Chloroplast biogenesis 84: solubilization and partial purification of membrane-bound [4-vinyl]chlorophyllide a reductase from etiolated barley leaves.

[4-Vinyl] chlorophyllide a reductase (4VCR) is a key enzyme of the chlorophyll (Chl) biosynthetic pathway. It catalyzes the conversion of divinyl chlorophyllide (Chlide) a to monovinyl Chlide a by reduction of the vinyl group at position 4 of the macrocycle to ethyl. 4VCR is a membrane-bound enzyme, embedded in etioplast and etiochloroplast membranes. A study of the regulation and properties of this enzyme is mandatory for a comprehensive understanding of the biosynthetic heterogeneity of Chl biosynthesis. Solubilization and partial purification of 4VCR are described for the first time. The enzyme was solubilized with 5 mM Chaps and was partially purified by chromatography on DEAE-Sephacel and Cibacron Blue 3GA-1000 agarose. An overall 20-fold purification was achieved. The partially purified enzyme was stable for several months at -80 degrees C.

Modulator of heme biosynthesis induces apoptosis in leukemia cells.

OBJECTIVE: The purpose of this research is the investigation of the possible cause(s) of the dark-cell death phenomenon induced by 1,10-phenanthroline (Oph), a porphyrin biosynthesis modulator. SUMMARY BACKGROUND DATA: We have previously shown that porphyrin biosynthesis modulators, such as Oph, which is also an iron-chelating agent, enhance protoporphyrin IX (Proto) accumulation in mammalian neoplastic cells treated with delta-aminolevulinic acid (ALA). As a result of the enhanced Proto accumulation, a significant increase in photodynamic damage was observed under illumination. Also tetrapyrrole and heme-biosynthesis modulators have been shown to cause death in treated insect larvae in darkness, a phenomenon referred to as dark-cell death. Dark-cell death was also observed in Oph + ALA-treated transformed mammalian cells. METHODS: Neoplastic cells were treated with ALA, Oph, and ALA + Oph, and the following cell properties were investigated: growth arrest, membrane permeability, cell survival, nucleosomal cleavage, and cell cycle alterations. RESULTS: It was observed that Oph but not ALA induced growth arrest, in a T-cell leukemia line (MLA 144) as assessed by reduction in DNA synthesis. Exogenous Proto and isomers of Oph lacking the iron-chelating property of Oph also caused a dose-dependent inhibition of proliferation in MLA 144 cells. Although the plasma membrane of Oph-treated cells remained intact following 3 h of dark-incubation, the cells exhibited DNA internucleosomal cleavage, characteristic of cells undergoing apoptosis. Cell cycle analysis using the DNA intercalating dye propidium iodide (PI) coupled to flow cytometry, indicated that 81 +/- 5.6% of Oph-treated MLA 144 cells were apoptotic, with the majority of the cells arrested in the early S phase. On the other hand, treatment with either ALA or Proto did not alter the cell cycle. Also, using a double-labeling protocol with Hoechst 33342, and PI, and analysis by flow cytometry, Oph-treated cells were found to be 82% apoptotic after 3 h of dark-incubation. Apoptosis was reduced by 75% (p < 0.05) by the cytoplasmic protein synthesis inhibitor cycloheximide. CONCLUSIONS: These results indicate that in addition to enhancing Proto accumulation, the heme biosynthesis modulator Oph also induces growth arrest and apoptosis in transformed cells in darkness.

Enhancement of coproporphyrinogen III transport into isolated transformed leukocyte mitochondria by ATP.

It has been proposed that in normal animal cells, biosynthesis of the heme precursor protoporphyrin IX (Proto) requires cooperation between the mitochondria and cytoplasm [S. Granick (1967) in Biochemistry of the Chloroplast (Goodwin, T. W., Ed.), pp. 373-410, Academic Press, NY]. In this work, the conversion of ALA to Coprogen in the cytoplasm of MLA 144 cells (a retrovirally transformed gibbon ape leukemic T cell line) is demonstrated. This in turn indicates that the intracellular localization of Coprogen biosynthesis in transformed animal cells is similar to that proposed for normal animal cells. It is also shown that in MLA 144 cells, after ALA conversion to Coprogen in the cytoplasm, Coprogen is transported into the mitochondria via an ATP-dependent process. The possible involvement of the mitochondrial peripheral-type benzodiazepine receptor (M-PBR) in Coprogen transport into mitochondria is discussed.

Induction of tumor necrosis by delta-aminolevulinic acid and 1,10-phenanthroline photodynamic therapy.

delta-Aminolevulinic acid (ALA) causes cells to accumulate protoporphyrin IX (Proto) and heme. Exposure to light in vitro causes intracellular Proto to initiate formation of singlet oxygen molecules, leading to self-destruction. This photoactivated destruction by ALA in vitro is enhanced by addition of the tetrapyrrole modulator 1,10-phenanthroline (Oph), which increases cellular accumulation of Proto. Here we significantly extend this idea by evaluating the efficacy of ALA and Oph photodynamic therapy of solid tumors in vivo. Methylcholanthrene-induced fibrosarcoma (Meth-A) cells were used, which lead to the formation of solid tumors when implanted into syngeneic recipients. Initially, suspensions of Meth-A cells were treated in vitro with combinations of ALA and Oph. Meth-A cells in suspension accumulated 6-fold greater amounts of Proto (P < 0.05) after 3-h incubation with ALA and Oph than when incubated with ALA alone, and were also more susceptible to subsequent photoactivated cell lysis in vitro. Similarly, solid Meth-A tumors grown in syngeneic BALB/c mice accumulated significant (P < 0.05) amounts of Proto 3 h after in vivo treatment with ALA, and Oph synergized with ALA to significantly (P < 0.05) enhance the induction of Proto in these tumors. ALA and Oph-based phototreatment of mice bearing Meth-A solid tumors resulted in necrosis of tumors, as determined by a significant reduction in both size and histopathology, with little damage to surrounding normal tissue. These data directly demonstrate the experimental usefulness of Proto modulators for ALA-based photodynamic therapy in the treatment of solid tumors in vivo and provide a rationale for their potential application in a multitude of tumor types.

Chloroplast biogenesis 72: a [4-vinyl]chlorophyllide a reductase assay using divinyl chlorophyllide a as an exogenous substrate.

[4-Vinyl]Chlorophyllide alpha reductase (4VCR) catalyzes the conversion of 2,4-divinyl chlorophyllide alpha (DV Chlide alpha) to 2-vinyl,4-ethyl chlorophyllide alpha (MV Chlide alpha) via an NAPDH- dependent reaction. MV Childe alpha is the immediate precursor of monovinyl chlorophyll alpha in plants. In etiolated cucumber (Cucumis sativus L.) cotyledons, 4VCR is a plastidic membrane-bound enzyme. Further research on this enzyme required the development of an assay that utilizes DV Childe alpha as an exogenous substrate. Such an assay is now described. It involves conversion of exogenous DV Chlide alpha to MV Chlide alpha at high rates by etioplast membranes of cucumber, corn (Zea mays L.), and barley (Hordum vulgare L.). 4VCR exhibits high activity between 30 and 40C and in the pH range of 6.3 to 7.0. Activity is quasilinear for the first 60 s of incubation.

Chlorophyll a biosynthetic heterogeneity.

Chlorophyll a biosynthesis is presently interpreted in terms of two different biochemical pathways. According to one pathway, chlorophyll a is made via a single linear chain of reactions starting with divinylprotoporphyrin IX and ending with monovinylchlorophyll a. The experimental evidence for this pathway is marred by incompletely characterized intermediates that were detected in Chlorella mutants. The second pathway considers chlorophyll a to be made via multiple and parallel biosynthetic routes that result in the formation and accumulation of monovinyl- and divinylchlorophyll a chemical species. Two of these routes, namely the di/monocarboxylic monovinyl and divinyl routes, are responsible for the biosynthesis of most of the chlorophyll a in green plants. The experimental evidence for these two routes consists of: (a) the detection and spectroscopic characterization of intermediates and end products; (b) the demonstration of precursor-product relationships between various intermediates in vivo and in vitro; and (c) the detection of 4-vinylreductases that appear to be mainly responsible for the observed biosynthetic heterogeneity. The biological significance of chlorophyll a biosynthetic heterogeneity is becoming better understood. On the basis of the prevalence of the di/monocarboxylic monovinyl-and divinylchlorophyll a biosynthetic routes, green plants have been classified into three different greening groups. It now appears that the major chlorophylls in the euphotic zone of tropical waters are divinylchlorophyll a and b. It also appears that the di/monocarboxylic monovinyl and divinyl biosynthetic routes lead to the formation of different pigment proteins in different greening groups of plants, and that the more highly evolved monovinylchlorophyll a biosynthetic route is associated with higher field productivity in wheat.

Chloroplast biogenesis: [4-vinyl] chlorophyllide a reductase is a divinyl chlorophyllide a-specific, NADPH-dependent enzyme.

Some properties of [4-vinyl] chlorophyllide a reductase are described. This enzyme converts divinyl chlorophyllide a to monovinyl chlorophyllide a. The latter is the immediate precursor of monovinyl chlorophyll a, the main chlorophyll in green plants. [4-Vinyl] chlorophyllide a reductase plays an important role in daylight during the conversion of divinyl protochlorophyllide a to monovinyl chlorophyll a. [4-Vinyl] chlorophyllide a reductase was detected in isolated plastid membranes. Its activity is strictly dependent on the availability of NADPH. Other reductants such as NADH and GSH were ineffective. The enzyme appears to be specific for divinyl chlorophyllide a, and it does not reduce divinyl protochlorophyllide a to monovinyl protochlorophyllide a. The conversion of divinyl protochlorophyllide a to monovinyl protochlorophyllide a has been demonstrated in barley and cucumber etiochloroplasts and appears to be catalyzed by a [4-vinyl] protochlorophyllide a reductase [Tripathy, B.C., & Rebeiz, C.A. (1988) Plant Physiol. 87, 89-94]. On the basis of reductant requirements and substrate specificity, it is possible that two different 4-vinyl reductases may be involved in the reduction of divinyl protochlorophyllide a and divinyl chlorophyllide a to their respective 4-ethyl analogues.

Chloroplast Biogenesis 65 : Enzymic Conversion of Protoporphyrin IX to Mg-Protoporphyrin IX in a Subplastidic Membrane Fraction of Cucumber Etiochloroplasts.

The preparation from Percoll-purified cucumber (Cucumis sativus)etiochloroplasts of a subplastidic membrane fraction that is capable of high rates of Mg insertion into protoporphyrin IX is described. The plastid stroma was inactive when used either alone or in combination with the membrane fraction. Successful preparation of the subplastidic membrane fraction required that Mg-protoporphyrin chelatase was first stabilized by its substrate. This was achieved by lysing Percoll-purified plastids in a fortified hypotonic medium containing protoporphyrin IX prior to ultracentrifugation and separation of the stroma from the plastid membranes. Protoporphyrin IX became membrane bound. Other additives needed for enzyme activity fell into two groups: (a) those needed for enzyme stabilization during membrane preparation and (b) those involved in the primary mechanism of Mg insertion into protoporphyrin IX. Ethylenediaminetetraacetate belonged to the first group, magnesium belonged to the second group, and ATP belonged to both groups.

Photodestruction of tumor cells by induction of endogenous accumulation of protoporphyrin IX: enhancement by 1,10-phenanthroline.

Rapidly proliferating transformed mammalian cells can be photodestroyed in vitro upon inducing the accumulation of endogenous protoporphyrin IX (Proto). Proto biosynthesis and accumulation were triggered by manipulation of the porphyrin-heme biosynthetic pathway. Proto accumulation in cultured cells was induced by treatment with 1.0 mM delta-aminolevulinic acid (ALA), a naturally occurring 5-carbon amino acid, for 3.5 h. In darkness, significant Proto accumulation became evident within 3.5 h of incubation. In the light, the accumulated tetrapyrroles triggered destruction of treated cells within the first 30 min of illumination, probably via the rapid oxidation of cellular constituents by singlet oxygen. Protoporphyrin IX accumulation and specific cell lysis increased significantly by inclusion of 0.75 mM 1,10-phenanthroline (Oph), a tetrapyrrole biosynthesis modulator. Slower growing untransformed cells did not accumulate significant amounts of Proto following ALA and Oph treatment unless stimulated to proliferate with the mitogenic lectin Concanavalin A.

Chloroplast biogenesis. Detection of monovinyl protochlorophyll(ide) b in plants.

The occurrence of protochlorophyllide b and protochlorophyllide b phytyl ester in green plants is described. The chemical structure of protochlorophyllide b phytyl ester was established by proton nuclear magnetic resonance, fast atom bombardment mass spectroscopic analysis, and chemical derivatization coupled to electronic spectroscopic analysis. The macrocycles of protochlorophyll(ide) b are identical to those of conventional protochlorophyll(ide) except for the presence of a formyl group instead of a methyl group at position 3 of the macrocycles. They differ from chlorophyll(ide) b by the presence of an oxidized double bond at positions 7 and 8 of the macrocycles. The trivial name protochlorophyll(ide) b is proposed to differentiate these two tetrapyrroles from conventional protochlorophyll(ide), which in turn will be referred to as protochlorophyll(ide) a. Protochlorophyll(ide) b appears to be widely distributed in green plants. Its molar extinction coefficients in 80% acetone and diethyl ether are reported. The impact of this discovery on the heterogeneity of the chlorophyll a and b biosynthetic pathways is discussed.

Intraplastidic Localization of the Enzymes That Convert delta-Aminolevulinic Acid to Protoporphyrin IX in Etiolated Cucumber Cotyledons.

The intraplastidic localization of the enzymes that catalyze the conversion of delta-aminolevulinic acid (ALA) to protoporphyrin IX (Proto) is a controversial issue. While some researchers assign a stromal location for these enzymes, others favor a membranebound one. Etiochloroplasts were isolated from etiolated cucumber cotyledons (Cucumis sativus, L.) by differential centrifugation and were purified further by Percoll density gradient centrifugation. Purified plastids were highly intact, and contamination by other subcellular organelles was reduced five- to ninefold in comparison to crude plastid preparations. Most of the ALA to Proto conversion activity was found in the plastids. On a unit protein basis, the ALA to Proto conversion activity of isolated mitochondria was about 2% that of the purified plastids, and could be accounted for by contamination of the mitochondrial preparation by plastids. Lysis of the purified plastids by osmotic shock followed by high speed centrifugation, yielded two subplastidic fractions: a soluble clear stromal fraction and a pelleted yellowish one. The stromal fraction contained about 11% of the plastidic ALA to Proto conversion activity while the membrane fraction contained the remaining 89%. The stromal ALA to Proto conversion activity was in the range of stroma contamination by subplastidic membrane material. Complete solubilization of the ALA to Proto activity was achieved by high speed shearing and cavitation, in the absence of detergents. Solubilization of the ALA to Proto conversion activity was accompanied by release of about 30% of the membrane-bound protochlorophyllide. It is proposed that the enzymes that convert ALA to Proto are loosely associated with the plastid membranes and may be solubilized without the use of detergents. It is not clear at this stage whether the enzymes are associated with the outer or inner plastid membranes and whether they form a multienzyme complex or not.

Chloroplast biogenesis: quantitative determination of monovinyl and divinyl chlorophyll(ide) a and b by spectrofluorometry.

Simultaneous equations for the determination of monovinyl (MV) and divinyl (DV) Chl a and b by spectrofluorometry in unsegregated mixtures of these tetrapyrroles were derived. The same equations can also be used for the quantitative determination of MV and DV chlorophyllide (Chlide) a and b in unpurified mixtures, after extraction of the Chls in hexane. The equations used differences in the Soret excitation maxima of these tetrapyrroles in ether at 77 degrees K, in order to correct the Soret excitation overlap between MV and DV Chl(ide) a and between MV and DV Chl(ide) b.

Chloroplast Biogenesis 60 : Conversion of Divinyl Protochlorophyllide to Monovinyl Protochlorophyllide in Green(ing) Barley, a Dark Monovinyl/Light Divinyl Plant Species.

In higher plants, most of the chlorophyll a is formed via the divinyl and monovinyl chlorophyll monocarboxylic biosynthetic routes. These two routes are strongly interconnected prior to protochlorophyllide formation in barley (Hordeum vulgare L. cv Morex), a dark monovinyl-light divinyl plant species, but not in cucumber (Cucumis sativus L. cv Beit Alpha MR), a dark divinyl-light divinyl plant species (BC Tripathy, CA Rebeiz, 1986 J Biol Chem 261: 13556-13564). It is shown that in dark monovinyl-light divinyl plant species such as barley, the divinyl and monovinyl monocarboxylic routes become interconnected at the level of protochlorophyllide during transition from the divinyl to the monovinyl protochlorophyllide biosynthetic mode. In cucumber, a dark divinyl-light divinyl plant species, in which the monovinyl monocarboxylic biosynthetic route becomes preponderant only after an abnormally long sojourn in darkness, the conversion of divinyl to monovinyl protochlorophyllide does not take place on the barley time-scale of incubation.

Chloroplast biogenesis. Demonstration of the monovinyl and divinyl monocarboxylic routes of chlorophyll biosynthesis in higher plants.

It is shown that barley (Hordeum vulgare), a dark monovinyl/light divinyl plant species, and cucumber (Cucumis sativus L.) a dark divinyl/light divinyl plant species synthesize monovinyl and divinyl protochlorophyllide in darkness from monovinyl and divinyl protoporphyrin IX via two distinct monovinyl and divinyl monocarboxylic chlorophyll biosynthetic routes. Evidence for the operation of monovinyl monocarboxylic biosynthetic routes consisted (a) in demonstrating the conversion of delta-aminolevulinic acid to monovinyl protoporphyrin and to monovinyl Mg-protoporphyrins, and (b) in demonstrating the conversion of these tetrapyrroles to monovinyl protochlorophyllide by both isolated barley and cucumber etiochloroplasts. Likewise, evidence for the operation of divinyl monocarboxylic chlorophyll biosynthetic routes consisted (a) in demonstrating the biosynthesis of divinyl protoporphyrin and divinyl Mg-protoporphyrins from delta-aminolevulinic acid, and (b) in demonstrating the conversion of the latter tetrapyrroles to divinyl protochlorophyllide. Finally, it was shown that the divinyl tetrapyrrole substrates were metabolized differently by barley and cucumber. For example, divinyl protoporphyrin, divinyl Mg-protoporphyrin, and divinyl Mg-protoporphyrin monoester were converted predominantly to monovinyl protochlorophyllide and to smaller amounts of divinyl protochlorophyllide by barley etiochloroplasts. In contrast, cucumber etiochloroplasts converted the above substrates predominantly to divinyl protochlorophyllide, although smaller amounts of monovinyl protochlorophyllide were also formed. Furthermore, it was shown that monovinyl protochlorophyllide was not formed from divinyl protochlorophyllide either in barley or in cucumber etiochloroplasts. These metabolic differences are explained by the presence of strong biosynthetic interconnections between the divinyl and monovinyl monocarboxylic routes, prior to divinyl protochlorophyllide formation, in barley but not in cucumber.

Chloroplast biogenesis 51 : modulation of monovinyl and divinyl protochlorophyllide biosynthesis by light and darkness in vitro.

It is shown that the monovinyl and divinyl protochlorophyllide biosynthetic patterns of etiolated maize (Zea mays L.), and cucumber (Cucumis sativus L.) seedlings and of their isolated etiochloroplasts can be modulated by light and darkness as was shown for green photoperiodically grown plants (E. E. Carey, C. A. Rebeiz 1985 Plant Physiol. 79: 1-6). In etiolated corn and cucumber seedlings and isolated etiochloroplasts poised in the divinyl protochlorophyllide biosynthetic mode by a 2 hour light pretreatment, darkness induced predominantly the biosynthesis of monovinyl protochlorophyllide in maize and of divinyl protochlorophyllide in cucumber. When etiolated seedlings and their isolated etiochloroplasts were poised in the monovinyl protochlorophyllide biosynthetic mode by a prolonged dark-pretreatment, light induced mainly the biosynthesis of divinyl protochlorophyllide in both maize and cucumber.

Chloroplast Biogenesis 49 : Differences among Angiosperms in the Biosynthesis and Accumulation of Monovinyl and Divinyl Protochlorophyllide during Photoperiodic Greening.

Various angiosperms differed in their monovinyl and divinyl protochlorophyllide biosynthetic capabilities during the dark and light phases of photoperiodic growth. Some plant species such as Cucumis sativus L., Brassica juncea (L.) Coss., Brassica kaber (DC.) Wheeler, and Portulaca oleracea L. accumulated mainly divinyl protochlorophyllide at night. Monocotyledonous species such as Avena sativa L., Hordeum vulgare L., Triticum secale L., Zea mays L., and some dicotyledonous species such as Phaseolus vulgaris L., Glycine max (L.) Merr., Chenopodium album L., and Lycopersicon esculentum L. accumulated mainly monovinyl protochlorophyllide at night.Under low light intensities meant to simulate the first 60 to 80 minutes following daybreak divinyl protochlorophyllide appeared to contribute much more to chlorophyll formation than monovinyl protochlorophyllide in species such as Cucumis sativus L. Under the same light conditions, species which accumulated mainly monovinyl protochlorophyllide at night appeared to form chlorophyll preferably via monovinyl protochlorophyllide.THESE RESULTS WERE INTERPRETED IN TERMS OF: (a) a differential contribution of monovinyl and divinyl protochlorophyllide to chlorophyll formation at daybreak in various plant species; and (b) a differential regulation of the monovinyl and divinyl protochlorophyllide biosynthetic routes by light and darkness.

Chloroplast biogenesis: quantitative determination of monovinyl and divinyl Mg-protoporphyrins and protochlorophyll(ides) by spectrofluorometry.

General equations which permit the determination of the amounts of any two closely related fluorescent compounds which can be distinguished by 77 degrees K but not by 293 degrees K spectrofluorometry have been described. This was achieved in the presence or absence of a third interfering compound, without prior separation of the fluorescent species. The adaptation of the generalized equations to the determination of the amounts of monovinyl (MV) and divinyl (DV) Mg-protoporphyrins or of MV and DV protochlorophyll(ides) in the presence or absence of Mg-Protos [Mg-protoporphyrin IX (Mg-Proto), Mg-Proto monoester, Mg-Proto diester or a mixture of those three tetrapyrroles] interference, was then demonstrated over a wide range of MV/DV tetrapyrrole proportions. These equations are likely to be very useful for the study of the intermediary metabolism of the monovinyl and divinyl chlorophyll biosynthetic routes in plants.

Chloroplast biogenesis. Molecular structure of chlorophyll b (E489 F666).

Nuclear magnetic resonance analysis established the presence of two vinyl groups/macrocycle of chlorophyll b (E489 F666). The latter is the only chlorophyll b that accumulates in a corn mutant (ON 8147). On the other hand the presence of only one vinyl group/macrocycle of authentic monovinyl chlorophyll b (E475 F660) was confirmed.