Heat Shock Proteins in Hypoxic-Ischemic Brain Injury: A Perspective

Hypothermia decreased the expression of heat shock proteins in neonatal rat model of hypoxic ischemic encephalopathy

Hypothermia (HT) is a well-established neuroprotective strategy against neonatal hypoxic ischemic encephalopathy (HIE). The overexpression of heat shock proteins (HSP) has been shown to provide neuroprotection in animal models of stroke. We aimed to investigate the effect of HT on HSP70 and HSP27 expression in a neonatal rat model of HIE. Seven-day-old rat pups were exposed to hypoxia for 90 min to establish the Rice-Vannucci model and were assigned to the following four groups: hypoxic injury (HI)-normothermia (NT, 36 °C), HI-HT (30 °C), sham-NT, and sham-HT. After temperature intervention for 24 h, the mRNA and protein expression of HSP70 and HSP27 were measured. The association between HSP expression and brain injury severity was also evaluated. The brain infarct size was significantly smaller in the HI-HT group than in the HI-NT group. The mRNA and protein expression of both HSPs were significantly greater in the two HI groups, compared to those in the two sham groups. Moreover, among the rat pups subjected to HI, HT significantly reduced the mRNA and protein expression of both HSPs. The mRNA expression level of the HSPs was proportional to the brain injury severity. Post-ischemic HT, i.e., a cold shock attenuated the expression of HSP70 and HSP27 in a neonatal rat model of HIE. Our study suggests that neither HSP70 nor HSP27 expression is involved in the neuroprotective mechanism through which prolonged HT protects against neonatal HIE.

Effects of L-tetrahydropalmatine on neuron apoptosis during acute cerebral ischemia-reperfusion of rats

To investigate the effects of L-Tetrahydropalmatine (L-THP) on neuron apoptosis during acute cerebral ischemia-reperfusion of rats and explore the effects of heat shock protein (HSP) on neuron apoptosis, Wistar rats were randomly divided into 3 groups: normal group, ischemia-reperfusion group and treatment group. The condition of neuron apoptosis, the survival state of neuron, pathological changes under an electron microscope and the number of HSP70 positive cells were measured in all groups. Results showed that the apoptosis neuron number was increased obviously at the 24th h during reperfusion and was further increased at the 48th h, the 72th h. While the number of survival neurons was decreased gradually with the prolongation of reperfusion time. Treatment with L-THP could decrease the apoptosis neuron number but increase the survival neuron number and the HSP70 positive cell number. Our study suggested that L-THP could decrease apoptosis and necrosis of neuron, up-regulate the expression of HSP70 and protect the cerebral ischemic injury.

Marked, sustained expression of a novel 150-kDa oxygen-regulated stress protein, in severely ischemic mouse neurons

The 150-kDa oxygen-regulated protein (ORP150) first was described with reference to the central nervous system in cultured astrocytes subjected to dense hypoxia. Subsequently its transcript was found in macrophages within human aortic atherosclerotic plaques, suggesting a role in protecting cells under hypoxic stress. In a mouse model of permanent focal brain ischemia, we aimed to elucidate the constitutive cellular localization in vivo of ORP150 in the central nervous system as well as the sequential alteration in its mRNA and protein expression during this severe ischemic insult. Immunohistochemical study demonstrated that ORP150 protein normally is present predominantly in neurons. The 78-kDa glucose-regulated protein, which is another well-known stress protein retained in the endoplasmic reticulum, also was stained in neurons. During the first 3 h after ischemia, ORP150 antigenicity was markedly enhanced in severely damaged neurons, while the amount of the glucose-regulated protein was decreased. Preceding this change, orp150 mRNA was selectively induced in neurons undergoing postischemic cytoskeletal proteolysis, as early as 1 h after middle cerebral artery occlusion. These results indicated that ORP150 might be regulated by transcriptional level as for many stress proteins, but unlike previously described other stress proteins it was translated in the center of ischemic lesions despite nearly complete energy depletion. In this paper, the biological potentials of ORP150 protein in the setting of brain ischemia in vivo will also be discussed.

Heat-shock proteins expression in fish central nervous system and its possible relation with water acidosis resistance

The expression of 70 and 60-kDa heat-shock proteins (HSP70 and HSP60) and glial fibrillary acidic protein (GFAP), determined by immunoblotting and immunohistochemical methods, was studied in fish neural tissue; moreover the possible correlation between the expression of these proteins in neural tissue and fish acidosis resistance was also examined. The HSP GFAP content was analyzed in four different teleostean fish species (gourami, carp, goldfish and trout) under control conditions and in carp under experimental conditions to induce HSPs expression. Under control conditions, HSP70 and HSP60 expression was similar in gourami, carp and goldfish, but gourami had the highest acidosis resistance; trout had the lowest HSP70 and 60 expression and lowest acidosis resistance. The HSP expression pattern was mainly neuronal under control conditions. HSP expression was induced in carp and the effect of this induction on acidosis resistance was studied. Two methods were used for HSP induction in carp: acid shock (2 h at 4.5 pH) and heat shock (2 h at 33 degrees C). A high acidosis resistance, although non-significant, was observed after heat pretreatment. An important HSP expression was detected in glial cells after induction. GFAP expression showed no association with acidosis resistance under either control or experimental conditions.

Prenatal ischemia reduces neuronal injury caused by neonatal hypoxia-ischemia in rats

To determine whether 'ischemic tolerance', first described in adult rodents, exists in fetal and neonatal rats, a comparison of brain injury was made between two groups of rat pups following neonatal hypoxia-ischemia (HI). One group of rat pups had previously been subjected to HI in utero (HI + HI); the other had been subjected to a sham operation (SH + HI). Brain infarct size and neuronal injury were measured 24 h after the neonatal HI insult. As indicated by 2,3,5-triphenyltetrazolium chloride staining and pathological examination, cerebral damage was significantly less in the HI+ HI group than in the SH + HI group. Induction of heat shock protein 70 (hsp70) was immunohistochemically detectable in both groups 24 h after the neonatal HI, and was proportional to the extent of tissue damage. The ischemic tolerance phenomenon observed in immature rats does not appear to be a result of induction of hsp70.

Astrocyte survival and HSP70 heat shock protein induction following heat shock and acidosis

Although severe acidosis is an important mediator of brain infarction, recent evidence suggests that mild acidosis may protect ischemic cells. The HSP70 heat shock protein is induced by acidosis in cultured cells and in ischemic brain and protects cells against many types of injury. Therefore, this study determined whether induction of heat shock proteins protects cultured astrocytes against acidosis. Brief exposure of cultured cortical astrocytes to acid (pH 5.2 for 40 min) or heat shock (45 degrees C for 40 min) markedly induced hsp70 mRNA and HSP70 protein. HSP70 protein was detected with the C92 monoclonal antibody (Welch and Suhan: J Cell Biol 103:2035, 1986), which has been shown to recognize the protein product of the full-length rat hsp70 cDNA (Longo et al: J Neurosci Res 36:325, 1993). Heat shock of the cultured cortical astrocytes completely protected the astrocytes from an otherwise lethal heat exposure 24 h later (45 degrees C for 4 h). In contrast, heat pretreatment sensitized the astrocytes to injury from acidosis 24 h later. Acid pretreatment, which markedly induced the HSP70 protein without producing astrocytic cell death, similarly sensitized the cells to injury from acidosis 24 h later (60% survival following pH 5.2 for 3 h versus 90% survival in controls; P < 0.0001). Surprisingly, heat shock pretreatment protected astrocytes against exposure to acid 48 h later (P < 0.05, 1.5-3 h), whereas acid pretreatment had no effect on astrocyte survival 48 h later. Since heat shock did not protect against acidosis at 24 h when HSP70 induction was maximal but did protect at 48 h when HSP70 was markedly diminished, the protective effect of heat shock at 48 h may be related to stress proteins present at 48 h. It is concluded that induction of HSP70 and other heat shock proteins by heat shock protects astrocytes against subsequent lethal heat shock. However, heat shock and acid treatment increase the vulnerability of astrocytes to acidosis 24 h later in spite of the induction of HSP70 heat shock proteins. The finding that heat shock protected astrocytes against acidosis 2 days later may suggest that delayed induction of stress proteins partially protects the astrocytes against damage produced by high concentrations of hydrogen ions.

Evidence for different mechanisms of induction of HSP70i: a comparison of cultured rat cortical neurons with astrocytes

This study is a follow-up of previous work which demonstrated that cultured cortical neurons did not synthesize HSP70i immediately after heat stress when compared with cultured cortical astrocytes. We have extended the period of observation for HSP70i induction of cultured cortical neurons and astrocytes up to 24 h after heat stress. Cultured rat cortical neurons derived from 16-day-old fetal rats respond differently to heat stress than cultured rat astrocytes derived from newborn rats. They showed a delayed HSP70i induction in the majority of cultured neurons and the response was heterogeneous and was absent in most smaller neurons. The delayed neuronal induction was accompanied by a prolonged activation of heat-shock transcription factor 1 (HSF-1) and prolonged transcription of HSP70i mRNA. In comparison astrocytes showed a marked early induction of HSP70i mRNA and protein. In addition the induction of HSP70i in astrocytes was followed by translocation of the protein into the nucleus, a finding which we failed to demonstrate in neurons. Immunostaining for HSP70i was more uniform in astrocytes than neurons. Many neurons did not stain for up to 24 h after heat shock in this study. Immunocytochemical staining of HSF-1 and 2 showed major differences between neurons and astrocytes. Astrocytes showed localization of HSF-1 to the nucleus before and after heat stress, while neurons showed HSF-1 localization to the cytoplasm and nucleus before and after heat stress. Finally HSF-2 was undetectable in neurons when compared with astrocytes by Western immunoblot analysis. However, astrocytes and neurons revealed weak immunostaining of HSF-2 in the cytoplasm and nucleus. The staining in the neurons was likely secondary to cross-reactivity to an unidentified protein. We conclude that HSP70i expression after heat shock is delayed in rat cortical neurons when compared with rat cortical astrocytes. In addition most small neurons did not synthesize HSP70i after heat shock. This difference in induction of HSP70i may be secondary to localization and activation of HSF-1 but not HSF-2. Neuronal susceptibility to injury may be related to the delayed induction of HSP70i and also the possible failure of newly synthesized HSP70i to translocate into the nucleus.

Time course of protein changes following in vitro ischemia in the rat hippocampal slice

Following 5 min in vitro ischemia, total protein synthesis is dramatically and persistently inhibited in neurons in the rat hippocampal slice. This model system was used to explore the responses of individual proteins to this irreversible insult. In vitro ischemia inhibited new protein synthesis of most proteins analyzed; however, the synthesis of a 68/70 kDa protein was substantially stimulated for the first hour after ischemia. By 3 hr postischemia, its synthesis rates were depressed to 60% of control rates. Although the total amounts of most proteins were not significantly depleted for the first few hours after ail ischemic episode, there were several notable exceptions. The levels of HSC73, a constitutively expressed member of the 70 kDa stress protein family, were reduced after in vitro ischemia. In addition, MAP-2 (microtubule-associated protein-2) and alpha-tubulin were depleted in the early hours after the insult, with MAP-2 exhibiting a detectable depletion earlier than tubulin. In contrast, the levels and distribution of a 68 kDa neurofilament protein localized to CA3 pyramidal neurons in the slice, apparently distinct from the band whose new synthesis was stimulated, were not affected by the 5 min in vitro ischemia insult. Thus, the responses of individual proteins to ischemia varied considerably, These individual responses could play an important role in the damage mechanism that is initiated in response to in vitro ischemia.

Differential expression of heme oxygenase-1 in cultured cortical neurons and astrocytes determined by the aid of a new heme oxygenase antibody. Response to oxidative stress

Heme oxygenase exists as two isoenzymes designated heme oxygenase-1 (HO-1) and heme oxygenase-2 (HO-2). HO-2 is made constitutively in many cell types whereas HO-1 is a stress protein inducible by heat, heavy metals, ultraviolet irradiation, and oxidative stress. Recombinant rat HO-1 was expressed in bacteria and antiserum designated HO-1713 was raised against the purified protein. HO-1713 detected recombinant rat HO-1 and recombinant rat HO-2. In rat tissues it detected HO-1 and a second, unidentified band designated HO-L (heme oxygenase-like immunoreactivity) which was not HO-2. Cultured rat cortical neurons and forebrain astrocytes were exposed to hydrogen peroxide (0.14-0.7 micromolar for 30 or 60 min). Neurons which contained little detectable HO-1 and which were sensitive to hydrogen peroxide at the high end of the dose curve failed to induce HO-1 by Western blot analysis. In contrast, cultured rat forebrain astrocytes which contained HO-1 under normal culture conditions and which were resistant to injury by hydrogen peroxide, increased their content of immunoreactive HO-1 by 7-fold within 3 h after exposure. Our results support a protective role for HO-1 in oxidative injury and suggest that the relative inability of neurons to increase HO-1 after oxidative stress may contribute to their selective vulnerability vis-a-vis astrocytes. They also suggest that differential expression of heme oxygenase in studies utilizing CNS cultures may alter normal cell physiology and cell survival.

The effects of reduced perfusion and reperfusion on c-fos and HSP-72 protein immunohistochemistry in gestational day 21 rat brains

Metabolic stressors such as hyperthermia, seizures and ischemic hypoxia result in the induction of c-fos and heat-shock proteins (HSP) in affected brain cells of the adult rodent, especially within the hippocampal region, which normally has high metabolic demands. Here we ligated the uterine vessels of gestational day (GD) 21 rat pups to produce ischemic hypoxia. We confirmed that HSP-72 protein, as previously reported, was activated in the perinatal rat pup, especially in the hippocampal CA3 region. However, the capability of hippocampal cells to produce c-fos protein following drug-induced seizures has been reported to develop only after postnatal day 13. Here, ischemic hypoxia caused CA1 hippocampal cells to produce immunohistochemically detectable c-fos protein in GD-21 rats. These results seem to contradict the previous reports of no c-fos induction in rats this young by demonstrating a functional c-fos translational mechanism by GD-21. However, seizure vs ischemic hypoxia-induced c-fos expression may involve several different pre-translational pathways. A delayed development of a receptor, second messenger, or genomic element for regulating c-fos transcription remain as possible explanations for the late maturity of responsivity to seizures.

Effects of electroconvulsive shock on the levels of hsp70 and hsc73 mRNA in the rat brain

We evaluated the effects of electroconvulsive shock (ECS) on the expression of two genes encoding 70 kDa stress proteins, in the rat brain. The study was carried out by in situ hybridization using oligonucleotide probes specific for either the constitutively expressed hsc73, or the strictly inducible hsp70 gene. Rats were submitted to single or repeated (7 days, one session for each day) sessions of Electroconvulsive Shock. Animals were sacrificed at various time after treatment. ECS enhanced the basal expression of hsc73 in limbic areas, such as dentate gyrus, CA3, and median habenular nucleus. ECS induced hsp70 mRNA, which was not detectable in control animals, specifically in the Dentate Gyrus. The effect was present 2 h following treatment. Both single and repeated ECS were similarly effective. The finding likely reflects neuroadaptive local changes associated with a generalized seizure activity.

Heat-shock proteins maintain the viability of ATP-deprived cells: what is the mechanism?

ATP depletion causes necrosis in mammalian cells. However, a previous heat shock can protect cells from the effects of energy deprivation, probably as a result of the synthesis and accumulation of heat-shock proteins (hsps). We propose that hsps protect ATP-depleted cells from rapid necrotic death by inhibiting the aggregation of cytoskeletal proteins that occurs when ATP synthesis is blocked.

The heat shock/stress response in focal cerebral ischemia

Focal ischemia results in striking changes in gene expression. Induction of hsp72, a member of the family of 70 kDa heat shock/stress proteins is a widely studied component of the generalized cellular response to injury known as the 'stress response' that is detected in brain after ischemia and other insults. This overview summarizes observations on hsp72 expression in models of focal cerebral ischemia, considering its cellular distribution, factors affecting its transcriptional and translational expression, and its potential relevance to post-ischemic pathophysiology. Hsp72 expression is essentially limited to regions in which cerebral blood flow falls below 50% of control levels, provided that residual perfusion allows synthesis of the induced mRNA and protein. The cellular distribution of hsp72 depends on the nature of the ischemic insult, with preferential vascular expression in severely ischemic territory that is destined to necrose, pronounced neuronal expression throughout the ischemic 'penumbra', and limited glial involvement in a narrow zone immediately surrounding the infarct. Together with results in other injury models, these observations indicate that hsp72 induction identifies discrete populations of surviving cells that are metabolically compromised, but not irreversibly damaged after focal ischemia. Available evidence suggests that the stress response is an important component of cellular defense mechanisms, and that successful accumulation of hsp72 is critical to survival following ischemia. Its expression may also contribute to mechanisms of induced ischemic tolerance. Future studies may be expected to more fully characterize the range of altered gene expression in response to focal ischemic injury and to establish specific roles for hsp72 and other induced proteins in the progression of injury and recovery following such insults.

Temporal and spatial distribution of heat shock mRNA and protein (hsp70) in the rabbit cerebellum in response to hyperthermia

We have previously investigated the expression of hsp70 genes in the hyperthermic rabbit brain at the mRNA level by Northern blot and in situ hybridization procedures. Our studies have now been extended to the protein level utilizing Western blot and immunocytochemistry. Using an antibody which is specific to inducible hsp70, a prominent induction of hsp70 protein in glial cells of hyperthermic animals was noted. In particular, Bergmann glial cells in the cerebellum are strongly immunoreactive while adjacent Purkinje neurons are immunonegative. Extension of our in situ hybridization studies to a time course analysis revealed that the initial glial induction events were followed by a delayed accumulation of inducible hsp70 mRNA in Purkinje neurons at 10 hr post-heat shock. In control animals, high levels of constitutively expressed hsc70 mRNA and protein were observed in Purkinje neurons. Similar hsc70 and hsp70 mRNA observations were also made in neurons of the deep cerebellar nuclei and in motor neurons of the spinal cord. Our results suggest that these neuronal cell types accumulate hsp70 mRNA in response to hyperthermic treatment; however, the response is delayed when compared to the rapid response seen in glial cells. The high constitutive levels of hsc70 in certain neuronal cell types may play a role in the initial dampening of the hsp70 induction response in these cells.

Rise in heat-shock protein level confers tolerance to energy deprivation

Heat shock (44 degrees C for 10 min) or ATP depletion by an uncoupler (CCCP for 20 min) is shown to result in stimulation of hsp68/70 synthesis in Ehrlich tumor cells. After 3 h of recovery, the cells become thermotolerant. Surprisingly, repeated ATP depletion caused by CCCP or rotenone (a respiratory inhibitor) treatment, had a much lower effect on cell viability. Both induction of tolerance to energy deprivation and hsp68/70 synthesis were totally suppressed by cycloheximide, an inhibitor of cytosolic protein synthesis. In tolerant cells, rotenone still induced ATP depletion; however, protein aggregation (the rise in Triton-insoluble proteins) was inhibited in these cells. It is suggested that cellular chaperones (e.g. hsp70) are involved in the protection of ischemic cells from necrosis, preventing protein aggregation under ATP deficiency.