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First published online September 19, 2006
Journal of Experimental Biology 209, 3862-3872 (2006)
Published by The Company of Biologists 2006
doi: 10.1242/jeb.02425
Identification and developmental expression of mRNAs encoding crustacean cardioactive peptide (CCAP) in decapod crustaceans
1 Center of Marine Biotechnology, University of Maryland Biotechnology
Institute, Baltimore, MD 21202, USA,
2 School of Biological Sciences, University of Wales, Bangor, Gwynedd LL57
2UW, Wales, UK
3 Department of Zoology, Stockholm University, Svante Arrhenius väg 14,
S-106 Stockholm, Sweden
* Author for correspondence (e-mail: s.g.webster{at}bangor.ac.uk)
Accepted 3 July 2006
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Key words: crustacean cardioactive peptide, mRNA sequence, development, expression, decapod crustacean
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Introduction |
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TOPSummaryIntroductionMaterials and methodsResultsDiscussionReferences |
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).
It produces potent chronotropic effects on semi-isolated heart preparations,
in contrast to proctolin, which exhibits mainly inotropic effects
(Stangier, 1991).
Additionally, CCAP is involved in modulation of stomatogastric ganglion motor
patterns in crustaceans (Weimann et al.,
1997; Richards and Marder,
2000). CCAP has been identified in many arthropods, revealing
highly conserved neural networks (Dircksen,
1998), and related molecules may exist in other phyla, such as
urechoid worms and molluscs (Ikeda et al.,
1991; Minakata et al.,
1993; Muneoka et al.,
1994; Hernadi and Agricola,
2000; Vehovsky et al., 2005).
The role of CCAP in insects has been an area of particular interest since
CCAP has several identified functions apart from its first defined biological
activity - cardioacceleration (Tublitz and
Truman, 1985a; Tublitz and
Truman, 1985b; Tublitz and
Evans, 1986; Cheung et al.,
1992). These include modulation of hindgut activity involved in
gut emptying during metamorphosis (Tublitz
et al., 1992), increasing blood circulation during wing inflation
(Tublitz and Truman, 1985b),
modulation of oviduct contractions in Manduca sexta
(Marshall and Reynolds, 1998)
and Locusta migratoria (Donini et
al., 2001; Donini and Lange,
2002) and a secretagogue action in induction of release of
adipokinetic hormone from the corpora cardiaca in L. migratoria
(Veelaert et al., 1997).
However, one of the most significant actions of CCAP in insects concerns its
role in the proximal triggering of ecdysis
(Gammie and Truman, 1997).
Specifically, targeted ablation of CCAP-expressing neurones in
Drosophila leads to severe defects in execution of pupal ecdysis and
abnormal gating of circadian eclosion rhythms
(Park et al., 2003), but
intriguingly only some disruption to larval ecdysis behaviour
(Clark et al., 2004). CCAP
knockouts are also defective in wing expansion and cuticle tanning following
eclosion (Dewey et al.,
2004).
Although evidence is now accumulating to suggest that CCAP is a critical
neurohormone during insect ecdysis, much less is known for crustaceans, which
are genetically intractable. In crayfish and crabs a very dramatic increase in
CCAP synthesis and release during moulting has been observed over a precise
temporal scale (Phlippen et al.,
2000), which may point to fundamental, and probably analogous,
roles of this peptide to that in insects during ecdysis. One way in which we
might address the role of CCAP in crustacean moulting and development in the
near future, given the intractability of crustaceans to contemporary molecular
approaches, would be to use knock-down techniques such as RNA interference
(RNAi). Although genomic and cDNA sequences for CCAP are known in some
insects, for example Drosophila
(Park et al., 2003),
Manduca sexta (Loi et al.,
2001) and Periplaneta americana
(Sakai et al., 2004), no
comparable information is available for crustaceans. Thus, to begin to address
this issue we have cloned and sequenced full-length cDNAs from a variety of
brachyuran and astacuran decapods. We have used quantitative molecular
approaches (quantitative reverse transcription-polymerase chain reaction,
qRT-PCR) to measure CCAP gene expression during development and the moult
cycle. Secondly, we have coupled a description of developmental expression of
CCAP peptide in the embryonic CNS to that of the cognate mRNA to further
elucidate the role of CCAP in development in crustaceans. Finally, we have
measured CCAP gene expression following exposure to environmentally relevant
stressors (severe hypoxia, thermal stress) that might be proposed to relate to
cardiac output.
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Materials and methods |
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, 22°C) under ambient photoperiod, and were fed daily
with chopped squid. Adult C. sapidus were obtained from the
Chesapeake Bay (MD, USA) by local fishermen. Green shore crabs, Carcinus
maenas (Linnaeus) and lobsters, Homarus gammarus (Linnaeus) were
collected using baited traps (Anglesey, UK), and were maintained in a
recirculating seawater system, under ambient conditions of photoperiod and
temperature, with ad libitum feeding of fish and squid. Specimens of
Calico crayfish, Orconectes immunis (Hagen), were collected from
lakes in Jones Falls, Baltimore MD, USA.
Nervous systems (eyestalk, brain and thoracic ganglia) were dissected from
ice-anaesthetised, moult-staged animals and immediately placed in RNAlater
(Ambion, Austin, TX, USA), (4°C overnight) and stored at -80°C.
Additionally, batches of 100 developmentally staged embryos
(Chung and Webster, 2004) were
taken from ovigerous Carcinus maenas. Total RNA was prepared using
TRIzol (Invitrogen, Carlsbad, CA, USA), and samples were subsequently treated
with 2 i.u. DNase I (37°C, 1 h) followed by clean up on DNA-free (Ambion).
For embryo samples, mRNA was subsequently isolated using Dynabeads (Dynal,
Oslo, Norway), and stored at -80°C in 10 mmol l-1 Tris (10
embryo equivalents µl-1).
For experiments on Callinectes involving anoxic and thermal
stress, crabs were either exposed to reduced O2 (0.5%) for 1 h, by
continuous nitrogen sparging (monitored using a dissolved oxygen meter; YSI,
Yellow Springs, OH, USA), or given thermal challenge for 2 h (from 22°C to
4°C or from 22°C to 29°C); controls remained at 22°C. All
experiments were performed in 15 seawater. Following these
experiments, eyestalk and thoracic ganglia were rapidly dissected from
ice-anaesthetised crabs, and immediately frozen on dry ice, prior to storage
(-80°C). Subsequent RNA extractions were as detailed above.
cDNA synthesis and rapid amplification of cDNA ends
1-2 µg samples of total RNA were reverse transcribed using AMV-RT
(Promega, Madison, WI, USA) or Superscript III (Invitrogen) (42°C, 1 h).
For 3' rapid amplification of cDNA ends (RACE) cDNA, reactions were
primed with Gene Racer 3' oligo(dT) adaptor primer (Invitrogen). RNA was
subsequently removed by incubation (37°C, 1 h) with 2 i.u. RNase H. For
5' RACE cDNA, 1 µg RNA was ligated to a 5' RACE adapter primer
(Invitrogen) according to the manufacturer's instructions, and reverse
transcribed using random primers.
3' RACE was performed using PCR with nested primers. Reverse primers were as supplied by the manufacturer (Invitrogen) and forward degenerate nested primers (dF1, dF2, dF3; Table 1) were designed from the sequence of CCAP, and C-terminal amidation and cleavage sites.
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3' RACE PCR of Carcinus and Homarus cDNAs
For the first PCR, conditions were: 1 µl 10 mmol l-1 dNTPs,
5'l 10 amplification buffer, 2 µl 50 mmol l-1
MgSO4, 4.25 µl 3' Gene Racer primer, 1 µl dF2 (100
µmol l-1), 0.5 µl (1.25 units) Platinum Pfx DNA
polymerase (Invitrogen), 2 µl cDNA, and water to 50 µl final volume.
Touchdown PCR conditions were: 1 cycle of 94°C 2 min; 5 cycles of 94°C
30 s, 72°C 1 min; 5 cycles of 94°C 30 s, 70°C 1 min; followed by
25 cycles of 94°C 30 s, 55°C 1 min, 68°C 1 min; and a final
extension at 68°C for 10 min. Following this PCR, a second nested PCR was
performed using 1 µl of the first PCR reaction as template, with 1.25 µl
of the nested 3' RACE primer, 1.25 µl dF3 (100 µmol
l-1) and 22.5 µl Megamix Blue (Helena Biosciences, Sunderland,
UK). Conditions were: 1 cycle of 94°C 4 min, followed by 35 cycles of
94°C 30 s, 55°C 1 min, 72°C 1 min and final extension for 10 min
at 72°C. PCR products were electrophoresed on agarose gels, and bands
excised and extracted (Ultrafree-DA, Millipore, Bedford, MA, USA).
5' RACE PCR of Carcinus and Homarus cDNAs
Nested PCR was performed using the Gene Racer forward 5' primers and
R1 (outer) and R2 (inner) reverse gene specific primers
(Table 1), which were designed
from sequence information from 3' RACE. Reagent composition for the
first PCR was similar to that described for the first 3' RACE PCR (using
Pfx polymerase), except that the 1 µl of R1 (10 µmol
l-1) was used. PCR conditions were: 4 min 94°C, followed by 30
cycles of 94°C 30 s, 55°C, 1 min, 68°C 1 min, final extension
68°C 10 min. Following this PCR, 1 µl of product was re-amplified with
the nested Gene Racer forward primer (1.25 µl) and R2 (10 µmol
l-1), 1.25 µl, using Megamix Blue. PCR conditions were 1 cycle
of 94°C, 4 min, followed by 30 cycles of 94°C 30 s, 58°C 1 min,
72°C 1 min and a final extension at 72°C for 10 min. PCR products were
electrophoresed and bands extracted, as above.
3' RACE of Callinectes and Orconectes cDNAs
cDNA for 3' RACE was synthesised using AMV and a Gene Racer 3'
oligo(dT) adapter primer (Invitrogen) with 1 µg total RNA from either
Callinectes or Orconectes. 20-50 ng of cDNA was firstly
amplified as detailed for Carcinus but using forward primer dF1 (100
µmol l-1). Touchdown PCR conditions were: 1 cycle of 94°C 3
min, 3 cycles of 94°C 30 s, 57°C 30 s, 68°C 1 min, 3 cycles of
94°C 30 s, 55°C 30 s, 68°C 1 min, 3 cycles of 94°C, 53°C
30 s, 68°C 1 min, 25 cycles of 94°C 30 s, 58°C 30 s, 68°C 1
min, and a final extension at 68°C for 10 min. Following this, a second
nested PCR was performed using 1 µl of the first PCR as template,
essentially as described for Carcinus, but using primers dF2 or dF3.
PCR conditions were: 1 cycle of 94°C 3 min followed by 30 cycles of
94°C 30 s, 58°C 30 s, 72°C 1 min and a final extension at 72°C
for 7 min. PCR products were electrophoresed on agarose gels, and bands were
extracted with a DNA extraction kit (Qiagen, Valencia, CA, USA).
5' RACE of Callinectes and Orconectes cDNAs
The same PCR conditions as described above were employed for 5' RACE;
nested reverse gene-specific primers (Table
1) were used with nested forward 5' RACE Gene Racer primers
(Invitrogen).
Cloning and sequencing of PCR products
Purified PCR products were ligated into a pCR 4-TOPO vector (Invitrogen),
transformed (TOP-10F', Invitrogen) according to the manufacturer's
instructions, and plasmid DNA from positive clones containing inserts of
correct size were purified and sequenced.
Quantitative RT-PCR, Carcinus
RNA samples (0.1-1 µg) from adult tissues and mRNA from embryos (40
embryo equivalents) were reverse transcribed with AMV-RT and random primers.
For cRNA standards, a PCR product from amplification of 430 bp CCAP sequence
(using primer pairs CCAP1F, CCAP1R; Table
1) was ligated to T7 promoter adapters (Lig'n Scribe, Ambion) and
run-off transcripts prepared and purified as previously described
(Chung and Webster, 2003). RNA
was quantified using Ribogreen (Molecular Probes, Eugene, OR, USA) using yeast
tRNA as standard, diluted in 1 x TE and stored in silanised tubes at
concentrations of 1011 copies per µl. For estimation of CCAP
copy numbers, samples were reverse transcribed simultaneously with a standard
series of cRNA samples (109-103 copies per reaction) and
cDNAs amplified on a Roche Light Cycler using DNA Master kits (Roche
Diagnostics, Mannheim, Germany), with SYBR Green detection. 10 µl reaction
volumes were used in the capillaries, adjusting reagent volumes accordingly.
Mg2+ concentration was 3 mmol l-1, primer concentration
500 nmol l-1 (using primer pairs CCAP2F, 2R;
Table 1; 210 bp product).
Standards were duplicated, embryo samples were single. To detect interassay
drift, each carousel used contained a previously quantified sample. PCR
conditions were as described previously
(Chung and Webster, 2004). To
normalise samples from adult CNS, arginine kinase (AK) expression was
quantified in parallel with CCAP. Production of cRNA standards for AK was as
previously described (Chung and Webster,
2003). Primer sequences used are shown on
Table 1.
To verify that different quantitative PCR instruments gave comparable results, quantitative PCR was also performed on cDNA from adult Carcinus CNS using an Applied Biosystems 7700 instrument, using Sensimix (dT) reagents (Quantace, Watford, UK) with SYBR Green detection. 25 µl reaction volumes were used in 96-well plates. Mg2+ was 1.5 mmol l-1, primer concentration 200 nmol l-1, using the primer pairs shown above. PCR conditions were: initial denaturation 95°C 10 min, 40 cycles of 95°C 15 s, 60°C 60 s.
Quantitative RT-PCR, Callinectes
Total RNA extracted from the CNS of Callinectes was reverse
transcribed (1 µg, AMV, random primers), and cDNA used to prepare
quantified run-off transcripts essentially as detailed above. Quantitative PCR
was performed on an Applied Biosystems 7700 instrument, using a proprietary
SYBR Green kit (Applied Biosystems, Foster City, CA, USA) using the same
reagent concentrations as described above, and the primer pairs shown in
Table 1. PCR conditions were:
initial incubation 50°C 4 min, denaturation 95°C 10 min, 40 cycles of
95°C 15 s, 60°C 1 min.
Immunohistochemistry
Embryos were taken from ovigerous Carcinus, staged as previously
described (Chung and Webster,
2004) fixed (24 h, 4°C) in 2% paraformaldehyde, 15% aqueous
saturated picric acid in 0.1 mol l-1 sodium phosphate buffer, pH
7.3 (Stefanini et al., 1967).
To aid fixation and (essentially) to allow antibody penetration, batches of
50-100 embryos were carefully microscopically dissected within 1 h of fixation
to remove the entire egg shell. Embryos were then washed extensively (48 h) in
0.1 mol l-1 sodium phosphate buffer containing 0.1% Triton X-100,
0.05% sodium azide (PTX). CCAP antisera were produced in rabbits using a
mixture of both 1-ethyl-3, 3'-dimethyl-aminopropyl-carbodiimide (EDC)
and glutaraldehyde-conjugated thyroglobulin-CCAP, prepared as previously
described (Dircksen and Keller,
1988) by Proteintech Group Inc. (Chicago, USA). The resulting
antiserum showed excellent specificity to CCAP, and gave strong immunostaining
(1:1000 dilution) in whole-mount tissues using Stefanini's fixative. Embryos
were incubated in primary antisera in PTX for 4 days at 4°C, extensively
washed in PTX (2 days, 4°C), and incubated in secondary antiserum, 1:50
goat-anti-rabbit fluorescein isothiocyanate conjugate for 2 days (4°C),
followed by extensive washing. Embryos were mounted in Vectashield (Vector
Labs., Burlinghame, CA, USA) and preparations examined by confocal microscopy
using a Zeiss LSM 510 instrument. Proprietary software was used for stacked
projection analysis. Between 20 and 32 consecutive (1.5 µm distance) images
were collected for each projection. Images were manipulated using Adobe
PhotoShop 7.0 and CorelDraw 8.0 software.
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In all instances, cDNAs encoded short 5' untranslated regions (UTRs), followed by open reading frames (ORFs) encoding a (conceptually translated) conventional 30-32 residue signal peptide. In all cases, except Orconectes immunis, the 3' UTR included a putative polyadenylation site (AATAAA). In the case of Orconectes and Callinectes, it was notable that the 3' UTRs were rather shorter than for Carcinus and Homarus. Analysis of the putative signal peptides within the ORFs, using Signal P3.0 (www.cbs.dtu.dk/services/SignalP), indicated that all were probably cleaved from the signal at the AG boundary (positions 32-33; Fig. 1). The precursor peptide contains four putative dibasic (37-38, 49-50), tribasic (61-63) and tetrabasic (115-119) cleavage sites, which could result in the genesis of five peptides, including that encoding CCAP. However, none of these, excepting that encoding CCAP contain amidation (GK, K, R) signals. Comparing all four sequences (Fig. 1), it is readily apparent that all are similar, and encode a putative tetrapeptide (CCAP AP1), a decapeptide (CCAP AP2), CCAP, a 51-mer (CCAP AP3), and a 23-25-mer (CCAP AP4). In particular, it is notable that CCAP AP3 contains a number of identical domains, and that the precursor peptides of brachyuran and astacurans are identifiable in terms of sequence identity.
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). The
results showed that prior to development of eye tissues CCAP expression was
minimal, amounting for less than 1-2000 copies per embryo. Such expression was
deemed to be intrinsic, rather than due to genomic DNA contamination, or from
limited reverse transcriptase activity of Taq, since RT controls showed no
amplification of gene-specific products, and amplification and melt curve
analysis suggested low level expression (data not shown). However, highly
significant increases in expression were observed at the beginning of eye
formation (eye smear, 50% development) as shown in
Fig. 2. A further approx.
threefold increase was seen when eye formation was established (
70%
development). During later stages of development, increased CCAP expression
continued. Just prior to hatching, CCAP mRNA expression appeared to increase,
but levels were not significantly different from those of the preceding stage
(85-90% development).
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Expression profiles of CCAP and corresponding neurogenesis were monitored by whole-mount confocal microscopy of embryos using CCAP immunohistochemistry. Expression of CCAP peptide was first observed at 70% development, when small, rather inconspicuous immunoreactive structures could be observed on the dorsal side of the embryo, corresponding to the position of the heart (Fig. 3A). Ventral views of the embryos at this time revealed bilaterally symmetrical immunopositive structures (Fig. 3B). CCAP immunopositive neurones became clearly visible at 80% embryonic development, when axons in the developing thoracic ganglion and two segmental nerves became prominent (Fig. 3C). Subsequent stages in embryogenesis (85-100%) (Fig. 3D,E) showed accumulation of CCAP immunoreactivity (IR) in the segmental nerves and, in particular, in structures reminiscent of the anterior ramifications (AR) in the adult CNS. For fully developed embryos, some details of neuroanatomy of the thoracic ganglion (TG) could be established, in particular the projection of contralateral axonal projections and varicosities at four or five fairly defined positions in the developing TG (Fig. 3D,F), but the positions of corresponding perikarya were very difficult to establish. In one preparation, some outlines of presumptive perikarya were just observable (Fig. 3F). Despite extensive investigation of many embryos, only a few preparations revealed faintly staining perikarya, where three pairs of small cells (<10 µm diameter) were visible in stacked confocal images (Fig. 3G).
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Expression of CCAP mRNA in adult CNS
Conventional PCR using primer pair CCAP F1, R1 (430 bp product) showed that
CCAP was only expressed in eyestalk, brain and thoracic ganglia, and was
undetectable in non-neural tissues (Fig.
4 inset). qRT-PCR results showed that although thoracic ganglia
expressed over 100-fold more CCAP than other neural tissues, the eyestalk
tissues expressed significantly more CCAP mRNA than brain tissues
(Fig. 4). With regard to copy
number per tissue, for adult Carcinus (carapace width 45-55 mm) these
were [x106, mean ± s.e.m. (N)]: eyestalk
3.50±0.4 (14), cerebral ganglia 1.03±0.35 (8), thoracic ganglia
527±103.3 (8). For adult Callinectes (which were much larger;
carapace width 160-180 mm), copy numbers were about tenfold
higher [x107, mean ± s.e.m. (N)]: eyestalk
4.6±1.3 (6), cerebral ganglia 4.4±1.5 (6), thoracic ganglia
681±20.6 (6). Intriguingly, results from one set of simultaneous
isolations from both males and females indicated that in female eyestalks CCAP
mRNA expression was significantly greater [26.7±7.3 (6)
(P<0.05)] compared to males [4.6±1.3 (6)].
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Quantitative expression patterns of instantaneous levels of CCAP mRNA in thoracic ganglia were determined by qRT-PCR throughout the moult cycle in three ways: without normalisation, normalisation to total RNA, and to the invariant housekeeping gene, arginine kinase (AK) (Fig. 5). RT reactions were simultaneously performed on all samples to avoid interassay drift. For Carcinus, mean levels of un-normalised CCAP copy numbers were between 0.9x109 and 1.6x109 per thoracic ganglion, when normalised against total RNA they were between 60x106 and 117x106 copies per µg RNA, and when normalised to AK they were between 19.3 and 51 (103 copies CCAP/106 copies AK). None of these changes were statistically significant (one-way ANOVA, and Dunn's multiple comparison tests). For Callinectes, copy number of CCAP per thoracic ganglion increased from 1.85x108 to 3.7x108 during postmoult to premoult, normalised patterns (per µg RNA) from 9.8x106 to 17.3'106 and for AK normalised samples, from 7.6 to 13.2 (103 copies CCAP/106 copies AK). Nevertheless, these increases were not significant (P>0.05).
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Expression of CCAP mRNA in eyestalk and thoracic ganglia following hypoxic and temperature stress
CCAP expression in eyestalk and thoracic ganglia was determined following
severe hypoxic stress (1 h, <0.5% dissolved O2). The results are
summarised in Fig. 6. Although
no significant changes in CCAP or AK expression were seen in the thoracic
ganglia, hypoxia induced a significant downregulation in CCAP expression in
eyestalk ganglia, which seemed to be specific, in that AK expression levels,
although very variable, were not reduced to the same extent as those seen for
CCAP. With regard to temperature stress, where crabs were subjected to severe
hypothermal episodes or hyperthermic stress, to mimic yearly extremes in the
Chesapeake Bay, CCAP copy numbers were rather lower in those exposed to
hypothermic stress (22-24°C) than in those animals exposed to hyperthermic
stress (22-29°C). Nevertheless, these changes were statistically
insignificant, and were not mirrored by changes in expression patterns of AK
in eyestalk tissues (Table
2).
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) have clearly identified CCAP, and quite a number of
peptides (39), yet molecular ions similar to those predicted in our studies
were not determined in this study. Nevertheless, direct profiling by MALDI-TOF
MS of PO homogenates in Cancer borealis have identified CCAP, and
also a number of as yet unidentified peptides of mass ranges similar to those
predicted in the present study, in particular, those similar to CCAP AP3 and 4
(Li et al., 2003). However,
should these putative peptides be authentic neurohormones, their functions are
of course unknown. Carcinus sinus gland (SG) and PO express three
crustacean hyperglycaemic hormone precursor-related peptide (CPRP) variants
(Dircksen et al., 2001), and
others (Cancer productus) may express up to four CPRPs, and possibly
truncated variants (Fu et al.,
2005b). To date no biological activity has been ascribed to these
peptides, and for CPRP, in view of its notably long half-life in circulation
(Wilcockson et al., 2002), a
hormonal role seems unlikely. Additionally, for the CCAP precursor, it should
be noted that there are few similarities in sequence of the putative peptides
identified so far when insects and crustaceans are compared, and none of these
bear C-terminal amidation sites characteristic of the majority of secreted
neuropeptides. Thus it seems possible that the CCAP-associated peptides may
have no functionally relevant role as neuropeptides. It would be interesting
to determine the cellular expression and distribution patterns of the
CCAP-associated peptides in the PO and to determine (co) release patterns from
the PO by raising specific antisera for ICC and radioimmunoassay studies.
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), yet
the first expression of CCAP, as detected by immunochemical localisation, was
observed a little later, at 70% embryonic development, which corresponded to a
lag of around 5 days (Chung and Webster,
2004). Nevertheless, it could be argued that measurement of CCAP
mRNA expression is inherently more sensitive than detection of peptide by ICC.
However, we have previously observed correspondence in detection of gene
expression and peptide for moult-inhibiting hormone (MIH) and crustacean
hyperglycaemic hormone (CHH) at the eye anlage stage (50% development) of
Carcinus embryos (Chung and
Webster, 2004), suggesting that detection limits using mRNA
quantification and immunohistochemistry may be similar in some instances.
In embryos of the lobster Homarus americanus, clearly defined
immunoreactivity corresponding to CCAP (and a variety of other neuropeptides)
in a well developed PO have been observed at about 50% development
(Pulver and Marder, 2002),
somewhat earlier that recorded in the present study. However, the lobster has
a prolonged embryonic life and hatches at a relatively advanced developmental
stage, compared to crabs. In the lobster, gross anatomy of the PO, segmental
nerves 1-5 and dorsal nerves 1-3 are easily visible at 50% development, thus a
direct comparison based on timed criteria of development may not be
appropriate. A dramatic increase in expression of CCAP mRNA occurred at
mid-eye (80% development). This corresponded to the appropriate phenotype,
i.e. at this time the heart starts to beat rapidly, rather that the irregular
heart beat seen prior to 70% development
(Chung and Webster, 2004).
Despite the dramatic increase in CCAP transcript number during embryogenesis
(103-fold), immunopositive structures whilst developing in
complexity, seemed not to mirror transcript number. In particular, the
expression of CCAP in three pairs of immunopositive neurones in the TG of late
embryos (Fig. 3G) suggested
quite low level translation. This observation could not be explained by (for
example) poor penetration of the antibody, since the segmental nerves,
anterior ramifications and neuronal architecture of the developing thoracic
ganglia all gave very intense signals. In the adult a similar situation has
been noted with regard to low level translation
(Stangier et al., 1988), where
low levels of CCAP were observed in the thoracic ganglia (1.4 pmol
mg-1 protein) compared to much higher levels in the PO (868 pmol
mg-1 protein).
By comparison with the detailed description of the CCAP-expressing neurones
in adult Carcinus (Dircksen,
1998), some analysis of CCAP neuroanatomy in embryos can be made.
The appearance of strong immunopositive signals in dorsal regions of the
segmental nerves at around 80% development
(Fig. 3C) allowed
identification of the anterior ramifications
(Fig. 3D), thus the anterior
nerve is segmental nerve 1, which arises from the first thoracic (maxilliped
1) segment [neuromere 7 using criteria adopted by Harzsch
(Harzsch, 2003)]. At full
development, five pairs of contralaterally projecting axons can be seen in the
TG, which probably correspond to projections from large (type-1)
CCAP-containing neurones in the adult. However, since these cells contained
very small quantities of CCAP, unequivocal identification of only three pairs
of cells was possible. Furthermore, the nine pairs of CCAP-expressing neurones
corresponding to the fused abdominal ganglion of the adult were not seen in
the TG or abdomen of the embryo.
Expression of CCAP mRNA in the nervous system
Expression of CCAP in adult crabs was restricted to the CNS, as has been
previously reported from radioimmunoassay studies
(Stangier et al., 1988).
Although the thoracic ganglia expressed the majority of transcripts for CCAP,
it was notable that, for Carcinus, transcript number normalised
against total RNA, was significantly higher that that of the cerebral ganglia.
Although this phenomenon was not seen in Callinectes, previous
studies have indicated that each eyestalk contains very few, perhaps only one
perikaryon, immunopositive for CCAP neurones, in contrast to the cerebral
ganglia where at least five pairs of CCAP-immunoreactive perikarya have been
observed (Dircksen and Keller,
1988). Radioimmunoassay studies
(Stangier et al., 1988) have
shown that eyestalks and cerebral ganglia of Carcinus contain similar
quantities of CCAP (1.4 pmol mg-1 protein). Since CCAP has not been
identified in the SG (Fu et al.,
2005b), it seems that the CCAP immunoreactive structures in the
eyestalk, as in the brain, are interneurones.
Expression of CCAP in the nervous system during the moult cycle, and following environmentally relevant stressors
During the moult cycle, no significant changes were seen in CCAP expression
in thoracic ganglia. Despite extensive investigations, using normalisation to
total RNA, AK and in comparison to un-normalised data
(Fig. 5) we could find no
significant changes in mRNA transcription during the moult cycle of
Carcinus or Callinectes. Although a general trend could be
seen in Callinectes, whereby steady state transcription levels were
at their lowest during postmoult, and highest during premoult, a feature which
would also be discernible by pooling results from Carcinus in this
manner (given the inevitable errors involved in SYBR green detection of
amplicons in quantitative PCR, which cannot determine less than twofold
changes in amplicon concentration) it seems more than likely that steady-state
transcription of CCAP remains relatively constant throughout the moult cycle.
Indeed, the two normalisations performed on the data corroborate this, not
withstanding the fact that CCAP-expressing cells in the TG are invariant in
number, it seems likely that the first iteration using un-normalised copy
number data may be the most biologically relevant. Thus, it seems likely that
CCAP expression in the thoracic ganglia is constitutive. Therefore the
previously reported surge in CCAP release during ecdysis in crustaceans
(Phlippen et al., 2000) cannot
be correlated with increased transcription of CCAP during premoult.
Since Callinectes, which is a subtidal crustacean, experiences
environmental variabilities in the Chesapeake Bay area that are far greater
than those experienced by an essentially intertidal crustacean such as
Carcinus, we determined the steady-state expression of CCAP in
Callinectes, to determine the possible effects of (extreme)
environmental stressors (hypoxia, temperature changes), within the context of
recorded variables within Chesapeake Bay. The effects of hypoxia were of
particular interest, since, near-shore waters in Chesapeake Bay periodically
experience episodes of anoxia or severe hypoxia (<2 mg l-1)
during the summer (Breitburg,
1990), which may occasionally be of sufficient severity and
duration to cause mass mortalities
(Seliger et al., 1985).
Following extreme hypoxic episodes, expression of eyestalk CCAP mRNA was
significantly reduced, in contrast to that of thoracic ganglia CCAP
expression, which remained unchanged (Fig.
6). This result was interesting (and specific) since AK expression
levels remained unchanged in both eyestalk and thoracic ganglia. Nevertheless,
following thermal stress, both CCAP and AK expression was unchanged
(Table 2). Since the reduction
in CCAP expression in eyestalk ganglia prior to extreme hypoxia (copy number:
3.47±0.81x106) compared to expression after 1 h of
hypoxia (copy number: 0.91±0.36x106) was significant,
and in view of our results showing that CCAP expression in the eyestalks is
significant in relation to the much lower levels of expression seen in the
cerebral ganglia, given that there appear to be many more CCAP-expressing
neurons in the latter tissue (Dircksen,
1998), it is possible that CCAP has yet another role in
environmental adaptation, which remains to be uncovered. Additionally, the
sexual dimorphism in CCAP transcript number in Callinectes was
intriguing (males: 4.6±1.3'107; females:
26.7±7.2x107copies per eyestalk), and might possibly
suggest novel roles for this hormone in reproduction. Since CCAP has a role as
an adipokinetic hormone release-inducing factor in the locust corpora cardiaca
(Veelaert et al., 1997), it is
conceivable that this hormone may have modulatory roles in controlling the
release of peptides involved in control of vitellogenesis in the eyestalk
neurosecretory system of crustaceans, and this deserves further study.
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Acknowledgments |
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References |
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TOPSummaryIntroductionMaterials and methodsResultsDiscussionReferences |
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