The Effect of Simvastatin on the Dynamics of NF-κB-Regulated Neurodegenerative and Neuroprotective Processes in the Acute Phase of Ischemic Stroke.

Statins are lipid-lowering drugs that act by inhibiting 3-hydroxy-3-methylglutaryl coenzyme A reductase, a rate-limiting enzyme in cholesterol biosynthesis. Animal studies have shown neuroprotective effects of statins in cerebral stroke. However, the underlying mechanisms are not fully understood. The nuclear factor-kappa B (NF-κB) transcription factor is involved in the regulation of apoptosis in stroke. Different dimers of NF-κB regulate the gene expression of proteins involved in both neurodegeneration and neuroprotection. We aimed to determine whether simvastatin improves stroke outcome via inhibition of the RelA/p65-containing subunit and downregulation of stroke-induced pro-apoptotic genes or via activation of NF-κB dimers containing the c-Rel subunit and upregulation of anti-apoptotic genes during the acute stroke phase. Eighteen-month-old Wistar rats, subjected to permanent MCAO or sham surgery, were administered simvastatin (20 mg/kg b.w.) or saline for 5 days before the procedure. Stroke outcome was determined by measuring cerebral infarct and assessing motor functions. The expression of NF-κB subunits in various cell populations was investigated using immunofluorescence/confocal microscopy. RelA and c-Rel were detected by WB. The NF-κB-DNA binding activity was investigated using EMSA, and expression of Noxa, Puma, Bcl-2, and Bcl-x genes was analyzed by qRT-PCR. Results showed a 50% infarct size reduction and significant motor function improvement in the simvastatin-treated animals which correlated with a decrease in RelA and a transient increase in the c-Rel level in the nucleus, normalization of the NF-κB-DNA binding activity, and downregulation of the NF-κB-regulated genes. Our results provide new insights into the statin-mediated neuroprotective action against stroke based on NF-κB pathway inhibition.

The molecular mechanisms of cell death in the course of transient ischemia are differentiated in evolutionary distinguished brain structures.

There is large body of evidence suggesting distinct susceptibility to ischemia in various brain regions. However, the reason for this remains unexplained. Comparative studies of programmed cell death (PCD) pathways indicate their differentiated evolutional origin. The caspase-independent pathway is regarded as an older, whereas the caspase-dependent--as more advanced. In our study we address the question of whether there are any characteristic differences in the activation and course of PCD in phylogenetically and morphologically distinguished brain structures after transient focal ischemia. Using Western blot, we studied changes in expression of caspases: 3, 8, 9, and AIF in the frontoparietal neocortex, archicortex (CA1 and CA2 sectors of the hippocampus) and striatum, during reperfusion after 1 h occlusion of the middle cerebral artery. The caspase and AIF expression were differentiated between the studied structures. The activation of only the caspase-dependent pathway was observed in the neocortex. In the archicortex and striatum both caspase-dependent and caspase-independent pathways were activated, although in the latter the extrinsic apoptotic pathway was not activated. In summary, it is conceivable that structures of different evolutionary origin undergo cell-death processes with the participation of phylogenetically distinguished mechanisms. The previously reported unequal susceptibility to ischemia may co-exist with activation of different cell death pathways.

The anatomical relationships between the serotonergic afferents and the neurons containing calcium-binding proteins in the rat claustrum.

Claustrum is a telencephalic structure integrating information of various modalities. Proper functioning of this structure depends on the presence of a network of intrinsic connections. This includes GABA-ergic neuronal populations that also contain calcium-binding proteins (CaBPs). The goal of this study was to analyze qualitative and quantitative the 5-HT-containing fibers in the rat claustrum and to assess the relationships between these fibers and the populations of claustral neurons expressing CaBPs. We used the methods of immunocytochemistry and morphometry. The serotonergic fibers in the claustrum are heterogeneous, both with respect to their morphology and spatial distribution. Thin varicose fibers are more numerous and are homogeneously distributed within the claustrum. Remaining fibers were thicker and possessed larger varicosities. They were present mainly in the ventral part of the claustrum. Although the serotonergic fibers are found in the vicinity of claustral cells containing CaBPs, direct contacts between these fibers and cells are rare. Other mechanisms, including volume transmission, may possibly mediate serotonergic influences.

Morphological Changes within the Rat Lateral Ventricle after the Administration of Proteasome Inhibitors.

The broad variety of substances that inhibit the action of the ubiquitin-proteasome system (UPS)-known as proteasome inhibitors-have been used extensively in previous studies, and they are currently frequently proposed as a novel form of cancer treatment and as a protective factor in intracerebral hemorrhage treatment. The experimental data on the safest route of proteasome inhibitor administration, their associated side effects, and the possible ways of minimizing these effects have recently become a very important topic. The aim of our present study was to determine the effects of administering of MG-132, lactacystin and epoxomicin, compounds belonging to three different classes of proteasome inhibitors, on the ependymal walls of the lateral ventricle. Observations were made 2 and 8 weeks after the intraventricular administration of the studied substances dissolved in dimethyl sulfoxide (DMSO) into the lateral ventricle of adult Wistar rats. Qualitative and quantitative analysis of brain sections stained with histochemical and inmmunofluorescence techniques showed that the administration of proteasome inhibitors caused a partial occlusion of the injected ventricle in all of the studied animals. The occlusion was due to ependymal cells damage and subsequent ependymal discontinuity, which caused direct contact between the striatum and the lateral nuclei of the septum, mononuclear cell infiltration and the formation of a glial scar between these structures (with the activation of astroglia, microglia and oligodendroglia). Morphologically, the ubiquitin-positive aggregates corresponded to aggresomes, indicating impaired activity of the UPS and the accumulation and aggregation of ubiquitinated proteins that coincided with the occurrence of glial scars. The most significant changes were observed in the wall covering the striatum in animals that were administered epoxomicin, and milder changes were observed in animals administered lactacystin and MG-132. Interestingly, DMSO administration also caused damage to some of the ependymal cells, but the aggresome-like structures were not formed. Our results indicate that all of the studied classes of proteasome inhibitors are detrimental to ependymal cells to some extent, and may cause severe changes in the ventricular system. The safety implications of their usage in therapeutic strategies to attenuate intracerebral hemorrhagic injury and in brain cancer treatment will require further studies.

Neuropeptide-containing neurons in the endopiriform region of the rat: morphology and colocalization with calcium-binding proteins and nitric oxide synthase.

The endopiriform nucleus, further divided into dorsal and ventral parts, and the neighbouring pre-endopiriform (pEn) nucleus form a region of highly heterogeneous structure involved in numerous physiological and pathological processes. Nonpyramidal neurons of this region containing three neuropeptides-somatostatin (SOM), neuropeptide Y (NPY), and vasoactive intestinal peptide (VIP)-were examined in this study. Their colocalization with three calcium-binding proteins-parvalbumin (PV), calbindin D28k (CB), calretinin (CR), and with nitric oxide synthase (NOS), was investigated by qualitative and quantitative methods. The results are summarized as follows: (1) all studied substances are distributed in neurons of the entire region, (2) SOM-ir neurons constitute the most numerous neuropeptide-containing population, whereas NOS-ir neurons make up the largest population of all studied, (3) colocalizations are found in the endopiriform region (Enr) (SOM with CB, PV and NOS; VIP with CR; NPY with NOS and NOS with CR), (4) heterogeneity of the endopiriform region appears in the differences of cells' shape distributions of single-labeled (SOM-, CR-PV-ir) and double-labeled (SOM/CB-, SOM/PV-, NPY/NOS- and NOS/CR-ir) neurons, as well as in differentiated percentage values of SOM/NOS, NPY/NOS and VIP/CR double-labeled neurons in three studied parts; additionally, differences in distribution of immunoreactive neuropil elements between parts of the region are observed. Numerous regional differences concerning neuronal morphology and immunocytochemical characteristics justify further division of the endopiriform region into distinguished parts. Some immunocytochemical features of the neurons in studied region may contribute to the role in epileptogenesis.

Qualitative and quantitative study of the postnatal development of the rabbit claustrum.

The morphometric analysis of changes occurring in the rabbit claustrum in the early postnatal period was performed by means of unbiased stereological methods. Material consisted of 40 animals aged from P2 to P180 (P-postnatal day) divided into eight groups. The volume of the claustrum, total number and numerical density of its neurons change very rapidly at the beginning of the postnatal life and stabilize by about the fourth week. From the 21st postnatal day distribution and morphology of neurons correspond to that in adults. Almost from the beginning of the postnatal life the rabbit claustrum is composed of three different parts: anterior, central and posterior. The anterior part is the largest and it consists mainly of fusiform, pyramidal and multipolar neurons. The central part is generally composed of oval neurons. The posterior part is the smallest; the distribution of its neuronal types is similar to that in the anterior one. Rapid morphological changes of the claustrum and its neurons occurring during the first postnatal month seem to point out that this structure is able to fulfill its physiological role after this critical period.

Developmental changes of synaptic proteins expression within the hippocampal formation of the rat.

A properly structured neuronal network, which is a prerequisite of a correctly functioning central nervous system, depends on the proper construction of synaptic terminals. There are some studies concerning development of hippocampal cells, however, the data about maturation of the synaptic terminals network within the hippocampal formation are only fragmentary. The study was performed on Wistar rats of various ages. The following synaptic proteins: synaptophysin, SNAP-25 and GAP-43 (a growth axon cone protein) were used to study the maturation of synaptic terminals. We have found that, at the time of birth, the hippocampal formation is very immature. Synaptogenesis begins on P4 and lasts till P10 or P14. The strongest immunoreactivity of all proteins is observed at the beginning of this period. Thereafter, immunoreactivity decreases and, after P14, it is similar to that of adult animals. On P60 and P90, the level of immunoreactivity increases again. In the pyramidal and granular cell layers, the formation of synaptic terminals and their maturation occur earlier in embryonal life, and are almost completely mature at birth.

Distribution of immunoreactivity of calcium-binding proteins in the rabbit piriform cortex.

The piriform cortex has been extensively studied due to its possible role in epileptogenic activity. Neurones containing calcium-binding proteins (CaBPs), as a component of inhibitory circuitry, seem to be critically involved in this pathological process. The aim of the present study was to characterise the pattern of distribution of CaBPs-immunoreactivity in the piriform cortex of the adult rabbit. It comprises labelled cells, fibres (often with varicosities) and terminals. It varies among the layers. Moreover, the distribution of the parvalbumin- and calretinin-immunoreactive fibres and terminals allows even further subdivision of the layer I into two sublayers. Calretinin-ir neurones are located in subpial (Ia) layer, while parvalbumin - as well as calbindin-D28k-ir ones are mainly located in the second and third layer. Cajal-Retzius-like neurones containing calretinin, Chandelier cells containing parvalbumin and basket cells containing calbindin D28k and parvalbumin can be distinguished among labelled subpopulations of CaBPs neurones. In general, the pattern of PV- CR- and CB-immunoreactivity is similar to that previously characterised in other mammals, i.e., rats, guinea pigs, hedgehog, and tenrecs. The pattern is organised in topographic fashion confirming the complexity of regulatory circuits in the rabbit piriform cortex.

Changes in the volume of temporal lobe structures related to Alzheimer's type dementia.

We compared the volumes of the superior temporal gyrus, basolateral temporal area, parahippocampal gyrus, hippocampal head, amygdaloid body and the inferior horn of the lateral ventricle in 29 patients with dementia of Alzheimer's type (DAT) and in 14 cognitively normal controls. Measurements were performed on coronal MR images perpendicular to the long axis of the hippocampus then the raw data were normalised for intracranial volume. The volumes of all studied structures were significantly smaller in patients with DAT than in age-matched control group. The differences in the volume between DAT and age-matched control group were the largest for the amygdaloid body and the basolateral temporal area. The discriminant analysis including the volume of both the basolateral area and the left amygdaloid body allows for correct classification of 100% DAT patients and 93% controls. We conclude that the estimation of the volume of the amygdaloid body and basolateral temporal area seems to be the most important factor for DAT diagnosis.

Evolution of microglial and astroglial response during experimental intracerebral haemorrhage in the rat.

Intracerebral haemorrhage is a strong stimulus for both microglial and astroglial activations. There are some important pathophysiological features during haemorrhage that do not occur in ischaemic or traumatic brain injuries, and may influence the dynamics and intensity of glial activation. Studies on the evolution of glial reaction may have practical importance to the introduction of new therapeutic methods for influencing the inflammatory reaction during haemorrhage. Microglial and astroglial responses to experimental intracerebral haematoma were studied in 50 adult rats for 5 minutes after injection of 100 microl autologous arterial blood into the striatum. The survival period varied from 1 to 21 days. Microglial-macrophage lineage cells were immunocytochemically stained with antibodies OX42, OX6 and ED1. The astrocytic population was studied by means of anti-GFAP staining. Changes in cellular morphology and intensity of staining were time-dependent reactions in both microglial and astroglial cells. Strong activation of microglial-macrophage lineage cells revealed with OX6-and OX42-immunoreactivity started during the first postoperative day. The complete pattern of activation for ED1-immunoreactivity was observed from the third postoperative day. At this stage, numerous phagocytic macrophages started to appear in the perihaematoma region. Morphological changes were most intensive during the second postoperative week. The astroglial (anti-GFAP) reaction was observed after the third postoperative day and proceeded less dynamically. The glial reaction gradually stopped but not completely during the period of observation. The early occurrence of glial activation, pattern of morphological changes and characteristic sequence of antigens expression indicate a very intense type of glial reaction. Evolution of glial response to haemorrhage reveals characteristic features. In our opinion, the initial phase of glial activation, comprising 72 hours after the occurrence of haemorrhage, is potentially the most promising period for influencing the extent of glial reaction with therapeutic agents.

Analysis of calcium binding protein immunoreactivity in the claustrum and the endopiriform nucleus of the rabbit.

The present paper describes parvalbumin, calbindin-D28k and calretinin immunoreactivity in the claustrum and endopiriform nucleus of adult rabbits. Studied neuronal populations are characterized by morphological heterogeneity. Four types were identified in each subpopulation of cells containing calcium binding proteins on the basis of the number of processes and their branching pattern. There were no spatial differences in the distribution of cells containing either parvalbumin or calbindin-D28k in the claustrum and endopiriform nucleus. Well documented presence of the various projective zones in the rabbit claustrum did not reflect the specific distribution of neurons containing calcium binding proteins, except those containing calretinin. Their localization may correspond with the limbic zone. We have found that the rabbit claustrum and endopiriform nucleus have different pattern of parvalbumin and calretinin immunoreactivity. The former was more intense in the claustrum and the distribution of cell types was significantly different from that in the endopiriform nucleus. Calretinin-positive cells were observed in the claustrum, while in the endopiriform nucleus they were scarce. The distribution of neither calbindin-D28k-ir neurons nor fibers allowed differentiation of claustrum and endopiriform nucleus. Significant differences between the claustrum and endopiriform nucleus observed in the rabbit might be related with ontogenetic as well as other (functional) factors.

Postnatal development of NOS-ir neurons in the rat claustrum.

The morphological features of nitric oxide synthase (NOS)-containing neurons in the rat claustrum (Cl) were studied during the period of four months after birth. Forty-five animals divided into nine groups, according to survival period (P0, P4, P7, P10, P14, P21, P28, P60, P120) were used in the study. The immunocytochemical staining to neuronal NOS was performed and the material was studied both qualitatively and quantitatively using unbiased stereological methods. Our observations indicate that the process of maturation of NOS-immunoreactive (ir) neurons in Cl takes place during the early postnatal period. We report the increase of numerical density of immunoreactive neurons, changes in neuronal size, expressed by the decrease of the percentage of small neurons with simultaneous increase of the participation of medium-sized neurons and large neurons. In the whole studied period the prevalence of oval and fusiform neurons is observed. However, the increase of the proportion of multipolar neurons takes place. Round neurons are most characteristic in the youngest groups of animals and later become dominated by the developing subpopulations of ir neurons of other shapes. In the anterior, central and posterior parts of Cl, a similar pattern of maturation of NOS-ir neurons is observed. No prevalence of characteristically shaped neurons is observed in any part of Cl. The adult-like pattern of morphological features in the NOS-ir neuronal population in Cl is reached in the third postnatal week. The maturation of NOS-ir neurons in the claustrum is a dynamic process which is not stabilised at the moment of birth. It may be assumed that characteristic changes of the NOS-ir population of neurons may be influential on the physiological processes observed in Cl. These may in particular have some importance for the processes of synaptogenesis and establishing as well as refining of numerous claustral connections with the other structures of the central nervous system.

Co-localisation of NOS with calcium-binding proteins during the postnatal development of the rat claustrum.

An immunocytochemical double-staining method was applied in order to study the co-localisation of nitric oxide synthase (NOS) with three calcium-binding proteins, calbindin D28k (CB), calretinin (CR) and parvalbumin (PV) in the claustrum of the rat during the first 4 months of life (postnatal days: PO-P120). The co-localisation of NOS/PV and NOS/CB is reported. These neurons fall into the category of non-pyramidal cells. Double-labelled NOS/CB neurons are observed in the claustrum starting from P4, whereas double-labelled NOS/PV neurons are observed from P14 onwards. The percentages of double-labelled neurons increase in relation to the age. Double-labelled NOS/CB and NOS/PV neurons, although they do not constitute a numerous population, play an important role in the process of maturation of the claustrum. This is confirmed by the occurrence of these types of neurons at definite stages of maturation and by the increase in their number.

Developmental expression of SNAP-25 protein in the rat striatum and cerebral cortex.

The developmental changes of 25-kDa synaptosomal-associated protein (SNAP-25) expression in the rat striatum and cerebral cortex were examined using Western- blotting and densitometric scanning of immunoblots. Analysis of the striatum extracts from postnatal day 0 (P0) to postnatal day 120 (P120) demonstrated that SNAP-25 is poorly expressed until P14. From this point the expression level gradually increases to reach a maximum on P60 and then decreases. The pattern of SNAP-25 expression in the rat cerebral cortex is different. Two peaks are observed, the first on P10 and the second on P60, after which the expression level decreases. These results appear to confirm the role of SNAP-25 protein in axon outgrowth and synaptogenesis in the nervous system.

Developmental changes of morphology in the basolateral complex of the rabbit amygdala.

The aim of the present study is to follow topographical and morphological changes in the development of the amygdaloid basolateral complex (BLC) in the rabbit. The material consists of 35 brains of New Zealand rabbits of both sexes, divided into 7 age groups (P2-P90). In cresyl violet preparations BLC is already well visible on P2 and is composed of the lateral (divided into dorsolateral and ventromedial divisions), basolateral and homogenous basomedial nuclei. On about the 7th postnatal day it is possible to divide the basomedial nucleus (BM) into dorsal (Bmd) and ventral (BMv) divisions. The topography and subdivisions set on P7 are maintained in further periods of life. The morphology of neurons (shape, dendrites, staining) changes significantly until P21 in all BLC nuclei. Our results indicate that BLC achieves morphological maturity relatively late, which is probably connected with a long creation of emotional memory and regulation of emotional behaviour.

Parvalbumin containing neurons of the piriform cortex in open field stress -- a developmental study in the rat.

In our study we used c-Fos protein (as a marker of cellular activity) to identify whether cells containing parvalbumin (PV) in the piriform cortex (PC) are engaged in the response to stress stimulation and to discover how this expression changes during maturation. The material consisted of Wistar rats of postnatal (P) ages between 0 and 120 days divided into 9 groups: P0, P4, P7, P10, P14, P21, P30, P90, P120. Each group consisted of 5 experimental and 3 control animals. Rats of the experimental groups were exposed to the "open field test" throughout 10 minutes. The control animals were kept in a home cage. Our results showed that c-Fos activity in the open field test was observed in layers II and III of PC after birth. It then increased and stabilised on P30. In the second week of life PV-positive cells were also observed in those layers. These achieved maturity in the 4th week of life. After this time basket-like structures appeared but the level of PV/c-Fos co-localisation was low. Only small differences were observed between the anterior and posterior parts of PC. In the anterior part a higher number of PV-positive neurons, neuropil threads, and basket-like structures and a larger degree of PV/c-Fos co-localisation were observed. Our results suggested that during maturation PV cells are not directly activated in response to stress stimuli but PV neurons via their numerous endings influence the activation of c-Fos-positive cells predominantly in the anterior part of PC.

Do the asymmetry and the size of the structures of the temporal lobe persist in early stages of schizophrenia?

A total of 14 patients of various ages diagnosed with schizophrenia and, as an age-matched control group, 12 healthy subjects were examined using the MRI method of neuro-imaging. The volume of the following structures was evaluated in the right and left hemispheres: the superior temporal gyrus, the basolateral temporal area (the region including the middle temporal gyrus, inferior temporal gyrus and fusiform gyrus), the parahippocampal gyrus, the hippocampal head, the amygdaloid body and the inferior horn of the lateral ventricle. In schizophrenia a significant increase in the volume of the amygdaloid body on both the left and right sides was observed. In the patients, as in the control group, we noticed significant asymmetry between the left and right sides in the volume of the structures studied. The left amygdaloid body was significantly larger than the right, whereas the left hippocampal head and the temporal horn of the lateral ventricle were smaller than the right. Our findings suggest that in the early stages of schizophrenia, despite the increased volume of the amygdaloid body, the asymmetry between the structures of the temporal lobe is still present. However, the changes observed in the temporal lobe could be related to the functional disturbances observed in this disease.

Qualitative and quantitative analysis of the postnatal development of the ventroposterolateral nucleus of the thalamus in rat and rabbit.

The morphometric analysis of changes occurring in the rat and rabbit ventroposterolateral (VPL) nucleus of the thalamus during the postnatal development was performed using unbiased stereological methods. The materials used in the study included 30 Wistar rats and 32 New Zealand rabbits aged from P0 to P180 (P-postnatal day), which were divided into six and eight age groups, respectively. The following stereological parameters of VPL nucleus on the cresyl violet stained sections were determined: volume of the nucleus, numerical density and total number of neurons. The total number of neurons indicated that the development of VPL nucleus in both species ended within the third week of postnatal life. The volume of VPL nucleus increased gradually (by about 2.2 and 5 times in rats and rabbits, respectively) in comparison with the volume of the cerebral hemisphere during the development from P0 to adulthood. The numerical density of VPL neurons decreased rapidly at the beginning of postnatal life and stabilized by the end of the third week. In both species, the gradual increase in the volume of VPL nucleus and the simultaneous decrease in the neuronal density in the first week of postnatal life were mainly caused by changes in the neuropil volume. The total number of cells did not change remarkably during the first postnatal week. However, it decreased significantly during the second week. This decrease was probably due to the naturally occuring cell death. These results show that the most prominent qualitative and quantitative changes in VPL nucleus and its neurons occur during the first two weeks of postnatal life of rats and rabbits. Also, because the thalamocortical relay neurons completely acquire their physiological features, this the most critical period of time for their morphological maturation.

Postnatal development of the somatosensory thalamocortical projection in rat and rabbit--a combined retrograde transport and stereological comparative study.

A comparative quantitative study of the somatosensory thalamocortical connections in the rat and rabbit, labeled with the fluorescent retrograde tracer Fluoro-Gold (FG), was conducted by means of unbiased stereology. FG was injected into the primary somatosensory cortex of the rat and rabbit in different age groups from P0 to P180 (P-postnatal day). The numerical density of retrogradely labeled the ventroposterolateral (VPL) projection neurons was analyzed. A significant decrease in this parameter was observed during the first two weeks of postnatal life in both studied species. Changes of the neuropil volume and selective elimination of early cortical connections stemming from the VPL may possibly cause this process. A withdrawal of axon collaterals from the expanded cortical sites as well as apoptosis (existing both in the VPL and parietal cortex) contribute to a decrease in the numerical density. Our observations allow us to conclude that the thalamocortical somatosensory connections established before the birth undergo significant quantitative changes in both studied species during the first two weeks of postnatal life and this period seems to be crucial for maturation of the thalamocortical loop.