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Plant Physiol. (1998) 116: 1259-1269
Evidence that the Plant Host Synthesizes the Heme Moiety of
Leghemoglobin in Root Nodules1
Maria A. Santana2,
Kaarina Pihakaski-Maunsbach3,
Niels Sandal,
Kjeld A. Marcker, and
Alison G. Smith*
Department of Plant Sciences, University of Cambridge, Downing
Street, Cambridge CB2 3EA, United Kingdom (M.A.S., A.G.S.); and Laboratory of Gene Expression, Department of Molecular Biology,
University of Aarhus, Gustav Wieds Vej 10, DK-8000 Aarhus, Denmark
(K.P.-M., N.S., K.A.M.)
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ABSTRACT |
Although
it is well established that the plant host encodes and synthesizes the
apoprotein for leghemoglobin in root nodules, the source of the heme
moiety has been uncertain. We recently found that the transcript for
coproporphyrinogen III oxidase, one of the later enzymes of heme
synthesis, is highly elevated in soybean (Glycine max
L.) nodules compared with roots. In this study we measured enzyme
activity and carried out western-blot analysis and in situ
hybridization of mRNA to investigate the levels during
nodulation of the plant-specific coproporphyrinogen oxidase and four
other enzymes of the pathway in both soybean and pea (Pisum
sativum L.). We compared them with the activity found in leaves
and uninfected roots. Our results demonstrate that all of these enzymes
are elevated in the infected cells of nodules. Because these are the
same cells that express apoleghemoglobin, the data strongly support a
role for the plant in the synthesis of the heme moiety of
leghemoglobin.
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INTRODUCTION |
The major tetrapyrrole synthesized in plants is chlorophyll, which
in leaf tissue may be present at 2.5 µmol/g fresh weight.
In contrast, the levels of other tetrapyrroles such as siroheme,
phytochromobilin, and heme are much lower, with an estimated 2 nmol/g
fresh weight for mitochondrial heme. However, in leguminous root
nodules, levels of heme may be elevated a few hundred-fold. Nodules are
unique, specialized organs that are the result of a symbiotic
association between plants of the family Leguminosae and
soil bacteria of the genera Sinorhizobium,
Rhizobium, Bradyrhizobium, and
Azorhizobium. The bacteria are present in the infected plant cell surrounded by the peribacteroid membrane, which is derived from the plant cell membrane. There they differentiate into bacteroids and express the enzyme nitrogenase, which enables them to fix atmospheric dinitrogen, thus allowing the plant host to grow without external reduced nitrogen. Nitrogenase is oxygen-sensitive, but the
vigorously respiring bacteroids require an adequate supply of oxygen.
This is achieved by the presence of leghemoglobin, which facilitates
oxygen diffusion to the endosymbiont. Leghemoglobin has been
immunolocalized to the cytosol of the infected plant cell, and is
absent from the bacteroid and peribacteroid space (for review, see
Appleby, 1984 ).
It is well established that the plant host encodes the gene for the
leghemoglobin apoprotein (Jensen et al., 1981), but the source of the
heme moiety has been the subject of much debate. Early biochemical work
found that plant nodule tissue could not synthesize heme, whereas the
rhizobia both made and exported heme (Cutting and Schulman, 1969).
Similarly, the bacteroid fraction of soybean (Glycine max
L.) nodules contained detectable levels of the enzyme ALA synthase, but
the plant cytosol had none (Nadler and Avissar, 1977). ALA is the first
committed precursor of all cellular tetrapyrroles (Fig.
1). The conclusion drawn from these studies was that the bacterial endosymbiont was responsible for the
synthesis of the heme group of leghemoglobin, leading to proposals that
leghemoglobin synthesis is a means of intimate contact between the
plant and bacterial host (Appleby, 1984; Haaker, 1988).
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| Figure 1.
Pathway of tetrapyrrole synthesis in higher
plants, showing the major end products (boxed) and relevant
intermediates and enzymes. In plants, algae, and most bacteria, the
first committed precursor ALA is synthesized from glutamate in the C5
pathway in three steps. However, in rhizobial species (as well as in
certain other bacteria, animals, and fungi) ALA is synthesized in a
single step by ALA synthase (dotted line). Urogen, Uroporphyrinogen.
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However, the conclusions were based on erroneous assumptions about
plant heme biosynthesis (for review, see O'Brian, 1996). In
particular, it is now known that plant cells synthesize ALA by a
completely different route, namely from glutamate via the so-called C5
pathway involving three enzymes (for review, see Kannangara et al.,
1988). Glutamate-dependent ALA synthesis has been shown to be present
at much higher levels in soybean nodules than in uninfected roots
(Sangwan and O'Brian, 1992), whereas bacterial ALA synthase activity
was essentially the same in nodules and in free-living bacteria.
Furthermore, the plant gene for one of the C5 pathway enzymes, GSA
aminotransferase, is induced during nodulation, concomitantly with
the increase in enzyme activity (Sangwan and O'Brian, 1993; Frustaci
et al., 1995). The same group also investigated the next enzyme in the
pathway, ALA dehydratase. They found that, although message levels were
relatively high in roots, there was no detectable protein. However, in
nodules both protein level and enzyme activity are markedly increased (Kaczor et al., 1994). The results of both these studies suggest that
the plant host responds during nodulation to the need for increased
heme biosynthesis.
We have reported the isolation and characterization of a soybean cDNA
that is strongly induced during nodulation, with a time course
comparable to the increase in leghemoglobin (Madsen et al., 1993). This
cDNA was identified as encoding coprogen oxidase, a later enzyme of
tetrapyrrole synthesis (Fig. 1), because it showed considerable
sequence similarity to the same enzyme isolated from yeast (Zagorec et
al., 1988) and was able to complement a yeast mutant with a deletion in
the coprogen oxidase gene (Madsen et al., 1993). It has since been
shown to encode a protein with coprogen oxidase activity (M.A. Santana
and A.G. Smith, unpublished data). The fact that it is induced in root
nodules suggests, as for GSA aminotransferase and ALA dehydratase, that
it plays a role in the requirement for increased heme synthesis in
these organs. To investigate this further, we carried out a careful biochemical and molecular analysis of the levels of coprogen oxidase enzyme during nodulation and also examined four other enzymes of the
pathway, namely ALA dehydratase, PBG deaminase, protogen oxidase, and
ferrochelatase (Fig. 1). This paper presents our findings.
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MATERIALS AND METHODS |
Growth of Plant Material and Nodulation
Soybean (Glycine max L., cv Merrill) seeds were surface
sterilized in hypochlorite and then soaked in water overnight. They were planted in trays containing sterile, lightweight, expanded clay
aggregate. Pea (Pisum sativum L., cv Feltham First) seeds were surface sterilized and soaked in water for 1 to 2 h. They were then sown in Levington compost (Fisons, Beverly, MA). Plants were
maintained in a greenhouse at approximately 25°C under a 16-h light,
8-h dark cycle or, alternatively, in complete darkness for the
production of etiolated plants. After 2 weeks of growth, soybean plants
were inoculated with Bradyrhizobium japonicum USDA110 and
pea plants were inoculated with Rhizobium leguminosum bv
viciae strain 3841. For growth under anaerobic conditions,
2-week-old soybean plants were placed in pots in which the roots were
submerged in water continuously bubbled with nitrogen to saturate it. A set of control plants was maintained under the same conditions but
bubbled with air.
Tissue extracts for enzyme assays and western analysis were prepared by
grinding fresh material in 50 mm Hepes-NaOH, pH 8.2, 6 mm MgCl2, and 5 mm
2-mercaptoethanol in a mortar with a pestle and a small amount of
acid-washed sand and centrifuging at 13,000g for 10 min.
They were stored at  70°C until needed.
Enzyme Assays and Analytical Methods
ALA dehydratase and PBG deaminase assays were carried out as
described by Smith (1988), and coprogen oxidase and protogen oxidase
were measured fluorimetrically as described by Smith et al. (1993).
Ferrochelatase was assayed spectrofluorimetrically using
deuteroporphyrin IX as the substrate by the method of Porra and
Lascelles (1968). Alcohol dehydrogenase was assayed as described by
Mohanty et al. (1993). All assays were carried out two to four times on
at least two independent extractions. Chlorophyll was measured by the
method of Arnon (1949). Protein was determined with a protein
estimation kit (Bio-Rad) according to the
manufacturer's instructions, using BSA as the standard. Heme was
measured with a hemoglobin kit (Sigma), following the manufacturer's
instructions.
Western Analysis
For western analysis, protein extracts (10-50 µg protein) were
subjected to electrophoresis, as described by Laemmli (1970), on 12.5%
polyacrylamide gels in the presence of SDS (1% [w/v] in the gel,
0.1% [w/v] in the electrode buffer), and then transferred to
nitrocellulose membranes (Schleicher & Schuell) using a semidry blotting apparatus (Atto Corp., Tokyo). Proteins were visualized with
Ponceau S and washed in TBS (20 mm Tris-HCl, pH 7.5, and 500 mm NaCl), and the nonspecific protein sites were
blocked overnight with 3% nonfat, powdered milk in TBS. The blots were
then challenged with antiserum raised against soybean coprogen oxidase
(M.A. Santana and A.G. Smith, unpublished data) at a 1:2000 dilution in
TBS containing 0.05% Tween 20 and 1% nonfat milk. Bound antibodies were visualized with goat anti-rabbit antibodies conjugated to alkaline
phosphatase (Bio-Rad) according to the manufacturer's instructions.
In Situ Hybridization
Pea and soybean root nodules of various sizes were harvested
26 d after inoculation and fixed with FAA (3.7% formaldehyde, 5%
acetic acid, and 50% ethanol) or with 4% para-formaldehyde and 0.25%
glutaraldehyde in 50 mm sodium phosphate buffer (pH 7.2)
for 4 h, dehydrated in graded ethanol and xylene series, and
embedded in Paraplast. Sections (7 µm) were attached to
poly-l-Lys-coated slides, deparaffinized with xylene, and
rehydrated through a graded ethanol series. Cross-sections of nodules
were hybridized with 35S-labeled antisense or
sense RNAs (see below), as described by van de Wiel et al. (1990) from
a modification of the method of Cox and Goldberg (1988). Sections were
pretreated with proteinase K, dehydrated, dried under a vacuum until
they were coated with NTB2 nuclear emulsion (Kodak), and exposed for 7 to 40 d at 4°C. Slides were developed in D19 developer (Kodak)
and fixed in Unifix (Kodak). Sections were stained with 0.25%
toluidine blue, dehydrated, and mounted with DPX (BDH, Toronto,
Ontario, Canada). They were viewed and photographed with an axioscope
(Zeiss) equipped with dark-field and epipolarization optics on
Fujicolour HG Super 100 film.
Sense and antisense RNA probes were prepared from the pea ALA
dehydratase cDNA clone pALAD209 (Boese et al., 1991; a gift from Dr. M. Timko, University of Virginia, Charlottesville), the pea PBG deaminase
cDNA clone pPD1 (Witty et al., 1993), and the soybean coprogen oxidase
cDNA clone pCOF (Madsen et al., 1993). RNA was transcribed in vitro
from each of these clones using SP6 or T7 polymerase, as appropriate,
in the presence of 35S-UTP (1250 Ci/mmol,
Amersham) and was degraded to about 150-nucleotide-long fragments
before hybridization.
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RESULTS |
Induction of Coprogen Oxidase during Nodulation
The maximum level of coprogen oxidase mRNA was seen at about 3 weeks after infection (Madsen et al., 1993), just as the number of
observable nodules starts to increase. This is also the time at which
the rate of heme synthesis is maximal (Nadler and Avissar, 1977;
Sangwan and O'Brian, 1992). However, the amount of transcript is not
necessarily a direct indication of the amount of enzyme; therefore, we
investigated this with western-blot analysis and a determination of
enzyme activity over the same time course of nodulation. Figure
2 shows the results of a representative
experiment. The levels of activity were virtually undetectable in
uninfected roots when the fluorimetric assay for coprogen oxidase was
used (Labbe et al., 1985), although with the more sensitive radioactive assay (Elder and Evans, 1978), it was possible to measure activity reproducibly (data not shown). However, within 1 week of inoculation with B. japonicum, coprogen oxidase activity started to
increase markedly, reaching a maximum at 3 weeks (Fig. 2A). The
increase in specific activity was 27-fold compared with uninfected
roots. Because there was also an increase in protein during the
development of nodules, if the activity is expressed per gram fresh
weight, then the increase is even more dramatic at 250-fold, although the shape of the curve over the whole time course is essentially the
same (data not shown). Thereafter, coprogen oxidase activity declined,
but there was considerable activity even at 7 weeks (when the nodules
are effectively senescent), more in fact than was found in green leaves
(see below).
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| Figure 2.
Changes in coprogen oxidase during the development
of soybean root nodules. A, Coprogen oxidase activity measured with the fluorimetric assay. Once determinate nodules were visible (after 2-3
weeks), these were removed from the roots, but the samples before this
included some root material. The sample before inoculation was root
alone. Each point is the mean of three assays of the same sample
extract; the variation between assays was less than 10%. B,
Western-blot analysis of coprogen oxidase on the same samples assayed
in A. Soluble proteins (10 µg) were separated by SDS-PAGE, blotted
onto nitrocellulose, and then challenged with polyclonal antibodies
raised against recombinant soybean coprogen oxidase. Bound antibodies
were visualized with alkaline phosphatase-linked second antibody
followed by colorimetric detection. The arrow indicates the 37-kD
coprogen oxidase protein.
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Because the assays were carried out on extracts from whole,
unfractionated nodules, it was not possible to determine whether the
enzyme activity was associated with the plant host or the bacterial
symbiont. We therefore carried out western-blot analysis. Samples of
the soluble protein extracts were subjected to electrophoresis and
transferred to nitrocellulose. The blot was then challenged with
antibodies raised against the 37-kD soybean coprogen oxidase (M.A.
Santana and A.G. Smith, unpublished data). These antibodies do not
cross-react with a protein of similar size in extracts of free-living
B. japonicum (data not shown). It can be seen (Fig. 2B) that
during the first 4 weeks there was a parallel increase in the levels of
enzyme protein, although there was not such an obvious decline in the
older nodules. The amount of coprogen oxidase protein was estimated by
densitometry to be 14 times greater in 3-week-old nodules than in
uninfected roots. Although this figure shows that no immunoreactive
protein was visible in the uninfected roots, when 3 times more protein
was used (30 µg), a band was detected (Fig.
3, lane 0). From these experiments, it
would appear that the nodule-induced increase in expression of the
soybean coprogen oxidase gene results directly in an increase in
plant-specific coprogen oxidase protein, with a concomitant increase in
enzyme activity within the nodule. Similar time courses of induction were observed after western-blot analysis of two of the earlier enzymes
of the pathway, GSA aminotransferase (Sangwan and O'Brian, 1993;
Frustaci et al., 1995) and ALA dehydratase (Kaczor et al., 1994).
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| Figure 3.
Effect of anaerobiosis on soybean roots.
Two-week-old soybean plants were placed in pots so that the roots were
submerged in water through which either air or nitrogen was bubbled. A, Activity of alcohol dehydrogenase in roots under aerobic ( ) or anaerobic ( ) conditions. The increase in alcohol dehydrogenase in
the latter samples confirmed that the roots were anaerobic (Russell et
al., 1990). Each point is the mean of two assays carried out on the
same extract. Levels of coprogen oxidase activity remained essentially
undetectable in these roots throughout the treatment. B, Western
analysis of coprogen oxidase. Soluble protein (30 µg) from roots
grown under anaerobic conditions (0-21 d) or leaves from plants grown
aerobically (L) or anaerobically (L+) for 21 d were challenged
with coprogen oxidase antibodies as described in the legend of Figure
2. prot, Protein.
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Correlation between Coprogen Oxidase Activity and Leghemoglobin
Synthesis
The observation that plant coprogen oxidase increases during
nodulation suggests that it has a role in enhanced heme biosynthesis, presumably for leghemoglobin. To investigate this further, we determined the levels of heme in different-aged nodules and calculated the rate of heme synthesis over the period 3 to 4 weeks postinoculation to be 0.73 nmol h 1 g1
fresh weight (Table I). For comparison,
the rate of chlorophyll synthesis in soybean leaves was determined,
both during greening of dark-grown etiolated plants and during leaf
expansion of light-grown plants, and both were found to be much higher
than that of heme synthesis in nodules. In contrast, coprogen oxidase
activity was much greater in the nodules than in the leaves. This was
also seen in the western analysis, in which the amount of coprogen oxidase per unit protein was estimated by densitometry to be 5 times
greater in 3-week-old nodules (Fig. 2B, lane 3) compared with
light-grown leaves (Fig. 3B, lane L).
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Table I.
Rates of tetrapyrrole synthesis and levels of
tetrapyrroles in soybean tissues
Soybean plants were grown as described in ``Materials and Methods''.
For the measurement of heme synthesis during nodulation, they were
grown in a greenhouse for 14 d before infection with B. japonicum. For chlorophyll synthesis during greening, plants were
grown in complete darkness for 7 d and then exposed to continuous
illumination. The rate was determined between 24 and 48 h, in the
exponential phase. For chlorophyll synthesis during leaf expansion of
light-grown plants, samples of leaves were taken at the newly emerged
stage and then again when they were fully expanded (7 d later). The enzyme activity values are the means ± se of four
samples, and those for heme and chlorophyll are the means of three
samples.
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The fact that the activity of coprogen oxidase in nodules was much
greater than that required to account for the rate of heme synthesis
might mean that the induction of coprogen oxidase activity is unrelated
to the need to synthesize more heme and is due to some other factor.
One possibility is that the low free-oxygen content within the nodule
is responsible for the induction. Coprogen oxidase uses molecular
oxygen as one of its substrates, and in yeast the enzyme is induced by
anaerobiosis (Zagorec and Labbe-Bois, 1986). It has been proposed that
this induction in yeast is to ensure a large excess of the enzyme to
scavenge any available oxygen so that heme synthesis may continue. We
therefore investigated the effect of anaerobiosis on levels of coprogen
oxidase by growing soybean roots in water through which either air or
nitrogen was continuously bubbled. Root samples were taken after 1, 3, 5, 7, and 21 d of treatment, when plants under anaerobic
conditions showed severe chlorosis of young leaves, growth retardation,
and early senescence of mature leaves. There was considerable induction of alcohol dehydrogenase activity in the roots compared with those grown in air-saturated water (Fig. 3A), demonstrating that they were
indeed under anaerobic stress (Russell et al., 1990). In contrast,
coprogen oxidase activity remained essentially undetectable with the
fluorimetric assay. This is also reflected in the western blot (Fig.
3B), in which the levels of enzyme protein remained unchanged,
considerably less than that present in leaves, either those from
anaerobically treated plants (L+) or from controls (L). In nodules
there was 3 to 10 times more coprogen oxidase activity and protein than
in green leaves (Table I). Similar results were obtained when a
suspension culture of soybean cells was grown under anaerobic
conditions. Although alcohol dehydrogenase activity was induced from 63 to 1385 nmol min1 mg1
protein after 8 d, as observed previously by Mohanty et al.
(1993), coprogen oxidase activity remained essentially undetectable
throughout the anaerobic treatment. Therefore, it is unlikely that the
induction of coprogen oxidase in nodules is due to the anaerobic
conditions but rather is due to a response to the need for increased
heme synthesis.
Levels of Other Tetrapyrrole Synthesis Enzymes in Root Nodules
To investigate this further, the activities of other heme
synthesis enzymes during the nodulation process were determined. Figure
4 shows the results of a representative
experiment expressed per gram fresh weight; essentially similar shaped
curves were seen for enzyme-specific activity (data not shown). The
activities of all of the enzymes followed very similar time courses
over the 5-week period: in each case there was an increase in activity starting at about 14 d, which was when the first nodules were visible on the roots. The levels peaked at 21 d, concomitantly with the initial appearance of leghemoglobin, and were more than sufficient to account for the rate of heme synthesis in nodules during
this period. The stimulation of the first three enzymes, ALA
dehydratase, PBG deaminase, and coprogen oxidase, was about 17-fold,
whereas it was only 3- to 4-fold for protogen oxidase and
ferrochelatase, respectively, probably because the activities of the
latter two enzymes were relatively high, even in uninfected roots. This
increase in enzyme activity was specific to the nodule tissue, because
the activities in the roots of the nodulated plants were essentially
unaltered compared with uninfected plants (Table II). When the levels in nodules were
compared with those in expanded green leaves, differences between the
enzymes were apparent. Both ALA dehydratase and PBG deaminase
activities were higher in leaves than in nodules, whereas for the two
oxidases and ferrochelatase the reverse was true.
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| Figure 4.
Activity of heme biosynthesis enzymes during the
development of soybean root nodules. Samples of root nodule were taken
as described in the legend of Figure 2 and assayed for the different enzyme activities. Each value is the mean of four replicate assays, except ferrochelatase, which is the mean of two replicates. The variation in assay values were in general less than 10%. This is a
representative experiment; essentially similar time courses were
observed on several occasions. fr wt, Fresh weight.
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Table II.
Activities of heme synthesis enzymes in soybean
tissues
The levels of heme synthesis enzymes were determined in roots and
expanded leaves of 2-week-old soybean plants and then again in nodules
and roots 3 weeks after inoculation with B. japonicum. The
values are the means ± se of the number of samples
indicated in parentheses. Because four molecules of PBG are required
for each tetrapyrrole molecule, in general, in most plant tissues examined the ALA dehydratase rate is much higher than that of the other
enzymes of the pathway (Smith, 1986, 1988).
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To determine whether this increase in heme synthesis enzymes was a
universal feature of nodule physiology or unique to soybean, enzyme
activities were determined during nodulation of pea roots with R. leguminosarum bv viciae. Table
III presents the activity of ALA
dehydratase, PBG deaminase, coprogen oxidase, and protogen oxidase in
uninfected pea roots and in nodules 21 d after infection. For each
enzyme, the activity was enhanced in the nodules, and as in soybean,
both coprogen and protogen oxidase activities were greater in nodules
than in green leaves.
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Table III.
Activity of heme synthesis enzymes in pea tissues
Pea plants were grown under a 16-h light, 8-h dark cycle as described
in ``Materials and Methods''. After 14 d, root and leaf samples
were taken for assay, and the plants were inoculated with R. leguminosarum bv. viciae. Nodules (approximately 2 mm
in diameter) were harvested after 3 weeks. The activities are the means
of two determinations. The variation between samples was less than
10%. n.d., Not detectable.
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In Situ Localization of Transcripts for Heme Synthesis Enzymes
Although the measurement of enzyme activities in nodules showed
that the heme synthesis enzymes were elevated, as for coprogen oxidase,
it is not possible to distinguish between the bacterial and plant
enzymes when measuring enzyme activity alone. However, plant coprogen
oxidase transcripts are increased in nodules (Madsen et al., 1993), as
are transcripts of plant ALA dehydratase (Kaczor et al., 1994) and
plant GSA aminotransferase (Sangwan and O'Brian, 1993; Frustaci et
al., 1995). We have found that transcripts of PBG deaminase also
increase during nodule development (data not shown). We have now
studied the distribution of transcripts by in situ hybridization of
three enzymes for which we had suitable cDNA clones. As well as
demonstrating the increase in plant-specific message levels, it also
provided information about the spatial location of the transcripts
within the nodule.
The probes used were the cDNAs for soybean coprogen oxidase (Madsen et
al., 1993), pea PBG deaminase (Witty et al., 1993), and pea ALA
dehydratase (Boese et al., 1991). Antisense RNAs for each of these
clones were prepared and hybridized to sections of soybean root nodules
of 1 to 2 mm (3-4 weeks after infection), where the maximum induction
of enzyme activity had been observed. In nodules of this size, the
meristematic region has already differentiated into nodular tissue
because soybean nodules are of the determinate type. The largest part
of such a nodule is composed of central tissue containing mainly
infected cells, which are surrounded by the nodule inner cortex and the
outermost cortex (outer cortex). Sense RNAs were used as controls.
With a 35S-labeled antisense probe for ALA
dehydratase, the transcript was localized in the central tissue of the
nodule (Fig. 5, A and B), mainly in
infected cells, with a gradient of expression in the infected zone of
the central tissue. An increased signal was also present in the nodule
inner cortex (Fig. 5, A and B, red triangle), but a weak signal was
visible in the uninfected cells of the outer cortex (Fig. 5A, red
star). This was concluded from the light-microscope observations made
at a higher magnification. No hybridization was obtained when the
35S-labeled sense probe was used (Fig. 5C). Some
thick-walled schlerenchyma cells, lignified xylem cells, and starch
grains were refractive in dark-field microscopy (Fig. 5C, red
triangles).
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| Figure 5.
Localization of ALA dehydratase (A-C), PBG
deaminase (D-F), and coprogen oxidase (G-I) transcripts in
longitudinal sections of soybean nodules using 35S-labeled
probes. A, C, D, F, G, and I, Dark-field micrographs in which silver
grains are visible as white dots. B, E, and H, Bright-field micrographs
of the same sections that show the antisense RNAs
pictured in A, D, and G. An intense signal in the infected cells of the central tissue (ct) is observed in A, D, and G. Increased expression in the nodule inner cortex (red triangle in A) and weak
expression in the outer cortex (red star in A) are apparent. A black
arrowhead points to the endodermis in A. No specific signal was
detectable in the micrographs probed with the sense transcripts (C, F,
and I). Thick-walled schlerenchyma cells, lignified xylem cells, and
starch grains appear yellowish-white (red triangles in C). Bar = 100 µm. J and K, Localization of PBG deaminase transcripts in
longitudinal section of the root nodule of pea using the
35S-labeled probe. Dark-field micrograph (J) shows that
transcripts are localized in the cytoplasm of infected cells (i),
whereas only few silver grains are present in uninfected cells (u).
Starch (s) is visible as grayish grains in uninfected cells. K,
Bright-field micrograph of section shown in J. Nuclei are stained
blue. Bar = 10 µm.
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The intensity of the signals obtained after hybridization with the PBG
deaminase (Fig. 5, D and E) or with the coprogen oxidase (Fig. 5, G and
H) probes was not as intense as with ALA dehydratase. However, the
distribution of both PBG deaminase (Fig. 5D) and coprogen oxidase (Fig.
5G) transcripts resembled that of ALA dehydratase, i.e. they were
present in the central tissue, although there was no gradient of
expression or an increased expression in the nodule inner cortex. No
hybridization signal was obtained with sense probes for either of these
two enzyme clones (Fig. 5, F and I).
In similar experiments on pea nodules, the results were the same. The
transcripts of all three enzymes appeared even more distinct in
infected cells of pea than in those of soybean because of the larger
size of the pea nodule cells (Fig. 5, J and K). In both pea and soybean
the signal intensities of the three enzyme transcripts were not
significantly above background levels in root tissues adjacent to the
nodule.
Leghemoglobin gene transcripts are located mainly in infected cells (de
Billy et al., 1991; Tate et al., 1994). The plant heme synthesis
enzymes are therefore increased in the same type of cells where the
protein moiety of leghemoglobin is synthesized.
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DISCUSSION |
In this study we determined the expression of five heme synthesis
enzymes during the nodulation of soybean and pea roots. All of these
enzymes, ALA dehydratase, PBG deaminase, coprogen oxidase, protogen
oxidase, and ferrochelatase, increase during nodulation, with a maximum
at 3 weeks after infection with the appropriate inoculant (Fig. 4). The
time courses of induction were virtually identical for each enzyme and
paralleled the increase of both heme and holo-leghemoglobin in the
nodule (Nadler and Avissar, 1977; Sangwan and O'Brian, 1992). A
similar observation was made for GSA aminotransferase, one of the
enzymes of the C5 pathway (Sangwan and O'Brian, 1993), which was
undetectable in uninfected roots, and increased to levels greater than
in leaves 20 d after infection. This was paralleled by increases
in transcript and enzyme protein (Frustaci et al., 1995). The same
workers found that ALA dehydratase activity and message were high in
nodules but were completely absent from uninfected roots (Kaczor et
al., 1994). This differs somewhat from our results, in which ALA
dehydratase was present before infection. Because the synthesis of heme
is cell autonomous, the enzymes of the pathway would be expected to be
present in all tissues of the plant to provide heme for cytochromes and
other hemoproteins. The discrepancy might be explained by the fact that
we used roots from 14-d-old plants, whereas Kaczor et al. (1994)
measured activity in much older plants (23 d postinoculation). The
detectable activity of ALA dehydratase and PBG deaminase in pea roots
was found to be a maximum 5 d after germination and thereafter
steadily declined (Smith, 1986). Additionally, maximum PBG deaminase
activity was found in root tips compared with the older tissue in the
elongation zone (Witty et al., 1993). Therefore, it is most likely that
enzyme activity is present in roots but at levels too low to be assayed
accurately. Similarly, we were unable to detect coprogen oxidase
activity reproducibly in uninfected roots, most likely because of the
limitations of the fluorimetric assay, which suffers from high
background (Smith and Griffiths, 1993). In contrast, protein was
detectable on western blots of uninfected roots (Fig. 3), and coprogen
activity was measurable in roots (data not shown) using a more
sensitive radiochemical assay (Elder and Evans, 1978).
Our assays of enzyme activity were carried out on extracts of whole,
unfractionated nodules; therefore, it is not possible to distinguish
whether the enzymes were plant or bacteria derived. However, support
for the conclusion that it is the plant enzymes that are stimulated
comes from the results of cell-fractionation studies. Sangwan and
O'Brian (1991) found that ALA dehydratase and PBG deaminase levels
were the same in free-living and symbiotic B. japonicum
cells, and Jacobs et al. (1990) found increased protogen oxidase
activity in the peribacteroid membrane (which is plant derived)
compared with uninfected roots. We have obtained further evidence by
investigating the levels of enzyme protein with antibodies and
transcripts with the available cDNA probes. These molecular probes are
specific for the plant enzymes and do not detect those from the
symbiont. For coprogen oxidase, in situ hybridization confirmed earlier
results (Madsen et al., 1993) that there is a specific increase in mRNA
levels in nodules, and with western analysis we found a concomitant
increase in enzyme protein, which correlates with the increase in
enzyme activity. The similarly large increase in ALA dehydratase and
PBG deaminase transcripts detected by northern analysis and in situ
hybridization also provides evidence that the increase in enzyme
activity is due to the plant-specific enzyme. Furthermore, the
increased level of transcripts for the plant enzymes is specifically in
the infected cells, where the apoprotein of leghemoglobin is
exclusively synthesized (de Billy et al., 1991; Tate et al.,
1994).
Thus, our results provide additional evidence for the involvement of
the plant heme synthesis enzymes in the production of heme in the
mature nodule. Because the major hemoprotein by far is leghemoglobin,
the conclusion to be drawn is that the plant host provides some if not
all of its prosthetic heme. At first this might seem contradictory to
results obtained from the study of rhizobial mutants of heme synthesis.
For instance, although hemA mutants (defective in ALA
synthase) of Rhizobium sp. NGR234 (Stanley et al., 1988),
R. meliloti (Leong et al., 1982, 1985; Mohapatra and Puhler,
1986; de Bruijn et al., 1989), and Azorhizobium caulinodans
(Pawlowski et al., 1993) are able to elicit nodules on their
corresponding host roots, the nodules are unable to fix nitrogen.
Similarly, B. japonicum mutants defective in ALA dehydratase (hemB; Chauhan and O'Brian, 1993) and ferrochelatase
(hemH; Frustaci and O'Brian, 1992) elicit such so-called
Fix nodules. In all of these examples, there is
no apoleghemoglobin. Another B. japonicum mutant lacking
protogen oxidase activity, which also forms Fix
nodules, nonetheless contains the leghemoglobin apoprotein (O'Brian et
al., 1987) despite the lack of bacterial heme. In this case, the
primary mutation has been demonstrated to be in a gene involved in the
biosynthesis of c-type cytochromes (Ramseier et al., 1991). In contrast, a hemA mutant of B. japonicum MLG1,
which has no detectable heme in the free-living form, induces the
formation of functional nodules containing holo-leghemoglobin and
other bacterial hemes (Guerinot and Chelm, 1986; Chauhan and O'Brian, 1993). This discrepancy has been explained by the proposal that ALA can
be provided to the bacterial symbiont by the soybean host but that
later intermediates cannot be transported across the peribacteroid
membrane (Sangwan and O'Brian, 1991). Further evidence for this model
comes from the observation that those Rhizobium species that
require the hemA gene for symbiosis are severely deficient
in ALA uptake activity (McGinnis and O'Brian, 1995).
Further work on the hemA mutants of R. meliloti
using ultrastructural analysis, translation in vitro of plant RNA, and
northern blots found that there was (a) atypical nodule morphology and infection thread development, (b) arrest early in development, and (c)
only early nodulin genes expressed (Dickstein et al., 1991). Three of
the mutants initiated nodules that did not contain any intracellular
bacteria. A reduction in viable bacterial cells is observed in the
hemB and hemH mutants as well (Frustaci and O'Brian, 1992; Chauhan and O'Brian, 1993). Thus, the
Fix phenotype may not be a direct consequence
of the bacteria's inability to supply heme for leghemoglobin but
rather is a pleiotropic effect of the failure of nodule development.
Although we have clearly demonstrated induction in the nodule of
plant-specific enzymes of heme biosynthesis, it remains uncertain as to
what signal leads to this induction. Although the time course of
increase in the level of the coprogen oxidase transcript was the same
as that for leghemoglobin, there were no significant sequence
similarities between the coprogen oxidase promoter and those of other
late nodulin genes (Madsen et al., 1993). The induction is also
unlikely to be in direct response to anoxia, which increases expression
of the yeast coprogen oxidase gene (Zagorec and Labbe-Bois, 1986),
because we could detect no increase in the soybean enzyme in roots
subjected to anaerobiosis. This is perhaps not surprising, because
although the nodule environment has a low free-oxygen content, this is
mediated by leghemoglobin, which requires coprogen oxidase to provide
its prosthetic group. Therefore, the requirement for increased coprogen
oxidase activity would be before the production of a hypoxic
environment. One interesting observation is that the coprogen oxidase
gene appears to be induced in nodules to a much higher level than in
leaves, even though the rates of tetrapyrrole synthesis are much
greater in the latter (Table I). Similarly, protogen oxidase activity
is greater in nodules than in leaves (Tables II and III). It is
conceivable that the efficiency of extraction of the enzymes from the
two tissues is different, although intuitively it would be expected to
be easier from the softer leaf tissue. The present study is the first,
to our knowledge, in which the activity of several of the tetrapyrrole
synthesis enzymes has been determined in different tissues of the same
plant, so this question must remain unresolved. Nonetheless, in nodules
all of the enzymes are in vast excess over that required to sustain the observed rate of heme, even ALA dehydratase and PBG deaminase, which
appear to be higher in leaves than in nodules.
An explanation for this apparent anomaly would be that there is
considerable heme turnover; therefore, the rate we have calculated is
an underestimate. Evidence for the ability of plants to turn over heme
comes from the study of tetrapyrrole synthesis during the greening of
etiolated seedlings, when there is massive flux through the chlorophyll
branch of the pathway. When [14C]ALA was
administered to greening barley seedlings after 5 h of
illumination, the specific radioactivities of extractable protoheme and
pheophorbide (a chlorophyll derivative) were essentially the same,
indicating that both were synthesized during the period. However, heme
did not accumulate (Castelfranco and Jones, 1975). If a similar
situation prevails in the nodule, the next obvious question is for what
purpose is the heme synthesized? One possibility is that heme is not
just required as a prosthetic group for leghemoglobin and respiratory
cytochromes but that it is also involved in the regulation of nodule
formation and/or function. Jensen et al. (1986) found that a
heme-specific regulatory system in yeast modulated the translation of
chimeric genes containing 5 flanking sequences from the soybean
leghemoglobin c3 gene. More intriguingly, the FixL protein of R. meliloti has been shown to be
a hemoprotein (Monson et al., 1992). FixL and
FixJ form the two-component regulatory system involved in
sensing and transducing the low-oxygen signal, which leads to
expression of the rhizobial genes required for nitrogen fixation.
In summary, the evidence presented in this paper supports that of
earlier studies (Jacobs et al., 1990; Madsen et al., 1993; Sangwan and
O'Brian, 1993; Kaczor et al., 1994, Frustaci et al., 1995; O'Brian,
1996), and together provide strong evidence that the plant cell is
responsible for making at least some, if not all, of the heme moiety of
leghemoglobin. Thus, the hypothesis that the plant host makes the
apoprotein and the bacterial endosymbiont makes the prosthetic group
(Appleby, 1984) is no longer tenable. Nonetheless, the fact that
several rhizobial heme-synthesis mutants are unable to form functional
nodules suggests the possibility that heme or some other tetrapyrrole
is required as a signal for the induction of certain plant genes that
are necessary for the later stages of nodule development and/or
function.
| |
FOOTNOTES |
1
This work was supported by a studentship from
the Venezuelan National Academy of Science (M.A.S.), and by a
short-term fellowship from the European Molecular Biology Organization
and grants from the Joint Committee of the Nordic Natural Science
Research Councils (K.P.-M.).
2
Present address: Instituto Internacional de
Estudios Avanzados, Centro de Biociencias, Apartado 17606, Parque
Central, Caracas 1015 A, Venezuela.
3
Permanent address: Laboratory of Plant
Physiology and Molecular Biology, Department of Biology, University of
Turku, FIN-20014 Turku, Finland.
*
Corresponding author; e-mail as25{at}cam.ac.uk; fax
44-1223-333953.
Received September 1997;
accepted January 6, 1998.
| |
ABBREVIATIONS |
Abbreviations:
ALA, 5-aminolevulinic acid.
coprogen oxidase, coproporphyrinogen III oxidase.
GSA, glutamate-1-semialdehyde.
PBG, porphobilinogen.
protogen, protoporphyrinogen IX.
| |
ACKNOWLEDGMENTS |
K.P.-M. thanks Dr. Ton Bisseling, Dr. Wei-Cai Yang, and Jan-Elo
Jørgensen for helpful discussion of in situ-hybridization techniques.
We are grateful to Dr. Mike Timko (University of Virginia, Charlottesville) for the gift of the cDNA clone for pea ALA
dehydratase.
| |
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Abstract
Introduction