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The Journal of Neuroscience, August 15, 2000, 20(16):6249-6255
Transduction Sites of Vagal Mechanoreceptors in the Guinea
Pig Esophagus
Vladimir P.
Zagorodnyuk and
Simon J. H.
Brookes
Department of Human Physiology and Centre for Neuroscience,
Flinders University of South Australia, Adelaide, South Australia
5001
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ABSTRACT |
Extrinsic afferent neurons play an essential role in both sensation
and reflex control of visceral organs, but their specialized morphological peripheral endings have never been functionally identified. Extracellular recordings were made from fine nerve trunks
running between the vagus nerve and esophagus of the guinea pig.
Mechanoreceptors, which responded to esophageal distension, fired
spontaneously, had low thresholds to circumferential stretch, and were
slowly adapting. Calibrated von Frey hairs (0.12 mN) were used to probe
the serosal surface at 100-200 sites, which were mapped on a video
image of the live preparation. Each stretch-sensitive unit had one to
three highly localized receptive fields ("hot spots"), which were
marked with Indian ink applied on the tip of the von Frey hair.
Recorded nerve trunks were then filled anterogradely, using biotinamide
in an artificial intracellular solution. Receptive fields were
consistently associated with intraganglionic laminar endings (IGLEs) in
myenteric ganglia, but not with other filled neuronal structures. The
average distance of receptive fields to IGLEs was 73 ± 14 µm
(24 receptive fields, from 12 units; n = 5),
compared to 374 ± 17 µm for 240 randomly generated sites (n = 5; p < 0.001). After
maintained probing on a single receptive field, spontaneous discharge
of units was inhibited, as were responses to distension. During adapted
discharge to maintained distension, interspike intervals were
distributed in a narrow range. This indicates that multiple receptive
fields interact to encode mechanical distortion in a graded manner.
IGLEs are specialized transduction sites of mechanosensitive vagal
afferent neurons in the guinea pig esophagus.
Key words:
vagus nerve; primary afferent; mechanoreceptor; intraganglionic laminar ending; guinea pig; esophagus; enteric nervous
system
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INTRODUCTION |
Visceral afferents to the gut are
involved in many pathological conditions such as gastroesophageal
reflux (which causes the symptoms of heartburn), gastroparesis, and the
"functional disorders" such as irritable bowel syndrome, which have
major medical and economic impact on the community (Talley et al.,
1995 ). Sensations such as satiety, nausea, and pain are also mediated
by these neurons. However they are also important in reflex control of
normal gut functions, such as swallowing, gastric accommodation, and
control of gastric acid secretion (Cervero, 1994; Sengupta and Gebhart, 1994). The efferent side of many of these reflexes is well understood, being mediated via parasympathetic pathways, which run in the vagus
nerve, or via sympathetic neurons running in mesenteric nerves to the
gut. Vagal efferent neurons in turn activate enteric neurons that
comprise the final output to effector cells and sympathetic fibers
modulate synaptic activity in the enteric nervous system (Furness and
Costa, 1987). However, the details of the afferent side of these
pathways are rather less clear.
Neuroanatomical techniques have characterized the morphology of
extrinsic afferent nerve endings in the wall of the gastrointestinal tract, particularly from the vagus nerve (Clerc and Condamin, 1987;
Berthoud and Powley, 1992; Berthoud et al., 1997; Phillips et al.,
1997). Vagal afferent neurons give rise to three types of specialized
endings in the gut wall. In myenteric ganglia, intraganglionic laminar
endings (IGLEs) (Lawrentjew, 1929; Rodrigo et al., 1975) are found on
the surfaces of myenteric ganglia. In the muscle layers, intramuscular
arrays (IMAs) of afferent nerve fibers have been described (Berthoud et
al., 1997; Phillips et al., 1997), and there are also vagal afferent
nerve endings in the mucosa (Berthoud and Patterson, 1996). There are
fewer studies on the terminations of spinal afferents to the
gastrointestinal tract, but these appear generally to give rise to
nonspecialized free nerve endings (Cervero, 1994) in the mucosa,
muscle, and serosa. Electrophysiologically, extrinsic mechanoreceptors
to the gut have been extensively studied using extracellular recording techniques (Iggo, 1955; Leek, 1977; Sengupta and Gebhart, 1994; Page
and Blackshaw, 1998). Among the vagal afferent fibers, mechanosensitive and chemosensitive mucosal receptors have been distinguished. Mechanoreceptors have been classified by their threshold, dynamic range, and rate of adaptation (Sengupta and Gebhart, 1994). However, it
has not been possible, to date, to relate morphological and physiological studies of visceral afferent neurons and thus identify the endings of particular types of afferents. In this study, vagal mechanoreceptors to the guinea pig esophagus were studied
electrophysiologically, and their morphology was subsequently
determined by anterograde labeling from the recorded nerve trunk.
Intraganglionic laminar endings were shown to be the transduction sites
of vagal mechanoreceptors in the guinea pig esophagus. This novel
combination of techniques now makes it possible to characterize the
morphological features of functionally identified visceral afferent neurons.
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MATERIALS AND METHODS |
Close extracellular single unit recording. Guinea
pigs (n = 57) were killed humanely by stunning and
exsanguination, in a manner approved by the Animal Welfare Committee of
Flinders University. The distal esophagus was opened up into a flat
sheet. The mucosa was then removed, and the preparation was attached to
a microprocessor-controlled tissue stretcher (Brookes et al., 1999). A
fine vagal nerve trunk was dissected free of connective tissue and
passed under a glass coverslip partition into a small chamber (~1000
µl volume) made from Sylgard (Dow Corning, Midland, MI) and filled
with paraffin. Single-unit recordings were made differentially from the
nerve trunk and from a strand of connective tissue, via platinum
electrodes, on a MacLab 8s at 20,000 samples/sec, using Chart 3.6 software (ADI, Sydney, Australia). Single units were
discriminated by amplitude and duration using Spike Histogram software
(AD Instruments). Preparations were stretched by the tissue stretcher
at 10-5000 µm/sec and held for 3-60 sec, while monitoring
circumferential tension. A hand-held, calibrated von Frey hair was
applied to the serosal surface of the preparation to identify receptive
fields of vagal mechanosensitive afferent neurons. Von Frey
hair-sensitive spots (hot spots) and few nearby landmarks were then
marked by applying Indian ink on the tip of the hair to the serosal
surface. A video camera, positioned above the preparation, was used to capture images of the whole preparation, including ink marks, and to
record each site of probing with the von Frey hair.
Anterograde transport and histochemistry. At the end of the
recording period, paraffin was removed from the recording chamber and
replaced with a 1% solution of biotinamide (Molecular Probes, Eugene,
OR) in an artificial intracellular medium [in mM: 150 monopotassium L-glutamic acid, 7 MgCl2, 5 glucose, 1 EGTA, 20 HEPES, and 5 disodium adenosine-triphosphate, 0.02% saponin, and 1%
dimethylsulfoxide (Tassicker et al., 1999)]. The preparation was
covered in supplemented culture medium [DME/F-12 with 10% fetal
bovine serum, 1.8 mM CaCl2, 100 IU/ml
penicillin, 100 µg/ml streptomycin, 2.5 µg/ml amphotericin B, 20 µg/ml gentamycin (Cytosystems, New South Wales, Australia), pH
7.4] and placed on a rocking tray in a humidified incubator with 5%
CO2 in air at 37°C. After 12-15 hr,
preparations were fixed in modified Zambonis fixative (15% saturated
picric acid and 2% formaldehyde in a 0.1 M phosphate buffer, pH 7.0), cleared in DMSO for 30 min, and rinsed in PBS. Labeled nerve fibers were visualized with streptavidin-FITC (catalog #RPN1232; Amersham Life Sciences, Sydney, New South Wales,
Australia; 1:50, 4 hr) or streptavidin-Cy3 (Jackson ImmunoResearch,
West Grove, PA; 1:150, 4 hr). Some preparations were labeled overnight at room temperature with antisera to tyrosine hydroxylase (TH) (catalog
#108460; Incstar, Stillwater, MN; mouse, 1:600), calcitonin gene-related peptide (CGRP) (catalog #IHC6006; Peninsula Laboratories, Belmont, CA; rabbit, 1:1600), choline acetyltransferase (ChAT) (from
Dr. M. Schemann, Hannover Germany, Yeboah; 1:1000), or nitric oxide
synthase (NOS) (from Dr. P. Emson, University of Cambridge, Cambridge,
UK; K205, 1:1000). These were then rinsed three times in PBS then
incubated in appropriate secondary antisera for 2-4 hr (all raised in
donkeys and obtained from Jackson ImmunoResearch: anti-sheep IgG-AMCA,
42308: 1:50, anti-rabbit IgG-CY5, 25325, 1:50, anti-mouse IgG-AMCA
19973, 1:200, anti-mouse-FITC 34010 1:100). Preparations were then
rinsed again in PBS and mounted in bicarbonate-buffered glycerol, pH
8.6.
Labeled nerve fibers were analyzed on an Olympus AX70 epifluorescence
microscope, using a computerized plotting system which recorded the
microscope stage X and Y position on two linear scales with 1 µm
resolution (Mitutoyo, Tokyo, Japan). The coordinates of labeled fibers,
IGLEs, viscerofugal nerve cell bodies, Indian ink marks, and the
outlines of the preparation were recorded and reconstructed (Brookes et
al., 1992) using commercial graph plotting software (SigmaPlot; Jandel,
Corte Madera, CA). Images of labeled neural structures were digitally
captured via a Sony (Tokyo, Japan; SSC-M370CE) black and white video
camera and recorded on an Apple Power Macintosh 7100 computer using NIH
Image version 1.62 software (National Institutes of Health, Bethesda,
MD) via a Scion LG-3 frame grabber board (Scion, Frederick, MD). These
were then used to create montages to which the computerized
reconstructions were fitted, using Canvas 3.05 software (Deneba).
Confocal images were obtained on a Bio-Rad (Herts, UK) MRC-1024
combined with an Olympus AX70 microscope equipped with a krypton-argon
laser. Optical sections were acquired using a 20× Olympus oil
immersion lens (numerical aperture, 0.8) with the confocal iris set to
1-2 mm. The preparations were scanned at 1 µm steps to obtain a Z
series of up to 45 optical sections. The microscope was linked to a
Compaq Pentium personal computer, running Laser Sharp software
(Bio-Rad) for instrument control and data acquisition. Images were
combined, cropped, scaled, adjusted for brightness and contrast in NIH
Image version 1.62, then scaled, aligned, and labeled in Microsoft
Powerpoint 4 and printed on an Epson Stylus Photo EX color printer.
Results are expressed throughout as means ± SEM, with
n referring to the number of animals. Statistical analysis
was performed by means of Student's t test for paired and
unpaired data. Differences were considered significant if
p < 0.05.
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RESULTS |
In vitro recordings from vagal afferent fibers to the
guinea pig esophagus
Preparations had a resting circumference of 5.9-7.2 mm under a
resting tension of 1 mN. Extracellular recordings were made from fine
vagal nerve trunks, 2-4 mm from the edge of the preparation, and
confined to discriminated single axons or "units" whose firing rate
was modified by circumferential stretch (36 of 41 units, n = 30). Of these stretch-sensitive units, 33 of 36 were spontaneously active, firing at 3.2 ± 0.5 Hz
(n = 30) when the preparation was under minimal resting
tension (Fig. 1a,b).
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Figure 1.
Typical response of esophageal vagal afferents
to circumferential stretch. a, Rapid stretch (2 mm at 5 mm/sec) evoked an increase in firing above the spontaneous firing rate.
After the removal of stretch, spontaneous firing was inhibited for
~20 sec. b, During slow stretch (3 mm at 200 µm/sec)
there was a graded, approximately linear increase in firing rate.
c, Combined data from 13 units show graded responses to
rapid stretch (5 mm/sec) of different amplitudes (1 mm, filled
circles; 2 mm, open squares; and 3 mm,
filled triangles), with a graded poststimulus inhibition
of firing. d, Combined data from 11 units respond to 2 mm of stretch at 5 mm/sec, maintained for 30 sec. This evoked an
increase in firing that declined with a time constant of 4.0 ± 0.1 sec (11 units), but the firing rate remained elevated compared to
control spontaneous firing. e, Effect of rate of
stretch on firing. Preparations (n = 7) were
stretched by 3 mm at 10 µm/sec (filled
circles), 50 µm/sec (open squares), 100 µm/sec (filled triangles), or 200 µm/sec
(open diamonds), and firing frequency was calculated at
each length. Consistently larger responses were evoked by the faster
rates of stretch for any given length, demonstrating ongoing adaptation
during the slower stretches.
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Rapid circumferential stretch (5 mm/sec) evoked an abrupt increase in
firing (Fig. 1a) which adapted, with a time constant of
4.0 ± 0.7 sec (11 units, n = 10) to a rate higher
than resting (Fig. 1d). The circumferential tension of the
preparation declined after the initial rise, but with a significantly
slower time constant (6.7 ± 0.6 sec, n = 10, p < 0.05), suggesting that neural adaptation may have
been partially, but not entirely, attributable to changes in intramural
tension. Both phasic and tonic changes in firing were graded with
distensions of 1-3 mm (Fig. 1c), evoking maximum firing
rates up to 75 ± 23 Hz (15 units, n = 12). After
returning to resting length, spontaneous firing of units was typically
diminished or abolished, returning to control rates over a period of
0.5-30 sec (Fig. 1a-c). Stretches >3 mm sometimes caused
irreversible changes in responses and were not used. Stretch at slower
rates (10-200 µm/sec) evoked gradually increasing rates of firing.
The rate of firing for any particular length was greater when the faster rates of stretch were used (n = 7), indicating
ongoing adaptation during slow distension (Fig. 1e).
Focal mechanical stimulation
Serosal probing with a calibrated von Frey hair (which exerted a
force of 0.12 mN) was applied to 100-200 sites in each preparation and
always evoked bursts of firing in just a few sites, which we called hot
spots (Figs. 2a,b,
3a,b). Of a total of 23 units tested, 20 had at least one hot spot (n = 11). Probing
evoked discharges with maximum firing rates of 58 ± 14 Hz (12 units, n = 10). During maintained probing, there was
adaptation of firing but never back to the spontaneous discharge rate.
After withdrawal of the probe, spontaneous firing was inhibited or
abolished, recovering over a period of 0.5-5 sec. In all cases, units
that had one or more hot spots were also activated by circumferential
stretch of the preparation (Fig. 2c). In 3 of 23 cases,
distension-sensitive units were recorded for which no hot spot was
located. Given their small size, relative to the preparation, it is
possible that some hot spots were missed during these studies.
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Figure 2.
Activation of mechanoreceptors by focal pressure
with a calibrated von Frey hair and circumferential stretch. a,
b, Applying a 0.12 mN calibrated von Frey hair to two sites
(designated sites 23 and 38, from the same preparation as Fig. 3)
separately activated two units which could be readily discriminated by
amplitude. Insets show eight superimposed action
potentials activated by von Frey hair. c, The same units
both responded when the preparation was stretched by a
just-suprathreshold length (0.5 mm). Calibration bars in
c also apply to a and b.
Insets show eight superimposed successive action
potentials from the same units in a and
b, confirming that the same units were activated by the
von Frey hair and by stretch. Insets have separate
calibration bars (right side of c).
Asterisks show stepper motor artifacts.
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Figure 3.
Units responded to probing with a calibrated von
Frey hair (0.12 mN) and circumferential stretch. a,
Video image of preparation with recording chamber to the right and
array of hooks connected to the tissue stretcher on the left. Sites
that evoked a response (hot spots) are shown as large white
circles with black outline, sites that evoked no
response (small black dots, white outline), and Indian
ink marks (white triangles). Four sites evoked responses
in two units: sites 1, 4, and 23 all evoked activity in the same unit;
site 38 belonged to a second unit (see Fig. 2). Scale bar, 1 mm.
b, Activity evoked by probing with a von Frey hair
at sites 1, 4, and 23, all of which evoked activity in the same unit
(insets show 10 superimposed action potentials of the
discriminated unit; they are identical). c, Control
response of another preparation to a small, suprathreshold stretch (0.5 mm at 5 mm/sec) (left panel). Probing with the
von Frey hair, at a hot spot, evoked a strong burst of firing in the
large-amplitude unit, after which the response to the same stretch was
inhibited (right panel). Insets
show 10 superimposed action potentials activated by stretch
(left inset) and by the von Frey hair (right
inset), confirming that the same unit was activated by
different stimuli.
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Hot spots and a few nearby landmarks were marked by applying Indian
ink, evaporated onto the tip of the von Frey hair, to the serosal
surface of the preparation (Fig. 3a). Multiple sites surrounding each marked hot spot were always probed, but consistently failed to evoke discharge. From this observation, it became clear that
the axons that led to the hot spot were not sensitive to the local
mechanical distortion evoked by the von Frey hair. From the distance of
nonresponding sites to the hot spot it was calculated that the
receptive fields were very small, with a maximum diameter ranging from
90 to 330 µm (mean, 178 ± 16 µm; 17 units; n = 5). In several units (4 of 12; n = 5) two or more hot
spots were found for the same unit; these were spaced up to 2.3 mm
apart (Fig. 3a,b).
The refractory period after probing with a von Frey hair was used to
study how multiple transduction sites may contribute to the overall
firing of the unit. After recording responses to small rapid
circumferential stretches (0.5-1.5 mm), the von Frey hair was applied
to a hot spot, held, and then released. During the ensuing refractory
period, the small rapid circumferential stretch was repeated (Fig.
3c). In the first 2 sec of control stretches, firing
increased from the spontaneous rate of 3.6 ± 0.6 to 7.3 ± 1.0 Hz, but when preceded by Von Frey hair probing, the same stretch
evoked a firing rate of 2.9 ± 1.3 Hz, which was slightly lower
than the spontaneous rate. Thus, increases in firing evoked by
distension were significantly reduced after probing with a von Frey
hair on a single receptive field (p < 0.05; 11 units; n = 6). As a control, we examined stretch-evoked
responses of other afferent units, which were not affected by applying
the von Frey hair. Their responses to stretch were not changed (13 units; n = 6), indicating that the effects of the von
Frey hair were specific for the particular unit. Similar inhibition of
stretch responses was seen when a von Frey hair was applied to a single site of a unit with two or more identified hot spots. This indicated that hot spots do not generate spikes independently of one another, because desensitization of a single hot spot inhibited the
stretch-evoked discharge of the entire unit, including other
nonactivated hot spots.
This was investigated further by studying interspike intervals during
adapted discharge evoked by 2 mm distensions maintained for 30-60 sec.
For each unit, adapted firing occurred at a very constant frequency
(6.7 ± 1.5 Hz; 14 units; n = 9) with interspike intervals distributed over a very narrow range (Fig.
4a,b). The mean firing
frequency was considerably less than the peak frequency that the unit
could generate, indicating spike intervals were not determined by the
absolute refractory period of the axon. The absence of closely spaced
spikes made it unlikely that hot spots generated spikes independently.
This was readily tested by simple modeling. Each simulated spike was
set to follow its predecessor by a set interval, with normally
distributed temporal "noise" added. The mean interval and variance
of the intervals matched those of a real unit (Fig. 4c).
Next two spike trains were generated, each with double the mean
interspike interval, but the same variance, with the first spikes
180° out of phase. This simulated two identical, independent spike
generating sites, contributing equally to the spike train. Very
quickly, spikes from the two generating sites began to move in and out
of phase (Fig. 4d). The resulting interspike intervals had a
uniform interval ranging from zero to twice the mean interval (Fig.
4c). This confirms that it is very unlikely that separate
hot spots generate their spikes independently from one another during
circumferential stretch.
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Figure 4.
Analysis of interspike intervals during adapted
discharge to maintained stretch. a, Rapid
circumferential stretch (2 mm at 5 mm/sec for 30 sec) evoked firing in
two units, which adapted to a constant rate after the first 10 sec.
b shows the distribution of interspike intervals in the
same units from 10 to 30 sec after the onset of stretch. Note the
normal distribution and relatively small variance in intervals.
c, Interspike intervals during adapted discharge in a
unit from another preparation, identified as having two hot spots
(open bars). A simulated unit, with identical mean and
variance is superimposed (thick line). The simulated
interspike intervals for a unit with two independent spike-generating
sites, with the same variance, is shown as small filled
circles; the uniform distribution suggests that multiple hot
spots are unlikely to generate action potentials independently, when
the preparation is stretched. d, Simulated firing of a
single unit with two independent spike-generating sites with identical
means and variance, initially set 180° out of phase. Note that spikes
from the two sites (visually distinguished by amplitude) rapidly go in
and out of phase to generate the uniform distribution of intervals
shown in c.
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Anterograde labeling of vagal nerve fibers
To identify the potential sources of stretch-induced activity
recorded from vagal nerve trunks, rapid anterograde labeling was used
(Tassicker et al., 1999), in combination with immunohistochemistry for
CGRP, TH, NOS, or ChAT. The most numerous labeled afferent nerve
endings were those of IGLEs, characterized by their leaf-like ramifying
endings on the surfaces of the ganglia, which were seen in 32 of 40 preparations (Figs. 5a,
6b,c). In most cases they were
restricted to one end of a ganglion and occupied a mean area of
6924 ± 577 µm2 with a long axis of
147 ± 8 µm (79 IGLEs; n = 20). In many cases a
single axon gave rise to several IGLEs of various sizes in different ganglia. Bare axons, running for several millimeters parallel to
striated muscle fibers of the inner and outer muscle layers were seen
in 12 of 22 preparations (Fig. 5b). These typically branched
rather little and never gave rise to motor endplates or IGLEs, as far
as we could determine. A total of 93 nerve cell bodies were
retrogradely labeled from vagal nerve branches in 17 of 40 preparations
(Fig. 5a). These were small to medium cells (maximal
cross-sectional area 651 ± 35 µm2;
56 neurons; n = 12), with a few short lamellar or
lobular dendrites and, as far as could be determined, a single axon. Of
these cell bodies, 53 of 59 were NOS-immunoreactive, and 5 of 10 also
showed ChAT immunoreactivity. These could be the cell bodies of
inhibitory motor neurons to the trachea (Fischer et al., 1998; Moffatt
et al., 1998) or may project to sympathetic ganglia, mediating reflexes analogous to those described in the intestine (Kreulen and Szurszewski, 1979). Motor endplates were present in 18 of 33 preparations (Fig. 5c). TH- or CGRP-immunoreactive paravascular axons were
scarce (4 of 21 preparations). Varicose fibers of vagal preganglionic neurons were also frequently labeled. They branched extensively within
myenteric ganglia (33 of 40 preparations; Fig. 5d),
sometimes forming dense baskets of endings around unlabeled nerve cell
bodies.
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Figure 5.
Anterograde filling from fine branches of the
vagus nerve using biotinamide (see Materials and Methods).
a, A retrogradely labeled nerve cell body, several
varicose axons, and a faint IGLE are labeled in a myenteric ganglion.
b, Varicose fibers running within the inner striated
muscle layer all arose from a single fiber, which did not give rise to
motor endplates. c, Three motor endplates arising
from a single filled axon are visible within the inner, striated muscle
layer. d, Extensive varicose branching arising from a
single vagal preganglionic efferent fiber ramify through a myenteric
ganglion. Such fibers were readily distinguishable from the flattened,
leaf-like processes of IGLEs, which were generally confined to the
upper and lower surfaces of the ganglia. Scale bars, 50 µm.
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Figure 6.
Anterograde filling from a fine vagal nerve trunk
from which afferent units had been previously recorded.
a, Montage of labeled fibers, anterogradely filled from
a recorded vagal nerve trunk. Coordinates of hot spots (large
white circles with black outline), sites that
evoked no response (small black circles, white outline),
and Indian ink landmarks (white triangles) were
extracted from the video image of the preparation and superimposed on
the montage by aligning the Indian ink marks. Note that hot spots are
closely related to IGLEs. Details of two sites are shown in
b and c that activated the same unit.
Images are merged vertical projections of through-ganglion
z-series taken on a confocal microscope.
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Identification of mechanical transduction sites
After physiological characterization of mechanoreceptor activity
and marking of hot spots with Indian ink, recorded vagal nerve trunks
were anterogradely filled with 1% biotinamide. The average number of
visible axons filled from recorded vagal nerve trunks varied from 3 to
15 (mean, 8.7 ± 1.2; n = 10). In preliminary experiments at low magnification, each marked hot spot lay close to an
anterogradely filled IGLE (mean distance, 108 ± 48 µm;
n = 6). When mapped at higher magnification (Fig.
6a), the mean distance from hot spots to the nearest IGLE
was 73 ± 14 µm (24 hot spots; from 12 units; n = 5). In contrast, the mean distance from randomly generated sites
(within the filled area) to the nearest IGLE was significantly greater
(374 ± 17 µm; 240 sites; n = 5;
p < 0.001). In several cases, the only nearby filled
structure was an IGLE in a myenteric ganglion. It is likely that the
distance from IGLEs to hot spots may have been slightly overestimated
because Indian Ink marks shifted slightly during tissue handling
because of the mobility of the serosa. No other biotinamide-labeled
neural structures were associated with hot spots, including bare axons in muscle layers, motor endplates, or postganglionic efferent varicose
endings. Four units had two or more hot spots, separated by distances
of up to 2.4 mm (mean, 749 ± 247 µm; eight distances; n = 3). In each case an IGLE was associated with each
hot spot (Fig. 6a-c), spaced up to 2.3 mm apart (mean,
789 ± 275 µm; eight pairs of IGLEs; n = 3). In
3 of 11 guinea pigs, nerve cell bodies were filled from recorded nerve
trunks, however they were located 697 ± 234 µm (five neurons,
n = 3) from the nearest recorded hot spot.
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DISCUSSION |
Since Pacinian corpuscles were first identified as rapidly
adapting mechanoreceptors (Hunt, 1961), the morphology and physiology of many classes of nerve endings in the skin have been identified, providing a firm foundation for the analysis of cutaneous sensation (Iggo, 1985). However, this has not been achieved for visceral afferents, largely because the high density of intrinsic innervation made it impossible to identify unambiguously which nerve ending had
been stimulated. Anterograde filling of small numbers of axons in
recorded nerve trunks avoids this problem and has made it possible for
us to identify the function of morphologically characterized visceral
afferent endings for the first time.
The vagal mechanoreceptors studied here have been recorded
electrophysiologically over many years (Iggo, 1955; Leek, 1977; Sengupta and Gebhart, 1994; Page and Blackshaw, 1998), and it is firmly
established that they act primarily as in-series tension receptors
(Iggo, 1955). Besides their role in mediating sensations such as
fullness, when the stomach is distended, extrinsic visceral afferent
nerve endings play important roles in regulating the physiological
function of the gut (Cervero, 1994; Sengupta and Gebhart, 1994). From
the results of the present study, intraganglionic laminar endings are
likely to be the first element in physiologically important vagal
reflex pathways activated by distension. These include the activation
of antral contractions by stomach contents (Andrews et al., 1980),
gastric accommodation (Takahashi and Owyang, 1997), duodeno-gastric
inhibition (Holzer and Raybould, 1992), and the triggering of transient
lower esophageal sphincter relaxations responsible for gastroesophageal
reflux (Mittal et al., 1995). The esophageal vagal mechanoreceptors,
which were the particular subject of this study, have been shown to
modulate the central pattern generator controlling swallowing (Falempin
et al., 1986). The recent demonstration that vagal mechanoreceptors can
be pharmacologically modulated by GABAB receptor
agonists (Page and Blackshaw, 1999) raises the possibility of
intervening in reflex control of gastrointestinal function at the level
of the specialized afferent neurons.
Morphologically, IGLEs were first described in the esophagus
(Lawrentjew, 1929), and are known to be present in the smooth muscle
esophagus of cat and rhesus monkey (Rodrigo et al., 1975) and in the
striated muscle esophagus of the dog (Nonidez, 1946), mouse (Sang and
Young, 1998), and guinea pig (present study). In fact, IGLEs are also
abundant in the stomach and the small and large intestines (Berthoud et
al., 1997), indicating that they play an important role throughout the
gastrointestinal tract. Their location, exclusively in myenteric
ganglia, led to suggestions that they may be the efferent collaterals
of extrinsic afferents (Berthoud and Powley, 1992) or that they may
function as mixed afferent and efferent endings (Neuhuber, 1987).
Whereas the present study showed that IGLEs are the transduction sites
of tension-sensitive mechanoreceptors, it does
not exclude the possibility that they may also play an efferent role,
because they appear to make close contacts with enteric neurons
(Rodrigo et al., 1975; Neuhuber, 1987; Berthoud, 1995). However, a
recent study examining fos expression after electrical stimulation of
the vagus nerve suggested that such an efferent role for IGLEs or other
vagal afferents is likely to be rather limited (Zheng et al.,
1997).
Most vagal mechanoreceptors appeared, in our morphological studies, to
give rise to several IGLEs in separate ganglia. It is likely that each
IGLE is capable of generating action potentials, because von Frey hair
probing apparently activated all IGLEs. Several lines of evidence
suggested that mechanoreceptor firing evoked by circumferential stretch
of the preparation results from coordinated activity between different
IGLEs. After maintained pressure applied by a von Frey hair to a single
IGLE, spontaneous firing and stretch-evoked responses of the entire
unit were inhibited. This suggests that strong activation of one IGLE
reduced the excitability of other IGLEs belonging to the same unit.
Analysis of interspike intervals during adapted discharge revealed an
absence of closely spaced pairs of impulses that would be expected if
multiple spike-generating sites operated independently (Iggo and Muir,
1969). This was supported by statistical modeling, which showed that
two independent spike-generating sites do not give rise to the narrow
distribution of interspike intervals observed during adapted discharge.
One simple explanation for these findings would be that action
potentials generated by one IGLE may invade other IGLEs antidromically
and reset their discharge. If this is the case, multiple IGLEs may
function to "even out" the firing rate for a given stimulus, or, if
they have different sensitivities, they may extend the dynamic range
over which the unit responds.
This study has identified the peripheral endings of the primary
afferent neurons involved in detecting mechanical deformation of the
gut wall. These neurons are involved in extrinsic reflex pathways that
play important roles in controlling gut function. The approach that we
have developed here will allow the systematic identification of
extrinsic afferent nerve endings in the gut and other visceral organs.
| |
FOOTNOTES |
Received March 13, 2000; revised May 22, 2000; accepted May 30, 2000.
This study was funded by AstraZeneca, Mölndal, Sweden, and
S.J.H.B. was supported by the National Health and Medical
Research Council of Australia. We thank Grant Hennig for his generous
help with the mapping of video images and Bill Blessing, Marcello
Costa, Ian Gibbins, Phil Jobling, and Judy Morris for commenting on
this manuscript.
Correspondence should be addressed to Simon Brookes, Department of
Human Physiology, Flinders University, GPO Box 2100, Adelaide, South
Australia 5001. E-mail: simon.brookes{at}flinders.edu.au.
| |
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ABSTRACT
INTRODUCTION
