Differential Effects of Methyl Jasmonate on the Expression of the Early Light-Inducible Proteins and Other Light-Regulated Genes in Barley

Wierstra, Inken; Kloppstech, Klaus

doi:10.1104/pp.124.2.833

Cited by 50 publications

(27 citation statements)

References 66 publications

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Section: Resultsmentioning

confidence: 99%

“…However, we cannot rule out that other biochemical factors associated with the thylakoid membranes are responsible for the death of triple mutant plants grown at high temperature. On this line, linolenic acid is a precursor of jasmonic acid that is involved in many plant responses [29,30].The nature of the effects seems also to depend on a specific species that is deficient rather than through the mediation of global changes in membrane fluidity or integrity in the mutant. Approximately one-third of trienoic fatty acids is sufficient to maintain normal photosynthetic function and growth at either lower or higher than normal temperatures.…”

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Trienoic fatty acids and plant tolerance of temperature

Routaboul¹,

Browse²

2002

OCL

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Résumé : Les membranes des chloroplastes, siège de la photosynthèse, sont très riches en acides gras tri-insaturés. La proportion de ces acides gras dans les membranes végétales peut être modifiée lors de changements de température. Pour cette raison, il a été postulé que ces acides gras sont impliqués dans les mécanismes de résistance à la chaleur ou au froid des fonctions membranaires, en particulier de la photosynthèse qui est une des fonctions de la cellule les plus sensibles à la température. Afin de tester cette hypothèse, nous avons obtenu un triple mutant d'Arabidopsis qui ne contient pas d'acides gras tri-insaturés et mesuré les effets de la température sur cette lignée. Nous montrons que les acides gras tri-insaturés ne sont pas nécessaires pour la croissance et la photosynthèse dans des conditions normales de température et de lumière. En revanche, ils sont importants pour assurer la biogenèse et le maintien des chloroplastes de plantes cultivées à 4 °C, ou pour la survie de la plante cultivée à 33 °C. La présence de seulement un tiers de ces acides gras est suffisante au maintien d'une croissance et d'une photosynthèse normale si la plante est transférée à une température en dessus ou au-dessous de la normale.Mots-clés : résistance au froid, thermorésistance, acides gras, lipides, photosynthèse. Summary :The biophysical reactions of light harvesting and electron transport during photosynthesis take place in a uniquely constructed bilayer, the thylakoid. In all photosynthetic eukaryotes, the complement of atypical glycerolipid molecules that form the foundation of this membrane are characterised by sugar head-groups and a very high level of unsaturation in the fatty acids that occupy the central portion of the thylakoid bilayer. alpha-linolenic (18:3) or a combination of 18:3 and hexadecatrienoic (16:3) acids typically account for approximately two-thirds of all thylakoid membrane fatty acids and over 90% of the fatty acids of monogalactosyl diacylglycerol, the major thylakoid lipid [1,2]. The occurrence of trienoic fatty acids as a major component of the thylakoid membrane is especially remarkable since these fatty acids form highly reactive targets for active oxygen species and free radicals, which are often the by-products of oxygenic photosynthesis. Photosynthesis is one of the most temperature-sensitive functions of plant [3,4]. There remains a widespread belief that these trienoic fatty acids might have some crucial role in plants to be of such universal occurrence, especially in photosynthesis tolerance of temperature [5].Article disponible sur le site http://www.ocl-journal.org ou http://dx.doi.org/10.1051/ocl.2002.0000 ARTICLE Do plants adapt to temperature by changing the fatty acid composition of their membrane lipids?In some desert and evergreen plants, the proportion of trienoic fatty acids in the membrane glycerolipids decreases when plants acclimate to high temperatures [6]. Conversely, cold acclimation in higher plants induces increases in trienoic fatty acid level in leaves [7]. These...

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Section: Resultsmentioning

confidence: 99%

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confidence: 99%

Trienoic fatty acids and plant tolerance of temperature

Routaboul¹,

Browse²

2002

OCL

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“…However, no relation between ELIPs and dormancy or germination has been reported. ELIPs have also been shown to be induced by heat shock in Arabidopsis (Harari-Steinberg et al, 2001) and to be repressed by jasmonates in barley in a light-independent manner (Wierstra and Kloppstech, 2000). The light-regulated pathway that controls the expression of ELIPs must be different from the pathway that regulates HvNCED1, since HvNCED1 is not regulated by after-ripening.…”

Section: Light Sensitivity and After-ripeningmentioning

confidence: 99%

Anatomical and Transcriptomic Studies of the Coleorhiza Reveal the Importance of This Tissue in Regulating Dormancy in Barley

et al. 2009

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The decay of seed dormancy during after-ripening is not well understood, but elucidation of the mechanisms involved may be important for developing strategies for modifying dormancy in crop species and, for example, addressing the problem of preharvest sprouting in cereals. We have studied the germination characteristics of barley (Hordeum vulgare 'Betzes') embryos, including a description of anatomical changes in the coleorhiza and the enclosed seminal roots. The changes that occur correlate with abscisic acid (ABA) contents of embryo tissues. To understand the molecular mechanisms involved in dormancy loss, we compared the transcriptome of dormant and after-ripened barley embryos using a tissue-specific microarray approach. Our results indicate that in the coleorhiza, ABA catabolism is promoted and ABA sensitivity is reduced and that this is associated with differential regulation by after-ripening of ABA 8#-hydroxylase and of the LIPID PHOSPHATE PHOSPHA-TASE gene family and ABI3-INTERACTING PROTEIN2, respectively. We also identified other processes, including jasmonate responses, cell wall modification, nitrate and nitrite reduction, mRNA stability, and blue light sensitivity, that were affected by after-ripening in the coleorhiza that may be downstream of ABA signaling. Based on these results, we propose that the coleorhiza plays a major role in causing dormancy by acting as a barrier to root emergence and that after-ripening potentiates molecular changes related to ABA metabolism and sensitivity that ultimately lead to degradation of the coleorhiza, root emergence, and germination.

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“…(Potter and Kloppstech, 1993;Adamska and Kloppstech, 1994;Hutin et al, 2003;Bruno and Wetzel, 2004). In all cases these proteins were induced by light alone or in combination with other stresses such as high and low temperatures, drought and salinity (Kloppstech et al, 1991;Adamska and Kloppstech, 1994;Zeng et al., 2002) and also by factors such as the stage of plant development, senescence (Binyamin et al, 2001;Norén et al, 2003), light quality (Sävenstrand et al, 2004) or hormonal action (Wiestra and Kloppstech, 2000). In perennial plants ELIPs studies are scarce (Bhalerao et al, 2003;Peng et al, 2008).…”

Section: Abstract: Photoinhibition Elips Induction Abiotic Stressmentioning

confidence: 99%

Expression of Early Light Induced Protein in Grapevine and Pea, under Different Conditions and Itis Relation with Photoinhibition

Berti

Pinto

2012

Chilean J. Agric. Res.

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Early light induced proteins (ELIP) are a type of proteins which are expressed before than other chloroplast proteins in the presence of light. These proteins have been studied in a large number of annual species such as pea (Pisum sativum L.), barley (Hordeum vulgare L.) and Arabidopsis sp. In perennials plants the studies about ELIPs are very scarce. The possible photoprotective function of the ELIPs has motivated the interest in investigating the presence of this type of proteins in a perennial plant such as grapevine (Vitis vinifera L.) and if their characteristics differ from those found in annual plants. In this paper a comparative study was conducted on the ELIPs expression in grapevine and pea to investigate whether there are differences regarding to temperature and light intensity conditions necessary for maximum ELIP expression in each species and for studying in each case the relationship between ELIP expression and photoinhibition degree. The results of this study showed that the maximum ELIPs expression was reached from 25 ºC and 1000 µmol PAR m -2 s -1 in both species. Above these values the expression remained constant. Regarding the temperature and light intensity effect on the photoinhibition degree, it was observed that temperature produced inverse relation in grapevine but no relation with pea. On the other hand, the light intensity produced direct relation in both grapevine and pea. The light intensity effect on ELIP expression suggests that these proteins may have a photorepairing role of the photosynthetic system, but the effect of temperature on the ELIP expression in short-term stress may be associated rather to the optimum conditions for their synthesis.

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Differential Effects of Methyl Jasmonate on the Expression of the Early Light-Inducible Proteins and Other Light-Regulated Genes in Barley

Cited by 50 publications

References 66 publications

Trienoic fatty acids and plant tolerance of temperature

Trienoic fatty acids and plant tolerance of temperature

Anatomical and Transcriptomic Studies of the Coleorhiza Reveal the Importance of This Tissue in Regulating Dormancy in Barley

Expression of Early Light Induced Protein in Grapevine and Pea, under Different Conditions and Itis Relation with Photoinhibition

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