The Effect of Phytohormones on Chlorophyll(ide), Protochlorophyll(ide) and Carotenoid Formation in Greening Dark Grown Wheat Leaves

The influence of phytohormones on chlorophyll and carotenoid formation during the greening of irradiated dark grown wheat leaves (Triticum aestivum L. cv. Starke II Weibull) was studied. Leaves were floated on solutions of abscisic acid, gibberellic acid and kinetin for 24 h. The chlorophyll and carotenoid contents were determined during a subsequent period of 48 h of continuous irradiation. Leaves treated with abscisic acid showed a longer lag phase and a lower rate of accumulation of chlorophyll as compared to the control than did leaves treated with gibberellic acid and kinetin. The carotenoid content was low both in leaves treated with abscisic acid and in those treated with gibberellic acid. Treatment with abscisic acid lowered the protochlorophyllide regeneration after a saturating light flash while gibberellic acid as well as kinetin had no effect. The influence of ABA was partly dependent on an increase of the wounded part of the cut leaf segments. The accumulation of protochlorophyllide in leaves treated with δ-aminolevulinic acid was not affected by the different hormonal treatments. These results suggest that the main effect of abscisic acid is probably outside the chloroplast, i.e. on the formation or transport of δ-aminolevulinic acid.     

Effect of phytohormones on chlorophyll degradation during aging of chloroplastsin vivo andin vitro

Summary Phytohormones like IAA and kinetin inhibit chlorophyll loss during aging of wheat chloroplasts duringin vivo andin vitro. GA, on the other hand, stimulates the pigment degradation during aging of attached leaves in contrast to its senescence inhibiting action in detached leaves and isolated chloroplasts. A shift in optimum concentration of hormone in inhibiting chlorophyll degradation suggests a differential pool size of endogenous hormone regulating aging of chloroplastsin vivo andin vitro. The retardation of chlorophyll loss by kinetin, IAA and GA during aging of chloroplastsin vitro would indicate that the effect of hormones in preventing yellowing of senescing leaves may be mediated through their direct action on chloroplasts.     

The effect of cytokinins on nitrate reductase activity

Cytokinins in addition to nitrate induce nitrate reductase activity (NRA) in some plants. Effects of cytokinins onNRA was investigated in stem pith parenchyma of kale, intact wheat and barley seedlings and isolated cucumber cotyledons. The most profound effect onNRA was found in barley and wheat seedlings.NRA in seedlings sprayed with 100 μM 6-benzylaminopurine (BAP) for three subsequent days was increased in leaves and decreased in roots. These changes were further enhanced in seedlings grown in nutrient solution lacking nitrate:NRA in wheat and barley leaves was increased by 57% and 202%, respectively, in plants supplied with nitrate theNRA increase was not significant: in wheat and barley leaves by 22% and 9%, respectively. Similar effect of BAP and kinetin was found in kale stem parenchyma and cucumber cotyledons. The cytokinin kinetin or BAP alone increasedNRA about twice in kale and three times in cucumber. Addition of nitrate to the medium enhanced the effect of kinetin in kale discs, but the two effects were not additive. Additive effect of nitrate and BAP onNRA was found in cucumber cotyledons in light. In general NRA was more affected by cytokinins in intact seedlings of wheat and barley as compared to explanted tissue of kale and cucumber, and lack of nitrogen made their effect more expressive.     

Synthesis and cytokinin-like activity of 7-chloro-imidazo[1,2-c]pyrimidines

Some 5-amino substituted 7-chloro-imidazo[1,2-c]pyrimidines and 7-chloro-8-methylthio-imidazo[1,2-c]pyrimidines were synthesized for further information on the role of the purine ring in cytokinin structure/activity relationships. Their cytokinin-like activity was examined using four different tests: expansion of cucumber etiolated cotyledons; formation of chlorophyll in etiolated cotyledons of cucumber; preservation of chlorophyll breakdown in sections of barley leaves; inhibition of root growth in intact wheat seedlings. Compounds with the imidazopyrimidine ring were generally less active than those with the purine ring, with the exception of the pentenylamino derivatives, which showed an activity comparable with that of the control, kinetin.     

Increased Levels of Cytokinins in Barley Leaves Having the Systemic Acquired Resistance to Bipolaris sorokiniana (Sacc.) Shoemaker

The role of endogenously induced higher level of cytokinins and exogenously applied kinetin in relation to the development of barley leaf spot caused by Bipolaris sorokiniana (Sacc.) Shoemaker (syn. Helminthosporium sativum Pammel, King and Bakke) was studied. Spraying barley leaves with kinetin suppressed the number and the size of necrotic spots caused by the fungus. Inoculation of the lower leaves of barley by a spore suspension of the fungus B. sorokiniana induced resistance on the upper leaves against a subsequent challenge inoculation by the same pathogen 10 days later. An increase in the level of cytokinins was observed in these resistant leaves. Elevated levels of cytokinins may cause a type of juvenility in leaf tissues. The juvenile state could be in a causal relationship with the suppression of necrotic spots caused by the fungus.     

The effect of kinetin on chlorophyll synthesis in ageing etiolated barley leaves exposed to light

Etiolated barley seedlings lose the ability to produce chlorophyll and soluble protein on exposure to light with increasing age. Similarly, the production of δ-aminolaevulinic acid-dehydratase and succinyl-CoA synthetase is decreased in older etiolated leaves exposed to light. The rate of protochlorophyllide₆₅₂ regeneration decreased well before the rates of exogenous δ-aminolaevulinic acid conversion to protochlorophyllide₆₃₂ was affected by ageing. Application of kinetin retarded these ageing symptoms in the etiolated leaves.     

The effects of lead and kinetin on greening barley leaves

The content of lead in greening etiolated barley leaves remained the same, regardless the time of incubation of excised leaves in the presence of lead ions (8–24 h). The lead deposits have not been detected within mesophyll cells, but were found in intercellular spaces of mesophyll, in guard cells and in cuticle covering stomata. This suggests that lead may be transported in the leavesvia transpiration stream. Lead reduced the content of chlorophyll, especially chlorophyllb content and the average number of grana, whereas in the presence of kinetin the content of chlorophyll increased. In the combined treatment (lead + kinetin) kinetin diminished the inhibitory effect of lead on the chlorophyll content. The number of chloroplasts in mesophyll cells remained unchanged after lead treatment, whereas kinetin alone or applied together with lead increased the average chloroplasts number. The thylakoids system in chloroplasts of kinetin and kinetin + lead treated plants was similar to that observed in control, although the grana number was smaller. Both lead and kinetin increased the content of condensed chromatin in nuclei.     

Changes in chloroplast peroxidase activities in relation to chlorophyll loss in barley leaf segments

Total peroxidase activity increased during senescence of excised barley ( Hordeum vulgare L. cv. Kashimamugi) leaves. Kinetin treatment furter increased total peroxidase activity but repressed chlorophyll degradation in excised barley leaves. When isoperoxidases were extracted from barley leaf segments. 4 cationic and 4 anionic isozymes were found in polyacrylamide gel electrophorests during leaf senescence. The chloroplasts contained only two cationic isoperoxidase activities. One (designated C4) was repressed by kinetin. and the other (C3) was increased by kinetin. Glucosamine, which also repressed the degradation of chlorophyll, completely repressed C4 activity but did not affect C3 activity. The induction with senescence, and the repression with kinetin and glucosamine, suggest chat chloroplast isoperoxidase C4 may function as a chlorophyll-degrading enzyme during barley leaf senescence.     

The light-induced development of nitrate reductase in etiolated barley shoots: An inhibitory effect of laevulinic acid

Induction of nitrate reductase EC 1.6.6.1 in etiolated barley (Hordeum vulgare L., var. Proctor) required continuous illumination and showed a lag period of about three hours. During the first 16 h of illumination the ratio NADH/NAD and NADPH/NADP, taken as a measure of internal oxidation reduction potential, declined. The inhibitor DCMU applied to whole leaves at concentrations shown to inhibit the reduction of cytochrome f by Photosystem 2 light did not inhibit the induction of nitrate reductase nor did it diminish the ratio of reduced to oxidised puridine nucleotides in the early hours of greening. It was concluded that light driven electron flow was not necessary for nitrate reductase induction. Chloramphenicol gave a slight inhibition of nitrate reductase induction. Laevulinic acid was added to greening barley leaves to inhibit tetrapyrrole pigment biosynthesis and plastid development. It strongly inhibited chlorophyll synthesis and nitrate reductase induction, with relatively little effect upon Photosystem 1 and 2 activities in isolated plastids. The activities of other inducible enzymes and control enzymes were little affected by laevulinic acid. Laevulinic acid also inhibited nitrate reductase induction by added nitrate in fully-greened illuminated plants grown in nitrate-free medium and so is unlikely to be acting through inhibition of plastid development. This inhibitor lowered the level of protohaem in whole leaves and plastids of greening barley and it is postulated that it may diminish the protohaem available for the assembly of a cytochrome b component of nitrate reductase.Abbreviations DCMU 3-(3:4-Dichlorophenyl)-1:1-dimethylurea - LA laevulinic acid     

The inhibition of kohlrabi chloroplast degeneration by kinetin

Summary Detached kohlrabi leaves of late autumn material yellowed completely after 6 days in weak light. This process was accompanied by a decrease in chlorophyll, protein, and ribonucleic acid levels. In the chloroplasts, degeneration symptoms such as reduction in chloroplast volume, the decay of grana, development of the long thylakoid system, disappearance of chloroplast ribosomes, increase in the volume of plastoglobuli, and finally a complete breakdown of plastids in the digesting vacuoles, were observed. The ultrastructural changes in degenerating kohlrabi chloroplasts resembled those described earlier for brussels sprouts (Dennis et al. 1967), which suggests that the plastid degeneration model may be specific for speciesBrassica oleracea L.Kinetin inhibited the fall in the level of chlorophyll, proteins, and RNA in relation to the control material, and even stimulated chlorophyll and protein synthesis to a level higher than that of the initial material. Treatment with kinetin also markedly delayed the loss of chloroplast ribosomes. The most evident effect of the kinetin influence on the plastid ultrastructure was the stimulation of the formation and maintenance of grana. A possible mechanism for these processes in the light of the recent studies on the chloroplast membranes is discussed.     

Discrete character of the development of the photosynthetic apparatus in greening barley leaves

Biogenesis of the photosynthetic apparatus in greening etiolated leaves of barley (Hordeum vulgare L) was investigated by an approach permitting investigation of this process under conditions that minimize differences in plastid development. Distributions of barley leaves greening for 24 h as to chlorophyll content and of chloroplast grana as to number of thylakoids were shown to be of a multimodal character. The shape of time-course curves of chlorophyll accumulation in local sites of greening etiolated leaves was of a stepped or (at the end of greening) undulated character. The stepwise accumulation of chlorophyll was accompanied by wave-like changes in chlorophyll b/a ratio, intensity of low-temperature chlorophyll fluorescence and photosynthetic activity with minima at the time points of transition to accelerated chlorophyll accumulation. It is assumed that (1) development of the photosynthetic apparatus in local sites of greening etiolated leaves occurs stepwise, from one steady level to another, but not as gradually as is generally accepted, and (2) every separate step in development of the photosynthetic apparatus seems to begin with formation of photosystem cores and to end with the synthesis of light-harvesting complexes. This revised version was published online in June 2006 with corrections to the Cover Date.     

Ineffectiveness of cytokinin-induced chlorophyll retention in hypostomatous leaf discs

Kinetin retarded the decrease in chlorophyll content in leafdiscs from 5 species of plants with amphistomatous leaves, wherethe upper surface was exposed to air, but not in Rumex acetosera.When leaf discs were floated so that the lower surface was exposed,the effect of kinetin was less evident. Kinetin also stimulatedtranspiration in leaf discs from Nicotiana tabacum (amphistomatous),but not in leaf discs from Paederia chinensis (hypostomatous).Nor kinetin did retard chlorophyll breakdown in this specieswhen leaf discs were floated so that the stomatal surface wasin contact with the solution. The ineffectiveness of cytokininsin chlorophyll retention in leaf discs from hypostomatous leaveswas not due to reduced uptake of benzylaminopurine-¹⁴C. Chlorophyll retention was severely inhibited by coating theleaf surface with vaseline either in the presence or absenceof kinetin. Leaf discs floated on a solution exposed to CO₂-lessair retained more chlorophyll than those in normal air. Thereis thus a close relationship between stomatal opening (as measuredby stimulation of transpiration) and chlorophyll retention,as influenced by cytokinins. It is suggested that cytokinin-induced chlorophyll retentionand odier effects on leaf tissues could be mediated throughits effects on stomatal opening. (Received January 22, 1976; )     

Translocation of radioactive kinetin

Kinetin has generally been thought to be immobile in plants. This was confirmed in the case of laminar applications in this study, but not in regard to petiole, vein, or root applications. Radioactivity from kinetin-8-¹⁴C (Kn^*) moved freely in the vascular system of several types of leaves. This movement was usually distal to the point of application and seemed to occur with the transpiration stream. Basipetal as well as acropetal translocation of radioactive kinetin was achieved in tobacco leaves. The translocated material was extracted from veinal tissue, shown to be radioactive, and to be able to retard senescence. Similar but less decisive results were obtained from agar blocks inserted into the vascular system of leaves receiving Kn^* by petiole uptake.

A bioassay employing disks from primary bean leaves was developed for the qualitative determination of substances like kinetin which possess the ability to retard chlorophyll breakdown and plant senescence. The use of radioactive kinetin provided a refinement in this bioassay because treated non-senescent areas could be correlated with exposed areas on radioautographs made from dried leaf disks.

Root treatments showed that cotton seedlings did not take up Kn^* but that similarly treated tobacco seedlings both absorbed and translocated the isotope readily.

     

Some effects of enhanced UV-B irradiation on the growth and composition of plants

Barley (Hordeum vulgare), corn (Zea mays), bean (Phaseolus vulgaris), and radish (Raphanus sativus) seedlings were continuously irradiated under a lighting device for 5–10 d at an increased ultraviolet (UV)-B fluence rate. In their growth parameters, composition, and leaf surface, these four species responded differently to the increased UV-B exposure. Bean seedlings suffered the most serious effects, radish and barley less, and corn was hardly influenced at all. In all plant species, the fresh weight, the leaf area, the amounts of chlorophylls, carotenoids and the galactolipids of the chloroplasts were reduced. The lipid content of the corn and bean seedlings also diminished. But all the irradiated plants showed a rise in their protein content compared to the control plants. The content of flavonoids increased in barley and radish seedlings by about 50%. The effects on growth parameters and composition were more extensive with increasing UV-B fluence rates, at least as shown in the case of barley seedlings. The fresh weights fell proportionally with the chlorophylls and carotenoids. In contrast, the flavonoid content of barley leaves rose parallel to the increasing UV-B fluence rates and reached 180% of the value in the control plants with the highest UV-B fluence rate. Scorching appeared regularly in the form of bronze leaf discoloration at the highest UV-B fluence rates. Scanning electron micrographs of the leaf surface of UV-B irradiated plants showed deformed epidermal structures.Abbreviations MGDG monogalactosyldiglyceride - DGDG digalactosyldiglyceride - SL sulfoquinovosyldiglyceride - PG phosphatidylglycerol - PC phosphatidylcholine - PE phosphatidylethanolamine - PI phosphatidylinositol - LA leaf are - FW fresh weight - DW dry weight - SEM scanning electron microscopy - C total carotenoids - Chl total chlorophyll     

Control of Chlorophyll Degradation in Detached Leaves of Barley and Oat through Effect of Kinetin on Chlorophyllase Levels

Chlorophyllase seems to be responsible for the degradation of chlorophyll during senescence of detached leaves of barley (Hordeum vulgare) and oat (Avena sativa). Treatment at temperatures higher than 40°C — which protects against chlorophyll loss — lowers the level of chlorophyllase. Kinetin treatment lowers the level of chlorophyllase in barley leaves and prevents its rise in oat leaves after their detachment. Synthesis of proteins in both cytoplasm and chloroplast seems to be required in order to maintain a high level of Chlorophyllase in barley leaves after detachment.     

Multiple actions of abscisic acid in senescence of oat leaves

The modifications induced by abscisic acid (ABA) on the senescence of oat leaves in darkness have been studied and are compared with its well-known effects in light. Contrary to the action in light, ABA preserves chlorophyll (Chl) in the dark almost as well as kinetin. Chlorophylla is decolorized more extensively thanb, and the content ofb is maintained by ABA almost at its initial level for 4 days. ABA also prevents proteolysis in darkness just as completely as chlorophyll loss, the relationship of both breakdown processes to ABA concentration being strictly log-linear over the range from 1 to 100 M. In line with this action, ABA inhibits formation of the neutral protease in the dark but not in the light. The data suggest that ABA and kinetin operate to preserve chlorophyll and protein by different mechanisms, since their actions are neither independent nor synergistic but actually interfere with one another. In this connection, protein values given by the Lowry and Bradford methods have been compared. In parallel with the effect on senescence, ABA slowly opens the stomata in the dark. This effect increases with time, and by day 3 the stomata in ABA are as open as in leaves on water in light. Thus all these effects of ABA in darkness are strikingly opposite to those commonly observed on leaves in natural lighting. In addition, ABA powerfully inhibits the formation of ethylene in the dark by the detached oat leaves, and this inhibition also tends to increase with time. Finally, a slight antagonism to ABA's action on senescence is exerted byp-coumaric acid in the light but not in the dark.     

Effetto dell'Irraggiamento X sulla Biosintesi degli Amminoacidi in Piante di Orzo

Abstract

The effects of irradiation on aminoacids biosynthesis in barley. — The effect of radiations on the biosynthesis of aminoacids in barley has been studied. Seeds have been irradiated with X-tays of 7.5 and seedlings with 7.5, 15 and 30 Kr. After 6–7 days of growth the control and irradiated seedlings, and the seedlings from control and irradiated seeds, have been supplied with 10–100 μC of C¹⁴O₂ in a closed chamber for 44–42 hours. The material was extracted with hot ethanol (85%–80% and 40%). Total radioactivity and the radioactivity of the basic fraction, eluted with HCl from Dowex 50, X-8′ (200–400 mesh, H^?) have been measured. It was observed that radiations increase the radioactivity of the aminoacid fraction, both in leaves and roots. A correlation between the decrease of fresh weight and increase of aminoacids radioactivity was shown. A possible explanation might be visualized in terms of the inhibition of growth and protein synthesis by radiations.     

Chlorophyll b reduction during senescence of barley seedlings

During senescence of flowering plants, only breakdown products derived from chlorophyll a were detected although  b disappears, too (Matile et al., 1996, Plant Physiol 112: 1403–1409). We investigated the possibility of chlorophyll b reduction during dark-induced senescence of barley (Hordeum vulgare L.) leaves. Plastids isolated from senescing leaves were lysed and incubated with NADPH. We found 7¹-hydroxy-chlorophyll a, 7¹-hydroxy-chlorophyllide a, and, after incubation with Zn-pheophorbide b, also Zn-7¹-hydroxy-pheophorbide a, indicating activity of chlorophyll(ide) b reductase. The highest activity was found at day 2 of senescence when chlorophyll breakdown reached its highest rate. Chlorophyllase reached its highest activity under the same conditions only at days 4–6 of senescence. Based on the chlorophyll b reductase activity of plastids at day 2.5 of senescence (=100%), the bulk of activity (83%) was found in the thylakoids and only traces (5%) in the envelope fraction. Chlorophyll b reduction is considered to be an early and obligatory step of chlorophyll b breakdown. Received: 22 February 1999 / Accepted: 24 March 1999     

Temperature dependence of delayed chlorophyll fluorescence in intact leaves of higher plants. A rapid method for detecting the phase transition of thylakoid membrane lipids

The temperature dependence of the yield of in vivo prompt and delayed chlorophyll fluorescence was investigated in maize and barley leaves. In the chilling-sensitive maize, delayed fluorescence at steady-state level showed a maximum near the temperature at which thylakoid membrane lipids undergo a phase transition as revealed by differential scanning calorimetry measurements. In the chilling-resistant barley, no phase transition was detected above 0°C and the delayed light emission varied in a monotonic fashion. It was shown that measurements of delayed luminescence intensity in vivo can provide a rapid and sensitive method for detecting the phase change of membrane lipids in intact leaves of chilling-sensitive plant species such as tomato, cotton, cucumber, castor bean or avocado. In contrast, the use of steady-state prompt chlorophyll fluorescence as an indicator of membrane fluidity change was not successful.