5-HT2A receptors: location and functional
analysis in intestines of wild-type and 5-HT2A knockout
mice
Elena
Fiorica-Howells1,
Rene
Hen2,
Jay
Gingrich2,
Zhishan
Li1, and
Michael D.
Gershon1
Departments of 1 Anatomy and Cell Biology and
2 Center for Neurobiology and Behavior, Columbia
University, College of Physicians and Surgeons, New York, New York
10032.
 |
ABSTRACT |
The
distribution and function of the 5-hydroxytryptamine
(5-HT2A) receptor were investigated in the intestines of
wild-type (5-HT2A +/+) and knockout (5-HT2A
/
) mice. In 5-HT2A +/+ mice, rats, and guinea pigs,
5-HT2A receptor immunoreactivity was found on circular and
longitudinal smooth muscle cells, neurons, enterocytes, and Paneth
cells. Muscular 5-HT2A receptors were concentrated in
caveolae; neuronal 5-HT2A receptors were found
intracellularly and on the plasma membranes of nerve cell bodies and
axons. Neuronal 5-HT2A immunoreactivity was detected as
early as E14 in ganglia, intravillus nerves, and the deep muscle
plexus. The 5-HT2A
/
colon did not express
5-HT2A receptors and did not contract in response to
exogenous 5-HT. 5-HT2A
/
enterocytes were smaller, Paneth cells fewer, and muscle layers thinner (and showed
degeneration) compared with those of 5-HT2A +/+
littermates. The 5-HT2A receptor may thus be required for
the maintenance and/or development of enteric neuroeffectors and other
enteric functions, although gastrointestinal and colonic transit times
in 5-HT2A
/
and +/+ mice did not differ significantly.
serotonin receptors; intestinal motility; immunocytochemistry
 |
INTRODUCTION |
THE ENTERIC NERVOUS
SYSTEM (ENS) is different from the autonomic innervation of other
organs, because it can mediate coordinated behaviors of the gut without
central nervous system input (28, 32, 53). The presence in
the bowel of intrinsic primary afferent neurons (IPANs)
enables the ENS to respond to luminal stimuli. Because no nerve fibers
enter the lumen, Bülbring and Crema (7) proposed
that sensory transduction is transepithelial, involving the
pressure-induced secretion of 5-HT from enterochromaffin (EC) cells to
stimulate the mucosal processes of the submucosal IPANs that initiate
reflexes. This hypothesis has since been confirmed, and EC cell-derived
5-HT is now thought to activate both peristaltic (21, 36, 37, 47,
50, 63) and secretory reflexes (12, 73).
In addition to its role in the initiation of enteric reflexes,
5-hydroxytryptamine (5-HT) also functions in ganglionic
neurotransmission within the ENS. A subset of myenteric interneurons is
serotonergic (8, 13, 22, 29, 31, 76, 77); therefore, 5-HT
antagonists can block peristaltic reflexes by inhibiting enteric
serotonergic neurotransmission (46, 60, 82) as well as by
interfering with the paracrine stimulation of IPANs. 5-HT from EC
cells also plays a role in extrinsic sensation by stimulating
extrinsic primary afferent nerves (2, 39, 40).
The bowel contains an abundance of 5-HT receptor subtypes located on
neurons, smooth muscle, and epithelial cells (24, 25, 30).
Enteric neuronal 5-HT receptors include 5-HT1A (26,
48, 49, 62), 5-HT1P (6, 59, 64),
5-HT2B (18), 5-HT3 (15, 25,
42, 59), and 5-HT4 (36, 37, 62, 80).
Enteric members of the 5-HT2 family are associated with
smooth muscle, which they stimulate to contract (17, 27, 51, 52,
67), and epithelial cells, which they stimulate to secrete
(3, 38, 41, 43, 74). The 5-HT2B receptor,
which was originally known as the rat fundus receptor because of its
location on the smooth muscle of gastric rumen (10, 11, 20, 54,
56), has now been shown also to be expressed on intestinal
neurons, to be developmentally regulated, and to promote the
development of enteric neurons (18). The
5-HT2C receptor is not expressed in the gut
(18).
There have been suggestions that a 5-HT2 receptor might be
involved in the modulation of enteric neuronal activity (19, 35,
43, 68). The current study was thus undertaken to test the
hypothesis that 5-HT2A receptors are present on enteric
neurons as well as on smooth muscle. To do so, we used RT-PCR to detect mRNA encoding the 5-HT2A receptor in the developing and
adult mouse intestine; moreover, light and electron microscopic
immunoreactivity were employed to locate 5-HT2A receptors
intracellularly and on the surfaces of enteric neurons and smooth
muscle cells. We also examined the intestines of mice carrying a
targeted deletion in the 5-HT2A promoter region
(5-HT2A
/
). Contractile responses to exogenous 5-HT,
the microscopic structure of muscle, nerve, and epithelium,
gastrointestinal transit, and colonic motility were compared in
5-HT2A
/
mice and their +/+ littermates. Observations suggest that 5-HT2A receptor may play roles in the ENS in
the maintenance of the targets of enteric innervation.
 |
MATERIALS AND METHODS |
Animals and tissue collection.
Adult Sprague-Dawley rats (Charles River Laboratories) were
anaesthetized with methoxyflurane (Pitman Moore) and decapitated. Guinea pigs (Kingstar Laboratories) were stunned and exsanguinated. Transgenic mice with a targeted disruption of the promoter region of
the 5-HT2A receptor (5-HT2A
/
) and their
5-HT2A +/+ littermates were bred on a C57/B6 background
(33). All pups were genotyped at birth by PCR analyses of
tissue samples from the tails of the animals. All mice used in the
current study were genotyped again at the time of use, once more by PCR
analyses of tissue obtained from a toe. 5-HT2A
/
mice
failed to exhibit the activation of cortical layer V pyramidal cells or
the behavioral head twitches and ear scratches that characterize
responses to the systemic administration of 5-HT2A agonists
(34). Female mice [age ~6 mo; C57/B6
(5-HT2A
/
and 5-HT2A +/+ littermate
controls) and CD-1 (Charles River Laboratories)] were killed by
cervical dislocation after narcotization with CO2. Fetuses,
obtained from timed pregnant CD-1 mice, were anaesthetized by cooling
and exsanguinated before dissection. The Animal Care and Use Committee
of Columbia University approved all procedures. The gut was dissected
from the animals and cleaned with Krebs solution. Stomach, small
intestine, and colon were each analyzed. Whole fetuses were also fixed
and frozen for cryostat sectioning (see below). In a subset of
experiments, the longitudinal muscle with adherent myenteric plexus
(LM-MP) was dissected from the wall of the gut at ages ranging from
embryonic (E) day 16 (mouse) to adult (rat and mouse). These
LM-MP preparations were stretched and pinned out as flat as possible on
dishes coated with a silicone elastomer (Sylgard) and maintained in
Krebs solution until fixed (see below). Primary cultures of dissociated
cells from the E14 fetal gut were prepared as previously
described (18). Briefly, after digestion of the fetal gut
with collagenase, the crest-derived cells were immunoselected with the
specific antibody for p75NTR. Cells were grown in defined
media on laminin substrate for 4 days and then fixed for immunocytochemistry.
RT-PCR.
RNA was extracted from segments of mature or fetal bowel using the
guanidinium thiocyanate method (9). RT-PCR was employed to
determine whether mRNA encoding any of the members of 5-HT2 receptor family could be detected in the stomach, small intestine, or
colon of either 5-HT2A +/+ or 5-HT2A
/
mice. For first strand cDNA synthesis, 1 µg of RNA was incubated for
1 h at 42°C with 200 units of Moloney murine leukemia virus
(M-MLV) reverse transcriptase, using random primers at a concentration
of 1 µM. This reaction and subsequent amplification with
Taq polymerase was carried out with a commercial kit
(GeneAmp; Perkin-Elmer, Foster City, CA) according to the
manufacturer's instructions. The sets of PCR primers used for the
analyses are listed in Table 1.
-Actin was used as an internal control for experiments involving comparative RT-PCR. The PCR profile for each set of primers (listed in Table 1) was programmed into a model PTC-150 programmable thermal
cycler (MJ Research, Watertown, MS). PCR reaction products were
resolved on 1.2% agarose/40 mM Tris-acetate, 1 mM EDTA gels, and their sizes were determined by using a 123-bp standard ladder.
Immunocytochemistry.
Both fresh-frozen and fixed preparations were examined. Segments of
adult gut and E16 fetuses were fixed with 4% formaldehyde (from
paraformaldehyde) in PBS for 1 and 4 h, respectively, at room
temperature. Both preparations were then washed extensively with PBS
(6 × 10 min), infiltrated with sucrose (30%; 4°C for 24-36 h), embedded with optimum cutting temperature medium
(Lipshaw), frozen in liquid N2, sectioned (at 10 µm) with
a cryostat-microtome, and collected on gelatin-coated glass slides.
Sections of fresh-frozen tissue were fixed on slides (1% formaldehyde,
10 min, 4°C) and washed (2 × 10 min) with PBS containing 0.1%
Triton X-100 (PBS-T). Endogenous peroxidase activity was inhibited by
treating preparations for 30 min with H2O2
(0.3%) in PBS-T. Preparations were washed again with PBS-T and blocked
for 30 min with 4% goat serum in PBS containing 0.3% Triton X-100.
Primary antibodies (Table 2) were then
applied to the sections for 72 h at 4°C. Sites of antibody binding were detected with secondary antibodies and, if necessary, visualizing reagents (Table 3). Double
label fluorescence immunocytochemistry was used to identify the
immunoreactivities of the neuronal marker, ubiquitin hydrolase protein
gene product 9.5 (PGP 9.5) (85) together with that of
5-HT2A receptors (Table 2). For studies of receptor
development in vitro, fixed cultures were either permeabilized with
PBS-T supplemented with 4% goat serum or examined without prior
permeabilization to demonstrate the immunoreactivity of receptors
inserted into the plasma membrane. LM-MP preparations were fixed
(as above) while pinned flat. The fixed material was then washed with
PBS, cut into small rectangles (~0.5 cm × 1.0 cm) and processed
as free-floating whole mounts. The LM-MP preparations were washed
(3 × 10 min) with PBS-T, blocked for 30 min with 4% goat serum
in PBS containing 0.3% Triton X-100 (blocking solution), incubated
overnight (4°C) with primary antibodies (Table 2), and finally
visualized with appropriate secondary antibodies (Table 3).
Preparations were mounted flat on slides and coverslipped with
Vectashield media (Vector Laboratories) to prevent fading. Fluorescence microscopy was carried out with a Leitz DMRD microscope equipped for vertical excitation. The filter/mirror cube used to
visualize the fluorescence of FITC did not reveal the emission of
cyanine 3 and that employed for the visualization of cyanine 3 fluorescence did not pass the FITC emission. Alternatively, specimens
were examined with a Zeiss confocal microscope.
Electron microscopy.
For routine electron microscopy (EM) analysis, ~1-cm segments from
the proximal and distal portions of the small intestine and the middle
of the colon of 5-HT2A +/+ and
/
mice were pinned flat
on Sylgard and fixed for 3 h at room temperature in a solution containing 4% formaldehyde and 3.5% glutaraldehyde in 0.1 M
cacodylate buffer (pH 7.4). The specimens were then postfixed for
1 h in a solution containing 1% OsO4, washed
extensively with sodium maleate buffer (pH 6.2), stained en bloc with
maleate-buffered uranyl acetate (2%), and dehydrated in an
ethanol gradient before embedding in an epoxy resin (Epon 812; Electron
Microscopy Science). Thin sections were then cut, picked up on copper
grids, and stained with uranyl acetate and lead citrate. Sections were
examined and photographed with a JEOL 1200 EX microscope.
EM immunocytochemistry.
Segments of bowel were cut along the mesenteric border and pinned flat
in tissue culture medium supplemented with nicardipine (1 µM) to
relax the smooth muscle cells. Specimens were then fixed by immersion
for 3 h in a solution containing 4% formaldehyde, 0.01 M sodium
periodate, and 0.075 M lysine · HCl in 0.1 M sodium phosphate
buffer (pH 7.4; to maximally preserve membranes without destroying
5-HT2A antigenicity). After fixation, tissues were washed
with 50% ethanol (4 × 10 min) and incubated overnight at 4°C
in phosphate buffer (0.1 M). The LM-MP was then dissected from the
preparations and treated for 1 h with 1% sodium borohydride and,
subsequently, for 30 min with 10% normal goat serum (in PBS). Antibodies to the 5-HT2A receptor (Table 2) were applied
overnight at 4°C in PBS containing 4% normal goat serum. After
washing with PBS, immunoreactivity was detected with biotinylated goat
anti-mouse secondary antibodies and visualized with
streptavidin-horseradish peroxidase (Table 3). The tissue was
then prepared for EM examination as described above.
Quantifying the branching of the myenteric plexus.
Neurons and their processes in LM-MP preparations from
5-HT2A +/+ and 5-HT2A
/
mice were labeled
with the neuronal marker PGP 9.5. Random fields were photographed and
examined at a uniform magnification of ×86. The percentage of the
total area of each micrograph occupied by PGP 9.5-immunoreactive
ganglia or secondary rami was then determined (tertiary branches of the
plexus were not considered for this analysis). To estimate this area, a
grid of 114 evenly spaced dots was superimposed on each picture and the
proportion of the dots falling on the PGP 9.5-immunoreactive neural
structures was determined. Data were analyzed by ANOVA using the
StatView 4.0 program for the Macintosh.
Gastric emptying and small intestinal transit.
Transit through the stomach and small intestine was measured by
administering a nonabsorbed marker (10% charcoal suspension in 5% gum
Arabic) to 5-HT2A +/+ and 5-HT2A
/
mice
(45, 58). The mice were given 0.2 ml of the suspension by
gavage through a straight blunt-ended feeding needle. Twenty min after
the charcoal was administered, the animals were killed and the entire
gastrointestinal tract was removed. The distances from the pylorus to
the front of the charcoal bolus and to the ileocecal junction were
measured. The rate of transit was determined from the relationship:
[distance to charcoal front]
[length of small intestine] × 100 and expressed as a percent. Transit was measured in 12 5-HT2A +/+ and 12 5-HT2A
/
mice, and means
were compared by Student's t-test.
Longitudinal muscle contraction.
Contraction of the colon from 5-HT2A +/+ and
5-HT2A
/
mice was measured in response to 5-HT (10 µM) and acetylcholine (10 µM) (16). Briefly, colons
were removed from 5-HT2A +/+ and 5-HT2A
/
mice with their attached mesentery, cleaned, mounted in a vertical
organ bath, and continuously superfused with Krebs solution (equilibrated with 95% O2-5% CO2) at 37°C.
The aboral end of the colon was fixed and the oral end was attached to
a linear motion transducer (model ST-2; Phipps and Bird). Movements of
the colon were displayed on a potentiometric pen recorder. The gut was
allowed to equilibrate for 30-40 min before the start of each
experiment. Compounds were applied for 5 min, during which the
superfusion of fresh buffer was halted. At least 15 min were
allowed to elapse before another compound was applied to the bath. In
no instance was a second drug tested before the response to the prior
application of a drug had dissipated and the preparation had resumed
its resting length. Segments of colon were removed from three mice of
each type for these analyses.
Colonic transit.
The motility of the colon was evaluated in separate sets of
5-HT2A +/+ and 5-HT2A
/
littermates.
Animals were lightly anesthetized with ether, and a glass microbead (3 mm in diameter) was inserted through the anus and pushed, with a
polished glass rod, into the colon for a distance of 2 cm
(61). The time from the completion of insertion to the
expulsion of the bead was measured to the nearest 0.1 min to provide an
estimate of the rate of motility of the colon.
 |
RESULTS |
Enteric 5-HT2A receptors were located by
immunocytochemistry.
Immunocytochemistry with 5-HT2A-selective antibodies was
used to locate sites of 5-HT2A receptor expression in
mature small and large intestines of the mouse, rat, and guinea pig.
Fixed-frozen sections and whole mount preparations from each species
were examined. The patterns of expression observed in the adult bowel
of the mouse, rat and guinea pig were identical. 5-HT2A
receptor immunoreactivity was detected in the mucosal epithelium (Fig.
1, A and C),
longitudinal and circular layers of the muscularis externa
(Fig. 1, A, C, and F), as well as in
both the submucosal (Fig. 1, A, C, and
D) and myenteric plexuses (Fig. 1, A,
C, and E). The epithelial
5-HT2A immunoreactivity was moderate in enterocytes and
crypt cells of the small intestine but intense in Paneth cells (Fig.
1A). The 5-HT2A receptor immunoreactivity of
crypt cells and enterocytes was more apparent in the colon, where it
was highly concentrated at basolateral cell surfaces, than in the small
intestine (compare Fig. 1, A with C). Many
neurons in each of the enteric plexuses (~40%) of both the small and
large intestines were 5-HT2A immunoreactive (Fig. 1,
A, and C-E). The ganglionic
neuropil and the interganglionic connectives also displayed
5-HT2A receptor immunoreactivity (Fig. 1, D and
E). In whole mount preparations, a series of
5-HT2A immunoreactive "hot" spots were visible in an
irregular distribution along the long axis of the muscle fibers (Fig.
1F). 5-HT2A-immunoreactive nerve fibers coursed
through the circular muscle layer; these nerve fibers were particularly
striking in the colon (Fig. 1C). No
5-HT2A-immunoreactive nerve fibers were observed in the
longitudinal muscle of either the small intestine or the colon.

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Fig. 1.
5-Hydroxytryptamine
(5-HT)2A immunoreactivity is found in enterocytes,
Paneth cells, the enteric nervous system (ENS; submucosal and myenteric
neurons), and the smooth muscle of the muscularis externa in the rat
small intestine. A: full thickness of the wall of the small
intestine is cut in cross section. Paneth cells (arrowheads) are
densely 5-HT2A immunoreactive, whereas the neighboring
enterocytes of the crypt epithelium are lightly immunostained.
Submucosal and myenteric ganglia (arrows) appear to be more densely
immunoreactive than the muscle cells of either the circular muscle (cm)
or longitudinal muscle (lm) layers. Smooth muscle 5-HT2A
immunoreactivity outlines cells and is thus probably concentrated in
plasma membranes. The small dark cells in the lamina propria bind
avidin and are stained nonspecifically; they can also be seen as tissue
not exposed to primary antibodies (B). B:
control; there is no staining of enterocytes, Paneth cells, the ENS, or
smooth muscle in the absence of antibodies to the 5-HT2A
receptor. C: cross section of the rat colon. The basolateral
surfaces of crypt epithelial cells (arrowheads), as well as submucosal
and myenteric ganglia (arrows), express intense 5-HT2A
immunoreactivity. Smooth muscle coats of both cm and lm layers are
outlined by 5-HT2A immunoreactivity. D:
dissected whole mount of the submucosal plexus. Many neuronal cell
bodies are densely 5-HT2A immunoreactive (arrows). The
neuropil and interganglionic connectives are moderately immunostained.
E: dissected whole mount of the lm with adherent myenteric
plexus (LM-MP). The muscle is out of focus. Many neuronal cell bodies
in ganglia are densely 5-HT2A immunoreactive (arrows). The
neuropil and interganglionic connectives are moderately immunostained.
F: dissected whole mount of the lm layer, which is in focus.
Muscle fibers are 5-HT2A immunoreactive, and there are
"hot" spots (arrowheads) that stand out along the length
of the fibers. Bars = 50 µm.
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EM immunocytochemistry was used to identify
5-HT2A-immunoreactive structures in ENS and
smooth muscle. Within the submucosal and myenteric plexuses,
5-HT2A receptor immunoreactivity was found on the plasma
membranes of subsets of neuronal perikarya and axons (Figs.
2, A and B and 3,
B-E). Axonal varicosities, in particular, were
often outlined by 5-HT2A receptor immunoreactivity, which was concentrated where varicosities contacted other cells (Figs. 2A and 3D). Most of the
5-HT2A-immunoreactive varicosities were predominantly
packed with small synaptic vesicles (diameters 50-55 nm) with
electron lucent cores. The membranes of some irregularly shaped
vesicles within varicosities appeared to be immunoreactive (Figs.
2B and 3E). A subset of neuronal perikarya
contained intracellular 5-HT2A immunoreactivity, which
appeared to be associated with the rough endoplasmic
reticulum (Fig. 3, B and
C). Within the smooth muscle, 5-HT2A
receptor immunoreactivity was strikingly concentrated in plasma
membrane caveolae (Fig. 2, E and F). Some caveolae were almost fully filled with reaction product. No
immunostaining of either nerve (Figs. 2C and 3A)
or muscle (Fig. 2D) was seen in control sections exposed to
normal rabbit serum instead of primary antibodies to the
5-HT2A receptor but otherwise processed in the same way as
the experimental preparations.

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Fig. 2.
5-HT2A immunoreactivity is found on the plasma
membranes of axonal varicosities and in caveolae of smooth muscle.
A: ganglion of the myenteric plexus of the rat small
intestine. 5-HT2A immunoreactivity outlines the plasma
membranes of several varicosities (arrows). B:
interganglionic connectives of the myenteric plexus of the rat small
intestine. 5-HT2A immunoreactivity appears on the plasma
membranes of axonal varicosities (arrows) that contain synaptic
vesicles. Some irregularly shaped vesicles within these varicosities
are immunostained. C: control section through a ganglion of
the myenteric plexus of the rat small intestine. There is no
immunostaining in the absence of primary antibodies to the
5-HT2A receptor. D: control section through the
smooth muscle of the muscularis externa of the rat small intestine. No
immunostaining is seen in the absence of primary antibodies to the
5-HT2A receptor. E and F: smooth
muscle of the muscularis externa of the rat small intestine.
5-HT2A immunoreactivity is found in caveolae
(arrowheads) associated with the plasma membranes of smooth
muscle cells. Bars = 1 µm.
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Fig. 3.
Intracellular 5-HT2A immunoreactivity is found in a
subset of enteric neurons. A: control. Neither
varicosities nor cell bodies of enteric neurons display a
3,3'-diaminobenzidene reaction product in tissues not exposed to
antibodies to the 5-HT2A receptor. B:
5-HT2A immunoreactivity is found in the cytoplasm of
a myenteric neuron. The immunoreactivity is most dense in ribosome-rich
patches near elements of endoplasmic reticulum that appear to have been
damaged by the horseradish peroxidase reaction; n, nucleus.
C: in another myenteric neuron, 5-HT2A
immunoreactivity can be seen in vesicles near the Golgi apparatus and
in association with the dilated ends of Golgi cisternae. D:
5-HT2A immunoreactivity is found in subsets of neuritic
processes (arrows) in an interganglionic connectives.
Inset: reaction product can also be seen in association with
synaptic membranes where varicosities containing small,
clear synaptic vesicles appose dendrites. E: vesicles
containing 5-HT2A immunoreactivity are found in subsets of
labeled neurites and varicosities (arrows). Bars = 1 µm.
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The 5-HT2A receptor is expressed in the E16 fetal
bowel.
5-HT2A receptor immunoreactivity was demonstrated in whole
mounts of preparations of the E16 fetal bowel from which the mucosa had
been removed by dissection under microscopic control. The tissues were
then examined by laser scanning confocal microscopy. The
immunoreactivity was found to be strikingly localized in two distinct
planes of the preparations. One corresponded to the developing myenteric plexus (Fig. 4A).
Within this plane, the immunoreactivity of the 5-HT2A
receptor was found in an anastomosing network of relatively thick rami
comprised mainly of the cellular elements of the primordial plexus.
Because immunofluorescent cells adjoined one another with little or no
intervening space, the borders of individual cells could not be
distinguished. Distinct secondary and tertiary branches of the plexus,
such as are seen in the mature myenteric plexus, were not apparent,
although the presumptive interganglionic connectives were thinner and
more fibrous than the presumptive ganglia. The second plane, at the
border between the circular muscle and the submucosa, consisted of a
dense anastomosing mesh of thin fibers with a predominant orientation
parallel to the direction of the circular muscle (Fig. 4B).
The immunofluorescent fibers were not varicose. Depth-coding the images
confirmed that the 5-HT2A-immunoreactive structures were
indeed located in separate planes of the gut wall, that there was
little overlap of the thin fibers and the myenteric plexus, and that
the predominant orientation of the thin
5-HT2A-immunoreactive fibers was perpendicular to that of
developing myenteric ganglia (Fig. 4C).

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Fig. 4.
Networks of
5-HT2A-immunoreactive processes are found in the embryonic
(E) day 16 small intestine. These networks lie in 2 distinct
planes and differ in appearance. A: in the plane of the
developing myenteric plexus, 5-HT2A immunoreactivity is
found in ganglia and developing interganglionic connectives.
B: second plexus of much finer
5-HT2A-immunoreactive processes is seen deep to the
myenteric plexus. C: depth-coded illustration. General
orientation of the deep 5-HT2A-immunoractive plexus is
roughly perpendicular to that of the primordial myenteric plexus and
~20 µm below it. Pseudocolors: 20 µm, red blue = superficial deep. Bar = 50 µm.
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Examination of PGP 9.5 immunoreactivity in sections of the E16 small
intestine revealed that at this age myenteric ganglia were well defined
and submucosal ganglia were small but recognizable (Fig.
5, A and C). In
addition, varicose nerve fibers could be seen extending from the
primordial submucosal plexus into the cores of the developing villi,
which are present at E16 in the proximal small intestine. Scattered PGP
9.5-immunoreactive neurons in the myenteric plexus were colabeled by
antibodies to the 5-HT2A receptor (Fig. 5, B and
C). Although distinctive 5-HT2A-immunoreactive nerve cell bodies were not observed in the submucosal plexus, there was
a considerable amount of 5-HT2A immunoreactivity in nerve
fibers within the region of the submucosal plexus, and thick PGP
9.5-immunoreactive nerve trunks that projected from the submucosal plexus into the cores of developing villi often displayed coincident 5-HT2A labeling (Fig. 5, D and E). In
addition to the neuronal expression of 5-HT2A
immunoreactivity, muscle cells were also 5-HT2A
immunoreactive, especially in the primordial longitudinal layer.

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Fig. 5.
5-HT2A-immunoreactive neurons and processes are
abundant in the E16 small intestine. A-C:
cross-sectioned preparations. D-F: whole
mount preparations. Specimens were processed to demonstrate protein
gene product 9.5 (PGP 9.5) and 5-HT2A immunoreactivities
simultaneously. A: PGP 9.5 immunoreactivity; this
panneuronal marker shows the locations in the intestinal wall of
ganglia of the myenteric (arrow) and submucosal (smp) plexuses.
Varicose axons extend into the cores of villi (v). The lm contains no
nerve fibers. B: 5-HT2A immunoreactivity;
myenteric but not submucosal neuronal cell bodies are immunoreactive.
C: Superimposed images. Note that the varicose neurites in
the villus core are not 5-HT2A immunoreactive.
D: PGP 9.5 immunoreactivity. A thick nerve trunk (arrow)
extends into the core of a villus from the smp. E:
5-HT2A immunoreactivity. Neurites in the smp and the thick
nerve trunk (arrow) are immunoreactive. F: superimposed
images. 5-HT2A-immunoreactive neurites are a subset of the
PGP 9.5-immunoreactive population. Bar = 25 µm.
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5-HT2A immunoreactivity is present on cell bodies and
varicosities of neurons that develop in vitro.
5-HT promotes the development of neurons in vitro, and this effect is
mediated by 5-HT2B receptors (18). The
observations discussed above, however, suggest that 5-HT2A
receptors are also expressed in the developing ENS. It is difficult to
expose the surfaces of neurons in situ for investigations of the
distribution of receptors. Individual processes and especially the
growth cones of extending neurites, furthermore, are not easily
distinguished. To facilitate an analysis of the location of 5-HT
receptors in developing neurons, therefore, we took advantage of
superior accessibility of enteric neurons developing in dissociated
cell cultures from neural crest-derived precursors (E16). The
distribution on enteric neurons of the 5-HT2A receptor was
compared with that of 5-HT2B receptors. Antibodies that
react with extracellular domains were used for the immunocytochemical
detection of the 5-HT2A and 5-HT2B receptors. Cultures to be examined were fixed and investigated as
whole mounts with or without prior permeabilization. The
nonpermeabilized preparations were studied to minimize intracellular
immunoreactivity and thus to facilitate the localization of receptors
on cell surfaces.
5-HT2A immunoreactivity was found to be very prominent on
the membranes of cells, which were verified to be neurons by their coincident expression of PGP 9.5 immunoreactivity (Fig.
6, A and B). The
5-HT2A immunoreactivity was restricted to highly localized "hot spots" on varicose expansions of neuronal processes and on perikarya. 5-HT2A immunoreactivity was also found on a
subset of cells that were weakly PGP 9.5 immunoreactive but which did not extend neuritic processes. The intensity of the 5-HT2A
immunoreactivity was much less than that of 5-HT2B
immunoreactivity in sister cultures, and many more cells were
5-HT2B than 5-HT2A immunoreactive (not illustrated). 5-HT2A-immunoreactive clusters were also more
localized to the varicosities of neurites (Fig. 6C)
than was 5-HT2B immunoreactivity (Fig. 6,
D-H). The immunoreactivity of
5-HT2A receptors was also more restricted than that of
5-HT2B receptors to cells that expressed coincident PGP 9.5 immunoreactivity (not illustrated) and thus were identified as neurons.
The 5-HT2B receptor immunoreactivity was expressed within
the lamellipodia of a subset of neuritic growth cones (Fig. 6,
F-H). Despite its abundance in the growth cone
proper, 5-HT2B immunoreactivity was excluded from their
thin filopodial extensions [compare Fig. 6F (PGP 9.5) with
6G (5-HT2B)]. In contrast to 5-HT2B
receptor immunoreactivity, little or no 5-HT2A receptor
immunoreactivity was present in growth cones, although striking
5-HT2A-immunoreactive clusters were prominent in neuritic
expansions proximal to the growth cones themselves (Fig.
6C).

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Fig. 6.
5-HT2A
immunoreactivity is present on the cell bodies and perikarya of neurons
that develop in vitro. A and B: enteric neurons
and varicosities processed as whole mounts and viewed to demonstrate
PGP 9.5 (A) and 5-HT2A immunoreactivities
(B) simultaneously. Note that 5-HT2A
immunoreactivity is concentrated on the cell bodies of the neurons and
the varicosities of their axons. C: enteric neuron
developing in vitro has been doubly immunostained with antibodies to
PGP 9.5 (green fluorescence) and 5-HT2A receptors (red
fluorescence). The 5-HT2A immunoreactivity in this cell is
confined to "hot spots" at varicose expansions and branch point of
extending neurites (arrows). D and E: enteric
neurons and varicosities processed as whole mounts and viewed to
demonstrate PGP 9.5 (D) and 5-HT2B
immunoreactivities (E) simultaneously. One neuron is
5-HT2B immunoreactive, whereas the other is not.
F-H: extending neurites and growth cones
illuminated to demonstrate PGP 9.5 (F) and
5-HT2B (G) immunoreactivities. Superimposed
images are seen in H. Note that 5-HT2B
immunoreactivity is strikingly concentrated at growth cones. Bars = 25 µm.
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|
Relative size of the myenteric plexus in 5-HT2A
/
mice is not significantly different from that of their
5-HT2A +/+ littermates.
To determine whether 5-HT2A receptors affect the
development of enteric neurons, the relative size of the myenteric
plexus was measured in 5-HT2A
/
mice, which lacked
5-HT2A receptors, and in their 5-HT2A +/+
littermates, which served as controls. Neurons were demonstrated in
dissected whole mounts of colon. This portion of the bowel was
investigated, because a preliminary study carried out by RT-PCR did not
reveal mRNA encoding the 5-HT2A receptor in the colons or
stomachs of the 5-HT2A
/
animals (Fig. 7A). In contrast, the
5-HT2A
/
small intestine was found to contain small
amounts of residual mRNA encoding the 5-HT2A receptor. Immunocytochemistry was also employed in 5-HT2A
/
animals, but the 5-HT2A immunoreactivity could not be
distinguished from background. Exogenous 5-HT (10 µM) was applied to
the isolated colon of 5-HT2A +/+ and
/
mice to
determine whether the 5-HT2A-mediated contractile effect,
which is a direct response of the longitudinal smooth muscle to 5-HT
(16), was retained or absent in the animals lacking 5-HT2A receptors (Fig. 7B). Whereas 5-HT evoked
a contraction of the 5-HT2A +/+ colon, no response was
elicited by 5-HT when it was applied to colon of the 5-HT2A
/
mice. The 5-HT2A
/
colon, however, contracted in
response to ACh (10 µM) and thus was able to respond to agents for
which receptors were present in the tissue.

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Fig. 7.
Expression of the
5-HT2A receptor is lacking in the colons of
5-HT2A / mice. A: RT-PCR; mRNA encoding the
5-HT2A receptor is present in the stomach, small intestine,
and colon of 5-HT2A +/+ mice (wt). 5-HT2A
transcripts are absent in the stomach and colon of 3 separate
5-HT2A / mice (ko), but a minimal amount of residual
5-HT2A expression can be detected in each of their small
intestines. B: 5-HT (10 µM) induces a contraction of the
lm of the 5-HT2A +/+ colon. In response to 5-HT (10 µM),
lm of the 5-HT2A / colon does not contract, but it does
contract in response to ACh (10 µM).
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|
The proportion of the serosal area occupied by PGP 9.5-immunoreactive
cells and neurites in the plane of the myenteric plexus was quantified
stereometrically in whole mounts of longitudinal muscle with attached
myenteric plexus (Fig. 8,
A-C). The relative areas of the myenteric
plexus in 5-HT2A
/
mice were not statistically different from those of their 5-HT2A +/+ littermates (Fig.
8A). Neurons that contain the immunoreactivities of nitric
oxide synthase 1 (NOS-1) (Fig. 9,
A-D) or calcitonin gene-related peptide
(CGRP; Fig. 9, E and F) were found in both
5-HT2A
/
and in their 5-HT2A +/+
littermates and were approximately equal in numbers in the two types of
mice. No difference in mRNA encoding NOS-1 was found by RT-PCR in
5-HT2A
/
and 5-HT2A +/+ animals (Fig.
9G).

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Fig. 8.
The size and pattern of the
myenteric plexus in 5-HT2A +/+ and / mice do not differ
significantly from one another. A: percentage of serosal
area occupied by PGP 9.5-immunoreactive elements of the myenteric
plexus in wt and ko mice. B: PGP 9.5 immunoreactivity in a
dissected preparation of LM-MP from a 5-HT2A / mouse.
C: PGP 9.5 immunoreactivity in the LM-MP from a
5-HT2A +/+ mouse. Bars = 200 µm.
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Fig. 9.
Nitric oxide synthase-1 (NOS-1)-
and calcitonin gene-related peptide (CGRP)-immunoreactive cells and
neurites cannot be distinguished in 5-HT2A +/+ and /
mice. A, C, and E: images from bowel
of 5-HT2A +/+ mice. B, D, and
F: images from bowel of 5-HT2A / mice.
A-D: NOS-1 immunoreactivity in the small
intestine (A and B) and colon (C and
D). E and F: CGRP immunoreactivity in
the colon. Bars = 50 µm. G: RT-PCR; mRNA encoding
NOS-1 is found in the colon (Col), small intestine (SI), and stomach
(St) of 5-HT2A +/+ (left) and 5-HT2A
/ (right) mice. Relative amounts can be compared
semiquantitatively relative to simultaneously analyzed mRNA encoding
-actin (Act).
|
|
5-HT2B expression in 5-HT2A
+/+ mice is not distinguishable
from their 5-HT2A
/
littermates.
The possibility that other members of the 5-HT2 family of
receptors might be upregulated in the bowel to compensate for the knockout of the 5-HT2A receptor was investigated. As noted
previously (18), mRNA encoding the 5-HT2C
receptor could not be detected by RT-PCR anywhere in the bowel of
wild-type (5-HT2A +/+; 5-HT2B +/+) mice.
Transcripts encoding the 5-HT2C receptor did not appear in
the 5-HT2A
/
gut (data not illustrated). The
5-HT2B receptor, however, is detectable in wild-type mice,
both in the stomach, the small intestine, and the colon (Fig.
10). The level of expression of mRNA
encoding the 5-HT2B receptor in 5-HT2A +/+ mice
was compared with that in their 5-HT2A
/
littermates by
semiquantitative RT-PCR (Fig. 10). No difference was apparent in the
stomach, the small intestine, or the colon; therefore, if
5-HT2B expression changes as a result of the knockout of
the 5-HT2A receptor, it does so too subtly to be detectable
by semiquantitative RT-PCR.

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Fig. 10.
Expression of
5-HT2B receptors is not substantially changed in
5-HT2A / mice. mRNA encoding the 5-HT2B
receptor and -actin ( -Act) was assessed by RT-PCR in the Col, SI,
and St of 5-HT2A +/+ and / mice.
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|
Smooth muscle, Paneth cells, and enterocytes are abnormal in
5-HT2A
/
mice.
The bowel wall appeared to be thinner in 5-HT2A
/
mice
than in their 5-HT2A +/+ littermates. Measurements were
thus made to quantify the thickness of the muscle layers and the
epithelium to identify the components of the bowel responsible for this
apparent difference among animals. These studies concentrated on cells (enterocytes, Paneth cells, smooth muscle) found in the
immunocytochemical studies (above) to express 5-HT2A
immunoreactivity. The height of enterocytes was measured from the
tip of the microvillus border to the basement membrane (Fig.
11A). The region selected
for measurement was on the sides of villi, where mature cells are
found. The cell extrusion zones at the tips of villi and cells in
crypts were excluded. The plane of section was such that the nuclei of
the measured cells formed a single row parallel to the basement
membrane. Measurements were obtained in both the proximal (duodenum)
and distal (ileum) small intestine. The height of the enterocytes of
5-HT2A +/+ mice in both the proximal (37.9 ± 0.8 µm) and distal (33.9 ± 0.9 µm) small intestine were
significantly greater (P < 0.0001) than those of their
5-HT2A
/
littermates (proximal = 28.5 ± 1.0 µm; distal = 19.8 ± 1.3 µm). The normal proximodistal decrease in enterocyte height was preserved, although the cells were
smaller both proximally and distally, in the 5-HT2A
/
animals. In contrast to villus height, the number of Paneth cells
per crypt increased proximodistally in 5-HT2A +/+ mice
(Fig. 11B). The density of Paneth cells, counted as the
number per crypt profile, was significantly less in 5-HT2A
/
mice than in their 5-HT2A +/+ littermates, both in
the proximal (1.3 ± 0.2 vs. 3.3 ± 0.4, respectively; P < 0.0001) and distal (2.6 ± 0.4 vs. 5.3 ± 0.6 respectively; P < 0.004) small intestine. In
addition to the epithelial abnormalities, the thickness of both the
circular (Fig. 11C) and longitudinal (Fig. 11D)
muscle layers was significantly less (P < 0.0001) in both the proximal and distal small bowel of 5-HT2A
/
mice than in their 5-HT2A +/+ littermates. The thickness of
the two external muscle layers tended to increase proximodistally, a
pattern seen in both 5-HT2A +/+ and
/
animals. The
difference in the thickness of the layers appeared to be due to the
presence of thinner muscle cells in the 5-HT2A
/
mice
rather than to fewer cells. The longitudinal muscle was about four to
five cells thick in the small intestine and three cells thick in the
colon of both 5-HT2A +/+ and
/
mice. The thickness of
the circular muscle was composed of ~6 cells in the small intestine
and 17 cells in the colon in both types of mouse.

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Fig. 11.
The height of enterocytes, numbers of Paneth cells, and thickness
of the layers of the muscularis externa were all significantly less in
5-HT2A / mice than in their 5-HT2A +/+
littermates. Comparisons were made with toluidine blue-stained plastic
sections (1.0 µm thick) of the proximal and distal small intestine.
Three mice per group were analyzed (the n values listed
below are the numbers of measurements made for each parameter).
Differences between 5-HT2A +/+ mice and their /
littermates were statistically significant (*). A:
enterocyte height (proximal: n = 21 +/+ and 25 / ;
distal: n = 8 +/+ and 12 / ). B: numbers
of Paneth cells per crypt. (proximal: n = 17 +/+ and 31 / ; distal: n = 18 +/+ and 10 / ). C:
thickness of the cm (proximal: n = 22 +/+ and 31 / ;
distal: n = 8 +/+ and 16 / ). D:
thickness of the lm. (n = 11 +/+ and 25 / ; distal:
n = 10 +/+ and 9 / ).
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|
Observations that the thickness of the muscle layers was different in
5-HT2A +/+ and
/
mice suggested that there might be structural abnormalities in the muscle. To evaluate this possibility, the murine gut was examined by EM. The most striking ultrastructural difference between 5-HT2A +/+ mice (Fig.
12, A and B) and
their 5-HT2A
/
littermates (Fig. 12,
C-F) was in the myofilaments of scattered
muscle cells found in both muscle layers. These cells were more
electron lucent than their neighbors, because they appeared to have
fewer thin filaments (Fig. 12D). In cross sections (Fig. 12,
E and F), islands of thin myofilaments could be
seen to be separated from one another by intervening patches of
cytosol. The abnormal muscle cells were thicker than most of their
normal-appearing neighbors.

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Fig. 12.
Degenerative changes are found in a subset of muscle fibers in the
muscularis externa of 5-HT2A / mice. Three mice of each
phenotype were investigated. A and B: illustrated
sections pass through the muscularis externa of the small intestines of
two 5-HT2A +/+ mice. Sections were taken either from the
center of the circular layer (A) or the border of the cm
with the submucosa (B). A ganglion of the smp appears at the
upper right in B. C-F: illustrated
sections pass through the muscularis externa of two 5-HT2A
/ littermates. Sections were taken from the circular layer at its
border with submucosa (C), center of cm, or from lm
(D) of small intestine and from the circular layer of colon
(F). Cells outlined by arrowheads show degenerative change.
Note relative electron lucent cytoplasm and relative paucity and
disorientation of thin filaments of these cells. In cross sections of
abnormal muscle cells, particularly in colon, zones free of
myofilaments appear so that remaining myofilaments are form islands in
cytoplasm. Bars = 1.0 µm.
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Gastrointestinal transit and colorectal motility are similar in
5-HT2A +/+ and
/
mice.
Gastrointestinal transit was measured to determine whether the loss of
the 5-HT2A receptor affects the timing of gastric emptying and subsequent propulsion in the small intestine. The rate of gastrointestinal transit was measured in 5-HT2A
/
mice
and compared with that in their 5-HT2A +/+ littermates.
Charcoal (in a suspension in gum Arabic) was administered by gavage,
and proportion of the length of the small intestine traversed by the
charcoal was determined. The rate of gastrointestinal transit in
5-HT2A
/
animals did not differ significantly from that
in their 5-HT2A +/+ littermates (Fig.
13A). The motility of the
colon was also examined. In this case, the speed of colonic transit was
estimated from the time required to expel a glass bead inserted into
the colon a fixed distance of 2 cm from the anal verge. The rate of
colonic transit of 5-HT2A
/
mice did not differ
significantly from that of their 5-HT2A +/+ littermates
(Fig. 13B).

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Fig. 13.
Neither gastrointestinal
transit time nor colorectal motility differ significantly in
5-HT2A / mice from those of their 5-HT2A
+/+ littermates. Measurements of each type were made on 10 paired
littermates of each phenotype. A: gastrointestinal transit
time estimated as the percentage of length of small intestine traversed
within 20 min by a bolus of charcoal instilled into the stomach by
gavage. B: motility in the distal colon and rectum estimated
as the time to expulsion through the anus of a glass bead pushed into
the colon for a distance of 2 cm.
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 |
DISCUSSION |
Since Gaddum and Picarelli (23) first distinguished
between enteric M and D receptors, muscular and neuronal 5-HT receptors of the bowel have generally been thought to be distinct and
nonoverlapping (17, 69). When the enteric
5-HT3 and 5-HT2A receptors were later
identified, the 5-HT3 receptor was equated with the M
receptor, because it was neuronal, whereas the 5-HT2A
receptor was equated with the D, because it acts directly on intestinal
smooth muscle (4). It is now apparent, however, that
enteric 5-HT receptors do not fall neatly into nonoverlapping neuronal
(M) and muscular (D) categories. The 5-HT4 receptor is
expressed both by enteric neurons (14, 25, 62) and muscle
cells (51, 52, 70). We have previously demonstrated that
the 5-HT2B receptor is also expressed by enteric nerve and
muscle (18), and we now find that the prototypic D
receptor, the 5-HT2A (4, 17, 69), is even more
widespread in its enteric distribution and is expressed not just by
smooth muscle but also by epithelial cells and neurons.
5-HT2A immunoreactivity was observed in mucosal enterocytes
and Paneth cells, neurons in both the submucosal and myenteric plexuses, and in both circular and longitudinal muscle cells. The
location of 5-HT2A receptors on enterocytes probably
accounts for the ketanserin-sensitive ability of 5-HT to act directly
on the epithelium to induce Cl
secretion, increase
inositine trisphophate, and for the specific binding of
3H-ketanserin (3, 38, 41, 43, 74). 5-HT has
also been reported to increase the rate at which enterocyte precursors
proliferate (81). Because 5-HT2 receptors
stimulate proliferation when expressed in transfected fibroblasts
(44, 55), the enhancement of enterocyte proliferation by
5-HT may be mediated by a 5-HT2 receptor.
In contrast to epithelial cells, no physiological response in enteric
neurons has yet been demonstrated to be 5-HT2A-mediated. It
is conceivable that the response evoked in enteric neurons by
5-HT2A stimulation has not yet been revealed by the
electrophysiological or biochemical methods thus far employed. Species
differences in the enteric innervation may also be significant, and the
electrophysiological investigations that have been carried out have
been heavily biased toward the guinea pig. Certainly, the location of
5-HT2A receptors on the plasma membranes of axon terminals
and their concentration at synaptic junctions (Figs. 2, A
and B, and 3, D and E) is consistent with the possibility that 5-HT2A receptors evoke pre-
and/or postsynaptic effects; moreover, indirect pharmacological studies
have suggested that a receptor in the 5-HT2 family modifies
the release of ACh (35, 68) and other transmitters
(43) from enteric nerves. The distribution of
5-HT2A receptors on neuronal plasma membranes is thus
consistent with a 5-HT2A mediation of these
5-HT2-like actions. A 5-HT2A-mediated trophic
effect would be equally consistent and might not be detected by
measurements of membrane potential or current. The abundance of
5-HT2A immunoreactivity that is found intracellularly in
subsets of neuronal perikarya probably reflects the biosynthesis of the
receptors in the rough endoplasmic reticulum (Fig. 3, B and
C). The intracellular 5-HT2A
immunoreactivity observed in axons and in irregularly shaped vesicles
in varicosities is likely to reflect axonal transport of the receptors
from cell bodies to terminals (Figs. 2B and 3E).
The distribution of 5-HT2A receptors in caveolae on the
plasma membranes of smooth muscle cells (Fig. 2, E and
F) is shared with certain other receptors involved in cell
signaling (1, 72). Because the affinity of the
5-HT2A receptor for 5-HT is relatively low
(65), the concentration of 5-HT in caveolae by potocytosis
(1) may facilitate ligand-receptor interactions. The
abundance of 5-HT2A receptors on fibers in the deep muscle plexus (Fig. 4B) is consistent with a role in interactions
of enteric neurons with interstitial cells of Cajal, which are
concentrated in this region (71, 78, 79), intimately
associated with nerve fibers (78, 83), and thought to be
intermediaries in the cholinergic neural control of the circular muscle
(84).
Transgenic mice with a targeted deletion of the promoter region of the
5-HT2A receptor were investigated to gain insight into the
physiological role(s) played by these receptors by a loss-of-function analysis. 5-HT2A expression was confirmed to be lacking in
the colons of the 5-HT2A
/
animals, although minimal
5-HT2A expression was retained in their small intestine.
Conceivably, the 5-HT2A receptor is expressed to a slight
extent in the small intestine, because a limited tissue-specific
activation of the gene can occur in this site despite the deletion in
its promoter region. Although rendered detectable by the high
sensitivity of RT-PCR amplification, the extremely low level of
5-HT2A mRNA in the small intestine of 5-HT2A
/
mice may not be physiologically meaningful. The contraction of
colonic smooth muscle evoked in 5-HT2A +/+ mice by
exogenous 5-HT was lacking in 5-HT2A
/
animals,
although the 5-HT2A
/
colon contracted in response to
ACh, suggesting that failure to respond to 5-HT is due to the absence
of responding receptors. Because the 5-HT2A receptor is
expressed as early as E14, developmental, as well as physiological,
abnormalities might be expected to accompany an absence of
5-HT2A expression. Changes in the development of other
members of the 5-HT2 receptor family to compensate for the
lack of 5-HT2A expression, however, were not observed in
5-HT2A
/
mice. 5-HT2B expression in
5-HT2A
/
animals could not be distinguished from that
in their 5-HT2A +/+ littermates, and 5-HT2C
expression was detected in neither. No defects were seen in the
morphology or size of the 5-HT2A
/
ENS or in the
proportion of enteric neurons expressing an early developing (NOS-1)
(5) or a late-developing phenotype (CGRP) (66). In addition, the rates of gastrointestinal transit
and colorectal motility were not significantly different in
5-HT2A
/
mice and their 5-HT2A +/+
littermates. Although these are all relatively gross indices of enteric
structure and function, their normality in the 5-HT2A
/
mice suggests that the gut develops adequately and can function without
5-HT2A receptors.
The fact that the motility of 5-HT2A
/
bowel is good
enough to support the life of an unchallenged mouse is not surprising. Despite the abundance of this 5-HT receptor subtype in the gut, there
are no sources of endogenous 5-HT close to muscular 5-HT2A receptors. The function of these receptors, therefore, may be more
important in emergency or pathophysiological responses than in normal
motility. A difference in pathophysiological effects between
5-HT2A
/
and +/+ mice would probably require the
application of noxious stimuli for detection. In contrast, the
5-HT2A receptors on the basolateral surfaces of epithelial
cells would be expected to be exposed to the 5-HT constitutively
secreted by EC cells into the lamina propria. The absence of these
receptors is associated with significant decreases in the size of
enterocytes and the numbers of Paneth cells, suggesting that
5-HT2A receptors function in the development and/or
maintenance of end-stage epithelial cells generated in intestinal
crypts (75). Development of intestinal epithelial cells is
a continuous process that persists throughout life.
The 5-HT2A receptors on smooth muscle, like those of the
epithelium, may also have evolved a role in maintenance. Whereas the
number of cells did not appear to be different, both longitudinal and
circular layers of muscle were thinner in 5-HT2A
/
mice than in their 5-HT2A +/+ littermates; moreover, some smooth
muscle cells showed evidence of degenerative change in the
5-HT2A
/
animals that were not apparent in the
5-HT2A +/+ mice. Because 5-HT2A receptors are
present both on nerve and muscle, these observations do not establish
that muscular 5-HT2A receptors are necessary for the
long-term maintenance of the cells of the muscularis externa, although
it is plausible that they are. An alternative possibility is that the
innervation of the muscle coats trophically maintains muscle and
functions abnormally when 5-HT2A receptors are absent in
the ENS. Because 5-HT2A receptors are also located on
enteric nerves within villi (Fig. 5, D-F),
their absence from the intravillus nerves of 5-HT2A
/
mice might also indirectly affect trophic influences, if any, that
these nerves exert on their epithelial targets. Further study is needed
to identify the function of 5-HT2A receptors in the enteric
plexuses. Whether effects of 5-HT2A knockout are direct or
indirect, the current observations suggest that 5-HT and its
5-HT2A receptor are important for the maintenance and/or
development of smooth muscle and epithelial cells in the bowel. The
preservation of gross measures of motility despite the changes in the
musculature suggest that there is a safety factor within which
abnormalities in the intestinal musculature can be tolerated in animals
not pathologically challenged.
 |
ACKNOWLEDGEMENTS |
The authors thank Valerie Boone and Martha Bator for their expert
technical assistance and Wanda Setlik for her invaluable contribution
to the EM study.
 |
FOOTNOTES |
This work was supported by National Institute of Child Health and Human
Development Grant HD-35632 (to E. Fiorica-Howells) and National
Institute of Neurological Disorders and Stroke Grants NS-12969 and
NS-15547 (to M. D. Gershon). Confocal microscopy was supported by
National Institutes of Health Grants RR-10506 and CA-13696.
Address for reprint requests and other correspondence: E. Fiorica-Howells, Dept. of Anatomy and Cell Biology, Columbia
University, College of Physicians and Surgeons, 630 W. 168th St., New
York, NY 10032 (E-mail:
ef7{at}columbia.edu).
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.
First published January 9, 2002;10.1152/ajpgi.00435.2001
Received 11 October 2001; accepted in final form 7 January 2002.
 |
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