S-100 protein in Schwann cells of the developing human peripheral nerve

Summary From approximately 7 weeks gestational age in developing human peripheral nerve, as in adult nerve, S-100 protein was found to be expressed solely and uniformly by Schwann cells associated with axons. In embryos younger than 7 weeks S-100 was much less constant and many cells did not show clear staining. The trigger for the initial appearance of the protein at around this age remains unclear although a relationship of S-100 expression in Schwann cells to close axonal contact is suggested. The value of S-100 protein in distinguishing Schwann cells from perineurial cells in normal nerves and nerve sheath tumours remains unclear.     

Immunostaining of a cell type in the islets of Langerhans of the monkey Macaca irus by antibodies against S-100 protein

Summary S-100 protein-immunoreactive cells were demonstrated by immunocytochemical procedures in the pancreatic islets of Langerhans in the monkey Macaca irus. By use of antibodies against human S-100 protein or bovine S-100 protein, these cells were observed in all islets in the head and tail portions of the pancreas. Immunostained cells were usually located in the center of the islets or sometimes found in a more widely distributed form, but they were never arranged in a regular concentric fashion. The number of immunoreactive cells varied from one islet to another but it was relatively limited making up only 0.75%–6.3% of all insular cells. With the use of the double-immunoenzymatic procedure for demonstration of the four main endocrine cell types (insulin-, glucagon-, somatostatin-and pancreatic polypeptide producing elements), it was possible to establish that S-100 protein-immunoreactive cells represent a distinct cell type. Antibodies against S-100 protein-stained neuroinsular complexes. The present findings speak in favor of a new cell type to be added to the large variety of S-100 protein-immunoreactive cells outside the central nervous system.     

The brain-specific S-100 protein on neuronal cell membranes

The S-100 protein has been localized to the neuronal plasma membranes of isolated Deiters' neurons by fluorescence microscopy using fluorescein-conjugated antiserum to the protein and by immunoelectron microscopy using peroxidase-conjugated anti-S-100 antiserum. In the present study this is shown also by incubating neurons with Sepharose 4B or methylacrylate spherules to which were coupled anti-S-100 antibodies. The specificity of the antiserum is discussed in the text. The technique described can be used to study the topography of antigenic characteristics of nerve cells by using antisera insolubilized on spherules of suitable size.     

S-100 protein in the testis

Summary S-100, a protein originally believed to be unique to the nervous system, has recently been found in extraneural cell types. We report here on the presence of S-100 in the testis, namely in Leydig cells and in lymphatic endothelial cells, using immunohistochemical and immunochemical methods. We show that the protein in the testis is immunologically identical to brain S-100. The S-100-labelled cells in the testis exhibit morphological similarities with other cell types in different tissues known to contain S-100.     

Endothelial cell oxidant generation during K+-induced membrane depolarization

We tested the hypothesis that membrane depolarization may initiate oxidant generation in the endothelial cell. Depolarization was produced in bovine pulmonary arterial endothelial cells (BPAEC) in monolayer culture with varying external K⁺, or with glyburide (10 μM), tetraethylammonium (TEA, 10 mM), gramicidin (1 μM), or nigericin (2 μM). Evaluation of bisoxonol fluorescence of BPAEC indicated concentration-dependent depolarization by high K⁺ (2% change in fluorescence/mV change in membrane potential in the 5.9–48 mM range of K⁺) and essentially complete depolarization with glyburide. Generation of oxidants was assessed with o-phenylenediamine dihydrochloride (o-PD) oxidation in the presence of horseradish peroxidase (HRP). There was a time-dependent increase in o-PD oxidation with 24 mM K⁺, nigericin, and gramicidin over 2 hours compared with control. In 1 hour o-PD oxidation increased 2.8-fold for 24 mM and 3.7-fold for 48 mM K⁺ compared with control. Catalase reduced 24 mM K⁺-induced o-PD oxidation by 50%, while Cu/Zn-superoxide dismutase (SOD) abolished the increase. Oxidation of o-PD was reduced by 57% in the absence of HRP in the system. With K⁺ channel blockade, o-PD oxidation increased 3.8-fold with glyburide and 4.6-fold with TEA compared with control. These data indicate formation of H₂O₂ and possibly other oxidants with depolarization and suggest involvement of K⁺-channels in this process. © 1996 Wiley-Liss, Inc.     

Wallerian degeneration in rabbit tibial nerve: changes in amounts of the S-100 protein

Abstract— —A soluble protein (S-100) which is unique to the nervous system was measured in rabbit tibial nerve at 0, 3, 7, 14, 21, and 28 days of degeneration. Amounts of S-100 in the degenerated peripheral segment of the transected nerve fell progressively during degeneration to 2 per cent of that measured in the corresponding portion of nerve taken from control rabbits 28 days postoperatively. Total soluble proteins increased 42 per cent during this time. Levels of S-100 and total soluble proteins remained unchanged in non-degenerated nerve segments from experimental and control rabbits. Correlations of amounts of S-100 measured in the study reported here with cellular changes demonstrated by other investigators to characterize Wallerian degeneration in peripheral nerve suggest that the S-100 protein is localized primarily in axons rather than in Schwann cells or myelin.     

Immunocytochemical detection of dendritic cell by S-100 protein in the chicken.

Positivity for S-100 protein in paraffin embedded chicken lymphoid tissue was found by using a polyclonal antibody against whole bovine S-100 protein. The S-100 protein-containing cells were observed in the locations which have been reported to contain avian dendritic cells such as the medulla of the bursal follicles, and the germinal centers and T-dependent areas in the spleen, Peyer's patches, caecal tonsil and Harderian gland. Positive cells were also found in the location where ellipsoid associated cell have been described, and between epithelial cells covering the Peyer's patches and the caecal tonsil, as well as between the cells lining the ducts within the Harderian gland. Macrophages were devoid of immunostaining. Our results confirm the location described elsewhere for chicken dendritic cells and indicate that S-100 protein can be considered as a cell marker for the identification of the chicken dendritic cell. Intraepithelial positive cells may be interdigitating dendritic cells in an unusual location (their function being the transport of the antigen from the epithelium to the diffuse lymphoid tissue), or cytotoxic T-lymphocytes which, in mammals, are immunoreactive for S-100 protein.     

Modulation of brain protein phosphorylation by the S-100 protein

The effects of the nervous system specific protein, S-100, on protein phosphorylation in rat brain is examined. The S-100 protein inhibits the phosphorylation of several soluble brain proteins in a calcium dependent fashion. The most potent effect exhibited by S-100 was on the phosphorylation of a protein having a molecular weight of 73,000. The data suggest that the calcium binding S-100 protein, for which a function has not yet been assigned, may modulate calcium dependent phosphorylation of selected brain proteins.     

Influence of nerve fiber K+ depolarization and altered membrane protein conformation on the state of myelin

Using Raman spectrometry and fluorescence microscopy, we studied the rearrangement of carotenoid molecules and membrane-bound Ca _mb ²⁺ in myelinated nerve fibers after K⁺ depolarization, K⁺-channel blocking, and altering the membrane protein conformation. We observed a decrease in Ca _mb ²⁺ and an increase of microviscosity in myelin after depolarization. Changes in Ca _mb ²⁺ and microviscosity were registered after blocking the K⁺ channels and modifying proteins with PCMB. Our results suggest an interconnection between the condition of nerve fiber membrane proteins, Ca _mb ²⁺ distribution, and myelin microviscosity.     

Appearance of a brain specific antigen (th S-100 protein) during human foetal development

—The concentration of a protein specific to brain, the S-100 protein, was measured in various regions of the human foetal brain at gestational ages ranging from 10 weeks until term. The relative increase in concentrations of the S-100 protein during development of the human foetal brain proceeded in a caudal-rostral fashion. This observation is emphasized by the delayed appearance of the S-100 protein in the frontal cerebral cortex until the 30th week of gestation.     

Immunohistochemical study of Pacinian corpuscles using monoclonal antibodies for neurofilament protein, glial fibrillary acidic protein and S-100 protein

The presence of neurofilament protein (NFP), glial fibrillary acidic protein (GFAP) and S-100 protein has been investigated in Pacinian corpuscles from cat's mesentery by means of immunohistochemical methods. The NFP-like positivity was found in the central axon of the corpuscles; the GFAP- and S-100 protein-like immunoreactivities were shown in the innermost layers of the differentiated cell of the inner core. No positive reaction was detected in the capsule. The authors discuss these findings.     

Comparative study of the effects of antibodies to S-100 protein and ouabain on neurons of Helix pomatia

Ouabain, used in 5.10(-4) M concentration, elicits 12 +/- 5 mV (15 experiments) depolarization of membrane of snail Helix neurons. In 80% of experiments depolarization is not accompanied by changes in membrane conductance, in 20% of experiments the decrease of the membrane conductance is observed. Application of the antibodies to S-100 protein (their concentration in the micropipette being 0.05 mg/ml) induces similar effects. The effects of ouabain and antibodies to S-100 protein are not additive and the main difference in their action lies in the ability of the cell to recover the resting potential of the membrane in the solution containing ouabain.     

Sustentacular cells in the fetal human adrenal medulla are immunoreactive with antibodies to brain S-100 protein

Summary Adrenal glands of human fetuses were investigated by means of an immunohistochemical method with the use of an anti-S-100 serum. S-100-immunoreactivity was recognized in sustentacular cells located among the chromaffin cells. A characteristic circular arrangement of the immunostained cells was found in the central region of the adrenal glands. It surrounded aggregations of non-argyrophilic, small, round cells, which were identified as the remaining sympathoblasts (primitive sympathetic cells).     

Changes in the concentration of enolase isozymes and S-100 protein in degenerating and regenerating rat sciatic nerve

Levels of enolase isozymes (alpha alpha, alpha gamma, and gamma gamma forms) and S-100 protein in rat sciatic nerves were determined during their degeneration and regeneration processes. The sciatic nerves were unilaterally crushed or severed. The rats were killed 1, 2, 6, and 8-9 weeks later, and both the proximal and distal portions of the damaged nerves were dissected. Control samples were obtained from the untreated contralateral hindlimbs. Enolase isozymes and S-100 protein in the nerve segments were determined with the enzyme immunoassay method. The control nerves contained about 40, 90, and 30 pmol/mg protein of alpha alpha, alpha gamma, and gamma gamma enolases, respectively, and 0.85 microgram/mg protein of S-100 protein. These levels were not affected by repetitive electrical stimulation of the nerve fibers in vivo. The levels of the nervous system-specific forms of enolase (alpha gamma and gamma gamma) and S-100 protein decreased markedly within a week in the distal portion of the crushed nerve (alpha gamma, 27 pmol/mg; gamma gamma, 5.5 pmol/mg; S-100 protein, 0.36 microgram/mg) with apparently no change in the concentration of alpha alpha enolase. These levels in the proximal portion of the crushed nerve remained unaltered. The sensory and motor functions impaired by the sciatic nerve crush showed a recovery more or less after 4-9 weeks. This recovery was accompanied by a gradual regaining of the specific proteins in the distal portion of injured nerves (alpha gamma, 64 pmol/mg; gamma gamma, 13 pmol/mg; S-100 protein, 0.63 microgram/mg at the 8-9th week).