Processing techniques for the demonstration of myelin basic protein in paraffin-embedded optic nerve: an immunoperoxidase study of the developing albino rat

A comparison was made of the effects of various fixation and processing conditions upon the antigenicity of myelin basic protein (MBP) in sections of paraffin-embedded optic nerve from the developing albino rat as judged by the unlabeled peroxidase-antiperoxidase technique. The fixatives used were: Perfix, 4% and 2% buffered paraformaldehyde (pH 7.4), 10% buffered formalin (pH 7.4); Bouin's, Clark's, and Carnoy's fixatives, and 20% formalin in a solution of HgCl2 that had been saturated at 1 degrees C. Perfix appeared to be the best fixative for the preservation of morphology and MBP antigenicity during the early stages of myelinogenesis but was not satisfactory during the later stages. The buffered aldehydes were slightly more destructive of MBP antigenicity than was Perfix, but they produced satisfactory results following the first postnatal week. Bouin's fixative was similar in effect to the buffered aldehydes, but nonspecific background staining was higher. HgCl2/formalin, Clark's and Carnoy's fixatives were unsuitable. No differences were noted in staining between material processed for embedding using 5, 30, or 60 min schedules.     

Myelin Basic Protein Deposition in the Optic and Sciatic Nerves of Dysmyelinating Mutants Quaking, Jimpy, Trembler, MLD, and Shiverer During Development

An ontogenetic survey of the basic protein of myelin, common to both central and peripheral nervous systems, was carried out on normal C57Bl and five dysmyelinating mutant mice. Myelin basic protein (MBP) was quantified by radioimmunoassay in the optic and sciatic nerves of mice from birth to adult stages, giving special attention to the premyelinating and early myelination periods. In the optic nerves of normal mice, MBP was already detectable at birth but the active period of myelin deposition was shown to occur after day 10 postnatal. The timing and rate of accumulation of MBP were normal in Trembler. In contrast, they were abnormal in the other mutants. In the quaking mouse, the active period of MBP deposition was delayed, and its final concentration represented no more than 12% of normal in the adult. No active period of MBP deposition was observed in the other mutants. In the jimpy mouse, a slow accumulation of MBP resulted in a final concentration reaching 2% of the normal value at 25 days. In mild and shiverer mice, the MBP was hardly detectable. In the sciatic nerves of normal mice, the active period of MBP deposition occurred between days 3 and 12 postnatal. No substantial changes occurred in the period of 2 months--2 years.(ABSTRACT TRUNCATED AT 250 WORDS)     

Immunocytochemical localization of P0 protein in Golgi complex membranes and myelin of developing rat Schwann cells

P0 protein, the dominant protein in peripheral nervous system myelin, was studied immunocytochemically in both developing and mature Schwann cells. Trigeminal and sciatic nerves from newborn, 7-d, and adult rats were processed for transmission electron microscopy. Alternating 1- micrometer-thick Epon sections were stained with paraphenylenediamine (PD) or with P0 antiserum according to the peroxidase-antiperoxidase method. To localize P0 in Schwann cell cytoplasm and myelin membranes, the distribution of immunostaining observed in 1-micrometer sections was mapped on electron micrographs of identical areas found in adjacent thin sections. The first P0 staining was observed around axons and/or in cytoplasm of Schwann cells that had established a 1:1 relationship with axons. In newborn nerves, staining of newly formed myelin sheaths was detected more readily with P0 antiserum than with PD. Myelin sheaths with as few as three lamellae could be identified with the light microscope. Very thin sheaths often stained less intensely and part of their circumference frequently was unstained. Schmidt-Lanterman clefts found in more mature sheaths also were unstained. As myelination progressed, intensely stained myelin rings became much more numerous and, in adult nerves, all sheaths were intensely and uniformly stained. Particulate P0 staining also was observed in juxtanuclear areas of Schwann cell cytoplasm. It was most prominent during development, then decreased, but still was detected in adult nerves. The cytoplasmic areas stained by P0 antiserum were rich in Golgi complex membranes.     

Comparative Evaluation of Methods for Estimating Retinal Ganglion Cell Loss in Retinal Sections and Wholemounts

To investigate the reliability of different methods of quantifying retinal ganglion cells (RGCs) in rat retinal sections and wholemounts from eyes with either intact optic nerves or those axotomised after optic nerve crush (ONC). Adult rats received a unilateral ONC and after 21 days the numbers of Brn3a⁺, βIII-tubulin⁺ and Islet-1⁺ RGCs were quantified in either retinal radial sections or wholemounts in which FluoroGold (FG) was injected 48 h before harvesting. Phenotypic antibody markers were used to distinguish RGCs from astrocytes, macrophages/microglia and amacrine cells. In wholemounted retinae, counts of FG⁺ and Brn3a⁺ RGCs were of similar magnitude in eyes with intact optic nerves and were similarly reduced after ONC. Larger differences in RGC number were detected between intact and ONC groups when images were taken closer to the optic nerve head. In radial sections, Brn3a did not stain astrocytes, macrophages/microglia or amacrine cells, whereas βIII-tubulin and Islet-1 did localize to amacrine cells as well as RGCs. The numbers of βIII-tubulin⁺ RGCs was greater than Brn3a⁺ RGCs, both in retinae from eyes with intact optic nerves and eyes 21 days after ONC. Islet-1 staining also overestimated the number of RGCs compared to Brn3a, but only after ONC. Estimates of RGC loss were similar in Brn3a-stained radial retinal sections compared to both Brn3a-stained wholemounts and retinal wholemounts in which RGCs were backfilled with FG, with sections having the added advantage of reducing experimental animal usage.     

Neurofilament phosphorylation in development. A sign of axonal maturation?

Monoclonal antibodies to the 200K neurofilament (NF) protein selectively decorated axons in tissue sections. Dilution of the antibodies in phosphate buffer and digestion with phosphatase abolished the stain. With conventional monoclonal and polyclonal NF antibodies, i.e. antibodies decorating NF regardless of their location (axons, perikarya and dendrites), the staining was not affected by this treatment. With all antibodies, axon-specific and conventional, the staining was abolished by trypsin digestion. Subsequent digestion with phosphatase did not restore the staining. Compared with conventional NF antibodies, staining with axon-specific anti-NF 200K was a late phenomenon in chick embryo development. NF 200K immunoreactivity was first observed in peripheral nerves and in the anterior columns of the spinal cord on day 10. Sensory ganglia and optic nerve fibers were negative. With conventional NF antibodies these structures were stained on days 4 and 5, respectively. In the following days of development the study was confined to the retina, optic nerves, cranial peripheral nerves and sensory ganglia. Up to day 16, bundles of thin peripheral nerve fibers, strongly decorated by conventional NF antibodies, did not stain with anti-NF 200K in double labelling experiments. Nerve bundles emerging from the ganglia were also negative, although some thick nerve fibers within the ganglia were stained. NF 200K immunoreactivity was first observed on day 17 in the optic nerve and in the layer of optic nerve fibers. At this time, staining was confined to the bundle emerging from the temporal side of the retina. In newborn chicken, only few fibers stained with anti-NF 200K in the nasal bundle, while the temporal bundle was well stained. It is suggested that the NF 200K antibodies reacted with a phosphorylated epitope in the axon, and that NF phosphorylation is a late event in ontogenesis probably related to axonal maturation.     

Myelin-Associated Glycoprotein: Electron Microscopic Immunocytochemical Localization in Compact Developing and Adult Central Nervous System Myelin

Light microscopic immunocytochemical studies have shown that myelin-associated glycoprotein (MAG) is localized in myelin of the developing CNS; but in the adult, MAG appears to be restricted to periaxonal regions of myelinated fibers. To extend these observations, we embedded optic nerves of 15-day-old rats, adult rats, and an adult human in epon after aldehyde and osmium tetroxide fixation. After 5% H2O2 pretreatment, thin sections were immunostained with 1:250-1:5,000 rabbit antiserum to rat CNS MAG according to the avidin-biotin-peroxidase complex (ABC) method. Dense deposits of reaction product covered compact myelin in both developing and adult optic nerves. When we used 1:500, 1:1,000, and 1:2,000 anti-MAG, less intense immunostaining of myelin was found. We also obtained the same localization in compact myelin with the peroxidase-antiperoxidase (PAP) method. With 1:250 anti-MAG, dense deposits of reaction product were not observed on axolemmal membranes or on oligodendroglial membranes located periaxonally and paranodally. In thin sections of adult human optic nerve, anti-MAG also stained compact myelin intensely. When thin sections of rat and human optic nerves were treated with preimmune or absorbed serum, no immunostaining was observed. Immunoblot tests showed that our MAG antisera did not react with any non-MAG myelin proteins. In contrast with earlier light microscopic data, this study shows that MAG localization does not change during CNS development; both developing and adult compact myelin sheaths contain MAG. As many biochemical studies also show that MAG is present in compact myelin, we suggest that this 100,000 dalton glycoprotein now be called myelin glycoprotein (MGP) instead of MAG.     

Axonal transport of RNA during regeneration of the optic nerves of goldfish.

The distribution of radioactive RNA and RNA precursors in the goldfish optic tecta following intraocular injection of 3H-uridine has been studied during various stages of optic nerve regeneration. 3H-uridine was injected into the posterior chamber of the right eye 17, 30, or 60 days after both optic nerves were crushed. Five were sacrificed at time intervals ranging from 0.5 to 21 days after injection. One day prior to sacrificing, 14C-proline was also injected into the right eye as a marked of fast axonal protein transport. Seventeen to 23 days after crushing, the approximate time of nerve reconnection, the amount of radioactive RNA appearing in the left optic tectum was increased by more than ten times control values. Approximately 30 days after crushing the nerve, when the reconnected nerve is maturing, RNA values were still elevated, but significantly decreased from the earlier stage. By 60 days after crushing the optic nerve, the amounts of RNA in the left tectum was close to normal. Evidence suggesting that, at least, some of the radioactive RNA in the tectum originated from RNA transported along optic axons rather than from RNA synthesized locally in the tectum was provided by autoradiographic experiments. Autoradiograms of paraffin sections taken from the goldfish optic tecta after the intraocular injection of 3H-uridine showed a distribution of grains in a linear pattern, suggesting a distribution over the incoming fibers during the reconnection stage of regeneration. Electron microsocpic autoradiography of glutaraldehyde fixed epoxy sections confirmed that a significant number of grains (shown to be 3H-RNA) were, in fact, over regenerating optic axons. Intracranial injection of 3H-uridine, during the same stage of regeneration, on the other hand, resulted in a distribution of grains, specifically over cell perikaprya. These experiments suggest that during the reconnection phase of nerve regeneration, large amounts of RNA may be carried within regenerating optic axons as they enter the optic tectum.     

Biochemical studies of myelin in Wallerian degeneration of rat optic nerve

Abstract— Wallerian degeneration of the optic nerves of the rat was induced by removal of the eyes. After 54, 66, 76 or 90 days of degeneration a myelin fraction of the nerves was obtained by the procedure of Laatsch et al. (1962). The yield of myelin from the degenerated nerves was decreased, but the isolated myelin appeared to be morphologically normal. The proportion of cholesterol in the myelin lipids was slightly increased, whereas that of the ethanolamineglycerophosphatides was decreased and galactolipids were normal. After one‘cycle’of myelin purification, the high-molecular-weight fraction formed a much greater percentage of the total protein in myelin isolated from degenerated optic nerves. After 2–3‘cycles’of purification, the distribution of protein in myelin isolated from degenerated and normal optic nerves was similar, an observation suggesting that the high-molecular-weight fraction in‘1-cycle myelin’from degenerated optic nerves may have been partly attributable to contamination. With the possible exception of ethanolamineglycerophosphatides, our data suggest that there was no preferential breakdown of myelin lipid constituents nor of protein constituents during Wallerian degeneration of rat optic nerve. As assessed by SDS-gel electrophoresis of the water-insoluble particulate fraction, the percentage of myelin protein was markedly decreased after 76 days of degeneration. However, the major myelin protein constituents in this fraction (the two basic proteins and proteolipid protein) appeared to decrease in the same relative proportions.     

The differential appearance of neurofilament triplet polypeptides in the developing rat optic nerve

The ontogenetic appearance of the individual triplet polypeptides that comprise mammalian neurofilaments was studied in the developing rat optic nerve. Triton-insoluble cytoskeletal preparations from the optic nerves of rats of postnatal ages 1 Day (P1), 6 days (P6), 10 days (P10), 20 days (P20), and 3 months (adult) were analyzed for protein composition by one and two-dimensional gel electrophoresis. Results indicate that at P1, both the 150- and 68-kDa neurofilament subunit proteins are present. The 200-kDa subunit first becomes discernible at P20, but, at this age, it is still present in considerably less quantity than in the adult. Immunocytochemical verification of the presence of neurofilament protein was accomplished by staining tissue sections with specific antibodies against the 150- and the 68-kDa neurofilament subunits using the peroxidase-antiperoxidase technique. Results of the morphological analyses have shown that neurofilaments are not present in quantity until P10, which coincides with the time when the 68-kDa subunit increases in quantity by one dimensional gel analysis. Thus, the 150- and 68-kDa subunits can be detected prior to the appearance of neurofilaments, and the 200-kDa protein is not observed until sometime later. The potential physiological significance of the differential subunit transport is discussed with respect to neuronal differentiation in the developing mammalian CNS.     

Axonal transport of RNA during regeneration of the optic nerves of goldfish

The distribution of radioactive RNA and RNA precursors in the goldfish optic tecta following intraocular injection of ³H-uridine has been studied during various stages of optic nerve regeneration. ³H-uridine was injected into the posterior chamber of the right eye 17, 30, or 60 days after both optic nerves were crushed. Fish were sacrificed at time intervals ranging from 0.5 to 21 days after injection. One day prior to sacrificing, ¹⁴C-proline was also injected into the right eye as a marker of fast axonal protein transport. Seventeen to 23 days after crushing, the approximate time of nerve reconnection, the amount of radioactive RNA appearing in the left optic tectum was increased by more than ten times control values. Approximately 30 days after crushing the nerve, when the reconnected nerve is maturing, RNA values were still elevated, but significantly decreased from the earlier stage. By 60 days after crushing the optic nerve, the amounts of RNA in the left tectum was close to normal. Evidence suggesting that, at least, some of the radioactive RNA in the tectum originated from RNA transported along optic axons rather than from RNA synthesized locally in the tectum was provided by autoradiographic experiments. Autoradiograms of paraffin sections taken from the goldfish optic tecta after the intraocular injection of ³H-uridine showed a distribution of grains in a linear pattern, suggesting a distribution over the incoming fibers during the reconnection stage of regeneration. Electron microscopic autoradiography of glutaraldehyde fixed epoxy sections confirmed that a significant number of grains (shown to be ³H-RNA) were, in fact, over regenerating optic axons. Intracranial injection of ³H-uridine, during the same stage of regeneration, on the other hand, resulted in a distribution of grains, specifically over cell perikarya. These experiments suggest that during the reconnection phase of nerve regeneration, large amounts of RNA may be carried within regenerating optic axons as they enter the optic tectum.     

Optic nerve histopathology in a case of Wolfram Syndrome: A mitochondrial pattern of axonal loss

Mitochondrial dysfunction in Wolfram Syndrome (WS) is controversial and optic neuropathy, a cardinal clinical manifestation, is poorly characterized. We here describe the histopathological features in postmortem retinas and optic nerves (ONs) from one patient with WS, testing the hypothesis that mitochondrial dysfunction underlies the pathology. Eyes and retrobulbar ONs were obtained at autopsy from a WS patient, and compared with those of a Leber hereditary optic neuropathy (LHON) patient and one healthy control. Retinas were stained with hematoxylin & eosin for general morphology and ONs were immunostained for myelin basic protein (MBP). Immunostained ONs were examined in four “quadrants”: superior, inferior, nasal, and temporal. The WS retinas displayed a severe loss of retinal ganglion cells in the macular region similar to the LHON retina, but not in the control. The WS ONs, immunostained for MBP, revealed a zone of degeneration in the temporal and inferior quadrants. This pattern was similar to that seen in the LHON ONs but not in the control. Thus, the WS patient displayed a distinct pattern of optic atrophy observed bilaterally in the temporal and inferior quadrants of the ONs. This arrangement of axonal degeneration, involving primarily the papillomacular bundle, closely resembled LHON and other mitochondrial optic neuropathies, supporting that mitochondrial dysfunction underlies its pathogenesis.     

Developmental changes in phosphorylation state of neurofilament proteins in the chick embryonic optic nerve

Developmental changes in the phosphorylation state of neurofilament proteins (NFPs) in the chick embryonic optic nerve were histochemically and biochemically studied using monoclonal antibody (MAb) 82E10 specific to the highly phosphorylated components of high (180K)- and middle (160K)-molecular-weight subunits of neurofilament (NF) in the chicken. Cross sections of developing embryonic optic nerve were studied by enzyme immunohistochemistry using this MAb. The staining pattern showed marked changes with the developmental stage. In 6-day embryos (E6) the entire cross section was stained, whereas in E10 only about a ventroposterior half of the cross section was stained. In E14 nearly the entire area of the cross section became unstained. Thereafter, the immunoreactivity reappeared and gradually increased, such that in E20 the entire cross section became immunopositive again. Electrophoretic and immunoblot analyses were made on optic nerves dissected out of embryos of various stages. The 82E10 immunoreactivity at the position of NF-M underwent a transient loss in E14 in parallel with the time course of histochemical change. Two-dimensional gels stained for protein further showed that the highly phosphorylated form of NF-M is transiently lost from embryonic optic nerve in E14, while the less phosphorylated form persists throughout the embryonic developmental stages. In order to understand the orderly loss of the 82E10 immunoreactivity in relation to retinotopic and chronotopic organizations of the fibers in the embryonic optic nerve, retinal injection of a fluorescent dye DiI as an anterograde tracing marker for selected fibers was utilized. An ordered arrangement of the fibers was present within the embryonic optic pathway, suggesting that the orderly loss of the 82E10 immunoreactivity in the embryonic optic nerve reflects the chronological order of the optic axons. These changes in the phosphorylation state of NFPs in the embryonic optic nerve presumably reflect dynamic changes of the neuronal cytoskeleton at certain stages during development.     

Specific cell surface labels in the visual centers of Xenopus laevis tadpole identified using monoclonal antibodies

Monoclonal antibodies (MAbs) against the optic tectum of Xenopus tadpoles were generated and screened by the immunofluorescent staining of frozen sections of tadpole brains. MAb-A5 stains the 8th and 9th plexiform layers of the optic tectum, whereas MAb-B2 stains all but the eighth and ninth plexiform layers of the optic tectum. MAb-A5 antigen is also detectable in the nucleus of Belonci, the corpus geniculatum thalamicum, the pretectal area, and the basal optic nucleus, all targets of the optic nerve, but is not detectable in the optic nerve or the optic tract. On the other hand, MAb-B2 does not stain any of these visual centers, though many fibers surrounding them are stained. Eye-enucleation experiments showed that MAb-A5 antigen is expressed in the optic tectum even when it is not innervated by optic nerves. Staining of viable brains with these MAbs indicates that these antigens are cell surface molecules. Immunoadsorption followed by SDS-PAGE suggests that proteins are constituents of these antigens. The MAb-A5 antigen in the diencephalon and the mesencephalon is not detectable at stage 35/36, but is detectable at stage 39 when the optic nerves begin to innervate the optic tectum. The spatial as well as the temporal patterns of the expression of the MAb-A5 antigen suggest that this molecule may be involved in the target recognition of optic nerve fibers.     

Optic Nerve Regeneration in Adult Fish and Apolipoprotein A-I

Fish optic nerves, unlike mammalian optic nerves, are endowed with a high capacity to regenerate. Injury to fish optic nerves causes pronounced changes in the composition of pulse-labeled substances derived from the surrounding non-neuronal cells. The most prominent of these injury-induced changes is in a 28-kilodalton (kDa) polypeptide whose level increases after injury, as revealed by one-dimensional gel electrophoresis and autoradiography. The present study identified as apolipoprotein A-I (apo-A-I) a polypeptide of 28 kDa in media conditioned by regenerating fish optic nerves. The level of this polypeptide increased after injury by approximately 35%. Apo-A-I was isolated by gel-permeation chromatography from delipidated high-density lipoproteins (HDL) that had been obtained from carp plasma by sequential ultracentrifugation. Further identification of the purified protein as apo-A-I was based on its molecular mass (28 kDa) as determined by gel electrophoresis, amino acid composition, and microheterogeneity studies. The isolated protein was further analyzed by immunoblots of two-dimensional gels and was found to contain six isoforms. Western blot analysis using antibodies directed against the isolated plasma protein showed that the 28-kDa polypeptide in the preparation of soluble substances derived from the fish optic nerves (conditioned media, CM) cross-reacted immunologically with the isolated fish plasma apo-A-I. Immunoblots of two-dimensional gels revealed the presence of three apo-A-I isoforms in the CM of regenerating fish optic nerves (pIs: 6.49, 6.64, and 6.73). At least some of the apo-A-I found in the CM is derived from the nerve, as was shown by pulse labeling with [35S]methionine, followed by immunoprecipitation. The apo-A-I immunoactive polypeptides in the CM of the fish optic nerve were found in high molecular-weight, putative HDL-like particles. Immunocytochemical staining revealed that apo-A-I immunoreactive sites were present in the fish optic nerves. Higher labeling was found in injured nerves (between the site of injury and the brain) than in non-injured nerves. The accumulation of apo-A-I in nerves that are capable of regenerating may be similar to that of apo-E in sciatic nerves of mammals (a regenerative system); in contrast, although its synthesis is increased, apo-A-I does not accumulate in avian optic nerves nor does apo-E in rat optic nerves (two nonregenerative systems).     

Comparative localization of Wolfgram W1 and myelin basic proteins in the rat brain during ontogenesis

Summary Antisera raised in rabbits against myelin basic proteins (MBP) and Wolfgram W1 protein isolated from rat myelin were used to study the maturation of oligodendrocytes in the developing rat nervous system. Both proteins were localized immunohistochemically at the light and electron microscopical levels in rat brain from the time of their first appearance to the adult stage. Oligodendrocytes were first detected by their positive staining with W1 antiserum two days after birth and at 1–3 days later with MBP antiserum. At 8–10 days, the number of oligodendrocytes labelled with both sera increases and the myelinated fibre pathways were clearly visible. Labelling with W1 antiserum was observed in oligodendrocytes at all stages from 2 days after birth to adulthood and in myelin fibres when they were present. In contrast, staining of oligodendroglial cells with MBP declined during the period of rapid myelination (20–25 days after birth) and finally disappeared, whereas myelin staining was still apparent. The electron microscopical study revealed that the synthesis of Wolfgram proteins occurred mostly at the peripheral cytoplasmic ribosomes of the cells, from where they were probably transported to processes engaged in myelination. The electron micrographs also showed that the sites of MBP synthesis seemed to be more uniformly distributed over the entire cytoplasm.     

Activation of epidermal growth factor receptors directs astrocytes to organize in a network surrounding axons in the developing rat optic nerve

In postnatal developing optic nerves, astrocytes organize their processes in a cribriform network to group axons into bundles. In neonatal rat optic nerves in vivo, the active form of EGFR tyrosine kinase is abundantly present when the organization of astrocytes and axons is most actively occurring. Blocking activity of EGFR tyrosine kinase during the development of rat optic nerves in vivo inhibits astrocytes from extending fine processes to surround axons. In vitro, postnatal optic nerve astrocytes, stimulated by EGF, organize into cribriform structures which look remarkably like the in vivo structure of astrocytes in the optic nerve. In addition, when astrocytes are co-cultured with neonatal rat retinal explants in the presence of EGF, astrocytes that are adjacent to the retinal explants, re-organize to an astrocyte-free zone into which neurites grow out from the retinal tissue. We hypothesize that in the developing optic nerve, EGFR activity directs the formation of a histo-architectural structure of astrocytes which surrounds axons and provides a permissive environment for axon development.     

猫视神经年龄相关的形态学变化

对4只青年猫(1-3龄)和4只老年猫(10-13龄)视神经进行形态计量比较研究。取两个年龄组的颅内相应部分视神经进行横向连续切片,H.E染色于光镜下观察其基本结构;相邻切片进行结晶紫染色显示胶质细胞;神经丝蛋白(NF)免疫染色显示视神经纤维,胶质纤维酸性蛋白(GFAP)免疫染色显示星形胶质细胞(AS),对实验结果进行统计学分析并绘制纤维直径谱。与青年猫相比,老年猫视神经外膜厚度、直径、面积均显著增加,视神经纤维的密度和数量显著下降,且以视神经中央部纤维密度下降最显著;纤维直径谱分析结果显示,青、老年猫纤维直径分布范围相似,但老年猫的峰直径及纤维平均直径比青年猫的显著减小;另外,老年猫视神经束中的星形胶质细胞明显膨大,胶质细胞密度以及星形胶质细胞占胶质细胞总数的百分比均显著增加。结果表明:在衰老过程中视神经纤维出现明显的丢失现象,纤维平均直径显著减小使其对视觉信息的传导速度减慢,这可能是导致老年个体视觉分析速度下降的重要原因;老年个体视神经束内胶质细胞活动增强可能对维持视神经纤维形态、功能或延缓视神经进一步衰老起保护作用     

Morphological changes of myelin sheaths in rats intracranially injected with apotransferrin

Previous findings from our laboratories indicate that the intracranial injection of apotransferrin (aTf) in neonatal rats produces an accelerated oligodendrocyte maturation and an enhanced production and deposition of myelin membranes in the brain. To evaluate the anatomical distribution and the morphological characteristics of the myelin in these rats, we analyzed the optic nerves, cerebellum, and selected areas of brain sections from aTf-treated and control rats by both light and electron microscopy. Microscopic identification of myelin using a specific staining procedure, showed that in aTf-injected rats, in coincidence with previous biochemical studies, there was an increased deposition of myelin in selected areas of the nervous system. Qualitative and quantitative analysis of electron micrographs from areas showing increased myelinaton, such as the optic nerves and the corpus callosum, showed that among other changes, the intracranial treatment with aTf produces ultrastructural evidences of myelin decompaction, consisting of an enlargement in the distance between adjacent major dense lines, a decreased density of the intraperiod line, and an increased electron density of the major dense line, accompanied by a significant increase in its width. The intracranial administration of aTf induces an increased deposition of myelin by oligodeudroglial cells (OLGc), and these myelin membranes, in spite of the changes in composition and in morphology, appear to function normally. Apotransferrin can be considered as a differentiation factor that could be used to stimulate remyelination in cases in which myelin has been destroyed by various pathological processes.     

The spatiotemporal distribution of N-CAM in the retinotectal pathway of adult goldfish detected by the monoclonal antibody D3

The spatiotemporal distribution of neural cell adhesion molecule (N-CAM) in the retinotectal system of adult goldfish was assessed by immunofluorescence using the monoclonal antibody (Mab) D3 against chick N-CAM. In immunoblots with extracts of cell surface membranes of fish brains, Mab D3 recognized a prominent band at 170K and a weak band at 130K (K = 10(3) Mr). N-CAM immunofluorescence on cells was restricted to the marginal growth zones of the retina and the tectum and, in normal fish, to the youngest axons from the new ganglion cells of the peripheral retinal margin. In fish with previously transected optic nerves (ONS), Mab D3 staining was found transiently on all axons from the site of the cut into the retinorecipient layers of the tectum, but disappeared from these axons 450 days after ONS. Growing retinal axons in vitro exhibited N-CAM immunofluorescence throughout their entire extent, including their growth cones. Glial cells cultured from regenerating optic nerves were, however, unlabeled. These data are consistent with the idea that N-CAM is involved in adhesive interactions of growing axons. The temporally regulated expression of N-CAM on the new retinal axons may contribute to the creation of the age-related organization of the axons in the retinotectal pathway of fish.     

Antibodies to neurofilament protein and other brain proteins reveal the innervation of peripheral organs

Monoclonal and polyclonal antibodies to neurofilament proteins, neuron-specific enolase, glial fibrillary acidic protein and S-100 have been used to demonstrate nerves, ganglion cells and the supportive glial system of the innervation of various organs. The female genitalia, the urinary tract, the respiratory system, the pancreas, the heart and the skin of several mammalian species, including rat, mouse, guinea pig, cat, pig, monkey and man were fixed in para-benzoquinone and portions of each organ were snap frozen. Serial or free-floating thick cryostat sections were stained using indirect immunofluorescence and peroxidase anti-peroxidase immunocytochemistry. In addition, the newly described and highly sensitive immunogold-silver staining technique was used on Bouin's-fixed and wax-embedded tissues. Antibodies to neurofilament proteins seemed to react with neuronal structures in all the species studied. Alternately stained serial sections showed a similar distribution of neurofilament proteins and neuron-specific enolase-containing nerves. Neuron-specific enolase staining had a diffuse appearance and was found to be highly variable, indicating that the neuron-specific enolase content might be related to the physiological state of the nerves and ganglion cells, whereas antibodies to neurofilament protein gave a consistently intense and very clear picture of the ganglion cells and nerve fibres. Antibodies to S-100 stained supportive elements of the peripheral nervous system in all tissues examined, whereas antibodies to glial fibrillary acidic protein were more selective.