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First published online March 27, 2009
Journal of Experimental Biology 212, 1202-1211 (2009)
Published by The Company of Biologists 2009
doi: 10.1242/jeb.025239
Increased gene expression of a facilitated diffusion urea transporter in the skin of the African lungfish (Protopterus annectens) during massively elevated post-terrestrialization urea excretion
1 Department of Biology, McMaster University, Hamilton, ON, Canada, L8S
4K1
2 Department of Biological Sciences, Louisiana State University, Baton Rouge, LA
70803, USA
3 Department of Biological Sciences, National University of Singapore, 10 Kent
Ridge Road, Singapore 117543, Republic of Singapore
* Author for correspondence (e-mail: woodcm{at}mcmaster.ca)
Accepted 9 February 2009
 |
Summary |
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 TOP Summary INTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONReferences |
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65% amino acid homology), followed by
mammals and elasmobranchs (60%), and then teleosts (50%).
lfUT was clearly expressed in gill, kidney, liver, skeletal muscle
and skin. Upon re-immersion in water after 33 days of air exposure
(`terrestrialization'), lungfish exhibited a massive rise in urea-N excretion
which peaked at 12–30 h with rates of 2000–5000 µmol-N
kg–1 h–1 (versus normal aquatic rates of
<130 µmol-N kg–1 h–1) and persisted
until 70 h. This appears to occur mainly through the skin. Total `excess'
urea-N excretion amounted to 81,000–91,000 µmol-N
kg–1 over 3 days. By real-time PCR, there was no difference
in lfUT expression in the ventral abdominal skin between aquatic
ammoniotelic controls and terrestrialized lungfish immediately after return to
water (0 h), and no elevation of urea-N excretion at this time. However, skin
biopsies revealed a significant 2.55-fold elevation of lfUT
expression at 14 h, coincident with peak urea-N excretion. At 48 h, there was
no longer any significant difference in lfUT mRNA levels from those
at 0 and 14 h, or from aquatic fed controls. In accordance with earlier
studies, which identified elevated urea-N excretion via the skin of P.
dolloi with pharmacology typical of UT-A carriers, these results argue
that transcriptional activation of a facilitated diffusion type urea
transporter (lfUT) occurs in the skin during re-immersion. This
serves to clear the body burden of urea-N accumulated during
terrestrialization.
Key words: facilitated diffusion urea transporter, ammonia, terrestrialization, skin
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INTRODUCTION |
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TOPSummaryINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONReferences |
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;
Walsh and Smith, 2001).
Non-erythrocytic urea transporters of the facilitated diffusion type (UT-A)
were first discovered in the mammalian kidney
(You et al., 1993;
Smith et al., 1995) and later
in amphibian bladder (Couriaud et al.,
1999; Konno et al.,
2006), elasmobranch kidney
(Smith and Wright, 1999;
Morgan et al., 2003;
Janech et al., 2003;
Janech et al., 2006;
Hyodo et al., 2004) and
teleost gills (Walsh et al.,
2000; Walsh et al.,
2001a; Walsh et al.,
2001b). A cDNA orthologue (UT-C) with relatively low sequence
identity (35%) to the UT-As has been identified in eel kidney
(Mistry et al., 2005). UT-A
urea transporters have been shown to facilitate diffusive urea transport when
expressed in Xenopus laevis oocytes
(Smith and Wright, 1999;
Fenton et al., 2000;
Walsh et al., 2000;
Walsh et al., 2001a;
Shayakul et al., 2001;
Janech et al., 2002;
Stewart et al., 2006;
MacIver et al., 2008).
The Dipnoi are facultatively ureotelic, but the possible occurrence of urea
transporters in this important evolutionary group has not been explored to
date. The African lungfishes (Protopterus spp.) are obligate
air-breathers which possess a primitive lung as well as both internal and
external gills; they are renowned for their ability to withstand prolonged
periods of drought by going into a state of torpor or aestivation, covered by
a cocoon to prevent dehydration (Smith,
1930; Janssens,
1964; DeLaney et al.,
1974). While submerged in water, lungfishes are usually
ammoniotelic, producing ammonia and excreting it across branchial and
cutaneous epithelia (Graham,
1997; Wood et al.,
2005). However, when water becomes limited and ammonia excretion
becomes impeded, lungfishes convert toxic ammonia into a less toxic
nitrogenous product, urea, and store it in the body
(Smith, 1930;
Janssens, 1964;
DeLaney et al., 1974;
Chew et al., 2003;
Chew et al., 2004;
Wood et al., 2005;
Ip et al., 2005;
Loong et al., 2005;
Loong et al., 2008;
Wilkie et al., 2007).
When Protopterus dolloi were returned to water after either
aestivation in air (with complete cocoon formation) or `terrestrialization' in
air (with minimal water available on the ventral surface only, and less
complete cocoon formation), the urea-N excretion rate was greatly elevated,
reaching 2000–6000 µmol-N h–1 kg–1
at 10–24 h after return to water
(Wood et al., 2005). A divided
chamber experiment demonstrated that 72% of this urea-N efflux occurs through
the posterior 85% of the body, with minimal involvement of the kidney, thereby
implicating the skin as an important site of urea-N excretion
(Wood et al., 2005). These
urea-N flux rates in lungfish are two to three orders of magnitude higher than
in most teleosts but comparable to two exceptions: the facultatively ureotelic
gulf toadfish Opsanus beta (Wood
et al., 1995; Wood et al.,
1998; Walsh, 1997;
Gilmour et al., 1998), and the
obligately ureotelic Lake Magadi tilapia Alcolapia grahami
(Randall et al., 1989;
Wood et al., 1989;
Wood et al., 1994;
McDonald et al., 2003). These
two teleosts both express UT-A type facilitated urea transporters which are
restricted to the gills (Walsh et al.,
2000; Walsh et al.,
2001a). Notably, during re-immersion after air exposure, urea
excretion in P. dolloi exhibited the same pattern of pharmacological
sensitivity to urea analogues (Wood et
al., 2005) as for toadfish and Magadi tilapia, which is the same
as reported earlier for UT-A transporters in higher vertebrates
(McDonald et al., 2003;
Walsh et al., 2001a).
In light of this background, we hypothesized that elevated urea-N excretion
in lungfish during the post-terrestrialization period is mediated by a
carrier, probably of the UT-A facilitated diffusion type, and that the
transporter is expressed in the skin and perhaps other body tissues. Given the
proposed evolutionary position of the Dipnoi as the closest living relatives
to the tetrapods (Meyer and Dolven,
1992; Cao et al.,
1998; Zardoya et al.,
1998; Tohyama et al.,
2000), we also postulated that such a carrier would show greatest
similarity in sequence to the UT-As of amphibians. In higher vertebrates,
transcriptional control of UT-A expression occurs only very slowly, in
response to dietary N changes, for example
(Bagnasco, 2005). In the gulf
toadfish, the rapid (1–3 h) pulses in urea excretion are not accompanied
by changes in UT-A gene expression (Walsh
et al., 2000). However, given the relatively slow time course of
the massive urea-N surge in the lungfish, peaking at 10–24 h
post-terrestrialization (Wood et al.,
2005), we also hypothesized that the expression of skin UT-A mRNA
would increase in accordance with the pattern of urea-N excretion. We selected
P. annectens for the present study, rather than the P.
dolloi earlier studied by Wood and colleagues
(Wood et al., 2005), because
of the scarcity of the latter. It was therefore first necessary to establish
the pattern of urea-N excretion after re-immersion in P.
annectens.
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MATERIALS AND METHODS |
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TOPSummaryINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONReferences |
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There has been confusion in the recent literature about the terminology
used to describe the various air exposure and aestivation protocols used by
different workers [see discussion by Loong and colleagues
(Loong et al., 2008)]. In the
experimental series of the present study, some of the lungfish were subjected
to an experimental treatment similar to that employed by Wood and colleagues
(Wood et al., 2005) and Wilkie
and colleagues (Wilkie et al.,
2007). This was originally described as `terrestrialization' by
Wood and colleagues (Wood et al.,
2005) and the same term is used here; it should not be confused
with true `aestivation' (see Loong et al.,
2008). Lungfish were induced to undergo terrestrialization in
their aquaria by removing all the water except for 5–10 ml of fresh
water. Throughout the terrestrialization period, the lungfish were kept under
24 h darkness with no feeding. Water (about 1 ml) was sprayed every 2 days to
keep the aquaria moist. It took about 5–7 days before a brown cocoon was
formed covering the body. Under these conditions, most fish exhibited very
little movement, but in a few instances it was clear that fish had shifted
position, with occasional slight damage to the cocoon. The total
terrestrialization period was 33 days. To control for the effects of fasting,
one control group was kept under standard aquatic conditions but without
feeding for the same length of time, while another aquatic control group was
fed every 2 days in the regular fashion.
Full-length cloning of urea transporter from P. annectens
One aquatic lungfish was killed for urea transporter cDNA cloning. The
lungfish was anaesthetized with 0.5 g of MS-222 (Syndel Laboratories,
Vancouver, BC, Canada) in 2 l of water (neutralized with NaOH), and then
killed by a sharp blow to the head followed by decapitation, and immediately
gill, kidney and skin were collected and frozen in liquid nitrogen. Total RNA
was extracted from these three tissues using Trizol reagent (Invitrogen,
Burlington, ON, Canada) according to the manufacturer's instructions and
pooled together for cDNA synthesis. First strand cDNA was synthesized using
Superscript reverse transcriptase II (Invitrogen, Carlsbad, CA, USA) with an
adaptor oligo dT primer (T17AP2: gACTCgAgTCgACATCgAT17).
Based on a partial cDNA sequence of a putative urea transporter, which we
had earlier cloned from another lungfish, P. dolloi (EU852333) (see
Wood et al., 2005), we
designed a pair of cloning primers for the P. annectens urea
transporter (Table 1).
Polymerase chain reaction (PCR) was carried out in a PTC-200 MJ Research
thermocycler with Platinum Taq DNA polymerase (Invitrogen) at 94°C (2
min), followed by 35 cycles of 94°C (30 s); 56°C (30 s); 72°C (45
s); and a final extension at 72°C (5 min). Electrophoresis on an ethidium
bromide-stained 1% agarose gel revealed a single PCR product. This PCR product
was excised and extracted using a Qiaquick gel extraction kit (Qiagen Inc.,
Mississauga, ON, Canada). Purified gel products were ligated into a pGEM-T
easy vector (Promega, Fisher Scientific, Nepean, ON, Canada), transformed into
competent Escherichia coli (XL-Blue, Stratagene, Mississauga, ON,
Canada), and then grown on ampicillin LB agar plates at 37°C. Positive
colonies containing the ligated product were inoculated into liquid LB media
and grown overnight. Plasmids from the overnight culture were obtained and
purified using GeneJet Plasmid Miniprep Kit (Fermentas Canada Inc.,
Burlington, ON, Canada) and sent for sequencing (ABI 3100 Gene Analyzer, MOBIX
lab, McMaster University). A partial sequence (286 bp) of the putative P.
annectens urea transporter was obtained. A partial actin
sequence was also obtained using degenerate primers
(Table 1) as described
above.
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Gene-specific primers (Table 1) were then designed to obtain the full-length sequence of the urea transporter by 3' and 5' RACE (Marathon cDNA Amplification Kit, Clontech, Mountainview, CA, USA). Messenger RNA needed for RACE cloning was purified from total RNA using an Oligotex Direct mRNA Mini Kit (Qiagen). The full-length sequence of P. annectens urea transporter lfUT (lungfish urea transporter) has been deposited in GenBank (accession number: EU716115).
Tissue distribution
Reverse-transcription (RT-) PCR was used to determine the mRNA expression
pattern of lfUT in various tissues of fasted control and
post-terrestrialized lungfish. Three lungfish were used per group.
On day 34, terrestrialized lungfish were moved to a lighted area and returned to aquatic conditions by adding 1 l of water. After re-immersion, it was about 45 min before the lungfish became active and struggled to break the cocoon to breathe. Therefore, before the lungfish were aroused, the aquaria were placed at an angle so that the nose of the lungfish was not covered by water, thereby preventing drowning. Residual cocoon pieces adhering to the skin of the lungfish were manually removed with a pair of blunt forceps. The lungfish were anaesthetized in neutralized MS-222 and killed within 10 min after they were aroused. Tissues were collected (gill, heart, kidney, liver, lung, muscle, dorsal and ventral skin) as described above. The fasted control group of lungfish were similarly killed and dissected on day 34 after 33 days of fasting.
Total RNA extraction and cDNA synthesis were done as described above. A DNase I (Invitrogen) digestion step was used (1 Uµg–1 RNA, 15 min at room temperature) to ensure there was no genomic DNA contamination prior to cDNA synthesis. Sense and anti-sense screening primers (Table 1) were used to examine the tissue-specific expression of lfUT. Actin (the same primer pair as used for real-time PCR; Table 1) was used as a control gene to ensure that the cDNA of individual samples was successfully synthesized. PCR was carried out at 94°C (2 min), followed by 30 cycles of 94°C (30 s); 58°C (30 s); 72°C (45 s); and a final extension at 72°C (5 min).
Sequence analysis
Molecular mass calculations and analyses of amino acid sequence and
sequence identity with other species were performed using BioEdit
(Hall, 1999). Serine,
threonine and tyrosine phosphorylation sites were predicted using NetPhos 2.0
Server (Blom et al., 1999).
Hydropathy analysis to predict transmembrane domains was done through an
online server
(http://www.cbs.dtu.dk/services/TMHMM-2.0).
Phylogenetic relationships were constructed by sequence alignment using
ClustalW software (Thomson et al., 1994), followed by POWER software
(Lin et al., 2005) using the
neighbour-joining method for tree construction with an evaluation of 1000
bootstrap replicates.
Series 1: urea and ammonia excretion rates
To determine the amount of urea excreted by P. annectens under
control and post-terrestrialization conditions, we terrestrialized six
lungfish as described above, and subjected a second group of six lungfish to
33 days of fasting under standard aquatic conditions. A third group were fed
regularly every 48 h; their excretion rates have been reported by Iftikar and
colleagues (Iftikar et al.,
2008). On day 34, the terrestrialized lungfish were moved to a
lighted area and the aquaria were quickly flushed with 2x1 l of water to
remove any accumulated waste. The lungfish were carefully handled as described
above to prevent drowning. Both sets of lungfish were then put in water with a
volume equal to 25x the animals' body mass, together with two air-stones
in each aquarium to ensure thorough mixing. Starting at 2 h, and at 2 h
intervals throughout the 72 h re-immersion, a 10 ml water sample was withdrawn
from each aquarium and stored at –20°C until further analysis. Water
was changed at 20, 40 and 60 h. Likewise, water samples were collected from 33
day fasted control fish at the same time intervals, using an identical
protocol.
Water urea concentrations were measured by the diacetyl monoxime method
(Rahmatullah and Boyde, 1980),
and water ammonia concentrations were measured by the indophenol blue method
(Verdouw et al., 1978), using
freshly prepared urea (Sigma, St Louis, MO, USA) and NH4Cl (Sigma)
standards.
Series 2: urea excretion and skin lfUT mRNA quantification
After determining the pattern of urea flux from post-terrestrialization
lungfish in series 1, we subjected another group of five lungfish to
terrestrialization for 33 days and collected water for urea excretion rate
measurement as described above, up to 60 h re-immersion. This time, we also
collected ventral skin samples. Our skin sampling protocol avoided the need to
kill these animals. Approximately 2 mmx1 mm biopsies of ventral skin
were taken from all five individual lungfish at 0, 14 and 48 h re-immersion to
investigate lfUT mRNA expression of P. annectens. Thus each
fish was biopsied 3 times. Fed aquatic control animals (fed regularly at 48 h
intervals) were similarly biopsied at 24 h after feeding. The lungfish were
removed from the tank briefly for biopsy, which took about 1–2 min to
complete and no bleeding was observed following each biopsy. The lungfish were
not anaesthetized during the process and they were then kept in water
supplemented with 20 µgml–1 of ampicillin to prevent any
bacterial infection. Ventral skin samples collected were placed in Trizol
reagent and frozen in liquid nitrogen immediately upon excision. A preliminary
test was carried out to ensure that water urea concentration measurements were
not affected by the addition of ampicillin.
Real-time PCR
Total RNA was extracted as described above, with the following
modifications to increase the yield of RNA: after phenol–chloroform
extraction, the upper aqueous phase containing RNA was transferred to a new,
RNase-free 1.5 ml centrifuge tube and mixed well with 1 µl of glycogen (20
µg µl–1, molecular biology grade, Fermentas), before
isopropanol addition. The mixture was then stored at –80°C
overnight, and centrifuged for 1 h at 4°C to collect the final RNA pellet.
DNase digestion was performed before first-strand cDNA synthesis.
lfUT mRNA expression in aquatic, fed control lungfish as well as post-terrestrialization lungfish at 0, 14 and 48 h re-immersion was determined by quantitative real-time PCR (qPCR). qPCR primer (Table 1) specificity was tested in preliminary experiments to ensure only a single PCR product was obtained with the skin cDNA samples. The PCR product was purified and sequenced to confirm its identity. qPCR analyses of lfUT expression were performed on an Mx3000P QPCR System (Stratagene, Cedar Creek, TX, USA). Each qPCR reaction (20 µl) containing 4 µl of DNaseI-treated (Invitrogen) cDNA (1:4 dilution), 4pmol each of forward and reverse primer, 10 µl of Platinum SYBR Green qPCR SuperMix-UDG (Invitrogen) and 0.8 µl of ROX (1:10 dilution) was performed at 50°C, 2 min; 95°C, 2 min; followed by 40 cycles of 95°C, 15 s; and 60°C, 30 s. Melt-curve analysis further verified that only one unique product was produced and gel electrophoresis confirmed the presence of a single band. Two negative controls were included: a non-reverse-transcribed RNA sample which controlled for possible genomic DNA contamination; and a water sample to ensure that primers and all reagents were free of contamination. In this study, actin was used as the normalization factor because it displayed consistent expression in aquatic, fed control samples and at all three time points post-terrestrialization. A standard curve was run for each of the genes in this study.
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RESULTS |
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TOPSummaryINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONReferences |
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Tissue expression in control and post-terrestrialization lungfish
RT-PCR results revealed that lfUT was clearly expressed in a
number of tissues, including gill, kidney, liver, muscle, skeletal muscle,
dorsal skin and ventral skin but was only weakly expressed in or absent from
heart and lung of control (aquatic) P. annectens, and after 33 days
of terrestrialization (Fig. 4).
There were no marked differences in tissue-specific expression by RT-PCR
associated with terrestrialization; note that these animals were killed
immediately after return to water.
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Following re-immersion after 33 days of terrestrialization, P. annectens exhibited a marked surge in urea-N excretion lasting approximately 3 days. The response was slightly delayed, inasmuch as urea-N excretion rates during the first 8 h of re-immersion were similar to those of control lungfish. The urea-N excretion rate was significantly higher at 14 h (2156±834 µmol-N kg–1 h–1) when compared with that at 2–8 h, and the rates remained significantly elevated up to 56 h (Fig. 5). The peak excretion rate occurred at 20 h (5132±380 µmol-N kg–1 h–1) and was significantly higher than the 2–18, 22, 26 and 30 h through to 72 h post-terrestrialization measurements. When compared with control P. annectens, urea-N excretion rates of re-immersed P. annectens were significantly higher from 10 h through to 70 h at every corresponding time point (Fig. 5). The total `extra' urea-N excretion over the 3 day period was 81,070 µmol-N kg–1.
Ammonia-N excretion rates, however, did not show any significant difference between fasted control and post-terrestrialization P. annectens or significant variation over time (data not shown). The mean ammonia excretion rate of fasted control lungfish was 48.9±4.4 µmol-N kg–1 h–1 and that of re-immersed P. annectens was 58.4±1.0 µmol-N kg–1 h–1, respectively. By way of comparison, fed aquatic lungfish exhibited a significantly higher ammonia-N excretion rate of 155.2±11.8 µmol-N kg–1 h–1, integrated over the 48 h feeding cycle.
Series 2: real-time PCR results
The only methodological difference in this experiment from series 1 was
that the five terrestrialized lungfish were subjected to ventral skin biopsies
at 0, 14 and 48 h re-immersion. The pattern of urea-N excretion following
re-immersion was broadly similar to that in series 1
(Fig. 5), except for a variable
elevation at 2 h (2100±1150 µmol-N kg–1
h–1, in series 2 fish), although this rate was not
significantly higher than that measured at this time in series 1
(372±77 µmol-N kg–1 h–1). Urea-N
excretion rates at 14–50 h post-terrestrialization were significantly
higher than those measured at 6–10, 54 and 60 h. The total `extra'
urea-N excretion in this series was about 91,000 µmol-N
kg–1 when compared with the total urea excreted by control
aquatic lungfish in series 1 (up to 60 h).
lfUT mRNA expression in the ventral skin of aquatic fed control and re-immersed lungfish of series 2 was normalized to actin mRNA expression (which did not change) and the results are presented as a relative ratio of lfUT to actin mRNA levels (Fig. 6). There was no difference in lfUT/actin expression between fed control lungfish and 33 days terrestrialized lungfish. However, lfUT/actin expression was significantly higher (2.55-fold) in 14 h re-immersed lungfish skin when compared with that of aquatic, fed controls, and also significantly higher than in fish re-immersed at 0 h. At 48 h, relative lfUT/actin expression declined, so it was no longer significantly different from either the 14 or 0 h samples, or from the aquatic controls (Fig. 6).
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DISCUSSION |
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TOPSummaryINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONReferences |
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;
Bagnasco, 2003) but lacks the
UT-B signature ALE domain. These findings suggest that this newly identified
urea transporter from lungfish is a UT-A. A number of UT-A isoforms or
transcripts have been identified in mammals, amphibians and elasmobranchs (see
Introduction) (for reviews, see Bagnasco,
2003; Bagnasco,
2005; McDonald et al.,
2006). It is possible that lungfish also possess more than one
copy of UT-A in their very large genome. Repeated attempts to identify other
UT-A as well as UT-C isoforms from the skin of P. annectens have
proven unsuccessful to date.
Phylogenetic analysis based on amino acid sequences of the urea
transporters available in GenBank indicated that lfUT is
distinctively different from teleost, amphibian, elasmobranch, mammalian and
prokaryotic urea transporters. Nevertheless, it is noteworthy that
lfUT shares the highest homology with the amphibian orthologues,
followed by mammals and elasmobranchs, and is only about 50% identical to the
teleost UT-As (Table 2). The
phylogenetic tree (Fig. 3)
shows that the most primitive urea transporters separated into two groups:
UT-C and all other urea transporters, similar to results reported earlier
(Mistry et al., 2005).
Prokaryotic (Yersinia frederiksenii and Actinobacillus
pleuropneumoniae) transporters then divided from eukaryotic transporters.
Eukaryotic urea transporters then branched into two main groups:
`erythrocytic' UT-Bs and `renal' UT-As. Mammalian UT-As are furthered
clustered as one group, separated from amphibian and fish UT-As.
Interestingly, lfUT is branched out as a unique group, between
amphibians and fish (teleosts and elasmobranchs).
The fact that the lungfish lfUT is more closely related to the
amphibian UT-As is in accordance with reported phylogenetic relationships for
other lungfish genes including somatostatin precursors I and II
(Trabucchi et al., 1999),
myelin DM20 (Tohyama et al.,
2000) and urate oxidase
(Anderson et al., 2006). In
fact, recent evolutionary analyses have hypothesized that lungfish (Subclass
Dipnotetrapodomorpha) are phylogenetically the closest relatives to tetrapods
(Meyer and Dolven, 1992;
Cao et al., 1998;
Zardoya et al., 1998;
Tohyama et al., 2000), though
exact relationships between lungfish, coelocanths and tetrapods remain unclear
(Takezaki et al., 2004;
Friedman et al., 2007).
Furthermore, the environmental circumstances of amphibians and lungfish
(amphibious life style, frequent danger of dehydration, ability to aestivate)
are similar. Therefore, it is possible that regulatory mechanisms (e.g.
transcriptional, translational or post-translational modification, hormonal
controls) of lungfish lfUT may also be more similar to those of
amphibians than fish.
In teleost fish, gene expression of UT-A appears to be restricted to the
gills (Walsh et al., 2000;
Walsh et al., 2001a;
Mistry et al., 2001), but in
the amphibian Bufo marinus, UT-A is expressed in many tissues,
including kidney, urinary bladder, intestine, brain, lung, spleen and testis
(Konno et al., 2006). P.
annectens also exhibits a broad distribution pattern, although the sites
of expression are somewhat different from those in amphibians: lfUT
is expressed not only in the skin but also in both gill and kidney, as well as
in the liver and muscle (Fig.
4). This discrepancy in urea transporter expression probably
indicates different major sites of urea excretion in amphibians
versus lungfish. The absence of urea transporter expression in the
skin of teleosts and amphibians but its presence in the lungfish signifies the
importance of the skin as a major site for facilitated urea excretion in the
lungfish.
Urea-N and ammonia-N fluxes during re-immersion after terrestrialization
When kept in water under normal fed conditions, P. annectens is
ammoniotelic with >50% of nitrogenous waste excreted as ammonia-N
(Loong et al., 2008;
Iftikar et al., 2008). It is
interesting therefore that the 33 day fasted control animals of the present
study were actually ureotelic, excreting about 71% urea-N (119.6±2.6
µmol urea-N kg–1 h–1 versus
48.9±4.4 µmol ammonia-N kg–1 h–1).
Notably, however, this apparent `switch' to ureotelism was not due to an
elevation in urea-N excretion, which remained unchanged relative to fed
control rates (129.9±9.6 µmol-N kg–1
h–1), but rather was due to a reduction in ammonia-N
excretion significantly below fed control rates (155.2±11.8 µmol-N
kg–1 h–1). Loong and colleagues
(Loong et al., 2008) noted a
similar change, with 57% urea-N excretion in P. annectens during
a comparable fasting protocol. Thus the ratio between urea-N and ammonia-N
excretion is very sensitive to feeding and fasting states in aquatic lungfish.
Indeed the balance may also shift towards ureotelism during the digestion of a
large meal (Lim et al., 2004;
Iftikar et al., 2008).
However, during prolonged aestivation or terrestrialization (when fasting also
occurs), it is now clearly established that urea-N, and not the more toxic
ammonia-N, progressively accumulates in the body tissues (see Introduction for
references). Upon return to water, this accumulated urea-N burden is
excreted.
The present N excretion data following re-immersion in terrestrialized
P. annectens, showing a large but delayed and prolonged increase in
urea-N efflux (Fig. 5) with
only minor changes in ammonia-N efflux, are very similar to those reported
earlier in the congeneric P. dolloi
(Wood et al., 2005). In the
present study, these measurements were continued for a much longer duration,
showing that while the urea-N excretion surge reached its peak in the first 24
h, it did not fully attenuate until about 70 h post-terrestrialization
(Fig. 5). Furthermore, the
generally similar pattern between series 2 (where the fish were biopsied) and
series 1 (where they were left undisturbed) suggests that the urea-N excretion
mechanism was not greatly perturbed by handling
(Fig. 5). It is possible that
the initial transient elevation in urea-N excretion in series 2 could have
resulted from disturbance, but the rates at this time were not significantly
greater than those in series 1 (Fig.
5) and, furthermore, a similar transient initial rise was seen in
undisturbed P. dolloi immediately after re-immersion
(Wood et al., 2005). It seems
likely that similar mechanisms are at play in the two species, and that the
slow, prolonged surge represents increased activity of a UT-A facilitated
diffusion urea transport system, mainly in the skin, as argued below.
The magnitude of the `excess' urea-N excretion in both series was
remarkable (81,000–91,000 µmol urea-N kg–1), in
accordance with the early data of Smith
(Smith, 1930) and Janssens
(Janssens, 1964) on
post-aestivation P. aethiopicus. This value is in line with plasma
and tissue urea-N concentrations (50,000–200,000 µmol urea-N
kg–1) measured after comparable air exposure treatments in
both P. dolloi (Chew et al.,
2004; Wood et al.,
2005; Wilkie et al.,
2007) and P. annectens
(Loong et al., 2008). The
tests of Wood and colleagues (Wood et al.,
2005) on P. dolloi indicated that simple diffusion or
kidney excretion could explain only a small fraction of this. Inasmuch as the
majority (72%) of this high urea-N efflux occurred through the posterior 85%
of the body, did not occur through the kidney, and occurred in concert with a
greatly elevated excretion of two urea analogues but not the paracellular
permeability marker PEG-4000, the evidence pointed to increased activity of a
specific urea transporter in the skin
(Wood et al., 2005). The
measured analogue permeability order of urea>thiourea>acetamide was
typical of UT-A type facilitated diffusion transporters in the gills of
ureotelic teleosts (McDonald et al.,
2000; Walsh et al.,
2001a) and mammalian kidney
(Chou and Knepper, 1989). The
present study provides further evidence for this idea, inasmuch as
lfUT was expressed in the skin, and exhibited a significant increase
in mRNA expression level (Fig.
6) at the time of peak urea-N excretion
(Fig. 5).
The role of lfUT in increased urea excretion
Although modest, the 2.55-fold increase in lfUT expression in
lungfish skin at 14 h post-terrestrialization
(Fig. 6) coincident with the
surge of urea-N excretion (Fig.
5) was in accordance with our original hypothesis, and very
different from the situation in teleost fish
(McDonald et al., 2006). This
difference may reflect the different time course of the response, which is
slow enough to allow increased mRNA and protein synthesis in the lungfish. In
mammals, transcriptional activation of UT-A is generally slow, and associated
with the action of antidiuretic hormone (ADH), glucocorticoids and cAMP on
promoter regions (Bagnasco,
2003; Bagnasco,
2005). Transcriptional activating mechanisms for UT-A expression
are unknown in lungfish, but in amphibians the ADH analogue arginine vasotocin
appears to be involved (Uchiyama, 1994;
Konno et al., 2006). In
toadfish, the expression of the branchial tUT mRNA transcript is
constant, and not correlated with the rapid, short-lasting (1–3 h)
pattern of pulsatile urea-N excretion across the gills
(Walsh et al., 2000). McDonald
and colleagues (McDonald et al.,
2006) have reviewed the evidence that both a decline in
circulating cortisol (as a permissive agent) and the release of serotonin
(5-HT, as a neuroendocrine activating agent) may quickly turn on the toadfish
gill tUT at the time of a urea-N pulse, probably by
post-translational mechanisms. In the Magadi tilapia, the gill mtUT
appears to be continually turned on, to deal with the very high rates of
continuous urea-N excretion required by these 100% ureotelic teleosts
(Walsh et al., 2001a).
However, similar to the response in lungfish skin, modest transcriptional
activation (2-fold) of UT-As has been seen in the kidney and urinary
bladder of the marine toad Bufo marinus
(Konno et al., 2006), and in
the kidney of the red-eared slider turtle Trachemys scripta elegans
(Uchiyama et al., 2009)
exposed to dehydrating conditions for 7 days. These slow increases in UT mRNA
expression in the toad and the turtle were associated with the accumulation of
urea in urinary bladders, while in lungfish urea was excreted across the skin
(Wood et al., 2005).
In the present study there was no difference in lfUT expression
(Fig. 6) between fed control
lungfish and 33 days terrestrialized lungfish at 0 h (i.e. immediately after
return to water) despite the fact that terrestrialized lungfish are known to
have 4- to 11-fold greater plasma urea concentrations at this time
(Wood et al., 2005;
Wilkie et al., 2007;
Loong et al., 2008).
Furthermore, there was no elevation in urea-N excretion at this time or for
the next 8 h (Fig. 5). This
suggests that despite the large gradient, the availability of functional
lfUT carrier proteins was initially limiting upon return to water for
the flux of this poorly diffusible molecule, perhaps due to the general
metabolic depression occurring during terrestrialization
(Staples et al., 2008). Indeed
it took at least 14 h for urea-N excretion to reach a peak
(Fig. 5), and the modest
increase in lfUT mRNA expression at this time
(Fig. 6) was sufficient to
facilitate an enormous amount of urea-N excretion. lfUT mRNA
expression was no longer significantly elevated at 48 h
(Fig. 6). Our interpretation is
that, by this time, the functional UT protein level was probably sufficient
for the remaining urea to be excreted without having to make more
lfUT transcripts, and as accumulated urea was excreted and the
gradient fell, the rate of excretion similarly fell through to 70 h
(Fig. 5). However, it certainly
remains possible that post-translational mechanisms acting at the
lfUT protein level may also have been involved. In future
experiments, it will be of interest to investigate the signalling mechanisms
for these events.
Although RT-PCR is only a semi-quantitative technique, the absence of marked changes in lfUT expression in the various tissues immediately after terrestrialization (Fig. 3) is notable, and in accordance with the more sensitive real-time PCR results for the skin at 0 h (Fig. 6). In future studies, it will be of interest to use real-time PCR to evaluate whether lfUT expression increases later during re-immersion in other tissues as it does in the skin (e.g. at 14 h), coincident with greatly elevated urea-N excretion at this time.
In summary, in accordance with our original hypotheses (see Introduction) we have cloned a cDNA encoding UT-A in lungfish P. annectens (lfUT), shown that it bears greatest sequence similarity to the UT-As of amphibians, and demonstrated that the expression of lfUT in the skin is correlated with the greatly elevated rate of urea-N excretion during re-immersion after a prolonged period of terrestrialization in air.
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Footnotes |
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References |
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TOPSummaryINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONReferences |
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