Biogenesis of chloroplast membranes. I. Plastid dedifferentiation in a dark-grown algal mutant (Chlamydomonas reinhardi)

This paper describes the morphology and photosynthetic activity of a mutant of Chlamydomonas reinhardi (y-1) which is unable to synthesize chlorophyll in the dark. When grown heterotrophically in the light, the mutant is indistinguishable from the wild type Chlamydomonas. When grown in the dark, chlorophyll is diluted through cell division and the photosynthetic activity (oxygen evolution, Hill reaction, and photoreduction of NADP) decays at a rate equal to or faster than that of chlorophyll dilution. However, soluble enzymes associated with the photosynthetic process (alkaline FDPase, NADP-linked G-3-P dehydrogenase, RuDP carboxylase), as well as cytochrome f and ferredoxin, continue to be present in relatively high concentrations. The enzymes involved in the synthesis of the characteristic lipids of the chloroplast (including mono- and digalactoside glycerides, phosphatidyl glycerol, and sulfolipid) are still detectable in dark-grown cells. Such cells accumulate large amounts of starch granules in their plastids. On onset of illumination, dark-grown cells synthesize chlorophyll rapidly, utilizing their starch reserve in the process. At the morphological level, it was observed that during growth in the dark the chloroplast lamellar system is gradually disorganized and drastically decreased in extent, while other subchloroplast components are either unaffected (pyrenoid and its tubular system, matrix) or much less affected (eyespot, ribosomes). It is concluded that the dark-grown mutant possesses a partially differentiated plastid and the enzymic apparatus necessary for the synthesis of the chloroplast membranes (discs). The advantage provided by such a system for the study of the biogenesis of the chloroplast photosynthetic membranes is discussed.     

Characterization of Chlamydomonas mutants defective in the H subunit of Mg-chelatase

Two chlorophyll-deficient mutants of Chlamydomonas reinhardtii, chl1 and brs-1, are light sensitive and, when grown heterotrophically in the dark, accumulate protoporphyrin IX and exhibit yellow/orange pigmentation. The lesions in both mutants were mapped to the gene (CHLH) for the plastid-localized H subunit of the heterotrimeric magnesium chelatase that catalyzes the insertion of magnesium into protoporphyrin IX. The genetic defects in the mutants could be assigned to +1 frameshift mutations in exon 9 (chl1) and exon 10 (brs-1) of the CHLH gene. In both mutants, the H subunit of magnesium chelatase was undetectable, but, as shown for chl1, the steady-state levels of the I and D subunits were unaltered in comparison to wild type. The CHLH gene exhibits marked light inducibility: levels of both the mRNA and the protein product are strongly increased when cultures are shifted from from the dark into the light, suggesting that this protein may play a crucial role in the light regulation of chlorophyll biosynthesis.     

GENETIC CONTROL OF CHLOROPHYLL BIOSYNTHESIS IN CHLAMYDOMONAS : Analysis of Mutants at Two Loci Mediating the Conversion of Protoporphyrin-IX to Magnesium Protoporphyrin

In this report we describe two nonallelic Mendelian protoporphyrin accumulating mutants br_s-1 and br_c-1. Results of experiments with these mutants lead us to postulate that porphyrin biosynthesis branches into light and dark steps between protoporphyrin-IX and magnesium protoporphyrin. We hypothesize that the br_c locus controls a dark step while the br_s locus either controls a step in the main pathway before the branch or mediates the preparation of the magnesium ion for its insertion into protoporphyrin-IX. The br_s-1 mutant is thought to be light sensitive because a block prior to the branch point in the porphyrin pathway prevents chlorophyll formation in either the light or the dark. The br_c-1 mutant, which also accumulates protoporphyrin in the dark, forms chlorophyll and chloroplast lamellae when transferred to the light, showing that function of the porphyrin pathway is normal in the light.     

Isolation and physiological and biochemical characterization of the Chlamydomonas reinhardtii C-41 mutant,a superproducer of ζ-carotene

The composition of the carotenes and xanthophylls of Chlamydomonas reinhardtii Dang. C-41, a mutant of a unicellular green alga and a superproducer of ζ-carotene, was studied. The light-harvesting complexes and a complex of the PS-II reaction center were established to be disrupted in the C-41 mutant. However, the mutant retained a high (up to 46%) photosynthetic activity and the capacity to accumulate chlorophylls and carotenoids (up to 50%). The composition of carotenes was studied, and it was shown that, in contrast to wild-type K(+) cells, which accumulate up to 95% of β-carotene and 5% α-carotene, cells of the C-41 mutant contained 43% β-carotene, 19% β-zeacarotene, and 38% ζ-carotene. The high level of C-41 mutant biomass accumulation made it possible to recommend the mutant as a superproducer of ζ-carotene in phytobiotechnology.     

Chloroplast Biogenesis: XX. Accumulation of Porphyrin and Phorbin Pigments in Cucumber Cotyledons during Photoperiodic Greening

A study of greening in cucumber (Cucumis sativus L.) cotyledons grown under a light (14-hour) dark (10-hour) photoperiodic regime was undertaken. The pools of protoporphyrin IX, Mg-protoporphyrin IX monoester, protochlorophyllide, and protochlorophyllide ester were determined spectrofluorometrically. Chlorophyll a and b were monitored spectrophotometrically. Pigments were extracted during the 3rd hour of each light period and at the end of each subsequent dark period during the first seven growth cycles. Protoporphyrin IX did not accumulate during greening. Mg-protoporphyrin IX monoester and longer wavelength metalloporphyrins accumulated during the light cycles and disappeared in the dark. Their disappearance was accompanied by the accumulation of protochlorophyll. Higher levels of protochlorophyll were observed in the dark than in the light, and the greatest accumulation occurred during the third and fourth dark cycles. Protochlorophyllide was present in 3- to 10-fold excess over protochlorophyllide ester; it was detectable during the period of net chlorophyll accumulation as well as afterward. In contrast, protochlorophyllide ester was observable only during the first four photoperiodic cycles, suggesting that it was a metabolic intermediate only during the early stages of chlorophyll accumulation. Between the third and fourth growth cycles, a rapid increase in area and fresh weight per cotyledon began. This was accompanied by a 250-fold increase in the level of chlorophyll a + b during the three subsequent growth cycles. No lag period in the accumulation of chlorophyll b was observed, and at all stages of greening, the chlorophyll a/b ratio was approximately 3.     

Chloroplast signalling in the light induction of nuclear HSP70 genes requires the accumulation of chlorophyll precursors and their accessibility to cytoplasm/nucleus

Chlorophyll precursors Mg-protoporphyrin IX and its monomethylester are candidates for plastid-derived molecules involved in light signalling from the chloroplast to the nucleus. The pool sizes of these two Mg2+-containing porphyrins and of protoporphyrin IX transiently increased upon a shift of Chlamydomonas cultures from dark to light. This increase coincided with the accumulation of mRNAs encoded by the nuclear genes HSP70A and HSP70B. Analysis of a mutant (brs-1), previously shown to be defective in the light induction of these genes, revealed high levels of protoporphyrin IX but no light-induced increase in the levels of Mg2+-containing porphyrins. Inhibitors of cytoplasmic protein synthesis prevented both the light-induced rise in pool levels and induction of the HSP70 genes. Similarly, pre-gametes, intermediates of sexual differentiation, lacked both responses to light. The block in light induction of the HSP70 genes in inhibitor-treated cells and in pre-gametes could be circumvented by the exogenous addition of Mg-protoporphyrin IX in the dark. This suggests an essential role for light-induced Mg-protoporphyrin IX accumulation in this chloroplast-to-nucleus signalling pathway. However, accumulation of this porphyrin in the dark - presumably in the chloroplast - did not result in induction. A second crucial role for light in this signalling pathway is postulated which makes this plastidic compound accessible to the cytoplasm/nucleus where the downstream signalling pathway may be activated.     

Metabolism of Magnesium Protoporphyrin Monomethyl Ester in Chlamydomonas reinhardtii

The y-1 mutant of Chlamydomonas reinhardtii is defective in the conversion of protochlorophyllide (Pchlide) to chlorophyllide in the dark. Aerobic δ-aminolevulinic acid (ALA) feeding of y-1 cells causes protoporphyrin monomethyl ester (PME) to accumulate in addition to increased levels of Pchlide. y-1 cell homogenates are not capable of methylating protoporphyrin (PROTO) to form PME but can methylate magnesium protoporphyrin (MgP) to form magnesium protoporphyrin monomethyl ester (MgPME). Anaerobic ALA feeding of y-1 causes concomitant accumulation of PME and MgPME. y-1 cells treated with α,α′-dipyridyl (DP) accumulate MgPME but not PROTO or PME. A mutant strain (bme) of Chlamydomonas has been isolated which has very little chlorophyll and accumulates PME. bme Cell homogenates can methylate MgP but not PROTO. We propose that: (a) in Chlamydomonas, PME is the initial breakdown product of MgPME; (b) both the breakdown of MgPME to PME and the conversion of MgPME to Pchlide require O₂; (c) the breakdown of MgPME to PME appears to require Fe; and (d) the PME accumulated in the bme mutant is the result of an increased breakdown of MgPME.     

Heme, a plastid-derived regulator of nuclear gene expression in Chlamydomonas

To gain insight into the chloroplast-to-nucleus signaling role of tetrapyrroles, Chlamydomonas reinhardtii mutants in the Mg-chelatase that catalyzes the insertion of magnesium into protoporphyrin IX were isolated and characterized. The four mutants lack chlorophyll and show reduced levels of Mg-tetrapyrroles but increased levels of soluble heme. In the mutants, light induction of HSP70A was preserved, although Mg-protoporphyrin IX has been implicated in this induction. In wild-type cells, a shift from dark to light resulted in a transient reduction in heme levels, while the levels of Mg-protoporphyrin IX, its methyl ester, and protoporphyrin IX increased. Hemin feeding to cultures in the dark activated HSP70A. This induction was mediated by the same plastid response element (PRE) in the HSP70A promoter that has been shown to mediate induction by Mg-protoporphyrin IX and light. Other nuclear genes that harbor a PRE in their promoters also were inducible by hemin feeding. Extended incubation with hemin abrogated the competence to induce HSP70A by light or Mg-protoporphyrin IX, indicating that these signals converge on the same pathway. We propose that Mg-protoporphyrin IX and heme may serve as plastid signals that regulate the expression of nuclear genes.     

delta-Aminolevulinic Acid Synthase of Euglena gracilis: Regulation of Activity

δ-Aminolevulinic acid (ALA), a key precursor of the tetrapyrroles heme and chlorophyll, is capable of being synthesized by two different routes in cells of the unicellular green alga Euglena gracilis: from the intact carbon skeleton of glutamate, and via the condensation of glycine and succinyl CoA, mediated by the enzyme ALA synthase. The regulatory properties of ALA synthase were examined in order to establish its role in Euglena.

Partially purified Euglena ALA synthase, unlike the case with the bacterial or animal-derived enzyme, does not exhibit allosteric inhibition by the tetrapyrrole pathway products heme, protoporphyrin IX, and porphobilinogen, at concentrations up to 100 micromolar.

In aplastidic mutant cells, extractable ALA synthase activity is constant during exponential growth, and decreases to low levels as the cells reach the stationary state. Rapid exponential decline of ALA synthase (t_1/2 = 55 min) occurs after administration of 43 micromolar cycloheximide, but not 6.2 millimolar chloramphenicol. These results suggest that, as in other eukaryotic cells, ALA synthase is synthesized on cytoplasmic ribosomes and is subject to rapid turnover in vivo.

Extractable ALA synthase activity increases 2.5-fold within 6 hours after administration of 100 millimolar ethanol, a stimulator of mitochondrial development, and 4.5-fold within 12 hours after administration of 1 millimolar 4,6-dioxoheptanoic acid, which blocks ALA utilization, suggesting that activity is controlled in vivo by a feedback induction-repression mechanism, coupled with rapid enzyme turnover.

In heterotrophically grown wild-type cells, low levels of ALA synthase rapidly increase 4.5-fold within 12 hours after cells are transferred from the light to the dark, and decrease exponentially (t_1/2 = 75 min) when cells are transferred from the dark to light. The dark levels are equal to those in light- or dark-grown aplastidic mutant cells. The low level occurring in light-grown wild-type cells is not altered by the presence of 10 micromolar 3-(3,4-dichlorophenyl)-1,1-dimethylurea, which blocks photosynthetic O₂ production. The decrease that occurs on dark-to-light transfer can be diminished by 12- or 24-hour prior incubation with 6.2 millimolar chloramphenicol, which also retards chlorophyll synthesis after the transfer to light.

The positive relationship of ALA synthase activity to degree of mitochondrial expression, and the inverse relationship to plastid development and chlorophyll synthesis, suggests that ALA synthase functions to provide precursors to nonplastid tetrapyrroles in Euglena. In light-grown, wild-type cells, the diminished levels of ALA synthase may be due to the ability of developing plastids to export heme or a heme precursor to other cellular regions, which thereby supplants the necessity for ALA formation via the ALA synthase route.

     

Regulation of light-harvesting chlorophyll-binding protein mRNA accumulation in Chlamydomonas reinhardi. Possible involvement of chlorophyll synthesis precursors

Light induction of light-harvesting chlorophyll a/b-binding protein (LHCP) mRNA accumulation was studied in light-dark synchronized cultures of Chlamydomonas reinhardi. LHCP mRNA accumulation was prevented by the chlorophyll-synthesis inhibitor alpha,alpha-dipyridyl which blocks late steps in the chlorophyll biosynthetic pathway and leads to the accumulation of the porphyrin intermediate magnesium protoporphyrin methyl ester. LHCP mRNA accumulated normally, however, when chlorophyll synthesis was blocked by inhibitors such as hemin and levulinic acid which interfere with early steps in the chlorophyll biosynthesis pathway prior to the formation of magnesium protoporphyrin methyl ester. Similar effects were observed in the light induction of LHCP mRNA levels in protoporphyrin IX-accumulating mutants, brc-1 and brs-1. These mutants have low levels of LHCP mRNA when grown under heterotrophic conditions in the dark where they accumulate protoporphyrin IX. However, LHCP mRNA is light-induced in brc-1 which synthesizes chlorophyll in the light and presumably consumes porphyrin intermediates in doing so. These results suggest that the chlorophyll-synthesis intermediates, magnesium protoporphyrin methyl ester and its immediate precursors, inhibit by a feedback mechanism the light induction of LHCP mRNA accumulation. Low magnesium protoporphyrin methyl ester levels permit the light-induced accumulation of LHCP mRNA, whereas high magnesium protoporphyrin methyl ester levels destabilize LHCP mRNA regardless of the illumination conditions. Preliminary experiments show that LHCP mRNA accumulation in C. reinhardi is stimulated by blue light, and not by red light which stimulates LHCP mRNA accumulation in higher plants.     

Biogenesis of chlorophyll-binding proteins under iron stress in <Emphasis Type="Italic">Synechocystis</Emphasis> sp. PCC 6803

The biogenesis of chlorophyll-binding proteins under iron stress has been investigated in vivo in a chlN deletion mutant of Synechocystis sp. PCC 6803. The chlN gene encodes one subunit of the light-independent protochlorophyllide reductase. The mutant is unable to synthesize chlorophyll in darkness, causing chlorophyll biosynthesis to become light dependent. When the mutant was propagated in darkness, essentially no chlorophyll and photosystems were detected. Upon return of the chlN deletion mutant to light, 77 K fluorescence emission spectra and oxygen evolution of greening cells under iron-sufficient or-deficient conditions were measured. The gradual blue shift of the photosystem I (PS I) peak upon greening under iron stress suggested the structural alteration of newly synthesized PS I. Furthermore, the rate of biogenesis of PS II was delayed under iron stress, which might be due to the presence of IsiA.     

Effect of Dim Light on the y-1 Mutant of Chlamydomonas reinhardtii

The y-1 mutant of Chlamydomonas reinhardtii tends to die or revert to wild type when grown in the dark for a long period of time. A small amount of white light (0.5 lux) enables the y-1 mutant to grow indefinitely in a “near dark” condition. Under this condition, the y-1 mutant is physiologically and ultrastructurally similar to the dark-grown y-1 yet remains genetically stable.     

The psbO mutant of Chlamydomonas reinhardtii is capable of assembling stable, photochemically active reaction center of photosystem II

The functional status of photosystem II (PSII) complex in the dark-grown PsbO-deficient mutant of green alga Chlamydomonas reinhardtii was studied. It was found that ΔpsbO mutant cells of C. reinhardtii grown under heterotrophic conditions (dark + acetate) were capable of assembling stable, photochemically-competent reaction centers of PSII (as confirmed by immunological analysis of D1 protein level, pigments content and photoinduced changes of PSII chlorophyll fluorescence yield), while O₂-evolution activity was not revealed. The ratio F _v/F _m for the dark-grown ΔpsbO mutant C. reinhardtii was 0.37 and that for the dark-grown wild type cells was 0.56. Analysis of chlorophyll fluorescence induction curve indicated that the absence of oxygen-evolving activity could be due to some defects in the organization of the PSII catalytic manganese cluster. Decrease of the rate of the electron donation from water-oxidizing complex to the PSII reaction center as well as the appearance of an additional transient fluorescence peak during the dark relaxation of F _v testify to the damages to the PSII donor side. The data obtained suggest that the dark-grown PsbO-deficient cells of C. reinhardtii are able to form stable, photochemically active PSII reaction center, unable to oxidize water due to probable defects in the assembly of the manganese cluster.     

Responses of a Mutant Strain of Chlamydomonas reinhardi to Prolonged Organotrophic Growth

The responses of the wild type strain and of the y-2 mutant strain of Chlamydomonas reinhardi to long term organotrophic growth were studied. It was shown that wild type can be cultured as an organotroph for at least a month with little decrease in chlorophyll content and no loss of viability. On the other hand, the mutant strain y-2 dies during such organotrophic growth, death beginning after 5 to 6 days in the dark. The kinetics of death indicate that the loss of 95% of the chlorophyll precedes death and that revertants to wild type overgrow such a culture. The results suggest that death of y-2 is correlated with the loss of chlorophyll rather than simple metabolic response to organotrophy and that the chloroplast or a chloroplast related factor may perform certain nonphotosynthetic functions in C. reinhardi. The activities of nicotine adenine dinucleotide and nicotine adenine dinucleotide phosphate dependent triose phosphate dehydrogenases were studied during long term organotrophic growth of y-2. It was found that the activities of these enzymes varied in a manner consistent with previous findings under these conditions. The activity of glutamic dehydrogenase was found to vary as a function of chlorophyll content in the mutant strain y-2.