Differential vulnerability of microtubule components in cerebral ischemia

Cyclin-dependent protein kinase 5 activity increases in rat brain following ischemia

Cyclin-dependent kinase 5 (CDK5) is the 34 kDa catalytic subunit of a recently characterized neuronal cdc2-like protein kinase which appears to be involved in regulation of the neurocytoskeleton. Using the rat postdecapitative model, the effect of brain ischemia on histone H1 and tau protein CDK5 phosphorylating activity was examined. Histone H1 kinase activity increased in both cytosolic and particulate fractions of the hippocampus and neocortex after 5 min and 15 min of ischemia, then declined to control levels. CDK5 tau protein phosphorylating activity increased after 15 min ischemia; however, no electrophoretic shifts or changes in radiodensity of the tau bands were observed autoradiographically. On Western blot analysis, the CDK5 protein band did not change after 25 min ischemia, despite the increase and subsequent decline in enzyme activity. These data demonstrate a postischemic increase in CDK5 activity, an associated increase in CDK5 tau phosphorylating activity and a decline in activity in the absence of massive proteolysis. CDK5 appears to play a role in the events associated with neuronal response to ischemic injury.

A near-infrared spectroscopic study of cerebral ischemia and ischemic tolerance in gerbils

BACKGROUND AND PURPOSE

To explore the physiological mechanism of ischemic tolerance, we studied intracerebral oxygenation states noninvasively using near-infrared spectroscopy after bilateral common carotid artery occlusion (BCO) in gerbils with and without ischemic pretreatment.

METHODS

Under ether anesthesia, gerbils with sham operation (S group, n = 8) and those with pretreatment consisting of BCO for 2 minutes, twice at 3 days and 2 days earlier (T group, n = 8), were again subjected to BCO for 5 minutes. Changes in oxyhemoglobin (HbO2), deoxyhemoglobin (Hb), and total hemoglobin (HbT) as well as reduction in cytochrome oxidase (cyt.aa3) were calculated from the absorbance changes of the light transmitted through the brain. Seven days after the ischemic study, immunohistochemical examination was performed with an antiserum against microtubule-associated proteins.

RESULTS

In both groups, the increase of Hb and decrease of HbO2 and HbT proceeded rapidly after BCO, and the maximal deoxygenation of hemoglobin occurred within 2.5 minutes. Reduction of cyt.aa3 also ensued rapidly and reached the maximal reduction within 3 minutes in both groups. In the T group, however, both deoxygenation of hemoglobin and reduction of cyt.aa3 progressed more slowly than in the S group. The time (seconds) necessary for a maximal change for cyt.aa3 was significantly longer in the T group (203.8 +/- 34.0 [mean +/- SD]; P < .01) than in the S group (68.0 +/- 14.7). The time necessary for a half-maximal change was also significantly longer in the T group than in the S group for both Hb (22.0 +/- 7.5 and 13.5 +/- 4.0, respectively; P < .05) and cyt.aa3 (23.9 +/- 5.7 and 11.6 +/- 4.3; P < .01). After recirculation for 7 days, all gerbils in the S group were found to have neuronal death in the hippocampus, while those in the T group did not.

CONCLUSIONS

The present study indicated that mild ischemic stress can induce improvement in oxygen metabolism during subsequent ischemia, which might be causally related to the phenomenon known as "ischemic tolerance," in which a protective effect toward ischemic/postischemic injury is induced by earlier mild ischemic pretreatment.

Rapid alteration of tau in oligodendrocytes after focal ischemic injury in the rat: involvement of free radicals

Glial inclusions containing the microtubule-associated protein tau are present in a variety of chronic neurodegenerative conditions. We now report a rapid and time-dependent increase of tau immunoreactivity within oligodendrocytes after focal cerebral ischemia in the rat. The number of tau positive oligodendrocytes in the ipsilateral subcortical white matter increased six- to eightfold by 40 minutes after permanent middle cerebral artery occlusion (MCAO). Tau was detected using antibodies that label both the N- and C-terminal of the protein, suggesting accumulation of full-length protein within these cells. Pretreatment with the spin trap agent alpha-phenyl-tert-butyl-nitrone (PBN)(100mg/kg) reduced the number of tau-positive oligodendrocytes by 55% in the subcortical white matter of the ischemic hemisphere compared with untreated animals at 40 minutes after MCAO. In contrast, pretreatment with glutamate receptor antagonists MK-801 (0.5 mg/kg) or 2,3-dihydroxy-6-nitro-7-sulpfamoyl-benzo(f)quinoxaline (NBQX) (2 x 30 mg/kg), failed to reduce the number of tau-positive oligodendrocytes after 40 minutes of ischemia. The results indicate that oligodendrocytes respond rapidly to an ischemic challenge and that free radical-mediated mechanisms are involved in the cascade leading to increased tau immunoreactivity.

The effect of postmortem delay on the distribution of microtubule-associated proteins tau, MAP2, and MAP5 in the rat

Breakdown or disruption of the cytoskeleton has been implicated in the neurodegenerative processes of a variety of diseases, including Alzheimer disease (AD) and stroke. Studies of such diseases in the human involve the use of postmortem brain tissue. Postmortem delay may vary considerably from a few hours to a few days, and within this period, a degree of cytoskeletal breakdown may occur. It is therefore crucial to examine alterations occurring in the cytoskeleton as a result of postmortem delay and subtract these from those caused by the disease. In this study, the distribution of tau, MAP2, and MAP5 immunohistochemistry was examined following postmortem intervals of 0-72 h in the rat cerebral cortex, corpus callosum, caudate nucleus, and hippocampus. Each microtubule-associated protein (MAP) underwent unique changes that were dependent both on postmortem interval and the brain region examined. Following long postmortem delays, some of the changes in these proteins were similar to those seen in rodent models of cerebral ischemia. These results demonstrate that MAPs are not stable during postmortem delay in the rat. Therefore, caution must be exercised when interpreting changes in MAPs in human postmortem tissue, especially in cases where ischemic injury may be involved. Examination of control tissue carefully matched for postmortem delay is therefore essential to allow meaningful interpretation of cytoskeletal abnormalities in human neurodegenerative disease.

The effect of circulatory arrest and retrograde cerebral perfusion on microtubule-associated protein 2: an immunohistochemical study in pig hippocampus

Microtubule-associated protein 2 (MAP2) immunohistochemical labeling in the hippocampus was studied to assess the protective effect of brain perfusion during surgery requiring hypothermic circulatory arrest in 24 pigs exposed to anesthesia alone (control), 120 min of complete circulatory arrest at 15 degrees C, min of retrograde cerebral perfusion at 15 degrees C, or 120 min of anterograde cerebral perfusion at 15 degrees C. Pigs were reperfused for 60 min and sacrificed. In the control anterograde perfusion groups, the intensity of MAP2 labeling was similar in all regions of the hippocampus. Circulatory arrest and retrograde perfusion resulted in significant reduction of MAP2 labeling (28% and 38% respectively of control, P < 0.001) of neurons in the CA1 region. MAP2 labeling may be useful for assessing early damage in the hippocampus in this model.

Microtubular proteolysis in focal cerebral ischemia

Calpain, a neutral protease activated by calcium, may promote microtubular proteolysis in ischemic brain. We tested this hypothesis in an animal model of focal cerebral ischemia without reperfusion. The earliest sign of tissue injury was observed after no more than 15 min of ischemia, with coiling of apical dendrites immunolabeled to show microtubule-associated protein 2 (MAP2). After 6 h of ischemia, MAP2 immunoreactivity was markedly diminished in the infarct zone. Quantitative Western analysis demonstrated that MAP2 was almost unmeasurable after 24 h of ischemia. An increase in calpain activity, shown by an antibody recognizing calpain-cleaved spectrin fragments, paralleled the loss of MAP2 immunostaining. Double-labeled immunofluorescent studies showed that intraneuronal calpain activity preceded evidence of MAP2 proteolysis. Perikaryal immunolabeling of tau protein became increasingly prominent between 1 and 6 h in neurons located within the transition zone between ischemic and unaffected tissue. Western blot experiments confirmed that dephosphorylation of tau protein occurred during 24 h of ischemia, but was not associated with significant loss of tau antigen. We conclude that focal cerebral ischemia is associated with early microtubular proteolysis caused by calpain.

Changes in microtubule-associated protein 2 and amyloid precursor protein immunoreactivity following traumatic brain injury in rat: influence of MK-801 treatment

We investigated by immunohistochemistry dendritic and axonal changes occurring in the rat brain after mild focal cortical trauma produced by the weight drop technique. One and 3 days after injury, nerve cell bodies and dendrites in the perimeter of the impact site displayed decreased microtubule-associated protein 2 (MAP2) immunoreactivity. Some dendrites in the immediate adjacent region were more intensely stained and distorted. The dentate hilar region of the hippocampus showed a reduction of immunoreactive nerve cell bodies and dendrites. Twenty-one days after injury the strongly stained cortical dendrites and the reduction of immunoreactivity in the hippocampus remained, whereas the reduced staining in the perimeter of the lesion had normalised. These results indicate that there is a long-lasting disturbed dendritic organisation implicating impaired neurotransmission after this type of mild brain trauma. beta-Amyloid precursor protein (APP) immunohistochemistry revealed numerous stained axons in the ipsilateral subcortical white matter and thalamus indicating local and remote axonal injuries with disturbed axonal transport. Twenty-one days after injury, numerous small immunostained profiles appeared in the neuropil of the cortical impact site and in the ipsilateral thalamus. The axonal changes indicate disturbed connectivity between the site of the impact and other brain regions, chiefly the thalamus. The presence of beta-amyloid was investigated 21 days after trauma. There were no signs of beta-amyloid depositions in the brain after injury. Finally, we tested if the non-competitive NMDA receptor antagonist dizocilpine maleate (MK-801) could influence the observed MAP2 and APP changes. Pretreatment with this compound did not affect the early MAP2 and APP alterations. Instead, an increased expression of the APP antigen in the thalamus was observed 21 days after trauma in the MK-801-treated animals. The cause of this phenomenon is not known but may be related to a delayed neurotoxic action of MK-801 treatment.

Acute focal ischemia-induced alterations in MAP2 immunostaining: description of temporal changes and utilization as a marker for volumetric assessment of acute brain injury

The utility of microtubule-associated protein 2 (MAP2) immunostaining as a marker of acute focal ischemic injury was investigated. Permanent middle cerebral artery occlusion (MCAO) elicited a rapid reduction in MAP2 immunostaining that was visible 1 h post-MCAO and that increased in intensity and area encompassed over time. The ischemic lesion borders were well defined by loss of MAP2 immunostaining, but alterations in staining within the lesion were more heterogeneous. Lesion volume increased significantly from 1 to 4 h post-MCAO (from 63.8 +/- 10.8 to 111.3 +/- 19.0 mm3, mean +/- SD). Thus, MAP2 immunostaining is a sensitive, quantifiable indicator of acute brain injury following focal ischemia.

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.

Induction of c-fos and c-jun gene products and heat shock protein after brief and prolonged cerebral ischemia in gerbils

BACKGROUND AND PURPOSE

Proto-oncogene activation and induction of heat shock protein (HSP) occur in response to various stimuli to brain, but the role in neuronal survival after cerebral ischemia remains uncertain. We compared the extent of insults and induction of c-fos and c-jun gene products (c-FOS and c-JUN) as well as HSP in ischemic and postischemic gerbil brains immunohistochemically.

METHODS

Common carotid arteries of Mongolian gerbils were occluded for 5 or 15 minutes and recirculated for 0 minutes to 7 days. Antibodies for c-FOS, c-JUN, and HSP 70 were used for immunohistochemistry, and positive reactions were semiquantitatively analyzed. The presence of ischemic and postischemic lesions was ascertained with an antibody for microtubule-associated proteins.

RESULTS

After ischemia for 15 minutes and reperfusion, c-FOS was induced promptly after 1 to 6 hours in pyramidal cells of the CA3 and CA4 regions, while c-JUN became visible in the same areas after recirculation for 4 to 48 hours. HSP 70 was detected after recirculation for 24 hours in the CA3 region. In layers I and II of the cerebral cortex, c-FOS and c-JUN peaked at 3 hours and HSP 70 at 96 hours. Induction of these proteins was absent or negligible in the areas that developed ischemic or postischemic lesions, including the subiculum-CA1 and CA1 regions of the hippocampus and layers III/IV and Vb/VI of the cerebral cortex. After shorter ischemia for 5 minutes and reperfusion, c-FOS and c-JUN were rapidly induced at 15 minutes to 1 hour except for the subiculum-CA1 and CA1 regions of the hippocampus. Induction of HSP 70 did not occur for 24 hours and was noted only in the hippocampus.

CONCLUSIONS

Induction of c-FOS and c-JUN occurred in the areas surviving after transient cerebral ischemia, but the extent of induction and the latent period varied depending on the duration of the insult and the location. In the areas with ischemic or postischemic damage detected by loss of the reaction for microtubule-associated proteins, the induction of c-FOS and c-JUN was either absent or minimal, suggesting that active induction of those immediate early gene products occurred early in surviving neurons. On the other hand, the induction of HSP 70 did not occur until reperfusion for 24 hours and actively occurred only in the areas with earlier induction of c-FOS and/or c-JUN, suggesting that the induction of HSP 70 occurred in neurons that survived to that point, but it did not participate in early responses for neuronal survival after global cerebral ischemia.

Ischemic delayed neuronal death. A mitochondrial hypothesis

BACKGROUND

A brief period of global brain ischemia causes cell death in hippocampal CA1 pyramidal neurons days after reperfusion in rodents and humans. Other neurons are much less vulnerable. This phenomenon is commonly referred to as delayed neuronal death, but the cause has not been fully understood although many mechanisms have been proposed.

SUMMARY OF REVIEW

Hippocampal CA1 neuronal death usually occurs 3 to 4 days after an initial ischemic insult. Such a delay is essential for the mechanism of this type of cell death. Previous hypotheses have not well explained the reason for the delay and the exact mechanism of the cell death, but a disturbance of mitochondrial gene expression could be a possibility. Reductions of mitochondrial RNA level and the activity of a mitochondrial protein, encoded partly by mitochondrial DNA, occurred exclusively in CA1 neurons at the early stage of reperfusion and were aggravated over time. In contrast, the activity of a nuclear DNA-encoded mitochondrial enzyme and the level of mitochondrial DNA remained intact in CA1 cells until death. Immunohistochemical staining for cytoplasmic dynein and kinesin, which are involved in the shuttle movement of mitochondria between cell body and the periphery, also showed early and progressive decreases after ischemia, and the decreases were found exclusively in the vulnerable CA1 subfield.

CONCLUSIONS

A disturbance of mitochondrial DNA expression may be caused by dysfunction of the mitochondrial shuttle system and could cause progressive failure of energy production of CA1 neurons that eventually results in cell death. Thus, the mitochondrial hypothesis could provide a new and exciting potential for elucidating the mechanism of the delayed neuronal death of hippocampal CA1 neurons.

Phenytoin inhibits expression of microtubule-associated protein 2 and influences cell-viability and neurite growth of cultured cerebellar granule cells

The objective of this study was to show whether an in vitro model for Phenytoin-related cytoskeletal impairment could be helpful to investigate cerebellar side effects of Phenytoin (DPH). DPH dose-and time-dependently resulted in decreasing numbers of vital cells. Cells formed only a rarefied intercellular neuritic network. This effect was already evident 24 h after plating. Western-blot analysis revealed that the expression of the dendritic marker microtubule-associated protein 2 (MAP2) was dramatically decreased in DPH-treated cultures.

Immunocytochemical and in situ hybridization approaches to the optimization of brain slice preparations

Methods are described for determining the expression of specific mRNAs and proteins in brain slices, in order to elucidate changes in gene expression during preparation of vibratome slices from hippocampus of adult rats. In situ hybridization with 35S-labeled oligonucleotides was used to evaluate the level and distribution of c-fos and hsp72 mRNAs in 15-microns frozen sections prepared from these slices. Commercially available antibodies were used to examine the distribution of induced Fos and Jun proto-oncogenes as well as expression of the neuronal cytoskeletal protein, microtubule-associated protein 2 (MAP2), in 50-microns vibratome sections from immersion-fixed slices. These studies confirm the induction of c-fos and hsp72 mRNAs during routine incubation, as previously observed in hippocampal slices obtained with a tissue chopper and incubated under somewhat different conditions, indicating that such responses are likely to be common features of many slice preparations. Accumulation of Fos and Jun immunoreactivities in neurons and glia was generally consistent with the distribution of c-fos mRNA induction observed in slices, and the neuronal component of this response was comparable to the expression of these proteins observed after transient ischemia in vivo. MAP2 immunoreactivity detected in the dendritic processes of neurons tended to show an increase in staining intensity during slice incubation, although loss of dendritic staining in specific regions was occasionally observed in association with the absence of Fos and Jun expression and histological evidence of neuron damage. These results support the use of MAP2 immunoreactivity as a sensitive indicator of neuronal integrity in slices.(ABSTRACT TRUNCATED AT 250 WORDS)

A synaptic vesicle-associated protein (SVP-38) as an early indicator of delayed neuronal death

Sixteen gerbils were subjected to 5 min of forebrain ischemia. Their brains were processed for immunohistochemical staining using monoclonal antibodies against a synaptic vesicle-associated protein 38 (SVP-38) and microtubule-associated protein 2 (MAP2) after recirculation times of 10 min, and 1, 4, and 7 days. After 10 min recirculation, SVP-38 immunoreactive dots were observed only in the CA1 region of the hippocampus. After 1 day recirculation, SVP-38 immunostaining was diffuse and weak throughout the hippocampus, despite preservation of MAP2 immunoreactivity. After 4 and 7 days recirculation, SVP-38 immunoreactivity had been restored in the whole hippocampus, despite the complete loss of MAP2 immunoreactivity due to delayed neuronal death. Our results demonstrate an immediate and significant change in the immunoreactivity of a synaptic vesicle-associated protein at the beginning of the process of delayed neuronal death. Thus, changes in the immunoreactivity of synaptic vesicle-associated proteins such as SVP-38 appear to be one of the earliest indicators of the onset of neuronal death.

Expression of beta-actin and alpha-tubulin mRNA in gerbil brain following transient ischemia and reperfusion up to 1 month

The time course of mRNA expressions of two cytoskeletal proteins, beta-actin and alpha-tubulin, was studied by Northern blot analysis and in situ hybridization in the same gerbil brains at various periods of recirculation following 10 min of forebrain ischemia. On Northern blot analysis, beta-actin mRNA in the forebrain showed increase after 6 h and 24 h recirculation. There was wide variation in its expression 3 days postischemia (PI), and by 7 days PI it had returned to control. The alpha-tubulin mRNA in the forebrain was shown to be reduced 6 h PI in our previous study. In the present analysis of Northern blots of delayed postischemic periods, there was no significant change in its expression even though there were variations. In situ hybridization revealed a decline in the mRNA expressions of both alpha-tubulin and beta-actin in the CA1 region as early as 6-24 h PI with the reductions being prominent at 3 days PI. By 7 days PI, beta-actin was only faintly visible while alpha-tubulin was completely absent in the CA1 region. Neither RNA was detectable in CA1 1 month PI. The heat shock-70 protein was expressed by 1 h PI, and it continued to be expressed up to 24 h, returning to control by 3 days PI. These results indicate that ischemia inhibits mRNA expressions of cytoskeletal protein in the selectively vulnerable region of the brain, i.e. CA1. The time course of the reduction of the two mRNAs coincides with delayed neuronal death suggesting that the cytoskeletal proteins may play important roles in selective postischemic neuronal injury.

Reexpression of developmentally regulated MAP2c mRNA after ischemia: colocalization with hsp72 mRNA in vulnerable neurons

Levels of mRNAs encoding the microtubule-associated proteins MAP2b and MAP2c as well as the 70-kDa stress protein [72-kDa heat shock protein (hsp72)] were evaluated in postischemic rat brain by in situ hybridization with oligonucleotide probes corresponding to the known rat sequences. Rats were subjected to 10-min cardiac arrest, produced by compression of major thoracic vessels, followed by resuscitation. The normally expressed MAP2b mRNA showed transient twofold elevations in all hippocampal neuron populations at 6-h recirculation, followed by a return to control levels by 24 h. MAP2b hybridization was progressively lost thereafter from the vulnerable CA1 and outer cortical layers, preceding both the fall in immunoreactive MAP2b and the eventual cell loss in these regions. The depletion of MAP2b mRNA coincided with an increase in the alternatively spliced MAP2c in vulnerable regions during 12-48 h of recirculation, precisely overlapping the late component of hsp72 expression that persisted in these cell populations. Previous studies have suggested that the initial induction of hsp72 provides an index of potential postischemic injury in neuron populations that may or may not be injured, while lasting hsp72 mRNA expression is associated with cell damage. In contrast, the present results demonstrate that MAP2c expression under these conditions occurs uniquely in neuron populations subject to injury. Available evidence suggests that MAP2c expression represents a plastic response in subpopulations of neurons that will survive in these regions, although it remains to be explicitly determined whether it may also be transiently expressed in dying cells. In any case, these observations demonstrate that reexpression of developmentally regulated MAP2c mRNA is a relatively late postischemic response in vulnerable cell populations, indicating that pathways regulating MAP2 splicing may be closely associated with mechanisms of neuron injury and/or recovery.

Early immunohistochemical changes of microtubule based motor proteins in gerbil hippocampus after transient ischemia

Changes of immunoreactivities for microtubule based motor proteins, kinesin and cytoplasmic dynein, and non-motor protein, microtubule associated protein (MAP) 2 were investigated in gerbil hippocampus after transient ischemia. The immunoreactivities for kinesin showed a progressive decrease in hippocampal CA1 cells from 8 h after transient 5 or 15 min of ischemia that is lethal to the CA1 cells, while it showed no change after 2 min of ischemia that is non-lethal to the cells. The immunoreactivities for cytoplasmic dynein showed a decrease from 3 or 1 h of reperfusion in the CA1 cells after 5 or 15 min of ischemia, respectively. In contrast, the immunoreactivity for MAP2 remained normal until 2 days in the CA1 cells after 5 min of ischemia. These results showed an early changes of microtubule based motor proteins, such as kinesin and cytoplasmic dynein in vulnerable CA1 neurons. These changes may affect the mitochondrial shuttle system between neuronal cell body and the peripheries such as axon terminal and dendrites. This early disturbance may cause a failure to obtain newly synthesized nuclear encoded mitochondrial protein, and result in mitochondrial dysfunctions and the subsequent cell death.

Golgi electron microscopic study of the cerebral cortex after transient cerebral ischemia and reperfusion in the gerbil

Fine structures of defined neurons and their dendritic processes were studied in the cerebral cortex of gerbil brains by using Golgi electron microscopy during progressive cerebral ischemia for 10 and 20 min and after reperfusion for up to 72 h following transient ischemia for 20 min. The periphery of ascending dendrites of the vulnerable neurons in layers III and Vb became distended immediately after ischemia with swollen mitochondria and disintegrated microtubules, but the proximal portion of the same dendrites remained unchanged. After reperfusion for 6 h, distension of the dendroplasm of the impregnated dendrites in layer I receded, but the proximal portion of the same dendrites showed indentation caused by swollen astrocytic processes and derangement of microtubules inside. Polyribosomes in most neuronal perikarya were disaggregated, but severe neuronal damage was rarely found among those neuronal cell bodies impregnated by the Golgi method. Recovery with reaggregation of polyribosomes and realignment of microtubules was more clearly observed after reperfusion for 24 h and thereafter in impregnated neurons. These results indicated that impregnation during progressive ischemia occurred in many neurons with progressive structural damage but that impregnation during reperfusion occurred in a limited number of neurons with limited damage, allowing us to observe the recovery process, and that neuronal derangement in the dendrosomatic direction initially occurred both in the irreversibly damaged neurons and in the reversibly damaged ones. It is possible that disintegration of microtubules and the resulting disruption of dendritic transport may contribute to subsequent development of delayed neuronal death, if the recovery process does not take place promptly. Golgi electron microscopy is useful for ultrastructural investigation of defined neurons and their dendrites together and may be applicable for investigation of selected neuropathologic conditions.

Alterations in tau immunostaining in the rat hippocampus following transient cerebral ischemia

Previous studies in gerbils have shown that cytoskeletal disruption and a loss of the dendritic microtubule-associated protein, MAP2, may occur after short periods of transient global ischemia. tau, a predominantly axonal microtubule-associated protein, has not been examined following ischemia. We compared neuronal damage with alterations in MAP2, tau, and 72-kD heat shock protein (HSP72) immunostaining at various reperfusion times following 20 min of ischemia in the rat four-vessel occlusion model. tau accumulated in neuronal cell bodies throughout the hippocampal formation 30 min to 2 h after the ischemic insult. Perikaryal tau immunostaining was transient in most regions, but persisted in polymorphic hilar neurons. This was accompanied by a loss of immunostaining in the target of many hilar neurons, the inner molecular layer of the dentate gyrus. The same neuronal populations that exhibited increased tau immunostaining of perikarya later displayed an induction of HSP72 immunoreactivity. In contrast, loss of MAP2 immunostaining was not consistently observed before neuronal death and did not correspond to HSP72 induction. The altered tau immunostaining is not the direct result of excitotoxic insult, as intrahippocampal injection of kainic acid did not cause the somal accumulation of tau, but did cause disruption of MAP2 immunostaining. Taken together, the results suggest that the somal accumulation of tau is an early, sensitive, and selective marker of ischemic insult.

Postmortem changes in the levels and localization of microtubule-associated proteins (tau, MAP2 and MAP1B) in the rat and human hippocampus

The neuronal cytoskeleton is disrupted in neurodegenerative disorders such as Alzheimer's disease. Due to the lack of suitable animal models, studies examining the events involved in the neurodegeneration have relied on postmortem human brain tissue obtained from individuals with the disease and from normal controls. However, it is uncertain if the neuronal cytoskeleton is stable during the postmortem interval. Immunohistochemistry and immunoblots were used to examine the microtubule-associated proteins tau, MAP2, and MAP1B in the rat hippocampus at various times after death. Shortly after death, tau immunoreactivity was lost from axons and accumulated in somatodendritic compartments. MAP2 and MAP1B also accumulated in neuronal cell bodies prior to a loss of immunostaining in some regions, notably subiculum. Immunoblots confirmed a loss of MAP2 and MAP1B within a few hours after death. Tau levels remained constant during the 8-hour postmortem interval examined, although the electrophoretic mobility of some tau bands was altered. Human brain tissue obtained at autopsy and at surgery demonstrated similar cytoskeletal alterations in postmortem tissue. These results demonstrate that microtubules and associated proteins are not stable postmortem.

Effects of intrahippocampal colchicine administration on the levels and localization of microtubule-associated proteins, tau and MAP2

Colchicine, a microtubule disrupting agent, has been used to model several aspects of Alzheimer's disease-related neuropathology. The formation of neurofibrillary tangles, one of the pathological hallmarks of Alzheimer's disease, involves the loss of tau (a low mol. wt. microtubule-associated protein) from axons and accumulation of abnormally phosphorylated tau in somatodendritic compartments. Other cytoskeletal proteins, such as microtubule-associated protein 2 (MAP2), disappear as tau accumulates. The present study was directed at evaluating the effects of colchicine on tau and MAP2, to determine if changes in their levels or distribution might be similar to those which precede the formation of neurofibrillary tangles in Alzheimer's disease. Six hours following intrahippocampal colchicine injection (3.5 micrograms injected into two rostro-caudal locations) tau-1 immunostaining was enhanced in CA1 s. radiatum and decreased in the outer molecular layer of the dentate gyrus. In addition, a shift in the relative abundance of tau isoforms was observed in Western blots. Both the immunocytochemical and immunoblot results are consistent with a dephosphorylation of tau. Loss of MAP2 was evident 3 days postinjection which coincided with a loss of Cresyl violet staining in granule cell, CA3, subicular and entorhinal neurons. Accumulation of tau or MAP2 in neuronal perikarya was not observed at any postinjection time points. Thus, intrahippocampal colchicine administration does not model the shift in tau localization, excessive tau phosphorylation, or other cytoskeletal alterations that are suggested to precede or accompany the formation of neurofibrillary pathology in Alzheimer's disease.

Glutamate, beta-amyloid precursor proteins, and calcium mediated neurofibrillary degeneration

In this article we present evidence supporting the interaction between excitotoxicity, beta APP mismetabolism, metabolic compromise and intracellular calcium destabilization in the process of neurodegeneration associated with Alzheimer's disease (AD). AD is characterized by the presence of neurofibrillary tangles and amyloid-containing plaques in specific regions of the brain. There appear to be several processes which contribute to the neurodegeneration associated with AD. Although AD has been linked to genetic mutations on chromosomes 21, 19 and 14, there are sporadic forms of AD that have no known genetic mutation involved. Aging is the major risk factor for AD. During the course of normal aging several metabolic compromises may occur in the brain. Both decreased glucose transport and utilization, and increased glucocorticoid levels are known to occur with aging and may lead to decreased energy supplies, ATP depletion, failure of Ca2+ buffering systems, excess glutamate release and activation of glutamate receptors. In addition, a reduction in antioxidant enzymes and consequently an increase in free radicals has also been associated with aging. Each of the preceeding alterations would lead to an increase in neuronal [Ca2+]i. Elevated calcium could then activate calcium-dependent proteases which degrade particular cytoskeletal proteins, and lipases which generate free radicals resulting in membrane damage and possible cell death. In this article we provide evidence that amyloid beta-peptide (A beta), the substance which accumulates in AD plaques, exacerbates excitotoxic and metabolic compromises to neurons resulting in changes in the cytoskeleton which resemble those seen in the neurofibrillary tangles of AD. We also provide evidence that secreted forms of beta-amyloid precursor protein (beta APP) are neuroprotective against excitotoxic insults. Recent findings concerning the normal function of beta APP and the mechanism of A beta toxicity place beta APP at the center of changes leading to neuronal degeneration in AD.

Immunohistochemical patterns of selective cellular vulnerability in human cerebral ischemia

Although specific patterns of cellular vulnerability have been identified in experimental models of cerebral ischemia, there is little data on the occurrence of similar abnormalities in human ischemia. We therefore used a variety of histochemical methods to define changes affecting specific classes of cells in post-mortem specimens from seven patients with hippocampal and neocortical ischemic lesions. In acute lesions, staining with SMI-32, an antibody directed against nonphosphorylated neurofilaments that labels pyramidal projection neurons, was prominently depleted even when conventional Nissl staining revealed only mild pyknosis. In contrast, staining for other markers such as microtubule-associated protein 2 (MAP-2), another cytoskeletal protein, or parvalbumin, a calcium-binding protein found in gamma-aminobutyric acid (GABA)-ergic interneurons, were relatively preserved. SMI-32 antibody also labeled dystrophic axons and axonal retraction balls in and around acute ischemic lesions. The pattern of differential changes in immunoreactivity was essentially the same in all acute ischemic injuries, including both diffuse lesions in the CA1 field (Sommer's sector) and discrete infarcts in CA1 and neocortex. In addition, immunoreactivity for the immediate early gene product c-fos was enhanced in and around the acute ischemic lesions that we studied. In some very acute lesions, immunoreactivity for glial fibrillary acidic protein (GFAP) was depleted in areas of severe ischemia and necrosis, but, as expected, GFAP immunoreactivity was increased in lesions more than a few days old. In contrast, the loss of SMI-32 immunoreactivity persisted in chronic lesions. These findings are consistent with those of experimental ischemia in animals and confirm the relevance of these studies for human cerebral ischemia. The pattern of selective changes also resembles that of injuries induced directly by excitatory amino acids, which may play a significant role in the pathogenesis of ischemic damage.

Comparison of alpha-tubulin mRNA and heat shock protein-70 mRNA in gerbil brain following 10 min of ischemia

In situ hybridization and Northern blot analysis were used to characterize the mRNA expression of alpha-tubulin, a neuroprotein crucial for neuronal structural and functional restoration, in comparison to that of the stress inducible heat shock protein-70 (HSP-70), in the same gerbil brain following 10 min of forebrain ischemia. The HSP-70 expression was noted in the dentate granule layer 1 h postischemia (PI) and became prominent in all pyramidal cell fields of the hippocampus in addition to the dentate layer at 6 h PI. The induction of HSP-70 persisted in CA1 and CA2 regions and partly in dentate gyrus for up to the 1 day PI period examined. There was no significant HSP-70 expression in any of the regions of the nonischemic or 15 min PI brain. alpha-Tubulin, on the other hand, was expressed in all pyramidal fields of the hippocampus as well as dentate gyrus in nonischemic controls. A decline was noted in the CA1 region 1 h PI onward and was maximal at 6 h PI. Its expression, however, increased at 24 h PI (significant only in comparison to 15 min and 6 h PI but not to control) when it became rather strong in the dentate gyrus. Thus, the temporal pattern of expression of alpha-tubulin sharply contrasted with that of HSP-70 in the PI brain as it declined in the vulnerable CA1 region during the 1st 24 h PI, i.e., the period when HSP-70 was induced and its expression was lowest in the 6 h group when HSP-70 peaked. It was maximum in the dentate gyrus at 24 h PI when HSP-70 was marginally detectable in that region. These studies indicate that in early recirculation period following prolonged ischemia, HSP-70 mRNA is expressed in both vulnerable regions as well as in regions of the brain that are destined to survive while alpha-tubulin is diminished in vulnerable regions. These data suggest a positive correlation between the loss of alpha-tubulin mRNA and delayed neuronal necrosis that follows in the vulnerable CA1 region.

Acute anoxia-induced alterations in MAP2 immunoreactivity and neuronal morphology in rat hippocampus

Cerebral ischemia induces major neuronal morphological alterations. It is not clear, however, whether this is directly caused by O2 deprivation. To determine the effect of hypoxia on cytoskeletal structures and neuronal morphology, we performed experiments and examined anoxia-induced changes in microtubule-associated protein 2 (MAP2) and cell morphology in hippocampal slices in vitro. Anoxia (measured PO2 = 0 Torr) induced a marked loss in dendritic MAP2 immunoreactivity and cell swelling of hippocampal neurons by 2 h after O2 reinstitution. These changes were severe in CA1 and CA3 neurons and comparatively mild in dentate gyrus neurons. Quantitative analysis showed that 10 min of anoxia induced a 30% loss of MAP2-positive dendrites but this increased to 70% after 30 min of anoxia. A concurrent major increase in somata area of about 100% and 200% was observed in CA1 and CA3 neurons respectively. Somata area in the lower dentate gyrus, however, increased either insignificantly or by only 30% for the respective periods of anoxia. These results suggest that deprivation of O2 can by itself induce a major loss in dendritic MAP2 immunoreactivity and changes in cell morphology in hippocampal neurons. These alterations occur rapidly after hypoxia, and the severity of these changes is directly related to the duration of anoxia and brain region in the hippocampus.

Identity of the dorsal hippocampal region most vulnerable to cerebral ischemia

Our previous investigations demonstrated that neurons in the area between the subiculum and the medial CA1 region and another area between the lateral CA1 and the CA3 region of the hippocampus are very vulnerable to cerebral ischemia in gerbils, where irreversible damages have been observed occur as early as 4-5 min after unilateral or bilateral common carotid artery occlusion. The present study was aimed to characterize these areas anatomically by using the immunohistochemical and zinc histochemical as well as Golgi silver impregnation methods. Our results indicated that these two areas which are topographically apart on the coronal section actually had a common origin in the rostral part of the hippocampus and that they were separated by insertion of the Ca1 neurons between them in the more caudal part of the hippocampus. The distribution pattern of mossy fibers indicated that these areas belonged to the CA2 region. The double immunohistochemical and zinc histochemical procedure confirmed that these areas developed ischemic lesions promptly even without reperfusion but that the CA1 region did not develop similar lesions until after reperfusion for 12-24 h if the ischemic period was brief. While the reason for the observed susceptibility of the CA2 region is not certain at the present time, it is important to distinguish the ischemic lesions in the CA2 region from those in the CA1 and CA3 regions.

Electron microscopic investigation of the cerebral cortex after cerebral ischemia and reperfusion in the gerbil

Prompt dendritic damage has been observed in the hippocampus of the gerbil brain after transient cerebral ischemia. In the present study, we studied the frontoparietal cortex of the gerbil brain electron microscopically after brief bilateral carotid occlusion to assess the vulnerability of dendritic processes. After ischemia for 5 min, there was swelling of the periphery of dendrites accompanied by swelling of mitochondria, cytoplasmic vacuolation and disintegration of microtubules in layer I, which spread to layer III after ischemia for 20 min. After reperfusion for 3-24 h following ischemia for 20 min, swelling in the periphery of dendrites and of mitochondria inside receded but vacuole formation and disintegration of microtubules propagated proximally. In neuronal perikarya, polyribosomal disaggregation was observed after ischemia for 20 min and persisted thereafter, while fragmentation of rough endoplasmic reticulum (ER) and microvacuolation occurred after reperfusion for 3 h. Electron-dense clumping of neuronal perikarya was observed after reperfusion for 6 h particularly in layers III and Vb, which increased in number for up to 72 h. The observed progressive damage in dendrites may be common to neurons vulnerable to cerebral ischemia and may significantly contribute to development of delayed neuronal death.

Silver impregnability of ischemia-sensitive neocortical neurons after 15 minutes of cardiac arrest in the dog

The development of postischemic neuronal argyrophilia and the subsequent fate of argyrophilic neurons were studied in dogs after 15 min of complete cerebral ischemia and survival varying from 1 h to 7 days. Histopathological examination of the vulnerable neocortical region was performed using the Nauta degeneration method, and the time course of cellular changes was described. Clear-cut neuronal argyrophilia was found to precede cell body shrinkage and gradual disintegration corresponding to selective neuronal death. To clarify this initial stage of neuronal impregnability, the samples from the animals surviving 8 h postarrest were stained with toluidine blue or processed for electron microscopy, and the distribution of argyrophilic cells was confirmed to be identical with that of hyperchromatic or electron-dense cells. On the other hand, infrequently observed "tissue infarctions" exhibited no silver affinity in spite of apparent cellular damage. These findings indicate that enhanced impregnability is related to cytochemical processes incidental to the phenomenon of "selective neuronal death", which can be readily detected by the Nauta method.