Nitric oxide modulates peristaltic muscle activity associated with fluid circulation in the sea pansy Renilla koellikeri
Département de sciences biologiques, Université de Montréal, Case postale 6128, Succ. Centre-Ville, Montréal, Québec, Canada H3C 3J7
* Author for correspondence (e-mail: michel.anctil{at}umontreal.ca)
Accepted 15 March 2005
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Summary |
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Key words: sea pansy, Cnidaria, peristalsis, muscle, nitric oxide (NO)
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Introduction |
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That NO is a phylogenetically ancient signalling molecule in multicellular
animals is documented by reports of the presence and activity of NO systems in
cnidarians, the most basal animals with nervous systems. NO has been
implicated in the regulation of cnidocyte discharge in the sea anemone
Aiptasia diaphana (Salleo et al.,
1996), in the feeding response of Hydra vulgaris to
chemosensory stimuli (Colasanti et al.,
1997
), and in the response to stress of Aiptasia pallida
(Trapido-Rosenthal et al.,
2001
). While Elofsson et al.
(1993
) found no evidence of
NOS activity in cnidarian neurons, NOS activity was detected by NADPH
diaphorase staining in unidentified cells of the ectoderm and endoderm of the
body wall of A. diaphana (Morrall
et al., 2000
). Only recently has NOS activity been demonstrated in
sensory neurons of the jellyfish Aglantha digitale in which NO was
reported to activate motoneurons and to upregulate swimming
(Moroz et al., 2004
).
While regulation of vascular tone was the first role for NO to be reported
in vertebrates (for a review, see
Cosentino and Lüscher,
1996), such a role was rarely identified in invertebrates. A
vasodilatatory role was reported in the cephalopod Sepia officinalis
(Schipp and Gebauer, 1999
),
and the only effect of NO that may present some analogy to vascular control in
another invertebrate is the relaxation of smooth muscles in the starfish
Asterias rubens (Elphick and
Melarange, 1998
; Melarange and
Elphick, 2003
). Although cnidarians are basically bilayered
(diploblastic) animals without separate circulatory and gastric organs, the
sea pansy Renilla koellikeri, an octocorallian of the sea pen family,
generates peristaltic contractions that are the driving force for the movement
of sea water through the gastrovascular cavity (coelenteron) of polyps and
into the colonial mass (Parker,
1920
). Sea water is pumped in through the pharynx of numerous
inhalent siphonozooids, circulates through gastrovascular cavities, reaches
the axial canal and is pushed out through the large exhalent siphonozooid
(Fig. 1). The gastrovascular
cavities of the colony are lined by musculo-epithelial cells in which smooth
muscle fibres are laid down largely in circular or longitudinal orientations,
and by gastric cells, which secrete enzymes that digest food particles flowing
by (Lyke, 1965
). Thus the
internal channels of the sea pansy combine gastric and circulatory roles,
thereby making this anthozoan an attractive model to investigate the
physiology of a primitive gastrovascular system.
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Regulatory activities of peristalsis in the sea pansy have previously been
investigated. Serotonin was reported to enhance peristaltic activity through
the mediation of cyclic AMP (Anctil,
1989). In contrast, melatonin sharply depressed peristalsis
through the mediation of cyclic GMP (Anctil
et al., 1991
). Peptides of the gonadotropin-releasing hormone
family also depressed peristalsis (Anctil,
2000
). Neurons were labelled by antibodies raised against these
putative transmitters (Umbriaco et al.,
1990
; Mechawar and Anctil,
1997
; Anctil,
2000
). In this study, we tested whether NO is a regulator of
peristalsis and muscle tone in the sea pansy by analogy to the role of NO in
modulating vascular tone in vertebrates and in cephalopods. To achieve this,
first, we recorded the effects of NO donors and NO-related drugs on
peristaltic contractions of reduced sea pansy preparations and on the
contractile state of intact animals. Second, we examined the distribution of
putative NOS activity in the tissues of the sea pansy by NADPH-diaphorase
histochemistry and citrulline immunohistochemistry. Preliminary results from
this work were presented at the sixth International Congress of Comparative
Physiology and Biochemistry (Anctil and
Poulain, 2003
).
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Materials and methods |
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Physiological and behavioural experiments
Peristaltic contractions were recorded from reduced preparations as
described by Anctil (1989) with
modifications. Polyp bearing triangular pieces of the colony mass were excised
consistently from the same area in each of the colonies used. Two cuts through
the entire thickness of the colonial mass were initiated from the median axial
canal proceeding to the left outer margin of the colony, thus resulting in a
triangular piece with the outer margin intact
(Fig. 1A). The outer margin of
the preparation was pinned on Sylgard coating (Dow Corning Canada,
Mississauga, ON, Canada) near the bottom of a 50-ml experimental bath, and the
wedge tip, opposite the outer margin (originating from the axial canal), was
attached with thread to a Grass FT-03C isometric force transducer (Astro-Med
Inc, Longueuil, Canada). The transducer signals were transmitted to a Grass
CP122 strain gauge amplifier that was interfaced with a Grass PolyView
analogue-to-digital converter and data acquisition system. The calibrated mass
values were converted to force units (Newtons). In a few experiments designed
to monitor the excitability of preparations, two 30G Grass platinum electrodes
were inserted into reduced preparations and were fed to a Grass S48 square
pulse stimulator (Astro-Med Inc.).
Because manipulations led to extremely contracted preparations, these were allowed to relax in the bath with fresh ASW for 30-90 min before experiments. Bath solutions were routinely maintained at 21-23°C. As the basal tension dropped, peristaltic waves began to appear and they reached relatively stable amplitudes when basal tension itself stabilised. Typically, experiments began by recording peristaltic activity for 30 min after adding a volume of solvent (filtered ASW alone or ASW with 1% dimethylsulfoxide) equal to that used later when adding drug solutions. Drugs were added and peristaltic activity was recorded for another 30 min. This was usually followed by a rapid and complete evacuation of the bath, which was then filled with fresh ASW. When the amplitude of peristaltic waves stabilized after washing, the same drug was added again at the same or a different concentration, or a putative antagonist drug was added, and peristaltic activity recorded for 30 min. When an antagonist drug was used, addition of the first drug followed the incubation with the antagonist, without washing for 30 min, then the bath contents were replaced with fresh ASW a second time. A period of 1 h after washing was allowed before the first drug was added a last time, and peristaltic activity was monitored to assess reversibility of drug effects. Amino-3-morpholinyl-1,2,3-oxadiazolium (SIN-1) chloride, aminoguanidine hydrochloride, 1H-(1,2,4)oxadiazolo(4,3-a)quinoxalin-1-one (ODQ) and Zaprinast were obtained from Tocris Cookson Inc. (Ellisville, Missouri, USA). All remaining drugs mentioned below were purchased from Sigma-Aldrich Canada (Oakville, Ontario, Canada) unless stated otherwise.
Although SIN-1 is known to generate superoxide ions as well as NO
(Feelisch et al., 1989;
Hogg et al., 1992
), we used
substantially lower concentrations of SIN-1 than those used to detect
superoxides (1-5 mmol l-1). In addition, the effects of SIN-1 on
our preparations were similar to those induced by
S-nitroso-N-acetylpenicillamine (SNAP), a NO donor that does not
generate superoxide ions (see Results).
Monitoring experimental conditions for 30 min each allowed the passage of five to eight peristaltic waves. From the data analysed with the Grass Polyview software, the amplitudes of the last three peristaltic contractions for each condition were averaged. The averaged value for each preparation exposed to the solvent (vehicle) was subtracted from that of the same preparation during drug exposure, and the differential was normalized as a percentage relative to the control value (vehicle). Hence data are represented as means ± standard error of change in peristaltic force relative to controls, where N is the number of separate experiments on different reduced preparations. Statistical significance between any two sets of data was evaluated by using the paired t-test or the Mann-Whitney test.
In addition to reduced preparations, whole colonies were used to record the effects of NO-related drugs on contractile behaviour. The colonies were placed individually in 140x75 mm crystallizing dishes filled with ASW maintained at 21-23°C and allowed to relax. Drugs were injected gently, under a dissecting microscope, with a syringe and a 26G needle into a gastrovascular channel on the left side of the biradial colony as shown in Fig. 1A. An identical volume of solvent was similarly injected in an opposite channel on the right side of the colony. Thus each colony served as its own control. Successful experiments resulted in long-lasting (>1 h) shape asymmetries of the two sides (see Results). Preliminary injections of Methylene Blue had shown that periods in excess of 40 min were needed for dye to visibly transfer from one side of the colony to the other.
NADPH-diaphorase histochemistry
Although immunohistochemistry with Universal NOS (uNOS) antibodies was
successful in higher invertebrates (Scholz
et al., 2002; Christie et al.,
2003
), its use (product no. PA1-039; Affinity BioReagents, Golden,
CO, USA) in the sea pansy at a dilution of 1:100 and incubation time of 48 h
gave no result. This may be due to a lack of significant homology between
vertebrate and cnidarian NOS isoforms. Therefore, fixative-resistant
NADPH-diaphorase (NADPH-d) activity was used instead, as a marker for NOS
activity.
The NADPH-d histochemical method of Moroz et al.
(2004) was applied as follows.
The distal segment (anthocodium) of autozooid (feeding) polyps was excised
from colonies, some of which were anaesthesized in a 1:1 mixture of 0.37 mol
l-1 MgCl2 and ASW and the anaesthetics rinsed off before
further processing. In addition, mesenteries were dissected and removed from
inside the colonial mass (rachis). The tissues were fixed in 4%
paraformaldehyde in ASW (pH 7.8) for 30 min at room temperature. They were
rinsed 3x10 min in 0.5 mol l-1 Tris-HCl (pH 8). Staining took
place in a solution containing 1 mmol l-1 ß-NADPH, 0.5 mmol
l-1 nitro blue tetrazolium, 0.3% Triton X-100 and 0.5 mol
l-1 Tris-HCl. The incubation lasted 90 min in the dark at room
temperature, followed by three rinses of 10 min each in 0.5 mol l-1
Tris-HCl. Tissues were post-fixed in 4% paraformaldehyde in 50% methanol for
30-60 min, followed by dehydration in two changes of ethanol of 15 min each.
Tissues were cleared in xylene and mounted in Permount (Fisher
Scientific).
Controls were performed by substituting ß-NADH or ß-NADP+ for ß-NADPH at the same concentration. Additionally, diphenyleneiodonium, a selective inhibitor of specific NADPH-dependent activity, was used at a concentration of 0.1 mmol l-1.
Citrulline immunohistochemistry
As another alternative approach to the localization of NOS, an
anti-citrulline antibody was used. Citrulline is a by-product of NO formation
from arginine and therefore citrulline production is considered a reliable
indicator of NOS enzymatic activity
(Eliasson et al., 1997;
Scholz et al., 2001
).
For sectioned preparations, the colonial mass was rapidly cut into slices
5 mm thick that were oriented parallel to the biradial axis of the rachis
(see Fig. 1A). The slices were
immersed for 2 h at 4°C in a mixture of 2% paraformaldehyde and 2%
glutaraldehyde in 0.1 mol l-1 phosphate buffer (PB). The slices
were washed 3x 15 min in phosphate buffered saline (PBS; 2.4% NaCl added
to PB), then transferred to 15% and 30% sucrose in PBS for 30 min each. The
slices were placed in Tissue-Tek OCT, frozen in dry ice-chilled isopentane and
sectioned at 16 mm with a Leica CM 3050 cryotome (Leica Microsystems,
Dollard-des-Ormeaux, Quebec, Canada). Sections were placed on
gelatin-chromalum-coated slides and frozen at -20°C until processed.
Sections were washed 3x 15 min in PBS containing 0.2% Triton X-100 (PBST), followed by 10 min in PBS containing 1% H2O2 to inactivate endogenous peroxidases. After another rinse in PBST the sections were transferred to a diluted (1:1000 in PBST) solution of a polyclonal antibody raised in rabbit against a citrulline-glutaraldehyde-BSA complex (AB5612, Chemicon International, Temecula, CA, USA). Sections were incubated overnight in the primary antibody at 4°C. They were washed again repeatedly and processed with the BioStain Super ABC/peroxidase rabbit IgG detection kit according to the manufacturer's instructions (Biomeda, Foster City, CA, USA). After repeated washes in PBS, section staining was completed with 0.06% 3,3'-diaminobenzidine in PBS intensified with 0.025% cobalt chloride and 0.02% nickel ammonium sulphate. Sections were immersed first in DAB alone for 10 min, followed by DAB with 0.01% H2O2 for another 10 min. After a 15 min wash in PBS the sections were mounted in a glycerol-PBS mixture and stored at -20°C until examined.
For whole mounts, tissues were excised from colonies as described in the preceding section. Tissue processing followed the procedure for sections except that PBST contained 0.4% Triton X-100 and that the duration of washes was doubled. In all experiments preparations in which the primary antibody step was omitted served as controls. In addition, some preparations were treated with the NOS inhibitor 7-nitroindazole, at 0.1 mmol l-1 for 3-6 h before fixation and citrulline immunohistochemistry. The latter control revealed non-specific diffuse staining throughout the tissues and in some cells of the mesenteries, but otherwise the staining abolished by 7-nitroindazole was consistent with specific NADPH-d staining (see Results).
Microscopy and image treatment
Whole-mounts and sections were viewed with a Wild-Leitz Laborlux S
trinocular microscope and photographed with a Nikon Coolpix 4500 digital
camera. Images were cropped and contrasted with Adobe Photoshop. Colour
enhancement was also applied for some images (Figs
8A-D,
9A,C).
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Results |
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Injection of NO donors into the gastrovascular cavities of the colonial mass of five intact colonies in a relaxed state consistently induced a contracted state that occurred after 3-6 min and lasted for at least 1 h (Fig. 3B). During that period, the response was confined to the half of the biradial colony where the injection occurred. The other half, injected with the vehicle alone, remained in a relaxed state (Fig. 3B). Both halves of the colony displayed peristalsis during this procedure. In contrast, injecting four colonies in a fully contracted state with NO donors consistently caused a relaxation of the half colony where injection occurred, while the half injected with the vehicle remained contracted (Fig. 3C). In addition, the contractile responses of reduced preparations to electrical stimulation were decreased by the NO donor SNAP (Fig. 2B). The amplitude, duration and relaxation phase of these responses were diminished by the NO donor in a reversible manner. Because peristaltic activity was undetectable in fully contracted colonies and recordings of reduced preparations show a sharp drop of peristaltic contraction amplitude after electrically induced contractions (Fig. 2B), relaxing effects of NO donors on peristalsis were not investigated.
Effects of NOS inhibitors
The competitive NOS inhibitor L-NAME (N()-nitro-L-arginine methyl
ester) decreased the amplitude of peristaltic contractions and substantially
lowered basal tension in a dose-dependent manner
(Fig. 4,
Fig. 5A). The effect of 0.1
mmol l-1 L-NAME on peristalsis was entirely reversible over a
period of 1 h following washout, but basal tension did not return to control
levels during that period. The stereospecific isomer D-NAME had no significant
effect on these activities (Fig.
5A). Another NOS inhibitor, 7-nitroindazole, had an effect similar
to that of L-NAME (not shown). In contrast, aminoguanidine, a selective
inhibitor of inducible NOS (iNOS)
(Griffiths et al., 1993
;
Joly et al., 1994
), increased
considerably the amplitude of peristaltic contractions without affecting basal
tension (Fig. 4). This effect
was dose-dependent (Figs 4,
5A) and reversible 35-45 min
after washout.
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Injection of 1 mmol l-1 L-NAME induced a relaxed state in four of six contracted intact colonies tested, whereas the site of injection of the solvent vehicle remained contracted (Fig. 5B). The effect appeared 5-8 min after injection and began to wane 50-70 min after injection. In contrast, injection of 1 mmol l-1 aminoguanidine led to a contracted state within 6-10 min after injection in all six relaxed colonies tested (Fig. 5C). This effect vanished 30-40 min after washout. While peristalsis was observed in all the colonies tested with either NOS inhibitor, it was more robust in aminoguanidine-treated colonies.
To test whether the potentiating effect of serotonin on the amplitude of
peristaltic contractions of reduced preparations
(Anctil, 1989) could be
mediated by NO, the NOS inhibitor L-NAME was added to the bath and the
response to serotonin (5-hydroxytryptamine creatinine sulphate) recorded 30
min later. Serotonin at 10 mmol l-1 caused a 75% increase in the
amplitude of the contractions, and this increase was reduced to near 20% in
the presence of 0.1 mmol l-1 L-NAME
(Fig. 5A). Similarly, the
ability of aminoguanidine to interfere with the inhibitory effect of melatonin
on peristaltic contractions (Anctil et al.,
1991
) was tested. Melatonin, at 10 mmol l-1, reduced
the amplitude of the contractions by more than 60%, and this reduction was not
significantly changed in the presence of 1 mmol l-1 aminoguanidine
(Fig. 5A). In contrast,
aminoguanidine not only eliminated the inhibiting effect of mammalian GnRH
(gonadotropin-releasing hormone), which, similarly to GnRH-like sea pansy
factors, reduces peristalsis (Anctil,
2000
), but also reversed the response to produce a potentiating
effect on peristalsis (Fig.
5A).
Effects of inhibitors of soluble guanylyl cyclase and cGMP-specific phosphodiesterase
ODQ (at 0.1 mmol l-1), a specific blocker of NO-dependent
guanylyl cyclase, rapidly increased the amplitude of peristaltic contractions
by 65% in reduced preparations (Fig.
6, Fig. 7A). In the
presence of 0.1 mmol l-1 SNAP, ODQ at the same concentration
increased this amplitude by a further 20%, although the difference is not
significant (P>0.01, paired t-test). The inhibiting
effect of melatonin, via cyclic guanosine monophosphate (cGMP), on peristalsis
was previously reported (Anctil et al.,
1991). In the present study, melatonin at 10 mmol l-1
reduced the amplitude of contractions by 60%, and this reduction was halved in
the presence of 0.1 mmol l-1 ODQ (Fig.
7A). Zaprinast, a selective inhibitor of cGMP-specific
phosphodiesterase, reduced the amplitude of peristaltic contractions and the
addition of dibutyryl cGMP (db cGMP) further reduced this amplitude
(Fig. 6,
Fig. 7A). This response was
accompanied by a slight drop in the basal tension. The response to both
zaprinast and db cGMP appeared 6-7 min after exposure and was fully reversible
after washout. Similarly, IBMX, which appears to act as a selective cGMP
phosphodiesterase inhibitor in the sea pansy
(Anctil et al., 1991
), sharply
reduced the amplitude of peristaltic waves beyond the level of reduction
achieved with zaprinast (Fig.
7A).
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Injection of 0.1 mmol l-1 ODQ into six intact colonies consistently induced a contracted state and strong peristalsis compared to the control side of the colonies (Fig. 7B). In contrast, 0.1 mmol l-1 zaprinast, injected in the left half of five intact colonies, consistently relaxed that half and reduced its peristalsis, whereas the control right half was more contracted and underwent strong peristalsis (Fig. 7C).
Distribution of putative NOS-containing cells
The sea pansy is a colony of polyps: the autozooids are the feeding and
reproductive polyps, and the siphonozooids control the intake and exit of
water (Fig. 1). The part of the
authozooids that emerges above the colonial mass, the anthocodium, includes
the upper body column, the tentacles and mouth (oral disc). Histochemical
staining of NADPH-d was localized throughout the anthocodium. In addition,
staining was observed in endodermal muscles of the autozooid parts buried
inside the colonial mass (zooecium) and in the perinuclear region of oocytes.
No staining was detected in preparations in which ß-NADPH was replaced by
ß-NADH or ß-NADP+, and staining was abolished in preparations
exposed to diphenyleneiodonium except for oocytes where staining remained.
Staining was prominent in the oral disc
(Fig. 8A) and at the base of
tentacles of autozooids (Fig.
8B). Staining was also present in small cells (4-6 µm)
aggregated at the edge of the oral disc and a few other cells scattered over
the surface of the oral disc where there is also a dense meshwork of fine
neurites (Fig. 8C). Although
processes emerge from these cells, the relationship of the latter to the
neurite meshwork could not be ascertained. In tentacles, many stained neurites
run alongside each other from the tentacle base to the tentacle tip both on
the oral and aboral sides. The fine processes are varicose and intertwine with
each other (Fig. 8D). The
neurites on the aboral side of tentacles extend into the upper body column
where they merge with neurites from the neighbouring tentacle to form a local
nerve-net (Fig. 8B,D). The
somata of the tentacle cells are localized at the base of the ectodermal
epithelium (Fig. 8E,F) where a
basiectodermal nerve-net is located (Lyke,
1965; Fautin and Mariscal,
1991
). Neurites from the oral side of tentacles extend into the
oral disc (Fig. 8F). The
stained tentacle cell somata are small (4-6 µm) and bear an apical process
typical of cnidarian neurosensory cells
(Fig. 8G). Because of their
basiectodermal position, they possess a short process that bifurcates within
the neurite meshwork near the ectoderm-mesoglea interface
(Fig. 8F) where an ectodermal
muscle layer is located (Lyke,
1965
; Fautin and Mariscal,
1991
). The cell somata in the oral disc have a similar morphology
except that the presence of an apical process could not be clearly
ascertained.
The distribution of 7-nitroindazole-sensitive citrulline immunostaining was similar to that of NADPH-d staining. In particular, immunostained cells were present in the same location at the base of tentacles (Fig. 9A) as for the NADPH-d reactive cells (Fig. 8E). In cross-sections of the tentacles, the immunostaining was concentrated at the base of the ectoderm and in the endoderm just across from the mesoglea (Fig. 9B).
Fig. 8E shows a bundle of NADPH-d stained neurites running from cell somata at the base of a tentacle downward to the body column. In autozooid polyps the body column possesses eight radial septa that compartmentalize eight gastrovascular cavities between the outer wall and the central pharynx. These cavities line up with the cavity of each of the eight tentacles above them. The stained neurite bundles were localized at the interface of each septum with the outer wall (Fig. 9C,D). All these cavities are covered by endodermal epithelia in which musculo-epithelial cells are present. In the outer wall endoderm these cells form circular muscle sheets that consistently display NADPH-d staining (Fig. 9D). Citrulline immunostaining was also found in this circular musculature, both in the muscle feet of the myoepithelial cells themselves and in multipolar neurons that send processes to these feet (Fig. 9E). These endodermal neurons do not appear to be interconnected. Occasionally NADPH-d staining was also present in the muscular septa where muscle fibre orientation differs from that of the circular musculature (Fig. 9D). A similar localization of citrulline immunostaining was observed. In sectioned material of zooecia, which contribute the bulk of endodermal muscles involved in transcolonial peristaltic activity, citrulline immunostaining was detected in both septal muscles (longitudinal and radial), as well as in the circular muscle of the outer wall (Fig. 9F). However, it was not possible to ascertain whether staining was present inside the musculo-epithelial cells because of the interfering presence of neurites over the muscle elements.
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Discussion |
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In addition, the pharmacological data with NOS inhibitors suggest that NO
is endogenously generated and that two distinct nitrergic pathways may be
involved. The reduction of the amplitude of peristaltic contractions and of
basal tension levels by L-NAME and 7-nitroindazole is consistent with the
stimulatory effects of NO donors on these activities. In contrast, the
potentiating effect of a selective inhibitor of iNOS, aminoguanidine, on the
amplitude of peristaltic contractions appears to be inconsistent with these
effects. Interestingly, the induction of a contracted state in intact colonies
by aminoguanidine is the opposite of the relaxing effect of NO donors on the
initially contracted colony. This suggests that two NOS isoforms exist in the
sea pansy, one of which may be a NOS involved in a pathway leading to a
positive modulation of peristalsis and basal tension, and the other could be a
iNOS associated with general muscle relaxation and negative modulation of
peristalsis. Although this hypothesis must be validated by the
characterization of NOS forms in the sea pansy, the recent cloning of an iNOS
isoform in another anthozoan, the corallimorph Discosoma (Panchin,
Sadreyev and Moroz, personal communication in
Moroz et al., 2004), makes it
plausible.
The possibility that iNOS-like activity in the sea pansy is involved in
regulating peristalsis raises interesting physiological issues. This form of
NOS commonly shows negligible activity unless induced by agents such as
cytokines and bacterial endotoxins that set in motion defence mechanisms
against pathogens (Griffin and Stuehr,
1995; Moroz,
2001
). The consistent effect of aminoguanidine on peristalsis
suggests a similar role of iNOS in the sea pansy, and points to the existence
of dual NOS synthetic pathways (constitutive versus inducible) as in
vertebrates. However, only constitutive, neuronal forms of NOS have been
reported so far in other invertebrates
(Moroz, 2001
).
Interactions of NO with other transmitters
Because the indoleamines serotonin and melatonin were reported to modulate
the peristalsis of the sea pansy in opposite manners
(Anctil, 1989;
Anctil et al., 1991
), the
possibility arose that the effects of NO on peristalsis are either mediated by
the indoleamines or constitute the mediation event for the responses to
indoleamines. The sharp diminution of the potentiating effect of serotonin on
peristalsis by L-NAME (Fig. 5A)
suggests that NO mediates the serotonin response. Conversely, the serotonin
antagonist 1-(1-naphthyl)piperazine, known to be an effective and specific
blocker of the serotonin response (Anctil,
1989
), slightly reduced the potentiating effect of the NO donor
SNAP on peristalsis (Fig. 3A), thus making it unlikely that serotonin has a major role in mediating the NO
response.
Because the effect of aminoguanidine on peristalsis suggested the presence of an inhibitory nitrergic pathway, the effect of this iNOS blocker on the peristalsis-reducing response to melatonin was investigated. Aminoguanidine was unable to counteract the melatonin response (Fig. 5A), thus suggesting that NO is unlikely to mediate the melatonin response. However, melatonin appears to have prevented aminoguanidine from producing its potentiating effect on peristalsis, thus pointing to a pathway in which melatonin signalling would be downstream from iNOS-linked nitrergic signalling. In contrast, aminoguanidine was able to reverse the GnRH effect (Fig. 5A), but the reversal is partial and the amplitude of the GnRH response accounts for the difference between the partial reversal in the presence of aminoguanidine and the full potentiating response to aminoguanidine alone. Therefore it is likely that the inhibitory nitrergic and GnRH signalling pathways are independently activated.
Transduction of nitrergic signalling
NO action is usually mediated by the second messenger cGMP generated by the
catalytic activity of a soluble form of guanylyl cyclase
(Murad, 1996). A previous
study showed that membrane-permeable analogues of cGMP mimicked melatonin in
sharply reducing the amplitude of peristaltic waves of the sea pansy
(Anctil et al., 1991
).
Therefore it is not surprising that the data presented here suggest that the
nitrergic pathway associated with reduction of peristalsis is mediated by
cGMP. This is supported by the potentiating effect of the inhibitor of soluble
guanylyl cyclase ODQ on peristalsis (Fig.
7A). This potentiating effect suggests that removal of cGMP from
the tissues not only eliminates the inhibitory effect on peristalsis, but
somehow also activates a potentiating pathway, possibly via cAMP, which
potentiates peristalsis and has its levels raised by cGMP-lowering agents
(Anctil, 1989
;
Anctil et al., 1991
). As NO
enhances peristalsis, it is not surprising that it has an additive effect to
that of ODQ (Fig. 7A). In
addition, the reduction of the melatonin response by half in the presence of
ODQ also alludes to some form of interaction between melatonin and nitrergic
signalling in inducing cGMP transduction.
The data suggest that two distinct forms of phosphodiesterase responsible
for hydrolysing cGMP exist in the sea pansy. While zaprinast, a known
selective inhibitor of cGMP phosphodiesterase (PDE5), decreased the amplitude
of peristaltic waves by 30%, adding IBMX, an inhibitor of cAMP
phosphodiesterase, had a greater, additive effect that almost obliterated
peristalsis. As adding dibutyryl cGMP consecutively to zaprinast has nearly
the same additive effect as IBMX, it is likely that IBMX acts by raising cGMP
levels in the tissues. Anctil et al.
(1991) have reported that in
the sea pansy IBMX raises cGMP levels significantly while depressing cAMP
levels. Although the functional significance of this finding is not yet clear
and sea pansy phosphodiesterases remain to be characterized, the data point to
the coexistence of zaprinast-sensitive and IBMX-sensitive phosphodiesterases,
possibly having distinct functional roles. The existence of multiple isoforms
of cGMP phosphodiesterase serving different roles in mammalian vascular smooth
muscle is well documented (Beavo,
1995
; Rybalkin et al.,
2003
).
Histochemistry of putative NOS-containing cells
The effects of NO donors and of NOS inhibitors on peristalsis indicated
that NOS should be associated with endodermal muscles which cover the
gastrovascular cavities and participate in peristalsis as well as in setting
basal tension of polyps and colonial mass. Although both NADPH-d activity and
citrulline immunostaining were located in these muscles, considerable staining
was also present in basiectodermal neurons at the base of tentacles and in the
oral disc of autozooid polyps. Staining specificity was ascertained by
verifying that the NADPH-dependent NOS inhibitor diphenyleneiodonium abolished
NADPH-d staining and that the NOS inhibitor 7-nitroindazole abolished
citrulline immunostaining. Because there is no available NOS antibody that
reacts with cnidarian tissues, NADPH-d staining has proved to be a reliable
marker for multiple isoforms of NOS activity, and the case for its use with
cnidarians has been persuasively made
(Morrall et al., 2000;
Moroz et al., 2004
). Although
this is the first report of citrulline immunoreactivity in a cnidarian, it is
also considered a reliable marker of NOS activity in as much as controls
include specific NOS inhibitors because of other potential metabolic sources
of citrulline such as the urea cycle
(Keilhoff and Wolf, 2003
). The
similar localization of these two different markers in sea pansy tissues is
unlikely to be merely coincidental, which also argues for staining
specificity. In the following analysis no distinction will be drawn between
the two types of staining unless otherwise indicated.
The distribution of stained cells at the base of tentacles and in the oral
disc, and of their accompanying neurites forming a nerve net, resembles the
arrangement of the nitrergic neurosensory system described in the tentacles
and bell margin of the jellyfish Aglantha digitale
(Moroz et al., 2004). As in
A. digitale, the stained cell somata of the sea pansy are located in
the ectoderm, their neurites run up the tentacles and connect from the aboral
to the oral side. However, the stained sea pansy neurons differ from those of
A. digitale in that the cell somata are restricted to the base of
tentacles and in the oral disc, and only their neurites run up to the distal
tip of the tentacles. In addition, contrary to A. digitale, the
stained cell somata are embedded at the base of the ectoderm, away from the
external surface. Nevertheless, the association of NOS with the nervous system
of an anthozoan as well as a hydrozoan indicates that nitrergic neurons with
conserved distributions are a general feature of cnidarians.
A departure of importance from the nitrergic system of A. digitale
is the localization of staining in the endoderm. In sea pansy whole-mount
preparations, tracts of neurites were observed to run from the ectoderm across
the mesoglea and into the endoderm of either tentacles or column of polyps.
The presence of staining in the ectoderm and endoderm immediately adjacent to
the mesoglea in cross sections of tentacles is consistent with this
observation and with a similar distribution of NADPH-d staining in the column
of the sea anemone Aiptasia pallida
(Morrall et al., 2000). Thus,
even though the endodermal muscles may lie within the range of action of NO
released from the ectoderm across the thin mesoglea, according to calculations
by Moroz et al. (2004
), the
possibility exists for NO to be released into endodermal muscles from local
neurites. Moreover, the observation of citrulline-immunoreactive multipolar
neurons in endodermal muscle sheets of the anthocodium and zooecium, with
short neurites extending to muscle feet, suggests the existence of a second,
entirely endodermal, neuromuscular nitrergic system in the sea pansy.
Assuming that the stained tentacle cells of the sea pansy are sensory,
their deep location in the ectodermal epithelium would suggest that only a
proprioceptive function is available to them. If so, one role of these
nitrergic neurons could be to detect distortion from moving internal fluids by
way of stretch receptors and to transmit output signals to other neurons or
musculo-epithelial cells thereby directly adjusting muscle tension levels and
peristalsis. This postulated mechanism has some analogy with the shearing
forces acting on the luminal surface of mammalian vascular endothelium to
regulate the release of NO (Buga et al.,
1991; Smiesko et al.,
1989
). The location of these neurons in the tentacles and oral
disc also suggest a role in feeding, but preliminary experiments with NO
donors and NOS inhibitors failed to affect the posture of tentacles or mouth
opening. Also, the photocytes responsible for the sea pansy's bioluminescence
are located in the endoderm just across the mesoglea from the stained neurons
at the base of the tentacles. However, in our hands, NO donors had neither
inducing effect on bioluminescence nor modulatory effect on electrically
stimulated bioluminescence. Because the neurites of the tentacle cells do not
appear to reach the lower part of the anthocodium and the zooecium where the
bulk of muscles participating in peristalsis are located, the local endodermal
multipolar neurons there could play a proprioceptive and modulatory role in
colony-wide modulation of peristalsis and contracted state.
Functional significance
The data point to a complex involvement of NO signalling in setting basal
muscle tension and peristaltic force in the sea pansy in response to putative
interoceptive inputs. This could be achieved through two distinct nitrergic
pathways, one responsible for muscle relaxation and lowered peristaltic force
involving iNOS and soluble guanylyl cyclase, and the other associated with
elevation of basal muscle tension and peristaltic force via another NOS
isoform and possibly cAMP. The experimental evidence presented here indicates
that these putative pathways do interact with indolaminergic transmitters,
serotonin and melatonin, which themselves display opposite actions on
peristaltic force. Ectodermal serotoninergic and melatoninergic neurons are
distributed throughout the tentacles and column of the autozooid polyps and
they possess long neurites like those of the putative nitrergic neurons
(Umbriaco et al., 1990;
Mechawar and Anctil, 1997
), so
the possibility exists of physical contacts between these three sets of
neurons. The indolaminergic neurons differ from the putative nitrergic neurons
in that the apical process of their somata reaches the external surface of the
ectoderm. The serotoninergic neurons seem to detect the speed of water flow
over the ectoderm surface and to mediate a peristalsis-adjusting response
(Anctil, 1989
;
Umbriaco et al., 1990
). Thus
indolaminergic and nitrergic neurons may respond to different sensory
modalities (exteroceptive and interoceptive, respectively) but interact with
each other to modulate peristaltic force. The precise nature of these
interactions and how they compare with the mammalian vascular model, in which
sympathetic nerve stimulation causing vasoconstriction-derived shear leads to
NO release and NO-mediated inhibition of norepinephrine release
(Macedo and Lautt, 1996
), need
to be examined.
It is assumed that the two hypothesized nitrergic pathways in the sea
pansy, each involving its own NOS isoform, would be present in different cell
types, in accordance with the mammalian vascular model in which constitutive
NOS is detected in endothelial cells and inducible NOS in smooth muscle cells
(Cosentino and Lüscher,
1996). This cannot be demonstrated at this time because of the
lack of reactivity of mammalian NOS antibodies with cnidarian NOS-like
proteins. Nevertheless, the presence of NADPH-d and citrulline staining in
ectodermal neurons forming a nerve-net strongly suggests the involvement of a
neuronal form of constitutive NOS in these cells. Deriving the cellular origin
of the putative iNOS is less straightforward, but endodermal
musculo-epithelial cells are possible candidates even though it proved
difficult to distinguish neuronal from musculo-epithelial staining in this
layer. Because muscle oxidative enzyme activity unrelated to NOS may be
revealed by NADPH-d staining (Planitzer et
al., 2000
), part of the NADPH-d (but not citrulline) staining
appearing in sea pansy musculo-epithelial cells may not reflect the presence
of NOS. Although much remains to be resolved at the cellular level, the
present data point to the existence of two nitrergic pathways with distinct
locations in the tissue layers of the sea pansy.
This study has demonstrated that NO can modulate two physiological
parameters, basal tension and peristalsis, that affect the movement of fluid
and food particles in the coelenteron of the sea pansy. The analogy with the
NO-mediated modulation of vascular tone
(Cosentino and Lüscher,
1996) and of peristalsis (Anand
and Paterson, 1994
) in mammals suggests that these physiological
roles of NO were conserved throughout the evolution of metazoans. While other
roles of NO were proposed for cnidarians, such as in the feeding behaviour of
Hydra (Colasanti et al.,
1997
), the nematocyst discharge of a sea anemone
(Salleo et al., 1996
) and the
swimming behaviour of a jellyfish (Moroz
et al., 2004
), this is the first report of NO involvement in
cnidarian activities related to internal fluid movement.
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