Effects of the selective herbicide fluazifop on fatty acid synthesis in pea (Pisum sativum) and barley (Hordeum vulgare).

Concentrations of fluazifop-butyl sprayed on intact plants caused large decreases in the incorporation of radioactivity from [1-14C]acetate into lipids of barley (Hordeum vulgare) leaves and stems, but did not affect leaves or stems of pea (Pisum sativum). Labelling of all acyl lipids, but not pigments, was reduced. The effects of the active acid form, fluazifop, were also determined in leaf pieces and chloroplasts. Concentrations of (R,S)-fluazifop up to 100 microM had no affect upon quality or quantity of fatty acids produced from [1-14C]acetate in pea. In barley, however, 100 microM-(R,S)-fluazifop caused 89% (leaf) or 100% (chloroplasts) inhibition in labelling of fatty acids from [1-14C]acetate. Lower concentrations of fluazifop (less than 25 microM) caused incomplete inhibition and significant decreases in the proportion of C18 fatty acids synthesized, particularly by isolated chloroplasts. Synthesis of fatty acids from [2-14C]malonate was also inhibited (59%) in barley leaf tissue by 100 microM-(R,S)-fluazifop. The labelling pattern of products showed that elongation reactions were unaffected by the herbicide, but synthesis de novo was specifically diminished. By using resolved stereoisomers, it was found that the (R) isomer was the form which inhibited fatty acid synthesis, a finding that is in agreement with its herbicidal activity. These results suggest that inhibition of fatty acid synthesis de novo forms the basis for the selective mode of action of fluazifop.

Fluazifop, a grass-selective herbicide which inhibits acetyl-CoA carboxylase in sensitive plant species.

Fluazifop is a grass-selective herbicide that appears to act by inhibiting fatty acid synthesis de novo in sensitive species. Results from four different types of experiment show that this inhibition is due to an action of fluazifop on acetyl-CoA carboxylase and not on fatty acid synthetase. The acetyl-CoA carboxylase from sensitive barley (Hordeum vulgare), but not from resistant pea (Pisum sativum), is inhibited by the R stereoisomer, a finding that agrees with the herbicidal specificity of fluazifop.

Changes in the activities of chloroplast and cytosolic isoenzymes of glutamine synthetase during normal leaf growth and plastid development in wheat.

Soluble protein extracts and chloroplasts from a serial sequence of transverse sections of a 7-d-old wheat leaf (Triticum aestivum cv. Maris Huntsman) were used to study changes in the activity of glutamine synthetase (GS; EC 6.3.1.2) during cell and chloroplast development. Glutamine synthetase activity increased more than 50-fold per cell from the base to the tip of the wheat leaf. Two isoenzymes of GS were separated using fast protein liquid chromatography (FPLC). Glutamine synthetase localized in the cytoplasm (GS1) eluted at about 0.21 M NaCl, and the isoenzyme localized in the chloroplast (GS2) eluted at about 0.33 M NaCl. The increase in GS activity during leaf development was found to be caused primarily by an increase in the activity of the chloroplast GS2. The activity of the cytoplasmic GS1 remained constant as the cells were displaced from the base to the tip of the leaf, whereas GS2 activity increased within the chloroplast throughout development. At the base of the leaf, 26% of total GS activity was cytoplasmic; the remaining 74% was in the chloroplast. At 10 cm from the base, only 4% of the activity was cytoplasmic, and 96% was in the chloroplast. The results indicate that the chloroplast GS2 is probably responsible for most of the ammonia assimilation in the mature wheat leaf, whereas cytoplasmic GS1 may serve a role in immature developing leaf cells.

Kinetics for glutamine-synthetase inhibition by phosphinothricin and measurement of other enzyme activities in situ in isolated asparagus cells using a freeze-thaw technique.

Kinetics for the inhibition of glutamine synthetase (EC 6.3.1.2) in situ by the herbicidal glutamate analogue, phosphinothricin, have been generated, and produce an inhibitor dissociation constant (Ki) of 6.5 µM. This has been achieved through the development of a rapid technique for the isolation of mesophyll cells from the cladophylls of young asparagus (Asparagus sprengeri) plants to provide starting material for the direct measurement of enzyme activities in situ. A modification of the technique developed by Rhodes and Stewart (Planta 118, 133-144 (1974) for the direct determination of enzyme activities in higher-plant tissues has been applied to these asparagus cells. Treatment of the cells by a single freezing in liquid nitrogen for a very short period (10 s), followed by thawing, alters the permeability of cell and organelle membranes allowing enzymes to become accessible to many small molecules, and yet remain concentrated and active within the cell. The activities of enzymes known to be located specifically in the organelles as well as the cytoplasm can be measured in asparagus cells treated in this way. Comparisons have been made between the activity and inhibition of glutamine synthetase in situ, and the enzyme isolated and partially purified from asparagus cells by fast protein liquid chromatography. Similarities in Km and Ki values obtained between these two emphasize the efficacy of the freeze-thaw technique. There is only a single glutamine-synthetase isoenzyme in asparagus mesophyll cells, which copurifies with the one normally associated with the chloroplast (GS2).

Interaction of chloroplasts with inhibitors: effects of two diphenylether herbicides, fomesafen and nitrofluorfen, on electron transport, and some comparisons with dibromothymoquinone, diuron, and paraquat.

Several effects on pea (Pisum sativum L. var Onwards) chloroplasts of a new diphenylether herbicide, fomesafen (5-[2-chloro-4-trifluoromethyl-phenoxy]-N-methanesulfonyl-2 -nitrobenzamide) have been compared with those of a herbicide of related structure, nitrofluorfen (2-chloro-1-[4-nitrophenoxy]-4-[trifluoromethyl]benzene). Although both compounds produce the same light-dependent symptoms of desiccation and chlorosis indicative of a common primary mechanism of action, this study is concerned with a more broadly based investigation of different effects on the electron transport system. Comparisons have also been made with other compounds interacting with the chloroplast. Unlike nitrofluorfen, fomesafen has little effect as an inhibitor of electron flow or energy transfer. Both compounds have the ability to stimulate superoxide production through a functional electron transport system, and this involves specifically the p-nitro substituent. The stimulation, which is not likely to be an essential part of the primary herbicidal effect, is diminished under conditions that remove the coupling factor. Evidence suggests that both diphenylethers may be able to bind to the coupling factor, and kinetic studies reveal this for dibromothymoquinone as well. Such a binding site might be an important feature in allowing the primary effect of the diphenylether herbicides to be expressed.

Interaction of Chloroplasts with Inhibitors: Location of Carotenoid Synthesis and Inhibition during Chloroplast Development.

The inhibitor SAN 6706 [4-chloro-5-(dimethylamino)-2-(alpha,alpha,alpha,-trifluoro- m-tolyl-3(2H)-pyridazinone] has been used to study the synthesis of carotenes and xanthophylls during the conversion of etioplasts to chloroplasts in developing barley (Hordeum vulgare) shoots. SAN 6706 inhibits carotenoid synthesis and causes an accumulation of phytoene, but it is also a potent inhibitor of chloroplast electron transport. When developing barley is treated with SAN 6706, carotenoid synthesis is inhibited but total photosynthesis is unaffected. The ability of SAN 6706 to inhibit carotenoid synthesis becomes progressively less if etiolated shoots are illuminated for increasing lengths of time before treatment. During the greening of treated barley shoots only light-induced beta-carotene synthesis is immediately inhibited; xanthophyll synthesis is not affected until after about 8 hours. The hypothesis that SAN 6706 cannot enter the chloroplast but inhibits carotenoid synthesis from the cytoplasm is discussed, and the question as to whether there are not two separate groups of enzymes for the synthesis of carotenes and xanthophylls is considered.

Interaction of chloroplasts with inhibitors: induction of chlorosis by diuron during prolonged illumination in vitro.

A primary symptom of diuron (DCMU) phytotoxicity in plants is the destruction of chlorophyll. To study this process in vitro, chloroplasts from pea leaves (Pisum sativum L.) have been incubated in the light with DCMU for periods of up to 34 hours. The sequence of photodestruction of chlorophylls and carotenoids has been followed to try and establish the nature of the chloroplast protection mechanisms that are destroyed by DCMU. beta-Carotene decays most rapidly, followed by chlorophyll a and xanthophylls which are destroyed in a constant ratio, followed finally by chlorophyll b. Bypassing the DCMU block in the electron transport system with an artificial electron donor provides complete protection against chlorophyll and carotenoid photodestruction. The same protection by this electron donor system is afforded to stroma-free lamellae from which soluble reductants have been removed so that NADPH formation, which has been proposed as an essential part of a protective xanthophyll cycle, is not possible. Both this and the simultaneous loss of chlorophyll a and xanthophylls tend to preclude the breakdown of a xanthophyll cycle from the possible protective mechanisms inhibited or destroyed by DCMU.Cofactors of cyclic electron transport also protect against DCMU-induced photodestruction of pigments. Their concentration dependence for this protection appears to reflect their various abilities to catalyze cyclic photophosphorylation. The extent to which the chlorophylls are destroyed in the major pigment-protein complexes from chloroplasts illuminated with and without DCMU has been measured. In the absence of DCMU, the light-harvesting chlorophyll a/b protein complex is destroyed most rapidly. In the presence of DCMU, the losses of chlorophyll a from the photosystem I P700-chlorophyll a protein and the chlorophyll a/b complex are about the same. Chlorophyll losses are matched by simultaneous losses of the protein moieties; spectral analyses show that the remaining chlorophyll a is held in a loose association with the protein. Phenazine methosulfate protects the chlorophyll of the light-harvesting complex in DCMU-treated chloroplasts more than it protects that in photosystem I. Data published on DCMU-induced fluorescence and its quenching are used to interpret the longer term DCMU-induced chlorosis and its protection. By blocking electron transport, conformational changes in the membrane that allow spillover of excitation energy from photosystem II to photosystem I (and quenching of fluorescence by this means) are prevented. The mechanism that normally protects the chloroplast against excessive illumination is then overloaded which impairs the harmless dissipation of absorbed light energy; consequently, the pigments are destroyed. When photosystem I is allowed to function again through cyclic electron flow, a necessary conformational change is believed to be reintroduced that once again allows the harmless dissipation of excitation energy through spillover. A functional electron transport system associated with photosystem I will protect against DCMU-induced chlorosis when the thylakoid membranes are intact, but when the P700-chlorophyll a protein complex is in isolation, there is only a limited degree of protection.

The survival of chloroplasts in vitro: Particle volume distribution patterns as a criterion for assessing the degree of integrity of isolated chloroplasts.

Volume distribution patterns of chloroplast suspensions obtained electronically with a Coulter counter have been compared with the corresponding diameter measurements and with the appearance of chloroplasts observed by phase-contrast microscopy. It was found that the Coulter counter pattern could be used to detect gross morphological changes of chloroplasts in isolation, but could not be used for the quantitative determination of the properties of chloroplasts in different morphological states. The pattern for a suspension containing both intact and damaged chloroplasts in approximately equal numbers has only one maximum. Two maxima are present if the proportion of intact chloroplasts is considerably greater than 50%. Chloroplasts which have lost both their outer limiting membrane and also their stroma (i.e. naked, but intact, lamellae systems) make only a very small contribution to the size distribution pattern in the region recording apparent volumes between 0 and 11.2 µ(3).Previous workers have described intact chloroplasts as "Class I", and damaged chloroplasts lacking limiting membrane and stroma as "Class II". We suggest that a third "Intermediate Class" should be recognized for chloroplasts devoid of their limiting membrane, but still retaining stroma. Such chloroplasts can be distinguished from Class II chloroplasts by their less clearly visible grana, and slightly lighter appearance under phase contrast, and also by their considerable contribution to Coulter counter volume distribution patterns with a peak maximum between 35 and 55 µ(3). Such Intermediate Class chloroplasts would also be expected to have biochemical properties differing considerably from those of both Class I and Class II chloroplasts.