Enzyme cytochemistry of the cerebral microvessel wall

Butyrylcholinesterase activity in the rat forebrain and upper brainstem: Postnatal development and adult distribution

Unlike the development of acetylcholinesterase (AChE) activity, the postnatal development of the activity of the related enzyme butyrylcholinesterase (BuChE) in the rodent brain has not been investigated in a comprehensive manner. The purpose of the present study was to fill this gap. Development of histochemically visualized BuChE activity followed four distinct stages. Between birth and five postnatal days (P0-P5) BuChE staining of very low intensity was present in nearly all neurons in the forebrain and upper brainstem. Substantial BuChE activity was present in the endothelial cells of blood vessels and the cuboidal cells lining the ventricles. At P6-P10, BuChE neuronal staining of high to moderate intensity emerged in many areas, including certain thalamic nuclei (e.g. anterior group), a number of brainstem nuclei, and darkly stained neurons in the olfactory tubercle/piriform cortex. At P11-P17, the staining which emerged in earlier stages was darker and had expanded to include more neurons. A scattered population of BuChE-positive neurons of moderate to high intensity emerged in the neocortex and amygdala. Importantly, at P17, the very light staining present in all neurons since birth was no longer visible. At P18-P30, the number and staining intensity of cortical neurons displayed a gradual increase while the staining in certain thalamic nuclei was substantially decreased or completely disappeared (e.g. ventral lateral nucleus). A prominent feature of this stage was the emergence of BuChE activity in many fiber tracts. At P30, the adult pattern of staining was attained. The transient presence of BuChE activity of very low intensity in all neurons and of higher intensity in thalamic neurons supports the implied role for this enzyme in neuronal development.

The blood supply of the cat's visual cortex and its postnatal development

We examined the blood supply of the cat's visual cortex using alkaline phosphatase histochemistry to demonstrate the capillary endothelial cells. In the adult, layer 4 is marked by a band that is of obviously greater density, extends throughout areas 17 and 18, and ends abruptly at the 18/19 border. We quantified blood vessel density in area 17, observing a 23% greater density in layer 4 than in supragranular and infragranular layers. This difference reflects a laminar difference in metabolic rate. In three animals studied using the metabolic marker 2-deoxyglucose, layer 4 was 25% denser than the other layers. The band of greater density in layer 4 is not present in newborn kittens, but becomes apparent at about 5 weeks of age. Early in development, the endothelial cells form filopodia as the capillaries grow and branch. The density of blood vessels decreases slightly during the first week of postnatal life, but increases between 1 and 6 weeks of age, so that by 6 weeks, the blood supply of the visual cortex resembles that seen in the adult. This pattern resembles that of cortical metabolism seen with 2-deoxyglucose [J. Cereb. Blood Flow Metab. 11 (1991) 35], but the increase in vascular density precedes that in glucose metabolism.

Purification and characterization of metabolically active capillaries of the blood-brain barrier

Microvessels were isolated from bovine and rat cerebral cortex by simple procedures involving mechanical homogenization, differential and density-gradient centrifugation, and chromatography on a column of glass beads. The preparations were composed of short capillaries with a diameter of 1-10 microns. Both purifications were monitored by assaying the activity of the marker enzyme gamma-glutamyl transpeptidase (gamma-GTase). The final bovine and rat preparations were enriched 20- and 14-fold over the homogenate respectively. gamma-GTase activity was measured in different fractions after bovine and rat membranes were solubilized with 0.5% and 0.3% Triton X-100 respectively. Measurement of 5'-nucleotidase and acetylcholinesterase activities indicated very low levels of contamination of the microvessel preparations by glial cells and neurons. The integrity of the capillary membranes was confirmed by the assay of a cytosolic marker enzyme, lactate dehydrogenase. Viability of the microvessels was demonstrated by the presence of detectable levels of adenylates and by tissue respiration induced by glucose and succinate. Comparison of the proteins of homogenized bovine and rat brain cortex with those of purified capillaries separated by SDS/PAGE revealed enrichment of at least three predominant proteins of 14, 16 and 18 kDa in the capillary preparations. It is concluded that these methods allow rapid isolation of small blood vessels of the blood-brain barrier which are suitable for metabolic and structural studies in vitro.

Molecular anatomy of the blood-brain barrier as defined by immunocytochemistry

This review outlines the recent developments and improvements of our knowledge concerning the molecular composition of the BBB as revealed by immunocytochemistry. Data have been accumulated which show that the BBB exhibits a specific collection of structural and metabolic properties which are also found in tight transporting epithelia. This conclusion is substantiated by (i) the implementation of antibodies which recognize proteins of non-BBB origin, to show that these biochemical markers and the functions that they represent are localized in the BBB endothelium; and (ii) the characterization of target molecules to which polyclonal or monoclonal antibodies which have been generated to epitopes of the BBB endothelium or brain homogenates. According to these data the protein assemblies comprising the phenotypical appearance of the BBB can therefore be defined by the particular selection as well as topological expression of common epithelial antigens, rather than the expression of BBB-unique molecular species. In this respect the immunocytochemical data corroborate the physiological assumption that the BBB possesses the character of a specific polarized epithelium. Attention is also given to the description of developmental expression of BBB-related immunomarkers. By collecting the data from different sources we introduce a classification of the BBB marker proteins according to their developmental appearance. Three groups of proteins are classified with respect to their sequential expression around the time of BBB closure: Phase E (early) markers which appear before BBB closure, phase I (intermediate) markers which are expressed at the time of BBB tightening, and phase L (late) markers which are detectable after the closure of the BBB. Such a scheme may to be useful in better defining the maturation process of BBB, which apparently is not a momentary event in brain development, but rather consists of a temporally sequenced process of hierarchically structured gene expression which finally define the molecular properties of the BBB. This process continues even after parturition, especially with regard to the achievement of immunological properties of the mature BBB. By examining the developmental spatio-temporal expression of different BBB markers we conclude that the mechanisms governing the pattern of BBB maturation are not limited to the interactions occurring between glial and endothelial cells. We therefore suggest a heuristic model in a triangular interrelationship that includes differentiation effects of neurons on glia and of glia cells on the BBB endothelium.(ABSTRACT TRUNCATED AT 400 WORDS)

A cytochemical study of cerebrovascular lesions in mice infected with Plasmodium berghei

Mice with a Plasmodium berghei infection exhibit morphological and cytochemical changes in the blood-brain barrier. Changes in activity and localization of alkaline phosphatase and adenosine triphosphatase, enzymes with important functions in the maintenance of the blood-brain barrier, were observed. Changes in activity and localization of those enzymes in and near the endothelial cells of the microvasculature, concomitant with an increase in pinocytotic activity, and formation of irregular cytoplasmic extensions in these cells, as well as loosening of the basal lamina are indicative of a functional deterioration of the blood-brain barrier in the course of infection.

Neuronal localization of pseudocholinesterase in the rat cerebellum: sagittal bands of Purkinje cells in the nodulus and uvula

The histochemical distribution of pseudocholinesterase was studied in the rat cerebellum using Koelle's copper-thiocholine method. Throughout the cerebellum, pseudocholinesterase is uniformly localized in the endothelial cells of blood vessels and in the cell bodies and processes of the Bergmann glia. In addition, we demonstrate that exclusively in the ventral uvula and in the nodulus (lobules IXc and X of Larsell) pseudocholinesterase is localized in a small subpopulation of Purkinje cells. The cell bodies and dendrites of these labeled Purkinje cells form at least 4 distinct parallel bands extending along the sagittal plane of each of the lobules. Two broad bands on either side of the midline, approximately 800-900 microns wide and composed of 15-20 Purkinje cells have been designated as A bands. Two narrower bands, approximately 160-300 microns wide and composed of 5-7 Purkinje cells, on the lateral aspects of the lobules have been designated as B bands. The unique distribution of pseudocholinesterase in a small and anatomically restricted population of neurons suggests that in the cerebellum this enzyme may play a role in the metabolism of neuroactive substances.

Molecular forms of butyrylcholinesterase in the human neocortex during development and degeneration of the cortical cholinergic system

The total levels of butyrylcholinesterase (BChE) activity and, more specifically, the distribution of BChE molecular forms were measured in the human neocortex during fetal development. Both the amount of total activity and the abundance of the different molecular forms (G1 and G4) remained relatively constant between gestational ages of 8-22 weeks and were similar to those observed in samples of cortex from aged brain. In addition, in both Alzheimer-type and parkinsonian dementia, the levels of total BChE activity as well as the relative abundance of the G1 and G4 molecular forms were similar to those observed in control tissue. Hence, both the levels of total activity and the distribution of molecular forms did not change significantly either during fetal development or in the neurodegenerative disorders of Alzheimer-type and parkinsonian dementias. Because these situations are accompanied by changes in the cortical cholinergic system (including an increase and decrease in levels of the G4 form of acetylcholinesterase, respectively), it is concluded that, at least in the human neocortex, BChE is unrelated to cholinergic neurotransmission associated with subcortical cholinergic projection fibres.

Glial cells influence membrane-associated enzyme activity at the blood-brain barrier

Glial cells have been shown to influence several cerebral endothelial cell properties in vitro. A situation similar to the endothelial-astrocyte relationship existing at the blood-brain barrier (BBB) can be produced by growing cultured cerebral endothelium on one side of a filter and glial cells on the other in an enclosed double chamber. In this setting membrane-associated reaction product on the cerebral endothelial cell for both Na+,K+-ATPase and non-specific alkaline phosphatase was markedly increased when the endothelial cells were co-cultured with glial cells. In addition, the distribution of reaction product on the cerebral endothelial cell membrane was similar to that reported in vivo. These observations support a glial influence on enzyme activity at the BBB.

On the composition and characteristics of microvessels isolated from the rabbit and bovine brain

Brain capillaries (microvessels) were isolated from the rabbit and bovine brain. Extensive morphological examinations were performed at the light and electron microscopical levels. The relative contribution of endothelium (52%), basal membrane (32%) and pericytes (16%) to the composition of the microvessel was assessed. The ability of the endothelium from bovine brains to maintain a membrane potential, i.e. to accumulate the lipophilic cation [3H]TPMP, was shown. The transmitter catabolizing enzymes MAO and AchE were shown to be, and COMT and GABA-T not to be associated with the microvessel fraction isolated from rabbits.

Is the peptidase activity of highly purified human plasma cholinesterase due to a specific cholinesterase isoenzyme or a contaminating dipeptidylaminopeptidase?

The peptidase site of human plasma cholinesterase (butyrylcholinesterase) is distinct from its esteratic site. We found that the number of peptidase sites on an enzyme highly purified from pooled plasma is less than 0.1, as compared with 4 esteratic sites, per tetramer. However, the subunits which carry the peptidase sites are electrophoretically indistinguishable from esteratic subunits. The atypical-silent enzyme (Ea1Es1) had a much higher absolute peptidase activity when substance P was used as the substrate, and we found that the number of peptidase and esteratic sites of this enzyme was roughly the same. This suggests that the mutated esteratic site of the silent possesses a peptidase activity. The esteratic site of the usual allozyme (Eu1Eu1) has no peptidase activity towards substance P. However, a small proportion of peptidase subunits are present in all preparations of enzymes purified from the plasmas of homozygote individuals. The peptidase activity of butyrylcholinesterase might therefore correspond to a specific isoenzyme produced by an epigenetic mechanism or produced by a gene distinct from genes E1 and E2 encoding for cholinesterase subunits. However, the possibility that highly purified cholinesterase contains traces of a dipeptidylaminopeptidase cannot be completely ruled out.

A glutamate-sensitive neuronal system originating from the area postrema terminates in and transports acetylcholinesterase to the nucleus of the solitary tract

The possible cellular mechanism of action of systemically administered monosodium-L-glutamate and the projections of glutamate-sensitive area postrema neurons have been studied in rats. Parenteral administration of monosodium-L-glutamate induced a selective degeneration of a particular population of AChE-containing area postrema neurons. Electron microscopic cytochemistry and X-ray microanalysis revealed the presence of calcium-containing electron-dense deposits in the mitochondria of degenerating area postrema neurons indicating the possible pathogenetic role of an enhanced intracellular calcium level in the mechanism of monosodium-L-glutamate-induced nerve cell degeneration. Degeneration of area postrema neurons was followed by the appearance of degenerating axon terminals in a well-defined region of the nucleus of the solitary tract, the area subpostrema. Degenerating area postrema neurons and axon terminals were rapidly engulfed by phagocytes predominantly of microglial character. AChE activity, localized to the basal lamina of the capillaries of the area subpostrema under normal conditions, could no longer be detected in rats treated with monosodium-L-glutamate 3-4 weeks previously. These findings provide evidence for the existence of a particular population of glutamate-sensitive, AChE-containing area postrema neurons which project and transport AChE to the nucleus of the solitary tract. This specific neuronal pathway connecting the area postrema with the nucleus of the solitary tract may play an important role in some of the functions attributed to the area postrema. The results also strengthen the hypothesis that brain capillary AChE activity may be of neuronal origin.

Ultrastructural studies of concanavalin A receptors and 5'-nucleotidase localization in normal and injured mouse cerebral microvasculature

Plant lectin concanavalin A conjugated with ferritin (Con A-F) injected i.v. was used for the detection of the specific monosaccharide residues (alpha-D-mannosyl and alpha-D-glucosyl) on the luminal surface of endothelial cells (ECs) in brain micro-blood vessels (MBVs). Both normal mice and animals with mechanically damaged blood-brain barrier (BBB) were used in this study. In addition, the activity of 5'-nucleotidase (5'N), the putative receptor for Con A, was studied cytochemically. Various methodologic experiments indicated that the reaction product formed on the luminal plasmalemma of ECs after incubation of samples in the cytochemical medium for the detection of 5'N activity results from the action of unspecific phosphatase hydrolyzing both specific and nonspecific substrates. The abluminal side of the wall of MBVs seems to be a major location of 5'N activity. Thus, no correlation between cytochemically demonstrable 5'N activity and Con A receptor sites on the luminal surface of ECs was noted. After damage of the BBB, extensive internalization of the luminal plasmalemma forming the limiting membranes of pinocytotic vesicles, vacuoles, and endothelial channel-like structures was observed. This process was represented by a relatively rapid translocation of Con A receptors from luminal surface into the interior of the ECs and to the abluminal side of the vessel wall.