SET8 Inhibition Potentiates Radiotherapy by Suppressing DNA Damage Repair in Carcinomas

OBJECTIVE

SET8 is a member of the SET domain-containing family and the only known lysine methyltransferase (KMT) that monomethylates lysine 20 of histone H4 (H4K20me1). SET8 has been implicated in many essential cellular processes, including cell cycle regulation, DNA replication, DNA damage response, and carcinogenesis. There is no conclusive evidence, however, regarding the effect of SET8 on radiotherapy. In the current study we determined the efficacy of SET8 inhibition on radiotherapy of tumors and the underlying mechanism.

METHODS

First, we explored the radiotherapy benefit of the SET8 expression signature by analyzing clinical data. Then, we measured a series of biological endpoints, including the xenograft tumor growth in mice and apoptosis, frequency of micronuclei, and foci of 53BP1 and γ-H2AX in cells to detect the SET8 effects on radiosensitivity. RNA sequencing and subsequent experiments were exploited to verify the mechanism underlying the SET8 effects on radiotherapy.

RESULTS

Low expression of SET8 predicted a better benefit to radiotherapy in lung adenocarcinoma (LUAD) and invasive breast carcinoma (BRCA) patients. Furthermore, genetic deletion of SET8 significantly enhanced radiation treatment efficacy in a murine tumor model, and A549 and MCF7 cells; SET8 overexpression decreased the radiosensitivity. SET8 inhibition induced more apoptosis, the frequency of micronuclei, and blocked the kinetics process of DNA damage repair as 53BP1 and γ-H2AX foci remained in cells. Moreover, RNF8 was positively correlated with the SET8 impact on DNA damage repair.

CONCLUSION

Our results demonstrated that SET8 inhibition enhanced radiosensitivity by suppressing DNA damage repair, thus suggesting that SET8 potentiated radiotherapy of carcinomas. As new inhibitors of SET8 are synthesized and tested in preclinical and clinical settings, combining SET8 inhibitors with radiation warrants consideration for precise radiotherapy.

Meso-scale Discovery Assay Detects the Changes of Plasma Cytokine Levels in Mice after Low or High LET Ionizing Irradiation

OBJECTIVE

To obtain precise data on the changes in the levels of 29 cytokines in mice after high or low linear energy transfer (LET) irradiation and to develop an accurate model of radiation exposure based on the cytokine levels after irradiation.

METHODS

Plasma samples harvested from mice at different time points after carbon-ion or X-ray irradiation were analyzed using meso-scale discovery (MSD), a high-throughput and sensitive electrochemiluminescence measurement technique. Dose estimation equations were set up using multiple linear regression analysis.

RESULTS

The relative levels of IL-6 at 1 h, IL-5 and IL-6 at 24 h, and IL-5, IL-6 and IL-15 at 7 d after irradiation with two intensities increased dose-dependently. The minimum measured levels of IL-5, IL-6 and IL-15 were up to 4.0076 pg/mL, 16.4538 pg/mL and 0.4150 pg/mL, respectively. In addition, dose estimation models were established and verified.

CONCLUSIONS

The MSD assay can provide more accurate data regarding the changes in the levels of the cytokines IL-5, IL-6 and IL-15. These cytokines could meet the essential criteria for radiosensitive biomarkers and can be used as radiation indicators. Our prediction models can conveniently and accurately estimate the exposure dose in irradiated organism.

MMP Inhibitor Ilomastat Improves Survival of Mice Exposed to γ-Irradiation

There is still a need for better protection against or mitigation of the effects of ionizing radiation following conventional radiotherapy or accidental exposure. The objective of our current study was to investigate the possible roles of matrix metalloproteinase inhibitor, ilomastat, in the protection of mice from total body radiation (TBI), and the underlying protective mechanisms. Ilomastat treatment increased the survival of mice after TBI. Ilomastat pretreatment promoted recovery of hematological and immunological cells in mice after 6 Gy γ-ray TBI. Our findings suggest the potential of ilomastat to protect against or mitigate the effects of radiation.

Irradiation Response of Adipose-derived Stem Cells under Three-dimensional Culture Condition

OBJECTIVE

Adipose tissue distributes widely in human body. The irradiation response of the adipose cells in vivo remains to be investigated. In this study we investigated irradiation response of adipose-derived stem cells (ASCs) under three-dimensional culture condition.

METHODS

ASCs were isolated and cultured in low attachment dishes to form three-dimensional (3D) spheres in vitro. The neuronal differentiation potential and stem-liked characteristics was monitored by using immunofluoresence staining and flow cytometry in monolayer and 3D culture. To investigate the irradiation sensitivity of 3D sphere culture, the fraction of colony survival and micronucleus were detected in monolayer and 3D culture. Soft agar assays were performed for measuring malignant transformation for the irradiated monolayer and 3D culture.

RESULTS

The 3D cultured ASCs had higher differentiation potential and an higher stem-like cell percentage. The 3D cultures were more radioresistant after either high linear energy transfer (LET) carbon ion beam or low LET X-ray irradiation compared with the monolayer cell. The ASCs' potential of cellular transformation was lower after irradiation by soft agar assay.

CONCLUSION

These findings suggest that adipose tissue cell are relatively genomic stable and resistant to genotoxic stress.

Irreversible aggregation of protein synthesis machinery after focal brain ischemia

Focal brain ischemia leads to a slow type of neuronal death in the penumbra that starts several hours after ischemia and continues to mature for days. During this maturation period, blood flow, cellular ATP and ionic homeostasis are gradually recovered in the penumbral region. In striking contrast, protein synthesis is irreversibly inhibited. This study used a rat focal brain ischemia model to investigate whether or not irreversible translational inhibition is due to abnormal aggregation of translational complex components, i.e. the ribosomes and their associated nascent polypeptides, protein synthesis initiation factors and co-translational chaperones. Under electron microscopy, most rosette-shaped polyribosomes were relatively evenly distributed in the cytoplasm of sham-operated control neurons, but clumped into large abnormal aggregates in penumbral neurons subjected to 2 h of focal ischemia followed by 4 h of reperfusion. The abnormal ribosomal protein aggregation lasted until the onset of delayed neuronal death at 24-48 h of reperfusion after ischemia. Biochemical study further suggested that translational complex components, including small ribosomal subunit protein 6 (S6), large subunit protein 28 (L28), eukaryotic initiation factors 2alpha, 4E and 3eta, and co-translational chaperone heat-shock cognate protein 70 (HSC70) and co-chaperone Hdj1, were all irreversibly clumped into large abnormal protein aggregates after ischemia. Translational complex components were also highly ubiquitinated. This study clearly demonstrates that focal ischemia leads to irreversible aggregation of protein synthesis machinery that contributes to neuronal death after focal brain ischemia.

Protein aggregation after focal brain ischemia and reperfusion

Two hours of transient focal brain ischemia causes acute neuronal death in the striatal core region and a somewhat more delayed type of neuronal death in neocortex. The objective of the current study was to investigate protein aggregation and neuronal death after focal brain ischemia in rats. Brain ischemia was induced by 2 hours of middle cerebral artery occlusion. Protein aggregation was analyzed by electron microscopy, laser-scanning confocal microscopy, and Western blotting. Two hours of focal brain ischemia induced protein aggregation in ischemic neocortical neurons at 1 hour of reperfusion, and protein aggregation persisted until neuronal death at 24 hours of reperfusion. Protein aggregates were found in the neuronal soma, dendrites, and axons, and they were associated with intracellular membranous structures during the postischemic phase. High-resolution confocal microscopy showed that clumped protein aggregates surrounding nuclei and along dendrites were formed after brain ischemia. On Western blots, ubiquitinated proteins (ubi-proteins) were dramatically increased in neocortical tissues in the postischemic phase. The ubi-proteins were Triton-insoluble, indicating that they might be irreversibly aggregated. The formation of ubi-protein aggregates after ischemia correlated well with the observed decrease in free ubiquitin and neuronal death. The authors concluded that proteins are severely damaged and aggregated in neurons after focal ischemia. The authors propose that protein damage or aggregation may contribute to ischemic neuronal death.

Early release of cytochrome C and activation of caspase-3 in hyperglycemic rats subjected to transient forebrain ischemia

The mechanisms underlying the aggravating effect of hyperglycemia on brain damage are still elusive. The present study was designed to test our hypothesis that hyperglycemia-mediated damage is caused by mitochondrial dysfunction with mitochondrial release of cytochrome c (cyt c) to the cytoplasm, which leads to activation of caspase-3, the executioner of cell death. We induced 15 min of forebrain ischemia, followed by 0.5, 1, and 3 h of recirculation in sham, normoglycemic and hyperglycemic rats. Release of cyt c was observed in the neocortex and CA3 in hyperglycemic rats after only 0.5 h of reperfusion, when no obvious neuronal damage was observed. The release of cyt c persisted after 1 and 3 h of reperfusion. Activation of caspase-3 was observed after 1 and 3 h of recovery in hyperglycemic animals. No cyt c release or caspase-3 activation was observed in sham-operated controls while a mild increase of cyt c was observed in normoglycemic ischemic animals after 1 and 3 h of reperfusion. The findings that there is caspase activation and cyt c relocation support a notion that the biochemical changes that constitute programmed cell death occur after ischemia and contribute, at least in part, to hyperglycemia-aggravated ischemic neuronal death.

Alterations of hippocampal postsynaptic densities following transient ischemia

A transient interruption in cerebral blood flow can lead to delayed neuronal death in certain vulnerable cell populations several days after blood flow is restored. Among the most vulnerable cell populations in the forebrain are hippocampal CA1 pyramidal neurons, which die between 48-72 h after the ischemic insult. Neurons in the dentate gyrus and area CA3 are relatively resistant, and will recover from the same insult. Uncovering the factors that render some neuronal populations vulnerable to transient ischemia is key to understanding mechanisms leading to cell death and to developing therapeutic interventions. By applying selective staining and three-dimensional (3D) imaging with electron tomography, we uncovered dramatic structural modifications in postsynaptic densities in the postischemic brain. Postsynaptic densities in the postischemic brain appeared both thicker and less condensed than those from sham-operated controls. Although the class of synapse could not be determined with the methods used, most are likely to be glutamatergic synapses onto dendritic spines, because the majority of synapses in the region examined belong to this class. Further analysis using electron tomography to examine the 3D structure of postsynaptic densities revealed degenerative changes, as evidenced by an overall loosening of the normally compact structure. Synaptic modifications were particularly severe and persistent in hippocampal area CA1 compared to the dentate gyrus. These structural modifications correlate well with biochemical and physiological studies indicating that alterations in synaptic transmission occur in the postischemic brain. The combination of selective staining and 3D reconstruction provides a valuable tool for revealing aspects of synaptic morphology not apparent from standard electron microscopic evaluation.

Protein ubiquitination in rat brain following hypoglycemic coma

Hypoglycemic coma of 30 min duration selectively damages CA1 pyramidal neurons and the crest of dentate gyrus (DG) granule cells in hippocampus. Here, we show by high-resolution confocal microscopy and biochemical analysis that 30 min of hypoglycemic coma induces the ubiquitination and aggregation of several proteins in rat brain tissues. Protein ubiquitination and aggregation occurred in the CA1 and DG regions as early as the end of 30 min of hypoglycemic coma and lasted until neuronal death in the late recovery period after hypoglycemia. In comparison, the neurons surviving hypoglycemia were less affected. On western blots, ubiquitinated proteins (ubi-proteins) were present mainly in Triton-insoluble pellets, indicating that they are irreversibly aggregated. We conclude that proteins are ubiquitinated and aggregated in neurons after hypoglycemia prior to their death. We hypothesize that protein ubiquitination and aggregation may contribute to neuronal damage after hypoglycemia.

Phosphorylation of extracellular signal-regulated kinase after transient cerebral ischemia in hyperglycemic rats

The present study was undertaken to investigate whether extracellular signal-regulated kinase (ERK) was involved in mediating hyperglycemia-exaggerated cerebral ischemic damage. Phosphorylation of ERK 1/2 was studied by immunocytochemistry and by Western blot analyses. Rats were subjected to 15 min of forebrain ischemia, followed by 0.5, 1, and 3 h of reperfusion under normoglycemic and hyperglycemic conditions. The results showed that in normoglycemic animals, moderate phosphorylation of ERK 1/2 was transiently induced after 0.5 h of recovery in cingulate cortex and in dentate gyrus, returning to control values thereafter. In hyperglycemic animals, phosphorylation of ERK 1/2 was markedly increased in the cingulate cortex and dentate gyrus after 0.5 h of recovery, the increases being sustained for at least 3 h after reperfusion. Hyperglycemia also induced phosphorylation of ERK 1/2 in the hippocampal CA3 sector but not in the CA1 area. Thus, the distribution of phospho-ERK 1/2 coincides with hyperglycemia-recruited damage structures. The results suggest that hyperglycemia may influence the outcome of an ischemic insult by modulating signal transduction pathways involving ERK 1/2.

Alterations of Akt1 (PKBalpha) and p70(S6K) in transient focal ischemia

The serine-threonine kinase Akt1 promotes cell survival through inhibition of apoptosis. One of the potential downstream targets of Akt1 is p70 S6 kinase, p70(S6K), an enzyme implicated in the regulation of protein synthesis. In this study, we investigated the changes in total and phosphorylated levels of Akt1 and p70(S6K) during transient focal ischemia. Male Wistar rats were subjected to 2 h of middle cerebral artery occlusion followed by 1, 4, and 24 h of reperfusion. The expression of total and phosphorylated forms of Akt1 and p70(S6K) were examined by Western blot analysis. Phosphorylation of Akt1 on Ser473 transiently increased at 1 and 4 h of reperfusion, whereas phosphorylation of Akt1 on Thr308 was reduced during reperfusion. The levels of total Akt1 remained unchanged at 1 and 4 h of reperfusion, but decreased significantly at 24 h of reperfusion. Phosphorylation of p70(S6K) on Thr389 decreased at 1, 4, and 24 h of reperfusion, while the levels of total p70(S6K) protein remained unchanged at 1 and 4 h of reperfusion but decreased at 24 h of reperfusion. The results show that cell survival pathways, such as Akt1 and p70(S6K) signaling, are suppressed after transient focal ischemia, which may contribute to the development of neuronal cell death after an ischemic insult.

Alteration of cyclic adenosine monophosphate response element binding protein in rat brain after hypoglycemic coma

In the current study, the temporal and regional changes of the transcription factor cyclic adenosine monophosphate response element binding protein (CREB) were investigated in rat brains subjected to 30 minutes of hypoglycemic coma followed by varied periods of recovery using Western blot and confocal microscopy. The total amount of CREB was not altered in any area examined after coma. The level of the phosphorylated form of CREB decreased during coma but rebounded after recovery. In the relatively resistant areas, such as the inner layers of the neocortex and the inner and outer blades of the dentate gyms (DG), phospho-CREB increased greater than the control level after 30 minutes of recovery and continued to increase up to 3 hours of recovery. In contrast, little or no increase of phospho-CREB was observed during the recovery period in the outer layers of the neocortex and at the tip of the DG, that is, regions that are selectively vulnerable to hypoglycemic insults. The current findings suggest that a neuroprotective signaling pathway may be more activated in the resistant regions than in the vulnerable ones after hypoglycemic coma.

Differential phosphorylation at Ser473 and Thr308 of Akt-1 in rat brain following hypoglycemic coma

We analyzed both total Akt-1 and phosphorylation of Akt-1 at residues Ser473 and Thr308 (phospho-Akt-1(Ser474) and phospho-Akt-1(Thr308), respectively) in the outer and inner layers of cortex following 30 min of hypoglycemic coma by Western blot analyses and confocal microscopy. The total amount of Akt-1 was not altered in any area examined. Phospho-Akt-1(Ser474), however, increased significantly in both layers of cortex at 0 and 30 min of recovery, but returned to control level at 3 h of recovery. In the vulnerable area (outer layer of cortex), no upregulation of phospho-Akt-1(Thr308) was observed at any time points examined. In the resistant area like inner layer of cortex, however, phospho-Akt-1(Thr308) was significantly over the control level at 3 h of recovery. Confocal microscopy result indicates that most of phospho-Akt-1(Thr308) had already moved into nucleus at 3 h of recovery. Our results suggest that Akt-1, when phosphorylated at Thr308, may play a protective role for neurons in the resistant regions of the brain.

Involvement of caspase-3 in cell death after hypoxia-ischemia declines during brain maturation

The involvement of caspase-3 in cell death after hypoxia-ischemia (HI) was studied during brain maturation. Unilateral HI was produced in rats at postnatal day 7 (P7), 15 (P15), 26 (P26), and 60 (P60) by a combination of left carotid artery ligation and systemic hypoxia (8% O2). Activation of caspase-3 and cell death was examined in situ by high-resolution confocal microscopy with anti-active caspase-3 antibody and propidium iodide and by biochemical analysis. The active caspase-3 positive neurons were composed of more than 90% HI damaged striatal and neocortical neurons in P7 pups, but that number was reduced to approximately 65% in striatum and 34% in the neocortex of P15 pups, and approximately 26% in striatum and 2% in neocortex of P26 rats. In P60 rats, less than 4% of the damaged neurons in striatum and less than 1% in neocortex were positive for active caspase-3. Western blot analysis demonstrated that the level of inactive caspase-3 in normal forebrain tissue gradually declined from a high level in young pups to very low levels in adult rats. Concomitantly, HI-induced active caspase-3 was reduced from a relatively high level in P7, to moderate levels in P15 and P26, to a barely detectable level in P60 rats. The authors conclude that the involvement of caspase-3 in the pathogenesis of cell death after HI declines during neuronal maturation. The authors hypothesize that caspase-3 may play a major role in cell death in immature neurons but a minor role in cell death in mature neurons after brain injury.

Alteration of MAP kinase pathways after transient forebrain ischemia

Extracellular regulated kinase (ERK) transduce growth factor signals while c-Jun NH(2)-terminal kinase (JNK) delivers stress signals into the nuclei for regulation of gene expression. These signaling pathways were studied by laser-scanning confocal microcopy and Western blot analysis using phospho-specific antibodies on rat brains that were subjected to 15 minutes transient forebrain ischemia followed by varied periods of reperfusion. Extracellular regulated kinase was activated at 30 minutes and 4 hours of reperfusion in the nuclei and dendrites of surviving dentate gyrus (DG) cells, but not in dying CA1 neurons after ischemia. Tyrosine phosphorylation of Trk kinase, an ERK upstream growth factor receptor, was elevated in the DG tissue, and to a lesser extent in the CA1 region. In addition, phosphorylation of activating transcription factor-2 (ATF-2) and c-Jun was selectively increased in CA1 dying neurons during the late period of reperfusion. These findings suggested that the Trk-ERK signaling pathway might be neuroprotective for dentate granule cells. The activation of ATF-2 and c-Jun pathways in the late period of reperfusion in CA1 dying neurons might reflect damage signals in these neurons. These results suggested that the lack of protective signals acting in concert with the presence of damage signals in CA1 neurons after ischemia might contribute to delayed neuronal death after transient forebrain ischemia.

Protein aggregation after transient cerebral ischemia

Protein aggregates containing ubiquitinated proteins are commonly present in neurodegenerative disorders and have been considered to cause neuronal degeneration. Here, we report that transient cerebral ischemia caused severe protein aggregation in hippocampal CA1 neurons. By using ethanolic phosphotungstic acid electron microscopy (EM) and ubiquitin immunogold EM, we found that protein aggregates were accumulated in CA1 neurons destined to die 72 hr after 15 min of cerebral ischemia. Protein aggregates appeared as clumps of electron-dense materials that stained heavily for ubiquitin and were associated with various intracellular membranous structures. The protein aggregates appeared at 4 hr and progressively accumulated at 24 and 48 hr of reperfusion in CA1 dying neurons. However, they were rarely observed in dentate gyrus neurons that were resistant to ischemia. At 4 hr of reperfusion, protein aggregates were mainly associated with intracellular vesicles in the soma and dendrites, and the nuclear membrane. By 24 hr of reperfusion, the aggregates were also associated with mitochondria, the Golgi apparatus, and the dendritic plasmalemma. High-resolution confocal microscopy further demonstrated that protein aggregates containing ubiquitin were persistently and progressively accumulated in all CA1 dying neurons but not in neuronal populations that survive in this model. We conclude that proteins are severely aggregated in hippocampal neurons vulnerable to transient brain ischemia. We hypothesize that the accumulation of protein aggregates cause ischemic neuronal death.

Survival- and death-promoting events after transient cerebral ischemia: phosphorylation of Akt, release of cytochrome C and Activation of caspase-like proteases

Release of cytochrome c (cyt c) into cytoplasm initiates caspase-mediated apoptosis, whereas activation of Akt kinase by phosphorylation at serine-473 prevents apoptosis in several cell systems. To investigate cell death and cell survival pathways, the authors studied release of cyt c, activation of caspase, and changes in Akt phosphorylation in rat brains subjected to 15 minutes of ischemia followed by varying periods of reperfusion. The authors found by electron microscopic study that a portion of mitochondria was swollen and structurally altered, whereas the cell membrane and nuclei were intact in hippocampal CA1 neurons after 36 hours of reperfusion. In some neurons, the pattern of immunostaining for cyt c changed from a punctuate pattern, likely representing mitochondria, to a more diffuse cytoplasmic localization at 36 and 48 hours of reperfusion as examined by laser-scanning confocal microscopic study. Western blot analysis showed that cyt c was increased in the cytosolic fraction in the hippocampus after 36 and 48 hours of reperfusion. Consistently, caspase-3-like activity was increased in these hippocampal samples. As demonstrated by Western blot using phosphospecific Akt antibody, phosphorylation of Akt at serine-473 in the hippocampal region was highly increased during the first 24 hours but not at 48 hours of reperfusion. The authors conclude that transient cerebral ischemia activates both cell death and cell survival pathways after ischemia. The activation of Akt during the first 24 hours conceivably may be one of the factors responsible for the delay in neuronal death after global ischemia.

Modification of postsynaptic densities after transient cerebral ischemia: a quantitative and three-dimensional ultrastructural study

Abnormal synaptic transmission has been hypothesized to be a cause of neuronal death resulting from transient ischemia, although the mechanisms are not fully understood. Here, we present evidence that synapses are markedly modified in the hippocampus after transient cerebral ischemia. Using both conventional and high-voltage electron microscopy, we performed two- and three-dimensional analyses of synapses selectively stained with ethanolic phosphotungstic acid in the hippocampus of rats subjected to 15 min of ischemia followed by various periods of reperfusion. Postsynaptic densities (PSDs) from both area CA1 and the dentate gyrus were thicker and fluffier in postischemic hippocampus than in controls. Three-dimensional reconstructions of selectively stained PSDs created using electron tomography indicated that postsynaptic densities became more irregular and loosely configured in postischemic brains compared with those in controls. A quantitative study based on thin sections of the time course of PSD modification indicated that the increase in thickness was both greater and more long-lived in area CA1 than in dentate gyrus. Whereas the magnitude of morphological change in dentate gyrus peaked at 4 hr of reperfusion (140% of control values) and declined thereafter, changes in area CA1 persisted and increased at 24 hr of reperfusion (191% of control values). We hypothesize that the degenerative ultrastructural alteration of PSDs may produce a toxic signal such as a greater calcium influx, which is integrated from the thousands of excitatory synapses onto dendrites, and is propagated to the neuronal somata where it causes or contributes to neuronal damage during the postischemic phase.

Persistent phosphorylation of cyclic AMP responsive element-binding protein and activating transcription factor-2 transcription factors following transient cerebral ischemia in rat brain

The transcription factors cyclic AMP responsive element-binding protein (CREB) and activating transcription factor-2 were studied in rat brains subjected to 15 min ischemia followed by varied periods of reperfusion using western blot and immunocytochemical analyses. The total amounts of both CREB and activating transcription factor-2 were not altered in the hippocampus after ischemia. In contrast, levels of the phosphorylated forms of both transcription factors decreased during ischemia but rebounded following reperfusion. The phospho-forms of CREB and activating transcription factor-2 showed regional and temporal differences in their expression. Phospho-CREB was increased relative to control levels at 30 min, and continued to increase for at least three days postischemia, mainly in dentate granule cells. The level of phospho-activating transcription factor-2 appeared to be higher in CAI pyramidal cells than in dentate granule cells after ischemia. The present findings suggest that the signaling pathways for phosphorylation of CREB may be neuroprotective for dentate cells, which are relatively resistant to ischemic insults. The increased phospho-activating transcription factor-2 may reflect increased stresses in these neurons. The more modest activation of CREB pathways in CA1 neurons may not be enough to overcome the increased stresses in these neurons, contributing to delayed neuronal death.

Assembly of proteins to postsynaptic densities after transient cerebral ischemia

Transient ischemia leads to changes in synaptic efficacy and results in selective neuronal damage during the postischemic phase, although the mechanisms are not fully understood. The protein composition and ultrastructure of postsynaptic densities (PSDs) were studied by using a rat transient ischemic model. We found that a brief ischemic episode induced a marked accumulation in PSDs of the protein assembly ATPases, N-ethylmaleimide-sensitive fusion protein, and heat-shock cognate protein-70 as well as the BDNF receptor (trkB) and protein kinases, as determined by protein microsequencing. The changes in PSD composition were accompanied by a 2.5-fold increase in the yield of PSD protein relative to controls. Biochemical modification of PSDs correlated well with an increase in PSD thickness observed in vivo by electron microscopy. We conclude that a brief ischemic episode modifies the molecular composition and ultrastructure of synapses by assembly of proteins to the postsynaptic density, which may underlie observed changes in synaptic function and selective neuronal damage.

[Studies on desensitization of GABAB receptor coupled adenylate cyclase]

After preincubation of crude synaptic membranes (P2 membranes) with phorber ester (PMA) or GABAB receptor agonist baclofen (BAL), the rate of inhibition of BAL on basal adenylate cyclase (AC) activity and forskolin-stimulated AC activity significantly reduced (desensitized). This effect of BAL did not change after preincubation with forskolin suggesting that the desensitization mechanism of GABAB receptor coupled AC is related with activation of protein kinase C (PKC), but not with protein kinase A. It was further found that the equilibrium dissociation constant (Kd) of GABAB receptor was increased during desensitization. Our results suggest that PKC activation may cause some structural or conformational changes of GABAB receptor, resulting in an uncoupling from G protein and desensitization of GABAB receptor-coupled AC.

[A study on the change of myocardial neuropeptide Y release induced by electric stimulation and myocardial ischemia in guinea pig heart]

Electrical stimulation of the left stellate ganglion in guinea pig heart evoked a calcium-dependent, exocytotic release of neuropeptide Y (NPY). Stimulation after 10 min of global ischemia (S2), compared with control period stimulation (S1), had no significant effect on the NPY release. The release of NPY produced by the same stimulation after 20 min of ischemia was inhibited to certain extent (S2/S1: 0.72, P < 0.05), whereas the inhibition of NPY release disappeared after 5 min of reperfusion (with a S2/S1 of 1.01). Ischemia alone, without electric stimulation, did not apparently induce NPY release, suggesting that electrical stimulation may induce a calcium-dependent, exocytotic release of NPY. It is further suggested that the inhibition of NPY release may be produced by some metabolites and the abolishment of the inhibition after reperfusion may be due to washout of the metabolites.

[Expression of c-fos mRNA induced by pressure overload in the left ventricle]

In the present study the effect of pressure overload on the expression of protooncogene c-fos in the left ventricle was investigated in rats with abdominal aorta constriction. It was found that a remarkable expression of c-fos was induced by pressure overload and the expression was greatly attenuated by angiotensin converting enzyme inhibitor captopril. In the pressure overload group the angiotensinogen mRNA level was found increased. The above results suggest that angiotensin II is involved in the expression of c-fos due to pressure overload.

[Improvement of learning and memory functions by GABAB receptor antagonists in mice]

In one trial passive avoidance response in mice, the effects of gamma-aminobutyric acid (GABA)B receptor agonist baclofen and antagonist CGP35348 and CGP36742 on acquisition, consolidation and retrieval of memory were observed. The results showed that the antagonists could significantly promote the acquisition impairment induced by baclofen, the consolidation impairment induced by baclofen and NaNO2, and the retrieval impairment induced by baclofen and 30% alcohol. These results suggest that the GABAB receptor antagonists may become a novel type of drug for the treatment of Alzheimer's disease.

Alterations of Ca2+/calmodulin-dependent protein kinase II and its messenger RNA in the rat hippocampus following normo- and hypothermic ischemia

The change in the subcellular distribution of Ca2+/calmodulin-dependent protein kinase II was studied in the rat hippocampus following normothermic and hypothermic transient cerebral ischemia of 15 min duration. A decrease in immunostaining of Ca2+/calmodulin-dependent protein kinase II was observed at 1 h of reperfusion which persisted until cell death in the CA1 region. In the CA3 and dentate gyrus areas immunostaining recovered at one to three days of reperfusion. The CA2+/calmodulin-dependent protein kinase II was translocated to synaptic junctions during ischemia and reperfusion which could be due to a persistent change in the intracellular calcium ion homeostasis. The expression of the messenger RNA of the alpha-subunit of Ca2+/calmodulin-dependent protein kinase II decreased in the entire hippocampus during reperfusion, and was most marked in the dentate gyrus at 12 h of reperfusion. This decrease could be a feedback downregulation of the mRNA due to increased Ca2+/calmodulin-dependent protein kinase II activation. Intraischemic hypothermia protected against ischemic neuronal damage and attenuated the ischemia-induced decrease of Ca2+/calmodulin-dependent protein kinase II immunostaining in all hippocampal regions. Hypothermia also reduced the translocation of Ca2+/calmodulin-dependent protein kinase II and restored Ca2+/calmodulin-dependent protein kinase II alpha messenger RNA after ischemia. The data suggest that ischemia leads to an aberrant Ca2+/calmodulin-dependent protein kinase II mediated signal transduction in the CA1 region, which is important for the development of delayed neuronal damage. Hypothermia enhances the restoration of the Ca2+/calmodulin-dependent protein kinase II mediated cell signalling.

Persistent translocation and inhibition of Ca2+/calmodulin-dependent protein kinase II in the crude synaptosomal fraction of the vulnerable hippocampus following hypoglycemia

Alterations in the levels and activity of Ca2+/calmodulin-dependent protein kinase II (CaM-kinase II) were studied in the rat hippocampus during and after insulin-induced hypoglycemic coma. A permanent loss of CaM-kinase II immunohistostaining in the neuronal layer begins at 10 min of isoelectricity in the tip of the dentate gyrus and at 30-min isoelectricity in the CA1 region. The reduction in immunohistostaining in the neurites is less pronounced. Immunoreactivity of CaM-kinase II on western blots increases in the crude synaptosomal fractions and decreases in cytosolic fraction, indicative of a translocation of CaM-kinase II. The translocation persists for at least 1 day of recovery after 30 min of isoelectricity in the vulnerable hippocampus (dorsomedial hippocampus) but not in the resistant hippocampus (dorsolateral hippocampus). Calmodulin binding to western blots shows changes similar to the immunoblots. Ca2+/calmodulin-dependent activity of CaM-kinase II in the crude synaptosomal fraction is elevated immediately before isoelectricity and is then inhibited during and after 30 min of isoelectricity, despite the increase of CaM-kinase II immunoreactivity. This was seen in the vulnerable hippocampus. The data indicate that stimulus of translocation and inhibition of CaM-kinase II persist during the recovery phase, preceding neuronal degeneration in the vulnerable hippocampus. This may be of significance for hypoglycemia-induced neuronal death.

[Angiotensin II induces c-fos and c-myc proto-oncogene expression in the left ventricle]

In the present study, the effects of angiotension II on the expression of protooncogene c-fos and c-myc in the left ventricle were investigated on Langedorff heart preparations. It was observed that angiotensin induced both c-fos and c-myc expression in a dose-dependent manner and the c-fos expression showed an earlier appearance than c-myc. All these induced expressions were blocked by a Angiotensin II receptor antagonist saralasin. The Angiotensin II induced expression of c-fos was also blocked by TTX, but the c-myc gene expression was unaffected.

Persistent translocation of Ca2+/calmodulin-dependent protein kinase II to synaptic junctions in the vulnerable hippocampal CA1 region following transient ischemia

The influence of brain ischemia on the subcellular distribution and activity of Ca2+/calmodulin-dependent protein kinase II (CaM kinase II) was studied in various cortical rat brain regions during and after cerebral ischemia. Total CaM kinase II immunoreactivity (IR) and calmodulin binding in the crude synaptosomal fraction of all regions studied increase but decrease in the microsomal and cytosolic fractions, indicative of a translocation of CaM kinase II to synaptosomes. The translocation of CaM kinase II to synaptic junctions occurs but not to synaptic vesicles. The translocation in neocortex and CA3/DG (dentate gyrus) is transient, whereas in the hippocampal CA1 region, it persists for at least 1 day of reperfusion. The Ca2+/calmodulin-dependent activity of CaM kinase II in the subsynaptosomal fractions of neocortex is persistently decreased by up to 85%, despite the increase in CaM kinase II IR. The decrease in activity is more pronounced than the decline in IR, suggesting that CaM kinase II is covalently modified in the postischemic phase. The persistent translocation of CaM kinase II in the vulnerable ischemic CA1 region indicates that a pathological process is sustained in the area after the reperfusion phase and this may be of significance for ischemic brain injury.

Changes in the tyrosine phosphorylation of mitogen-activated protein kinase in the rat hippocampus during and following severe hypoglycemia

The changes in the levels of tyrosine-phosphorylated proteins in the cytosolic fraction of the rat hippocampus subjected to severe hypoglycemia were analyzed. A marked increase in tyrosine phosphorylation of a 43-kDa protein was observed at 30 min of isoelectric EEG and 30 min and 1 h of recovery. Immunostaining of the same blot with antibody against mitogen-activated protein (MAP) kinase demonstrated a double band of approximately 42 and 43 kDa. The increased tyrosine phosphorylation of MAP kinase during hypoglycemic coma and the early recovery period suggests that MAP kinase may be involved in neuronal degeneration and repair.

Tyrosine phosphorylation and activation of mitogen-activated protein kinase in the rat brain following transient cerebral ischemia

Activation of trophic factor receptors stimulates tyrosine phosphorylation on proteins and supports neuronal survival. We report that in the recovery phase following reversible cerebral ischemia, tyrosine phosphorylation increases in the membrane fraction of the resistant hippocampal CA3/dentate gyrus (DG) region, whereas in the sensitive CA1 region or striatum, tyrosine phosphorylation is less marked or decreases. In the cytosolic fractions, a 42-kDa protein, identified as mitogen-activated protein (MAP) kinase, is markedly phosphorylated and activated immediately following ischemia, in particular in CA3/DG, but not in striatum. In the CA1 region, phosphorylation of MAP kinase is less intense and decreases later during reperfusion, which could explain the delay of neuronal degeneration in this structure. The data suggest that in ischemia-resistant neurons the growth factor receptor-coupled signaling cascade is stimulated and, through its effects on DNA transcription and mRNA translation, supports neuronal survival.

Depression of neuronal protein synthesis initiation by protein tyrosine kinase inhibitors

Growth factors stimulate cellular protein synthesis, but the intracellular signaling mechanisms that regulate initiation of mRNA translation in neurons have not been clarified. A rate-limiting step in the initiation of protein synthesis is the formation of the ternary complex among GTP, eukaryotic initiation factor 2 (eIF-2), and the initiator tRNA. Here we report that genistein, a specific tyrosine kinase inhibitor, decreases tyrosine kinase activity and the content of phosphotyrosine proteins in cultured primary cortical neurons. Genistein inhibits protein synthesis by > 80% in a dose-dependent manner (10-80 micrograms/ml) and concurrently decreases ternary complex formation by 60%. At the doses investigated, genistein depresses tyrosine kinase activity and concomitantly stimulates PKC activity. We propose that a protein tyrosine kinase participates in the initiation of protein synthesis in neurons, by affecting the activity of eIF-2 directly or through a protein kinase cascade.

Heat-shock inhibits protein synthesis and eIF-2 activity in cultured cortical neurons

Stress, such as heat-shock, hypoxia and hypoglycemia, inhibits the initiation of protein synthesis. The effects of heat-shock on protein synthesis, eucaryotic initiation factor 2 (eIF-2) activity, protein kinase C (PKC), and casein kinase II (CKII) activities were studied in primary cortical neuronal cultures. In neurons exposed to heat-shock at 44 degrees C for 20 min, protein synthesis is inhibited by more than 80%, and is accompanied by a 60% decrease in eIF-2 activity. Steady state PKC and CK II activities were not affected by heat-shock. Vanadate (200 microM), a protein phosphotyrosine phosphatase inhibitor, partially prevented the depression of eIF-2 activity during heat-shock, and increased CKII activity by 90%. In contrast, staurosporine (62nM), a protein kinase C inhibitor, did not affect eIF-2 activity. We conclude that heat-shock causes a change in the phosphorylation/dephosphorylation of regulatory proteins leading to a depressed eIF-2 activity and protein synthesis in neurons.

Postischaemic changes in protein synthesis in the rat brain: effects of hypothermia

Protein synthesis, measured as [14C]-leucine incorporation into proteins, was studied in the normothermic rat brain following 15 min of transient cerebral ischaemia and 1 h, 24 h and 48 h of recirculation, and in the hypothermic (33 degrees C) brain following 1 h and 48 h of recirculation. Ischaemia was induced by bilateral common carotid occlusion combined with hypotension. Following normothermic ischaemia, incorporation of [14C]-leucine was depressed by 40-80% at 1 h of recirculation in all brain regions studied. At 48 h postischaemia, incorporation returned to normal or above normal levels in the inner layers of neocortex, the CA3 region, the striatum and the dentate gyrus, while in the outer layers of neocortex and in the hippocampal CA1 region the incorporation was persistently decreased by 26% and 40% respectively. At 24 and 48 h postischaemia, protein synthesis in the CA1 region and the striatum could be attributed to proliferating microglia. Intra-ischaemic hypothermia ameliorated the persistent depression of protein synthesis in the CA1 region at 48 h postischaemia, and a two-fold increase compared to the normothermic group was observed both in the CA1 region and the striatum. In the cortex, eucaryotic initiation factor 2 activity transiently decreased at 30 min postischaemia. In animals subjected to intra-ischaemic hypothermia, the eucaryotic initiation factor 2 activity was reduced by 50% of control at 30 min of recirculation compared with 77% in normothermic animals. We conclude that the postischaemic depression of protein synthesis is in part caused by a decrease in eucaryotic initiation factor 2 activity.(ABSTRACT TRUNCATED AT 250 WORDS)

Initiation of protein synthesis and heat-shock protein-72 expression in the rat brain following severe insulin-induced hypoglycemia

Following stress such as heat shock or transient cerebral ischemia, global brain protein synthesis initiation is depressed through modulation of eucaryotic initiation factor (eIF) activities, and modification of ribosomal subunits. Concomitantly, expression of a certain class of mRNA, heat-shock protein (HSP) mRNA, is induced. Here we report that the activity of eucaryotic initiation factor-2 (eIF-2), a protein that participates in the regulation of a rate-limiting initiation step of protein synthesis, transiently decreases following insulin-induced severe hypoglycemia in the rat brain neocortex. Expression of HSP 72, a 72-kDa HSP, in surviving neurons was seen at 1-7 days of recovery following 30 min of hypoglycemic coma, but not at 1 h and 6 h of recovery. In the neocortex, HSP 72 was first seen in layer IV, and later also in surviving neurons in layer II. In the CA1 region and in the crest of dentate gyrus, HSP 72 expression was evident in cells adjacent to irreversibly damaged neurons. In the CA3 region and the hilus of dentate gyrus, HSP 72 was expressed in a few scattered neurons. In septal nucleus, HSP 72 was expressed in a lateral to medial fashion over a period of 1-3 days of recovery. We conclude that severe insulin-induced hypoglycemia induces a stress response in neurons in the recovery phase, including inhibition of protein synthesis initiation, depression of eIF-2 activity, and a delayed and prolonged expression of HSP 72 in surviving neurons. The HSP 72 expression may be a protective response to injurious stress.

Stress-induced inhibition of protein synthesis initiation: modulation of initiation factor 2 and guanine nucleotide exchange factor activities following transient cerebral ischemia in the rat

Neuronal protein synthesis is severely depressed following stress such as heat-shock, hypoxia, and hypoglycemia. Following reversible cerebral ischemia, protein synthesis is transiently inhibited in ischemia-resistant areas, but persistently depressed in vulnerable brain regions. Eukaryotic initiation factor 2 (eIF-2) activity, that is, the formation of the ternary complex eIF-2.GTP.initiator 35S-Met-tRNA, a rate-limiting step in the initiation of cellular protein synthesis, was studied in the rat brain during and following 15 min of transient global cerebral ischemia. At 30 min and 1 hr of reperfusion, a general decrease of eIF-2 activity by approximately 50% was seen in the postmitochondrial supernatant (PMS). In the relatively resistant neocortex and CA3 region of the hippocampus, the eIF-2 activity returns to control levels at 6 hr of reperfusion, but remains depressed in the vulnerable striatum and the CA1 region. Similarly, the activity of the guanine nucleotide exchange factor (GEF), which catalyzes the exchange of GTP for GDP bound to eIF-2, a crucial step for the continued formation of the ternary complex, is transiently reduced in neocortex but persistently depressed in striatum. The postischemic decrease in eIF-2 activity is further attenuated by agarose-bound alkaline phosphatase, and mixing experiments revealed that a vanadate-sensitive phosphatase may be responsible for the depression. Addition of partially purified GEF to PMS from postischemic neocortex restored eIF-2 activity to control levels. We conclude that ischemia alters the balance between phosphorylation and dephosphorylation reactions, leading to an inhibition of GEF and a depression of ternary complex formation.(ABSTRACT TRUNCATED AT 250 WORDS)

Casein kinase II activity in the postischemic rat brain increases in brain regions resistant to ischemia and decreases in vulnerable areas

Casein kinase II (CKII) is a protein kinase acting in the intracellular cascade of reactions activated by growth factor receptors, and that has a profound influence on cell proliferation and survival. In this investigation, we studied the changes in the activity and levels of CKII in the rat brain exposed to 10, 15 and 20 min of transient forebrain ischemia followed by variable periods of reperfusion. The cytosolic CKII activity decreased during reperfusion by approximately 30 and approximately 50% in the selectively vulnerable areas, striatum and the CA1 region of the hippocampus, respectively. In the resistant CA3 region of hippocampus and neocortex, the activity increased by approximately 20 and approximately 60%, respectively. The postischemic changes in CKII activity were dependent on the duration of the ischemic insult. The levels of CKII did not change after ischemia, suggesting that the enzyme is modulated by covalent modification or is interacting with an endogenous inhibitor/activator. Treatment of the cytosolic fraction from cortex of rats exposed to ischemia and 1 h of reperfusion with agarose-bound phosphatase decreased the activity of CKII to control levels, suggesting that CKII activation after ischemia involves a phosphorylation of the enzyme. The correlation between postischemic CKII activity and neuronal survival implies that preservation or activation of CKII activity may be important for neuronal survival after cerebral ischemia.

Changes in tyrosine phosphorylation in neocortex following transient cerebral ischaemia

Growth factor receptors activate protein tyrosine kinases, which are important for cell growth and survival. The protein tyrosine kinase (PTK) activity and the levels of phosphotyrosine (Ptyr) containing proteins were studied in the rat neocortex exposed to 15 min of transient cerebral ischaemia. The levels of the Ptyr containing proteins increase during recovery in the synaptosomal fraction, while the changes in the light membrane fraction are less marked. Protein tyrosine phosphorylation in the cytosol decreases. The differential changes in the levels of phosphotyrosine proteins in the particulate and cytosolic fractions suggest that the signal cascade from membrane bound receptors through tyrosine phosphorylation in the cytosol may be interrupted following ischaemia. This may be of importance for the development of neuronal damage.

[Solubilization and characterization of benzodiazepine receptors in frontal cortex of rabbit brain]

[3H]Flunitrazepam binding to benzodiazepine receptors solubilized by the detergent 3-[(3-cholamidopropyl)-dimethyl-ammonio]-l-propanesulfonate (CHAPS) was saturable and showed non-linear Scatchard plot with KD1 0.31 nmol/L and KD2 6.7 nmol/L. The affinities of soluble receptors to benzodiazepine were consistent with P2 membrane. One radioactive zone was found by SDS-PAGE after photoaffinity labelling of soluble membrane and the apparent molecular weight of 55,000 was reported. [3H]Flunitrazepam binding to soluble receptors was enhanced by GABA, NaCl or KCl and barbiturates, but inhibited by bicuculline and picrotoxinin. The enhancement of GABA on [3H]flunitrazepam binding was amplified by NaCl or KCl and antagonized by bicuculline and picrotoxinin. These results suggest that the benzodiazepine receptors solubilized by CHAPS have their pharmacological properties and are still associated with GABA receptors and chloride channel.