Nancy H. Sternberger

Immunocytochemical method to identify basic protein in myelin-forming oligodendrocytes of newborn rat C.N.S.

SummaryAn immunocytochemical method for detecting myelin basic protein in oligodendrocytes and myelin of newborn rat C.N.S. is described. C.N.S. tissue is perfused and fixed in HgCl2-formaldehyde and 20 μm Vibratome sections are treated with antibodies to myelin basic protein using the peroxidase-antiperoxidase method. Oligodendrocytes in the newborn rat are intensely stained by antiserum to basic protein and multiple stained processes extend from the perikaryon to myelin sheaths. With this procedure it is possible to demonstrate the geometric relationships between a single oligodendrocyte and multiple myelin sheaths. Stained oligodendrocytes and myelin are present in newborn cervical spinal cord, medulla oblongata, pons and midbrain. By 25 days of age, staining in oligodendrocytes is less intense than in newborn rats and differences in amount of staining can be detected in areas that are myelinating at different rates. With anticerebroside serum, cerebroside, of newborn and developing rat C.N.S. tissue is localized only in myelin. In the developing P.N.S., myelin basic protein is localized in Schwann cell cytoplasm and myelin sheaths of the trigeminal ganglion. Cerebroside is found only in myelin.

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.

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 Alzheimers disease and Parkinsons 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.

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.

Neurofilamentous Abnormalities in Motor Neurons in Spontaneously Occurring Animal Disorders

Abstract 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.

IMMUNOCYTOCHEMICAL STUDY OF P0 GLYCOPROTEIN, P1 AND P2 BASIC PROTEINS, AND MYELIN‐ASSOCIATED GLYCOPROTEIN (MAG) IN LESIONS OF IDIOPATHIC POLYNEURITIS

Schober R., Itoyama Y., Sternberger N.H., Trapp B.D., Richardson E.P., Asbury A.K., Quarles R.H. & Webster H. deF. (1981) Neuropathology and Applied Neurobiology 7, 421–434

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.