Phytol synthesis from geranylgeraniol in spinach chloroplasts

The reduction of /2-¹⁴C/-geranylgeranylpyrophosphate to phytylpyrophosphosphate is shown for the first time in chloroplasts. The esterification of exogenous /2-¹⁴C/-geranylgeranylpyrophosphate with endogenous chlorophyllide and the stepwise reduction of the pigment bound geranylgeraniol to phytol was also proved for spinach chloroplasts for the first time.     

Site of synthesis of geranylgeraniol derivatives in intact spinach chloroplasts

Chloroplasts isolated from fully developed spinach leaves and incubated in the presence of isopentenyl pyrophosphate were able to synthesize rapidly geranylgeranyl chlorophyll a and geranylgeraniol.The biosynthesis of the geranylgeraniol derivatives from isopentenyl pyrophosphate is a compartimentalized process. The membrane fractions (thylakoid and envelope membranes) were essentially unable to synthesize geranylgeraniol, geranylgeranyl pyrophosphate and geranylgeranyl chlorophyll a. When stromal and thylakoid fractions were combined the capacity to synthesize geranylgeranyl chlorophyll a and geranylgeraniol was restored. When stromal and envelope membrane fractions were combined the capacity to synthesize geranylgeranyl pyrophosphate and geranylgeraniol was restored. The products of the reaction were discharged inside the lipid phase of the membranes.     

Two pathways of electron transfer in quinol-mediated cyclic phosphorylation in spinach chloroplasts

Low potential quinones are mediators of cyclic phosphorylation in washed spinach thylakoid membranes if they are prereduced to provide the proper redox poise. Cyclic phosphorylation catalyzed by different quinols varies in its sensitivity to the electron transfer inhibitor 2-iodo-6-isopropyl-3-methyl-2′,4,4′-trinitrodiphenyl ether (DNPINT), which is thought to inhibit electron flux from the bound plastoquinone (B) to the plastoquinone pool (Trebst, A., Wietoska, H., Draber, W. and Knops, H.J. (1978) Z. Naturforsch. 33c, 919–927). Cyclic phosphorylation catalyzed by uncharged quinols is extremely sensitive to DNPINT, whereas cyclic phosphorylation catalyzed by negatively charged quinols is approximately two orders of magnitude less sensitive. Many quinols have pK₁ values in the physiological range (pH 7–9). Increasing the concentration of the deprotonated quinol either by raising the assay pH, increasing the mediator concentration, or increasing the fractional reduction of the quinone results in a decrease in the sensitivity of cyclic phosphorylation to DNPINT. At very high DNPINT concentrations, cyclic phosphorylation catalyzed by all quinols (and ferredoxin) is inhibited, but not phenazine methosulfate catalyzed cyclic phosphorylation.These data suggest that the deprotonated form of the quinol can donate electrons directly to the plastoquinone pool, whereas the uncharged quinol most obligately transfer electrons through the bound plastoquinone ‘B’. A second site of DNPINT action after the plastoquinone pool is also observed, which requires much higher DNPINT concentrations for inhibition of phosphorylation.     

Crystal structures of two functionally different thioredoxins in spinach chloroplasts

Thioredoxins are small ubiquitous proteins which act as general protein disulfide reductases in living cells. Chloroplasts contain two distinct thioredoxins ( f and m) with different phylogenetic origin. Both act as enzyme regulatory proteins but have different specificities towards target enzymes. Thioredoxin f (Trx f), which shares only low sequence identity with thioredoxin m (Trx m) and with all other known thioredoxins, activates enzymes of the Calvin cycle and other photosynthetic processes. Trx m shows high sequence similarity with bacterial thioredoxins and activates other chloroplast enzymes. The here described structural studies of the two chloroplast thioredoxins were carried out in order to gain insight into the structure/function relationships of these proteins. Crystal structures were determined for oxidized, recombinant thioredoxin f (Trx f-L) and at the N terminus truncated form of it (Trx f-S), as well as for oxidized and reduced thioredoxin m (at 2.1 and 2.3 A resolution, respectively). Whereas thioredoxin f crystallized as a monomer, both truncated thioredoxin f and thioredoxin m crystallized as non-covalent dimers. The structures of thioredoxins f and m exhibit the typical thioredoxin fold consisting of a central twisted five-stranded beta-sheet surrounded by four alpha-helices. Thioredoxin f contains an additional alpha-helix at the N terminus and an exposed third cysteine close to the active site. The overall three-dimensional structures of the two chloroplast thioredoxins are quite similar. However, the two proteins have a significantly different surface topology and charge distribution around the active site. An interesting feature which might significantly contribute to the specificity of thioredoxin f is an inherent flexibility of its active site, which has expressed itself crystallographically in two different crystal forms.     

Ferrochelatase of spinach chloroplasts

Spinach chloroplasts catalyse the incorporation of Fe(2+) into protoporphyrin, mesoporphyrin and deuteroporphyrin to form the corresponding haems. This ferrochelatase activity was detected by pyridine haemochrome formation with acetone-dried powders of chloroplasts, or from the formation of [(59)Fe]haems by intact chloroplasts. Decreasing the mitochondrial contamination of the chloroplasts by density-gradient centrifugation did not cause any loss of activity: spinach ferrochelatase appears to be principally a chloroplast enzyme. The characteristics of the enzyme were examined by using [(59)Fe]haem assay. The activity was pH-dependent: for both mesohaem and protohaem formation there were two pH maxima, a major peak at about pH7.8 and a smaller peak at about pH9.2. Lineweaver-Burk plots showed that the K(m) for Fe(2+) incorporation into protoporphyrin was 8mum and that for Fe(2+) incorporation into mesoporphyrin was 36mum. At non-saturating Fe(2+) concentrations the K(m) for protoporphyrin was 0.2mum and that for mesoporphyrin was 0.4mum. Ferrochelatase was not solubilized by treatment of chloroplasts with ultrasound but was solubilized by stirring in 1% (w/v) Tween 20 at pH10.4. Unlike the rat liver mitochondrial enzyme, chloroplast ferrochelatase was not stimulated by treatment with selected organic solvents. The spinach enzyme was inactive in aerobic conditions and it was shown by using an oxygen electrode that under such conditions the addition of Fe(2+) to buffer solutions caused a rapid uptake of dissolved oxygen, believed to be due to the oxidation of Fe(2+) to Fe(3+); Fe(3+) is not a substrate for ferrochelatase.     

Isomers in thioredoxins of spinach chloroplasts

We have developed a method for the concomitant purification of several components of the ferredoxin/thioredoxin system of spinach chloroplasts. By applying this method to spinach-leaf extract or spinach-chloroplast extract we separated and purified three thioredoxins indigenous to chloroplasts. The three thioredoxins, when reduced, will activate certain chloroplast enzymes such as fructose-1,6-bisphosphatase and NADP-dependent malate dehydrogenase. Fructose-1,6-bisphosphatase is activated by thioredoxin f exclusively. Malate dehydrogenase is activated by thioredoxin mb and thioredoxin mc in a similar way, and it is also activated by thioredoxin f but with different kinetics. All three thioredoxins have very similar relative molecular masses of about 12,000 but distinct isoelectric points of 6.1 (thioredoxin f), 5.2 (thioredoxin mb) and 5.0 (thioredoxin mc). The amino acid composition as well as the C-terminal and N-terminal sequences have been determined for each thioredoxin. Thioredoxin f exhibits clear differences in amino acid composition and terminal sequences when compared with the m-type thioredoxins. Thioredoxin mb and thioredoxin mc, however, are very similar, the only difference being an additional lysine residue at the N-terminus of thioredoxin mb. Amino acid analyses, terminal sequences, immunological tests and the activation properties of the thioredoxins support our conclusion that thioredoxins mb and mc are N-terminal redundant isomers coming from one gene whereas thioredoxin f is a different protein coded by a different gene.     

Fluorescence induction in intact spinach chloroplasts

Under conditions in which the Photosystem II quencher is rapidly reduced upon illumination, either after a preillumination or following treatment with dithionite, the fluorescence-induction curve of intact spinach chloroplasts (class I type) displays a pronounced dip. This dip is probably identical with that observed after prolonged anaerobic incubation of whole algal cells (“I-D dip”). It is inhibited by 3(3,4-dichlorophenyl)-1,1-dimethylurea and occurs in the presence of dithionite, sufficient to reduce the plastoquinone pool. It is influenced by far red light, methylviologen, anaerobiosis and uncouplers in a manner consistent with the interpretation that it represents a photochemical quenching of fluorescence by an electron transport component situated between the Photosystem II quencher and plastoquinone. Glutaraldehyde inhibition may indicate that protein structural changes are involved.     

Glycolate formation in intact spinach chloroplasts

Photosynthetic ¹⁴CO₂ fixation and the accumulation of photosynthetic products and the response of each process to both 3-(3,4-dichlorophenyl)-1, 1-dimethylurea (DCMU) and ascorbate were investigated in the intact spinach chloroplast.     

Starch degradation in isolated spinach chloroplasts

A method for loading isolated intact spinach (Spinacia oleracea L.) chloroplasts with ¹⁴C-starch is described. These intact chloroplasts were incubated aerobically in the dark for 30 minutes. Radioactivity in starch declined and glyceric acid 3-phosphate and maltose were the major radioactive products. It is proposed that starch is degraded within the chloroplast to glyceric acid 3-phosphate and to maltose.     

Radical pair interactions in spinach chloroplasts

Time-resolved EPR studies were done on broken spinach chloroplasts under reducing conditions at low temperature (10 K). A dramatic dependence of signal dynamics and lineshape in the g 2.00 region on the reduction state of Photosystem I is demonstrated. Computer simulations of the spin-polarized lineshapes obtained in this work suggest that the primary electron acceptor in Photosystem I, a species known as A₁, could be a chlorophyll a dimer.     

Quantitation of plastoquinone photoreduction in spinach chloroplasts

The question of plastoquinone (PQ) concentration and its stoichiometry to photosystem I (PSI) and PSII in spinach chloroplasts is addressed here. The results from three different experimental approaches were compared. (a) Quantitation from the light-induced absorbance change at 263 nm (A₂₆₃) yielded the following ratios (mol:mol); Chl:PQ=70:1, PQ:PSI=9:1 and PQ:PSII=7:1. The kinetics of PQ photoreduction were a monophasic but non-exponential function of time. The deviation of the semilogarithmic plots from linearity reflects the cooperativity of several electron transport chains at the PQ pool level. (b) Estimates from the area over the fluorescence induction curve (A_fl) tend to exaggerate the PQ pool size because of electron transfer via PSI to molecular oxygen (Mehler reaction) resulting in the apparent increase of the pool of electron acceptors. The reliability of the A_fl method is increased substantially upon plastocyanin inhibition by KCN. (c) Quantitation of the number of electrons removed from PQH₂ by PSI, either under far-red excitation or after the addition of DCMU to preilluminated chloroplasts, is complicated due to the competitive loss of electrons from PQH₂ to molecular oxygen. The latter is biphasic reaction occurring with half-times of about 2 s (30–40% of PQH₂) and of about 60 s (60–70% of PQH₂).Abbreviations A_fl area over the fluorescence induction curve - Chl chlorophyll - Cyt cytochrome - DCMU 3-(3,4-dichlorophenyl)-1,1-dimethylurea - PQ plastoquinone - PS photosystem - P700 reaction center of PSI - Q primary quinone acceptor of PSII - Tricine N-tris (hydroxymethyl) methyl glycine - Triton X-100 octyl phenoxy polyethoxyethanol