Types Of Afferents Research Articles

Expression and involvement of the Mas‐related gene receptor MrgD in intestinal inflammation in the mouse

Some members of the Mas‐related gene receptor (Mrg) family have been suggested to play a role in mediating IgE‐independent mast cell activation, as well as in neuroimmune communication. In a previous study, we observed an increased expression of some Mrgs, such as MrgD, in the murine ileum during intestinal inflammation. To further unravel the distribution and involvement of MrgD in intestinal inflammation, we compared the ileum of non‐inflamed and Schistosoma mansoni‐infected wild‐type and MrgD−/− mice. In the wild‐type mice, in the non‐inflamed ileum, immunohistochemistry revealed no MrgD immunoreactivity (IR), whereas in the inflamed ileum, MrgD IR was observed in 5% of the myenteric neurons. Neurochemical coding revealed that the MrgD‐expressing neurons were of the intrinsic primary afferent type. Moreover, MrgD IR was detected in mucosal mast cells (MMCs) in the inflamed ileum. In the MrgD−/− mice, no MrgD IR was detected, while an increased infiltration of MMCs was observed in the inflamed ileum. The expression of MrgD in sensory neurons and MMCs in the inflamed ileum of wild‐types, and the increased MMC infiltration observed after MrgD deletion, suggest that MrgD is involved in nociceptive and mast cell responses during intestinal schistosomiasis. Future work should aim at elucidating the mechanisms underlying MrgD‐mediated effects during intestinal inflammation. Supported by FWO grant G.0179.08

Characterisation of chemosensory trigeminal receptors in the rainbow trout,Oncorhynchus mykiss: responses to chemical irritants and carbon dioxide

Trigeminally innervated, mechanically sensitive chemoreceptors (M) were previously identified in rainbow trout, Oncorhynchus mykiss, but it is not known whether these receptors are responsive only to noxious, chemical irritants or have a general chemosensory function. This study aimed to characterise the stimulus-response properties of these receptors in comparison with polymodal nociceptors (P). Both P and M gave similar response profiles to acetic acid concentrations. The electrophysiological properties were similar between the two different afferent types. To determine whether the receptors have a nociceptive function, a range of chemical stimulants was applied to these receptors, including non-noxious stimuli such as ammonium chloride, bile, sodium bicarbonate and alarm pheromone, and potentially noxious chemical irritants such as acetic acid, carbon dioxide, low pH, citric acid, citric acid phosphate buffer and sodium chloride. Only irritant stimuli evoked a response, confirming their nociceptive function. All receptor afferents tested responded to carbon dioxide (CO(2)) in the form of mineral water or soda water. The majority responded to 1% acetic acid, 2% citric acid, citric acid phosphate buffer (pH 3) and 5.0 mol l(-1) NaCl. CO(2) receptors have been characterised in the orobranchial cavity and gill arches in fish; however, this is the first time that external CO(2) receptors have been identified on the head of a fish. Because the fish skin is in constant contact with the aqueous environment, contaminants with a low pH or hypercapnia may stimulate the nociceptive system in fish.

Encoding of communication signals by three types of electroreceptor afferents in Eigenmannia virescens

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Axonal protein synthesis: a potential target for pain relief?

Research on the role of axonal protein synthesis in the regulation of nociceptive mechanisms has grown significantly over the past four years. Recent advances include evidence that local translation of mRNA can occur in adult primary afferents under the control of the mammalian target of rapamycin (mTOR) and the extracellular signal-regulated kinase (ERK) signaling pathways. Studies investigating the effect of mTOR and ERK pathway inhibitors in a number of pain models suggest that these signaling pathways may act independently, depending on the type of sensory afferents studied. The evidence that nociception can be regulated at the level of mRNA translation in nociceptors has important implications for the understanding of the mechanisms of nociceptive plasticity and therefore for therapeutic interventions in chronic pain conditions.

A computational model for estimating recruitment of primary afferent fibers by intraneural stimulation in the dorsal root ganglia

Primary afferent microstimulation has been proposed as a method for activating cutaneous and muscle afferent fibers to restore tactile and proprioceptive feedback after limb loss or peripheral neuropathy. Large populations of primary afferent fibers can be accessed directly by implanting microelectrode arrays in the dorsal root ganglia (DRG), which provide a compact and stable target for stimulating a diverse group of sensory fibers. To gain insight into factors affecting the number and types of primary afferents activated, we developed a computational model that simulates the recruitment of fibers in the feline L7 DRG. The model comprises two parts. The first part is a single-fiber model used to describe the current–distance relation and was based on the McIntyre–Richardson–Grill model for excitability. The second part uses the results of the singe-fiber model and published data on fiber size distributions to predict the probability of recruiting a given number of fibers as a function of stimulus intensity. The range of intensities over which exactly one fiber was recruited was approximately 0.5–5 µA (0.1–1 nC per phase); the stimulus intensity at which the probability of recruiting exactly one fiber was maximized was 2.3 µA. However, at 2.3 µA, it was also possible to recruit up to three fibers, albeit with a lower probability. Stimulation amplitudes up to 6 µA were tested with the population model, which showed that as the amplitude increased, the number of fibers recruited increased exponentially. The distribution of threshold amplitudes predicted by the model was similar to that previously reported by in vivo experimentation. Finally, the model suggested that medium diameter fibers (7.3–11.5 µm) may be recruited with much greater probability than large diameter fibers (12.8–16 µm). This model may be used to efficiently test a range of stimulation parameters and nerve morphologies to complement results from electrophysiology experiments and to aid in the design of microelectrode arrays for neural interfaces.

TRPV1 and TRPA1 Function and Modulation Are Target Tissue Dependent

The nerve growth factor (NGF) and glial cell line-derived neurotrophic factor (GDNF) families of growth factors regulate the sensitivity of sensory neurons. The ion channels transient receptor potential vanilloid 1 (TRPV1) and transient receptor potential channel, subfamily A, member 1 (TRPA1), are necessary for development of inflammatory hypersensitivity and are functionally potentiated by growth factors. We have shown previously that inflamed skin exhibits rapid increases in artemin mRNA with slower, smaller increases in NGF mRNA. Here, using mice, we show that, in inflamed colon, mRNA for both growth factors increased with a pattern distinct from that seen in skin. Differences were also seen in the pattern of TRPV1 and TRPA1 mRNA expression in DRG innervating inflamed skin and colon. Growth factors potentiated capsaicin (a specific TRPV1 agonist) and mustard oil (a specific TRPA1 agonist) behavioral responses in vivo, raising the question as to how these growth factors affect individual afferents. Because individual tissues are innervated by afferents with unique properties, we investigated modulation of TRPV1 and TRPA1 in identified afferents projecting to muscle, skin, and colon. Muscle and colon afferents are twice as likely as skin afferents to express functional TRPV1 and TRPA1. TRPV1 and TRPA1 responses were potentiated by growth factors in all afferent types, but compared with skin afferents, muscle afferents were twice as likely to exhibit NGF-induced potentiation and one-half as likely to exhibit artemin-induced potentiation of TRPV1. Furthermore, skin afferents showed no GDNF-induced potentiation of TRPA1, but 43% of muscle and 38% of colon afferents exhibited GDNF-induced potentiation. These results show that interpretation of afferent homeostatic mechanisms must incorporate properties that are specific to the target tissue.

TRPA1 contributes to specific mechanically activated currents and sensory neuron mechanical hypersensitivity

The mechanosensory role of TRPA1 and its contribution to mechanical hypersensitivity in sensory neurons remains enigmatic. We elucidated this role by recording mechanically activated currents in conjunction with TRPA1 over- and under-expression and selective pharmacology. First, we established that TRPA1 transcript, protein and functional expression are more abundant in smaller-diameter neurons than larger-diameter neurons, allowing comparison of two different neuronal populations. Utilising whole cell patch clamping, we applied calibrated displacements to neurites of dorsal root ganglion (DRG) neurons in short-term culture and recorded mechanically activated currents termed intermediately (IAMCs), rapidly (RAMCs) or slowly adapting (SAMCs). Trpa1 deletion (–/–) significantly reduced maximum IAMC amplitude by 43% in small-diameter neurons compared with wild-type (+/+) neurons. All other mechanically activated currents in small- and large-diameter Trpa1−/− neurons were unaltered. Seventy-three per cent of Trpa1+/+ small-diameter neurons responding to the TRPA1 agonist allyl-isothiocyanate (AITC) displayed IAMCs to neurite displacement, which were significantly enhanced after AITC addition. The TRPA1 antagonist HC-030031 significantly decreased Trpa1+/+ IAMC amplitudes, but only in AITC responsive neurons. Using a transfection system we also showed TRPA1 over-expression in Trpa1+/+ small-diameter neurons increases IAMC amplitude, an effect reversed by HC-030031. Furthermore, TRPA1 introduction into Trpa1−/− small-diameter neurons restored IAMC amplitudes to Trpa1+/+ levels, which was subsequently reversed by HC-030031. In summary our data demonstrate TRPA1 makes a contribution to normal mechanosensation in a specific subset of DRG neurons. Furthermore, they also provide new evidence illustrating mechanisms by which sensitisation or over-expression of TRPA1 enhances nociceptor mechanosensitivity. Overall, these findings suggest TRPA1 has the capacity to tune neuronal mechanosensitivity depending on its degree of activation or expression.

Molecular Microdomains in a Sensory Terminal, the Vestibular Calyx Ending

Many primary vestibular afferents form large cup-shaped postsynaptic terminals (calyces) that envelope the basolateral surfaces of type I hair cells. The calyceal terminals both respond to glutamate released from ribbon synapses in the type I cells and initiate spikes that propagate to the afferent's central terminals in the brainstem. The combination of synaptic and spike initiation functions in these unique sensory endings distinguishes them from the axonal nodes of central neurons and peripheral nerves, such as the sciatic nerve, which have provided most of our information about nodal specializations. We show that rat vestibular calyces express an unusual mix of voltage-gated Na and K channels and scaffolding, cell adhesion, and extracellular matrix proteins, which may hold the ion channels in place. Protein expression patterns form several microdomains within the calyx membrane: a synaptic domain facing the hair cell, the heminode abutting the first myelinated internode, and one or two intermediate domains. Differences in the expression and localization of proteins between afferent types and zones may contribute to known variations in afferent physiology.

Modulation of synaptic transmission from primary afferents to spinal substantia gelatinosa neurons by group III mGluRs in GAD65-EGFP transgenic mice

Group III metabotropic glutamate receptors (mGluRs) are involved in nociceptive transmission in the spinal cord. However, the cellular mechanism underlying the modulation of synaptic transmission from nociceptive primary afferents to dorsal horn neurons by group III mGluRs has yet to be explored. In this study, we used transgenic mice expressing enhanced green fluorescent protein (EGFP) under the control of the glutamate decarboxylase (GAD) 65 promoter to identify specific subpopulations of GABAergic inhibitory interneurons. By GABA immunolabeling, we confirmed the majority of GAD65-EGFP-expressing neurons were GABAergic. Because GAD65-EGFP-expressing neurons have not been examined in detail before, we first investigated the physiological properties of GAD65-EGFP- and non-EGFP-expressing neurons in substantia gelatinosa (SG) of the spinal dorsal horn. Membrane properties, such as the resting membrane potential, membrane capacitance, action potential threshold, and action potential height, differed significantly between these two groups of neurons. Most EGFP-expressing neurons displayed a tonic firing pattern (73% of recorded neurons) and received monosynaptic Aδ and/or C primary afferent inputs (85% of recorded neurons). In contrast, we observed a delayed firing pattern in 53% of non-EGFP-expressing neurons. After identifying the physiological properties of EGFP-expressing neurons, we tested the effects of group III mGluRs on synaptic transmission pharmacologically. A group III mGluR agonist, L-AP4, attenuated Aδ fiber-evoked synaptic transmission but did not affect C fiber-evoked synaptic transmission to EGFP-expressing neurons. Similar primary afferent-specific inhibition by L-AP4 was also observed in non-EGFP-expressing neurons. Moreover, Aδ fiber-evoked synaptic transmission was suppressed by a selective mGluR7 agonist, AMN082. These results suggest that modulation of the synaptic transmission from primary afferents to SG neurons by group III mGluR agonist is specific to the type of nociceptive primary afferents but not to the type of target neurons.

Distinct target cell-dependent forms of short-term plasticity of the central visceral afferent synapses of the rat

BackgroundThe visceral afferents from various cervico-abdominal sensory receptors project to the dorsal vagal complex (DVC), which is composed of the nucleus of the solitary tract (NTS), the area postrema and the dorsal motor nucleus of the vagus nerve (DMX), via the vagus and glossopharyngeal nerves and then the solitary tract (TS) in the brainstem. While the excitatory transmission at the TS-NTS synapses shows strong frequency-dependent suppression in response to repeated stimulation of the afferents, the frequency dependence and short-term plasticity at the TS-DMX synapses, which also transmit monosynaptic information from the visceral afferents to the DVC neurons, remain largely unknown.ResultsRecording of the EPSCs activated by paired or repeated TS stimulation in the brainstem slices of rats revealed that, unlike NTS neurons whose paired-pulse ratio (PPR) is consistently below 0.6, the distribution of the PPR of DMX neurons shows bimodal peaks that are composed of type I (PPR, 0.6-1.5; 53% of 120 neurons recorded) and type II (PPR, < 0.6; 47%) neurons. Some of the type I DMX neurons showed paired-pulse potentiation. The distinction of these two types depended on the presynaptic release probability and the projection target of the postsynaptic cells; the distinction was not dependent on the location or soma size of the cell, intensity or site of the stimulation, the latency, standard deviation of latency or the quantal size. Repeated stimulation at 20 Hz resulted in gradual and potent decreases in EPSC amplitude in the NTS and type II DMX neurons, whereas type I DMX neurons displayed only slight decreases, which indicates that the DMX neurons of this type could be continuously activated by repeated firing of primary afferent fibers at a high (~10 Hz) frequency.ConclusionsThese two general types of short-term plasticity might contribute to the differential activation of distinct vago-vagal reflex circuits, depending on the firing frequency and type of visceral afferents.

Biphasic and bilateral changes in striatal VGLUT1 and 2 protein expression in hemi-Parkinson rats

Parkinson's disease is characterized by disturbed glutamatergic neurotransmission in the striatum. Important mediators of extracellular glutamate levels are the vesicular glutamate transporters VGLUT1 and VGLUT2 in respectively corticostriatal and thalamostriatal afferents, next to the high-affinity Na +/K +-dependent glutamate transporters and the cystine/glutamate antiporter. In the present study, we compared bilateral striatal VGLUT1 and VGLUT2 protein expression as well as VGLUT1 and VGLUT2 transcript levels in the neocortex and parafascicular nucleus of hemi-Parkinson rats at different time intervals post unilateral 6-OHDA injection into the medial forebrain bundle versus controls. Three weeks post-injection we detected increased striatal VGLUT1 expression together with decreased VGLUT2 expression. On the other hand, after twelve weeks, the expression of VGLUT1 was decreased in hemi-Parkinson rats whereas the striatal expression of VGLUT2 was comparable to control rats. No effect could be seen on VGLUT transcript levels in the respective projection areas at any time. In conclusion, we observed a biphasic and bilateral change in the protein expression levels of both VGLUTs in the striatum of hemi-Parkinson rats indicative for a different and time-dependent change in glutamatergic neurotransmission from the two types of striatal afferents.

The Regularity of Sustained Firing Reveals Two Populations of Slowly Adapting Touch Receptors in Mouse Hairy Skin

Touch is initiated by diverse somatosensory afferents that innervate the skin. The ability to manipulate and classify receptor subtypes is prerequisite for elucidating sensory mechanisms. Merkel cell-neurite complexes, which distinguish shapes and textures, are experimentally tractable mammalian touch receptors that mediate slowly adapting type I (SAI) responses. The assessment of SAI function in mutant mice has been hindered because previous studies did not distinguish SAI responses from slowly adapting type II (SAII) responses, which are thought to arise from different end organs, such as Ruffini endings. Thus we sought methods to discriminate these afferent types. We developed an epidermis-up ex vivo skin-nerve chamber to record action potentials from afferents while imaging Merkel cells in intact receptive fields. Using model-based cluster analysis, we found that two types of slowly adapting receptors were readily distinguished based on the regularity of touch-evoked firing patterns. We identified these clusters as SAI (coefficient of variation = 0.78 +/- 0.09) and SAII responses (0.21 +/- 0.09). The identity of SAI afferents was confirmed by recording from transgenic mice with green fluorescent protein-expressing Merkel cells. SAI receptive fields always contained fluorescent Merkel cells (n = 10), whereas SAII receptive fields lacked these cells (n = 5). Consistent with reports from other vertebrates, mouse SAI and SAII responses arise from afferents exhibiting similar conduction velocities, receptive field sizes, mechanical thresholds, and firing rates. These results demonstrate that mice, like other vertebrates, have two classes of slowly adapting light-touch receptors, identify a simple method to distinguish these populations, and extend the utility of skin-nerve recordings for genetic dissection of touch receptor mechanisms.

Encoding of tangential torque in responses of tactile afferent fibres innervating the fingerpad of the monkey

Torsional loads are ubiquitous during everyday dextrous manipulations. We examined how information about torque is provided to the sensorimotor control system by populations of tactile afferents. Torsional loads of different magnitudes were applied in clockwise and anticlockwise directions to a standard central site on the fingertip. Three different background levels of contact (grip) force were used. The median nerve was exposed in anaesthetized monkeys and single unit responses recorded from 66 slowly adapting type-I (SA-I) and 31 fast adapting type-I (FA-I) afferents innervating the distal segments of the fingertips. Most afferents were excited by torque but some were suppressed. Responses of the majority of both afferent types were scaled by torque magnitude applied in one or other direction, with the majority of FA-I afferent responses and about half of SA-I afferent responses scaled in both directions. Torque direction affected responses in both afferent types, but more so for the SA-I afferents. Latencies of the first spike in FA-I afferent responses depended on the parameters of the torque. We used a Parzen window classifier to assess the capacity of the SA-I and FA-I afferent populations to discriminate, concurrently and in real-time, the three stimulus parameters, namely background normal force, torque magnitude and direction. Despite the potentially confounding interactions between stimulus parameters, both the SA-I and the FA-I populations could extract torque magnitude accurately. The FA-I afferents signalled torque magnitude earlier than did the SA-I afferents, but torque direction was extracted more rapidly and more accurately by the SA-I afferent population.

Cutaneous Afferents From the Monkeys Fingers: Responses to Tangential and Normal Forces

Control of tangential force plays a key role in everyday manipulations. In anesthetized monkeys, forces tangential to the skin were applied at a range of magnitudes comparable to those used in routine manipulations and in eight different directions. The paradigm used enabled separation of responses to tangential force from responses to the background normal force. For slowly adapting type I (SAI) afferents, tangential force responses ranged from excitatory through no response to suppression, with both a static and dynamic component. For fast adapting type I (FAI) afferents, responses were dynamic and excitatory only. Responses of both afferent types were scaled by tangential force magnitude, elucidating the neural basis for previous human psychophysical scaling data. Most afferents were direction selective with a range of preferred directions and a range in sharpness of tuning. Both the preferred direction and the degree of tuning were independent of the background normal force. Preferred directions were distributed uniformly over 360 degrees for SAI afferents, but for FAI afferents they were biased toward the proximo-ulnar direction. Afferents from all over the glabrous skin of the distal segment of the finger responded; there was no evident relationship between the position of an afferent's receptive field on the finger and its preferred direction or its degree of tuning. Nor were preferred directions biased either toward or away from the receptive field center. In response to the relatively large normal forces, some afferents saturated and others did not, regardless of the positions of their receptive fields. Total afferent response matched human psychophysical scaling functions for normal force.

Conveying tactile feedback in sensorized hand neuroprostheses using a biofidelic model of mechanotransduction.

One approach to conveying tactile feedback from sensorized neural prostheses is to characterize the neural signals that would normally be produced in an intact limb and reproduce them through electrical stimulation of the residual peripheral nerves. Toward this end, we have developed a model that accurately replicates the neural activity evoked by any dynamic stimulus in the three types of mechanoreceptive afferents that innervate the glabrous skin of the hand. The model takes as input the position of the stimulus as a function of time, along with its first (velocity), second (acceleration), and third (jerk) derivatives. This input is filtered and passed through an integrate-and-fire mechanism to generate a train of spikes as output. The major conclusion of this study is that the timing of individual spikes evoked in mechanoreceptive fibers innervating the hand can be accurately predicted by this model. We discuss how this model can be integrated in a sensorized prosthesis and show that the activity in a population of simulated afferents conveys information about the location, timing, and magnitude of contact between the hand and an object.

Sensing the fullness of the bladder

Mechanosensory transduction participates in vital physiological functions such as control of blood pressure, food intake and micturition. Within the urinary tract, electrical impulses in bladder afferent fibres encode the fullness (volume and/or pressure) of the bladder; the information is conveyed via the pelvic and hypogastric nerves to the central neuronal circuits which in turn generate efferent nerve activity to drive coordinated activity of detrusor contraction and urethral sphincter relaxation that initiate evacuation (de Groat, 2006). Extensive efforts have been devoted in recent years to investigate the mechanisms that control bladder afferent activity in normal and in pathological conditions. Despite of the various progresses reported in the literature, the fundamental question of how mechanical force is transduced into afferent discharges remains largely unresolved. It has long been hypothesized that mechanosensory transduction relies on mechanically gated ion channels expressed on afferent terminals. Studies in C. elegans and Drosophila have identified three classes of putative mechanosensory transduction molecules: the degenerin/ENaC/ASIC channels, the transient receptor potential (TRP) cation channels and the two-pore-domain K+ channels (Chalfie, 2009). However, little information is currently available as to whether these channels, except for TRPV1 (Birder et al. 2002; Daly et al. 2007), participate in mechanosensory transduction in the urinary bladder. On the other hand, there has also been increasing interest in the putative sensory role of the urothelial (and other non-neuronal) cells, which have been shown to express a range of putative ‘sensory molecules’ and to release chemical mediators such as ATP, NO and prostanoids in response to mechanical and chemical stimulations (Birder, 2005). These mediators may in turn interact with receptors on afferent terminals to activate afferents or to modulate afferent excitability. In an article in this issue of The Journal of Physiology, Zagorodnyuk et al. (2009) employed a flat-sheet guinea pig bladder preparation to study the mechanosensory responses of bladder afferents by ‘close-to-target’ extracellular recordings. They had previously identified five major functional types of bladder afferents in this species (Zagorodnyuk et al. 2006, 2007) and here they focused on two types of bladder afferents with receptive fields in the vicinity of the urothelium. They examined the effects of degenerin/ENaC/ASIC channel blockers on the responses of muscular-mucosal and mucosal high-responding afferents to muscle stretch and/or mucosal stroking. Amiloride (100 μm) was ineffective, whilst remarkably, benzamil attenuated stretch- and/or stroking-induced afferent discharges in a concentration-dependent manner with 300 μm benzamil virtually abolishing stretch-induced responses. Stretch-activated channel blockers (gadolinium and SKF96365), on the other hand, were without effect on the mechanosensory responses. Furthermore, they showed that mechanosensory responses in these fibres were unaltered in the presence of a purinergic antagonist pyridoxal phosphate 6-azophenyl-2′,4′-disulfonic acid (PPADS) or when calcium-dependent vesicle release of chemical mediators was blocked. The authors concluded that mechanosensory transduction in muscle-mucosal and mucosal high-responding fibres does not rely on Ca2+-dependent vesicle release of chemical mediators such as ATP. Instead, benzamil-sensitive stretch-activated ion channels are likely to mediate mechanosensory transduction by receptive terminals. If they are right, these findings may represent an important step towards eventually delineating the molecular mechanisms of mechanosensory transduction in the urinary bladder. Conceivably, the search for mechanosensory transduction molecules can be narrowed down to the benzamil-sensitive degenerin/ENaC/ASIC channel family, some of which are known to be expressed in the urothelium, the detrusor muscle and the afferent terminals. Nevertheless, considering that relatively high concentrations of benzamil were needed to block the mechanosensory activity in the guinea pig bladder, further studies using more potent and selective pharmacological tools, with other species as well as transgenic animals, should be warranted. It may be worth pointing out that the finding that Ca2+ free perfusion did not affect mechanosensory activity in the guinea pig bladder does not necessarily preclude a sensory role of non-neuronal cells in other conditions. Rather, the data at best imply that non-neuronal release of mediators may not be sufficient to exert significant effects on afferent terminals in such experimental condition. Indeed, there has been plenty of experimental data indicating that the urothelial contribution to mechanosensory activity may be up-regulated in pathological conditions. Moreover, the use of Ca2+ free perfusion may not be sufficient to block potential intercellular communication between primary afferents and non-neuronal cells via exchange of second messenger molecules through gap junctions, as has been demonstrated by Ennes et al. (1999) for DRG and colonic myocytes co-cultured in vitro. An exciting new development in the field of mechanotransduction in vascular smooth muscles has been the findings that several Gq-coupled GPCRs can be activated by membrane stretch, leading to the activation of certain TRP channels via the phospholipase C (PLC) pathway (Voets & Nilius, 2009). It will be interesting to investigate whether a similar GPCR–TRP channel interaction mediates mechanosensory transduction in the urinary bladder.

Mechanotransduction and chemosensitivity of two major classes of bladder afferents with endings in the vicinity to the urothelium

The guinea pig bladder is innervated by at least five distinct major classes of extrinsic sensory neurons. In this study, we have examined the mechanisms of mechanotransduction and chemosensitivity of two classes of bladder afferents that have their endings in the vicinity of the urothelium: stretch-sensitive muscle-mucosal mechanoreceptors and stretch-insensitive, mucosal high-responding afferents. The non-selective P2 purinoreceptor antagonist pyridoxal phosphate-6-azophenyl-2',4'-disulphonic acid did not affect stretch- or stroking-induced firing of these afferents but significantly reduced the excitatory action of alpha,beta-methylene ATP. Blocking synaptic transmission in Ca(2+)-free solution did not affect stretch-evoked firing but slightly reduced stretch-induced tension responses. Stroking-induced firing of both classes of afferents was also not affected in Ca(2+)-free solution. Of blockers of mechano-gated channels, benzamil (100 microM), but not amiloride (100 microM), Gd(3+) (100 microM) or SKF 96365 (50 microM), inhibited stretch- and stroking-induced firing. Serotonin (100 microM) applied directly onto receptive fields predominantly activated muscle-mucosal afferents. Muscarine (100 microM) and substance P (100 microM) in 24% and 36% cases activated only mucosal high-responding units. Bradykinin (10 microM), but not prostaglandin E2 (10 microM), excites predominantly mucosal units. High (80 mM) K(+) solution activated both afferent classes, but responses of mucosal units were 4 times greater. In contrast to muscle-mucosal units, most mucosal high-responding units were activated by hot Krebs solution (45-46 degrees C), low pH (pH 4) and capsaicin (3 microm). TRPV1 antagonist, capsazepine (10 microM) was without effect on mechanotransduction by mucosal high-responding afferents. The results show that mechanotransduction of these two types of afferents are not dependant upon Ca(2+)-dependent exocytotic release of mediators, or ATP, and it is likely that benzamil-sensitive stretch-activated ion channels on their endings are involved in direct mechanotransduction. The chemosensitivity to agonists and noxious stimuli differs significantly between these two major classes of bladder afferents that reflects their different physiological and pathophysiological roles in the bladder.

Labeling of inner ear afferents in the transgenic thy1‐YFP‐H mouse

We wished to assess the level of inner ear endorgan labeling in a transgenic mouse expressing yellow fluorescent protein (YFP) driven by the thy1 promoter and to examine the possibility of using this thy1‐YFP‐H mouse as a model for studying inner ear afferents. End‐organ YFP fluorescence in a postnatal day 8 (P8) thy1‐YFP‐H mouse was observed using confocal microscopy after anesthetizing the animal, then transcardially perfusing it with PBS and 4% paraformaldehyde. Images from utricular and cochlear whole mounts and crista sections suggest that in the thy1‐YFP‐H P8 mouse, vestibular afferents, including both calyces and boutons and type I and II spiral ganglion afferents are labeled. Afferents in the striolar region were more intensely labeled than extrastriolar afferents, and no supporting cell labeling was observed. Cochlear afferents, including those innervating both inner and outer hair cells, were also labeled. In conclusion, the thy1‐YFP‐H mouse could be a useful model in which to study inner ear endorgan structure and function as it lends itself to in‐vivo imaging and enables easy identification and distinction of afferent types and regions.Supported by NIH DC‐02521.Grant Funding SourceNIH DC‐02521

Vibration-processing interneurons in the honeybee brain

The afferents of the Johnston's organ (JO) in the honeybee brain send their axons to three distinct areas, the dorsal lobe, the dorsal subesophageal ganglion (DL-dSEG), and the posterior protocerebral lobe (PPL), suggesting that vibratory signals detected by the JO are processed differentially in these primary sensory centers. The morphological and physiological characteristics of interneurons arborizing in these areas were studied by intracellular recording and staining. DL-Int-1 and DL-Int-2 have dense arborizations in the DL-dSEG and respond to vibratory stimulation applied to the JO in either tonic excitatory, on-off-phasic excitatory, or tonic inhibitory patterns. PPL-D-1 has dense arborizations in the PPL, sends axons into the ventral nerve cord (VNC), and responds to vibratory stimulation and olfactory stimulation simultaneously applied to the antennae in long-lasting excitatory pattern. These results show that there are at least two parallel pathways for vibration processing through the DL-dSEG and the PPL. In this study, Honeybee Standard Brain was used as the common reference, and the morphology of two types of interneurons (DL-Int-1 and DL-Int-2) and JO afferents was merged into the standard brain based on the boundary of several neuropiles, greatly supporting the understanding of the spatial relationship between these identified neurons and JO afferents. The visualization of the region where the JO afferents are closely appositioned to these DL interneurons demonstrated the difference in putative synaptic regions between the JO afferents and these DL interneurons (DL-Int-1 and DL-Int-2) in the DL. The neural circuits related to the vibration-processing interneurons are discussed.

Discharges in human muscle spindle afferents during a key‐pressing task

Most manual tasks demand a delicate control of the wrist. Sensory information for this control, e.g. about the position and movement velocity of the hand, is assumed to be primarily provided by muscle spindle afferents. It is known that human muscle spindles in relaxed muscles behave as stretch receptors but it is unclear how they discharge during 'natural' hand movements, since their discharges can also be affected by extrafusal contractions and fusimotor activity. We therefore let subjects perform a centre-out-centre key-pressing task on buttons laid out in a 3 x 3 pattern, a task that allowed unconstrained hand and finger movements and required precise control of the wrist. Microneurography recordings from muscle spindle afferents of the wrist extensor muscles were obtained along with wrist kinematics and electromyographic signals. The discharge rates of afferents were more phase advanced than expected on the length of the radial wrist extensor, which acted as an anti-gravity muscle in the key-pressing task. As such, both acceleration and velocity had significant impacts on the discharge rate of primary afferents, velocity on that of secondary afferents, and length had no impact on either afferent type. The response patterns were different for the two types of muscle spindle afferents from the predominantly eccentrically contracting ulnar wrist extensor: muscle length and velocity had significant impacts on the ensemble response of secondary afferents whereas the primary afferents showed highly variable responses. Accordingly, good predictions of the radial ulnar angular velocity were possible from spindle ensemble responses (R(2) = 0.85) whereas length could be predicted only for phases with lengthening of the ulnar wrist extensor. There are several possible explanations for the unexpectedly large phase advance of spindle afferents in the radial wrist extensor. Given the compliance of tendons, for instance, the phase relationship between the muscle fascicle length and the whole muscle length is conjectured to depend on the load. While additional phase advances are advantageous in motor control, it is concluded that if the central nervous system estimates length or velocity of a muscle from its muscle spindle discharges, this would require additional information about not only the concomitant extrafusal and fusimotor drive but also about the mechanical properties of the load on which the muscle acts.