The NADPH-dependent electron flow in chloroplasts of the higher plants

The NADPH-dependent reduction of some photosynthetic electron carriers in the dark, and the reduction of NADP+ associated with the glycolytic sequence and the oxidative pentose phosphate pathway in chloroplasts are reviewed. The postulated pathways of electron transports sensitive and insensitive to antimycin A are also evaluated. It is proposed that the electron flow, predominantly through cytochrome bf complex, may be also involved in the pathway of NADPH-dependent and antimycin A-insensitive back electron transport. An information on the chlororespiration in higher plants is also included.     

The NADPH-dependent electron flow in chloroplasts of the higher plants

The NADPH-dependent reduction of some photosynthetic electron carriers in the dark, and the reduction of NADP+ associated with the glycolytic sequence and the oxidative pentose phosphate pathway in chloroplasts are reviewed. The postulated pathways of electron transports sensitive and insensitive to antimycin A are also evaluated. It is proposed that the electron flow, predominantly through cytochrome bf complex, may be also involved in the pathway of NADPH-dependent and antimycin A-insensitive back electron transport. An information on the chlororespiration in higher plants is also included. This revised version was published online in June 2006 with corrections to the Cover Date.     

The ATP-dependent Clp protease in chloroplasts of higher plants

The best-known proteases in plastids are those that belong to families common to eubacteria. One of the first identified was the ATP-dependent caseinolytic protease (Clp), whose structure and function have been well characterized in Escherichia coli . Plastid Clp proteins in higher plants are surprisingly numerous and diverse, with at least 16 distinct Clp proteins in the model plant Arabidopsis thaliana . Multiple paralogues exist for several of the different types of plastid Clp protein, with the most extreme being five for the proteolytic subunit ClpP. Both biochemical and genetic studies have recently begun to reveal the intricate structural interactions between the various Clp proteins, and their importance for chloroplast function and plant development. Much of the recent data suggests that the function of many of the Clp proteins probably affects more specific processes within chloroplasts, in addition to the more general 'housekeeping' role previously assumed.     

Ent-kaurene synthesis in chloroplasts from higher plants

Lysed chloroplasts from several higher plants synthesized ent-kaurene from copalyl pyrophosphate but not from geranylgeranyl pyrophosphate. The copalyl pyrophosphate transforming activity (so-called B activity of kaurene synthetase) was relatively stable in plastid lysates from Pisum sativum but remarkably unstable in similar preparations of Hordeum vulgare. The bulk of the B activity of kaurene synthetase appeared to reside in the stroma of plastids from P. sativum but required the presence of plastid membranes for maximum activity.     

Manipulating ribulose bisphosphate carboxylase/oxygenase in the chloroplasts of higher plants

Transgenic manipulation of the photosynthetic CO2-fixing enzyme, ribulose bisphosphate carboxylase/oxygenase (Rubisco) in higher plants provides a very specific means of testing theories about photosynthesis and its regulation. It also encourages prospects for radically improving the efficiencies with which photosynthesis and plants use the basic resources of light, water, and nutrients. Manipulation was once limited to variation of the leaf's total content of Rubisco by transforming the nucleus with antisense genes directed at the small subunit. More recently, technology for transforming the small genome of the plastid of tobacco has enabled much more precise manipulation and replacement of the plastome-encoded large subunit. Engineered changes in Rubisco's properties in vivo are reflected as profound changes in the photosynthetic gas-exchange properties of the leaves and the growth requirements of the plants. Unpredictable expression of plastid transgenes and assembly requirements of some foreign Rubiscos that are not satisfied in higher-plant plastids provide challenges for future research.     

The role of a glyoxylate-glycolate system in chloroplasts of higher plants

Photoreduction of glyoxylate and oxidation of glycolate wereinvestigated using unwashed chloroplasts from spinach leaves.A glyoxylateglycolate system operated in light and under aerobicconditions. Accompanying the photoreduction of glyoxylate andthe oxidation of glycolate, was the disappearance of inorganicphosphate. Photoreduction of oxalate was also observed in illuminatedchloroplasts. The reaction rate was, however, much lower thanthat for the photoreduction of glyoxylate. (Received August 4, 1969; )     

The family of Deg proteases in cyanobacteria and chloroplasts of higher plants

The family of Deg proteases is present in nearly all organisms from bacteria to higher plants. This family consists of ATP-independent serine endopeptidases with a catalytic domain of trypsin type and up to three PDZ domains, involved in protein–protein interactions. Sixteen deg genes (originally named deg P1–16) were found in Arabidopsis thaliana , and the chloroplast location was predicted or experimentally proven for seven proteins. The cyanobacterium Synechocystis sp. PCC6803 contains three Deg homologues, HtrA (DegP), HhoA (DegQ) and HhoB (DegS), but their number can vary between one and six in other photosynthetic Prokaryota. Interestingly, all of these proteases are evolutionarily more closely related within one species than proteases with the same names present in other organisms. This means that Deg proteases from A. thaliana are not necessarily the closest relatives of cyanobacterial DegP. Therefore, we propose to change the misleading original name 'DegP' to 'Deg' for A. thaliana enzymes. Here, we summarize the expression, location and functions of Deg proteases from cyanobacteria and chloroplasts of higher plants, with special emphasis on their role in the photosystem II (PSII) repair cycle under light stress conditions.     

Ascorbate-independent carotenoid de-epoxidation in intact spinach chloroplasts

Slow (> 1 s) light-induced absorbance changes in the 475–530 nm spectral region were examined in Type A chloroplasts from spinach. The most prominent absorption change occurred at 505 nm. The difference spectrum for this light-induced increase, its absence in osmotically shocked chloroplasts and restoration by ascorbate, and its sensitivity to dithiothreitol indicate that the absorption change is due to carotenoid de-epoxidation. The reaction in intact chloroplasts is characterized by its independence of exogenous ascorbate and a rate constant 3- to 8-fold higher than that reported previously for chloroplasts supplemented with ascorbate.The relevance of carotenoid de-epoxidation to other photosynthetic processes was examined by comparing their sensitivities to dithiothreitol. Levels of dithiothreitol that eliminate the 505 nm shift are without effect on saturated rates of CO₂ fixation and do not appreciably inhibit fluorescence quenching. We conclude that carotenoid de-epoxidation is not directly involved in the reactions of photosynthesis or in the regulation of excitation allocation between the photosystems.     

Clinorotation effect on thermodynamic efficiency of energy transformation in chloroplasts of higher plants

The aim of the work was to estimate the effect of clinorotation on thermodynamic coupling and efficiency of the process of photosynthetic energy transformation in chloroplasts using nonequilibrium thermodynamics approach. These parameters were calculated from experimentally determined net photosynthetic oxygen evolution at static head [(Je)sh], uncoupled rate of the oxygen evolution (Jo)unc and net rate of ATP production. It was found that in chloroplasts isolated from control and clinorotated pea plants coefficient of thermodynamic coupling of photophosphorylation (q) was 0.94 and 0.91 respectively. Optimal thermodynamic efficiency (eta opt) of the systems were calculated as 0.64 and 0.6 for control and clinorotation plants. Thus the data of the work show that thermodynamic efficiency of light energy transformation in higher plants is under influence of imitated weightlessness conditions.     

Targeted overexpression of the Escherichia coli MinC protein in higher plants results in abnormal chloroplasts

Higher plant chloroplast division involves some of the same types of proteins that are required in prokaryotic cell division. These include two of the three Min proteins, MinD and MinE, encoded by the min operon in bacteria. Noticeably absent from annotated sequences from higher plants is a MinC homologue. A higher plant functional MinC homologue that would interfere with FtsZ polymerization, has yet to be identified. We sought to determine whether expression of the bacterial MinC in higher plants could affect chloroplast division. The Escherichia coli minC (EcMinC) gene was isolated and inserted behind the Arabidopsis thaliana RbcS transit peptide sequence for chloroplast targeting. This TP-EcMinC gene driven by the CaMV 35S² constitutive promoter was then transformed into tobacco (Nicotiana tabacum L.). Abnormally large chloroplasts were observed in the transgenic plants suggesting that overexpression of the E. coli MinC perturbed higher plant chloroplast division.     

Chlorophyll a and carotenoid triplet states in light-harvesting complex II of higher plants.

Laser-flash-induced transient absorption measurements were performed on trimeric light-harvesting complex II to study carotenoid (Car) and chlorophyll (Chl) triplet states as a function of temperature. In these complexes efficient transfer of triplets from Chl to Car occurs as a protection mechanism against singlet oxygen formation. It appears that at room temperature all triplets are being transferred from Chl to Car; at lower temperatures (77 K and below) the transfer is less efficient and chlorophyll triplets can be observed. In the presence of oxygen at room temperature the Car triplets are partly quenched by oxygen and two different Car triplet spectral species can be distinguished because of a difference in quenching rate. One of these spectral species is replaced by another one upon cooling to 4 Ki demonstrating that at least three carotenoids are in close contact with chlorophylls. The triplet minus singlet absorption (T-S) spectra show maxima at 504-506 nm and 517-523 nm, respectively. In the Chl Qy region absorption changes can be observed that are caused by Car triplets. The T-S spectra in the Chl region show an interesting temperature dependence which indicates that various Car's are in contact with different Chl a molecules. The results are discussed in terms of the crystal structure of light-harvesting complex II.