Differential expression of SNAP-25 isoforms and SNAP-23 in the adrenal gland

In the rat adrenal gland, we previously observed that SNAP-25 is not restricted to the plasmalemma in noradrenergic cells as it is in adrenergic cells, and hypothesized that SNAP-25 isoform expression is different in the two phenotypes. Expression of SNAP-25 isoforms and SNAP-23 was examined by immunoblotting, immunofluorescence, and RT-PCR. Amplifications of SNAP-25 mRNAs were combined with Southern hybridization, restriction enzyme analysis, and sequencing of cloned PCR products to compare SNAP-25 isoform expression in rat and bovine adrenal glands. SNAP-25 and SNAP-23 mRNA and protein are expressed in the glands; SNAP-23 is enriched in the adrenal cortex, whereas SNAP-25 is restricted to the adrenal medulla. Furthermore, high levels of SNAP-25 and low levels of SNAP-23 are observed in the PC12 cells, whereas both SNAP-25 and SNAP-23 are expressed in adrenal medullary cultures. In all extracts, the SNAP-23 mRNA corresponded to SNAP-23a. SNAP-25a is the major form expressed in rat adrenal glands (75%), as it is in PC12 cells (80%), but both SNAP-25a and SNAP-25b (40% vs. 60%) are expressed in bovine adrenal medulla in situ and in culture. In addition, an enriched population of adrenergic cells (93%) expressed a higher level of SNAP-25b (70%), suggesting that this isoform may not be restricted to fast neurotransmission.

Computational models of coherent and transparent plaid motion

The perceived motion of two added sinusoidal gratings of similar amplitude and spatial frequency but different orientations is often coherent. However, when either relative grating contrast or frequency are varied, perception may transform to a motion transparency. For plaids, both multiplicative and additive transparent percepts are reported. To explain perception, several computational models of motion transparency are proposed. The most general model considered is, however, a quadratic form with five unknowns. To stabilize the transparent model, additional constraints are introduced so that two velocities may be detected from the motion of plaid patterns. It is shown how this model may be realised by a two-layer (linear) feedforward network and how network learning paradigms may be used to explain some facets of visual perception. To describe the motion of plaid patterns there is an ambiguity because computational models of both coherent and transparent motion may be used to detect image velocity. In view of this competition between models, the issue of model selection is addressed; especially for cases where two or more models fit the image measurements without a residual error. The computational approach that is proposed affords one explanation why perception selects transparency in favour of coherence for plaid patterns by adjustments of relative grating contrast and frequency.

Linear and nonlinear transparencies in binocular vision

When the product of a vertical square-wave grating (contrast envelope) and a horizontal sinusoidal grating (carrier) are viewed binocularly with different disparity cues they can be perceived transparently at different depths. We found, however, that the transparency was asymmetric; it only occurred when the envelope was perceived to be the overlaying surface. When the same two signals were added, the percept of transparency was symmetrical; either signal could be seen in front of or behind the other at different depths. Differences between these multiplicative and additive signal combinations were examined in two experiments. In one, we measured disparity thresholds for transparency as a function of the spatial frequency of the envelope. In the other, we measured disparity discrimination thresholds. In both experiments the thresholds for the multiplicative condition, unlike the additive condition, showed distinct minima at low envelope frequencies. The different sensitivity curves found for multiplicative and additive signal combinations suggest that different processes mediated the disparity signal. The data are consistent with a two-channel model of binocular matching, with multiple depth cues represented at single retinal locations.

Plaid slant and inclination thresholds can be predicted from components

We investigated whether stereoscopic slant and inclination thresholds for surfaces defined by two component plaids could be predicted from the interocular differences in their individual component gratings. Thresholds were measured for binocular images defined by single sinusoidal gratings and two component plaids. In both cases thresholds showed a marked dependence on component orientation. For absolute component orientations greater than 45 deg we found that inclination thresholds were smaller than slant thresholds. However, for absolute component orientations less than 45 deg, we found a reversal: slant thresholds were smaller than inclination thresholds. We considered three models that might account for these data. One assumed that thresholds stemmed from interocular position differences of corresponding image points. The other two assumed a combination of position, orientation and/or spatial-frequency differences. The best fits were obtained from those models that explicitly represented orientation differences. From the model combining orientation and spatial-frequency differences, we estimated the relative cue sensitivity to be 1.7:1, respectively. For plaids, we found that thresholds obtained from the individual components could be used to predict thresholds for plaids, even though an additional disparity cue from the contrast beat was available.

Are exocytosis mechanisms neurotransmitter specific?

Neurotransmission is a multistage regulated process in which a variety of active molecules contained in vesicles are liberated in response to specific stimuli from different types of neurone or related cells. This includes the release of fast neurotransmitters such as amino acids and acetylcholine from central and peripheral synapses, but also that of relatively slow-acting polypeptides from central and peripheral neurones or neuroendocrine cells. Considerable progress has been made over recent years in the understanding at a molecular level of the mechanism of regulated exocytosis, a crucial phase in this phenomenon. The currently proposed overall mechanism, which incorporates the "SNARE" hypothesis for vesicle-membrane docking and fusion, is based on data from experimental models ranging from brain synaptosomes to mast cells. Since the kinetics of the models studied and the physiological effects of the neurotransmitters implicated vary so much, it is pertinent to question whether a general mechanism can be proposed from such experimental data. This review examines known differences in putative exocytotic mechanisms for the various systems studied and attempts to relate these to the nature of the active substances released. Differences exist in each step of the exocytosis process and include the channel through which Ca2+ enters to trigger it or the internal Ca2- source, the type of vesicle in which the transmitter is packaged, the way vesicles are translocated to the surface membrane or how they dock and fuse with it. Major differences have been reported in release mechanisms of different types of vesicle, but minor differences also exist within the same vesicle class. Thus small synaptic vesicles and large dense core vesicles are translocated by distinct processes and the Ca2+ channels, Ca2+ sensors and docking proteins involved in other steps are not identical in all neuronal phenotypes. It may be concluded that each of these differences has evolved to accommodate the different physiological requirements of the neuromodulator released.

Chymase cleavage of stem cell factor yields a bioactive, soluble product

Stem cell factor (SCF) is produced by stromal cells as a membrane-bound molecule, which may be proteolytically cleaved at a site close to the membrane to produce a soluble bioactive form. The proteases producing this cleavage are unknown. In this study, we demonstrate that human mast cell chymase, a chymotrypsin-like protease, cleaves SCF at a novel site. Cleavage is at the peptide bond between Phe-158 and Met-159, which are encoded by exon 6 of the SCF gene. This cleavage results in a soluble bioactive product that is 7 amino acids shorter at the C terminus than previously identified soluble SCF. This research shows the identification of a physiologically relevant enzyme that specifically cleaves SCF. Because mast cells express the KIT protein, the receptor for SCF, and respond to SCF by proliferation and degranulation, this observation identifies a possible feedback loop in which chymase released from mast cell secretory granules may solubilize SCF bound to the membrane of surrounding stromal cells. The liberated soluble SCF may in turn stimulate mast cell proliferation and differentiated functions; this loop could contribute to abnormal accumulations of mast cells in the skin and hyperpigmentation at sites of chronic cutaneous inflammation.

An adaptive Reichardt detector model of motion adaptation in insects and mammals

There are marked similarities in the adaptation to motion observed in wide-field directional neurons found in the mammalian nucleus of the optic tract and cells in the insect lobula plate. However, while the form and time scale of adaptation is comparable in the two systems, there is a difference in the directional properties of the effect. A model based on the Reichardt detector is proposed to describe adaptation in mammals and insects, with only minor modifications required to account for the differences in directionality. Temporal-frequency response functions of the neurons and the model are shifted laterally and compressed by motion adaptation. The lateral shift enhances dynamic range and differential motion sensitivity. The compression is not caused by fatigue, but is an intrinsic property of the adaptive process resulting from interdependence of temporal-frequency tuning and gain in the temporal filters of the motion detectors.

Psychophysics of motion adaptation parallels insect electrophysiology

We investigate the form and time course of motion adaptation, comparing the psychophysical performance of human subjects with existing electrophysiological data on insect vision. In the H1 neuron of the fly, the response to a maintained motion stimulus is known to decrease over time while sensitivity to variations in speed around the maintained level increases. This behaviour can be modelled by modifying a correlation-based motion detector to include adaptable temporal filters (Fig. 1). We find that the form and time course of sensitivity changes in human motion perception are comparable to fly vision. We propose that, in both cases, adaptation serves to improve the transmission of novel motion information along the visual pathways at the expense of maintaining an accurate representation of the unchanging components of the stimulus.

Immunocytochemical localization of NCAM and catecholamine-synthesizing enzymes in rabbit intra- and extra-adrenal chromaffin tissue

The expression of the neural cell adhesion molecule, chromogranin A, and catecholamine-synthesizing enzymes (tyrosine hydroxylase and phenylethanolamine N-methyl transferase) in adrenal medulla and para-aortic bodies (paraganglia) of the adult rabbit, was studied by immunofluorescence. The specificity of the neural cell adhesion molecule antibody employed was demonstrated on rabbit tissue by immunoblotting. Neural cell adhesion molecule was found to be expressed not only by adrenal medullary cells but also by extra-adrenal chromaffin cells present in para-aortic bodies. These paraganglionic cells were as intensely immunolabelled for chromogranin A as adrenal medullary chromaffin cells. They were also labelled for the catecholamine-synthesizing enzymes tested here. However, their levels of the adrenalin-synthesizing enzyme phenylethanolamine N-methyl transferase were lower than those of medullary chromaffin cells.

A model of temporal adaptation in fly motion vision

A computational model is proposed to account for the adaptive properties of the fly motion system. The response properties of motion-sensitive neurons in the fly are modelled using an underdamped adaptive scheme to adjust the time constants of delay filters in an array of Reichardt detectors. It is shown that the increase in both temporal resolution and sensitivity to velocity change observed following adaptation to constant motion can be understood as a consequence of local adaptation of the filter time constants on the basis of the outputs of elementary motion detectors.

Structure-function relationships of stem cell factor: an analysis based on a series of human-murine stem cell factor chimera and the mapping of a neutralizing monoclonal antibody

Although much is now known about the biological properties of the c-kit receptor and its ligand, stem cell factor (SCF), little is known of the structural basis for the binding and function of this hematopoietic cytokine. By analyzing the activities of chimeric interspecies and homologue muteins and epitope mapping of a monoclonal antibody (MoAb) to the human protein, we have found that three distinct regions of SCF are essential for full biological function. Homologue and interspecies swapping of polypeptide sequences between the amino terminus and G35, between L79 and N97, and between R121 and D128 reduced or eliminated the ability of the chimera to act in synergy with murine granulocyte-macrophage colony-stimulating factor (GM-CSF) to promote hematopoietic colony formation. Moreover, a nonconformation-dependent MoAb that neutralizes human, but not murine SCF, was found to bind to residues within the L79-N97 segment of the human homologue. As these three regions localize to the putative first, third, and fourth helices of the protein, findings remarkably similar to previous studies of cytokines as diverse as growth hormone, GM-CSF, and interleukin (IL)-4, our results suggest that cytokines of multiple classes share a common functional organization.

Linear filtering precedes nonlinear processing in early vision

BACKGROUND

Nonlinearities play a significant role in early visual processing. They are central to the perception of spatial contrast variations, multiplicative transparencies and texture boundaries. This article concerns the stage of processing at which nonlinearities first become significant.

RESULTS

Subjects were adapted to a high contrast sinusoidal grating followed by a brief presentation of a contrast modulated test (plaid) pattern. Thresholds for the detection of the contrast modulation (the beat) were measured. Results show that threshold elevation is greatest when the orientation and spatial frequency of the adapting grating are close to the principal Fourier frequency (the carrier) of the test pattern. Adaptation to sinewave-gratings near the frequency of the contrast modulation has relatively little effect. The data also show that the processing of contrast is frequency selective, with a peak tuning frequency near 0.4 cycles per degree.

CONCLUSIONS

The data are consistent with a model in which the contrast beats are processed in a frequency-specific manner, after an initial stage of frequency-specific and orientation-specific linear filtering.

SNAP-25 is differentially expressed by noradrenergic and adrenergic chromaffin cells

This study examines chromaffin cell expression of the synaptosomal-associated protein SNAP-25 in the adrenal medulla by immunoblotting, immunocytochemistry and PCR. Both mRNAs coding for the SNAP-25 isoforms a and b were detected and SNAP-25 was found to be present in all chromaffin cells in adult rat adrenal gland sections. It was essentially restricted to a zone close to the cytoplasmic face of the plasma membrane in the majority of cells, but located extensively throughout the cytoplasm in a chromaffin cell sub-population, identified by double immunofluorescence labelling to have a noradrenergic phenotype. This differential SNAP-25 expression may reflect different stages in the phenotypic development of the sympathoadrenal lineage and be related to an additional functional role in noradrenergic chromaffin cells not associated with secretion.

Xenogeneic expression of human stem cell factor in transgenic mice mimics codominant c-kit mutations

Mutations of c-kit, which encodes a transmembrane receptor tyrosine kinase, have been identified in mice by abnormal coat color, anemia, and germ cell defects. Mice heterozygous for mutations of c-kit have a white forehead blaze and a white ventral spot, leading these mutants to be termed dominant White spotting (W). We have previously demonstrated that the membrane-associated isoform of human stem cell factor (hSCF220, the ligand for c-kit) is inefficiently processed in murine stromal cell transfectants. Thus, in murine cell lines analyzed in vitro, hSCF220 transfectants present SCF as a membrane restricted protein in contrast to the murine SCF220 cDNA protein product, which is slowly cleaved and secreted. We show here that transgenic mice expressing the human SCF220 isoform in vivo display a phenotype indistinguishable from some alleles of W. Specifically, hSCF220-expressing transgenic mice display a prominent forehead blaze and a white ventral spot. Generations of doubly heterozygous animals that carry both a mutated c-kit allele and the hSCF220 transgene display a more severe coat color abnormality. This phenotype appears to be due to occupancy of murine c-kit by human SCF and diminished cell surface expression of endogenous murine SCF. Normal signaling events that lead to cell survival or proliferation appear to be disrupted in vivo in these transgenic mice.

Glucocorticoids and nerve growth factor differentially modulate cell adhesion molecule L1 expression in PC12 cells

The differential expression of the cell adhesion molecule L1 by chromaffin cells has recently been suggested to be responsible for the segregation of chromaffin cells into homotypic catecholaminergic groups in the adrenal gland. The present study was undertaken to test the hypothesis that glucocorticoids, which increase in the adrenal gland during development, could be responsible for the repression of L1 in adrenergic chromaffin cells. PC12 cells were used as the experimental model, and relative L1 protein and mRNA levels were examined after treating the cells with glucocorticoids or NGF. Analysis of western blots indicated that glucocorticoids decreased the L1 protein levels by one-half, whereas NGF increased L1 protein levels approximately 2.3-fold. In addition, the glucocorticoids inhibited both the NGF induction of the neurite outgrowth and the increase in L1 expression. Analysis of the mRNA levels by PCR and northern blots indicated that glucocorticoids reduced the L1 mRNA, whereas NGF increased the level of L1 mRNA. Maximal inhibition of L1 expression was observed at concentrations of 10(-7) M dexamethasone, and the decrease occurred during the second day of treatment. The effects of dibutyryl cyclic AMP and phorbol ester on the glucocorticoid and NGF regulation of L1 protein were also examined. This is the first report indicating that L1 expression can be down-regulated by glucocorticoids. The results support the hypothesis that during development the repression of L1 in adrenergic chromaffin cells may be, in part, linked to the increase in glucocorticoid levels in the adrenal gland.

Somatic c-KIT activating mutation in urticaria pigmentosa and aggressive mastocytosis: establishment of clonality in a human mast cell neoplasm

Mastocytosis is characterized by accumulations of mast cells in various organs (1). Most cases are indolent and confined to the skin, where discrete mast cell infiltrates are associated increased epidermal melanin, a clinical picture known as urticaria pigmentosa (UP). Other forms of mastocytosis combine UP with aggressive involvement of other organs or with haemotologic abnormalities (1-4). It is not known whether all forms of mastocytosis are true neoplasms or whether some might represent reactive hyperplasias (5-7). The c-KIT proto-oncogene encodes a type III receptor tyrosine kinase (KIT) that is critical to the development and survival of mast cells and melanocytes (8-11). The ligand for KIT (KL) can stimulate mast cell development, proliferation, and mediator release (9,12-17), as well as melanocyte proliferation and pigment production (18-20). To determine the role of c-KIT in the pathogenesis of mastocytosis, we examined tissue and cells isolated from a patient with UP and aggressive systemic mastocytosis with massive splenic involvement. We found a mutation that results in constitutive activation and expression of c-KIT in mast cells of both skin and spleen. This is the first in situ demonstration of an activation c-KIT mutation in neoplastic cells. It also demonstrates the clonal and neoplastic nature of this form of mastocytes.

Long term stimulation changes the vesicular monoamine transporter content of chromaffin granules

Bovine chromaffin cells cultured for 5 days in the presence of depolarizing concentrations of K+ ions show a decreased number of secretory (chromaffin) granules per cell. These cells were still capable of exocytosis. Their contents in catecholamine and chromogranin A, components of the granule matrix, and cytochrome b561, a major protein of the granule membrane, were decreased to 35, 30, and 50% of control cells, respectively. However, in the same cells, the number of [3H]dihydrotetrabenazine binding sites, a specific ligand of the vesicular monoamine transporter, was increased to 180% of controls. In situ uptake of noradrenaline in permeabilized cells indicated that [3H]dihydrotetrabenazine binding sites were associated with a functional vesicular monoamine transporter. When analyzed by isopycnic centrifugation, these sites cosedimented with catecholamine, chromogranin A, and cytochrome b561, in a peak with a density lighter than that from controls. The composition of this peak suggests that it contains incompletely matured secretory granules, with a 3-5-fold increase in the vesicular monoamine transporter content of this membrane. This increase might indicate that an adaptative process occurs which allows a faster filling of the granules in continuously secreting cells.

Expression of neural cell adhesion molecules, NCAMs, and their polysialylated forms, PSA-NCAMs, in the developing rat pituitary gland

Neural cell adhesion molecules (NCAMs) can undergo post-translational modifications, such as the addition of polysialic acid chains, thus generating PSA-NCAMs, which are expressed mainly during development. Since polysialylation considerably modifies NCAM adhesivity, expression of NCAMs and PSA-NCAMs has been investigated in the developing hypophysis by immunohistochemistry. At embryonic day 13 (E13), an antibody against NCAM outlined all cellular profiles in the entire Rathke's pouch; this labelling persisted until adulthood. NCAM expression increased in all lobes during development and concerned all pituitary cell types. In contrast, at E13, PSA-NCAMs were only detected in the neural lobe, solely constituted of pituicytes at this stage, and the tuberal lobe, the only lobe expressing hormonal mRNA at the same stage. PSA-NCAMs expression increased in the neural lobe at E17 with the arrival of the neurosecretory fibres and persisted into adulthood. In the anterior lobe, PSA-NCAMs appeared at E15 where their distribution was similar to that of the differentiating corticotrophic cells; at subsequent stages, their expression extended to the whole anterior lobe. Only two cell types, corticotrophic and somatotrophic cells, remained labelled in the adult gland. In the intermediate lobe, melanotrophic cells never expressed PSA-NCAMs but these were expressed on folliculo-stellate cells at birth, preceding the onset of innervation. These results suggest that NCAMs and PSA-NCAMs play a role in pituitary histogenesis, cell differentiation and neurointermediate lobe innervation.

Computational analysis of non-Fourier motion

Non-Fourier motion is now commonplace in research on visual motion perception, yet lacks a computational framework. This paper examines this issue based on the observation that many non-Fourier motion stimuli have a simple characterization in the frequency domain, in terms of oriented power distributions that lie along lines (or planes) that do not pass through the origin. This provides a unifying theoretical framework for a very diverse class of non-Fourier phenomena. It also allows us to examine some central issues concerning the computational nature of non-Fourier models, and naturally occurring sources of non-Fourier motion. For example, it is shown that the orientation of power in frequency domain corresponds to the velocity of a multiplicative envelope, and may arise as a restricted form of lighting effects, translucency or occlusion. We also show that both the location and orientation of spectral power may be extracted from the phase and amplitude output of band-pass filters, consonant with existing non-Fourier models.

Expression of GAP-43 (neuromodulin) during the development of the rat adrenal gland

The 'growth-associated protein', GAP-43 was originally considered to be a neuron-specific protein associated with plasticity. However, we have recently shown that GAP-43 is expressed by noradrenergic, but not by adrenergic chromaffin cells in the adult rat adrenal gland. In this study, we examine the expression of GAP-43 during embryonic and post-natal development of the adrenal gland using immunohistochemical techniques. In parallel, antibodies directed against two neuroendocrine markers, the catecholamine-synthesizing enzymes, tyrosine hydroxylase (TH) and phenylethanolamine N-methyltransferase (PNMT) were employed to permit identification of the developing chromaffin cell phenotypes. At embryonic day 15.5, GAP-43 was predominately localized in sympathoadrenergic precursor cells in the extra-adrenal blastema, and also in nerve fibers within the adrenal gland. At later embryonic stages, GAP-43 was expressed by nearly all intra-adrenal chromoblasts. Two subsets of chromoblasts can be distinguished even at early stages. A strong GAP-43-positive immunoreaction was observed in those chromoblasts organized in a few large compact clusters which weakly expressed TH and did not express PNMT. A generally weaker GAP-43 immunoreaction was observed in a second type of intra-adrenal chromoblasts which were organized in small isolated groups and characterized by a PNMT-positive, and strong TH-positive immunoreactivity. GAP-43 immunoreactivity was still associated with many PNMT-positive adrenergic chromoblasts at birth, but decreased to undetectable levels during the first post-natal week. By the second post-natal week, GAP-43 was restricted, as in the adult, to noradrenergic chromaffin cells which expressed TH, but not PNMT, in addition to nerve fibers and their associated glial cells in the gland. An immunoblot analysis confirmed a decrease in GAP-43 protein during the post-natal period. In agreement with these observations, a three-fold decrease in GAP-43 mRNA in the adrenal gland was measured between late embryogenesis and the second post-natal week. During development, the spatiotemporal expression of GAP-43 suggests a possible role in the migration and aggregation of chromaffin cell precursors into the medullary region of the adrenal gland.

Rhinocerebral mucormycosis diabetes mellitus and adrenogenital syndrome

A case of rhinocerebral mucormycosis in a diabetic is described. The case is unusual as the mucormycosis developed in the absence of ketoacidosis and because that patient had concomitant adrenogenital syndrome.