Ayami Nakazawa

Presence of molecular chaperones, heat shock cognate (Hsc) 70 and heat shock proteins (Hsp) 40, in the postsynaptic structures of rat brain.

The synaptic localization of molecular chaperones, heat shock cognate protein 70 (Hsc70) and Hsp40, was investigated immunohistochemically in the normal rat brain. Postsynaptic density (PSD) fractions contained a constitutive form of HSP70, heat shock cognate protein 70 (Hsc70 or p73) but not inducible form of HSP70 (p72). The immunoreactivities of Hsc70 (p73) were distributed throughout the rat brain, in neuronal somata, dendrites and axons. Their immunoreactivity in neurons was localized in the cytoplasmic matrix, dendrites, and spines at the electron microscopic level. Presynaptic terminals, but less frequently than postsynaptic staining, were also reactive. Postsynaptic areas immediately beneath the synaptic contact or PSDs were immunoreactive for Hsc70. The Hsp40 was highly concentrated in PSD fractions. The staining of Hsp40 immunoreactivity was punctate and distributed widely in the brain. Hsp40 immunoreactivity was localized in dendritic spines, especially in the subsynaptic web, with weak staining of PSDs at the electron microscopic level. Double immunofluorescent staining and confocal microscopy revealed that Hsc70 and Hsp40 were co-localized on somata and neuronal processes of cultured cerebral neurons, on which synaptophysin immunoreactive spots were scattered. These results suggest that Hsp40 and Hsc70 are co-localized at postsynaptic sites and postsynaptic chaperone activity may be mediated by these two heat shock proteins.

Modification of Endothelial NO Synthase Through Protein Phosphorylation After Forebrain Cerebral Ischemia/Reperfusion

Background and Purpose— Production of NO by endothelial NO synthase (eNOS) is thought to play a neuroprotective role after cerebral ischemia. The vascular endothelial growth factor (VEGF) contributes to activation of eNOS by Ca2+/calmodulin and also stimulates the protein kinase Akt, which directly phosphorylates eNOS on Ser1177 and increases enzyme activity. Although the expression of VEGF has been studied in ischemic stroke models, the activation of eNOS after cerebral ischemia has not been investigated. The purpose of the present study was to clarify molecular mechanisms underlying the regulation of eNOS activity through protein phosphorylation in postischemic processes. Methods— Sprague-Dawley rats were subjected to forebrain cerebral ischemia for 15 minutes with hypotension and reperfusion for up to 24 hours. Western blot analysis and ELISAs were used to study the temporal profiles of Akt, phospho-Akt at Ser437, eNOS, phospho-eNOS at Ser1177, and VEGF expression, respectively. Immunohistochemical studies were performed to examine the spatial expression patterns of phospho-Akt at Ser437 and phospho-eNOS at Ser1177. Results— Increase in phospho-Akt at Ser437 was observed transiently 0.5 to 2 hours after reperfusion, whereas elevation of phospho-eNOS at Ser1177 and VEGF expression was observed from 6 hours after reperfusion. Endothelial cells in the microvessels were the major source of eNOS phosphorylated at Ser1177 at the 12-hour time point. Conclusions— Increase in Ser1177 phospho-eNOS occurs in endothelial cells of microvessels after ischemic episodes with temporal expression of VEGF, pointing to a contribution to the autoregulation of postischemic brain damage.

Localization of Calcineurin in the Mature and Developing Retina

SUMMARY We studied the localization of calcineurin by immunoblotting analysis and immunohistochemistry as a first step in clarifying the role of calcineurin in the retina. Rat, bovine, and human retinal tissues were examined with subtype-nonspecific and subtype-specific antibodies for the Aα and Aβ isoforms of its catalytic subunit. In mature retinas of the three species, calcineurin was localized mainly in the cell bodies of ganglion cells and the cells in the inner nuclear layer, in which amacrine cells were distinctively positive. The calcineurin Aα and Aβ isoforms were differentially localized in the nucleus and the cytoplasm of the ganglion cell, respectively. Calcineurin was also present in developing rat retinas, in which the ganglion cells were consistently positive for it. The presence of calcineurin across mammalian species and regardless of age shown in the present study may reflect its importance in visual function and retinal development, although its function in the retina has not yet been clarified. (J Histochem Cytochem 49:187–195, 2001)

Expression Pattern and Gene Structure of Phenylalanine Ammonia-Lyase in Pharbitis nil

PAL gene expression were examined in flower buds and irradiated hypocotyls in Pharbitis nil. PAL activity and transcript levels were correlated with the accumulation of anthocyanin. Both in flower buds and hypocotyls, transcript levels, PAL activity, and then the amount of anthocyanin, increased. The PAL transcript was abundant in flower buds for a few days before flower opening. But the increase in PAL transcript induced by irradiation was temporal in hypocotyls. Phytochrome was shown to be involved in inducing the accumulation of anthocyanin in hypocotyls. To examine the mechanism regulating the expression of the PAL gene, the gene was cloned and sequenced, and the promoter region was compared with that of other PALs. The gene had two exons separated by an intron of 989 bp with consensus sequences at the intron/exon border. The predicted primary structure of the PAL protein consists of 711 amino acids. The promoter region was AT-rich and there were sequences similar to box 1, box 2, an AT-1 binding site and a G box. The role of PAL in the accumulation of anthocyanin is discussed.

Immunohistochemical Localization of Peroxisomal Enzymes in Developing Rat Kidney Tissues

We studied the developmental changes in the localization of peroxisome-specific enzymes in rat kidney tissues from embryonic Day 16 to postnatal Week 10 by immunoblot analysis and immunohistochemistry, using antibodies for the peroxisomal enzymes catalase, d-amino acid oxidase, L-α-hydroxyacid oxidase (isozyme B), and enoyl-CoA hydratase/3-hydroxyacyl-CoA dehydrogenase bifunctional protein. Peroxisomal enzymes were detected in the neonatal kidney by immunoblot analysis and their amount increased with kidney development. By light microscopic immunohistochemistry, they were first localized in a few proximal tubules in the juxtamedullary cortex of 18-day embryos. The distribution of proximal tubules positive for them expanded towards the superficial cortex with development. The full thickness of the cortex became positive for the staining by 14 days after birth. Peroxisomes could be detected by electron microscopy in structurally immature proximal tubules in 18-day embryos. Their size increased and the ultrastructure of subcompartments became clear with continuing development of proximal tubules. These results show that peroxisomal enzymes appear in the immature proximal tubules in the kidney of embryos and that the ultrastructure of the peroxisomes and localization of the peroxisomal enzymes develop along with the maturation of proximal tubules and kidney tissues.

Immunoelectron Microscopy of Peroxisomes Employing the Antibody for the SKL Sequence PTS1 C-terminus Common to Peroxisomal Enzymes

Immunohistochemistry employing a new hapten antibody that detects the SKL sequence and its variants of the PTS1 C-terminus of peroxisomal enzymes was attempted to visualize peroxisomes across species. Rabbits were immunized with the SKL sequence coupled with KLH, between which an arm molecule was interposed. IgG fractions of antisera were affinity-purified against the hapten and employed for immunochemical analyses and immunoelectron microscopy. The specificity of the antibody was examined by immunoblot analyses for various purified enzymes of rat liver peroxisomes and by dot-blot analyses inhibited by SKL peptide and its variants. Various animal and plant tissues were subjected to immunoelectron microscopy with the protein A-gold technique. The antibody reacted with various enzymes in the peroxisome with the SKL motif. The affinity of the antibody for tripeptides, which varied depending on their structures, was higher for SKL than for its variants. Hepatic and renal peroxisomes of vertebrates, peroxisomes in the fat body of an insect, and the cotyledon of a plant were visualized by immunoelectron microscopy. Immunohistochemistry employing this SKL antibody may provide specific staining that can detect peroxisomes across different species.

Quantification of Protein A-Gold Staining for Peroxisomal Enzymes by Confocal Laser Scanning Microscopy

The protein A-gold technique has been widely applied for visual localization and quantification of various antigens by electron microscopy. Observation of specimens stained by the protein A-gold technique with conventional light microscopy is difficult because of insufficient sensitivity of the staining. Light microscopic visualization and quantification of the reaction products were attempted employing a confocal laser scanning microscope (CLSM). Liver tissues of normal and peroxisome proliferator-treated rats were fixed and embedded in Lowicryl K4M resin. Ultrathin and thin sections were stained for catalase and a peroxisome-specific β-oxidation enzyme by the protein A-gold technique. Ultrathin sections were observed by electron microscopy and the labeling density for each enzyme was analyzed with an image analyzer. Thin sections were observed with a CLSM in the reflection mode and the intensity of the light reflection was analyzed under the same conditions for all specimens. A comparison of these two observation procedures was also attempted using liver tissues stained with various concentrations of the antibody for catalase. The intensity of the reflection for each, as observed by CLSM, correlated well with the labeling density observed by electron microscopy. CLSM made it possible to quantify and to directly observe protein A-gold staining at the light microscopic level.

Peroxisomes in permanent and provisional kidneys. Phylogenic and ontogenic considerations.

Peroxisomes in three forms of vertebrate kidney (pronephros, mesonephros, and metanephros), as permanent or provisional kidney, are summarized concerning their ultrastructure and developmental changes. Because the peroxisome is known to be diverse in mammalian metanephros, and species difference is its distinctive feature among cell organelles, information should be obtained on each kidney of each species. The ultrastructural and biochemical features of peroxisomes have at least been partly delineated in the metanephros and mesonephros, but nothing is known about the pronephros. Ultrastructural studies of the metanephric peroxisomes are present in mammals, birds, and reptiles, but information on their development is restricted to mammals and birds. As for the mesonephric peroxisomes, both ultrastructural and developmental data have been accumulating on mammals and amphibians, and ultrastructural information is present on fishes, but not on birds and reptiles. At present, studies on peroxisomes of provisional kidney have been restricted to mammalian mesonephros. The common features of renal peroxisomes previously examined are that they are spherical cell organelles with a single limiting membrane in ultrastructure, and are positive for catalase. Information on the ultrastructure and enzymes is not sufficient at present for comparing the ontogenesis of renal peroxisomes with their phylogenesis.