Ischemia increases prostaglandin H synthase-2 levels in retina and visual cortex in piglets.

BACKGROUND: Ischemia increases levels of prostaglandin H synthase-2 (PGHS-2) in neonatal brain and cerebral vasculature, but effects on the developing visual system are unknown. We examined the effects of ischemia on PGHS-2 mRNA and protein levels in the retina and visual cortex in anesthetized piglets. METHODS: Ten minutes of complete retinal and brain ischemia was induced by increasing intracranial pressure. After 2-12 h of reperfusion, samples of retina and visual cortex were collected for determinations of levels of PGHS-2 mRNA (RNase protection assay) or protein (immunohistochemistry and western blotting). Tissues also were obtained from control animals. RESULTS: Levels of PGHS-2 mRNA were undetectable in control animals but showed a dramatic increase at 2-4 h in the cortex and retina in animals exposed to ischemia. Detectable but limited PGHS-2 immunoreactivity (IR) was present in the retina and visual cortex from control animals. In piglets not subjected to ischemia, PGHS-2 IR was localized mainly to the outer limiting membrane and to the Muller cells. Ischemia induced a marked increase in PGHS-2 IR in the neural retina, with the greatest increase in the photoreceptor layer. PGHS-2 levels in whole retina also increased at 8 h after ischemia. In the intact visual cortex PGHS-2 IR was evident in layers II and V. Ischemia increased the intensity of IR in layers II/III as well as layer V. CONCLUSIONS: Detectable amounts of PGHS-2 protein are present in the piglet retina and visual cortex under normal conditions, but levels are markedly increased 8-12 h after ischemic stress. Enhanced PGHS-2 levels after ischemic stress may contribute to delayed pathological changes of the visual system in the neonate.

Effects of ischemia on prostaglandin H synthase-2 expression in piglet choroid plexus.

We examined effects of ischemia on expression of prostaglandin H synthase-1 (PGHS-1) and prostaglandin H synthase-2 (PGHS-2) in piglet choroid plexus. Ten minutes of ischemia was induced by increasing intracranial pressure. Whole choroid plexus was removed and fixed and/or frozen after 1, 2, 4, and 8 h of recovery from anoxic stress. In addition, tissues were obtained from untreated animals or from time control animals. Tissues were analyzed for mRNA, using RNase protection assays, and for proteins, using immunohistochemical approaches. Limited, but detectable PGHS-2 immunoreactivity was present in choroid plexus under normal conditions, and there was no difference between time-control and non-treated animals. Further, PGHS-2 mRNA increased by 2-4 h after ischemia, and enhanced immunoreactivity for PGHS-2 was present at 8 h after ischemia. Enhanced immunoreactivity for PGHS-2 was present in vascular endothelial cells as well as cuboidal epithelial cells and macrophages. In contrast, PGHS-1 mRNA did not increase following ischemia. We conclude that PGHS-2 is present in piglet choroid plexus under normal conditions and that ischemia increases levels of PGHS-2 in choroid plexus.

Effects of anoxic stress on prostaglandin H synthase isoforms in piglet brain.

We examined effects of ischemia and asphyxia on levels of prostaglandin H synthase-1 (PGHS-1) and prostaglandin H synthase-2 (PGHS-2) in piglet brain. Ischemia was induced by increasing intracranial pressure and asphyxia was induced by turning off the respirator. Duration of anoxic stress was 10 min. In some animals, indomethacin (5 mg/kg, i.v.) or 7-nitroindazole (7-NI) was administered prior to ischemia to block PGHS or brain nitric oxide synthase (bNOS), respectively. Tissues from cerebral cortex and hippocampus were removed and fixed and/or frozen after 1, 2, 4 and 8 h of recovery from anoxic stress. In addition, tissues were obtained from untreated animals or from time control animals. Levels of mRNA and proteins were determined using RNase protection assay and immunohistochemical approaches, respectively. In the tissues studied, only a few neurons were immunopositive for PGHS-1, and neither ischemia or asphyxia affected PGHS-1 immunostaining at 8 h after recovery. Likewise, PGHS-1 mRNA did not increase following anoxic stress. In contrast, substantial PGHS-2 immunoreactivity was present in neurons and glial cells in the cerebral cortex and hippocampus and there was no difference between time control and non treated animals. PGHS-2 mRNA increased by 2-4 h after ischemia, and heightened immunoreactivity for PGHS-2 was present at 8 h after ischemia in cerebral cortex and hippocampus. However, asphyxia did not increase PGHS-2 mRNA or immunostaining. Indomethacin pretreatment inhibited increases in mRNA and protein for PGHS-2 after ischemia, while 7-NI had little effect on increases in PGHS-2 immunoreactivity. We conclude that: (1) PGHS-2 is the predominant isoform present in piglet cerebral cortex and hippocampus; (2) Ischemia but not asphyxia increases levels of PGHS-2; (3) Ischemia does not increase levels of PGHS-1; and (4) Indomethacin but not 7-NI attenuates ischemia-induced increases in PGHS-2.

Regional distribution of prostaglandin H synthase-2 and neuronal nitric oxide synthase in piglet brain.

Immunohistochemical techniques were used to examine the distribution of prostaglandin H synthase (PGHS)-2 and neuronal nitric oxide synthase (nNOS) in piglet brain. Samples from parietal cortex, hippocampus, and cerebellum were immersion fixed in 10% formalin, sectioned at 50 microm, and immunostained using specific antibodies against PGHS-2 and nNOS. Immunoreactivity for PGHS-2 was extensive throughout the areas examined. For example, PGHS-2 immunoreactive cells were present in all layers of the cortex, but were particularly dense among neurons in layers II/II, V, and VI. In addition, glial cells associated with microvessels in white matter showed PGHS-2 immunoreactivity. In contrast, nNOS immunoreactive neurons were limited in number and widely dispersed across all layers of the cortex and thus did not form a definable pattern. In the hippocampus, heavy PGHS-2 immunoreactivity was present in neurons and glial cells in the subgranular region, stratum radiatum, adjacent to the hippocampal sulcus, and in CA1 and CA3 pyramidal cells. Immunostaining for nNOS displayed a different pattern from PGHS-2 in the hippocampus, and was mainly localized to the granule cell layer of the dentate gyrus and the mossy fiber layer. In the cerebellum, PGHS-2 immunoreactivity was heavily represented in the Bergmann glia and to a lesser extent in cells of the granular layer, whereas nNOS was detected only in Basket cells. There are four conclusions from this study. First, PGHS-2 immunoreactivity is widely represented in the cerebral cortex, hippocampus, and cerebellum of neonatal pigs. Second, glia cells as well as neurons can show immunoreactivity for PGHS-2. And third, the distribution of nNOS is different from PGHS-2 immunoreactivity in the cerebral cortex, hippocampus, and cerebellum.

Indomethacin attenuates early increases in inducible heat shock protein 70 after cerebral ischemia/reperfusion in piglets.

Indomethacin-sensitive mechanisms involved in inducible heat shock protein 70 (iHSP 70) synthesis were investigated at 6 h after global cerebral ischemia in parietal cortex and hippocampus. In anesthetized piglets, increased intracranial pressure was used to produce 5 or 10 min of cerebral ischemia. Brain regions were sampled for immunoblot analysis, immunohistochemistry and morphology. Immunoblots revealed differential expression of iHSP 70 in untreated brains. Cerebellum contained substantial amounts of iHSP 70 while lower levels were present in parietal cortex and hippocampus. Detectable increases in iHSP 70 were observed at 2 h after ischemia in parietal cortex and hippocampus. Using immunoblot data, calculation of percent change from control at 6 h after ischemia revealed significant (p < 0.05) increases in iHSP 70 of 111 +/- 39% (x +/- sem) (n = 6) in parietal cortex and 195 +/- 69% (n = 8) in hippocampus. Increased iHSP 70 immunoreactivity occurred primarily in the granular/subgranular area of the dentate gyrus 6 h after ischemia. Histological staining revealed little cellular injury at 6 h after ischemia in the granular/subgranular region injury whereas the CA3 region, which lacked iHSP 70 staining, displayed modest cellular injury. Cellular injury was also observed in cortical layers II/III and VI. At 6 h after ischemia, indomethacin pretreatment (5 mg/kg, i.v.) attenuated the iHSP 70 increases in parietal cortex and hippocampus (7 +/- 30% and 89 +/- 30%, respectively n = 5; p < 0.05 compared to ischemia). Also, the increase in iHSP 70 immunoreactivity and appearance of cellular injury were not detected with indomethacin pretreatment. Thus, prior administration of indomethacin is associated with attenuation of ischemia-induced increases in iHSP 70 and cellular injury.

In vitro and in vivo localization of prostaglandin H synthase in fetal sheep neurons.

Immunoreactive (IR) prostaglandin H synthase (PGHS) was evident in primary cortical cultures as early as day 2 after seeding. Labeling did not increase with time in culture, nor was there an apparent difference in IR intensity between 2 and 10% serum cultures or between glial and neuronal figures. PGHS-1 IR appeared as a homogeneous cytoplasmic fluorescence compared with PGHS-2 IR which tended to be more intense, particulate and exclusively perinuclear. PGHS-2(+) IR in both neurons and glia increased with time in culture. Immunofluorescence varied in intensity, but no significant degree of variation was seen between cell types. Neuronal PGHS-2 IR extended into processes and amassed in growth cones and at the leading edge processes of astrocytes. Novel rosette formations, possibly lipid bodies, were common in cultured neurons, but not astrocytes.

Cerebral ischemia/reperfusion increases endothelial nitric oxide synthase levels by an indomethacin-sensitive mechanism.

In anesthetized piglets, endothelial and neuronal nitric oxide synthase (eNOS and nNOS, respectively) levels were investigated after global cerebral ischemia. Increased intracranial pressure was used to produce 5 or 10 minutes of global ischemia, which was verified visually by observing pial arteriolar blood flow and by a microsphere technique. At 4 to 6 hours of reperfusion, parietal cortex, hippocampus, and cerebellum were collected for immunohistochemical or immunoblot analysis. Immunohistochemical examination localized eNOS only to blood vessels and nNOS only to nonvascular cells, which were primarily neurons in all regions examined. Analysis of immunoblot data revealed significant increases in eNOS levels from 47 +/- 22 pixels/micrograms protein for time controls to 77 +/- 36 pixels/micrograms protein (75% increase) for ischemia in parietal cortex (n = 9 to 10) and 22 +/- 10 for control to 40 +/- 16 pixels/micrograms protein (40% increase) for ischemia in hippocampus (n = 7 to 8). Levels of eNOS in cerebellum also tended to be higher but were variable and not significant (n = 5 to 6). In contrast, changes in nNOS levels were not detected at 4 or 6 hours. The increase in eNOS levels detected on immunoblots also was apparent on tissue sections as an increase in intensity of staining. Cyclooxygenase-dependent mechanisms were investigated with respect to the ischemia-induced increase in eNOS levels. Pretreatment with the cyclooxygenase inhibitor indomethacin (5 mg/kg intravenously) abolished the ischemia-induced eNOS increase in parietal cortex and hippocampus (n = 7). Thus, we conclude that the eNOS response is rapid, specific to vessels, and involves an indomethacin-sensitive mechanism.

Heat shock protein 70 in the retina of Xenopus laevis, in vivo and in vitro: effect of metabolic stress.

We utilized the frog eyecup as an in vitro model to compare heat-shock protein 70 (hsp70) synthesis in untreated retinas and in hyperthermia-, arsenite-, or glutamate-treated retinas. Hsp70-like immunoreactivity in vivo was concentrated in the photoreceptors in a pattern that was basically unchanged throughout the light/dark cycle. Retinas from eyecups in culture displayed the same immunoreactivity pattern as those in vivo except for a rapid, transient increase in immunoreactivity surrounding the photoreceptor nuclei. The immunoreactivity pattern in heat-treated retinas was similar to that of controls, but overall intensity was greatest in the outer plexiform layer. Arsenite-treated retinas displayed hsp70-like immunoreactivity in a pattern that was also like that of control retinas. Glutamate exposure resulted in increased hsp70-like immunoreactivity not only in the inner segments and outer plexiform layer, but also in photoreceptor nuclei. Gel fluorography of 35S-methionine-labeled proteins from heat- and arsenite-stressed retinas demonstrated increased synthesis of one or two proteins of approximately 70 kD and one protein of approximately 90 kD. Exposure of eyecups to glutamate did not result in detectable changes in protein synthesis. Following exposure to heat or glutamate, the retinas displayed swelling of the inner plexiform layer (IPL) as well as pyknotic nuclei in the inner nuclear layer. Exposure of eyecups to arsenite caused clumping of the melanin granules of the retinal pigmented epithelium (RPE) but not IPL swelling or pyknotic nuclei. We have shown that the stress response can be manipulated successfully in the in vitro Xenopus retina and that the pattern of the response depends on the nature of the stressor.

Comparative effects of cytosine arabinoside and a prostaglandin E2 antagonist, AH6809, on chondrogenesis in serum-free cultures of chick limb mesenchyme.

The present study was designed to compare effects of an established inhibitor of cell proliferation and growth, cytosine arabinoside (Ara C), with that of a prostaglandin E2 (PGE2) antagonist, AH6809, on chondrogenesis in cultured mesenchyme derived from stage 25 chick limb buds. Continuous treatment of cell cultures with 10(-4) M AH6809 prevented completely the twofold increases in DNA content of control cultures which occurred between Day 1 and Day 5 of culture and also produced 90% inhibition of chondrogenesis occurring in control cultures during this same period. Treatment of cells with Ara C (0.1-0.5 microgram/ml) produced equivalent inhibition of DNA content during the same time period; however, chondrogenesis, as evaluated on Day 5 of cell culture, remained at approximately 90% of control cultures. These results indicate that the inhibitory effect of PGE2 receptor blockade on cell growth in these cultures cannot account for the potent inhibitory effects observed on differentiation of cartilage and provide further evidence in support of the notion that PGE2 plays an important initiating role in the process of chondrocyte differentiation within limb mesenchyme.