Protein synthesis by isolated chloroplasts

Isolated chloroplasts show substantial rates of protein synthesis when illuminated. This in organello protein synthesis system has been advantageously utilised to elucidate the coding capacity of chloroplast and the regulation of chloroplast genes. The system is also being used recently to transcribe and translate homologous and heterologous templates. In this mini-review, we attempt to critically ecaluate the available literature and present the current and the prospective lines of research.     

Energy thresholds for ATP synthesis in chloroplasts

We have investigated the ATP synthesis associated with acid-base transitions in chloroplast lamellae under conditions which allow simultaneous control of the thermodynamic variables, ΔpH, membrane potential and ΔG_ATP. These variables have been directly imposed rather than simply inferred. Since the initiation of labeled P_i incorporation seems to measure accurately the initiation of net ATP synthesis, the following conclusions can be drawn: (1) The proton-motive force which is just sufficient for ATP synthesis provides almost exactly the required energy for ΔG_ATP if the efflux of three H⁺ is required for each ATP molecule formed. (2) The membrane potential and the ΔpH contribute to the proton-motive force in a precisely additive way. Thus, the threshold can be reached or exceeded by a ΔpH in the absence of a membrane potential, by a membrane potential in the absence of a ΔpH, or by any combination of membrane potential and ΔpH. With a large enough membrane potential, ATP synthesis occurs even against a small inverse ΔpH. In each instance the combined ΔpH and membrane potential necessary for initiation of ATP synthesis represent the same threshold proton-motive force.     

ADP binding and ATP synthesis by reconstituted H-ATPase from chloroplasts

The H⁺-ATPase from chloroplasts, CF₀F₁, was isolated, purified and reconstituted into asolectin liposomes. The enzyme was brought either into the oxidized state or into the reduced state, and the rate of ATP synthesis was measured after energisation of the proteoliposomes with an acid—base transition ΔpH (pH_in = 5.0, pH_out = 8.5) and a K⁺/valinomycin diffusion potential, Δφ (K⁺_in = 0.6 mM, K⁺_out = 60 mM). A rate of 250 s⁻¹ was observed with the reduced enzyme (85 s⁻¹ in the absence of Δφ). A rate of 50 s⁻¹ was observed with the oxidized enzyme under the same conditions (15 s⁻¹ in the absence of Δφ). The reconstituted enzyme contained 2 ATP_bound per CF₀F₁ and 1 ADP_bound per CF₀F₁. Upon energisation the enzyme was activated and 0.9 ADP per CF₀F₁, was released. Binding of ADP to the active reduced enzyme was observed under different conditions. In the absence of phosphate the rate constant for ADP binding was 10⁵ M⁻¹·s⁻¹ under energized and de-energized conditions. In the presence of phosphate the rate of ADP binding drastically increased under energized conditions, and strongly decreased under de-energized conditions.     

High rates of protein synthesis by isolated chloroplasts

Improvements are described in the preparation and in vitro conditions of an intact pea (Pisum sativum Progress No. 9) chloroplast system which provides high efficiency for translation of endogenous messenger RNA, using light as an energy source. High rates result in the incorporation into protein of up to 100 nanomoles tritiated leucine per milligram chlorophyll. These rates suggest extensive reinitiation, and repeated utilization of the messenger RNA that code for thylakoid proteins. Up to 39 radioactive thylakoid peptide bands were detected by fluorography after labeling with tritiated leucine.     

A proposed mechanism for the stimulatory effect of bicarbonate ions on ATP synthesis in isolated chloroplasts

The effect of bicarbonate ions on induction of Mg²⁺-ATPase activity, on the N-ethylmaleimide inhibition of phosphorylation and on energy-dependent adenine nucleotide exchange has been examined with pea seedling chloroplasts. Incubation of chloroplasts with N-ethylmaleimide in the presence of 15 millimolar bicarbonate in the light results in enhanced inhibition of ATP synthesis when the preillumination pH is maintained between 7.0 and 7.5. Bicarbonate also enhances Mg²⁺-ATPase activity when it is included in the light-triggering stage at pH 7.0. The conditions (medium pH, bicarbonate concentration, etc.) for demonstrating the bicarbonate-induced enhancement of the N-ethylmaleimide inhibition and ATPase activity are similar to those required for the direct effect of bicarbonate on phosphorylation. Bicarbonate, under the same conditions, does not affect adenine nucleotide exchange (binding or release). It is concluded that the stimulatory effect of bicarbonate on ATP synthesis may be related to its ability to alter directly the conformation of the chloroplast coupling factor under conditions (suboptimal pH) where the enzyme shows minimal activity.     

On the localization of organic acids in Acid-induced ATP synthesis

This study of the penetration and localization in isolated chloroplasts of some selected organic acids under inducing and non-inducing conditions has shown that there are 4 distinct relationships of acid penetration to ATP synthesis. Succinic acid which is effective as an inducer penetrates quite rapidly at pH 4.0 with the time course coinciding with that of acid-poise as determined by ATP synthesis. As the pH of stage I is raised (acid more dissociated) the penetration is slower, and the internal concentration at equilibrium is less. At pH 6.5 where succinic acid is fully dissociated there is little or no penetration of the dianion. A portion of the succinic acid (presumably the dianion) is retained in the chloroplasts on pH transition. This internal acid can be removed by placing plastids back in solution whose pH is less than 5.

A relatively ineffective dicarboxylic acid, e.g. malonic, penetrates quite slowly at pH 4.0. The acid-poise is maximized and declines (possibly due to acid denaturation of phosphorylating enzymes) much before the internal malonate is maximal. This dicarboxylic acid also shows little penetration as the dianion and some of it is effectively retained on pH transition from 4.0 to 8.4.

Acetic, an ineffective acid, penetrates quite well both as the acid and the anion and is not retained as the anion on transition from pH 4.0 to 8.4.

Glutamic acid which produces ATP yields comparable to those obtained with HCl was found to penetrate very slowly and did not reveal a measurable amount of retained acid on transition from pH 4.0 to 8.4.

     

Gibberellic Acid-induced synthesis of protease by isolated aleurone layers of barley

The production of protease by isolated aleurone layers of barley in response to gibberellic acid has been examined. The protease arises in the aleurone layer and is mostly released from the aleurone cells. The courses of release of amylase and protease from aleurone layers, the dose responses to gibberellic acid and the effects of inhibitors on the production of both enzymes are parallel. As is the case for amylase, protease is made de novo in response to the hormone. These data give some credence to the hypothesis that the effect of gibberellic acid is to promote the simultaneous synthesis and secretion of a group of hydrolases.     

Millisecond kinetics of ATP synthesis driven by externally imposed electrochemical potentials in chloroplasts

We have used rapid mixing and quenching techniques to measure the initial ATP synthesis rates and the duration of the ATP synthetic capacity derived from artificially imposed proton gradients and valinomycin-mediated K+ diffusion potentials in chloroplasts. The initial rate of ATP synthesis driven by a K+ diffusion potential was 10-fold slower than that driven by an acid-base transition of equivalent electrochemical potential. Total yields of ATP resulting from a K+ concentration shift were only slightly affected by the absence of Cl-, indicating that Cl- permeability does not significantly reduce the K+ diffusion potential. The ATP synthetic capacity decayed with a half-life of 0.2 s in the case of a K+ diffusion potential and a half-life of 1.0 s in the case of an acid-base shift. In both cases, ATP, added at the time of the pH or [KCl] shift, slowed the decay of the ATP synthesis rates, indicating that the coupling factor controls a channel for proton efflux, as proposed earlier (Portis, A.R., and McCarty, R.E. (1974) J. Biol. Chem. 249, 6250-6254). Because the proton gradient has a longer half-life than the K+ diffusion potential, when combinations of the two are employed to drive ATP synthesis, the proton gradient will make a larger contribution to the initial rate and total yield than that predicted from a strictly linear proportionality of the initial magnitudes of the two gradients.     

Factors affecting the development of the capacity for ATP formation in isolated chloroplasts

Full development of the capacity for ATP formation in isolated thylakoid membranes coincides with the beginning of illumination. Indeed, the yield of ATP per ms of illumination is about twice as great during the first 15 ms of high-intensity illumination as it is thereafter. The presence of valinomycin and K⁺ prevents the formation of a membrane potential (as indicated by the obliteration of most of the change in absorbance at 518 nm) and at the same time delays the formation of the capacity for ATP synthesis for many milliseconds. Presumably, phosphorylation is initially dependent on a rapidly formed membrane potential, whereas after a delay a ΔpH sufficient to drive ATP formation forms. The actual duration of this delay depends on the phosphoryl group transfer potential (i.e., ΔG_ATP) of the ATP-synthesizing reaction. If the delay in the presence of valinomycin and K⁺ represents the time required to develop a ΔpH capable of driving phosphorylation by itself, then the effect of ΔG_ATP on the duration of the delay suggests that the onset of phosphorylation is determined by the magnitude of the electrochemical potential of protons and not by factors affecting the activation of the coupling factor enzyme. The initial ATP formation, which is almost entirely dependent on the electrical potential, should not be affected by the electrically neutral exchange of cations catalyzed by nigericin. When the external pH is 7.0 this seems to be true, since the ATP synthesis which is initially sensitive to valinomycin and K⁺ is largely insensitive to nigericin and K⁺. However, when the external pH is 8.0 the response to nigericin is exactly the opposite and the ATP formation which is sensitive to valinomycin is also abolished by nigericin. These data suggest that there may be either an energetic requirement for both a ΔpH and membrane potential at alkaline pH or a non-energetic requirement for a minimum proton activity in the initiation of phosphorylation.     

Synthesis of acyl-CoAs by isolated spinach chloroplasts in relation to added CoA and ATP

The kinetics of incorporation of [2-¹⁴C] acetate into lipids and acyl-CoAs in relation to added CoA and ATP by isolated spinach chloroplasts have been examined. The effect of the concentration of these cofactors on lipid and acyl-CoA synthesis was also studied. In the absence of cofactors, or when only one was present, the incorporation was very low and went mainly into lipids. When both cofactors were present a strong stimulation of both activities occurred. After 25 min, acyl-CoAs were more strongly labeled than lipids and both activities continued linearly for at least 60 min.Abbreviations ACP acyl carrier protein - FFA free fatty acids