Development of the cation-induced stacking capacity during the biogenesis of higher plant thylakoids

We studied the capacity of the thylakoid membrane to form grana stacks in the presence of cations, monovalent or divalent, added to N-[2-hydroxy-1,1-bis(hydroxymethyl)ethyl]glycine “low-salt” disorganized plastids during their greening. Grana stacking was monitored by the yield of heavy subchloroplast fractions separated by differential centrifugation after digitonin disruption of plastids (J. H. Argyroudi-Akoyunoglou, 1976, Arch. Biochem. Biophys., 176, 267–274). Primary thylakoids of the agranal protochloroplasts formed in periodic light do not show the cation-induced stacking capacity of the mature green chloroplast thylakoids. Similarly, the cation effect saturates at lower cation concentrations in mature chloroplasts than in plastids of the early stages of greening. The capacity for cation-induced stacking and for saturation of the effect at low cation concentrations appears gradually after exposure to continuous light and parallel to the appearance of chlorophyll b and the polypeptides of the 25,000–30,000 molecular weight range of lipid-free thylakoids, probably derived from the chlorophyll b-rich chlorophyll protein Complex II. The thylakoid peripheral stroma proteins ribulosediphosphate carboxylase and the coupling factor protein are not involved in the cation-induced stacking, since their removal (H. Strotmann, H. Hesse, and K. Edelmann, 1973, Biochim. Biophys. Acta, 314, 202–210) does not affect the thylakoid aggregation.     

Proteolytic activity against the light-harvesting complex and the D1/D2 core proteins of Photosystem II in close association to the light-harvesting complex II trimer

Light-harvesting complex II (LHCII) prepared from isolated thylakoids of either broken or intact chloroplasts by three independent methods, exhibits proteolytic activity against LHCII. This activity is readily detectable upon incubation of these preparations at 37 °C (without addition of any chemicals or prior pre-treatment), and can be monitored either by the LHCII immunostain reduction on Western blots or by the Coomassie blue stain reduction in substrate-containing “activity gels”. Upon SDS-sucrose density gradient ultracentrifugation of SDS-solubilized thylakoids, a method which succeeds in the separation of the pigment-protein complexes in their trimeric and monomeric forms, the protease activity copurifies with the LHCII trimer, its monomer exhibiting no activity. This LHCII trimer, apart from being “self-digested”, also degrades the Photosystem II (PSII) core proteins (D1, D2) when added to an isolated PSII core protein preparation containing the D1/D2 heterodimer. Under our experimental conditions, 50% of LHCII or the D1, D2 proteins are degraded by the LHCII-protease complex within 30 min at 37 °C and specific degradation products are observed. The protease is light-inducible during chloroplast biogenesis, stable in low concentrations of SDS, activated by Mg²⁺, and inhibited by Zn²⁺, Cd²⁺, EDTA and p-hydroxy-mercury benzoate (pOHMB), suggesting that it may belong to the cysteine family of proteases. Upon electrophoresis of the LHCII trimer on substrate-containing “activity gels” or normal Laemmli gels, the protease is released from the complex and runs in the upper part of the gel, above the LHCII trimer. A polypeptide of 140 kDa that exhibits proteolytic activity against LHCII, D1 and D2 has been identified as the protease. We believe that this membrane-bound protease is closely associated to the LHCII complex in vivo, as an LHCII-protease complex, its function being the regulation of the PSII unit assembly and/or adaptation.     

Reorganization of the Photosystem II Unit in Developing Thylakoids of Higher Plants after Transfer to Darkness : Changes in Chlorophyll b, Light-Harvesting Chlorophyll Protein Content, and Grana Stacking

A light-dependent reversible grana stacking-unstacking process, paralleled by a reorganization of thylakoid components, has been noticed in greening etiolated bean (Phaseolus vulgaris, var. red kidney) leaves upon transfer to darkness. The reorganization, based on biochemical and biophysical criteria, involves mainly the photosystem II (PSII) unit components: upon transfer to darkness, the light-harvesting chlorophyll protein (LHCP), its 25 kilodalton polypeptide and chlorophyll b are decreased, while the CPa and its 42 kilodalton polypeptide are increased and new PSII units of smaller size are formed. This reorganization of components occurs only in thylakoids still in the process of development and not in those present in steady state conditions.

It is proposed that this process does not reflect the turnover of the LHCP component per se, but a regulatory process operating during development, by which the ratio of light-harvesting to PSII reaction center components, determined by the environmental conditions, controls the photosynthetic rate.

     

Effect of cations on the reconstitution of heavy subchloroplast fractions (grana) in disorganized low-salt agranal chloroplasts

The disorganization of grana in spinach chloroplasts and their reconstitution has been studied by varying their ionic environment. Dissociation in low-salt media and reconstitution by added cations (monovalent or divalent) was correlated with the formation in high yield of light or heavy subchloroplast membrane fractions, respectively, produced after digitonin treatment of chloroplasts. The formation of heavy subchloroplast fractions was dependent on cation concentration and reached a plateau at 0.1 m monovalent cation or 0.002 m divalent cation. The cation reconstituted fractions recovered the composition and activities of the respective fractions obtained from control chloroplasts. Cation addition to light subchloroplast fractions isolated from low-salt agranal chloroplasts after digitonin disruption also produced heavy fractions. Divalent cations were more effective than monovalent. The heavy fractions produced were enriched in Chlorophyll b and photosystem II activity while the light fractions were enriched in Chlorophyll a and photosystem I activity. The mechanism by which cations induce formation of heavy subchloroplast fractions is not osmotic. Upon reconstitution, stacking of thylakoids seems to occur at specific membrane binding sites.     

Photoinduced changes in the chlorophyll a to chlorophyll B ratio in young bean plants

An alternating light-dark system is described under which etiolated bean (Phaseolus vulgaris) leaves form selectively chlorophyll a.     

Effects of Intermittent and Continuous Light on the Chlorophyll Formation in Etiolated Plants at Various Ages

The effect of the tissue age of dark-grown bean plants on the chlorphyll formation under continuous illumination or short impulses of white light has been studied. It was found that the protochlorophyllide present in the tissue is age-dependent and reaches a plateau at about 10 days of age, as judged by the chlorophyll formed in etiolated plants of various ages after 5 min illumination. The amount of chlorophyll a and chlorophyll b formed under short impulses of while light increases up to about 9 days of age and thereafter decreases. However, the decrease in chlorophyll a is sharper than that of chlorophyll b, the amount of which remains almost constant. The ratio of chlorophyll a lo chlorophyll b under the short impulses of white light is higher in the younger plant. Similar results are obtained after transfer of the plants from the flashing light to continuous illumination In the young plant there is no lag phase in the chlorophyll biosynthesis while as the age is increased the lag phase is evident and its duration increases as the plant ages. After protochlorophyllide phototransformation under continuous illumination the lag phase in chlorophyll biosynthesis is also age-dependent. Leaves up to 5 days old show no lag phase in chlorophyll synthesis; after this point, however, the lag phase's duration increases continuously with age.     

Control of Thylakoid Growth in Phaseolus vulgaris

An attempt was made to answer whether the extent of thylakoid growth in Phaseolus vulgaris is controlled by a feedback inhibition mechanism, operating after insertion of all of the necessary components of the mature thylakoid, in the right amounts and ratio, or by parameters independent of the developmental stage of the membrane. This was done by following the growth of thylakoids, as monitored by the rate of chlorophyll accumulation and the rate of thylakoid protein synthesis, in etiolated plants exposed either directly to continuous light (transformation of prolamellar body to mature thylakoid) or first to periodic light and then to continuous light (transformation of prolamellar body to primary thylakoids and then to mature thylakoids). It was found that prolonged etiolation has no effect on the rate of thylakoid synthesis in continuous light. However, prolonged preexposure to periodic light diminishes drastically the rate of new thylakoid synthesis in continuous light. Since the thylakoids formed in the latter case are far from being complete, it seems that thylakoid growth can stop long before all of the necessary components are incorporated. Parameters independent of the developmental stage and composition of the membrane, therefore, seem to control membrane growth.