Mechanisms of mechanotransduction by specialized low-threshold mechanoreceptors in the guinea pig rectum

Vladimir P. Zagorodnyuk, Penny Lynn, Marcello Costa, and Simon J. H. Brookes

Department of Human Physiology and Centre for Neuroscience, Flinders University of South Australia, Adelaide, South Australia

Submitted 17 December 2004 ; accepted in final form 14 May 2005


    ABSTRACT
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 ABSTRACT
 MATERIALS AND METHODS
 RESULTS
 DISCUSSION
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 REFERENCES
 
The guinea pig rectum, but not the colon, is innervated by a specialized class of distension-sensitive mechanoreceptors that have transduction sites corresponding to rectal intraganglionic laminar endings (rIGLEs). Rectal mechanoreceptors recorded in vitro had low threshold to circumferential stretch, adapted slowly, and could respond within 2 ms to mechanical stimulation by a piezo-electric probe. Antagonists to ionotropic N-methyl-D-aspartate (NMDA; CGS 19755, memantine) and non-NMDA (6,7-dinitroquinoxaline-2,3-dione) glutamate receptors did not affect mechanotransduction. In normal Krebs solution, the P2X purinoreceptor agonist {alpha},{beta}-methylene ATP reduced mechanoreceptor firing evoked by distension but simultaneously relaxed circular smooth muscle and inhibited stretch-induced contractions. Neither ATP nor {alpha},{beta}-methylene ATP affected mechanotransduction when transduction sites were directly compressed with von Frey hairs. The P2 purinoreceptor antagonist pyridoxal phosphate-6-azophenyl-2',4'-disulfonic acid did not affect stretch-induced firing but reduced the inhibitory effect of {alpha},{beta}-methylene ATP on stretch-induced firing. Under isometric conditions, blocking synaptic transmission in Ca2+-free solution reduced stretch-evoked firing but not when basal tension was restored to control levels. Under isotonic condition, Ca2+-free solution did not significantly affect load-evoked firing. The blockers of mechanogated and/or transient receptor potential channels, benzamil, Gd3+, SKF 96365, and ruthenium red inhibited stretch-induced firing but, in parallel, significantly reduced stretch-induced contractions. Benzamil and SKF 96365 were able to inhibit mechanotransduction when transduction sites were compressed with von Frey hairs. The results show that mechanotransduction is rapid but does not depend on fast exocytotic release of mediators. It is likely that stretch-activated ion channels on rIGLEs are involved in direct, physical mechanotransduction by rectal low-threshold mechanoreceptors.

afferents; mechanosensory transduction


DISTENSION OF THE GUT WALL activates both intrinsic and extrinsic neuronal reflex pathways and may cause conscious sensation. The mechanisms underlying activation of mechanosensitive extrinsic afferent neurons are not well understood. Two types of mechanisms, chemical and physical, have been proposed for mechanotransduction by afferent neurons in different systems. Chemical transduction relies on mediators being released from nonneuronal cells by mechanical stimulation, which then activate afferent endings via corresponding receptors. Direct mechanotransduction is characterized by having all molecular elements (mechanogated ion channels and associated proteins) located in the afferent endings, without extracellular mediators being essential (6, 17, 23). Several recent reports have provided evidence for a role for chemical transduction in primary afferent neurons in several systems. Cutaneous slowly adapting mechanoreceptor corpuscles, Merkel cells, release glutamate in response to mechanical stimuli to activate afferent nerve fibers (18). Likewise, in the cochlea, glutamate probably mediates transmission between mechanosensitive inner hair cells and spiral ganglion neurons (40). In visceral primary afferents neurons, ionotropic glutamate receptor antagonists attenuate distension-evoked firing of spinal and vagal afferents innervating the gastrointestinal tract (30, 44). ATP has been postulated to be a key signaling molecule mediating mechanosensitivity in several regions (6), and mechanosensitive release of ATP may be a ubiquitous mechanism in eukaryotic cells (3, 24, 32). Both ionotropic P2X and metabotropic P2Y purinoreceptors are expressed on sensory neurons and their endings (9, 19, 46, 57) and purinoreceptor antagonists, such as suramin, pyridoxal phosphate-6-azophenyl-2',4'-disulfonic acid (PPADS), and 2',3'-O-trinitrophenyl-ATP (TNP-ATP), reduce mechanosensitivity of spinal afferents innervating the lower gut and urinary bladder (39, 52).

On the other hand, mechanogated channels also appear to be ubiquitous among eukaryiotic cells and are the prime candidates for transduction of mechanical stimuli into cellular electrochemical signals in some primary afferent neurons (23, 24). The most likely mechanosensitive ion channels belonging to TRP and/or ENaC/ASIC/degenerin of cationic and sodium ion channel families are involved in mechanotransduction in ciliated and nonciliated mechanoreceptors including mammalian extrinsic primary afferent neurons (21–23). A recent study has identified a role for a TRP channel family member (TRPA1) as the mechanotransducing channel in vertebrate hair cells (13).

In the gastrointestinal tract, both low- and high-threshold spinal mechanoreceptors have been documented (43); five main types of mechanoreceptors were identified in splanchnic and pelvic mechanosensory pathways to the mouse colon including two stretch-sensitive types of mechanoreceptor (4). Previously, we have identified rectal intraganglionic laminar endings (rIGLEs) as the mechanotransduction sites of low-threshold rectal mechanoreceptors (28). These endings are largely restricted to the rectum, being present in only small numbers in the distal colon, indicating that they comprise a specialized class of rectal mechanoreceptors (33). It has been suggested that they behave grossly as tension receptors (28) and may correspond to the muscular mechanoreceptors classified in the mouse colorectum (4). In the esophagus and stomach, morphologically similar endings, called intraganglionic laminar endings (IGLEs), are the transduction sites of vagal mechanoreceptors (54, 55). We have recently provided evidence indicating that IGLEs use direct, physical mechanisms of mechanotransduction via stretch-activated ion channels (57). The aim of this study was to investigate whether rectal mechanoreceptors in the guinea pig rectum transduce mechanical stimuli physically (via mechanosensitive ion channels) or indirectly (via release of chemicals from other cells).


    MATERIALS AND METHODS
 TOP
 ABSTRACT
 MATERIALS AND METHODS
 RESULTS
 DISCUSSION
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 REFERENCES
 
Extracellular recording. Adult guinea pigs [total no. of animals (N) = 66], weighing between 180 and 250 g, were killed by a blow to the occipital region and exsanguination, in a manner approved by the Animal Welfare Committee of Flinders University in accordance with the Australian Code of Practice for the Care and Use of Animals for Scientific Purposes (National Health and Medical Research Council of Australia, 7th ed., 2004). The method of extracellular recordings from rectal mechanoreceptor afferents in guinea pig has been described previously (28). Briefly, the distal rectum was opened up into a flat sheet, and the mucosa was removed from a 10-mm-long preparation and washed with Krebs solution (in mM: 118 NaCl, 4.75 KCl, 1.0 NaH2PO4, 25 NaHCO3, 1.2 MgSO4, 2.5 CaCl2, and 11 glucose; bubbled with 95% O2-5% CO2). Fine rectal nerve fibers (originating from the pelvic ganglia) were dissected free of connective tissue surrounding the rectum. The preparation was pinned along one edge in a 3-ml organ bath, and rectal nerve trunks and a separate strand of connective tissue were pulled into a second small chamber (1-ml volume) separated by a coverslip and silicon grease barrier (Ajax Chemicals). The small chamber was filled with paraffin oil, and conventional extracellular recordings were made with two platinum electrodes. Signals were amplified differentially (DAM 80, WPI) and recorded at 20 kHz with a MacLab 8sp (AD Instruments, Sydney, Australia) attached to a Macintosh G4 computer (Apple, Cupertino, CA) using Chart 3.6.5 software (AD Instruments). Single units were discriminated by amplitude and duration using Spike Histogram software (AD Instruments).

In most experiments, a small array of hooks was used to attach one edge of the preparation to an isometric force transducer (DSC no.46-1001-01, Kistler-Morse, Redmond, WA) that was mounted on a tissue stretcher device (5). The slack was taken up to give a resting tension of ~1 mN, and 60–120 min of equilibration were allowed before the experiment was started. Preparations were stretched by the microprocessor-controlled tissue stretcher (stretching by "imposed length" while recording the tension developed by the tissue), at 5 mm/s for distances of 1–3 mm and held for 10 s, at 3-min intervals. Mean firing rate of afferent units was calculated during a 10-s stretch. In all cases, stretch-evoked contraction was calculated as integrated tension (area under the curve) in (Newtons x seconds). When the effects of Ca2+-free Krebs solution were studied, stretches were applied by imposed length or by "imposed load" to the tissue. In later cases, the array of hooks was attached to the arm of an isotonic transducer via a pulley, and counterweight was increased by hanging 1- to 5-g weights. A resting load of 0.5 g was applied, and contractions of the tissues were recorded as change in length by the isotonic transducer (Harvard Bioscience, model 52-9511, S. Natick, MA).

Transduction sites ("hot spots") that correspond to rIGLEs (28) were identified by focal compression with von Frey hairs (0.1–1 mN) with tip diameters of <50 µm and marked on the tissue, using fine carbon particles attached to the tip of the hair. To determine the minimal latency of mechanotransduction, a blunt glass micropipette (~100 µm tip diameter) was mounted on a piezoelectric element (Radio Spares, Sydney, Australia). Voltage steps (100 V, 200-ms duration) were applied to the piezoelectric activator from a stimulator (Grass DS9A, Quincy, MA) producing a rapid displacement of ~10-µm amplitude with a latency of <0.1 ms. The tip of the pipette was placed precisely above a marked hot spot. Conduction latency was determined using a bipolar platinum stimulating electrode placed at exactly the same site above the marked hot spot. Pulses were delivered at 0.3 Hz, 0.6-ms duration, and suprathreshold voltage (10–30 V). Usually, 10–20 stimuli (mechanical and electrical) were delivered to a single hot spot, and the minimum latency for both stimuli was calculated. Studies of latency were carried out in Ca2+-free Krebs solution to prevent smooth muscle contractions during mechanical probing.

To study the effect of putative blockers of mechanogated channels on mechanotransduction, three consecutive probes with a von Frey hair (~1 mN for 1 s, 10 s apart) on marked hot spots were delivered at 4-min intervals. In preliminary experiments, it was found that this protocol gave reproducible, submaximal responses for period of at least 3 h. Mean firing rate from the three trials was calculated for the most sensitive hot spot.

Drugs. cis-4-[Phosphomethyl]-2-piperidinecarboxylic acid (CGS 19755), 6,7-dinitroquinoxaline-2,3-dione (DNQX), and memantine were obtained from Tocris (Avonmouth, UK). Gadolinium chloride, benzamil, ATP, {alpha},{beta}-methylene ATP ({alpha},{beta}-me ATP), SKF 96365, PPADS, and ruthenium red were obtained from Sigma (St. Louis, MO). Gd3+ was used in modified Krebs solution (in mM: 139 NaCl, 4.75 KCl, 5 HEPES, 1.2 MgCl2, 2.5 CaCl2, and 11 glucose; bubbled with 100% O2).

Data analysis. Results are expressed as means ± SE. Statistical analysis was performed by Student's two-tailed t-test for paired or unpaired data or by repeated-measures one- or two-way analysis of variance using Prism 4 software (GraphPad Software, San Diego, CA). Differences were considered significant if P < 0.05.


    RESULTS
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 ABSTRACT
 MATERIALS AND METHODS
 RESULTS
 DISCUSSION
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Most of rectal afferents [no. of units (n) = 84, N = 66] were electrically silent in unstretched rectal preparations and had low thresholds (~1 mm) to circumferential distension. After the onset of stretch using the tissue stretcher, mechanoreceptor firing showed an initial burst of firing followed by marked adaption that closely followed muscle tension in time course. These units were similar to previously described rIGLEs as transduction sites (29).

Latency of mechanotransduction. Mechanoreceptor afferents were slowly conducting with an average conduction velocity of 1.28 ± 0.13 m/s (n = 7, N = 6), within the C-fiber range. Focal compression of the tissue with light von Frey hairs (0.1–1 mN) activated rectal mechanoreceptors only at several highly localized sites (hot spots), which correspond to rIGLEs (28). The response latency at marked hot spots, determined for each unit using the piezoelectric probe, was 11.3 ± 2.2 ms (n = 7, N = 6). The latency for electrical stimulation from the same sites was 9.7 ± 2.3 ms (n = 7, N = 6; Fig. 1). The latter latency represents the delay due to conduction of action potential from the hot spot to the recording site. By subtracting the conduction latency from total latency for each unit, the mean delay due to mechanotransduction was calculated at 1.7 ± 0.4 ms (n = 7, N = 6). Latencies evoked by mechanical stimulation were more variable than those for electrical stimulation. Typically, shorter latencies were associated with a larger number of spikes evoked by mechanical stimulation. This suggests that small movements of the preparation may have moved hot spots relative to the probe, causing longer latencies and weaker responses when the probe was off center. Despite this variability, mechanotransduction by low-threshold rectal mechanoreceptors occurred on a millisecond time scale and must be due either to rapid chemical transmission from other cells or, alternatively, to activation via mechanogated ion channels located on rIGLEs.



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Fig. 1. Latency of responses to mechanical and electrical stimulation. A: the latency of an afferent action potential in response to electrical stimulation (black trace) is shorter than the response to mechanical stimulation (gray trace); in this example, the difference in latency, reflecting the mechanotransduction delay, is 2.7 ms (shown by double-headed arrow). B: histogram of mechanotransduction delay calculated following mechanical and electrical stimulation from the same hot spots [no. of units (n) = 7, no. of animals (N) = 6].

 
Effects of glutamate ionotropic receptors antagonists on transduction of rectal mechanosensitive afferents. Glutamate can mediate fast synaptic transmission on a submillisecond time scale via ionotropic receptors (41) and has been suggested to be involved in distension-induced activation of spinal and vagal mechanoreceptors (30, 44). The competitive antagonist to ionotropic N-methyl-D-aspartate (NMDA) receptors, CGS 19755 (30 µM), did not affect either stretch-induced firing [107 ± 19% of control for 3-mm stretch, n = 4, N = 3; not significant (NS)] or stretch-induced contraction (108 ± 5%, N = 3, NS). Similarly, the selective antagonist to non-NMDA ionotropic receptors, DNQX (100 µM), did not inhibit stretch-induced firing (91 ± 8% of control at 3-mm stretch, n = 5, N = 4, NS) or contractions (118 ± 3%, N = 4, NS). The open channel blocker of NMDA receptors, memantine (30 µM), affected neither stretch-evoked firing nor contraction (106 ± 23%, n = 5, N = 4, and 96 ± 4%, N = 4, of control 3-mm stretch, respectively). However, at 100 µM, memantine decreased stretch-induced firing slightly (to 74 ± 16% of 3-mm control stretch, NS, n = 6, N = 5) but also significantly decreased stretch-induced tension (to 62 ± 6% of control 3-mm stretch, N = 5, P < 0.005 by two-way ANOVA; Fig. 2). These results indicate that activation of ionotropic receptors by endogenous glutamate is not involved in mechanotransduction by spinal low-threshold mechanoreceptors in the guinea pig rectum.



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Fig. 2. Memantine reduced stretch-evoked firing and contraction in parallel. Averaged data (from 6 units, N = 5) of the effects of memantine (100 µM) on stretch-evoked firing (A) and on the area of contraction (integrated tension) evoked by stretch (B). *P < 0.005.

 
ATP and mechanotransduction. ATP, acting via P2X2/3 receptors, may be involved in mechanotransduction by some spinal afferents to the rat colorectum and mouse urinary bladder (39, 52). In the guinea pig rectum, the P2X-preferring agonist {alpha},{beta}-me ATP (30 µM for 1 min, n = 9, N = 6) evoked relaxation of circular muscle and inhibited muscle contractile responses to distension (to 15 ± 3% of control, 3-mm stretch, N = 6, P < 0.005 by paired t-test). In parallel, {alpha},{beta}-me ATP inhibited stretch-evoked firing (to 26 ± 6% of control, n = 9, N = 6, P < 0.005 by paired t-test) of rectal afferents (Fig. 3A). To determine whether the effect on the muscle could explain the reduced firing, studies were carried out in Ca2+-free Krebs solution. Under these conditions, basal muscle tension and stretch-evoked tension were reduced, presumably due to blockade of active muscle responses. The inhibitory effect of {alpha},{beta}-me ATP on muscle tension was abolished. However, even under these conditions, {alpha},{beta}-me ATP (30 µM) did not excite mechanosensitive endings. The nonselective P2 purinoreceptor antagonist PPADS (30 µM) did not affect stretch-induced firing of rectal mechanoreceptors in normal Krebs solution (91 ± 12% of control 3-mm stretch, n = 6, N = 4, NS by 2-way ANOVA; Fig. 3C). This concentration of PPADS (30 µM for 20 min) was effective, because in its presence, {alpha},{beta}-me ATP (30 µM) no longer inhibited stretch (3 mm)-evoked firing (77 ± 24% of control, n = 6, N = 4, NS by 2-way ANOVA).



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Fig. 3. Involvement of purinoreceptors in mechanotransduction. A: averaged data (from 9 units, N = 6) of the inhibitory effects of the P2X-preferring agonist {alpha},{beta}-methylene ATP ({alpha},{beta}-me ATP; 30 µM) on stretch (3 mm)-induced firing (left) and stretch induced contractions (N = 6; right). Note the reduction of stretch-induced firing by {alpha},{beta}-me ATP was paralleled by a similar reduction in stretch-induced contraction of the circular muscle. B: averaged data of the effects of {alpha},{beta}-me ATP (30 µM, n = 5, N = 4; left) and ATP (1 mM, n = 6, N = 5; right) on firing evoked by compression of transduction sites with a von Frey hair (~1 mN). C: pyridoxal phosphate-6-azophenyl-2',4'-disulfonic acid (PPADS; 30 µM) did not affect stretch-induced firing of rectal mechanoreceptors. Each value in C is the mean ± SE from 6 units in 4 preparations. *P < 0.005.

 
To exclude the indirect effect of purines on firing due to their influence on muscle tension, the actions of ATP and {alpha},{beta}-me ATP were examined on firing evoked by focal compression with a von Frey hair (~1 mN) on a previously marked hot spot. Neither {alpha},{beta}-me ATP (30 µM for 1 min) nor ATP (1 mM for 1 min) affected firing evoked by von Frey hair probing (91 ± 19% of control, n = 5, N = 4, NS; and 127 ± 15% of control, n = 6, N = 5, NS, respectively). Neither agonist activated low-threshold, stretch-sensitive units (Fig. 3B). However, two spontaneously active units (for which hot spots were not found) of 14 recorded units in 5 guinea pigs were slightly excited by application of 1 mM ATP. Overall, these data suggest that P2X receptors are unlikely to be involved in mechanotransduction by the majority of low-threshold mechanoreceptors.

Effects of Ca2+-free Krebs solution on mechanotransduction. We investigated the effect of blocking all rapid synaptic neurotransmitter release mechanisms on transduction using Ca2+-free and high-Mg2+ Krebs solution. Under isometric conditions, transduction of mechanical stimuli by rectal mechanoreceptors in the guinea pig rectum persisted at a reduced level in Ca2+-free (1 mM EDTA, 6 mM Mg2+) Krebs solution (Fig. 4). The number of action potentials evoked by 3-mm stretch was significantly reduced (to 40 ± 14% of control Krebs solution, n = 9, N = 7, P < 0.05 by 2-way ANOVA). This may have been due to the significant reduction of both resting tension and stretch-evoked tension (to 12 ± 3% of control, N = 7, P < 0.001 by 2-way ANOVA; Fig. 4, E and F). After resting tension was adjusted back to the control level, 3-mm stretch evoked an increase in passive tension that was still less than that in normal Krebs solution (30 ± 32% of control, N = 7, P < 0.001 by 2-way ANOVA). However, under these conditions, stretch-induced firing was not significantly different from control (100 ± 21%, n = 9, N = 7, NS; Fig. 4, E and F). To exclude the confounding effect of changes in muscle tension, we also investigated the effects of Ca2+-free Krebs solution under isotonic conditions. Application of Ca2+-free (with 3.6 mM Mg2+) Krebs solution for 1 h did not affect significantly either firing (n = 8, N = 6, NS by 2-way ANOVA) evoked by isotonic stretching of the tissue with imposed load (10–50 mN) or the length of the preparations (N = 6, NS by 2-way ANOVA; Fig. 4, G and H). These findings indicate that Ca2+-dependent fast synaptic release is not required for mechanosensory transduction by rIGLEs in the guinea pig rectum.



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Fig. 4. Effects of Ca2+-free Krebs solution on firing under isometric and isotonic conditions. Responses by 2 discriminated single units (7 superimposed action potentials for each unit are shown as insets at faster time scale at D) evoked by a 3-mm stretch in normal Krebs solution (A) were significantly reduced after 6 min of Ca2+-free (1 mM EDTA, 6 mM Mg2+) Krebs solution (B), and this was accompanied by a reduction in resting tone and in the tension response to stretch. C: stretch-induced firing of both units recovered after basal tension was readjusted back to control level in the continuing presence (20 min) of Ca2+-free medium. E and F: averaged data of the stretch-induced firing (E, n = 9, N = 7) and of the stretch-induced contraction (F, N = 7) in normal Krebs solution ({bullet}), in Ca2+-free Krebs solution ({blacktriangleup}), and after adjusting basal tension to control level in continuing Ca2+-free solution ({blacksquare}). *P < 0.05; @#P < 0.001. G and H: averaged data of the load-induced firing (G, n = 8, N = 6) and load-induced change in length (H, N = 6); neither was significantly affected by 60-min perfusion with Ca2+-free Krebs solution.

 
Effects of stretch-activated and cationic channel blockers on transduction by rectal afferents. We have previously showed that benzamil (a potent analog of amiloride) inhibited stretch-induced firing in the guinea pig esophagus at high concentrations (100 µM) (57). In the guinea pig rectum, benzamil (10–30 µM for 20–25 min) significantly decreased stretch-induced mechanoreceptor firing (Fig. 5A). However, it also reduced stretch-evoked increases in wall tension (Fig. 5B). Thus benzamil (30 µM) reduced firing to 22 ± 6% of control (n = 4, N = 4, P < 0.001 by 2-way ANOVA), whereas it reduced integrated tension to 33 ± 8% of control (N = 4, P < 0.001 by 2-way ANOVA). From these results, it was not possible to determine whether the inhibition of stretch-induced firing by benzamil was due to an effect on mechanogated ion channels on rIGLEs or alteration of the mechanical properties of muscle. Therefore, we studied the effects of benzamil on firing evoked by focal compression of hot spots (rIGLEs) with a von Frey hair. Benzamil (30 µM for 30–35 min) significantly reduced firing evoked by a von Frey hair (~1 mN) probing of hot spots (63 ± 9% of control, n = 5, N = 5, P ≤ 0.01 by 1-way ANOVA). The effect was reversible by washing for 60 min with normal Krebs solution (Fig. 5C).



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Fig. 5. Effects of benzamil on stretch- and compression-evoked firing and intramural tension. Averaged data (5 units in 4 guinea pigs) of the effect of benzamil (10 {blacksquare} and 30 µM {blacktriangleup}) on stretch-induced firing (A) and on stretch-induced contraction (B). Note that inhibition of stretch-induced firing was accompanied by a similar reduction of stretch-induced contraction. *P < 0.001; #P < 0.01; @P < 0.05. C: averaged data of the firing evoked by compression of transduction sites with a von Frey hair (~1 mN) in control solution, in the presence of benzamil (30 µM, n = 5, N = 5), and after wash out (Wash) for 60 min. *P ≤ 0.01.

 
Gadolinium ion (Gd3+; 100 µM for 20 min) inhibited stretch-induced firing to 13 ± 8% of control (3 mm stretch, n = 4, N = 3, P < 0.01 by 1-way ANOVA) but simultaneously reduced stretch-induced muscle tone (to 24 ± 6% of control, N = 3, P < 0.01 by 1-way ANOVA; Fig. 6A). The effect of Gd3+ on stretch-induced firing developed with a time course that paralleled the inhibition of stretch-induced intramural tension (Fig. 6B). Gd3+ (100 µM for 20 min) did not affect firing evoked by von Frey hair (~1 mN) compression of hot spots (112 ± 12% of control, n = 4, N = 4, NS by 1-way ANOVA; Fig. 6C). This suggests that the effect of Gd3+ on stretch-induced firing was probably largely due to reduction of muscle tension.



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Fig. 6. Effects of Gd3+ on stretch- and compression-evoked firing and intramural tension. Averaged data (4 units in 3 guinea pigs) of the effect of Gd3+ (100 µM) on stretch-induced firing (A) and on stretch-induced contraction (B). Note that effect of Gd3+ on stretch-induced firing occurred in parallel with inhibition of stretch-induced intramural tension. *@P < 0.01; #P < 0.05. C: averaged data (n = 4, N = 4) of the effect of Gd3+ (100 µM) on the firing evoked by compression of transduction sites with a von Frey hair (~1 mN).

 
The nonselective cation channel blocker SKF 96365 (30–50 µM for 10–15 min) also inhibited stretch-induced firing. Applied at 50 µM, stretch (3 mm)-induced firing was reduced to 16 ± 15% of control (n = 3, N = 3, P < 0.001 by 2-way ANOVA). Again, this followed a parallel reduction of stretch-induced contraction of smooth muscle (to 38 ± 3% of control, N = 3, P < 0.001 by 2-way ANOVA; Fig. 7, A and B). SKF 96365 (50 µM for 15–20 min) significantly inhibited firing evoked by von Frey hair (~1 mN) compression of hot spots (48 ± 11% of control, n = 6, N = 6, P ≤ 0.05 by 1-way ANOVA). The effect was washable within 45 min (Fig. 7C).



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Fig. 7. Effects of SKF 96365 on stretch- and compression-evoked firing and intramural tension. Averaged data (3 units in 3 guinea pigs) of the effect of SKF 96365 (30 and 50 µM) on stretch-induced firing (A) and on stretch-induced contractions (B). Note that the inhibitory effects of SKF 96365 on stretch-induced firing was associated with a significant reduction of stretch-induced intramural tension. *P < 0.001. C: averaged data (n = 5, N = 5) of the effect of SKF 96365 (50 µM) on the firing evoked by compression of transduction sites with a von Frey hair (~1 mN). *P ≤ 0.05.

 
The nonselective TRP channel blocker ruthenium red concentration-dependently inhibited stretch-induced firing. At 30 µM for 20 min, stretch (3 mm)-induced firing was 30 ± 14% of control (n = 5, N = 4, P < 0.01 by 2-way ANOVA), but, at the same time, stretch-induced tone was reduced to 22 ± 12% of control (N = 4, P < 0.001 by 2-way ANOVA) (Fig. 8, A and B). However, ruthenium red (30 µM for 35–40 min) significantly increased the firing evoked by von Frey hair (~1 mN) probing of hot spots (193 ± 22% of control, n = 6, N = 5, P ≤ 0.05 by 1-way ANOVA). The effect was washable for ≥60 min (Fig. 8C).



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Fig. 8. Effects of ruthenium red (RR) on stretch- and compression-evoked firing and intramural tension. Averaged data (5 units in 4 guinea pigs) of the effect of RR (3, 10, and 30 µM) on stretch-induced firing (A) and on stretch-induced contraction (B). Note that the inhibitory effects of RR on stretch-induced firing were similar to the reduction in stretch-induced intramural tension. *P < 0.001; #P < 0.01. C: averaged data of the effect of RR (30 µM, n = 6, N = 5) on the firing evoked by compression of the transduction sites with a von Frey hair (~1 mN). *P ≤ 0.05.

 

    DISCUSSION
 TOP
 ABSTRACT
 MATERIALS AND METHODS
 RESULTS
 DISCUSSION
 GRANTS
 REFERENCES
 
The present study has shown that mechanotransduction by low-threshold mechanoreceptors in the guinea pig rectum does not require synaptic transmission or endogenous transmitters ATP and glutamate, suggesting that stretch-activated ion channels on rIGLEs are involved in direct physical mechanotransduction by rectal low-threshold mechanoreceptors. By using a piezoelectrical probe to measure accurately responses to mechanical stimulation and subtracting conduction delays, the mechanotransduction delay was shown to be <2 ms. A similar short mechanotransduction delay of 6 ms was reported for vagal mechanoreceptors (57) and of 8 ms for low-threshold cutaneous D-hair receptors (45). In contrast, the mechanical latency for cutaneous high-threshold mechanoreceptors, in particular slowly adapting AM mechanoreceptors and polymodal nociceptors, is many times longer: up to 80 ms (45). Slowly adapting cutaneous mechanoreceptors supplying Merkel cell complexes in touch domes may rely on glutamate, released from Merkel cells, to activate afferent nerve fibers (18). Nevertheless, on its own, rapid mechanotransduction by rectal afferents is not sufficient proof that direct (nonchemical) mechanisms are responsible. At some glutamatergic central nervous system synapses, the total synaptic delay is only 150 µs (41). However, the observation that transduction persists in 0 mM Ca2+, when rapid exocytotic transmitter release is blocked, is strong evidence that chemical transduction is unlikely to be involved.

It has been reported from in vivo studies that glutamate acting at NMDA receptors may be involved in responses to noxious colonic distension in the rat. Recordings from three afferent units in pelvic nerves were reported to show that memantine, an open channel blocker of NMDA ionotropic receptors, reduced the increase in firing evoked by constant pressure distension (30). In the present study, memantine at 30 µM did not affect mechanotransduction by rectal afferents. This concentration is well above the IC50 for NMDA receptors (10). In our hands, at 100 µM, memantine slightly reduced firing but strongly and significantly inhibited stretch-induced contractility. In the study of McRoberts et al. (30), balloon volume was not monitored during the study so that effects of memantine on smooth muscle contractility were not measured. It has been reported for vagal afferents in the intact rat stomach in vivo that distension-evoked firing was reduced by CNQX, memantine, and MK-801 (44). In our hands, other ionotropic glutamate antagonists for both NMDA and non-NMDA receptors (CGS 19755 and DNQX) did not affect mechanotransduction of spinal low-threshold mechanoreceptors in the guinea pig rectum. Similarly, ionotropic glutamate receptor antagonists did not inhibit stretch-induced firing in an in vitro study of vagal mechanoreceptors in the guinea pig esophagus (57). The apparent discrepancies between these findings may be due to experimental differences. First, there may be differences between species. Second, our study was restricted to a highly defined, relatively homogenous class of low-threshold mechanoreceptors, with well-characterized, specialized endings in myenteric ganglia (28). In the other studies, it is not possible to be sure of the homogeneity of recorded receptors or the sites of their sensitive endings within the gut wall. Third, in the present study, high-resolution recordings were made of muscle length and tension within a small area surrounding the receptive field; in other studies, large balloons have been used for distension with or without recordings of contractile responses. A fourth potential explanation is the difference between in vivo and in vitro preparations. It is possible that higher levels of endogenous glutamate may access visceral afferent endings in an intact, perfused organ. Despite these differences in experimental approach, our results suggest that for rIGLE-bearing low-threshold rectal mechanoreceptors, glutamatergic transmission is not required for mechanotransduction. Whether it may contribute to modulating excitability of endings, which could affect the amplitude of responses to distension, remains to be determined. It is worth pointing out that in neither of the published studies cited above did antagonists entirely block responses. In our opinion, this is consistent with a modulatory, rather than transductive role for glutamate. Alternatively, multiple transduction mechanisms, using one or more chemical messenger such as ATP, 5-HT, and glutamate, may be involved.

The purinergic hypothesis for chemical mechanotransduction by spinal afferents suggests that ATP, released from epithelium or urothelium, activates afferent nerve endings via P2X2/3 receptors during gut or bladder distension (6). ATP is well established now as a neurotransmitter in the central and peripheral nervous systems but is also released from other tissues by touch, stretch, or tissue injury (2, 3, 6, 32, 38, 52). Both ionotropic P2X and metabotropic P2Y purinoreceptors are widely expressed on sensory neurons (9, 19, 46). In the current study, neither {alpha},{beta}-me ATP nor ATP activated low-threshold rectal mechanoreceptors. In addition, P2X2 receptor immunoreactivity was not detected on rectal IGLEs (V. P. Zagorodnyuk and S. J. H. Brookes, unpublished observations). In contrast, in the guinea pig esophagus and stomach, IGLES of vagal low-threshold mechanoreceptors were distinctively labeled by P2X2 receptor antibodies, and nearly all of afferent units were excited by {alpha},{beta}-me ATP with EC50 of ~20 µM (8, 57). The effects of purine receptor agonists on rectal mechanoreceptors were complicated by their direct inhibitory effects on smooth muscle; however, these were blocked in Ca2+-free Krebs solution (53, 59). Under identical conditions, a recent report (57) demonstrated that excitatory effects of {alpha},{beta}-me ATP were actually increased for vagal mechanoreceptors. In the rectum, however, we were still unable to detect the excitatory effect of {alpha},{beta}-me ATP on mechanoreceptors, even in Ca2+-free Krebs. The inability of purines to affect firing directly was supported by their lack of the effect on firing evoked by compression of hot spots (rIGLES) with a von Frey hair. In the rat colorectum, it was reported that {alpha},{beta}-me ATP at high concentrations (100 µM–1 mM) activated ~80% of mechanosensitive fibers (50). In contrast, fewer than 50% of esophageal mechanoreceptors are activated by the P2X agonist in the mouse and none in normal ferret esophagus (35, 36). These data support significant species differences in receptor expression in visceral afferents as reported previously (58). It has been suggested that ATP, acting on autocrine P2Y1 receptors, may be involved in some vertebrate touch sensitivity (32). However, in the guinea pig esophagus, the P2Y1 receptor agonist adenosine 5'-O-(2-thiodiphosphate) (38) activated vagal tension receptors with much less efficiency than {alpha},{beta}-me ATP (57). In the present study, the P2 antagonist PPADS did not affect mechanotransduction but antagonized the inhibitory effect of {alpha},{beta}-me ATP on stretch-induced firing. In previously published studies (39, 52), PPADS, suramin, and TNP-ATP modestly inhibited the peak of stretch-induced firing of a subset of low-threshold mechanoreceptors in the rat colorectum and mouse urinary bladder. In our opinion, all these data are compatible with a modulatory, rather than transductive role for purines in low-threshold mechanoreceptors. Alternatively, multiple transductive mechanism, species, and experimental condition differences may be involved explaining apparently discrepant observations between previously published reports and the present study. Purines are released from nonneuronal cells in damaged tissue or during inflammation (2, 6). After acid-induced inflammation, vagal mechanoreceptors in the ferret esophagus become sensitive to {alpha},{beta}-me ATP (36). Thus purinoceptors and purine release may play an important role in setting the excitability of mechanoreceptor endings, particularly in the mucosa and especially in the context of tissue damage. Consistent with this is the observation that high-threshold mechanoreceptors are more sensitive to ATP and purinergic antagonists than low-threshold mechanoreceptors (39, 52).

The latency of mechanotransduction in rectal mechanoreceptors in the guinea pig was <2 ms. In contrast, mechanically activated ATP release typically occurs over a time scale of seconds (2, 42), even when this is mediated by "burst release" (1). ATP and other transmitters can be released very rapidly, on a submillisecond timescale, by calcium-sensitive exocytotic release mechanisms at synapses (41, 60). The use of Ca2+-free and raised Mg2+ Krebs solution is a well-established procedure to block fast exocytotic synaptic release. In our hands, Ca2+-free solution significantly reduced stretch-induced firing. However, when basal tension was readjusted to control levels, the stretch-induced firing was also restored together with a partial recovery of peak tension during the stretch. In addition, in isotonic conditions, where confounding changes in muscle tension were prevented, Ca2+-free solution did not affect load-induced firing. Thus, mechanotransduction appears to be independent of exocytotic release, as reported previously for vagal esophageal low-threshold mechanoreceptors (57). This makes it very unlikely that chemical transduction is significant for rectal mechanoreceptors.

The most likely candidates for mechanogated channels of extrinsic primary afferent neurons in mammals belong probably to TRP and/or ENaC/ASIC/degenerin families of cation and sodium ion channels (14, 15, 20, 34, 37, 51). Recent studies have provided strong evidence for a role in TRPA1 channels in mechanosensitivity of cochlear hair cells (13) and TRPC1 channels in stretch responsiveness of many cell types (29). Nonselective blockers of mechanogated channels, Gd3+, amiloride, and benzamil, can block both families of ionic channels (15, 24, 26, 48). In the present study, benzamil (10–30 µM) inhibited stretch-induced firing of rectal mechanoreceptors, but this may have been due to its effects on wall tension. The inhibitory action of benzamil on firing evoked by von Frey hair compression of transduction sites suggests that mechanogated channels are present on rIGLE-bearing, low-threshold rectal mechanoreceptors. Similar to benzamil, Gd3+ inhibited both stretch-induced firing and contraction in the rectum. The latter effect may be due to blockade of stretch-activated cation channels in smooth muscle (47, 49, 50) because Gd3+ (100 µM) did not affect the firing evoked by von Frey hair compression of hot spots. This is in agreement with previous observations for vagal mechanoreceptors, in which Gd3+ did not inhibit mechanotransduction in concentrations up to 300 µM (55, 57).

Nonselective blockers of cation TRP channels, SKF 96365 and ruthenium red (12, 26), reduced in parallel both stretch-induced firing and muscle contractility. It is likely that the latter effects were due to inhibition of cation and/or voltage-operated L-type Ca2+ channels on smooth muscle cells (11, 25, 31). When the effects of these drugs were studied on firing evoked by von Frey hair compression of transduction sites, SKF 96365 still significantly inhibited mechanotransduction, suggesting an involvement of mechanogated channels (possibly belonging to the TRP family). In contrast to SKF 96365, ruthenium red actually increased compression-evoked firing. Although it is widely used to block TRP channels, ruthenium red also inhibits with similar potency a range of K+ channels (11, 25) that could be responsible for the increased excitability of rectal afferents. It has been previously reported (56) that several types of K+ channels are involved in control of spontaneous and stretch-induced firing of vagal esophageal IGLE-bearing mechanoreceptors. It should be noted that, although the drugs used to block mechanogated channels (benzamil, Gd3+, SKF 96365, and ruthenium red) are currently the best available pharmacological tools, all of them are known to affect other classes of ion channels (7, 16, 24, 27, 31). We cannot exclude the possibility that such nonspecific action may have contributed to their effects on firing. Our results show that care must be taken when interpreting the responses to drugs that affect mechanoreceptor firing; it is important to monitor their effects on smooth muscle tone, particularly when afferents behave grossly as tension receptors.


    GRANTS
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 ABSTRACT
 MATERIALS AND METHODS
 RESULTS
 DISCUSSION
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This study was funded by National Institute of Diabetes and Digestive and Kidney Diseases Grant DK-56986.


    ACKNOWLEDGMENTS
 
S. J. H. Brookes is a senior research fellow of the National Health and Medical Research Council of Australia.


    FOOTNOTES
 

Address for reprint requests and other correspondence: V. Zagorodnyuk, Dept. of Human Physiology, Flinders Univ., GPO Box 2100, Adelaide, South Australia 5001 (e-mail: vladimir.zagorodnyuk{at}flinders.edu.au)

The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.


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 MATERIALS AND METHODS
 RESULTS
 DISCUSSION
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 REFERENCES
 

  1. Arcuino G, Lin JH, Takano T, Liu C, Jiang L, Gao Q, Kang J, and Nedergaard M. Intercellular calcium signaling mediated by point-source burst release of ATP. Proc Natl Acad Sci USA 99: 9840–9845, 2002.[Abstract/Free Full Text]
  2. Birder LA, Barrick SR, Roppolo JR, Kanai AJ, de Groat WC, Kiss S, and Buffington CA. Feline interstitial cystitis results in mechanical hypersensitivity and altered ATP release from bladder urothelium. Am J Physiol Renal Physiol 285: F423–F429, 2003.[Abstract/Free Full Text]
  3. Bodin P and Burnstock G. Purinergic signalling: ATP release. Neurochem Res 26: 959–969, 2001.[CrossRef][ISI][Medline]
  4. Brierley SM, Jones RC 3rd, Gebhart GF, and Blackshaw LA. Splanchnic and pelvic mechanosensory afferents signal different qualities of colonic stimuli in mice. Gastroenterology 127: 166–178, 2004.[CrossRef][ISI][Medline]
  5. Brookes SJH, Chen BN, Costa M, and Humphreys CMS. Initiation of peristalsis by circumferential stretch in flat sheets of guinea-pig ileum. J Physiol 516.2: 525–538, 1999.
  6. Burnstock G. Purine-mediated signalling in pain and visceral perception. Trends Pharmacol Sci 22: 182–188, 2001.[CrossRef][ISI][Medline]
  7. Carr MJ, Gover TD, Weinreich D, and Undem BJ. Inhibition of mechanical activation of guinea-pig airway afferent neurons by amiloride analogues. Br J Pharmacol 133: 1255–1262, 2001.[CrossRef][ISI][Medline]
  8. Castelucci P, Robbins HL, Poole DP, and Furness JB. The distribution of purine P2X(2) receptors in the guinea-pig enteric nervous system. Histochem Cell Biol 117: 415–422, 2002.[CrossRef][ISI][Medline]
  9. Chen CC, Akopian AN, Sivilotti L, Colquhoun D, Burnstock G, and Wood JN. A P2X purinoceptor expressed by a subset of sensory neurons. Nature 377: 428–431, 1995.[CrossRef][ISI][Medline]
  10. Chen HS and Lipton SA. Mechanism of memantine block of NMDA-activated channels in rat retinal ganglion cells: uncompetitive antagonism. J Physiol 499: 27–46, 1997.[Abstract]
  11. Cibulsky SM and Sather WA. Block by ruthenium red of cloned neuronal voltage-gated calcium channels. J Pharmacol Exp Ther 289: 1447–1453, 1999.[Abstract/Free Full Text]
  12. Clapham DE, Montell C, Schultz G, and Julius D. International Union of Pharmacology. XLIII. Compendium of voltage-gated ion channels: transient receptor potential channels. Pharmacol Rev 55: 591–596, 2003.[Abstract/Free Full Text]
  13. Corey DP, Garcia-Anoveros J, Holt JR, Kwan KY, Lin SY, Vollrath MA, Amalfitano A, Cheung EL, Derfler BH, Duggan A, Geleoc GS, Gray PA, Hoffman MP, Rehm HL, Tamasauskas D, and Zhang DS. TRPA1 is a candidate for the mechanosensitive transduction channel of vertebrate hair cells. Nature 432: 723–730, 2004.[CrossRef][ISI][Medline]
  14. Drew LJ, Rohrer DK, Price MP, Blaver KE, Cockayne DA, Cesare P, and Wood JN. Acid-sensing ion channels ASIC2 and ASIC3 do not contribute to mechanically activated currents in mammalian sensory neurones. J Physiol 556: 691–710, 2004.[Abstract/Free Full Text]
  15. Drummond HA, Welsh MJ, and Abboud FM. ENaC subunits are molecular components of the arterial baroreceptor complex. Ann NY Acad Sci 940: 42–47, 2001.[Abstract/Free Full Text]
  16. Elinder F and Arhem P. Effects of gadolinium on ion channels in the myelinated axon of Xenopus laevis: four sites of action. Biophys J 67: 71–83, 1994.[Abstract]
  17. Ernstrom GG and Chalfie M. Genetics of sensory mechanotransduction. Annu Rev Genet 36: 411–453, 2002.[CrossRef][ISI][Medline]
  18. Fagan BM and Cahusac PM. Evidence for glutamate receptor mediated transmission at mechanoreceptors in the skin. Neuroreport 12: 341–347, 2001.[CrossRef][ISI][Medline]
  19. Fong AY, Krstew EV, Barden J, and Lawrence AJ. Immunoreactive localisation of P2Y1 receptors within the rat and human nodose ganglia and rat brainstem: comparison with [{alpha}33P]deoxyadenosine 5'-triphosphate autoradiography. Neuroscience 113: 809–823, 2002.[CrossRef][ISI][Medline]
  20. Garcia-Anoveros J, Samad TA, Zuvela-Jelaska L, Woolf CJ, and Corey DP. Transport and localization of the DEG/ENaC ion channel BNaC1{alpha} to peripheral mechanosensory terminals of dorsal root ganglia neurons. J Neurosci 21: 2678–2686, 2001.[Abstract/Free Full Text]
  21. Gillespie PG and Walker RG. Molecular basis of mechanosensory transduction. Nature 413: 194–202, 2001.[CrossRef][ISI][Medline]
  22. Goodman MB and Schwarz EM. Transducing touch in Caenorhabditis elegans. Annu Rev Physiol 65: 429–52, 2003.[CrossRef][ISI][Medline]
  23. Hamill OP and Martinac B. Molecular basis of mechanotransduction in living cells. Physiol Rev 81: 685–740, 2001.[Abstract/Free Full Text]
  24. Hamill OP and McBride DW Jr. The pharmacology of mechanogated membrane ion channels. Pharmacol Rev 48: 231–252, 1996.[Abstract]
  25. Hirano M, Imaizumi Y, Muraki K, Yamada A, and Watanabe M. Effects of ruthenium red on membrane ionic currents in urinary bladder smooth muscle cells of the guinea-pig. Pflügers Arch 435: 645–653, 1998.[CrossRef][ISI][Medline]
  26. Inoue R, Okada T, Onoue H, Hara Y, Shimizu S, Naitoh S, Ito Y, and Mori Y. The transient receptor potential protein homologue TRP6 is the essential component of vascular {alpha}1-adrenoceptor-activated Ca2+-permeable cation channel. Circ Res 88: 325–332, 2001.[Abstract/Free Full Text]
  27. Kleyman TR, and Cragoe EJ Jr. Amiloride and its analogs as tools in the study of ion transport. J Membr Biol 105: 1–21, 1988.[ISI][Medline]
  28. Lynn PA, Olsson C, Zagorodnyuk V, Costa M, and Brookes SJ. Rectal intraganglionic laminar endings are transduction sites of extrinsic mechanoreceptors in the guinea pig rectum. Gastroenterology 125: 786–794, 2003.[CrossRef][ISI][Medline]
  29. Maroto R, Raso A, Wood TG, Kurosky A, Martinac B, and Hamill OP. TRPC1 forms the stretch-activated cation channel in vertebrate cells. Nat Cell Biol 7: 179–185, 2005.[CrossRef][ISI][Medline]
  30. McRoberts JA, Coutinho SV, Marvizon JC, Grady EF, Tognetto M, Sengupta JN, Ennes HS, Chaban VV, Amadesi S, Creminon C, Lanthorn T, Geppetti P, Bunnett NW, and Mayer EA. Role of peripheral N-methyl-D-aspartate (NMDA) receptors in visceral nociception in rats. Gastroenterology 120: 1737–1748, 2001.[CrossRef][ISI][Medline]
  31. Merritt JE, Armstrong WP, Benham CD, Hallam TJ, Jacob R, Jaxa-Chamiec A, Leigh BK, McCarthy SA, Moores KE, and Rink TJ. SK&F 96365, a novel inhibitor of receptor-mediated calcium entry. Biochem J 271: 515–522, 1990.[ISI][Medline]
  32. Nakamura F and Strittmatter SM. P2Y1 purinergic receptors in sensory neurons: contribution to touch-induced impulse generation. Proc Natl Acad Sci USA 93: 10465–10470, 1996.[Abstract/Free Full Text]
  33. Olsson C, Costa M, and Brookes SJ. Neurochemical characterization of extrinsic innervation of the guinea pig rectum. J Comp Neurol 470: 357–371, 2004.[CrossRef][ISI][Medline]
  34. Page AJ, Brierley SM, Martin CM, Martinez-Salgado C, Wemmie JA, Brennan TJ, Symonds E, Omari T, Lewin GR, Welsh MJ, and Blackshaw LA. The ion channel ASIC1 contributes to visceral but not cutaneous mechanoreceptor function. Gastroenterology 127: 1739–1747, 2004.[CrossRef][ISI][Medline]
  35. Page AJ, Martin CM, and Blackshaw LA. Vagal mechanoreceptors and chemoreceptors in mouse stomach and esophagus. J Neurophysiol 87: 2095–2103, 2002.[Abstract/Free Full Text]
  36. Page AJ, O'Donnell TA, and Blackshaw LA. P2X purinoceptor-induced sensitization of ferret vagal mechanoreceptors in oesophageal inflammation. J Physiol 523: 403–411, 2000.[Abstract/Free Full Text]
  37. Price MP, Lewin GR, McIlwrath SL, Cheng C, Xie J, Heppenstall PA, Stucky CL, Mannsfeldt AG, Brennan TJ, Drummond HA, Qiao J, Benson CJ, Tarr DE, Hrstka RF, Yang B, Williamson RA, and Welsh MJ. The mammalian sodium channel BNC1 is required for normal touch sensation. Nature 407: 1007–1011, 2000.[CrossRef][ISI][Medline]
  38. Ralevic V and Burnstock G. Receptors for purines and pyrimidines. Pharmacol Rev 50: 413–492, 1998.[Abstract/Free Full Text]
  39. Rong W, Spyer KM, and Burnstock G. Activation and sensitisation of low and high threshold afferent fibres mediated by P2X receptors in the mouse urinary bladder. J Physiol 541: 591–600, 2002.[Abstract/Free Full Text]
  40. Ruel J, Chen C, Pujol R, Bobbin RP, and Puel JL. AMPA-preferring glutamate receptors in cochlear physiology of adult guinea-pig. J Physiol 518: 667–680, 1999.[Abstract/Free Full Text]
  41. Sabatini BL and Regehr WG. Timing of neurotransmission at fast synapses in the mammalian brain. Nature 384: 170–172, 1996.[CrossRef][ISI][Medline]
  42. Sauer H, Hescheler J, and Wartenberg M. Mechanical strain-induced Ca2+ waves are propagated via ATP release and purinergic receptor activation. Am J Physiol Cell Physiol 279: C295–C307, 2000.[Abstract/Free Full Text]
  43. Sengupta JN and Gebhart G. Gastrointestinal afferent fibers and sensation. In: Physiology of the Gastrointestinal Tract (3rd ed.), edited by Johnson LR. New York: Raven, 1994, p. 483–519.
  44. Sengupta JN, Petersen J, Peles S, and Shaker R. Response properties of antral mechanosensitive afferent fibers and effects of ionotropic glutamate receptor antagonists. Neuroscience 125: 711–723, 2004.[CrossRef][ISI][Medline]
  45. Shin JB, Martinez-Salgado C, Heppenstall PA, and Lewin GR. A T-type calcium channel required for normal function of a mammalian mechanoreceptor. Nat Neurosci 6: 724–730, 2003.[CrossRef][ISI][Medline]
  46. Thomas S, Virginio C, North RA, and Surprenant A. The antagonist trinitrophenyl-ATP reveals co-existence of distinct P2X receptor channels in rat nodose neurones. J Physiol 509: 411–417, 1998.[Abstract/Free Full Text]
  47. Thorneloe KS and Nelson MT. Properties of a tonically active, sodium-permeable current in mouse urinary bladder smooth muscle. Am J Physiol Cell Physiol 286: C1246–C1257, 2004.[Abstract/Free Full Text]
  48. Trebak M, St JBG, McKay RR, and Putney JW Jr. Comparison of human TRPC3 channels in receptor-activated and store-operated modes. Differential sensitivity to channel blockers suggests fundamental differences in channel composition. J Biol Chem 277: 21617–21623, 2002.[Abstract/Free Full Text]
  49. Wellner MC and Isenberg G. Properties of stretch-activated channels in myocytes from the guinea-pig urinary bladder. J Physiol 466: 213–227, 1993.[Abstract]
  50. Welsh DG, Nelson MT, Eckman DM, and Brayden JE. Swelling-activated cation channels mediate depolarization of rat cerebrovascular smooth muscle by hyposmolarity and intravascular pressure. J Physiol 527: 139–148, 2000.[Abstract/Free Full Text]
  51. Welsh MJ, Price MP, and Xie J. Biochemical basis of touch perception: mechanosensory function of degenerin/epithelial Na+ channels. J Biol Chem 277: 2369–2372, 2002.[Free Full Text]
  52. Wynn G, Rong W, Xiang Z, and Burnstock G. Purinergic mechanisms contribute to mechanosensory transduction in the rat colorectum. Gastroenterology 125: 1398–1409, 2003.[CrossRef][ISI][Medline]
  53. Zagorodnyuk V and Maggi CA. Pharmacological evidence for the existence of multiple P2 receptors in the circular muscle of guinea-pig colon. Br J Pharmacol 123: 122–128, 1998.[CrossRef][ISI][Medline]
  54. Zagorodnyuk VP and Brookes SJH. Transduction sites of vagal mechanoreceptors in the guinea pig esophagus. J Neurosci 20: 6249–6255, 2000.[Abstract/Free Full Text]
  55. Zagorodnyuk VP, Chen BN, and Brookes SJ. Intraganglionic laminar endings are mechano-transduction sites of vagal tension receptors in the guinea-pig stomach. J Physiol 534: 255–268, 2001.[Abstract/Free Full Text]
  56. Zagorodnyuk VP, Chen BN, Costa M, and Brookes SJ. 4-aminopyridine- and dendrotoxin-sensitive potassium channels influence excitability of vagal mechano-sensitive endings in guinea-pig oesophagus. Br J Pharmacol 137: 1195–1206, 2002.[CrossRef][ISI][Medline]
  57. Zagorodnyuk VP, Chen BN, Costa M, and Brookes SJ. Mechanotransduction by intraganglionic laminar endings of vagal tension receptors in the guinea-pig oesophagus. J Physiol 553: 575–587, 2003.[Abstract/Free Full Text]
  58. Zagorodnyuk VP, D'Antona G, Brookes SJ, and Costa M. Functional GABAB receptors are present in guinea pig nodose ganglion cell bodies but not in peripheral mechanosensitive endings. Auton Neurosci 102: 20–29, 2002.[CrossRef][ISI][Medline]
  59. Zagorodnyuk VP, Vladimirova IA, Vovk EV, and Shuba MF. Studies of the inhibitory nonadrenergic neuromuscular transmission in the smooth muscle of the normal human intestine and from a case of Hirschsprung's disease. J Auton Nerv Syst 26: 51–60, 1989.[CrossRef][ISI][Medline]
  60. Zimmerman H. Signalling via ATP in the nervous system. Trends Neurosci 17: 420–426, 1994.[CrossRef][ISI][Medline]




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