Molecular physiology of odor detection: current views

This review outlines current views of the principles and mechanisms underlying olfactory signaling, and presents some thoughts on open questions and future perspectives in this field. We briefly introduce the structure and function of the olfactory system and its sensory neurons, which respond to appropriate odorants with distinct patterns of electrical activity and contribute to the phenomenon of odor coding based on their characteristic receptor repertoire and their specific interconnections with target neurons in the brain. The molecular mechanisms mediating the process of chemo-electrical signal transduction in sensory cells and their functional implications are discussed. As a prerequisite for the high sensitivity and fast kinetics of the transduction process, we propose that the functional elements of the transduction cascades are spatially arranged in multimeric complexes, organized by scaffolding proteins, which anchor the signaling networks to the membrane of olfactory sensory cilia.

The neurofilament infrastructure of a developing presynaptic calyx

Calyx-type synapses appear to be specifically designed to support fast, reliable, high-frequency excitatory transmission. In the chick ciliary ganglion, calyx terminals from preganglionic neurons in the midbrain form early in development on ciliary neurons. We find that labeling the calyx membranes with a lipophilic dye delivered by diffusion down the preganglionic nerve reveals a large membrane structure engulfing the postsynaptic cell by the end of embryogenesis. In contrast, labeling the calyces with a water-soluble dye by diffusion through the preganglionic nerve suggests large discontinuities in the calyx. A similar pattern of discontinuities is seen when presynaptic neurofilaments are labeled with antibodies selective for highly phosphorylated neurofilaments. The neurofilament infrastructure of the calyx first appears as a single thick bundle, which subsequently bifurcates during development and eventually generates a fine meshwork of filaments subdivided by several large neurofilament bundles encircling the postsynaptic cell body. The large bundles probably produce protruding ridges in the otherwise thin calyx cup, accounting for the disparity in staining patterns observed with membrane and cytosolic dyes. The postsynaptic membrane also undergoes restructuring during development with the appearance of large folded mats of somatic spines heavily invested with nicotinic receptors. The large presynaptic neurofilament bundles do not overlap the postsynaptic receptor clusters but do codistribute with large tracks of presynaptic microtubules. The neurofilament bundles may act as girders to provide structural support while at the same time defining conduits for microtubule-dependent transport of materials and rapid propagation of electrical signals throughout the extended calyx.

Activity-dependent regulation of GABAA receptors

GABAA receptor heterogeneity is based on the combinatorial assembly of a large family of subunits into distinct receptor subtypes. A neuron-specific expression pattern of receptor subtypes has been demonstrated in adult rat brain, which can be reproduced in vitro in primary neuron cultures. This suggests that genetic programs established during ontogeny govern the expression of gamma-aminobutyric acid (GABAA) receptor subtypes. Activity-dependent mechanisms nevertheless modulate on a short-term basis the cell surface expression of GABAA receptors, as demonstrated in cultured hippocampal neurons upon blockade of synaptic transmission or application of brain-derived neurotrophic factor. Preliminary evidence points to changes in protein phosphorylation as a mechanism underlying short-term activity-dependent regulation of GABAA receptors. In vivo, chronic pharmacological modulation of neuronal activity during development, while having marked effects on the rate of cortical growth, failed to influence the expression of GABAA receptor subtypes, suggesting that additional factors are involved.

The effect of anti-diuretic hormone on the endolymphatic sac of the inner ear

The anti-diuretic hormone vasopressin (AVP) regulates water excretion from the kidney by increasing the water permeability of the collecting duct. AVP binds to V2-receptors and induces the translocation of aquaporin-2 water channels (AQP-2) into the apical plasma membrane of principal cells. By this mechanism AVP controls water reabsorption in the kidney. The effects of AVP on the endolymphatic sac (ES) of the inner ear, which is thought to mediate reabsorption of endolymph, were investigated. Both the V2-receptor and the AQP-2 water channel were found to be expressed in the ES epithelium. In the ES AVP binds to receptors most probably of the V2-subtype. Application of AVP to organotypically cultured ES inhibits membrane turnover in ribosomal-rich cells of the ES epithelia, which is thought to mediate translocation of AQP-2 into the surface membrane. This suggests that AVP has contrasting effects in the inner ear and kidney, which may be physiologically useful for maintaining endolymphatic pressure during severe hypovolemia. Animal experiments show that AVP causes endolymphatic hydrops after systemic application to guinea-pigs, which suggests a causal role for the increased AVP levels found in humans suffering from Ménière's disease.

GABAA-receptor subtypes in developing brain. Actors or spectators?

Distinct GABAA-receptor subtypes, differing in subunit composition, physiology, and pharmacology, are expressed in fetal, neonatal, and adult brain. Their developmental schedule, evidenced by the differential maturation of the GABAA-receptor subunits alpha 1, alpha 2, and alpha 5, is similar in rodents and primates, indicating that the regulation of receptor subtypes is conserved across species. "Adult" GABAA-receptors, characterized by the alpha 1-subunit immunoreactivity, are largely absent from fetal brain. They appear, however, before the onset of functional inhibitory connections, suggesting that GABAA-receptors may play an active role in the formation of GABAergic synapses. In neocortex, the maturation of GABAA-receptor subtypes is governed by an intrinsic program, leading to an area- and lamina-specific distribution as early as E20 in rats. In primary somatosensory and visual areas, this pattern is influenced postnatally by the ingrowing thalamocortical projection, a process that can be prevented experimentally by lesioning the thalamus at birth. Altogether, the expression of GABAA-receptor subtypes in developing brain reflects the changing functional needs of neurons during differentiation, the formation of inhibitory circuits, and the emergence of functionally distinct brain compartments.

Direct recording of nicotinic responses in presynaptic nerve terminals

Nicotinic acetylcholine receptors are widely expressed in the nervous system, but their functions remain poorly understood. One attractive hypothesis is that the receptors act presynaptically to modulate synaptic transmission. We provide a direct demonstration of presynaptic nicotinic receptors in situ by using whole-cell patch-clamp techniques to record currents in large presynaptic calyces that midbrain neurons form on ciliary neurons. Bath application of nicotine induced inward currents in the calyces capable of generating action potentials that overrode the limited space clamp achievable. The inward currents reversed near 0 mV and showed inward rectification common for neuronal nicotinic receptors. Tetrodotoxin (TTX) blocked the action potentials but not the inward currents. alpha-Bungarotoxin blocked both, consistent with the presynaptic receptors containing alpha7 subunits. Recording from the postsynaptic ciliary neurons during nicotine exposure revealed EPSCs that TTX blocked, presumably by blocking presynaptic action potentials. The postsynaptic cells also displayed bimodal inward currents caused by their own nicotinic receptors; the bimodal currents were not blocked by TTX but were blocked partially by alpha-bungarotoxin and completely by D-tubocurarine. Dye-filling with Lucifer yellow from the recording pipette confirmed the identity of patched structures and showed no dye transfer between calyx and ciliary neuron. When calyces or ciliary neurons were labeled en mass with neurobiotin and biocytin through nerve roots, dye transfer was rarely observed. Thus, electrical synapses were infrequent and unlikely to influence calyx responses. Immunochemical analysis of preganglionic nerve extracts identified receptors that bind alpha-bungarotoxin and contain alpha7 subunits. The results unambiguously document the existence of functional presynaptic nicotinic receptors.

Area-specific regulation of gamma-aminobutyric acid type A receptor subtypes by thalamic afferents in developing rat neocortex

Targeting and innervation of the cerebral cortex by thalamic afferents is a key event in the specification of cortical areas. The molecular targets of thalamic regulation, however, have remained elusive. We now demonstrate that thalamic afferents regulate the expression of gamma-aminobutyric acid type A (GABAA) receptors in developing rat neocortex, leading to the area-specific expression of receptor subtypes in the primary visual (V1) and somatosensory (S1) areas. Most strikingly, the alpha1- and alpha5-GABAA receptors exhibited a reciprocal expression pattern, which precisely reflected the distribution of thalamocortical afferents at postnatal day 7. Following unilateral lesions at the birth of the thalamic nuclei innervating V1 and S1 (lateral geniculate nucleus and ventrobasal complex, respectively), profound changes in subunit expression were detected 1 week later in the deprived cortical territories (layers III-IV of V1 and S1). The expression of the alpha1 subunit was strongly down-regulated in these layers to a level comparable to that in neighboring areas. Conversely, the alpha5 subunit was up-regulated and areal boundaries were no longer discernible in the lesioned hemisphere. Changes similar to the alpha5 subunit were also seen for the alpha2 and alpha3 subunits. These results indicate that the differential expression of GABAA receptor subtypes in developing neocortex is dependent on thalamic innervation, contributing to the emergence of functionally distinct areas.

Heterogeneity of GABAA-receptors: cell-specific expression, pharmacology, and regulation

Vigilance, anxiety, memory, epileptogenic activity and muscle tension can be regulated by a modulation of GABAA-receptor function. A multitude of different GABAA-receptors exist in the brain due to the combinational assembly of various subunits encoded by at least 15 genes. The clarification of the physiological and pharmacological significance of GABAA-receptor subtypes, in combination with their cellular localization, will make it possible to identify the neuronal circuits regulating the respective CNS states and to provide strategies for the development of subtype-specific drugs for selective therapies.

GABAA receptor alpha 1 subunit, an early marker for area specification in developing rat cerebral cortex

Changes in the expression of neurotransmitter receptors in developing cerebral cortex may be related to the functional maturation of distinct areas. In the present study, we have tested whether GABAA receptor expression in neonatal rats reflects the differentiation of cortical areas. Specifically, the alpha 1 subunit, one of the most prevalent GABAA receptor subunits in adult cerebral cortex, is up-regulated postnatally, suggesting a link with the establishment of inhibitory circuits. Using immunohistochemistry with a subunit-specific antiserum, we observed a striking area- and lamina-specific increase in staining for GABAA receptors containing the alpha 1 subunit (alpha 1-GABAA receptors), from low levels in neonates to an intense and uniform staining in adults. Already at birth, the alpha 1-subunit immunoreactivity selectively demarcated the boundaries of certain cortical areas. In particular, the primary somatosensory (S1) and visual (V1) areas were distinctly delineated with a band of alpha 1-subunit immunoreactivity located in the developing layers III and IV. The staining ended abruptly at the presumptive boundaries of S1 and V1, adjacent areas being unstained at this age. Around postnatal day 3, clusters of alpha 1-subunit positive cells were seen in layers III-IV of S1 and V1 extending their dendrites up to layer I, where they arborized profusely. In addition, the distribution of alpha 1-GABAA receptors in S1 revealed in detail the differentiation of the barrel field during early postnatal development. Although staining was observed in all areas by postnatal day 6, differences in the laminar distribution of alpha 1-GABAA receptors persisted for at least 1 more week. Our results provide evidence for the existence of area-specific boundaries in neocortex of newborn rats before layers III-IV are fully differentiated and innervated by cortical afferents. Furthermore, the area- and lamina-specific maturation of alpha 1-GABAA receptor staining demonstrates the value of this marker for investigating the cytoarchitectonic differentiation of cortical areas during development.

Switch in the expression of rat GABAA-receptor subtypes during postnatal development: an immunohistochemical study

The involvement of GABA in neuronal differentiation and maturation precedes its role as inhibitory neurotransmitter in the brain. It was therefore investigated whether GABAA receptors mediating the actions of GABA in neonatal and adult brain can be distinguished by their molecular structure and cellular location. Immunohistochemistry with subunit-specific antibodies was employed to analyze changes in the distribution of GABAA-receptor subunits during postnatal development. In particular, subunit association patterns, as evidenced by colocalization of subunits within individual neurons, were analyzed by confocal laser microscopy. The subunits analyzed include the alpha 1- and alpha 2-subunits, which are associated with pharmacologically distinct GABAA-receptor subtypes, and the beta 2,3-subunits, which are a major constituent of GABAA receptors in both immature and adult rat brain. Each of these subunits exhibited age-dependent changes in their distribution, indicative of a differential maturation process. The alpha1-subunit immunoreactivity (-IR) was low at birth, restricted to a few areas, and increased dramatically during the first postnatal weeks. By contrast, the alpha 2-subunit-IR displayed a widespread distribution throughout the brain at birth, and disappeared from numerous areas soon after the appearance of the alpha 1-subunit. Double-immunofluorescence staining demonstrated the coexistence of both subunits in many individual neurons during a short time window, indicating that receptors containing the alpha 1-subunit gradually replace receptors containing the alpha 2-subunit in these cells. Staining for the beta 2,3-subunits was prominent and ubiquitous at every developmental age, indicating that these subunits are present in both neonatal and adult GABAA receptors. Indeed, double-immunofluorescence staining revealed an extensive colocalization of the alpha 2- and beta 2,3-subunits in neurons from neonatal rats, whereas the beta 2,3-subunits were associated with the alpha 1-subunit at later stages. Thus, the onset of alpha 1-subunit staining in maturing brain is indicative for the expression of a new, prevalent receptor subtype, presumably involved in synaptic inhibition. These findings demonstrate a switch in the subunit composition of GABAA receptors during postnatal development, suggesting the existence of molecularly distinct immature and adult forms of GABAA receptors in rat CNS.