Sarah K. Pixley

Transition between immature radial glia and mature astrocytes studied with a monoclonal antibody to vimentin

A monoclonal antibody to vimentin (RBA1) and a polyclonal antiserum to glial fibrillary acidic protein (GFAP) were used in double labeling experiments to examine astrocyte intermediate filaments in development and wounding. RBA1 bound to radial glia in newborn rat parietal cortex that are predominantly anti-GFAP-negative. The RBA1-positive radial fibers disappeared by postnatal day 20 with the greatest rate of disappearance occurring between day 8 and day 15. Between birth and day 20, the anti-GFAP staining increased to the adult pattern in mature shaped astrocytes. Some overlay was observed between the binding patterns of the two antibodies. Stab wounds to cortical areas were made at a developmental time when there were normally no RBA1-positive astrocytes. RBA1-positivity was present in some astrocytes but only at the edges of the wounds. The distribution patterns of RBA1-positive cells led to hypotheses concerning the possible function of vimentin in astrocytes and its regulation during development and wounding.

CNS glial cells support in vitro survivial, division, and differentiation of dissociated olfactory neuronal progenitor cells

Olfactory receptor neurons (ORNs) are replaced and differentiate in adult animals, but differentiation in dissociated cell culture has not been demonstrated. To test whether contact with the CNS regulates maturation, neonatal rat olfactory cells were grown on a culture substrate or on CNS astrocytes. Mature ORNs, immunopositive for olfactory marker protein (OMP), disappeared rapidly from both systems. Neurons positive for neuron-specific tubulin (immature and mature) disappeared from substrate-only cultures, but remained abundant in the cocultures. OMP-positive neurons reappeared after 10 days in vitro. Pulse labeling with [3H]thymidine showed extensive neurogenesis of both immature and mature olfactory neurons. This demonstrates, in vitro, both division and differentiation of olfactory progenitor cells.

Ghrelin enhances olfactory sensitivity and exploratory sniffing in rodents and humans

Olfaction is an integral part of feeding providing predictive cues that anticipate ingestion. Although olfactory function is modulated by factors such as prolonged fasting, the underlying neural mechanisms remain poorly understood. We recently identified ghrelin receptors in olfactory circuits in the brain. We therefore investigated the role of the appetite-stimulating hormone ghrelin in olfactory processing in rodents and humans, testing the hypothesis that ghrelin lowers olfactory detection thresholds and enhances exploratory sniffing, both being related to food seeking. In rats, intracerebroventricular ghrelin decreased odor detection thresholds and increased sniffing frequency. In humans, systemic ghrelin infusions significantly enhanced sniff magnitudes in response to both food and nonfood odorants and air in comparison to control saline infusions but did not affect the pleasantness ratings of odors. This is consistent with a specific effect on odor detection and not the hedonic value of odors. Collectively, our findings indicate that ghrelin stimulates exploratory sniffing and increases olfactory sensitivity, presumably enhancing the ability to locate, identify, and select foods. This novel role is consistent with ghrelins overall function as a signal amplifier at the molecular interface between environmental and nutritional cues and neuroendocrine circuits controlling energy homeostasis.

OLFACTORY RECEPTOR NEURONS EXPRESS D2 DOPAMINE RECEPTORS

The role of the dopamine (DA) in the olfactory bulb (OB) was explored by determining which of the potential target cells express dopamine receptors (DARs). Previously, it was reported that D2‐like DAR (D2, D3, and D4 subtypes) radioligand binding is restricted to the outer layers of the OB. The neuronal elements present only in these layers are the axons of the olfactory receptor neurons (ORNs) and the juxtaglomerular (JG) neurons of the glomerular layer. Based on this pattern of D2‐like ligand binding, it was suggested that D2‐like receptors might be located presynaptically on ORN terminals. The present study was undertaken to investigate this hypothesis. In the outer bulb layers of rats in which the ORNs were destroyed by nasal lavage with ZnSO4, D2‐like radioligand binding was reduced severely. The receptor subtype D2 mRNA, but not D3 mRNA, was detected in adult rat olfactory epithelial tissue. By using in situ hybridization, this D2 mRNA was located preferentially in epithelial layers that contain ORN perikarya. D2 mRNA was eliminated after bulbectomy, a manipulation known to cause retrograde degeneration of the mature ORNs. Taken together, the surgical manipulations indicate that mature ORNs express D2 DARs and are consistent with the hypothesis that functional receptors are translocated to their axons and terminals in the bulb. This suggests that dopamine released from JG interneurons could be capable of presynaptically influencing neurotransmission from the olfactory nerve terminals to OB target cells through the D2 receptor. J. Comp. Neurol. 411:666–673, 1999.

AGE AND DIFFERENTIATION-RELATED DIFFERENCES IN NEURON-SPECIFIC TUBULIN IMMUNOSTAINING OF OLFACTORY SENSORY NEURONS

Olfactory sensory neurons (OSNs) are unusual mammalian neurons because they are produced continually throughout adult life and because their production is upregulated after injury. Because OSNs also have an unusual immunological profile and do not bind the commonly used antibody markers for neurons, we sought new antibody markers for studies of OSN regeneration. In this report, we characterize the staining patterns of antibodies to the Class III beta, neuron-specific, tubulin (NST) in rat olfactory tissue sections, to determine if these antibodies specifically label OSNs. In tissue sections from newborn rats, monoclonal antibodies to NST labeled cell bodies and processes of both immature (olfactory marker protein, OMP, -negative) and mature (OMP-positive) OSNs. In tissue sections from adult rats, immature OSNs showed both cell body and dendrite staining with anti-NST, while mature OSNs showed little or no cell body staining. Mature OSNs appeared to have both axonal and dendritic anti-NST staining. Axonal staining was suggested by the complete labeling of the olfactory nerve bundles and the nerve fiber layer of the olfactory bulb. The extent of labeling was judged by comparison with anti-OMP staining. Mature OSN dendritic staining was suggested because a much higher number of dendrites were anti-NST stained in the epithelium than cell bodies. These changes suggest both age and differentiation-related changes in subcellular distribution of NST in OSNs. NST antibodies are thus good markers for all OSNs in the newborn rat, but selective markers for immature OSNs and mature OSN processes in the adult rat. NST antibodies may also be useful probes for beta III tubulin function in neurons.

Cultured rat olfactory neurons are excitable and respond to odors.

Newborn rat nasal tissues containing olfactory epithelium were dissociated and maintained in a monolayer cell culture. Neurons were present, as determined by immunostaining with antibodies to 4 neuron-specific proteins: neuron-specific enolase, microtubule-associated protein 2, tau protein and synaptophysin. Immunostained neurons had a distinctive morphology resembling olfactory neurons. By patch-clamp analysis, these cells were electrically active. Responses of some neurons to physiological concentrations of an odorant mixture identified them as olfactory receptor cells.

A monoclonal antibody against vimentin: Characterization

A monoclonal antibody was developed using rat cerebral cortex astrocytes purified in vitro as the antigenic material. Screening was done by labeling antibodies bound to cerebellum slices with fluorescent tagged secondary antibodies. The monoclonal antibody (RBA1) bound to intracellular filaments in all cells examined in culture. The coloration of tissue sections by RBA1 was identical to that described for polyclonal antibodies against the intermediate filament protein vimentin. In the brain this included binding to meninges, blood vessels, ependymal cells, choroid plexus lining cells and a subpopulation of astrocytes. The latter included Bergman glial fibers, white matter astrocytes and tanycytes. Müller cells in the retina and fibroblast-like cells in the skin, tongue and intestine were RBA1-positive. In immunoblots in which purified vimentin and desmin were run on SDS and transferred to nitrocellulose paper, RBA1 bound to vimentin but not desmin. When cultured astrocyte proteins were blotted, the antibody bound to both GFAP and vimentin, but no GFAP staining was observed in any of the tissue section staining. Purified vimentin blocked tissue and cultured cell binding of the antibody. Therefore RBA1 is considered to be an antibody specific for the intermediate filament protein vimentin.

Poly(ε‐caprolactone)/keratin‐based composite nanofibers for biomedical applications

Keratin-based composite nanofibers have been fabricated by an electrospinning technique. Aqueous soluble keratin extracted from human hair was successfully blended with poly(ε-caprolactone) (PCL) in different ratios and transformed into nanofibrous membranes. Toward the potential use of this nanofibrous membrane in tissue engineering, its physicochemical properties, such as morphology, mechanical strength, crystallinity, chemical structure, and integrity in aqueous medium were studied and its cellular compatibility was determined. Nanofibrous membranes with PCL/keratin ratios from 100/00 to 70/30 showed good uniformity in fiber morphology and suitable mechanical properties, and retained the integrity of their fibrous structure in buffered solutions. Experimental results, using cell viability assays and scanning electron microscopy imaging, showed that the nanofibrous membranes supported 3T3 cell viability. The ability to produce blended nanofibers from protein and synthetic polymers represents a significant advancement in development of composite materials with structural and material properties that will support biomedical applications. This provides new nanofibrous materials for applications in tissue engineering and regenerative medicine.

Differential effects of antipsychotic and antidepressant drugs on neurogenic regions in rats

Increased neurogenesis in the hippocampus and subventricular zone (SVZ) of the brain of animals has been demonstrated following administration of several psychotropic medications. Such changes are thought to regenerate tissues and contribute to the beneficial effects of the medications. This study sought to determine if another neurogenic tissue, the peripheral olfactory epithelium (OE), might also exhibit changes after treatment with psychotropic medications. Young adult male rats were treated with risperidone and paliperidone, atypical antipsychotic medications; fluoxetine, a selective serotonin reuptake inhibitor (SSRI) antidepressant; and diluent control for 28days via drinking water. Bromodeoxyuridine (BrdU) was injected to label dividing cells and positive cells were quantified in the OE, cortical SVZ, and dentate gyrus (DG) of the hippocampus. In the first of two studies, paliperidone and risperidone treatment (at 1mg/kg/day) resulted in increased numbers over controls of BrdU positive cells in the OE. In the second study, examining OE, SVZ and DG in the same animal, paliperidone, but not risperidone or fluoxetine (0.6 mg/kg/day) resulted in increased cells in the OE and posterior SVZ. However, fluoxetine, but not paliperidone or risperidone treatment increased BrdU positive cells in the DG. These results show that psychotropic drug-induced cell proliferation occurs in the OE and parallels changes in the SVZ but not DG. Thus, the peripheral OE can serve as a proxy for certain psychotropic drug-induced actions on SVZ brain cell proliferation. This olfactory model can be employed in human research as a method to explore the neurogenesis effects of various pharmacologic treatments of neuropsychiatric disorders.

Characterization of olfactory receptor neurons and other cell types in dissociated rat olfactory cell cultures

In dissociated cell cultures, control over the cellular environment facilitates study of the differentiation of mature cellular phenotypes. Central to this approach is a rigorous characterization of the cells that reside in culture. Therefore, we have used a battery of cell type‐specific antibody markers to identify the cell types present in dissociated cultures of olfactory mucosal cells (containing cells from both the epithelium and lamina propria). To identify olfactory receptor neurons in the cultures, staining with antibodies against neuron‐specific tubulin was compared to staining with antibodies to neuron‐specific enolase, the neural cell adhesion molecule, N‐CAM, and the adhesion molecule, Ll. Staining of mature olfactory neurons in culture, with an antibody against the olfactory marker protein, was compared to staining with antibodies to carnosine. In contrast to tissue section staining, the overlap between carnosine and olfactory marker protein staining was not complete. Olfactory nerve glial cells were immunoreactive for the S100β protein and nestin, an intermediate filament found in early neuronal progenitor cells and Schwann cells. Antibodies to nestin did not label olfactory neurons or progenitor cells. An antibody to an oligodendrocyte‐Schwann cell enzyme, 2′,3′‐cyclic nucleotide 3′‐phosphodiesterase, did not label olfactory glia, but did label oligodendrocyte‐like cells that appeared to be derived from the CNS glial feeder layer. An antibody against the heavy (200 kDa) neurofilament protein stained a minor subset of cells. The cultures also contained muscle cells, cartilage cells and macrophages (and/or microglia). These results demonstrate that multiple cell types either maintain or re‐establish differentiated, cell type‐specific phenotypes in dissociated olfactory cell cultures.