Protein synthesis by chloroplasts during the senescence of barley leaves

Chloroplasts were isolated from senescent leaf segments of barley ( Hordeum vulgare L. var. Mozoncillo) and assayed for protein synthesis. Protein synthesis activity of the chloroplasts greatly increased after 10–20 h of incubation of leaf segments in the dark in spite of an intense degradation of chloroplast rRNA. The rise in the activity of protein synthesis was more pronounced when kinetin was present in the incubation medium. However, as deduced from SDS-polyacrylamide gel electrophoresis of the products, different proteins were synthesized under the two conditions of incubation of the leaf segments. The activity of protein synthesis of the chloroplasts decreased during the first hours of incubation of the leaf segments in the light.
Cutting and incubation in the dark of the leaf segments enhanced the synthesis of a few proteins also formed by chloroplasts in attached senescing leaves. Hormone and senescence treatments changed the type and the rate of the protein synthesized by chloroplasts, which suggests that hormones may control senescence through a modulation of the protein synthesized by the chloroplasts.     

Nondestructive analysis of senescence in mesophyll cells by spectral resolution of protein synthesis-dependent pigment metabolism

* Over 6 d of dark-induced senescence, leaf segments of wild-type Lolium temulentum lost > 96% chlorophyll a + b; leaves from plants containing a staygreen mutation introgressed from Festuca pratensis, which has a lesion in the senescence-associated fragmentation of pigment-proteolipid complexes, retained over 43% of total chlorophyll over the same period. * Mutant segments preferentially retained thylakoid membrane proteins (exemplified by LHCP II) but lost other cellular proteins at the same rate as wild-type tissue. The protein synthesis inhibitor D-MDMP inhibited chlorophyll degradation and partially prevented protein loss in both genotypes, but tissues treated with the ineffective L-stereoisomer were indistinguishable from water controls. * Principal-components analysis of leaf reflectance spectra distinguished between genotypes, time points and D-MDMP treatments, showing the disruption of pigment metabolism during senescence brought about by the staygreen mutation, by inhibition of protein synthesis and by combinations of the two factors. * The build-up of oxidized, dephytylated and phaeo-derivatives of chl a during senescence of staygreen tissue was prevented by D-MDMP and associated with characteristic difference spectra when senescent mutant tissue was compared with wild-type or inhibitor-treated samples. The suitability of senescence as a subject for systems biology approaches is discussed.     

Changes in the synthesis of rubisco in rice leaves in relation to senescence and N influx

BACKGROUND AND AIMS: The amount of ribulose-1,5-bisphosphate carboxylase/oxygenase (Rubisco, EC 4.1.1.39) synthesized in a leaf is closely correlated with N influx into the leaf throughout its lifetime. Rubisco synthesis and N influx are most active in the young leaf during expansion, but are very limited in the senescent leaf. However, it is not established whether Rubisco synthesis can be observed if N influx is increased, even in a very senescent leaf. This study first investigated changes in the relationships between rbcS and rbcL mRNA contents and Rubisco synthesis per unit of leaf mass with leaf senescence. Next, leaves were removed during late senescence, to examine whether Rubisco synthesis is re-stimulated in very senescent leaves by an increase in N influx. METHODS: Different N concentrations (1 and 4 mm) were supplied to Oryza sativa plants at the early (full expansion), middle and late stages (respectively 8 and 16 d after full expansion) of senescence of the eighth leaf. To enhance N influx into the eighth leaf 16 d after full expansion, all leaf blades on the main stem, except for the eighth leaf, and all tillers were removed and plants received 4 mm N (removal treatment). KEY RESULTS: Rubisco synthesis, rbcS and rbcL mRNAs and the translational efficiencies of rbcS and rbcL mRNAs decreased with leaf senescence irrespective of N treatments. However, in the removal treatment at the late stage, they increased more strongly with an increase in N influx than in intact plants. CONCLUSIONS: Although Rubisco synthesis and rbcS and rbcL mRNAs decrease with leaf senescence, leaves at the late stage of senescence have the potential actively to synthesize Rubisco with an increase in N influx.     

Study of early leaf senescence in Arabidopsis thaliana by quantitative proteomics using reciprocal 14N/15N labeling and difference gel electrophoresis

Leaf senescence represents the final stage of leaf development and is associated with fundamental changes on the level of the proteome. For the quantitative analysis of changes in protein abundance related to early leaf senescence, we designed an elaborate double and reverse labeling strategy simultaneously employing fluorescent two-dimensional DIGE as well as metabolic (15)N labeling followed by MS. Reciprocal (14)N/(15)N labeling of entire Arabidopsis thaliana plants showed that full incorporation of (15)N into the proteins of the plant did not cause any adverse effects on development and protein expression. A direct comparison of DIGE and (15)N labeling combined with MS showed that results obtained by both quantification methods correlated well for proteins showing low to moderate regulation factors. Nano HPLC/ESI-MS/MS analysis of 21 protein spots that consistently exhibited abundance differences in nine biological replicates based on both DIGE and MS resulted in the identification of 13 distinct proteins and protein subunits that showed significant regulation in Arabidopsis mutant plants displaying advanced leaf senescence. Ribulose 1,5-bisphosphate carboxylase/oxygenase large and three of its four small subunits were found to be down-regulated, which reflects the degradation of the photosynthetic machinery during leaf senescence. Among the proteins showing higher abundance in mutant plants were several members of the glutathione S-transferase family class phi and quinone reductase. Up-regulation of these proteins fits well into the context of leaf senescence since they are generally involved in the protection of plant cells against reactive oxygen species which are increasingly generated by lipid degradation during leaf senescence. With the exception of one glutathione S-transferase isoform, none of these proteins has been linked to leaf senescence before.     

Chloroplast polypeptides synthesized by leaf segments and isolated chloroplasts during senescence in barley.

Starting from senescent barley (Hordeum vulgare L. cv Hassan) leaf segments receiving light and hormone treatments affecting senescence, the plastid polypeptides synthesized by isolated chloroplasts and by leaf segments were analyzed by radiolabelling followed SDS-PAGE and fluorography. Among 20 to 30 polypeptides detected, a few were specifically synthesized (by chloroplasts and/or leaf segments) after each senescence treatment. Apparently, the polypeptides labelled in assays with isolated chloroplasts are truly synthesized in vivo, because most of them were also labelled in assays with leaf segments. The comparison of polypeptide profiles, for every senescence treatment, after labelling with isolated chloroplasts or leaf segments, suggests that most plastid polypeptides synthesized during senescence are coded in plastid DNA.     

Rubiscolytics: fate of Rubisco after its enzymatic function in a cell is terminated

Ribulose-1,5-bisphosphate carboxylase/oxygenase (Rubisco) is the predominant protein in photosynthesizing plant parts and the most abundant protein on earth. Amino acids deriving from its net degradation during senescence are transported to sinks (e.g. developing leaves, fruits). Rubisco catabolism is not controlled only by the overall sink demand. An accumulation of carbohydrates may also accelerate senescence and Rubisco degradation under certain conditions. Amino acids produced by proteolysis are rapidly redistributed in plants with proper source-sink relationships. In leaves of wheat plants with reduced sink capacity (e.g. sink removal, phloem interruption by steam girdling at the leaf base), Rubisco is degraded and free amino acids accumulate. They may be washed out in the rain during late senescence. In leaves of depodded soybeans, Rubisco is degraded and amino acids can be reutilized in these leaves for the synthesis of special vacuolar proteins in the paraveinal mesophyll (vegetative storage proteins). Nitrogen deriving from Rubisco degradation in older (senescing) leaves of annual crops is integrated to some extent again in newly synthesized Rubisco in younger leaves or photosynthesizing tissues of fruits. Finally, a high percentage of this nitrogen is accumulated in protein bodies (storage proteins). At the subcellular level, Rubisco can be degraded in intact chloroplasts. Reactive oxygen species may directly cleave the large subunit or modify it to become more susceptible to proteolysis. A metalloendopeptidase may play an important role in Rubisco degradation within intact chloroplasts. Additionally, the involvement of vacuolar endopeptidase(s) in Rubisco catabolism (at least under certain conditions) was postulated by various laboratories.     

Effects of growth regulators and light on chloroplasts NAD(P)H dehydrogenase activities of senescent barley leaves

The activities NADH and NADPH dehydrogenases were measured with ferricyanide as electron-acceptor (NADH-FeCN-ox and NADPH-FeCN-ox, respectively) in mitochondria-free chloroplasts of barley leaf segments after receiving various treatments affecting senescence. NADPH-FeCN-ox declined during senescence in the dark, in a way similar to chlorophyll and Hill reaction, and increased when leaf segments were incubated at light. These results suggest that NADPH-FeCN-ox is related to some photosynthetic electron transporter activity (probably ferredoxin-NADP⁺ oxidoreductase). In contrast, NADH-FeCN-ox is notably stable during senescence in the dark and at light. This activity increased during incubation with kinetin or methyl-jasmonate (Me-JA) but decreased when leaf segments were treated with abscisic acid (ABA). The effects of the inhibitors of protein synthesis cycloheximide and chloramphenicol suggest that the changes of NAD(P)H dehydrogenase activities may depend on protein synthesis in chloroplasts. In senescent leaf, chloroplast NADH dehydrogenase might be a way to dissipate NADH produced in the degradation of excess carbon which is released from the degradation of amino acids.Abbreviations ABA abscisic acid - DCPIP 2,6-dichlorophenol-indo-phenol - DOC deoxycholate - Me-JA methyl jasmonate - NADH-FeCN-ox NADH ferricyanide oxidoreductase - NADPH-FeCN-ox NADPH ferricyanide oxidoreductase     

Altered protein synthesis during in situ oat leaf senescence

Quantitative and qualitative changes in protein synthesis during in situ senescence of oat ( Avena saliva L. cv. Victory) leaf have been examined. The rate of protein synthesis shows a transitory increase during early stages of senescence. This increase is not accompanied by a corresponding increase in amino acid uptake and is smaller when expressed on a dry weight rather than a protein basis. Total protein, total RNA and poly(A)⁺-RNA decline rapidly during senescence. Analysis of protein populations with 2-D SDS-PAGE shows that while some proteins decline sharply during leaf senescence, the synthesis of several others is induced or enhanced. Synthesis of new proteins shown in this study may explain the reported requriement for protein synthesis in leaf senescence.     

Influence of senescence and of carbohydrate levels on the pattern of leaf proteases in purple nutsedge (Cyperus rotundus)

Cyperus rotundus L. is a monocotyledonous perennial weed, which forms large numbers of tubers during its vegetative growth. Since these tubers represent major sinks, source/sink interactions are more complex, and leaf senescence and proteolytic processes in this species may be different from the situation in the well‐investigated annual crop plants characterized by monocarpic senescence. Judged by native PAGE and by inhibitor studies, three different aminopeptidases, one iminopeptidase, two or more carboxypeptidases and two or more different endopeptidases were present in mature green leaves. Exo‐ and endoproteolytic activities increased during the senescence of excised leaf segments. A marked change was observed in the endopeptidase pattern, since a cysteine proteinase activity was strongly induced during senescence of the segments. This endopeptidase was also found in naturally senescing leaves and may, therefore, participate in nitrogen salvage from these organs. An increase of different protease activities was demonstrated in leaf segments of C. rotundus in the presence of high carbohydrate levels. The mechanisms involved, and the importance of this phenomenon for the interaction between source/sink relations and senescence, remain to be demonstrated.     

Increased Proteolysis of Senescing Rice Leaves in the Presence of NaCl and KCl

NaCl and KCl enhanced the degradation of chlorophylls and proteins in detached rice (Oryza sativa) leaves in a concentration-dependent manner. Ribulose-1,5-bisphosphate carboxylase/oxygenase (Rubisco) accounted for 73 to 80% of the protein lost by day 4 in the light. NaCl at 50 millimolar increased proteolysis by 21% over the control in 4 days, but the addition of cycloheximide reduced the increase to about one-half. Cycloheximide alone had no effect on proteolytic activity during this period. Leaf segments taken from 10-day-old seedlings contained the highest proteolytic activity. Both NaCl and KCl increased the activity of Rubisco-degrading endoproteinases (the amount of ninhydrin-positive compounds measured from HCl-hydrolyzates of trichloroacetic acid-soluble supernatant), but decreased the activity of hemoglobin- and Rubisco-degrading exoproteinases (the amount of ninhydrin-positive compounds measured directly from trichloroacetic acid-soluble supernatant). Efflux of amino acids from senescing leaf segments into the incubation media increased 7- and 12-fold in the presence of KCl and NaCl, respectively. The increased efflux resulted in a negative correlation between salt concentration and amino acid content of leaf segments at the later stage of senescence. It is concluded that, in addition to the induction of new proteinase synthesis, the increased efflux of protein hydrolyzates may play a significant role in increasing proteolysis of salt-treated leaves, especially at the later stages of senescence.     

Leaf senescence is accompanied by an early disruption of the microtubule network in Arabidopsis

The dynamic assembly and disassembly of microtubules (MTs) is essential for cell function. Although leaf senescence is a well-documented process, the role of the MT cytoskeleton during senescence in plants remains unknown. Here, we show that both natural leaf senescence and senescence of individually darkened Arabidopsis (Arabidopsis thaliana) leaves are accompanied by early degradation of the MT network in epidermis and mesophyll cells, whereas guard cells, which do not senesce, retain their MT network. Similarly, entirely darkened plants, which do not senesce, retain their MT network. While genes encoding the tubulin subunits and the bundling/stabilizing MT-associated proteins (MAPs) MAP65 and MAP70-1 were repressed in both natural senescence and dark-induced senescence, we found strong induction of the gene encoding the MT-destabilizing protein MAP18. However, induction of MAP18 gene expression was also observed in leaves from entirely darkened plants, showing that its expression is not sufficient to induce MT disassembly and is more likely to be part of a Ca(2+)-dependent signaling mechanism. Similarly, genes encoding the MT-severing protein katanin p60 and two of the four putative regulatory katanin p80s were repressed in the dark, but their expression did not correlate with degradation of the MT network during leaf senescence. Taken together, these results highlight the earliness of the degradation of the cortical MT array during leaf senescence and lead us to propose a model in which suppression of tubulin and MAP genes together with induction of MAP18 play key roles in MT disassembly during senescence.     

Effects of low temperature, high salinity and exogenous ABA on the synthesis of two chloroplastic drought-induced proteins in Solanum tuberosum

Two chloroplastic proteins of 32 and 34 kDa were previously shown to be substantially synthesized in response to a progressive water deficit in whole Solanum tuberosum plants (G. Pruvot, S. Cuiné, N. Gault, G. Peltier and P. Rey, unpublished data; G. Pruvot, S. Cuiné, G. Peltier and P. Rey. 1996. Planta 198: 471–479). These chloroplastic drought-induced stress proteins, named CDSP 32 and CDSP 34, accumulated in the stroma and in the thylakoids, respectively. In this study, we investigated the effects of low temperature and high salinity on the synthesis of the CDSP proteins. Whereas the CDSP 32 synthesis was not modified in response to a cold treatment, an increased synthesis of CDSP 32 was observed in salt-stressed plants, resulting in accumulation of the protein. The thylakoid CDSP 34 protein exhibited enhanced synthesis and substantial accumulation in response to cold and high salinity. A significant increase in the leaf abscisic acid content (at least 2.5-fold) was measured in plants subjected to water deficit, high salinity or low temperature. The contribution of ABA to the synthesis of the two proteins was investigated by spraying well-watered plants with a 100 μ M / ABA solution for 15 days. This treatment resulted in a 15-fold increase in the leaf ABA content. Whereas synthesis of the CDSP 32 protein was not affected by exogenous ABA, synthesis of the CDSP 34 protein was substantially enhanced. Based on these results, we conclude that ABA likely mediates the increased synthesis of CDSP 34 upon drought, low temperature and high salinity and suggest that another signal, likely related to high osmolarity, is involved in the induction of CDSP 32 synthesis.     

Chloroplast Protein Synthesis During Barley Leaf Growth and Senescence: Effect of Leaf Excision

Chloroplast protein synthesis was measured during the expansion,maturity and senescence of the oldest leaf of barley, Hordeumvulgare L., var. Hassan. A maximum rate of protein synthesisoccurred near the end of the expansion stage 9 d after sowing.Protein synthesis increased again at the beginning of senescenceand reached a new maximum at day 14 after sowing. Detachmentand incubation of leaves in the dark stimulated chioroplastprotein synthesis by fully expanded or by senescent leaves butnot by expanding leaves. If the detached leaves were kept inthe light, chloroplast protein synthesis was stimulated in fullyexpanded but not in senescent leaves. Short treatments (18 h)of leaf segments with growth substances in either light or indarkness, significantly changed the rate of protein synthesisshown by chloroplasts. The relationship between chloroplastprotein synthesis and leaf senescence is discussed. Key words: Hormones, light, maturity     

Thigmomorphogenesis: XXIII. Promotion of foliar senescence by mechanical perturbation of Avena sativa and four other species

Mechanical perturbation (MP, gentle tubbing) promoted the senescence of detached oat ( Avena sativa L. cv. Victory) leaf segments in the dark. The promotion of senescence increased with increase in the number of rubbings and could be seen after 24 h of dark incubation; the maximum effect was reached on day 3. The effect (% of control) of MP on the loss of protein was greater than the effect on chlorophyll (Chl) loss on day 1. However, on day 3 the effect of MP on the loss of Chl became greater than the effect on the loss of protein. Ethephon and 1-aminocyclopropane-1-carboxylic acid (ACC) marginally promoted the loss of Chl by both control and rubbed oat leaf segments, and the effect was additive with MP. Chloramphenicol (CAP), spermine, aminoethoxyvinylglycine (AVG) and Ca²⁺ marginally delayed the loss of Chl and protein in both control and rubbed segments. Kinetin greatly retarded the senescence of all segments. Even in the presence of these substances, the amounts of Chl and protein in the rubbed segments were always less than in their respective controls, thus retaining the effect of the MP. However, abscisic acid (ABA) and cycloheximide (CHI) caused the rubbed oat leaf segments to retain more Chl and protein than their respective control segments. The effect of CHI was actually enhanced by MP. Rubbing promoted the senescence of attached leaves of oats ( Avena sativa L. cv. Victory), maize ( Zea mays L. cv. Early Belle) and pumpkin ( Cucurbita pepo L. cv. Jack-o-lantern) cotyledons in the dark. Rubbing promoted the senescence of oat leaf segments even in light, although to a lesser extent compared to the effect in the dark. The senescence of leaves of pumpkin and cocklebur ( Xanthium strumarium Wallr. var. Pennsylvanicum ) in situ was also enhanced by MP.     

The proteomics of senescence in leaves of white clover,Trifolium repens (L.)

A proteomics approach has been used to study changes in protein abundance during leaf senescence in white clover. Changes in cell ultrastructure were also examined using transmission electron microscopy. The most obvious ultrastructural changes during senescence occurred in chloroplasts, with progressive loss of thylakoid integrity and accumulation of osmiophilic globules in the stroma. Quantitative analysis of 590 leaf protein spots separated by two-dimensional electrophoresis indicated that approximately 40% of the spots showed significant senescence related changes in abundance. Approximately one-third of the protein spots present in mature green leaves were also visible by two-dimensional electrophoresis of an isolated chloroplast fraction, and these spots represented a major proportion of the proteins showing senescence related declines in abundance. Chloroplast proteins that were identified by matrix-assisted laser desorption/ionization-time of flight mass fingerprinting included rubisco large and small subunits, a rubisco activase and the 33 kDa protein of the photosystem II oxygen-evolving complex. These proteins declined in abundance late in senescence, indicating that the photosynthetic apparatus was being degraded. A chloroplast glutamine synthetase showed partial decline in abundance during late senescence but was maintained at levels that may support provision of glutamine for export to other tissues. The results emphasise the importance of proteolysis, chloroplast degradation and remobilisation of nitrogen in leaf senescence.     

A combined 15N tracing/proteomics study in Brassica napus reveals the chronology of proteomics events associated with N remobilisation during leaf senescence induced by nitrate limitation or starvation

Our goal was to identify the leaf proteomic changes which appeared during N remobilisation that were associated or not associated with senescence of oilseed rape in response to contrasting nitrate availability. Remobilisation of N and leaf senescence status were followed using ¹⁵N tracing, patterns of chlorophyll level, total protein content and a molecular indicator based on expression of senescence‐associated gene 12/Cab genes. Three phases associated with N remobilisation were distinguished. Proteomics revealed that 55 proteins involved in metabolism, energy, detoxification, stress response, proteolysis and protein folding, were significantly induced during N remobilisation. Four proteases were specifically identified. FtsH, a chloroplastic protease, was induced transiently during the early stages of N remobilisation. Considering the dynamics of N remobilisation, chlorophyll and protein content, the pattern of FtsH expression indicated that this protease could be involved in the degradation of chloroplastic proteins. Aspartic protease increased at the beginning of senescence and was maintained at a high level, implicating this protease in proteolysis during the course of leaf senescence. Two proteases, proteasome beta subunit A1 and senescence‐associated gene 12, were induced and continued to increase during the later phase of senescence, suggesting that these proteases are more specifically involved in the proteolysis processes occurring at the final stages of leaf senescence.