Axoplasmic transport of a brain-specific soluble protein

Mouse adrenal chromaffin cells can transform to neuron-like cholinergic phenotypes after being grafted into the brain

The development of neuron-like cholinergic immunophenotypes by adrenal chromaffin cells was studied in 10-week-old mouse adrenal medullary grafts. Fragments of chromaffin tissue were implanted into mouse hippocampus, and antibodies specific for neurofilaments (NF), neuron-specific enolase (NSE), choline acetyltransferase (ChAT), acetylcholinesterase (AChE), and phenylethanolamine-N-methyltransferase (PNMT) were applied to the grafts. Adrenal medulla grafts survived well and most of the transplanted cells were either round or polygonal. A minority of chromaffin cells elaborated an intermediate or sympathetic neuron phenotype. Chromaffin cells showed pronounced immunoreactivity for NSE in their perikarya and axon-like processes: immunoreactivity for NF was only found in a few processes. In adjacent immunohistochemically stained sections, the transplanted cells stained for ChAT and AChE. At the electron-microscope level, the immunohistochemical reactions for the two acetylcholine-related enzymes were mainly located on the endoplasmic reticulum and in cell processes. Immunoreactivity for PNMT was found to decline in transplanted chromaffin cells below that of normal adrenal medulla. These observations suggest that, in adrenal medullary grafts implanted into the hippocampus, chromaffin cells are endowed with neuron-like cholinergic immunophenotypes.

Immunohistochemical demonstration of neuron specific enolase (NSE) on cutaneous nerves: comparative study using NSE and S-100 protein antibodies on denervated skin

The presence of neuron-specific enolase (NSE) and S-100 protein, which are nerve specific proteins, was immunohistochemically investigated on the cutaneous nerves. NSE was found in the axons of the cutaneous nerve bundles and the terminal axons in the Meissner and Pacinian corpuscles of the normal human and macaque skin. S-100 protein was found in the Schwann cells, lamellar cells of the Meissner corpuscles, and inner core cells of the Pacinian corpuscles. After denervation of the ulnar nerve on macaque, NSE on axons of the cutaneous nerves and Meissner and Pacinian corpuscles was completely disappeared in the 5th digit. However, S-100 protein was still maintained in the Schwann cells and Meissner and Pacinian corpuscles in the same digit. From these results, we conclude that the comparative immunohistochemical staining of NSE and S-100 protein is simple and reliable method to demonstrate the cutaneous nerves in normal and pathological conditions.

Neuron-specific enolase: investigation on its possible retrograde axonal transport

The possible rapid retrograde axonal transport of neuron-specific enolase was investigated employing a sensitive radioimmunoassay. The right sciatic nerve of rats was ligated and 6 and 24 h later the nerve was cut in two 5.0 mm segments immediately proximal and distal to the ligature. Similar segments were taken from the contralateral nerve as a control. No increase in the amount of neuron-specific enolase in the right-distal segment was observed indicating that the protein is not a component of retrograde axonal transport.

Nerve-specific enolase and creatine phosphokinase in axonal transport: soluble proteins and the axoplasmic matrix

The axonal transport of two soluble enzymes of intermediary metabolism was evaluated: the nerve-specific form of the glycolytic enzyme enolase (NSE) and the brain isozyme of creatine phosphokinase (CPK). Previously, little was known about the intracellular movements of the soluble proteins of the cell. Although the soluble enzymes of glycolysis and other pathways of intermediary metabolism have been thought to be freely diffusing in the cytosol, many are required in the axonal extremities of the neuron and must be transported to the sites of utilization. Comigration of purified enzymes with radioactive polypeptides associated with specific rate components of axonal transport in two-dimensional gel electrophoresis indicates that both NSE and CPK move in the axon solely as part of the group of proteins known as slow component b (SCb) at a rate of 2 mm/day. Peptide mapping following limited proteolysis confirmed identification of NSE and CPK in SCb. Materials associated with SCb have been shown to move coherently along the axon and to behave as a discrete cellular structure, the axoplasmic matrix. Association of two soluble enzymes, NSE and CPK, with the SCb complex of proteins requires a reevaluation of the assumption that these and other soluble proteins of the axon are freely diffusible.

Investigation of the axonal transport of three acidic, soluble proteins (14-3-2, 14-3-3, and S-100) in the rabbit visual system

The question of whether three acidic, water-soluble proteins (14-3-2, 14-3-3, and S-100, the first and last known to be brain-specific) are axonally transported was investigated in the rabbit visual system. The water-soluble proteins were obtained from individual optic nerves, combined optic tracts and lateral geniculate bodies, superior colliculi, and, in some instances, retinas at various times (1--56 days) after monocular injections of [3H]leucine. These proteins were separated by a two-step polyacrylamide gel electrophoresis procedure that isolated 14-3-2, 14-3-3, and S-100 almost uncontaminated by other radioactivity. The isolated 14-3-2 and S-100 were demonstrated to be approx. 90% pure by a new method based on retarding the migration of these proteins by immunoadsorption during the first step of electrophoresis. An analysis of the radioactive labeling of the total soluble proteins (TSP) and the isolated acidic proteins revealed that: (1) S-100 was not axonally transported; (2) both 14-3-2 and 14-3-3 were part of one of the slow components of axonal transport (2--4 mm/day); (3) the radioactivity of 14-3-2 and 14-3-3 represented about 2.7% and 3.2%, respectively, of the radioactivity incorporated into the axonally transported TSP; (4) the ultimate distributions of the radioactively labeled 14-3-2 and 14-3-3 were the same (about 70% of each destined for the superior colliculus) and differed from that of the TSP; and (5) the rates of catabolism of the axonally transported 14-3-2 and 14-3-3 were slightly greater than that of the TSP, with half-lives for 14-3-2 and 14-3-3 estimated to be 11 and 10 days, respectively.

Detection and localization of 14-3-2 protein in primary cultures of embryonic rat brain

The development of embryonic rat brain in cell cultures was studied by an immunocytochemical method based on the detection of 14-3-2 protein (neuron-specific enolase or NSE), a neuron-specific protein. This protein was already present in undifferentiated neurons (less than 5 days in culture), being dispersed throughout the cytoplasm, though seemingly concentrated in the vicinity of polyribosomal structures. It was not found in nuclei, in mitochondria or in the Golgi apparatus. During neuron differentiation, the location of 14-3-2 protein was related to neurite development insofar as it was detected along the axon and even in what could be taken to be the presynaptic region of numerous interneuron contacts. In contact areas, a thickening of the junction membrane was observed but the presence of 14-3-2 protein was always unilateral demonstrating the absence of a true synapse and reflecting the halt in neurite development observed after 15 days in culture. The presence of 14-3-2 protein in the cell cultures was confirmed by a microcomplement fixation assay. The protein detected in cell cultures had the same immunological properties as that found in the 17-day-old embryo, but was slightly different from that found in adult rat brain. This observation can be confronted with the lack of neuron maturation in the immunocytochemical studies.

Neuronal, non-neuronal and hybrid forms of enolase in brain: structural, immunological and functional comparisons

Three forms of the glycolytic enzyme, enolase [2-phospho-D-glycerate hydrolase (E.C. No. 4.2.1.11)] have been prepared from rat whole brain extract. The most acidic enolase form is neuron specific enolase (NSE) which had previously been designated neuron specific protein (NSP). The least acidic form designated non-neuronal enolase (NNE) has been purified and compared structurally, immunologically and functionally to NSE. NNE is a dimer of 86,500 M.W. consistint of two very similar subunits. The data establish that NNE is larger than NSE which has been shown to be composed of two apparently identical 39,000 molecular weight subunits (78,000). NNE is less acidic than NSE having a pI of 5.9 compared to the value of 4.7 for NSE. Structural and immunological analysis establishes that the NNE subunit is distinct from the NSE subunit, and are therfore products of two separate genes. The structural designation of NSE is (gammagamma) and that of NNE (alpha' alpha'). NSE is strictly localized in neurons indicating that the gene coding for the gamma subunit is only expressed in neuronal cells. The intermediate brain enolase form has been partially purified; structural and immunological evidence indicate that it is a hybrid molecule consisting of one NNE subunit and one NSE subunit (alpha'gamma).

Neuron specific protein (NSP) in neuroblastoma cells: relation to differentiation

The spectrum of enolase enzyme forms has been examined in several lines of neuroblastoma cells and compared to those present in whole brain. The neuron specific enolase (NSP) is greatly decreased in the cultured cells as judged by activity profiles and radioimmunoassay. The synthesis of neuronal enolase appears to be extensively depressed in these cells while the total enolase activity is not affected. The non-neuron form of enolase (NNE) apparently compensates for the lack of the neuronal forms in the cultured cells. The preponderance of NNE in cultured neurons suggests that this enzyme is present in immature neurons, and that neuroblastoma cells are not fully differentiated with respect to the enolase function. Dibutyryl cyclic adenosine monophosphate treatment does increase NSP levels in mouse neuroblastoma cells, but not to the levels expected for fully differentiated neurons. The results indicate that NSP is a molecular correlate of fully differentiated neurons.