Cytokinin effects on tetrapyrrole biosynthesis and photosynthetic activity in barley seedlings

Cytokinin promotes morphological and physiological processes including the tetrapyrrole biosynthetic pathway during plant development. Only a few steps of chlorophyll (Chl) biosynthesis, exerting the phytohormonal influence, have been individually examined. We performed a comprehensive survey of cytokinin action on the regulation of tetrapyrrole biosynthesis with etiolated and greening barley seedlings. Protein contents, enzyme activities and tetrapyrrole metabolites were analyzed for highly regulated metabolic steps including those of 5-aminolevulinic acid (ALA) biosynthesis and enzymes at the branch point for protoporphyrin IX distribution to Chl and heme. Although levels of the two enzymes of ALA synthesis, glutamyl-tRNA reductase and glutamate 1-semialdehyde aminotransferase, were elevated in dark grown kinetin-treated barley seedlings, the ALA synthesis rate was only significantly enhanced when plant were exposed to light. While cytokinin do not stimulatorily affect Fe-chelatase activity and heme content, it promotes activities of the first enzymes in the Mg branch, Mg protoporphyrin IX chelatase and Mg protoporphyrin IX methyltransferase, in etiolated seedlings up to the first 5 h of light exposure in comparison to control. This elevated activities result in stimulated Chl biosynthesis, which again parallels with enhanced photosynthetic activities indicated by the photosynthetic parameters F _V/F _M, J _CO2max and J _CO2 in the kinetin-treated greening seedlings during the first hours of illumination. Thus, cytokinin-driven acceleration of the tetrapyrrole metabolism supports functioning and assembly of the photosynthetic complexes in developing chloroplasts.     

Effect of kinetin on early stages of chlorophyll biosynthesis in streptomycin-treated barley seedlings

Treatment of barley seeds (Hordeum vulgare L.) with streptomycin, an inhibitor of plastid protein synthesis, resulted in growth of the albino phenotype seedlings with ribosome-deficient undifferentiated plastids and chlorophyll (Chl) level as low as 0.1% of that in control plant leaves. A major effect of the antibiotic was almost complete suppression of the ability of plants to synthesize 5-aminolevulinic acid (ALA) intended for Chl biosynthesis. The activity of synthesis of ALA intended for heme porphyrin biosynthesis in etiolated and greening seedlings and in light-grown albinophenotype plants was insensitive to light and cytokinins. In the upper parts of leaves of streptomycin-treated plants, exhibiting 60% Chl deficit, the cells with three types of chloroplasts could be observed: normally developed chloroplasts, chloroplasts composed of single thylakoids and grana, and completely undifferentiated plastids. In this Chl-deficient tissue, ALA synthesis was found to be stimulated by kinetin but much less than in leaves of the control plants. The endogenous cytokinin content in etiolated and greening seedlings treated with streptomycin was almost the same as it was in untreated control seedlings. The cytokinin level in the white tissue of plants grown in the light was on average twice as high as that in green leaves of the control plants. The capability of kinetin to stimulate the synthesis of ALA used for Chl biosynthesis was found to correlate with the Chl content and organization of the chloroplast internal structure. This correlation confirms the hypothesis that the normally developed internal structure of plastids is essential for the adequate phytohormone response in plants.     

Activity of the Fe-Branch of Tetrapyrrole Biosynthesis in the Chlorophyll-Deficient Plastome Mutant of Sunflower

The biosynthesis of heme, a plant tetrapyrrole, was studied in the leaves of a chlorophyll-deficient plastome mutant of the sunflower (Helianthus annuus L, line 2-24, albina form). In the light, the content of 5-aminolevulinic acid (ALA) in white mutant leaves was, on the average, ten times less than in that of the wild-type form (line 3629). Chlorophyll content in mutant leaves comprised only 0.3% of that of control plants. The activities of Fe-chelatase and ALA dehydratase in the heme synthesis were either comparable to or even higher than those in the wild-type leaves. A normal respiration rate in white mutant leaves, the equal content of phytochrome apoproteins in plants of both types, and the lack of noticeable morphogenetic differences realized through the phytochrome system can indicate that mutant and wild-type leaves are similar in their levels of phytochrome and the cytochromes of mitochondrial respiration. Nevertheless, in the mutant, the content of heme noncovalently bound by apoproteins amounted to only one third of its content in the wild-type plants. It seems that a dramatic decrease in the capability of white leaves for chlorophyll biosynthesis and for the formation of the photosynthetic apparatus is responsible for a low demand for chloroplast cytochromes, which is the major cause of a reduced heme content in the mutant.     

A novel role of water-soluble chlorophyll proteins in the transitory storage of chorophyllide

All chlorophyll (Chl)-binding proteins involved in photosynthesis of higher plants are hydrophobic membrane proteins integrated into the thylakoids. However, a different category of Chl-binding proteins, the so-called water-soluble Chl proteins (WSCPs), was found in members of the Brassicaceae, Polygonaceae, Chenopodiaceae, and Amaranthaceae families. WSCPs from different plant species bind Chl a and Chl b in different ratios. Some members of the WSCP family are induced after drought and heat stress as well as leaf detachment. It has been proposed that this group of proteins might have a physiological function in the Chl degradation pathway. We demonstrate here that a protein that shared sequence homology to WSCPs accumulated in etiolated barley (Hordeum vulgare) seedlings exposed to light for 2 h. The novel 22-kD protein was attached to the outer envelope of barley etiochloroplasts, and import of the 27-kD precursor was light dependent and induced after feeding the isolated plastids the tetrapyrrole precursor 5-aminolevulinic acid. HPLC analyses and spectroscopic pigment measurements of acetone-extracted pigments showed that the 22-kD protein is complexed with chlorophyllide. We propose a novel role of WSCPs as pigment carriers operating during light-induced chloroplast development.     

The white barley mutant albostrians shows a supersusceptible but symptomless interaction phenotype with the hemibiotrophic fungus Bipolaris sorokiniana

Bipolaris sorokiniana (teleomorph: Cochliobolus sativus) is a cereal pathogen of increasing global concern, with most significance in Asiatic cropping systems. In order to gain insight into the mechanism of host resistance, we studied fungal development on the supersusceptible barley mutant albostrians and its parent cv. Haisa. A microscopic dissection of early fungal growth on Haisa and green albostrians leaves revealed a distinct epidermis-localized biotrophic and a mesophyll-based necrotrophic phase. White, green, and striped white-green albostrians leaves showed extreme differences in disease development. When comparing cellular defense responses, we found restriction of fungal spreading after successful infection of host mesophyll tissue to be the most important mechanism limiting outbreak of the disease. Colonization of susceptible green leaves, but not extreme colonization of supersusceptible white albostrians leaves, was associated with macroscopically visible lesion formation and mesophyll accumulation of hydrogen peroxide (H2O2), implying a symptomless growth of the pathogen in supersusceptible host tissue. In contrast, early epidermal papilla-based resistance was closely linked to H2O2 accumulation in all leaf types. In white leaves, ascorbate peroxidase (APX), glutathione-S-transferase (GST), and the cell death regulator Bax-inhibitor-1 (BI-1) showed a stronger constitutive or pathogen responsive activation, whereas glycolate oxidase (GLOX) and catalase (CAT2) expression was stronger in green leaves. We discuss supersusceptibility and symptomless growth on the basis of the histochemical and the gene expression data.     

Coproporphyrinogen III oxidase from barley and tobacco — sequence analysis and initial expression studies

Coproporphyrinogen III oxidase (coprogen oxidase; EC 1.3.3.3) is part of the pathway from 5-aminolevulinate to protoporphyrin IX which is common in all organisms and catalyses oxidative decarboxylation at two tetrapyrrole side chains. We cloned and sequenced fulllength cDNAs encoding coprogen oxidase from barley (Hordeum vulgare L.) and tobacco (Nicotiana tabacum L.). They code for precursor peptides of 43.6 kDa and 44.9 kDa, respectively. Import into pea plastids resulted in a processed tobacco protein of approx. 39 kDa, which accumulated in the stroma fraction. Induction of synthesis of recombinant putative tobacco mature coprogen oxidase consisting of 338 amino-acid residues in Escherichia coli at 20°C result in a catalytically active protein of approx. 39 kDa, while induction of its formation at 37°C immediately terminated bacterial growth, possibly due to toxic effects on the metabolic balance of tetrapyrrole biosynthesis. The plant coprogen oxidase gene was expressed to different extents in all tissues investigated. This is most likely due to the differing requirements for tetrapyrroles in different organs. The steady-state level of mRNA did not significantly differ in etiolated and greening barley leaves. The content of coprogen oxidase RNA reached its maximum in developing cells and decreased drastically when cells were completely differentiated. Functioning of the two photosystems apparatus requires the synthesis of all pigment and protein components during plant development. It is speculated that the enzymes involved in tetrapyrrole synthesis are developmentally rather than light-dependently regulated. Regulation of these enzymes also guarantees a constant flux of metabolic intermediates and avoids photodynamic damage by accumulating porphyrins. Accession number: The nucleotide sequence data reported will appear in the EMBL, GenBank and DDBJ Nucleotide Sequence Databases under the accession numbers X82830 (barley coprogen oxidase) and X82831 (tobacco coprogen oxidase).     

Partial blocks in the early steps of the chlorophyll synthesis pathway: A common feature of chlorophyll b-deficient mutants

We have analyzed precursor pools in the chlorophyll (Chi) synthesis pathway for a set of eighteen well studied Chl b -defident mutants in monocotyledonous (barley, maize and wheat) and dicotyledonous plants ( Antirrhinum, Arabidopsis , soybean, tobacco and tomato) that form abnormal thylakoid membrane systems. All of these mutants have a partial block in Chl synthesis and nearly all of them accumulate protoporphyrin IX (Proto), the last porphyrin compound common to both heme and Chl synthesis. The large number of mutants at several genetic loci affecting this critical branchpoint in tetrapyrrole biosynthesis suggests that the Mg-chelatase enzyme, catalyzing the first committed step of Chi biosynthesis, is a multimeric complex composed of the products of some of these genetic loci, and perhaps regulated by others. We hypothesize that these mutants are Chi b -deficient and have reduced amounts of light-harvesting antenna complexes (LHCs.) and develop abnormal thylakoid membranes as a direct result of limited Chl synthesis. The observed bottleneck in Chl synthesis can also explain the light-intensity-dependent and temperature-dependent expression of the mutant phenotype. This hypothesis offers a simple explanation for the wide variety of pbenotypes that have been reported for the many Chl-deficient mutants in the literature. Our findings are also consistent with the notion that Chl b is made from "left over" Chl a molecules and suggest that the Chi b -deficient mutants should be considered more appropriately as leaky Chl-deficient mutants.     

Incorporation of 5-aminolevulinic acid into chlorophyll in darkness in barley

The incorporation of radioactive aminolevulinic acid (ALA) into chlorophyll (Chl) a and b , as well as protochlorophyllide (Pchlide) in light-grown barley seedlings ( Hordeum vulgare L. cv. Clipper) transferred to darkness is demonstrated.
In the experiments described, 6-day-old, glasshouse-grown seedlings were transferred to darkness and incubated in [¹⁴C]- or [³H]- ALA for 18 h.
Chl a and b were extracted and purified to constant specific radioactivity by HPLC and TLC of their magnesium-free derivatives, pheophytin a and b . The presence of label in the tetrapyrrole ring of the Chls was established by removal of the phytol chain by alkaline hydrolysis and determination of the specific radioactivity of the chlorin e ₆ and rhodin g ₇ derivatives.
Barley seedlings that had been grown in darkness for 5 days, transferred to light for 20 h, and then returned to darkness in the presence of radioactive ALA also incorporated label into Chl. However, this was only apparent in intact seedlings. Excised leaves from greened etiolated plants did not incorporate ALA into Chl in darkness. This was consistent with the finding of Apel et al. (K. Apel, M. Motzkus and K. Dehesh, 1984. Planta 161: 550–554) and may account for their failure to obtain evidence for a light-independent protochlorophyllide reductase in greening barley.
Although the incorporation of ALA into Chl compared to Pchlide was slight (5%), the presence of label in the tetrapyrrole nucleus of Chl a and b is unequivocal evidence of a light-independent pathway of Chl biosynthesis in barley that has been exposed to light during development. Limited entry of exogenous labelled ALA into the precursor pools leading to the dark reduction of Pchlide is postulated.     

Regulatory network of tetrapyrrole biosynthesis – studies of intracellular signalling involved in metabolic and developmental control of plastids

Plant tetrapyrrole metabolism is located in two different organelles and distributes end products into the whole cell. A complex regulatory network is involved to prevent metabolic imbalance and inefficient allocation of intermediates as well as to correlate the metabolic activities with organelle development. This review presents new findings about the control of tetrapyrrole biosynthesis and addresses the question of which regulatory principles are involved in controlling the expression of the participating enzymes and the metabolic flow in the entire pathway. It is suggested that functional organelles are required for nuclear gene expression and that metabolic signals participate in a signalling cascade transferring information from plastids to the nucleus. Recent reports about plastid-localised control mechanisms for plant tetrapyrrole metabolism are summarised and compared with results obtained in experiments on nucleus-plastid communication.     

Repression of the Plastidic Isoenzymes of Aldolase, 3-Phosphoglycerate Kinase, and Triosephosphate Isomerase in the Barley Mutant "albostrians"

White leaves of the mutant line albostrians and green leaves of the wild-type cultivar Salome of barley (Hordeum vulgare L.) were screened for the presence of plastidic and cytosolic isoenzymes of sugar-phosphate metabolism. Isoenzyme separation was achieved by anion-exchange chromatography on Fractogel TSK DEAE-650(S). The mutant tissue had a markedly reduced level of plastidic 3-phosphoglycerate kinase, triosephosphate isomerase, and aldolase activity. In contrast, the activity of plastidic glucosephosphate isomerase, fructose 1,6-bisphosphatase, 6-phosphogluconate dehydrogenase, starch phosphorylase, and ADP-glucose pyrophosphorylase was in the same range as in wild-type leaf tissue. The activity of the corresponding cytosolic isoenzymes (including UDP-glucose pyrophosphorylase) showed essentially no differences in mutant and wild type. The same trend was observed in dark-grown mutant and wild-type leaves. Interestingly, the total activity levels of all isoenzymes were about the same when comparing dark-grown and light-grown mutant or wild-type plants. From these data, it is concluded that mutant leaves exhibit a selective decrease of a subgroup of plastidic isoenzymes associated with the Calvin cycle.     

Polar lipid composition of a plastid ribosome-deficient barley mutant

Green and white leaves of the barley mutant line `albostrians' were compared for their polar lipid content and fatty acid composition. The mutant plastids of the white leaves have a double-layered envelope, but in contrast with the normal chloroplasts, lack 70 S ribosomes and thylakoids. In the green leaves, the amount of monogalactosyldiacylglycerol (MGDG) consistently exceeds the amount of digalactosyldiacylglycerol (DGDG) and the amount of galactolipids exceeds the amount of phospholipids. In contrast, in white leaves the amount of DGDG exceeds the amount of MGDG and the amount of phospholipids exceeds the amount of galactolipids. In white leaves, the galactolipid composition reflects the plastid envelope composition which is rich in DGDG, whereas in green leaves the galactolipid composition reflects the thylakoid composition which is rich in MGDG. These results demonstrate the likelihood that all the enzymes involved in galactolipid, sulfolipid and fatty acid synthesis are coded by the nuclear genome.     

The Effect of Diuron and 5-Aminolevulinic Acid on the Maintenance of Stable Chlorophyll Content in Greening Barley Leaves

Chlorophyll (Chl) accumulation and delayed luminescence of PSII were compared in greening barley leaves pretreated and untreated with diuron (DCMU) in the etiolated state, and reactions of two photosystems were studied in the plastids isolated from the pretreated and untreated leaves. The effect of treatment in light of post-etiolated leaves after 40-h illumination with 5-aminolevulinic acid (ALA), on the content of Chl and its precursor, protochlorophyllide (PChld) was also studied. The pretreatment of etiolated leaves with DCMU did not affect the rate of greening and the stable level of Chl content in barley. ALA, when introduced to leaves after the termination of Chl accumulation, increased PChld, but not Chl level. We suppose that the primary cause of greening cessation in etiolated leaves is the inhibition and cessation of the synthesis of apoproteins of pigment–protein complexes. The exhaustion of binding sites for newly synthesized Chl molecules leads to their retention in the so-called retroinhibitory pool of Chl, thus resulting in the inhibition of ALA synthesis by a negative feedback mechanism.