeneration: Its role in cell survival

Fish retinal ganglion cells (RGCs) can survive and regrow their axons after optic nerve injury. Injured RGCs express anti-apoptotic proteins, such as Bcl-2, after nerve injury; however, upstream effectors of this anti-apoptotic protein are not yet fully understood. Heat shock proteins (HSPs) play a crucial role in cell survival against various stress conditions. In this study, we focused on HSP70 expression in the zebrafish retina after optic nerve injury. HSP70 mRNA and protein levels increased rapidly 2.3-fold in RGCs by 1-6 h after injury and returned to control levels by 1-3 days. HSP70 transcription is regulated by heat shock factor 1 (HSF1). HSF1 mRNA and phosphorylated-HSF1 protein rapidly increased by 2.2-fold in RGCs 0.5-6 h after injury. Intraocular injection of HSP inhibitor I significantly suppressed the induction of HSP70 expression after nerve injury. It also suppressed Bcl-2 protein induction and resulted in TUNEL-positive cell death of RGCs at 5 days post-injury. Zebrafish treated with HSP inhibitor I retarded axonal elongation or visual function after injury, as analyzed by GAP43 expression and behavioral analysis of optomotor response, respectively. These results strongly indicate that HSP70, the earliest induced gene in the zebrafish retina after optic nerve injury, is a crucial factor for RGCs survival and optic nerve regeneration in fish.