Chloroplast Biogenesis: XXIV. Intrachloroplastic Localization of the Biosynthesis and Accumulation of Protoporphyrin IX, Magnesium-Protoporphyrin Monoester, and Longer Wavelength Metalloporphyrins during Greening

The intraplastidic localization of the endogenous metabolic pools from protoporphyrin to protochlorophyll was determined in Cucumis sativus. The endogenous protoporphyrin, Mg-protoporphyrin monoester + longer wavelength metalloporphyrins, protochlorophyllide and protochlorophyllide ester were membrane-bound. Protoporphyrin was synthesized in the stroma and subsequently became associated with the membranes. The membrane-associated protoporphyrin was then converted into Mg-protoporphyrin monoester + longer wavelength metalloporphyrins by membrane-bound enzymes. Although lysed plastids were capable of converting exogenous δ-aminolevulinic acid to protochlorophyllide, the net synthesis of protochlorophyllide from exogenous δ-aminolevulinic acid was lost upon segregating the lysed plastids into stromal and membrane fractions and then recombining the stromal and membrane fraction prior to incubation. The segregated membrane fraction was still capable of converting protoporphyrin into Mg-protoporphyrin monoester + longer wavelength metalloporphyrins in the presence or absence of the stromal fraction. These results indicated that although the reactions from protoporphyrin to Mg-protoporphyrin monoester and longer wavelength metalloporphyrins could survive a considerable degree of plastid disruption, the reactions from Mg-protoporphyrin monoester and longer wavelength metalloporphyrins to protochlorophyllide were more sensitive to structural disorganization.     

Chloroplast biogenesis: Biosynthesis and accumulation of Mg-protoporphyrin IX monoester and other metalloporphyrins by isolated etioplasts and developing chloroplasts

Developing chloroplasts isolated from greening cotyledons and isolated etioplasts were capable of synthesizing and accumulating Mg-protoporphyrin IX monoester as well as longer wavelength metalloporphyrins when incubated in the dark, in the presence of air, δ-aminolevulinic acid, and cofactors (coenzyme A, glutathione, adenosine triphosphate, nicotinamide adenine dinucleotide, methyl alcohol, magnesium, potassium, and phosphate). The putative metalloporphyrins exhibited distinct fluorescence emission and excitation properties and were detected by spectrofluorometry in situ and after extraction in organic solvents. The cofactors were previously shown to be required for protochlorophyll, and chlorophyll biosynthesis and grana assembly in vitro. The putative long wavelength metalloporphyrins were suggested earlier to represent intermediates between Mg-protoporphyrin IX monomethyl ester and protochlorophyllide. The isolated plastids were similar in this aspect of their biosynthetic activity to etiolated cotyledons greening in distilled H₂O. In contrast to greening cotyledons, however, the biosynthetic activity of the isolated plastids depended on the addition of exogenous cofactors and δ-aminolevulinic acid. This was interpreted as an indication that the isolated plastids were not capable of generating their own δ-aminolevulinic acid and cofactors under the present incubation conditions. Light was not required for the conversion of added ALA to metalloporphyrins in vitro. The metalloporphyrins synthesized in vitro were more highly fluorescent in situ than those of greening cotyledons. In addition to Mg-protoporphyrin IX monoester and longer wavelength metalloporphyrins, isolated etioplasts synthesized and accumulated Zn-protoporphyrin and Zn-protoporphyrin IX monoesterlike compounds.     

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.     

Steady state kinetic mechanism of the Escherichia coli coenzyme A transferase.

Developing chloroplasts isolated from greening cotyledons and isolated etioplasts were capable of synthesizing and accumulating Mg-protoporphyrin IX monoester and longer wavelength metalloporphyrins when incubated in the dark in the presence of protoporphyrin and cofactors. These results constituted the first unambiguous demonstration of the insertion of magnesium into exogenous protoporphyrin in a cell-free system from higher plants. The metalloporphyrin synthetic activity did not occur in the absence of the plastids or when the plastids were heated in a 100 °C water bath for 2 min. It is thus suggested that, in higher plants, the in vitro insertion of magnesium into protoporphyrin is an enzymatic reaction.     

Detection of protoporphyrin IX in envelope membranes of pea chloroplasts

Envelope membranes were prepared from mature pea chloroplasts. The tetrapyrrole contents of envelope membranes were analysed. The envelope membranes of pea chloroplasts contained substantial amounts of protoporphyrin IX and trace amounts of Mg-protoporphyrin IX and its monoester in addition to protochlorophyllide. The protoporphyrin IX content of envelope membranes was 89.25 pmol (mg protein)(-1). Its content in pea envelope membrane was higher than that of protochlorophyllide. The proportion of monovinyl and divinyl forms of protochlorophyllide present in pea chloroplast envelope membrane was 3:7. The significance of the presence of protoporphyrin IX in the envelope membrane is discussed in relation to plastidic Chl biosynthesis.     

Formation of Mg-Containing Chlorophyll Precursors from Protoporphyrin IX, delta-Aminolevulinic Acid, and Glutamate in Isolated, Photosynthetically Competent, Developing Chloroplasts

Intact developing chloroplasts isolated from greening cucumber (Cucumis sativus L. var Beit Alpha) cotyledons were found to contain all the enzymes necessary for the synthesis of chlorophyllide. Glutamate was converted to Mg-protoporphyrin IX (monomethyl ester) and protoclorophyllide. δ-Aminolevulinic acid and protoporphyrin IX were converted to Mg-protoporphyrin IX, Mg-protoporphyrin IX monomethyl ester, protochlorophyllide and chlorophyllide a. The conversion of δ-aminolevulinic acid or protoporphyrin IX to Mg-protoporphyrin IX (monomethyl ester) was inhibited by AMP and p-chloromercuribenzene sulfonate. Light stimulated the formation of Mg-protoporphyrin IX from all three substrates. In the case of δ-aminolevulinic acid and protoporphyrin IX, light could be replaced by exogenous ATP. In the case of glutamate, both ATP and reducing power were necessary to replace light. With all three substrates, glutamate, δ-aminolevulinic acid, and protoporphyrin IX, the stimulation of Mg-protoporphyrin IX accumulation in the light was abolished by DCMU, and this DCMU block was overcome by added ATP and reducing power.     

Porphyrin Biosynthesis in Cell-free Homogenates from Higher Plants

The porphyrin and phorbin biosynthetic activity of etiolated cucumber (Cucumis sativus, L.) cotyledons was compared to that of cotyledonary homogenates. Etiolated cotyledons incubated with δ-aminolevulinic acid accumulate protoporphyrin, coproporphyrin, small amounts of Mg protoporphyrin monoester, and trace amounts of uroporphyrin. They also incorporate 4-¹⁴C-δ-aminolevulinic acid into free porphyrins, protochlorophyllide, protochlorophyllide phytyl ester, and Mg protoporphyrin monoester. Homogenates incubated with δ-aminolevulinic acid likewise accumulate coproporphyrin, uroporphyrin, Mg coproporphyrin, and trace amounts of protoporphyrin. They also incorporate 4-¹⁴C-δ-aminolevulinic acid into Mg protoporphyrin monoester, Mg coproporphyrin, and free porphyrins. However, the capacity to synthesize protochlorophyllide and protochlorophyllide phytyl ester is lost and the endogenous protochlorophylls gradually disappear. Mg protoporphyrin monoester represents the terminal biosynthetic step in this cell-free system.     

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.     

Protochlorophyll Biosynthesis in a Cell-free System from Higher Plants

A cell free system prepared from etiolated cucumber (Cucumis sativus, L) in tris-sucrose buffer is able to incorporate delta-aminolevulinic acid-4- (14)C into the two components of protochlorophyll: protochlorophyllide and protochlorophyllide ester. The activity is associated with the etioplasts. Optimal incorporation is obtained at pH 7.7. For the formation of protochlorphyllide ester, oxygen, reduced glutathione, methyl alcohol, magnesium, inorganic phosphate, and nicotinamide adenine dinucleotide are required. For the formation of (14)C-protochlorophyllide, adenosine triphosphate, and coenzyme A are required in addition to the above. The requirement for methyl alcohol is highly specific, and the methyl group appears to be incorporated into the protochlorophyll molecules. A biosynthetic scheme resulting in the parallel production of (14)C-protochlorophyllide and (14)C-protochlorophyllide ester from (14)C-Mg protoporphyrin monoester is presented.     

Chloroplast biogenesis: Biosynthesis and accumulation of Mg-protoporphyrin IX monoester and longer wavelength metalloporphyrins by greening cotyledons

Etiolated excised cucumber cotyledons (Cucumis sativus L. cv. Alpha Green), while greening in distilled water, synthesized and accumulated several metalloporphyrins in the absence of added substrates or inhibitors. The metalloporphyrins, undetectable by conventional spectrophotometry, exhibited distinct fluorescence emission and excitation properties in situ and in organic solvents. The metalloporphyrins were partially segregated on thin layers of silica gel H into three Chromatographic bands and the bands were eluted in methyl alcohol:acetone (4:1 $\text{v}\text{v}$). The metalloporphyrins in the eluted bands were characterized by their soret excitation and short-wavelength emission maxima. One of the metalloporphyrins of band 3 (R_f, 0.4?0.56) was identified as Mg-protoporphyrin monoester. It was accompanied by traces of two other metalloporphyrins. Band 2 (R_f, 0.32?0.48) was made up of three metalloporphyrins and had the Chromatographic mobility of endogenous protochlorophyllide. Band 1 (R_f, 0.22?0.43) was made up of two metalloporphyrins; it moved with endogenous chlorophyllide. The metalloporphyrins of band 2 and 1 exhibited fluorescence emission and excitation maxima similar to Mg-protoporphyrin monoester but slightly shifted to longer wavelengths. The Chromatographic and spectral properties of these compounds suggested that they represent intermediates between Mg-protoporphyrin IX monomethyl ester and protochlorophyllide. The analytical techniques described in this work may prove useful in the elucidation of the enzymology between protoporphyrin IX and protochlorophyllide.     

Acclimation of chlorophyll biosynthetic reactions to temperature stress in cucumber (Cucumis sativus L.)

The adaptive responses of the greening process of plants to temperature stress were studied in cucumber (Cucumis sativus L. cv. Poinsette) seedlings grown at ambient (25 °C), low (7 °C) and high (42 °C) temperatures. Plastids isolated from these seedlings were incubated at different temperatures and the net syntheses of various tetrapyrroles were monitored. In plastids isolated from control seedlings grown at 25 °C, the optimum temperature for synthesis of Mg-protoporphyrin IX monoester or protochlorophyllide was 35 °C. Temperature maxima for Mg-protoporphyrin IX monoester and protochlorophyllide syntheses were shifted to 30 °C in chill-stressed seedlings. The net synthesis of total tetrapyrroles was severely reduced in heat-stressed seedlings and the optimum temperature for Mg-protoporphyrin IX monoester or protochlorophyllide synthesis shifted slightly towards higher temperatures, i.e. a broader peak was observed. To further study the temperature acclimation of seedlings with respect to the greening process, tetrapyrrole biosynthesis was monitored at 25 °C after pre-heating the plastids (28–70 °C) isolated from control, chill- and heat-stressed seedlings. In comparison to 28 °C-pre-heated plastids the percent inhibition of protochlorophyllide synthesis in 40 °C-pre-heated plastids was higher than for the control (25 °C-grown) in chill-stressed seedlings and lower than for the control in heat-stressed seedlings. Maximum synthesis of total tetrapyrroles and protoporphyrin IX was observed when chloroplasts were heated at 50 °C, which was probably due to heat-induced activation of the enzymes involved in protoporphyrin IX synthesis. Prominent shoulders towards lower or higher temperatures were seen in chill-stressed or heat-stressed seedlings, respectively. The shift in optimum temperature for tetrapyrrole biosynthesis in chill- and heat-stressed seedlings was probably due to acclimation of membranes possibly undergoing desaturation or saturation of membrane lipids. Proteins synthesized in response to temperature-stress may also play an important role in conferring stress-tolerance in plants. Received: 8 October 1998 / Accepted: 19 November 1998     

The use of continuous assays to characterize the oxidative cyclase that synthesizes the chlorophyll isocyclic ring.

A continuous spectroscopic assay has been developed for magnesium protoporphyrin monomethyl ester oxidative cyclase, which records either the dark formation of both free and protein-bound magnesium phaeoporphyrin or, following flash illumination, its corresponding chlorin. The properties of the enzyme were studied in wheat etioplasts. When plastids were pre-illuminated in the presence of NADPH all endogenous protochlorophyllide was converted into chlorophyllide and the product of dark incubation with magnesium protoporphyrin monomethyl ester was protein-bound magnesium 2-vinyl phaeoporphyrin a5 monomethyl ester with either a vinyl or an ethyl group at position 4 of the macrocycle alone. Rates of chlorin production from magnesium protoporphyrin monomethyl ester (up to 1240 pmol/h per mg of protein) were adequate to support known rates of plant chlorophyll synthesis. The enzyme required NADPH and O2 and had an approximate Km of 0.5 microM for magnesium protoporphyrin IX monomethyl ester. Lipid-soluble metal-complexing agents inhibited enzyme activity: hydrophilic agents were ineffective. The strong inhibition of mycobactin suggested the involvement of iron ions. Zinc protoporphyrin monomethyl ester, but not copper or nickel or metal-free protoporphyrin monomethyl esters, was a substrate; magnesium protoporphyrin dimethyl ester was inhibitory. The activity of the enzyme was unchanged by prior greening of the plants. The activity in isolated etioplasts was very dependent upon intactness of the plastid structure.     

An efficient and prolonged in vitro translational system from isolated cucumber etioplasts

Etioplasts were isolated from dark grown cucumber cotyledons pretreated with kinetin and gibberellic acid. When incubated in a cofactor enriched medium these etioplasts incorporated [35S] methionine into a hot trichloroacetic acid-insoluble fraction; this incorporation was linear for 8 h of incubation and was inhibited by chloramphenicol but not by cycloheximide. Over the same time period, the etioplasts showed continued linear synthesis of the chlorophyll precursors protochlorophyllide, Mg-protoporphyrin and protoporphyrin IX. Analysis of products of in vitro protein synthesis by etioplasts and cotyledons showed the thylakoid membrane polypeptide profiles to be identical. Continued incorporation of [35S] methionine into the large subunit of ribulose bisphosphate carboxylase/oxygenase (RuBisCO) for 8 h has been confirmed further by immunoprecipitation with anti-spinach RuBisCO. This competent in vitro translation system should be useful for future studies of chloroplast protein synthesis and gene expression.     

Differential distribution of chlorophyll biosynthetic intermediates in stroma, envelope and thylakoid membranes in Beta vulgaris

Stroma, envelope and thylakoid membranes were prepared from chloroplasts isolated from leaves of Beta vulgaris. Out of total plastidic protochlorophyllide, envelope membranes contained 1.5%, thylakoids had the maximum 98.48% and stroma had a trace fraction of 0.02%. Distribution of the Mg-protoporphyrin IX and its monoester was 89.0% in thylakoids, 10.0% in stroma and 1.0% in envelope. A substantial fraction (33.77%) of plastidic protoporphyrin IX was partitioned into stroma. Envelope contained 0.66% and thylakoids had 65.57% of the total plastidic protoporphyrin IX pool. The proportion of monovinyl and divinyl forms of protochlorophyllide was almost similar in intact plastid, thylakoids, and outer and inner envelope membranes suggesting a tight regulation of vinyl reductase enzyme. The significance of differential distribution of chlorophyll biosynthetic intermediates among thylakoids, envelope and stroma is discussed. This work was supported by a grant from the Council of Scientific and Industrial Research (38/1079/03/EMRII) to BCT.     

Plastid differentiation and chlorophyll biosynthesis in different leaf layers of white cabbage (Brassica oleracea cv. capitata)

The contents of protochlorophyllide, protochlorophyll and chlorophyll together with the native arrangements of the pigments and the plastid ultrastructure were studied in different leaf layers of white cabbage (Brassica oleracea cv. capitata) using absorption, 77 K fluorescence spectroscopy and transmission electron microscopy. The developmental stage of the leaves was determined using the differentiation of the stoma complexes as seen by scanning electron microscopy and light microscopy. The pigment content showed a gradual decrease from the outer leaf layer towards the central leaves. The innermost leaves were in a primordial stage in many aspects; they were large but had typical proplastids with few simple inner membranes, and contained protochlorophyllide and its esters in a 2 : 1 ratio and no chlorophyll. Short‐wavelength, not flash‐photoactive protochlorophyllide and/or protochlorophyll forms emitting at 629 and 636 nm were dominant in the innermost leaves. These leaves also had small amounts of the 644 and 654 nm emitting, flash‐photoactive protochlorophyllide forms. Rarely prolamellar bodies were observed in this layer. The outermost leaves had the usual characteristics of fully developed green leaves. The intermediary layers contained chlorophyll a and chlorophyll b besides the protochlorophyll(ide) pigments and had various intermediary developmental stages. Spectroscopically two types of intermediary leaves could be distinguished: one with only a 680 nm emitting chlorophyll a form and a second with bands at 685, 695 and 730 nm, corresponding to chlorophyll–protein complexes of green leaves. In these leaves, a large variety of chloroplasts were found. The data of this work show that etioplasts, etio‐chloroplasts or chloro‐etioplasts as well as etiolated leaves do exist in the nature and not only under laboratory conditions. The specificity of cabbage leaves compared with those of dark‐grown seedlings is the retained primordial or intermediary developmental stage of leaves in the inner layers for very long (even for a few month) period. This opens new developmental routes leading to formation of specially developed plastids in the various cabbage leaf layers. The study of these plastids provided new information for a better understanding of the plastid differentiation and the greening process .     

Developmental changes in sub-plastidic distribution of chlorophyll biosynthetic intermediates in cucumber (Cucumis sativus L.)

Four-day-old etiolated cucumber seedlings (Cucumis sativus L.) were transferred to cool-white-fluorescent light (15 mumol m-2 s-1) for 1 h and 24 hours and etiochloroplasts and chloroplasts were isolated from developing cotyledons. Plastids were fractionated to stroma, envelope and thylakoid or inner membranes and the pigment contents of all these different fractions were analysed. In intact cucumber chloroplast protochlorophylide was present in significant amounts whereas protoporphyrin IX and Mg-protoporphyrin plus its monoester were present only in very small quantities. Out of the total chloroplastic protochlorophylide pool 1.0% was partitioned to envelope membranes and 99.0% was partitioned to thylakoids. Stroma had only trace amounts of protochlorophylide. In contrast to chloroplasts, etiochloroplasts had, besides protochlorophylide, significant amounts of other chlorophyll biosynthetic intermediates. In etiochloroplasts, protoporphyrin IX primarily partitioned to inner membranes (59.1%) followed by stroma (37.7%) and envelope (3.21%). The content of Mg-protoporphyrin IX plus its monoester in different subplastidic fractions was 74.4% for inner membranes, 22.58% for stroma and 3.02% for envelope. Protochlorophyllide primarily partitioned to inner membranes (95.79%), followed by envelope (4.15%) and, to a negligible extent (0.06%), into stroma. The sub-plastidic distribution of chlorophyll biosynthetic intermediates in etiochloroplasts was, therefore, different than that of chloroplasts. The significance of differential distribution of chlorophyll biosynthetic intermediates among thylakoids, envelope and stroma in developing and mature plastids is discussed in relation to chloroplast biogenesis.     

Chloroplast Biogenesis 31: DETECTION OF AN INHIBITOR OF PROTOCHLOROPHYLL BIOSYNTHESIS IN CUCUMBER COTYLEDONS

An extract from cucumber cotyledons was shown to cause an inhibition of protochlorophyll biosynthesis and accumulation. The extract inhibited the net synthesis of protochlorophyll as well as the incorporation of δ-amino[¹⁴C]levulinic acid into protochlorophyllide and protochlorophyllide ester by excised cotyledons. The inhibition of δ-amino[¹⁴C]levulinic acid incorporation into the two protochlorophyll species was also observed in isolated etiochloroplasts before and after lysis of the plastids. The inhibition did not appear to involve the oxidation of the δ-aminolevulinic substrate or its translocation across the plastid membrane. Kinetic analysis of the rate of protochlorophyllide and protochlorophyllide ester biosynthesis in the presence and absence of the inhibitor suggested that the mode of inhibition of the two protochlorophyll species was different.     

The Mg insertion step in chlorophyll biosynthesis.

A developing chloroplast preparation obtained from greening cucumber cotyledons is able to bring about the synthesis of Mg-protoporphyrin-IX and/or Mg-protoporphyrin-IX monomethyl ester. l-glutamate, δ-aminolevulinic acid, and protoporphyrin-IX can serve as precursors for Mg-protoporphyrin synthesis. However, when δ-aminolevulinic acid or protoporpyrin are used, no Mg-protoporphyrin is formed unless l-glutamate is also added. Mg-Protoporphyrin synthesis with δ-aminolevulinic acid plus l-glutamate, or proto-porphyrin plus l-glutamate, is much more active than with l-glutamate alone. Therefore, it is apparent that l-glutamate plays a role in the Mg chelation step in chloroplasts. α-Keto-glutarate can replace l-glutamate in this role; glutamine cannot. ATP is also required for Mg chelation. The role of l-glutamate in the Mg insertion step is not yet understood, except that l-glutamate itself does not need to be converted to porphyrins in this process, because Mg-protoporphyrin can be synthesized from protoporphyrin and l-glutamate even in the presence of the δ-aminolevulinic acid dehydratase inhibitor, levulinate.     

Formation of the isocyclic ring of chlorophyll by isolated Chlamydomonas reinhardtii chloroplasts

Chlamydomonas reinhardtii chloroplasts catalyzed two sequential steps of Chl biosynthesis, S-adenosyl-l-methionine:Mg-protoporphyrin IX methyltransferase and Mg-protoporphyrin IX monomethyl ester oxidative cyclase. A double mutant strain of C. reinhardtii was constructed which has a cell wall deficiency and is unable to form chlorophyll in the dark. Dark-grown cells were disrupted with a BioNeb nebulizer under conditions which lysed the plasma membrane but not the chloroplast envelope. Chloroplasts were purified by Percoll density gradient centrifugation. The purified chloroplasts were used to define components required for the biosynthesis of Mg-2,4-divinylpheoporphyrin a ₅ (divinyl protochlorophyllide) from Mg-protoporphyrin IX. Product formation requires the addition of Mg-protoporphyrin IX, the substrate for S-adenosyl-l-methionine:Mg-protoporphyrin IX methyltransferase which produces Mg-protoporphyrin IX monomethyl ester. The Mg-protoporphyrin IX monomethyl ester that is generated in situ is the substrate for Mg-protoporphyrin IX monomethyl ester oxidative cyclase. The reaction product was identified as Mg-2,4-divinylpheoporphyrin a ₅ (divinyl protochlorophyllide) by excitation and emission spectrofluorometry and HPLC on ion-paired reverse-phase and polyethylene columns. Mg-2,4-divinylpheoporphyrin a ₅ formation by the coupled enzyme system required O₂ and was stimulated by the addition of NADP⁺, an NADPH regenerating system, and S-adenosyl-l-methionine. Product was formed at a relatively steady rate for at least 60 min.Abbreviations MgDVP Mg-2,4-divinylpheoporphyrin a ₅ (divinyl protochlorophyllide) - SAM S-adenosyl-l-methionine     

Separation of Mg-Protoporphyrin IX and Mg-Protoporphyrin IX Monomethyl Ester Synthesized de novo by Developing Cucumber Etioplasts

High pressure liquid chromatography was used to demonstrate that chelation of Mg²⁺ into protoporphyrin IX precedes methylation in isolated greening etioplasts from cucumber (Cucumis sativus L. var. Beit Alpha) cotyledons. Mg-protoporphyrin IX synthesized in vitro from protoporphyrin IX, Mg²⁺, and ATP or exogenous Mg-protoporphyrin IX could serve as substrates for the methylation step. In either case, S-adenosylmethionine was the methyl donor and could not be replaced by ATP plus methionine.