SummaryThe plastid encoded RNA polymerase subunit genes rpoA, B and C1 of tobacco were disrupted individually by PEG-mediated plastid transformation. The resulting off-white mutant phenotype is identical for inactivation of the different genes. The mutants pass through a normal ontogenetic cycle including¯ower formation and production of fertile seeds. Their plastids reveal a poorly developed internal membrane system consisting of large vesicles and, occasionally,¯attened membranes, reminiscent of stacked thylakoids. The rpo ± material is capable of synthesising pigments and lipids, similar in composition but at lower amounts than the wild-type. Western analysis demonstrates that plastids contain nuclear-coded stroma and thylakoid polypeptides including terminally processed lumenal components of the Sec but not of the DpH thylakoid translocation machineries. Components using the latter route accumulate as intermediates. In striking contrast, polypeptides involved in photosynthesis encoded by plastid genes could not be detected by Western analysis, although transcription of plastid genes, including the rrn operon, by the plastid RNA polymerase of nuclear origin is found as expected. Remarkably, ultrastructural, sedimentation and Northern analyses as well as pulse experiments suggest that rpo ± plastids contain functional ribosomes. The detection of the plastidencoded ribosomal protein Rpl2 is consistent with these results. The ®ndings demonstrate that the consequences of rpo gene disruption, and implicitly the integration of the two plastid polymerase types into the entire cellular context, are considerably more complex than presently assumed.
The enzyme NADPH:protochlorophyllide oxidoreductase (POR) is the key enzyme for light-dependent chlorophyll biosynthesis. It accumulates in dark-grown plants as the ternary enzyme±substrate complex POR-protochlorophyllide a-NADPH. Here, we describe a simple procedure for purification of pigment-free POR from etioplasts of Avena sativa seedlings. The procedure implies differential solubilization with n-octyl-b-dglucoside and one chromatographic step with DEAE-cellulose. We show, using pigment and protein analysis, that etioplasts contain a one-to-one complex of POR and protochlorophyllide a. The preparation of 13 analogues of protochlorophyllide a is described. The analogues differ in the side chains of the macrocycle and in part contain zinc instead of the central magnesium. Six analogues with different side chains at rings A or B are active substrates, seven analogues with different side chains at rings D or E are not accepted as substrates by POR. The kinetics of the light-dependent reaction reveals three groups of substrate analogues with a fast, medium and slow reaction. To evaluate the kinetic data, the molar extinction coefficients in the reaction buffer had to be determined. At concentrations above 2 mole substrate/mole enzyme, inhibition was found for protochlorophyllide a and for the analogues.
Chlorophyll synthetase catalyzes the last step of chlorophyll biosynthesis, namely prenylation (esterification) of chlorophyllide with phytyl diphosphate or geranylgeranyl diphosphate. During investigation of various chlorophyllide derivatives as potential substrates we observed lower esterification with increasing percentages of chlorophyllide a' in epimeric mixtures of chlorophyllides a and a: To avoid epimerization during esterification, we studied the reaction in detail with model compounds [zinc-1 32(R)-methoxy-pheophorbide a and zinc-1 3'(S)-rnethoxy-pheophorbide a, zinc-1 32(R)-methoxy-pyropheophorbide a and zinc-chlorin e,-l3', 1 5'-dimethylester]. We conclude that compounds which have the 13'-carbomethoxy group at the same side of the macrocycle as the propionic side chain of ring D are neither substrates nor competitive inhibitors. Only compounds having the 132-carbomethoxy group at the opposite site are substrates for the enzyme. Naturally occuring chlorophyll a ' must be formed by epimerization after esterification.Chlorophyll a' [a-'prime', 13Z(S)-chlorophyll a ] has been known since 1942 (Strain and Manning, 1942) as a byproduct of isolation of chlorophyll a [13'(R)-chlorophyll a]. Due to the easy epimerization of chlorophyll at C-13' (Hynninen, 1991) it is generally believed that it is formed from chlorophyll a during the extraction procedure. However, increasing evidence has accumulated during the last decade that chlorophyll a' is a natural constituent of higher plants and cyanobacteria (Watanabe et al., 1985 a,b;Kobayashi et al., 1988). Investigations on pigment composition of Chlamydomonas reinhardtii (Maroc and Tremolieres, 1990) and of P700-enriched chloroplasts of higher plants (Maeda et al., 1992) revealed that two chlorophyll a' molecules are situated in the core of photosystem I. Furthermore, the presence of two bacteriochlorophyll g 'molecules in the reaction center of heliobacteria was also described (Kobayashi et al., 1990(Kobayashi et al., , 1991. The question now arises, at which stage of the biosynthetic pathway of the chlorophylls is the prime pigment synthesized, especially whether it is formed before or after esterification of chlorophyllide a.Chlorophyll synthetase catalyzes prenylation of chlorophyllides with geranylgeranyl diphosphate (GerGerP,) or phytyl diphosphate (PhyP,), the last step of chlorophyll biosynthesis (Rudiger et al., 1980). This step is essential for translation and accumulation of chlorophyll a apoproteins (Eichacker et al., 1990(Eichacker et al., , 1992 and probably for stable assembly also for other components of the thylakoid membrane (Paulsen et al., 1990; Rudiger 1992 Rudiger , 1993. Chlorophyll synthetase catalyzes prenylation not only of chlorophyllide a, but also of chlorophyllide b and some modified derivatives (Benz and Rudiger, 1981 and Rudiger, 1992;Vezitskii and Sherbakov, 1987). During our studies on the substrate specificity of chlorophyll synthetase, we observed fractions of chlorophyllide a with a greatly reduced ability for esterificat...
The reduction of chlorophyllide b and its analogue zinc pheophorbide b in etioplasts of barley (Hordeum vulgare L.) was investigated in detail. In intact etioplasts, the reduction proceeds to chlorophyllide a and zinc pheophorbide a or, if incubated together with phytyldiphosphate, to chlorophyll a and zinc pheophytin a, respectively. In lysed etioplasts supplied with NADPH, the reduction stops at the intermediate step of 7 1 -OHchlorophyll(ide) and Zn-7 1 -OH-pheophorbide or Zn-7 1 -OH-pheophytin. However, the final reduction is achieved when reduced ferredoxin is added to the lysed etioplasts, suggesting that ferredoxin is the natural cofactor for reduction of chlorophyll b to chlorophyll a. The reduction to chlorophyll a requires ATP in intact etioplasts but not in lysed etioplasts when reduced ferredoxin is supplied. The role of ATP and the significance of two cofactors for the two steps of reduction are discussed.
During senescence of flowering plants, only breakdown products derived from chlorophyll a were detected although b disappears, too (Matile et al., 1996, Plant Physiol 112: 1403-1409). We investigated the possibility of chlorophyll b reduction during dark-induced senescence of barley (Hordeum vulgare L.) leaves. Plastids isolated from senescing leaves were lysed and incubated with NADPH. We found 7(1)-hydroxy-chlorophyll a, 7(1)-hydroxy-chlorophyllide a, and, after incubation with Zn-pheophorbide b, also Zn-7(1)-hydroxy-pheophorbide a, indicating activity of chlorophyll(ide) b reductase. The highest activity was found at day 2 of senescence when chlorophyll breakdown reached its highest rate. Chlorophyllase reached its highest activity under the same conditions only at days 4-6 of senescence. Based on the chlorophyll b reductase activity of plastids at day 2.5 of senescence (=100%), the bulk of activity (83%) was found in the thylakoids and only traces (5%) in the envelope fraction. Chlorophyll b reduction is considered to be an early and obligatory step of chlorophyll b breakdown.
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