Immunocytochemical expression of the endothelial barrier antigen (EBA) during brain angiogenesis.

The antibody to the endothelial barrier antigen (anti-EBA) is localized to the luminal plasma membrane of endothelia that have a blood-brain barrier (BBB) but not to other vessels, for instance those in the circumventricular organs, which lack barrier function. We have examined EBA expression in the rat in certain tissues and in brain microvessels in models of brain angiogenesis such as development, wound healing and neural transplantation. All brain microvessels including pial ones stained for anti-EBA whereas those of the dura, median eminence and choroid plexus did not. Vessels of the iris which are characterized by tight junctions and barrier function expressed EBA strongly. Embryonic day 18 brain did not stain at all for anti-EBA although vessels were readily localized with anti-laminin. Following stab wounds to mature brain, directly injured and adjacent microvessels lacked EBA expression for a period of approximately 2 weeks which is a similar time frame of BBB breakdown. Following this period, EBA expression gradually returned to a normal pattern by 3-4 weeks. Likewise, in intraparenchymal transplants of fetal neocortex EBA expression was not observed for 2 weeks and while at later times transplant vessels expressed EBA whereas some interface vessels associated with inflammatory cells did not. Permeable choroid plexus vessels vascularizing intraventricular transplants did not stain for anti-EBA at any time period and neither did vessels in adrenal medulla transplants. The present study shows that while EBA expression is a postnatal event unlike the development of a barrier to serum protein, its expression may be lost or delayed in injured vessels or ones associated with inflammatory cells or reactive astrocytes.

Variability of laminin immunoreactivity in human autopsy brain.

Laminin immunoreactivity is thought to be masked in formalin-fixed sections since proteolytic treatment is required to unmask it. We analyzed this masking with frozen and formalin-fixed human autopsy brains obtained at various postmortem periods. In unfixed, frozen sections, intense immunoreactivity was invariably detected in vascular walls of entire sections. When such sections were postfixed in formalin, immunoreactivity was not diminished even after prolonged fixation. In vibratome sections of brain fixed in formalin in situ, immunoreactivity varied with postmortem delay: in most cases, immunoreactivity was weak and restricted to superficial cortical layers. However, the extent of immunoreactivity increased with postmortem delay. Two cases fixed after prolonged postmortem periods revealed moderate immunoreactivity throughout the sections. We also investigated rat brains processed without postmortem delay. In unfixed frozen sections, immunoreactivity again was observed throughout the sections, independent of the length of any postfixation. In vibratome sections of fixed rat brain, immunoreactivity was restricted to the cutting margins of the brain blocks and around a trauma-induced cortical lesion, regardless of how long the blocks had been kept in fixative. Our data suggest that postmortem proteolysis accomplishes similar unmasking of laminin antigen as digestion on paraffin sections and that such unmasking can also be effected by proteolysis induced by damaging tissue during cryostat sectioning of fresh tissue.

Leakage and neuronal uptake of serum protein in aged and Alzheimer brains. A postmortem phenomenon with antemortem etiology.

Abnormal extravasation of serum proteins has frequently been reported in Alzheimer's disease (AD) and less often in nondemented, aged individuals. In order to establish whether these are ante or postmortem phenomena, we have now compared the immunocytochemical localization of immunoglobulin in young, aged, and AD brains. In all the young brains, but only in some of the aged and AD brains, immunoglobulin was confined to a fine network of microvessels. In contrast, the majority of AD, as well as apparently normal, aged brains revealed both focal and diffuse extravascular localization in the form of neuronal labeling as well as a general, diffuse background. Since microvessels in these areas were no longer revealed, it was felt that the extravascular leakage occurred postmortem at a time when replacement of intravascular immunoglobulin had ceased. Furthermore, there was a correlation between the extent of leakage and time interval between death and autopsy. Postmortem leakage of serum protein was reproduced in a more controlled system using young and aged rats; serum protein leakage evolved from focal to diffuse patterns in aged brains as the postmortem period increased, whereas the leakage was restricted to the outer half of the cortices in young brains even after a prolonged postmortem period. Postmortem trauma to the rat brain also caused lesion-related leakage as well as neuronal labeling. It was concluded that extravascular leakage and neuronal uptake in aged and AD brains is a postmortem phenomenon, due to delay in autopsy or mishandling of brains, but dependent in severity upon antemortem circumstances.

Abnormal processing of multiple proteins in Alzheimer disease.

Cerebrovascular amyloid is the main constituent of the perivascular and neuritic plaques typical of Alzheimer disease, whereas neurofilaments and microtubule-associated tau protein have been considered primary contributors to the formation of the characteristic Alzheimer tangles. Plaques and tangles and their constituents have at times been ascribed a role in pathogenesis of the disease. Normally, neurofilaments become phosphorylated only upon axonal entry. In many neurologic disorders, neurofilament phosphorylation, as detected by any of the available monoclonal antibodies (mAbs) to neurofilament phosphorylated epitopes is shifted from an axonal to a cell-body location. An exception is provided by Alzheimer disease, where tangles (which are neuronal cell-body-derived structures) exhibit only one phosphorylated epitope. However, the very presence of neurofilaments in tangles and plaques has been questioned because of a reported cross-reaction of mAbs to phosphorylated neurofilaments with tau protein. On reinvestigating this cross-reactivity we found that four of five mAbs to phosphorylated neurofilaments and four of five mAbs to nonphosphorylated neurofilaments failed to react with tau protein. A fifth mAb (07-5) to phosphorylated neurofilament cross-reacted with partially denatured tau protein at an affinity 1/1700th of that for denatured neurofilaments; nondenatured tau protein in tissue sections did not cross-react. A fifth mAb (02-40) to nonphosphorylated neurofilament also cross-reacted weakly. In Alzheimer disease normal-appearing axons were revealed with all the mAbs to phosphorylated neurofilaments, but tangles were revealed with only one of them (mAb 07-5). mAb to tau protein did not stain or did so indistinctly. Four of five mAbs to nonphosphorylated neurofilaments failed to reveal axons. Upon dephosphorylation of tissue, staining by mAbs to phosphorylated neurofilaments disappeared, and axons were revealed with the mAb to tau protein and all mAbs to the nonphosphorylated neurofilaments. Tangles became stained with tau mAb and one mAb to the nonphosphorylated neurofilaments (mAb 10-1). Quantitative evaluation of immunocytochemical staining intensities and immunoblot cross-reactivity showed that neurofilaments are, indeed, constituents of tangles--apparently exceeding the concentration of tau protein 17-fold. Contribution of both conformation and primary structure to IgG specificity may explain the lack of any cross-reaction of mAbs to neurofilaments with tau protein in intact tissue and the appearance of cross-reaction in immunoblots where conformation specificity may be largely lost. The present data extend earlier findings of abnormal processing of neurofilaments and tau protein in Alzheimer disease and, together with reported abnormal processing of cerebrovascular amyloid beta-protein, suggest that inhibition of the processing of multiple proteins is basic to the pathogenesis of Alzheimer disease, whereas formation of plaques and tangles could be merely the most striking histologic result.

Cell surface endothelial proteins altered in experimental allergic encephalomyelitis.

Endothelial cells (EC) are increasingly being considered as important participants in the early evolution of inflammatory and immune responses in experimental allergic encephalomyelitis (EAE). We have found that a mouse monoclonal antibody, which reacts with the luminal plasma membrane of central nervous system endothelium, detects an alteration in the blood-brain barrier (BBB) in lesions in Lewis rats with EAE. Anti-endothelial barrier antigen (EBA) reacted with microvessels in normal rat brain and spinal cord. This reaction was abolished in 'EAE' microvessels surrounded by inflammatory cells. In rats that had recovered from one attack most EC reacted with the antibody, indicating that EBA was reexpressed during recovery. However, blood vessels in areas with residual inflammatory lesions were negative. The biochemical changes that lead to this absence of antibody binding and the cells or mediators responsible for producing this change are not yet known. However, anti-EBA should provide a useful tool for exploring molecular mechanisms underlying BBB breakdown.

A comparison of intraventricular and intraparenchymal cerebellar allografts in rat brain: evidence for normal phosphorylation of neurofilaments.

Allografts of embryonic (E14-E15) rat cerebellum in adult brain were compared using the intraparenchymal and intraventricular transplantation techniques. We studied the expression and distribution of phosphorylated neurofilament (PNF) epitopes, nonphosphorylated neurofilament (nPNF) epitopes, synapse-associated antigens, glial fibrillary acidic protein (GFAP) and myelin basic protein (MBP). Both intraventricular and intraparenchymal grafts developed a clear trilaminar organization. Intraparenchymal grafts were much smaller and showed a large GFAP-positive glial scar and demyelination of host tissue. Nevertheless, myelinated fibers were present more often crossing the host-transplant border in intraparenchymal grafts. PNF and nPNF epitopes were present in both types of grafts. Staining patterns characteristic of normal rat cerebellum were seen. nPNF epitopes were present in Purkinje cell bodies and dendrites and PNF epitopes in basket cell axons surrounding Purkinje neurons. The appearance and distribution of PNF epitopes resembled that seen in normal postnatal cerebellar development and both PNF and nPNF epitopes were present at the same times in early development in both intraventricular and intraparenchymal grafts. In contrast to the situation in trauma and disease, PNF epitopes never appeared in perikarya of transplanted cerebellar neurons. The expression of synapse-associated antigens in grafted tissue was also similar to that seen in normal cerebellum.

Phosphorylation of neurofilaments is altered in amyotrophic lateral sclerosis.

We used a library of monoclonal antibodies (Mab) that distinguish phosphorylated (P+) and non-phosphorylated (P-) neurofilament (NF) epitopes to examine phosphorylation of NF in lower motor neurons of patients with amyotrophic lateral sclerosis (ALS), of neurologically normal controls of different ages, and of patients with central chromatolysis due to injuries to motor root axons. Monoclonal antibodies directed to P+ NF immunostained five to ten times more neuronal perikarya in ALS than in age-matched controls. Spheroids, which are NF containing axonal enlargements, found in significantly greater number in proximal axons in ALS, were also intensely immunostained with Mab to P+ NF. Moreover, anterior root axons in five of eleven cases of ALS reacted only with the Mab to P+ NF, while both P- and P+ NF were present in motor roots from controls. In control groups, the number of neuronal perikarya and spheroids that immunoreacted with the Mab to P+ NF increased moderately with age. Chromatolytic lower motor neurons were recognized by Mab to P+ NF. Our results show that the process of phosphorylation is altered in ALS. We propose that phosphorylation of NF in ALS occurs prematurely and that it is more likely to be associated with an impairment of NF transport than to be part of a chromatolytic reaction of lower motor neurons.

Expression of neurofilament proteins by Purkinje cells: ultrastructural immunolocalization with monoclonal antibodies.

Purkinje cell bodies in rodent cerebellum have been shown to express neurofilament protein epitopes but neurofilaments are rarely seen in these perikarya by classical morphological approaches. In an attempt to solve this enigma the ultrastructural distribution of two neurofilament epitopes was studied by immunoelectron microscopy with two monoclonal antibodies (Mabs) of divergent specificity: one, Mab 04-7 recognized a phosphorylated epitope, the other, Mab 02-135 a non-phosphorylated epitope. Longitudinal filamentous elements were heavily labeled in basket cell axons and afferent nerve fibers with both Mabs. While Mab 04-7 was unreactive with Purkinje cells, the immunoperoxidase reaction product with Mab 02-135 was distributed in the form of patches with no filamentous substructure throughout the cytoplasm of these cells. The data complement the results of other immunocytochemical studies showing the presence of all 3 neurofilament constituent proteins in Purkinje cell bodies, and lead to the conclusion that in these perikarya the majority of neurofilament proteins are not assembled in the form of neurofilaments.

Neurofilamentous abnormalities in motor neurons in spontaneously occurring animal disorders.

Cytoskeletal proteins have a characteristic distribution within neurons when immunocytochemical techniques are used on conventional paraffin sections. For example, phosphorylated neurofilaments are located within axons but are not normally present in the majority of perikarya of the central nervous system. This pattern can be altered in disease, and neurofilaments that accumulate within perikarya can be phosphorylated inappropriately. To determine whether retained neurofilaments were phosphorylated inappropriately, we used immunocytochemical techniques to examine several diseases in animals in which neurofilaments accumulate within neuronal perikarya. Our investigations of diseases with disparate etiologies show that, whenever neurofilaments are retained within the neuronal perikarya, they are phosphorylated. These results suggest that phosphorylation of neurofilaments in an inappropriate location, i.e. perikarya, may be a nonspecific disease-related response of neurons that can be initiated by a variety of cellular injuries.

Neurofilament antigens in acrylamide neuropathy.

After repeated exposure, acrylamide (AC) produces degeneration of distal axons. Because neurons whose axons have been injured (e.g. by axotomy) show alterations in their structural and chemical properties, the present study was designed to differentiate the direct effects of AC intoxication from neuronal responses secondary to axonal injury caused by AC. Rats were given AC as either a single high dose (75 mg/kg), or as daily intraperitoneal injections (30 mg/kg, six days per week for four weeks). Dorsal root ganglia of the fifth lumbar level, L5, were examined using a variety of monoclonal antibodies directed against nonphosphorylated (2-135) and phosphorylated (03-44, 06-17, 07-05) epitopes of 145 and 200 kilodalton neurofilament proteins. In control rats, antibody 2-135 stained axons and neuronal cell bodies; antibodies against phosphorylated epitopes of neurofilaments stained only axons distal to the glomerulus. Following chronic AC intoxication, all three antibodies directed against phosphorylated epitopes of neurofilaments (particularly 07-05) demonstrated intense immunoreactivity in 20-30% of neuronal cell bodies. In addition, the glomerular region of these axons was stained. Electron microscopy revealed many chromatolytic cells containing few neurofilaments. In contrast, a single high dose of AC produced no abnormal staining of neuronal cell bodies at a time when slow axonal transport was impaired. Our findings are compared to those observed following axotomy and to those occurring in aluminum-intoxicated rabbits, two experimental disorders in which altered distributions of phosphorylated filaments have been documented.

Lhermitte-Duclos disease. An immunohistochemical study of the cerebellar cortex.

Immunocytochemical studies were carried out on two previously reported autopsy cases of Lhermitte-Duclos disease. The unaffected cerebellar cortex adjacent to the lesions served as control. The findings supported the view, previously expressed by one of the authors, of a heterogeneous neuronal structure of the lesion, consisting of at least two cell types. No further light was thrown on the predominant medium-sized cells, believed to represent hypertrophic internal granular neurons. On the other hand the large cells shared a number of features with Purkinje cells. In particular they were recognized by the pan-T-cell antibody anti-Leu-4, were surrounded by axosomatic synapses visualized by the antisynaptic vesicle glycoprotein antibody SV2, and contained both non-phosphorylated and phosphorylated neurofilament epitopes. It is suggested that these cells represent dysplastic Purkinje cells. The lesion therefore appears to be a complex hamartoma rather than a simple hypertrophy of the internal granular neurons.

Blood-brain barrier protein recognized by monoclonal antibody.

An IgG1 mouse monoclonal antibody produced in response to immunization with rat brain homogenate reacted with endothelial cells in the central and peripheral nervous system. Because antibody reactivity was associated with endothelia that have a selective permeability barrier, the antibody was called anti-endothelial-barrier antigen (anti-EBA). Paraffin sections of Bouins'-fixed rat tissue were used for initial screening and subsequent characterization of antibody reactivity. The antibody was generally unreactive with endothelial cells in other organs and with nonendothelial cells in or outside of the nervous system. Antibody binding was greatly reduced or absent in endothelia of the area postrema and choroid plexus, sites known to possess fenestrated blood vessels. In developing rat brain, anti-EBA binding to some microvessels was seen at 3 days postnatally. Anti-EBA reactivity outside the nervous system occurred in spleen and skin. Patchy reaction with portions of some spleen blood vessels and binding to some cells in the spleen were observed. In the skin, small cells, tentatively identified as Langerhans cells, which participate in Ia presentation, were stained. On immunoblots of rat brain microvessel preparations electrophoresed in Na-DodSO4/polyacrylamide gels, anti-EBA reacted with a protein triplet of Mr 30,000, 25,000, and 23,500 components.

Distribution of neurofilament antigens after axonal injury.

Phosphorylated and nonphosphorylated epitopes of neurofilament (NF) proteins are distributed in different regions of individual neurons. Immunocytochemical methods, with monoclonal antibodies directed against phosphorylated and nonphosphorylated NF, demonstrated nonphosphorylated NF in perikarya and proximal axonal segments of neurons in dorsal root ganglia, while phosphorylated NF proteins were present in axons of these cells. The distribution of these epitopes of NF were examined at various times following injury of axons in the rat sciatic nerve. Between one and 21 days after crush of the proximal nerve, phosphorylated NF were present in neuronal perikarya. We have compared patterns of perikaryal immunoreactivity at one time point (three weeks) following a more distal crush or complete transection of the sciatic nerve. At this time period, following transection/ligation, phosphorylated NF immunoreactivity was not present in perikarya, but abnormal staining was observed after nerve crush. These altered distributions of phosphorylated epitopes of NF are of interest because several recent reports have indicated that similar, but not identical, abnormal staining patterns occur in human neurological diseases, including Alzheimer's disease and Parkinson's disease. In accord with previous studies, this investigation indicates that one response of neurons to injury, or to disease, is an abnormal distribution of phosphorylated epitopes of NF proteins.

Varying degrees of phosphorylation determine microheterogeneity of the heavy neurofilament polypeptide (Nf-H).

Two-dimensional immunoblots revealed a spectrum of 200 kDa neurofilament polypeptides (Nf-H) of apparent molecular weights ranging from 200 to 170 kDa. The entire spectrum was stained immunocytochemically by three monoclonal antibodies specific for nonphosphorylated neurofilaments, while more restricted staining was revealed by four monoclonal antibodies specific for phosphorylated neurofilament epitopes. Treatment with increasing amounts of phosphatase suggested the existence of various forms of partially phosphorylated neurofilaments that possess phosphoepitopes that differ in their ease of dephosphorylation. Immunoprecipitation in low detergent concentration confirmed the existence of microheterogeneous forms of Nf-H that differed in extent of phosphorylation or in distribution of phosphorylated sites.

The cytoskeleton of the human cerebellar cortex: an immunohistochemical study of normal and pathological material.

Monoclonal antibodies to non-phosphorylated and phosphorylated neurofilaments, as well as monoclonal and polyclonal antibodies to other cytoskeletal elements, were applied to the study of the cerebellar cortex of normal and pathological human material. The methods proved to be applicable to formalin fixed paraffin embedded tissue, provided the period of formalin fixation was short. The main difference between normal and pathological material was found in Purkinje cells and their dendrites. While normal Purkinje perikarya and dendrites expressed only non-phosphorylated neurofilaments, reactive dendrites stained more intensely with antibodies to phosphorylated neurofilaments. Similar observations were made on the abnormal dendritic ramifications of the partially deafferented, hypertrophic, inferior olive. The significance of the appearance of phosphorylated neurofilament epitopes in abnormal dendrites remains unknown and requires further investigation.

Phosphorylation protects neurofilaments against proteolysis.

During incubation with phosphatase, the 200 kDa neurofilament protein in cytoskeletal preparations is degraded extensively. Degradation, which is divalent cation-independent, does not occur when inhibitors of phosphatase are added. The 160 kDa chymotryptic fragment of neurofilaments or affinity-purified 200 kDa protein are not degraded by phosphatase. The results suggest that phosphorylated neurofilaments are protected against proteolysis, and dephosphorylated neurofilaments are degraded by a calcium-independent, endogenous proteinase which is associated with assembled neurofilaments or with other cytoskeletal components, and not with the phosphatase used.

Lewy body dementia without Alzheimer changes.

Three patients with clinical Alzheimer's disease were found at postmortem examination to have Lewy-bodies and Lewy-like bodies in the cerebral cortex and the pigmented brainstem nuclei. Neuritic plaques were found in neocortical areas but no neurofibrillary tangles. The distribution of cortical neuronal inclusions correlated with the proposed projection of dopamine terminals. Neuronal cell loss was marked in the ventral tegmental area (paranigral nucleus) and the basal nucleus of Meynert, suggesting a defect in dopaminergic and cholinergic innervation of the cerebral cortex. Immunohistochemical investigations revealed positive staining of cortical Lewy- and Lewy-like bodies for monoclonal antibodies to phosphorylated neurofilaments (03-44, 06-17, 04-7). Also cerebral neurons containing no inclusions showed positivity, suggesting an early neurofilament abnormality, preceding the formation of Lewy-type inclusions.

Association of synapsin I with neuronal cytoskeleton. Identification in cytoskeletal preparations in vitro and immunocytochemical localization in brain of synapsin I.

Calmodulin-dependent protein kinase II (CaM kinase II) is associated with microtubule preparations and phosphorylates several endogenous proteins including microtubule-associated protein 2, tubulin, and an 80,000-dalton protein doublet (pp80). We now report that pp80 is identical to synapsin I by all criteria studied including molecular weight, isoelectric point, phosphopeptide mapping of cAMP- and calmodulin-dependent phosphorylated protein, comigration with authentic synapsin I, and sensitivity to digestion with collagenase. Synapsin I and CaM kinase II were found in association with both microtubule preparations and preparations enriched in neurofilaments. Antibodies to synapsin I specifically labeled neurofilaments prepared in vitro. Immunocytochemical studies on rat brain tissue demonstrated synapsin I immunoreactivity specifically associated with the neuronal cytoskeleton as well as synaptic vesicles. The observed synapsin I staining on cytoskeletal elements was considerably diminished or abolished by the inclusion of Triton X-100 in the staining solutions. These results indicate that synapsin I is associated with the cytoskeleton and may be an important link between cytoskeletal elements as well as between the cytoskeleton and membrane.

Isolation and characterization of a new peptide from hypothalamus and pituitary using a monoclonal antibody to LHRH.

A new peptide with LHRH-like immunoreactivity has been isolated from rat hypothalamus and pituitary using an immunosorbent prepared with monoclonal antibody to luteinizing hormone-releasing hormone (LHRH). This peptide contains part of the C-terminal sequence of LHRH and has a molecular weight of about 2000. It comprises over 20% of hypothalamic immunoreactivity recognized by the monoclonal antibody. Chromatographic and amino acid analysis data confirm the distinction between this peptide and LHRH. Immunocytochemical evidence is consistent with its being a normal constituent of the LHRH system, while its presence in the pituitary suggests that it may play a role in the regulation of this gland.