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First published online May 18, 2006
Journal of Experimental Biology 209, 2129-2137 (2006)
Published by The Company of Biologists 2006
doi: 10.1242/jeb.02243
Hypoxia induces a complex response of globin expression in zebrafish (Danio rerio)
1 Institute of Zoology, University of Mainz, D-55099 Mainz,
Germany
2 Institute of Molecular Genetics, University of Mainz, D-55099 Mainz,
Germany
* Author for correspondence (e-mail: burmeste{at}uni-mainz.de)
Accepted 29 March 2006
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8.6 kPa) or severe
(PO2=4.1 kPa) hypoxia. Neuroglobin and myoglobin
protein levels were investigated by western blotting. Whereas mild hypoxia
caused only minor changes of mRNA levels, strong hypoxia enhanced mRNA levels
of the control genes (lactate dehydrogenase A and phosphoglycerate kinase 1).
Surprisingly, levels of hemoglobin 
and ß mRNA were significantly
reduced under severe hypoxia. Myoglobin mRNA and protein in heart mildly
increased, in line with its proposed oxygen supply function. Likewise,
neuroglobin mRNA and protein significantly increased in brain (up to 5.7-fold
at the protein level), but not in eye. This observation, firstly, suggests
physiological differences of zebrafish eye and brain under hypoxia, and
secondly, indicates an important role of neuroglobin in oxidative metabolism,
probably oxygen supply within neurons. There was little change in the
expression of the two cytoglobin genes. Globin X mRNA significantly decreased
under hypoxia, pointing to a functional linkage to oxygen-dependent
metabolism.
Key words: cytoglobin, hemoglobin, myoglobin, neuroglobin, oxygen, zebrafish, Danio rerio
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Introduction |
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TOPSummaryIntroductionMaterials and methodsResultsDiscussionReferences |
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;
Nilsson and Renshaw, 2004;
Cossins and Crawford, 2005;
Nikinmaa and Rees, 2005). Low
oxygen levels cause a decrease of activity, enhanced ventilation and reduction
of the metabolic rate (Jensen et al.,
1993; Dalla Via et al.,
1994; van den Thillart and van
Waarde, 1985; Smith et al.,
1996; Ton et al.,
2003; van der Meer et al.,
2005). Prolonged hypoxia, which extends more than a few days, may
also induce anatomical changes such as expansion of the gill surface
(Sollid et al., 2005;
van der Meer et al.,
2005).
It is not surprising that hypoxia causes major changes of gene expression
in fish (Gracey et al., 2001;
Ton et al., 2003;
Nikinmaa and Rees, 2005;
van der Meer et al., 2005),
which allow the animals to save oxygen and to better cope with periods of
oxygen shortage. For example, genes encoding enzymes for glycolysis and
fermentation were found to be more strongly expressed after long term hypoxia
in adult goby fish, Gillichthys mirabilis
(Gracey et al., 2001), adult
zebrafish, Danio rerio (van der
Meer et al., 2005), and after 24 h of anoxia (0% O2) in
zebrafish embryos (Ton et al.,
2003). By contrast, among others, genes required for
oxygen-dependent energy production (e.g. the TCA cycle or the mitochondrial
respiratory chain) and protein translation were repressed. Hypoxia also causes
developmental arrest, as reflected by the repression of cell cycle-related
genes (Padilla and Roth, 2001;
Ton et al., 2003).
Respiratory proteins enhance the availability of oxygen to the electron
transport chain in the mitochondria. All respiratory proteins of vertebrates
belong to the superfamily of globins, which harbor a porphyrin-ring with a
Fe2+ ion. Five globin classes are known to be present in fish
(Fig. 1). Hemoglobin (Hb)
consists of two and two ß chains, is located in the erythrocytes
and greatly increases the oxygen capacitance of the blood. It enables the
efficient transport of oxygen from the respiratory surfaces (lungs, gills,
skin) to the inner organs. The monomeric myoglobin (Mb) is mainly situated in
striated muscle and heart. It is supposed to store oxygen and to facilitate
intracellular oxygen diffusion (Wittenberg
and Wittenberg, 2003). Neuroglobin (Ngb) is located in the central
and peripheral nervous system (Burmester et
al., 2000), the retina
(Schmidt et al., 2003) and
some endocrine tissues (Reuss et al.,
2002). Ngb may have a Mb-like role in enhancing the availability
of oxygen to the metabolically active neurons, although other functions such
as the detoxification of reactive oxygen or nitrogen species (ROS, RNS) or
oxygen signaling have been proposed (for reviews, see
Burmester and Hankeln, 2004;
Hankeln et al., 2005).
Cytoglobin (Cygb) is expressed in fibroblast-related cells and some neurons
(Burmester et al., 2002;
Schmidt et al., 2004). Its
function may be related to ROS detoxification or oxygen supply to particular
enzymatic reactions (Schmidt et al.,
2004; Hankeln et al.,
2005). Globin X (GbX) is restricted to fish and amphibia
(Roesner et al., 2005). Its
function is currently unknown.
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), whereas
data on Mb expression under hypoxia are variable
(Hoppeler and Vogt, 2001;
Levine and Stray-Gundersen,
2001). Results on hypoxia regulation of Ngb in mammalian systems
are also not consistent. Whereas Ngb was found to be more highly expressed in
hypoxic cell and tissue culture systems
(Sun et al., 2001;
Fordel et al., 2004), no
changes in Ngb mRNA levels were found in whole animal experiments
(Mammen et al., 2002). Cygb
mRNA levels increase in hypoxic liver and heart of rat and mice
(Schmidt et al., 2004),
whereas the observed changes of Cygb mRNA levels in the brain were not
significant (Fordel et al.,
2004) (A. Avivi, F. Gerlach, S. Reuss, T. Burmester, E. Novo and
T. Hankeln, unpublished data).
Most mammals are not adapted to environments with low or changing oxygen
partial pressures. Therefore, at least some of the data on globin expression,
particularly those on Ngb and Cygb, have been obtained from animals that will
never be subject to any hypoxic conditions during their adult live. Here, we
investigate the response of globin mRNA and protein (for Mb and Ngb) levels to
hypoxia in the zebrafish Danio rerio. The zebrafish may actually
experience low oxygen levels in its warm and tropical environment and it has
an astonishing ability to withstand hypoxia
(Padilla and Roth, 2001;
Rees et al., 2001;
Pelster, 2002;
Ton et al., 2003;
van der Meer et al., 2005).
Moreover, D. rerio has become a prime model for investigation of
physiological adaptations at the molecular level.
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Hypoxic treatment
Groups of four fish were randomly assigned to hypoxia treatment or control
groups. Hypoxia treatment was performed in a 10 l glass aquarium, covered with
loosely fitting acrylic covers. Gas mixtures (2% O2 in
N2 or 5% O2 in N2, Air liquide, Dusseldorf,
Germany) were bubbled through water. A thermopump (Ekip 200, Hydor, Bassano
Del Grappa, Italy) was used to circulate the water and to keep the temperature
constant at 22°C. Oxygen partial pressure and temperature were measured
every 5 min by an oxygen sensor (Oxi 340i, WTW, Weilheim, Germany). Fish were
not fed for 24 h before the start of, or during, the experiment. Experiments
started at an oxygen partial pressure of 18.4 kPa (138 Torr). The water was
aerated to achieve 4.1 kPa (31 Torr, bubbled with 2% O2) or
8.6 kPa (65 Torr, bubbled with 5% O2), respectively, after 1
h. Oxygen partial pressure remained constant (±0.6-0.8 kPa) throughout
the experiment. Control zebrafish were kept under the same conditions, but the
water was gassed with room air (PO2=18.4 kPa). After
24 h or 48 h, fish were directly frozen in liquid nitrogen. For the
experiments employing total eyes, brain or heart, the specimens were cooled on
ice and killed by decapitation. For each fish, organs were removed within less
than 2 min, shock-frozen in liquid N2 and kept at -80°C until
use.
RNA extraction
RNA samples from total animals or single organs were extracted using the
RNeasy Mini Kit by Qiagen (Hilden, Germany). Fish were weighed and homogenized
in the required volume of RLT buffer (Qiagen) with a rotor stator. To avoid
contamination with genomic DNA, a DNase digestion was performed on the column
(Qiagen). Quality and amount of RNA were checked photometrically and with RNA
gel electrophoresis.
cDNA cloning and sequencing
The complete cDNA sequences of the genes used in this study [acidic
ribosomal protein [ARP (also known as rplp0), EMBL/GenBank
acc. no. BC049058], cyclophilin (AY391451), Hb [hba
(hbaa1), NM_131257), Hbß [hbb(ba1),
NM_131020], Mb (AY337025), Ngb (NM_131853), Cygb1 (AJ320232), Cygb2 (AJ635229)
and GbX (NM_001012261)] were obtained by amplification from total RNA with the
OneStep RT-PCR kit (Qiagen) using specific primers (see Table S1 in
supplementary material). After cloning into standard vectors (pCR4-TOPO,
Invitrogen, Karlsruhe, Germany, or pGEM Teasy, Promega, Mannheim, Germany) the
sequences were determined by a commercial service (Genterprise, Mainz,
Germany). The cDNA plasmids were used for generating standard curves for use
in real-time PCR (see below). The cDNAs of the genes used as positive controls
[lactate dehydrogenase A (ldha, NM_131246) and phosphoglycerate
kinase 1 (pgk1, NM_213387)] were not cloned.
Quantitative real-time PCR
RNA extractions and cDNA synthesis were carried out from single specimens,
except for the control group for which the RNA samples were combined before
cDNA synthesis. In the experiments with brains or total eyes, both the hypoxia
and control group animals were treated individually. Quantitative real-time
RT-PCR was performed with a two-step protocol. First, total RNA was converted
into cDNA employing Superscript II RNase H- reverse transcriptase
(Invitrogen) and an oligo(dT16) primer according to manufacturer's
instruction. The cDNA samples were diluted with the same volume of DNase-free
water. Real-time RT-PCR experiments were carried out on an ABI Prism 7000 SDS
(Applied Biosystems, Darmstadt, Germany) using the ABsoluteTM QPCR
SYBR® Green ROX Mix (Abgene, Hamburg, Germany). Levels of mRNA of ARP,
cyclophilin, LDHA, PGK1, Hba, Hbb, Mb, Ngb, Cygb1, Cygb2 and GbX were
evaluated. ARP and cyclophilin were employed as putatively
non-regulated reference genes (Simpson et
al., 2000). To avoid amplification of genomic DNA, all primer
pairs included one intron-spanning oligonucleotide. The oligonucleotide
primers were obtained from Sigma-Genosys (Hamburg, Germany) (see Supplemental
Table S1 in supplementary material). Reactions were run in triplicate with one
or two repetitions, using 1 µl of diluted cDNA as template in a reaction
volume of 30 µl. Primer concentrations were 0.13 µmol l-1 for
each oligonucleotide. The Taq-polymerase was activated for 15 min at 95°C,
followed by 40 cycles of a standard PCR protocol (94°C 15 s, 60°C 30
s, 72°C 30 s). Efficiency of reaction was measured by the slope of a
standard curve. For standard curves, only duplicates were run, using fivefold
cDNA dilutions (positive controls ldha and pgk1) or tenfold
dilutions of plasmids (all other genes). Specificity of the amplification
reaction was analyzed using dissociation curves with a temperature range from
60°C to 95°C. First evaluation of results was performed in the ABI
Prism 7000 SDS program; for normalization and calibration, data were exported
to qBase
(http://www.medgen.ugent.be/qbase/).
Final data analyses were carried out with the Microsoft Excel XP spreadsheet
program. The significance of the data was evaluated using Student's
t-test.
Protein extraction and western blotting
After the hypoxia treatment, zebrafish used for protein analyses were
cooled down on ice and immediately dissected. Total eyes, brains and hearts
were removed and stored at -20°C. Tissues were homogenized in 1x
phosphate-buffered saline (PBS; 140 mmol l-1 NaCl, 2.7 mmol
l-1 KCl, 8.1 mmol l-1 Na2HPO4, 1.5
mmol l-1 KH2PO4) with ultrasonication and
precipitated for 10 min at 13,000 g at 4°C. Protein
concentrations of the supernatant were determined with the Bradford method
(Bradford, 1976).
Protein extracts (100 µg per lane) were heat-denatured in sample buffer
(31.25 mmol l-1 Tris-HCl, pH 6.8, 1% SDS, 2.5%
ß-mercaptoethanol, 5% glycerol) for 5 min at 95°C and loaded onto a
15% SDS polyacrylamide gel. Antibody detection was carried out on protein
samples transferred to nitrocellulose membrane for 2 h at 0.8 mA
cm-2. Non-specific binding sites were blocked by incubating for 45
min with 2% bovine serum albumin (BSA) in TBS (10 mmol l-1 Tris, pH
7.4, 140 mmol l-1 NaCl). Membranes were then incubated for 2 h with
anti-Ngb antibodies (Fuchs et al.,
2004) or anti-zebrafish-Mb serum (raised against recombinantly
expressed D. rerio Mb; unpublished), both diluted 1:500 in 2%
BSA/TBS, and washed four times for 5 min with TBS. Membranes were incubated
with the goat anti-rabbit antibody coupled with alkaline phosphatase (Dianova,
Hamburg, Germany) for 1 h, diluted 1:10 000 in 2% BSA/TBS, and washed as
described above. Detection was carried out with nitroblue-tetrazolium chloride
and 5-bromo-4-chloro-3-indolyl-phosphate salt as substrates. The filters were
scanned at 1,200 d.p.i. and the images were imported into the Scion Image
program (version Beta 4.02) and an analysis of grey values was performed to
obtain an estimate of the protein levels. The mean grey values of the
background of empty gel lanes were subtracted from the measurements of the Ngb
or Mb protein levels. Data were imported into Microsoft Excel XP and Student's
t-test was used to assess significance.
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2.4 kPa
(18 Torr) was lethal for more than 80% of the animals after 24 h
(N=8). At 4.1 kPa O2 partial pressure and at
22°C, the survival rate was >80% after 48 h hypoxia exposure
(N=43). Therefore, the latter regime was applied as maximum (severe)
hypoxic conditions.
Changes of gene expression in the hypoxic zebrafish
Evaluation of real-time RT-PCR results showed that ARP expression does not
change under hypoxia (PO2=4.1 kPa or 8.6 kPa),
whereas we observed a mild but significant upregulation of cyclophilin (Figs
2 and
3). Therefore, all expression
levels were subsequently normalized according to ARP. Microarray data had
demonstrated that expression levels of LDH-A and PGK1 mRNA were highly
enhanced in zebrafish under hypoxia (Ton
et al., 2003). These mRNAs were used in our experiments as
positive controls to verify hypoxia exposure and response. In fact, at
PO2=4.1 kPa for 48 h, we saw significant upregulation
of the expression of both LDHA and PGK1 mRNA by a factor of 2.5 and 3.8,
respectively (Figs 2 and
3). PGK-1 levels increase even
under mild hypoxia (48 h, PO2=8.6 kPa; 1.9-fold
compared with the normoxic control) or after a shorter time-period (24 h,
PO2=4.1 kPa) (2.1-fold compared with the normoxia).
The large standard deviations reflect differences of mRNA levels among
individuals. However, the results were significant according to a Student's
t-test, as indicated in Figs
2 and
3.
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Globin-mRNA levels in zebrafish under different hypoxia regimes
We found only minor changes in globin mRNA levels in animals exposed to
PO2=8.6 kPa for 48 h
(Fig. 2). There was an
approximate 50% decrease in Hb and Hbß mRNA levels, which was,
however, not significant. Under severe hypoxia
(PO2=4.1 kPa), the changes in globin mRNA were much
more pronounced (Fig. 3). Hb
mRNAs decreased after 24 h by 20%, to 30% compared to the normoxia control,
and after 48 h at PO2=4.1 kPa they were reduced by
between 65% and 75% (P<0.005 and P<0.001). Mb mRNA
levels increased about 2.5-fold under short- and long-term severe hypoxia,
although this change was not significant because of the large standard
deviation. Ngb mRNA increased after 24 h strong hypoxia by about fourfold, but
the standard deviation results in a borderline significance
(P=0.065). After 48 h at 4.1 kPa PO2, the Ngb
mRNA levels were nearly back to normoxia levels, with only about a 1.3-fold
increase. Zebrafish possess two paralogous Cygb genes
(Fuchs et al., 2005). For
Cygb1 mRNA, we see a mild upregulation under hypoxia, which was, however, not
significant. Cygb2 mRNA levels remained almost unaltered. GbX mRNA expression
was unchanged at PO2=8.6 kPa, but significantly
decreased at PO2=4.1 kPa to a level of about 10% of
the normoxia control after 48 h (P<0.001).
Expression of Ngb mRNA in brain and eye
We further analyzed the expression of Ngb mRNA separately in brain and eye
of zebrafish that had been kept for 24 h at PO2=4.1
kPa. Total brains and eyes were immediately removed from zebrafish and
shock-frozen in liquid N2. Expression of selected genes was
analyzed in individuals by quantitative real-time PCR. Again, we found a
strong variation in gene expression levels between individuals of the same
group (Fig. 4). The
positive-control genes ldha and pgk1 were found to be
significantly upregulated in both tissues (data not shown). Ngb mRNA levels
were essentially the same in the normoxic and hypoxic eyes
(Fig. 4). However, in brain we
saw about threefold higher mRNA level in tissues from hypoxic animals compared
to the control (P<0.01).
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Quantitative western blotting
Proteins were extracted from brains, total eyes and hearts of individual
zebrafish that had been kept for 48 h at severe hypoxia
(PO2=4.1 kPa). To analyze changes in protein levels,
we performed quantitative western blots, applying a constant amount of total
protein extracts (100 µg per lane; Fig.
5). We observed a mildly (20%) but significantly
(P<0.05) higher level of myoglobin in the hearts from hypoxic
zebrafish compared to control animals that had been kept for the same time
under normoxia (PO2=18.4 kPa). Ngb protein levels
were somewhat higher in the protein extracts from the hypoxic eye than in
those of the normoxia control (1.6-fold), but this increase was not
significant (P=0.11). In the brain, however, we consistently observed
5.7-fold more Ngb protein in the hypoxic than in the normoxic animals. This
increase was highly significant, as estimated by a Student's t-test
(P<0.001).
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;
Nilsson and Renshaw, 2004;
Cossins and Crawford, 2005). A
previous study reported that adult zebrafish survive a PO2
of 2 kPa at 22°C for 48 h (Rees et
al., 2001), whereas in our hands PO2=2.4
kPa at 22°C caused >80% mortality after less than 24 h. This
discrepancy may be explained by differences in zebrafish strains. We have
chosen an oxygen partial pressure of 4.1 kPa (4.15 kPa) as the severe
hypoxic condition for our experiments. The strong upregulation of the typical
hypoxia-responsive genes ldha and pgk1, which is in line
with a recent microarray study (Ton et
al., 2003), demonstrates that under these conditions zebrafish
were actually experiencing serious hypoxic stress.
We observed a large standard deviation in all our quantitative real-time
PCR experiments employing zebrafish. A similarly large variability has been
noted for various fish species in a number of microarray studies
(Oleksiak et al., 2002;
Cossins and Crawford, 2005).
These variations in mRNA levels certainly reflect genetic, physiological or
behavioral differences between individuals. Nevertheless, most changes in
globin mRNA levels were significant, and, in the case of Mb and Ngb, agreed
with parallel western blot experiments. Moreover, we observed very similar
values for the expression levels of Hb and Hbß, as expected for
the products of such tightly co-regulated genes
(Hardison, 1998). It should
also be noted that variability in Mb and Ngb protein content was much smaller
than the variation in mRNA levels, suggesting additional regulation at the
translational level.
Understanding the role of respiratory proteins in hypoxia response
Maintaining a constant flow of oxygen from the water to the respiratory
chain of the mitochondria is a major challenge for fish living under hypoxia.
Respiratory proteins already enhance oxygen availability under normoxia, and
changes in their concentration or physiological properties are expected under
hypoxia. It is well established that Hb transports oxygen in the circulatory
system and that Mb enhances oxygen supply to striated muscle cells, which is,
in the case of fish, mainly the heart. Much less is known about the recently
discovered novel members of the globin family, Ngb, Cygb and GbX
(Burmester and Hankeln, 2004;
Hankeln et al., 2005), which
are present in fish (Awenius et al.,
2001; Burmester et al.,
2002; Fuchs et al.,
2004; Fuchs et al.,
2005; Roesner et al.,
2005). Their expression response in an animal system that is
evolutionarily adapted to at least temporarily low oxygen partial pressures
provides hints to their general physiological functions in vertebrates and
their particular roles in hypoxic response.
Hemoglobin mRNA is downregulated under hypoxia
A surprising finding of our study is that Hb and ß mRNA levels
were significantly lower after 2 days of hypoxia compared to the normoxia
controls. The response of Hb to hypoxia exposure in fish is not clear
(Nikinmaa and Rees, 2005).
Whereas some studies reported an increase of Hb under hypoxia (e.g.
Timmerman and Chapman, 2004),
others did not see any change in Hb concentration (e.g.
Person-Le Ruyet et al., 1998),
or a differential responses depending on exposure times (e.g.
Affonso et al., 2002). Thus
hypoxia response of Hb in fish may be species specific. Down-regulation of Hb
mRNA in zebrafish has previously been reported in a microarray study employing
embryos (Ton et al., 2003).
The authors explained this observation by stating that zebrafish embryos, 24 h
post-fertilization, did not require blood flow, but oxygen uptake was achieved
by diffusion. However, there is no doubt that adult zebrafish, which display
the same decrease of Hb mRNA (Figs
2 and
3), rely on blood circulation.
Therefore, an alternative hypothesis to explain Hb regulation in hypoxic
zebrafish is required.
First, we have to emphasize that we only monitored Hb mRNA. Protein levels
may actually behave quite differently. Another explanation could be the
induction of distinct Hb chains. Database searches revealed six copies of the
Hb gene and five of the Hbß gene. According to the annotation, two
and three ß hemoglobins are embryonic hemoglobins, leaving
multiple copies of each gene that are potentially expressed in the adult
zebrafish. The oligonucleotide primers we used for quantitative PCR were
designed to amplify all adult Hb and ß chains. Even a differential
behavior of adult Hb genes would not alter the observed overall
down-regulation of Hb. We cannot exclude that hypoxia, for example, induces
the expression of embryonic Hbs. In fact, it has been observed by gel
electrophoresis that hypoxia changes the pattern of Hb chains in trout
(Marinsky et al., 1990).
However, based on the observation of Ton et al.
(Ton et al., 2003) of a
down-regulation of embryonic Hbs in embryos, we consider this explanation less
likely.
Another possible explanation is that under hypoxia the amount of Hb exceeds
the available oxygen. Therefore, a rise in Hb concentration and thus oxygen
carrying capacity would have only minor effect on oxygen delivery, but would
be very energy costly. Numerous studies have demonstrated that hypoxia induces
in fish a change in oxygen binding properties of Hb
(Weber and Jensen, 1988;
Nikinmaa, 2001;
Jensen, 2004). Under hypoxia,
the concentrations of the modulators adenosine triphosphate (ATP) and
guanosine triphosphate (GTP) fall in red blood cells, leading to an increased
O2 affinity of Hb. This is a more efficient mechanism that improves
oxygen uptake by the blood. The decrease of Hb mRNA could be explained by an
energy-saving mechanism that ceases Hb synthesis. However, we should note that
we only investigated short-term changes, up to 2 days hypoxia. It is possible
that other regimes will reveal a distinct pattern of Hb expression. Clearly,
additional studies are required to fully understand the peculiar behavior of
Hb mRNA under hypoxia.
Hypoxia induces myoglobin expression in zebrafish heart
The function of Mb is to facilitate diffusion of oxygen from the
capillaries to mitochondria and to store oxygen, but it may also detoxify NO
(Wittenberg and Wittenberg,
2003). In mammals, the pattern of Mb regulation under hypoxia is
not conclusive. It is held that low-oxygen conditions, as they occur e.g.
during high altitude training, increase Mb levels
(Hoppeler and Vogt, 2001), but
not all agree (e.g. Levine and
Stray-Gundersen, 2001). In zebrafish, we observe that severe
hypoxia induces Mb mRNA and protein (Figs
2,
3 and
5). This observation is in line
with a major oxygen supply role of Mb for the heart. Because Mb is a monomeric
protein, it does not display an Hb-like cooperativity that would enhance its
oxygen affinity. The only possible mechanism to increase oxygen flow into the
cardiac muscle is therefore to raise Mb concentrations.
Hypoxia regulation of neuroglobin and implication for its function
In this study, we have investigated for the first time the changes of Ngb
expression in fish. Although this respiratory protein has been intensively
studied in recent years, its exact role in vertebrate neurons is far from
understood (Burmester and Hankeln,
2004; Hankeln et al.,
2005). The phylogenetic relationship of Ngb to invertebrate nerve
Hbs (Burmester et al., 2000),
positive correlation with the intensity of cellular metabolism
(Schmidt et al., 2003),
co-localization with mitochondria (Bentmann
et al., 2005) and ability to promote neuronal survival under
hypoxia or ischemia (Sun et al.,
2001) point to an Mb-like O2 supply function of Ngb.
However, other functions for Ngb, such as the detoxification of RNS and NO or
signaling have been proposed (for reviews, see
Burmester and Hankeln, 2004;
Hankeln et al., 2005).
The published data disagree on the regulation of expression of Ngb under
low oxygen conditions in mammalian systems. Sun et al. reported a 2.5-fold
upregulation of Ngb mRNA and protein under nominal anoxia in a primary
neuronal cell culture from mouse (Sun et
al., 2001). An upregulation of Ngb mRNA was also obtained in a
mouse neuronal cell line (Fordel et al.,
2004), although the changes were not significant. By contrast,
mice kept under sustained hypoxia (10% O2) for up to 2 weeks showed
no change in Ngb mRNA in the brain (Mammen
et al., 2002). However, in rat, we observed a down-regulation of
Ngb mRNA by about 40-60% after 5 h at 6% O2, or after up to 44 h at
10% O2 (A. Avivi, F. Gerlach, S. Reuss, T. Burmester, E. Nevo and
T. Hankeln, unpublished data).
We show here that Ngb behaves differentially in the zebrafish brain and
eye. Whereas in brain, Ngb mRNA levels showed a short-term upregulation after
24 h at PO2=4.1 kPa
(Fig. 4), no effect was
observed in the whole eye. This pattern perfectly matches the western blot
data (Fig. 5), which show a
5.7-fold increase of Ngb protein after 48 h severe hypoxia in brain but not in
eye. In the eye, the protein levels only slightly increased. The differences
might be explained by distinct behavior of these organs under hypoxia. The
crucian carp Carassius carassius, which also belongs to the
Cypriniformes, becomes blind under anoxia
(Johansson et al., 1997),
whereas the brain still functions
(Nilsson, 2001). By inference,
we assume that hypoxia causes a major decrease of metabolic activity of the
zebrafish eye, whereas the brain is more or less active. We have previously
demonstrated that the expression levels of Ngb in mammals are closely linked
to metabolic activity and oxygen consumption
(Schmidt et al., 2003;
Bentmann et al., 2005).
Therefore, high levels of Ngb are obviously required to preserve the oxidative
metabolism in the zebrafish brain.
Our data show for the first time that Ngb is actually a hypoxia-inducible
gene in vivo under naturally occurring conditions. This observation
perfectly agrees with the hypothesis of Ngb being an O2 supply
protein of the neurons, similar to the function of Mb in the muscle cells
(Burmester et al., 2000;
Sun et al., 2001;
Schmidt et al., 2003;
Bentmann et al., 2005). In
fact, Ngb behaves in the brain in a largely similar way to Mb in the heart.
Nevertheless, it should also be considered that several studies reported that
under low oxygen conditions (hypoxia or ischemia) the concentrations of ROS
and NO may increase (Jezek and Hlavata,
2005; Wenger,
2006). Therefore, it is still conceivable that Ngb breaks down
these deleterious compounds (Herold et
al., 2004; Brunori et al.,
2005). Regardless of its actual function at the molecular level,
Ngb is presumably neuroprotective for both fish and mammals.
The other globins: cytoglobin and globin X
Fish possess two paralogous Cygb genes, which duplicated early in teleost
evolution (Fuchs et al.,
2005). In mammals, which have only a single gene copy
(Burmester et al., 2002), Cygb
expression increases under hypoxia in a variety of tissues
(Schmidt et al., 2004;
Fordel et al., 2004). We did
not observe significant changes of Cygb1 or Cygb2 mRNA levels (Figs
2 and
3), indicating that Cygb is not
involved in acute hypoxia response of zebrafish. GbX has only recently been
discovered in fish and amphibians (Roesner
et al., 2005). It is expressed at a low level in a variety of
tissues, but its function is uncertain. The severe down-regulation of GbX mRNA
in hypoxic zebrafish points to a close relationship of the gene to
oxygen-dependent metabolism, but it is unlikely to be involved in oxygen
supply.
Conclusions
We have presented the first comprehensive study on the regulation of
globins under hypoxia in a single organism. Because zebrafish may actually
experience hypoxic periods in its environment, it is probable that the changes
in mRNA and protein levels we observed here reflect physiological responses.
This is in contrast to many mammalian studies, which have investigated species
that are unlikely to experience any hypoxic situation during adult life or
have used cell culture systems. The down-regulation of Hb mRNA in zebrafish
under hypoxia certainly requires additional studies. The increased expression
of Mb and Ngb under hypoxia is consistent with a proposed function of these
proteins in oxygen supply to the heart and brain, respectively. This finding
is remarkable in the case of Ngb, the function of which is still a topic of
hot debate. GbX gene expression is markedly reduced under oxygenated
conditions, providing a first hint to its physiological role.
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Acknowledgments |
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Footnotes |
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References |
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TOPSummaryIntroductionMaterials and methodsResultsDiscussionReferences |
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