Plant Physiol. (1999) 119: 143-152
Feedback Inhibition of Chlorophyll Synthesis in the Phytochrome
Chromophore-Deficient aurea and
yellow-green-2 Mutants of Tomato
Matthew J. Terry1, * and
Richard E. Kendrick
School of Biological Sciences, University of Southampton,
Bassett Crescent East, Southampton, SO16 7PX, United Kingdom (M.J.T.); and Laboratory for Photoperception and Signal Transduction, Frontier
Research Program, The Institute of Physical and Chemical Research
(RIKEN), Wako, Saitama, 351-0198, Japan (M.J.T., R.E.K.)
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ABSTRACT |
The aurea
(au) and yellow-green-2
(yg-2) mutants of tomato (Solanum
lycopersicum L.) are unable to synthesize the linear
tetrapyrrole chromophore of phytochrome, resulting in plants with a
yellow-green phenotype. To understand the basis of this phenotype, we
investigated the consequences of the au and
yg-2 mutations on tetrapyrrole metabolism. Dark-grown
seedlings of both mutants have reduced levels of protochlorophyllide
(Pchlide) due to an inhibition of Pchlide synthesis. Feeding
experiments with the tetrapyrrole precursor 5-aminolevulinic acid (ALA)
demonstrate that the pathway between ALA and Pchlide is intact in
au and yg-2 and suggest that the reduction in Pchlide is a result of the inhibition of ALA synthesis. This inhibition was independent of any deficiency in seed phytochrome, and experiments using an iron chelator to block heme synthesis demonstrated that both mutations inhibited the degradation of the
physiologically active heme pool, suggesting that the reduction in
Pchlide synthesis is a consequence of feedback inhibition by heme. We
discuss the significance of these results in understanding the
chlorophyll-deficient phenotype of the au and
yg-2 mutants.
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INTRODUCTION |
The use of mutants with impaired responses to light has been
instrumental in developing our current understanding of photoperception and signal transduction in higher plants (von Arnim and Deng, 1996
;
Fankhauser and Chory, 1997). The phytochrome chromophore-deficient mutants have been particularly useful in defining the role played by
phytochrome during photomorphogenesis, because all members of the
phytochrome photoreceptor family appear to use the same chromophore,
resulting in plants that have reduced activity of all phytochrome
species (Terry, 1997). The phytochrome chromophore 3(E)-P
B is synthesized in the plastid from the heme
branch of the tetrapyrrole-biosynthetic pathway (Fig.
1; Terry et al., 1993, 1995; Weller et
al., 1996). Biochemical analyses of chromophore biosynthesis have
identified mutants in this pathway from a number of species.
In pea two mutants have been identified, pcd1 and
pcd2, that are unable to convert heme to biliverdin IX
and biliverdin IX to 3(Z)-PB, respectively (Weller et
al., 1996, 1997). There are also two chromophore-deficient mutants in
tomato (Solanum lycopersicum L.). The
aurea (au) mutant is specifically deficient in
PB synthase activity (Fig. 1; Terry and Kendrick, 1996), whereas the
phenotypically indistinguishable yellow green-2
(yg-2) mutant is blocked in the preceding step in the
pathway and cannot synthesize biliverdin IX from heme (Terry and
Kendrick, 1996). The hy1 and hy2 mutants of
Arabidopsis (Parks and Quail, 1991) and the pew mutants of Nicotiana plumbaginifolia (Kraepiel et al., 1994) are
also deficient in chromophore synthesis.
The au mutant is one of the most exhaustively characterized
photomorphogenic mutants and until recently was thought to be specifically deficient in phyA despite considerable physiological data
to the contrary. The phenotype of au is typical of
chromophore-deficient mutants (Terry, 1997). White light-grown
seedlings are elongated and have impaired chloroplast development and
reduced levels of chlorophyll and anthocyanin, resulting in a pale,
yellow-green phenotype (Koornneef et al., 1985). This pleiotropic
phenotype is the consequence of the loss of multiple phytochromes.
Analyses of light-dependent inhibition of hypocotyl elongation and
anthocyanin synthesis have demonstrated that au seedlings
are deficient in both phyB1 and phyA activities (Koornneef et al.,
1985; van Tuinen et al., 1995a, 1995b; Kerckhoffs et al.,
1997).
These physiological data were recently supported by experiments showing
that the absence of spectrophotometrically detectable phytochrome in
vivo corresponds to the loss of at least three holophytochrome species
in etiolated au seedlings (Kerckhoffs, 1996). In mature
au plants, however, the situation is very different. Leaves
from 4- to 6-week-old au plants grown in the greenhouse contained 60% to 70% of wild-type phytochrome levels
(López-Juez et al., 1990), whereas the amount of photoactive
phytochrome detected by an antibody raised to pea phyB was the same in
both au and wild-type plants (Sharma et al., 1993). This
increase in holophytochrome levels relative to wild-type plants
results, not surprisingly, in the recovery of many phytochrome
responses, and mature au plants exhibit relatively normal
shade avoidance (Whitelam and Smith, 1991) and end-of-day far-red
responses (López-Juez et al., 1990). The recovery of phytochrome
responses during development seen in the au tomato
mutant appears to be characteristic of all chromophore-deficient mutants, although the basis for this phenomenon is not yet
established.
Although mature au plants are less phytochrome deficient
than au seedlings, they retain their dramatic yellow-gold
coloring that gave the au mutant its name. This can be seen
clearly in Figure 2. Tissue at the base
of each au leaflet is almost white and becomes gradually
darker until by the leaflet edges it is pale green. There is also a
distinctive mosaic effect caused by the veins of the au
leaflets being pale green and the cells in between remaining yellow.
Chlorophyll levels in mature au plants vary between 33% and
61% of wild type depending on the light and temperature conditions in
which they are grown (Koornneef et al., 1985; López-Juez et al.,
1990; Becker et al., 1992). However, this reduction in chlorophyll
levels is not the consequence of reduced photoinduction of
CAB genes (encoding chlorophyll
a/b-binding proteins), because CAB expression levels are normal in
au plants of this age (Becker et al., 1992). Moreover, the
characteristic leaf coloring as a result of the au mutation
is still apparent in the high pigment-1 (hp-1)
background (Fig. 2). The hp-1 mutation is believed to affect
light signal transduction, since light responses are exaggerated in
this mutant (Peters et al., 1992), and it might therefore be expected
to compensate for the effect of phytochrome deficiency on chlorophyll
synthesis.
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| Figure 2.
Leaf phenotype of au and
hp-1 mutants. Leaves are from 6-week-old wild-type
(left), au (second from left),
au,hp-1 (second from right), and
hp-1 (right) plants grown in the greenhouse.
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There are other features of the au phenotype that are
inconsistent with our current understanding of phytochrome function. Dark-grown au seedlings have reduced CAB
expression in the dark compared with wild-type seedlings (Sharrock et
al., 1988; Ken-Dror and Horwitz, 1990). Ken-Dror and Horwitz (1990)
also showed that levels of phototransformable Pchlide were reduced in
au under these conditions and noted the difficulty of
explaining these results in terms of a phytochrome deficiency. In
addition, etioplasts from hypocotyl cells of dark-grown au
seedlings do not develop normally, appearing as smaller proplastids
lacking a prolamellar body (Neuhaus et al., 1993). Is it possible that
these observations are related to an additional consequence of
inhibiting PB synthesis?
One obvious effect of such an inhibition would be to change the flux
through the tetrapyrrole-biosynthetic pathway. Chlorophyll and heme are
both synthesized in the plastid from ALA and share a common pathway
between ALA and Proto IX (Fig. 1; Beale and Weinstein, 1991; von
Wettstein et al., 1995). In the dark chlorophyll synthesis proceeds
only as far as Pchlide because the enzyme POR has an absolute
requirement for light. The rate-limiting step for chlorophyll or
Pchlide synthesis is the formation of ALA from glutamate via the
C5 pathway (Beale and Weinstein, 1991), and
experiments in which heme synthesis has been blocked using chelators of
iron (Duggan and Gassman, 1974; Chereskin and Castelfranco, 1982;
Beale and Weinstein, 1991) or herbicides (Masuda et al., 1990) have demonstrated that ALA synthesis (and therefore chlorophyll synthesis) is under the control of heme. We examined tetrapyrrole synthesis in the
au and yg-2 mutants to test the hypothesis that
the inhibition of heme degradation leads to a reduction in chlorophyll
synthesis via feedback inhibition.
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MATERIALS AND METHODS |
Plant Material and Growth Conditions
The tomato (Solanum lycopersicum L.) genotypes
used in this study are given in Table I.
All seeds were treated with 1% (v/v) bleach, washed thoroughly, and
sown on 0.6% (w/v) agar containing 0.46 g/L of Murashige-Skoog salts
(Life Technologies) in tissue-culture containers (Flow Laboratories,
McLean, VA). Seedlings were grown in the dark for 5 d (unless
otherwise stated) at 25°C. The au and yg-2
mutants were sown 12 h prior to wild-type seeds to synchronize germination.
Porphyrin Extraction and Quantitation
Cotyledons and hypocotyl hooks (0.5 g) were harvested under a
dim-green safelight, and porphyrins were extracted based on the method
of Rebeiz et al. (1975). Tissue was homogenized in 2.5 mL of cold
acetone: 0.1 M NH4OH (90/10, v/v) and
transferred to a centrifuge tube with an additional 1 mL of solvent.
Samples were centrifuged at 30,000g for 10 min. The pellet
was then reextracted in 1.5 mL of solvent and centrifuged again. The
supernatants were combined and washed successively with an equal volume
and a one-third volume of hexane prior to spectrophotometric analysis.
For determination of Pchlide ester the hexane washes were pooled and
analyzed directly.
Absorption spectroscopy of porphyrin samples was performed using a
spectrophotometer (model U-3410, Hitachi, Tokyo, Japan). Pchlide
concentrations were determined using a molar absorption coefficient of
31,100 M
1
cm1 at 626 nm (Kahn, 1983). For samples
containing significant quantities of Proto IX (i.e. ALA-feeding
experiments), the concentration of Proto IX was determined using a
molar absorption coefficient of 16,200 M1 cm1 at
503 nm (Gough, 1972), and the concentration of Pchlide was calculated
by subtracting the contribution of Proto IX (molar absorption
coefficient of 5,500 M1
cm1 at 628 nm; Gough, 1972) to the absorption
peak of Pchlide at 628 nm. Fluorescence spectroscopy was performed
(model F-3010, Hitachi), and fluorescence was measured using excitation
wavelengths of 410 nm for Proto IX and Mg-protoporphyrin and 440 nm for Pchlide and Pchlide ester.
In Vivo Feeding Experiments
For ALA feeding experiments, seedlings were cut under water and
placed in a beaker containing 15 mM Hepes/NaOH buffer, pH 7.0, with 5 mM MgCl2 for 20 h at
25°C. ALA was added to a final concentration of 10 mM.
Following incubation, porphyrins were extracted as described above
except that 0.25 g of tissue was used with the same volumes of
solvent. The iron chelator 2
2-bipyridyl (10 mM final
concentration diluted from a 1 M stock in ethanol) was fed
in 15 mM Hepes/NaOH buffer, pH 7.4, containing 10 mM glutamate under identical conditions. Tissue (0.25 g)
was extracted as above, but using one-half volume of solvent.
| |
RESULTS |
au and yg-2 Mutants Have Reduced Synthesis
of Pchlide in the Dark
Pchlide levels in wild-type, au, and yg-2
seedlings were determined by absorption spectroscopy. Figure
3A shows representative absorption
spectra of hexane-washed acetone extracts from 5-d-old dark-grown
seedlings. Both au and yg-2 had reduced levels of
Pchlide compared with wild type, although the absorption spectra were otherwise identical and consistent with previously published spectra from other species (Gough, 1972). Quantitation of the amount of Pchlide
using absorption spectra from replicate experiments demonstrated that
Pchlide levels were reduced in the mutants whether compared on a
seedling or fresh weight basis (Fig. 3, B and C). From these data it
can be calculated that au and yg-2 contain 68%
and 84% of wild-type Pchlide per seedling, respectively. Analysis of
Pchlide by fluorescence spectroscopy following excitation at 440 nm
(Rebeiz et al., 1975) gave qualitatively identical results (Fig. 3A,
inset, and data not shown).
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| Figure 3.
Analysis of Pchlide levels in au
and yg-2. A, Room-temperature absorption and
fluorescence (inset, excitation at 440 nm) spectra of hexane-washed
acetone extracts from 5-d-old, dark-grown wild-type, au,
and yg-2 seedlings. B and C, Quantitation of
Pchlide from multiple absorption spectra in different alleles of
au and yg-2 expressed per seedling (B) or
on a fresh weight basis (C). The wild-type (WT) value represents the
mean ± SE of four different backgrounds (Ailsa Craig,
Moneymaker, breeding line GT, and VF145 [Table I];
n  3 for each). All other values are means ± SE (n 3).
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To confirm that the reduced Pchlide was a direct consequence of the
au and yg-2 mutations, Pchlide was also measured
in additional alleles of both au and yg-2 (Fig.
3, B and C). A reduction in Pchlide was observed in all of the
au alleles tested and in the only other known
yg-2 allele, yg-2aud. Three of
the four additional au alleles and
yg-2aud all contained less Pchlide per
seedling than the original au and yg-2 alleles.
The
auw,yg-2aud
double mutant was also examined and was found to contain lower levels
of Pchlide than either single mutant, indicating an additive phenotype
for this effect (Fig. 3, B and C). To confirm that the reduction in
Pchlide levels was not a consequence of slower growth of the mutants,
we also measured the hypocotyl length of au,
yg-2, and wild-type seedlings grown in the dark for 5 d. Under these conditions there was no difference in the hypocotyl
length between wild-type and mutant seedlings (data not shown).
There are two possible explanations for the reduction in the amount of
Pchlide: either the rate of synthesis of Pchlide is reduced or the
Pchlide synthesized is being further metabolized to give a product that
is not detectable under these assay conditions. The most likely
candidate for the latter is Pchlide ester, which would be removed
during the hexane wash. We therefore determined the relative amounts of
Pchlide ester in wild-type and mutant seedlings by fluorescence
spectroscopy. Table II shows that the levels of Pchlide ester were more reduced than Pchlide in au
and yg-2, indicating that an increased synthesis of
Pchlide ester was not the reason for the lower levels of Pchlide.
We next compared the rate of accumulation of Pchlide in the wild
type and in the mutants by measuring Pchlide levels during seedling
growth. Figure 4 shows that the rate of
Pchlide accumulation was slower in both the au and
yg-2 mutants than in wild-type seedlings. Since Pchlide does
not appear to be further metabolized, these results show that the
reduced Pchlide levels in au and yg-2 are the
consequence of a reduced rate of Pchlide synthesis.
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Table II.
Analysis of Pchlide ester in au and yg-2 mutants
Pchlide ester was quantified by fluorescence spectroscopy in 5-d-old
dark-grown tomato seedlings. Values are means ± SE
(n = 3).
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| Figure 4.
Time course of Pchlide accumulation in
au and yg-2 mutants. Pchlide was measured
at various times in dark-grown wild-type (WT), au, and
yg-2 seedlings. Values are means ± SE
(n 3).
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Synthesis of Pchlide from ALA Is Not Affected by the au
and yg-2 Mutations
The inhibition of Pchlide synthesis in au and
yg-2 is likely to be the result of a reduction in ALA
synthesis, since Pchlide synthesis is controlled at this point in the
pathway (Beale and Weinstein, 1991). However, it is also possible that
the mutations lead to inhibition of an intermediate step(s) in the
biosynthetic pathway between ALA and Pchlide. We tested this
hypothesis by feeding ALA to wild-type, au, and
yg-2 seedlings and then examining the accumulation of
porphyrins. Figure 5 shows that
wild-type, au, and yg-2 seedlings accumulated
between 5- and 12-fold more Pchlide (determined by absorption
spectroscopy) after being fed ALA. This accumulation of Pchlide was
also detected by fluorescence spectroscopy following excitation at 440 nm (Fig. 5A, inset). Pchlide levels in seedlings fed buffer alone were
identical to those measured previously for intact seedlings, with lower
levels in au and yg-2 than in wild-type plants
(data not shown).
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| Figure 5.
Analysis of porphyrin synthesis in
au and yg-2 mutants following incubation
in porphyrin precursors. A, Room-temperature absorption and
fluorescence (inset, excitation at 440 nm) spectra of hexane-washed
acetone extracts from dark-grown wild-type (WT), au, and
yg-2 seedlings incubated in the dark for 20 h in 10 mM ALA. B, Quantitation of Pchlide and Proto IX following
incubation in 10 mM ALA or 10 mM glutamate
(glu). Values are means ± SE (n 3). The data for no addition (no add.) are from intact seedlings and
are the same as those shown in Figure 3 (au and
yg-2 only).
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Seedlings fed the ALA precursor glutamate contained slightly more
Pchlide than intact seedlings in all cases, but the inhibition of
Pchlide synthesis in au and yg-2 was still
maintained (Fig. 5B). The small effect of feeding glutamate would be
expected, since ALA synthesis is rate limiting for Pchlide synthesis.
It is clear from these data that the au and yg-2
mutations do not affect the Pchlide-synthesis pathway after ALA, since
Pchlide accumulates to high levels in the mutants. Indeed, more Pchlide accumulated in au seedlings fed ALA than in wild-type
seedlings (Fig. 5B). The accumulation of excess Pchlide in
au and yg-2 seedlings following ALA feeding
confirms that the reduced accumulation of Pchlide in dark-grown
seedlings (Figs. 3 and 4) was the result of a reduced rate of Pchlide
synthesis and is also consistent with the inhibition of Pchlide
synthesis being the consequence of a reduced rate of ALA synthesis.
In addition to Pchlide, other pigments were also detected
following ALA feeding. Small amounts of Mg-protoporphyrin were measured as a fluorescence peak at 595 nm following excitation at 410 nm. Mg-protoporphyrin was present in wild-type, au, and
yg-2 seedlings fed ALA but was not present in buffer
controls (data not shown). The most noticeable feature of the ALA-fed
seedlings was that both au and yg-2 accumulated
large quantities of Proto IX in addition to excess Pchlide (Fig. 5).
Since there was no corresponding inhibition of Pchlide synthesis, the
most likely explanation is that the accumulated Proto IX represents a
Proto IX pool that is no longer available for conversion to Pchlide
because it is spatially separated from the Pchlide-synthesis pathway.
Inhibition of Pchlide Synthesis Is Independent of Phytochrome
Deficiency
The synthesis of ALA is known to be regulated by both light, which
activates ALA synthesis through phytochrome (Kasemir, 1983; Huang et
al., 1989), and heme, which is an inhibitor of glutamyl-tRNA reductase
(Pontoppidan and Kannangara, 1994; Fig. 1). It is important to
distinguish between these two possibilities in order to understand the
phenotype of both the au and yg-2 mutants. The
experiments described to date were deliberately performed using
dark-grown seedlings to eliminate the effect of phytochrome on ALA
synthesis. However, seeds of both au and yg-2 are
likely to contain reduced levels of Pfr because the parent plant
is still phytochrome deficient at the mature stage of development;
Indeed, auw is impaired in phytochrome-mediated
dark germination (Koornneef et al., 1985). Although a deficiency in
seed Pfr has not been reported to have any additional phenotypic
effects (e.g. on hypocotyl length), it is possible that the reduction
in Pchlide in au and yg-2 is due to lower
levels of Pfr in seeds of these mutants.
We tested this possibility with a series of three experiments (Fig.
6). First, we measured Pchlide levels in
other phytochrome-deficient mutants. Figure 6A shows that the
phyA-deficient fri mutant (van Tuinen et al., 1995a), the
phyB1-deficient tri mutant (van Tuinen et al., 1995b), and
the fri,tri double mutant (Kerckhoffs et al., 1997) did not have reduced levels of Pchlide in the dark. Next we
tested whether phytochromes other than phyA and phyB1 could affect
Pchlide levels by giving saturating red and far-red light pulses to
wild-type seedlings 24 h after imbibition. These light treatments
were designed to convert the majority of the phytochrome present in
seeds to either the active Pfr form (red) or the inactive Pr form (far
red). As can be seen in Figure 6B, these light treatments had very
little effect on the subsequent synthesis of Pchlide. Although a small
response may exist, the absence of part of this response could not
account for the much larger inhibition of Pchlide synthesis in the
au seedlings. The third approach was to examine Pchlide
levels in the hp-1 mutant background. The hp-1
mutation leads to an amplification of light responses (Peters et al.,
1992) and might therefore be expected to amplify any difference between wild-type and au seedlings if the reduced level of Pchlide
in au was a consequence of reduced seed Pfr.
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| Figure 6.
Analysis of Pchlide levels in a range of
photomorphogenic mutants following brief light treatments. A and C,
Pchlide was measured in 5-d-old, dark-grown wild-type (WT) and
phyA (fri), phyB1
(tri), au, hp-1, and
double-mutant seedlings. MM, GT, and AC represent different genetic
backgrounds (Table I). B, Pchlide was measure in 5-d-old wild-type (WT)
seedlings treated with 5 min of red (R; 17 µmol m2
s1) or 15 min of far red (FR; 12 µmol m2
s1) light 24 h after imbibition. Values are
means ± SE (n 3).
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Figure 6C shows that the hp-1 background leads to a small
increase (20%) in Pchlide compared with wild-type seedlings. A small increase is also seen in the au,hp-1 double
mutant when compared with au alone. Therefore, if the
increase in hp-1 represents the amplification of the action
of seed Pfr, it is evident that au contains sufficient Pfr
to saturate this response. It should also be noted that the
au,hp-1 double mutant contains less Pchlide than
wild-type seedlings. Taken together, these results clearly indicate
that the reduced Pchlide levels in au and yg-2
are not a consequence of a deficiency in seed Pfr. Similar arguments
can be used to discount a stimulatory role of Pr on Pchlide synthesis in the dark. Both the fri and tri mutant alleles
contain barely detectable amounts of phytochrome protein (van Tuinen et
al., 1995a, 1995b), and light treatments resulting in differing
concentrations of Pr had little effect in wild-type seedlings (Fig.
6B). In addition, experiments in which harvest times were varied
excluded the possibility that the difference in Pchlide levels between
mutant and wild-type seedlings was the result of a light-independent
circadian regulation (data not shown).
au and yg-2 Mutations Affect the
Physiologically Active Heme Pool
Since the inhibition of Pchlide synthesis in au and
yg-2 is independent of reduced phytochrome levels, it is
likely that it results from the effects of heme accumulation following
lesions in the phytochrome chromophore (heme-degradation) pathway. To test this hypothesis it was necessary to determine whether the au and yg-2 mutations affect the physiologically
active free heme pool. It is not currently possible to measure this
heme pool directly; therefore, we used an alternative strategy of
manipulating the levels of free heme by incubating wild-type and mutant
seedlings in the iron chelator 22-bipyridyl. Chelation of free iron
will reduce the synthesis of heme from Proto IX, and it has been shown in numerous studies that such a treatment leads to an increase in the
synthesis of porphyrins because of the release of the feedback inhibition by heme on ALA synthesis (Duggan and Gassman, 1974; Chereskin and Castelfranco, 1982; Beale and Weinstein, 1991). The
proposed mechanism for this action is that, when the synthesis of new
heme is inhibited, the regulatory heme pool continues to be rapidly
degraded (Castelfranco and Jones, 1975).
We reasoned that, because the mutants were impaired in the
degradation of plastidic heme, the free heme pool would remain for
longer and porphyrin synthesis would not be stimulated. The chelator
treatment would therefore have the effect of amplifying the difference
in porphyrin synthesis between wild-type and mutant seedlings. The
results of this experiment are shown in Figure 7. In wild-type seedlings the major
product following 22-bipyridyl feeding was Mg-protoporphyrin
(including Mg-protoporphyrin methyl ester, which was indistinguishable
in this assay), identified by its sharp fluorescent peak at 595 nm
following excitation at 410 nm (Fig. 7A). Fluorescence spectra after
excitation at 440 nm indicated that there was no increase in Pchlide
during this period (data not shown). These results are consistent with
previous observations that iron chelators inhibit the conversion of
Mg-protoporphyrin methyl ester to Pchlide in addition to
ferrochelatase (Duggan and Gassman, 1974). Mg-protoporphyrin was
not detectable in control incubations; therefore, it represents new
porphyrin synthesis during the incubation period. The peak in Figure 7A
at approximately 635 nm represents a mixture of Pchlide with some Proto
IX and was similar in treated and untreated wild-type seedlings.
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| Figure 7.
Analysis of Mg-protoporphyrin synthesis in
au and yg-2 mutants following incubation
in the iron chelator 22-bipyridyl (BP). A, Room-temperature
fluorescence spectra (excitation at 410 nm) of hexane-washed acetone
extracts from dark-grown wild-type (WT), au, and
yg-2 seedlings incubated in the dark for 20 h in 10 mM 22-bipyridyl. B, Quantitation of Mg-protoporphyrin
from multiple fluorescence spectra. Values are means ± SE (n = 3).
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Feeding 22-bipyridyl to au and yg-2 seedlings
led to much smaller increases in Mg-protoporphyrin (Fig. 7A). This was
particularly apparent in yg-2, in which the
Mg-protoporphyrin levels were just 10% of wild-type levels, whereas
au contained 35% of that of control seedlings (Fig. 7B).
Fluorescence spectra after excitation at 440 nm indicated that Pchlide
levels were unaffected by 22-bipyridyl treatment in au
seedlings, although there was a small reduction in Pchlide in
yg-2 seedlings (data not shown). This is also apparent in
Figure 7A, where the peak at 635 nm in yg-2 is similar to
that in au and is considerably reduced in comparison with
wild-type. Our results indicate that when heme synthesis is blocked the
release of porphyrin synthesis is much greater in wild-type seedlings than in the mutants and, therefore, that the au and
yg-2 mutations affect the regulatory heme pool by blocking
normal heme turnover in plastids.
| |
DISCUSSION |
Feedback Inhibition of Chlorophyll Synthesis
The data presented here clearly demonstrate that the au
and yg-2 mutations lead to a decrease in Pchlide synthesis
in the dark. There are two possible explanations for this: either
inhibition of Pchlide synthesis results from the absence of
holophytochrome in au and yg-2 mutants or lesions
in the chromophore-biosynthesis pathway cause a decrease in Pchlide
synthesis that is independent of phytochrome deficiency. The poor dark
germination of au and yg-2 (Koornneef et al.,
1985) indicates that seeds of these mutants have reduced levels of
active phytochrome, and it is therefore possible that a lack of seed
phytochrome (either as Pfr or Pr) could lead to a reduction in Pchlide
synthesis. However, from the data shown in Figure 6 we can exclude such
an effect. The fri,tri double mutant, which lacks
detectable PHYA and PHYB1, accumulates Pchlide normally, and light
treatments designed to convert seed phytochrome predominantly to Pr or
Pfr were also ineffectual. We are not able to completely rule out the
possibility that Pr synthesized during seedling growth is necessary for
normal Pchlide accumulation, but this effect would clearly not require the presence of phyA or phyB1. Therefore, the inhibition of Pchlide synthesis is the direct result of lesions in chromophore biosynthesis.
One possible explanation for this is that Pchlide accumulation is
inhibited in a nonspecific manner as a result of pleiotropic effects on
plastid structure caused by the absence or mistargeting of the
chromophore-biosynthesis enzymes themselves or by the accumulation or
loss of molecules that might affect plastid development (e.g. heme or
PB). Although etioplasts from hypocotyl cells of the au mutant have been shown to have structural defects
(Neuhaus et al., 1993), there is good evidence that the effects of the mutations on the tetrapyrrole-biosynthesis pathway are actually quite
specific. Isolated plastids from au and yg-2 can
synthesize Proto IX from ALA at rates equal to wild-type plastids, and
neither mutation affects chromophore biosynthesis other than in the
step it specifically blocks (Terry and Kendrick, 1996). These results are supported by the finding that feeding ALA results in a substantial accumulation of Pchlide in both wild-type and mutant seedlings (Fig.
5), indicating that all of the enzymes between ALA and Pchlide are
functioning normally. This experiment is important because it
demonstrates that the reduction in Pchlide is not the result of a
reduced number of plastids and that the total capacity for tetrapyrrole
synthesis is uncompromised in au and yg-2
seedlings.
The simplest explanation for the reduction in Pchlide synthesis is
therefore that the au and yg-2 mutations directly
alter the regulation of tetrapyrrole biosynthesis. The most likely
mechanism for such an effect is that an increase in the physiologically active free heme pool directly inhibits ALA synthesis, which leads to a
reduction in Pchlide accumulation (Fig. 1). This explanation is
supported by data showing that inhibition of Pchlide synthesis takes
place prior to the formation of ALA (Fig. 5) and that both the
au and yg-2 mutations affect the degradation of
physiologically active heme (Fig. 7). It is also entirely consistent
with previously published data demonstrating that ALA synthesis is rate
limiting for chlorophyll synthesis and that heme is a feedback
regulator of this step (Beale and Weinstein, 1991). From our data we
cannot exclude the possibility that, in addition to feedback inhibition by heme, PB has a stimulatory effect on Pchlide synthesis, but there
is no evidence in the literature to support such a role.
The mechanism by which heme inhibits ALA synthesis is not entirely
understood. Three enzymes are required for the synthesis of ALA from
glutamate (von Wettstein et al., 1995; Kumar et al., 1996). The second
of the three enzymes, glutamyl-tRNA reductase, which converts glutamate
activated by ligation to tRNAGlu to glutamate
1-semialdehyde, is believed to be the rate-limiting step in ALA
synthesis and is therefore a likely target for heme inhibition. In
vitro experiments with purified and recombinant glutamyl-tRNA reductase
have shown that heme is a potent inhibitor of this enzyme (Pontoppidan
and Kannangara, 1994; Vothknecht et al., 1996). Whether heme also has a
regulatory role in the transcription or translation of the genes
encoding this or other ALA-synthesizing enzymes has yet to be
determined. However, since feeding heme to plant tissues is exceedingly
problematic, phytochrome chromophore-deficient mutants may prove to be
invaluable tools with which to address such questions. There is no
compelling evidence for the regulation of ALA synthesis by other
products of the tetrapyrrole-biosynthetic pathway, except that Pchlide
appears to limit its own synthesis in the dark (Beale and Weinstein,
1991). Again, the mechanism is not completely understood but is thought
to be related to the formation of the ternary POR-Pchlide-NADPH
complex. The data presented here indicate that, although Pchlide may be
important in preventing its own excess accumulation, it cannot override
the regulatory effect of heme under conditions in which Pchlide
synthesis is limiting.
Consequences of Feedback Inhibition of Chlorophyll Synthesis in the
Dark
The data presented here provide an explanation for the observation
that etiolated auw seedlings contain less
photoactive Pchlide than wild-type seedlings (Ken-Dror and Horwitz,
1990). However, the reduction in photoactive Pchlide (20% of wild
type) was greater than the reduction of Pchlide pigment seen for
auw in this study (60% of wild type) and
there may be additional reasons for the lower level of photoactive
Pchlide. For example, Pchlide is required for the import of POR
(Reinbothe et al., 1995), the major protein component of the
prolamellar body (Ikeuchi and Murakami, 1983). A reduced rate of
Pchlide synthesis might therefore be expected to result in reduced
levels of POR accumulation, which would further inhibit the formation
of the photoactive POR-Pchlide complex. Analysis of POR in
au and yg-2 seedlings has indeed shown that POR
protein levels are reduced in both cotyledons and hypocotyls of
au seedlings (M.J. Terry, unpublished results), and this may also contribute to the reduction in photoactive Pchlide in
auw.
The synthesis of tetrapyrroles is closely linked to plastid
development, and it has long been established that mutations leading to
defects in chlorophyll biosynthesis have a profound effect on the
structure of plastids (von Wettstein et al., 1971; Mascia and
Robertson, 1978). The formation of the prolamellar body correlates with
levels of the photoactive POR-Pchlide complex (Sperling et al., 1998);
therefore, it might be expected that dark-grown au and
yg-2 seedlings have poorly developed etioplasts. There has been no analysis to date of etioplast structure in dark-grown cotyledons of these mutants, but hypocotyl cells of dark-grown auw seedlings contain only small
proplastids that lack a prolamellar body (Neuhaus et al., 1993).
Moreover, preliminary analysis of Pchlide in dark-grown
au hypocotyls indicates that, compared with wild type, they
have even lower levels than cotyledons (M.J. Terry, unpublished
results), consistent with the hypothesis that feedback inhibition of
chlorophyll synthesis affects normal etioplast development in these
mutants.
The results described in this paper also provide a possible explanation
for the observation that CAB gene expression is reduced in
dark-grown au seedlings (Sharrock et al., 1988; Ken-Dror and Horwitz, 1990). This phenomenon has also been observed in the hy1 mutant of Arabidopsis (López-Juez et al., 1996),
which also has reduced levels of Pchlide in the dark (C.E. Raitt and
M.J. Terry, unpublished results), and it is possible that these two observations are related. CAB gene expression is known to be
regulated by a signal from the plastid (Taylor, 1989), and reduced
Pchlide synthesis may affect the expression of this gene either
directly or through effects on etioplast development.
There may be some additional reasons for the phenotype of etiolated
au seedlings, such as an effect of heme accumulation or a
loss of PB. Heme is a potent regulator of gene expression in other
organisms (Sassa and Nagai, 1996) and may also play a significant role
in plant development. It is also possible that PB (or its precursor,
biliverdin IX) can act as a signaling molecule, although there is
currently no evidence to support such a role. Alternatively, although
phytochrome (Pr or Pfr) did not have a direct effect on Pchlide
accumulation in these mutants, it is possible that it has an
independent role in plastid development in etiolated seedlings.
Consequences of Feedback Inhibition of Chlorophyll Synthesis in the
Light
It is difficult to estimate the contribution of feedback
inhibition of chlorophyll synthesis on the light-grown phenotype of
au and yg-2 mutants. The difficulty arises
because phytochrome is crucial for normal plastid development and has
been shown to regulate the synthesis of both chlorophyll (Kasemir,
1983) and chlorophyll a/b-binding proteins (Batschauer et
al., 1994). It is therefore hard to separate the role of phytochrome in
these processes from any contribution that feedback inhibition may have to the phenotype of light-grown au leaves. However,
light-grown auw plants contain substantial
amounts of phytochrome (López-Juez et al., 1990; Sharma et al.,
1993), resulting in many phytochrome-mediated responses being
relatively normal at this developmental stage (López-Juez et al.,
1990; Whitelam and Smith, 1991), including the expression of
CAB mRNA (Becker et al., 1992). This last observation in
particular suggests that the au phenotype is not the result of abnormal photoregulation of CAB genes. Indeed, pigment
synthesis rather than CAB gene expression appears to be the
most important factor in determining chlorophyll levels. Experiments
using antisense expression have demonstrated that reducing
CAB mRNA to almost undetectable levels results in plants
with no visible phenotype (Flachmann and Kühlbrandt, 1995); in
contrast, a 50% reduction in glutamate semialdehyde aminotransferase
activity leads to plants containing less than 30% of wild-type
chlorophyll (Höfgen et al., 1994). It is therefore probable that
the phenotype of light-grown au plants is a consequence of a
reduced rate of chlorophyll pigment synthesis arising from a
combination of reduced phytochrome activation and feedback inhibition.
The hypothesis that feedback inhibition of chlorophyll synthesis
contributes to the au phenotype will require rigorous
testing but is supported by a number of observations. The first is that the au,hp-1 double mutant retains a relatively
severe pale phenotype (Fig. 2), even though many phytochrome responses
are amplified by the hp-1 mutation (Peters et al., 1992).
Since mature au plants contain considerable amounts of
phytochrome, we might expect that the hp-1 mutation would be
able to fully rescue the leaf-color phenotype of mature au
plants. Further support comes from the comparison of au with
other phytochrome-deficient tomato mutants. The phyA-deficient
fri mutant (van Tuinen et al., 1995a), the phyB1-deficient
tri mutant (van Tuinen et al., 1995b), and the fri,tri double mutant do not exhibit the pale
coloring that is characteristic of au and yg-2.
This suggests that, if the phenotype of au and
yg-2 is primarily the result of a phytochrome deficiency, it
is not mediated by phyA or phyB1 but by the absence of one or more of
the additional phytochrome species in tomato, possibly in combination
with reduced levels of phyA. A mutant plant deficient in all
phytochrome apoproteins will be required before we can confidently
estimate the extent to which phytochrome deficiency contributes to the
golden phenotype of au.
Both au and yg-2 exhibit a marked susceptibility
to bleaching under high-light and low-temperature conditions. This
phenotypic trait can be accounted for by the explanations given above,
because plants with a low steady-state rate of chlorophyll synthesis
are more likely to be severely chlorophyll deficient under these
conditions. However, there are two additional explanations for this
bleaching phenotype. The first is that mutant plants might accumulate
pigments that cause photooxidative damage. Proto IX, which was present in au and yg-2 after ALA feeding in the dark
(Fig. 5), would be a prime candidate for mediating such an effect.
Alternatively, results of experiments with transgenic Arabidopsis
plants expressing mammalian biliverdin reductase have led to the
suggestion that phytochrome has an important role in regulating light
tolerance (Lagarias et al., 1997). Biliverdin reductase can metabolize
both biliverdin IX and PB to inactive rubins, and the resulting
phytochrome-chromophore-deficient plants are particularly sensitive to
high fluence rates of light. Since feedback inhibition does not
contribute to the phenotype of these plants, it is possible that the
loss of phytochrome is the primary cause of the chlorophyll deficiency
by preventing normal regulation of photosytem stoichiometry. Further
work on the characterization of phytochrome-chromophore-deficient
mutants is required to resolve these issues. This will be particularly important if this class of mutants are to be used effectively as
phytochrome-deficient controls in the study of plant growth and
development.
| |
FOOTNOTES |
1
M.J.T. is a Royal Society University Research
Fellow.
*
Corresponding author; e-mail mjt{at}soton.ac.uk; fax
44-1703-594269.
Received April 23, 1998;
accepted September 25, 1998.
| |
ABBREVIATIONS |
Abbreviations:
ALA, 5-aminolevulinic acid.
Pchlide, protochlorophyllide.
phyA, phytochrome A holoprotein.
phyB1, phytochrome B1 holoprotein.
PHYA, phytochrome A apoprotein.
PHYB1, phytochrome B1 apoprotein.
POR, NADPH:protochlorophyllide
oxidoreductase.
Proto IX, protoporphyrin IX.
PB, phytochromobilin.
| |
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