Shinobu C. Fujita

Subclasses of olfactory receptor cells and their segregated central projections demonstrated by a monoclonal antibody

A library of monoclonal antibodies (MAbs) was generated against a homogenate of the rabbit olfactory bulb. One of them immunohistochemically distinguished a subgroup of olfactory nerves. Both in the olfactory bulb and the epithelium, this MAb labeled most olfactory receptor axons in the lateral but only a small fraction in the medial portion. These findings demonstrate a molecular heterogeneity among olfactory receptor cells and suggest a functional division between the lateral and the medial portions of the epithelium and the bulb.

Identification of a synaptic vesicle-specific 38,000-dalton protein by monoclonal antibodies

Synaptic vesicles were purified from the guinea pig cerebrum by sucrose density gradient centrifugation, and monoclonal antibodies (MAbs) were produced against this vesicle fraction. Seven MAbs (171B5, 171E8, 174D12, 174H11, 177A2, 177H11 and 178D4) recognized a novel acidic protein of about 38,000 daltons which was specific to synaptic vesicles. In immunofluorescence microscopy, the staining pattern of these MAbs corresponded to the distribution of the synapses in the guinea pig central nervous system. These MAbs appeared to stain all synaptic regions, irrespective of their synaptic function or type of neurotransmitters. MAb 171B5 and 174H11 stained the rat, rabbit and bovine synapses similarly to the guinea pig. Two other MAbs (171E8 and 177H11) stained other mammals weakly but the remaining 3 MAbs reacted only with the guinea pig. In immunoelectron microscopy of both the cerebellar tissue and isolated vesicle fraction, these MAbs selectively labeled the synaptic vesicles but not other structures. Immunoblot analysis was performed on electrophoretically separated proteins in vesicle fraction and brain homogenate. All of 7 MAbs reacted with a band at a molecular weight of about 38,000 from the guinea pig. Isoelectric focussing disclosed that this protein was acidic (pI 4.5-5).

Immunochemical identification of subgroups of vomeronasal nerve fibers and their segregated terminations in the accessory olfactory bulb

Vomeronasal nerve (VNN) fibers and their terminations in the accessory olfactory bulb (AOB) were studied immunohistochemically using 3 monoclonal antibodies (MAbs). One MAb (R2D5) labeled all VNN fibers. Another MAb (R4B12) labeled a subgroup of the VNN fibers which terminated in the rostrolateral glomeruli in the AOB. The third MAb (R5A10) recognized a complementary subgroup of the VNN which terminated in the caudomedial portion of the AOB. These results for the first time show occurrence of subtypes in the VNN axons with segregated terminations in the AOB.

Projections of two subclasses of vomeronasal nerve fibers to the accessory olfactory bulb in the rabbit

The organization of the projections of subclasses of vomeronasal nerve fibers to the accessory olfactory bulb was analysed using monoclonal antibodies generated against a homogenate of the rabbit olfactory bulb. Monoclonal antibody R2D5 labels all the somata of vomeronasal receptor cells in the vomeronasal organ as well as all their axons (vomeronasal nerve fibers). Another monoclonal antibody (R4B12), which has been shown to selectively bind and thus identify a subclass of olfactory nerve fibers, also labels a subclass of vomeronasal nerve fibers. The R4B12-positive subclass of vomeronasal nerve fibers project to the glomeruli in the rostrolateral part of the accessory olfactory bulb. The third monoclonal antibody (R5A10) recognizes a complementary subclass of vomeronasal nerve fibers projecting to the glomeruli in the caudomedial part of the accessory bulb. In contrast to the clearly segregated terminations in the accessory bulb, the two subclasses of vomeronasal nerve fibers are intermingled with each other in the vomeronasal nerve bundles. Retrograde labeling of vomeronasal receptor cell somata following injection of horseradish peroxidase within the rostrolateral (R4B12-positive) part of the accessory bulb indicates that vomeronasal receptor cells of this subtype are widely distributed in the vomeronasal sensory epithelium. These results demonstrate the heterogeneity of vomeronasal receptor cells and the specificity of projections arising from subclasses of vomeronasal nerve fibers to the accessory olfactory bulb.

Glycosaminoglycan-related epitopes surrounding different subsets of mammalian central neurons

Among a panel of monoclonal antibodies generated against monkey brain tissue, a class of antibodies was found to produce perineuronal staining of small subsets of mammalian central neurons. Three antibodies (MAbs 473, 376, 528) we report here define two different, though partially overlapping, neuronal subsets in the monkey neocortex. All 3 antibodies stain in addition certain chondrocytes. The neural immunoreactivities were lost, and the chondral immunoreactivities either lost or enhanced, after treatment of the sections with chondroitinase ABC. Independently, 3 other antibodies (MAbs 1B5, 9A2, 3B3) with established specificity to glycosaminoglycan epitopes also produced perineuronal staining of a related subset of central neurons. Immunoblot experiments with two of the antibodies revealed bands of high molecular weight. These findings indicate that certain glycosaminoglycans occur surrounding mammalian central neurons, and suggest that different neuronal subsets are associated with different combinations of proteoglycan epitopes.

A monoclonal antibody identifies a novel epitope surrounding a subpopulation of the mammalian central neurons.

A monoclonal antibody was obtained by immunizing mice with an extract of monkey brain. The monoclonal antibody 473 stained a small subpopulation of neurons in various regions of monkey and rat central nervous system. The perimeters of neuronal somata and the proximal parts of dendrites bound the antibody. Electron microscopic analysis showed that the immunoreactivity was associated with the outer surface of the cell. The immunoreactivity in the rat cerebral cortex appeared gradually during the second four weeks after birth. The antibody stained fetal cartilages but otherwise was specific to the nervous system. Experiments on the stability of the immunoreactivity to enzymatic and chemical treatments of the sections suggest that the antigen molecule is of proteoglycan nature.

Four synaptic vesicle-specific proteins: identification by monoclonal antibodies and distribution in the nervous tissue and the adrenal medulla

Synaptic vesicles from the guinea-pig cerebrum were isolated and administered to mice for the production of monoclonal antibodies (MAb). Four vesicle-associated proteins in the guinea-pig nervous tissue were specifically and differentially recognized by MAbs thus obtained. These proteins had molecular weights of 30,000, 36,000, 38,000 and 65,000 Da and were named SVPs (synaptic vesicle proteins) 30, 36, 38 and 65, respectively. Immunohistochemistry demonstrated that all SVPs were localized in the synaptic regions throughout the central nervous system and in the adrenal medulla. Nerve terminals in skeletal muscle, smooth muscle and sympathetic ganglion contained SVPs 36 and 38. Immunoelectron microscopy of the cerebellar cortex confirmed the localization of SVPs in the synaptic vesicles and the adjacent membranes of the presynaptic nerve terminals. Fractionation of the cerebral tissue and treatment with various agents showed that SVPs were localized in the synaptic vesicles and the synaptic plasma membrane and that SVPs were integrated within the membrane and liberated only after solubilization of the membrane.

A monoclonal antibody specific for a subpopulation of retinal bipolar cells in the frog and other vertebrates.

One monoclonal antibody 115A10 (MAb 5A10) specifically stained a subpopulation of retinal bipolar cells in various vertebrates. In the bullfrog retina, MAb 5A10 stained the large bipolar cells, but not the small bipolar cells. Labeling of the living bipolar cells was observed in isolated cell preparation of the frog retina. MAb 5A10 can serve as a cell-specific marker of the bipolar cells.

Monoclonal antibodies demonstrate regional specificity in the spinal funiculi of the chick embryo

To explore the extent and significance of chemical diversity of neurons, monoclonal antibodies were generated that bind to the chick embryonic central nervous system with varying degrees of regional specificity. Mice were immunized against a homogenate of optic nerves from 8-day chick embryos. Antibody was screened by an indirect fluorescence immunohistochemical method using frozen sections of embryonic neural tissues. From 3 fusion experiments, 58 lines of hybrydoma were cloned. Twenty-three monoclonal antibodies were studied in detail, and here reported, for their characteristic staining patterns in the spinal cord of 6-day embryos. The majority of the antibodies bound preferentially to different subregions of spinal funiculi, in which glial elements are still undeveloped. At least 6 subregions could be distinguished in the funiculi, probably corresponding to the developing spinal tracts. For 8 of the antibodies, immunoreactive polypeptides were identified in an electrophoretic analysis.

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.