Enhanced Photosynthetic Performance and Growth as a Consequence of Decreasing Mitochondrial Malate Dehydrogenase Activity in Transgenic Tomato Plants

Nunes‐Nesi, Adriano; Carrari, Fernando; Lytovchenko, Anna; Smith, Anna M.O.; Loureiro, Marcelo Ehlers; Ratcliffe, George; Sweetlove, Lee J.; Fernie, Alisdair R.

doi:10.1104/pp.104.055566

Cited by 319 publications

(362 citation statements)

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“…Plants were handled as described in the literature (Carrari et al, 2003;Nunes-Nesi et al, 2005). For the drought stress treatments, well-watered 7-week-old flowering tomato plants were used.…”

Section: Methodsmentioning

confidence: 99%

RNA Interference of LIN5 in Tomato Confirms Its Role in Controlling Brix Content, Uncovers the Influence of Sugars on the Levels of Fruit Hormones, and Demonstrates the Importance of Sucrose Cleavage for Normal Fruit Development and Fertility

et al. 2009

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It has been previously demonstrated, utilizing intraspecific introgression lines, that Lycopersicum Invertase5 (LIN5), which encodes a cell wall invertase, controls total soluble solids content in tomato (Solanum lycopersicum). The physiological role of this protein, however, has not yet been directly studied, since evaluation of data obtained from the introgression lines is complicated by the fact that they additionally harbor many other wild species alleles. To allow a more precise comparison, we generated transgenic tomato in which we silenced the expression of LIN5 using the RNA interference approach. The transformants were characterized by an altered flower and fruit morphology, displaying increased numbers of petals and sepals per flower, an increased rate of fruit abortion, and a reduction in fruit size. Evaluation of the mature fruit revealed that the transformants were characterized by a reduction of seed number per plant. Furthermore, detailed physiological analysis revealed that the transformants displayed aberrant pollen morphology and a reduction in the rate of pollen tube elongation. Metabolite profiling of ovaries and green and red fruit revealed that metabolic changes in the transformants were largely confined to sugar metabolism, whereas transcript and hormone profiling revealed broad changes both in the hormones themselves and in transcripts encoding their biosynthetic enzymes and response elements. These results are discussed in the context of current understanding of the role of sugar during the development of tomato fruit, with particular focus given to its impact on hormone levels and organ morphology.The importance of the supply to, and the subsequent mobilization of Suc in, plant heterotrophic organs has been the subject of intensive research effort over many

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Section: Methodsmentioning

confidence: 99%

RNA Interference of LIN5 in Tomato Confirms Its Role in Controlling Brix Content, Uncovers the Influence of Sugars on the Levels of Fruit Hormones, and Demonstrates the Importance of Sucrose Cleavage for Normal Fruit Development and Fertility

et al. 2009

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“…These studies as well as those aimed at assessing the individual functions of various enymes participating in malate metabolism including the function of various isoforms of malate dehydrogenase (Nunes-Nesi et al, 2005;Cousins et al, 2008;Timm et al, 2008;Backhausen, 1998), malic enzyme (Fahenstich et al, 2007;Maurino et al, 2009) and fumarase , and further transporter proteins such as the proton dissipating uncoupling protein , have recently both confirmed and enhanced our knowledge in this area. Important findings of these recent studies were (i) the confirmation of the role of the mitochondria in optimising the rate of photosynthesis, (ii) the demonstration that the peroxisomal malate dehydrogenase is not essential for photorespiration (Cousins et al, 2008;Timm et al, 2008), although it is required to ensure optimal rates of photosynthesis, (iii) plants deficient in the expression of the chloroplastic malate dehydrogenase as well as those deficient in the expression of the mitochondrial uncoupling protein UCP1 provide convincing, although circumstantial, support for the operation of the malate valve, (iv) that malate (and fumarate) are required in considerable amount as respiratory substrate to stave off dark induced senescence and finally (v) that plants deficient in the expression of fumarase display altered stomatal function.…”

Section: Introductionmentioning

confidence: 91%

Malate. Jack of all trades or master of a few?

2009

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Malate. Jack of all trades or master of a few?Fernie, A R; Martinoia, E Fernie, A R; Martinoia, E (2009 Malate. Jack of all trades or master of a few? AbstractThe dicarboxylic acid malate has long been thought to play important roles in plant physiology. In addition to being a major photosynthate in C4 and CAM plants and an intermediate of the tricarboxylic acid cycle it has been proposed to play essential roles in pH regulation and important roles in pathogen response, as a component of the root exudates and as a regulatory osmolyte affecting stomatal function. Recent years have seen the cloning and functional analysis of a wide range of enzymes and transporters associated with malate metabolism. Here we attempt to provide a synthesis of research in this field as well as re-evaluating the role of this metabolite in mediating guard cell function. AbstractThe dicarboxylic acid malate has long been thought to play important roles in plant

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“…A wide range of mutant, antisense, or silenced plants with deficient expression of enzymes from the TCA cycle have been described, including citrate synthase (Landschü tze et al, 1995), aconitase (Carrari et al, 2003), malate dehydrogenase (Nunes-Nesi et al, 2005), fumarase , succinyl CoA ligase (Studart-Guimarães et al, 2007), and NAD + -dependent isocitrate dehydrogenase (Lemaitre et al, 2007). These studies have shown that modifications in the TCA cycle can modulate photosynthetic performance and, in the case of potato (Solanum tuberosum) citrate synthase, lead to a specific disintegration of the ovary tissues of flower.…”

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confidence: 99%

A Nuclear Gene Encoding the Iron-Sulfur Subunit of Mitochondrial Complex II Is Regulated by B3 Domain Transcription Factors during Seed Development in Arabidopsis

et al. 2009

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Mitochondrial complex II (succinate dehydrogenase) is part of the tricarboxylic acid cycle and the respiratory chain. Three nuclear genes encode its essential iron-sulfur subunit in Arabidopsis (Arabidopsis thaliana). One of them, SUCCINATE DEHYDROGENASE2-3 (SDH2-3), is specifically expressed in the embryo during seed maturation, suggesting that SDH2-3 may have a role as the complex II iron-sulfur subunit during embryo maturation and/or germination. Here, we present data demonstrating that three abscisic acid-responsive elements and one RY-like enhancer element, present in the SDH2-3 promoter, are involved in embryo-specific SDH2-3 transcriptional regulation. Furthermore, we show that ABSCISIC ACID INSENSI-TIVE3 (ABI3), FUSCA3 (FUS3), and LEAFY COTYLEDON2, three key B3 domain transcription factors involved in gene expression during seed maturation, control SDH2-3 expression. Whereas ABI3 and FUS3 interact with the RY element in the SDH2-3 promoter, the abscisic acid-responsive elements are shown to be a target for bZIP53, a member of the basic leucine zipper (bZIP) family of transcription factors. We show that group S1 bZIP53 protein binds the promoter as a heterodimer with group C bZIP10 or bZIP25. To the best of our knowledge, the SDH2-3 promoter is the first embryo-specific promoter characterized for a mitochondrial respiratory complex protein. Characterization of succinate dehydrogenase activity in embryos from two homozygous sdh2-3 mutant lines permits us to conclude that SDH2-3 is the major iron-sulfur subunit of mature embryo complex II. Finally, the absence of SDH2-3 in mutant seeds slows down their germination, pointing to a role of SDH2-3-containing complex II at an early step of germination.

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Enhanced Photosynthetic Performance and Growth as a Consequence of Decreasing Mitochondrial Malate Dehydrogenase Activity in Transgenic Tomato Plants

Cited by 319 publications

References 57 publications

RNA Interference of LIN5 in Tomato Confirms Its Role in Controlling Brix Content, Uncovers the Influence of Sugars on the Levels of Fruit Hormones, and Demonstrates the Importance of Sucrose Cleavage for Normal Fruit Development and Fertility

RNA Interference of LIN5 in Tomato Confirms Its Role in Controlling Brix Content, Uncovers the Influence of Sugars on the Levels of Fruit Hormones, and Demonstrates the Importance of Sucrose Cleavage for Normal Fruit Development and Fertility

Malate. Jack of all trades or master of a few?

A Nuclear Gene Encoding the Iron-Sulfur Subunit of Mitochondrial Complex II Is Regulated by B3 Domain Transcription Factors during Seed Development in Arabidopsis

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