Dissecting the Metabolic Role of Mitochondria during Developmental Leaf Senescence

Chrobok, Daria; Law, Simon R.; Brouwer, Bastiaan; Lindén, Pernilla; Ziółkowska, Agnieszka; Liebsch, Daniela; Narsai, Reena; Szal, Bożena; Moritz, Thomas; Rouhier, Nicolas; Whelan, James; Gardeström, Per; Keech, Olivier

doi:10.1104/pp.16.01463

Cited by 88 publications

(105 citation statements)

References 98 publications

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“…Metabolic changes during leaf senescence have been mainly investigated in Arabidopsis [11,13,32]. They showed many similar features to what we found here in barley, such as the accumulation of minor CHO and the decrease in most of the amino acids like glutamine, glutamate, aspartate, serine, glycine and arginine.…”

Section: Discussionsupporting

confidence: 50%

“…While pipecolate and α-aminoadipate decreased in primary leaves with senescence, they sharply accumulated in flag leaves with ageing, suggesting that lysine was used for mitochondria respiration in seedlings but not so much in the flag leaves. The anapleurotic respiration of amino acids has been mainly observed in Arabidopsis in response to dark stress [32,34,37] and Chrobok et al [32] showed that the whole metabolic pathway of lysine degradation was up-regulated in Arabidopsis individual darken leaves. It could then be possible that the differences of light environment between primary and flag leaves are the reason of these discrepancies and that lysine level could be related to both glutamate content and TCA replenishment.…”

Section: Discussionmentioning

confidence: 99%

“…It seems thus that the mitochondrial respiration is not affected in a similar manner by ageing at reproductive and vegetative stages. The maintenance of mitochondrial respiration during flag leaf senescence could explain that TCA compounds are poorly affected by ageing [32]. However, pipecolate and α-aminoadipate, which are both markers of the lysine anapleurotic respiratory pathway, increased during senescence in the flag leaf, suggesting a specific role of this pathway in flag leaf compared to seedling leaves [33,34].…”

Section: Senescence-associated Changes Occurring At the Reproductive mentioning

confidence: 99%

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Metabolite Profiling for Leaf Senescence in Barley Reveals Decreases in Amino Acids and Glycolysis Intermediates

2017

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Leaf senescence is a long developmental phase important for plant performance and nutrient management. Cell constituents are recycled in old leaves to provide nutrients that are redistributed to the sink organs. Up to now, metabolomic changes during leaf senescence have been mainly studied in Arabidopsis (Arabidopsis thaliana L.). The metabolite profiling conducted in barley (Hordeum vulgare L.) during primary leaf senescence under two nitrate regimes and in flag leaf shows that amino acids, hexose, sucrose and glycolysis intermediates decrease during senescence, while minor carbohydrates accumulate. Tricarboxylic acid (TCA) compounds changed with senescence only in primary leaves. The senescence-related metabolite changes in the flag leaf were globally similar to those observed in primary leaves. The effect of senescence on the metabolite changes of barley leaves was similar to that previously described in Arabidopsis except for sugars and glycolysis compounds. This suggests a different role of sugars in the control of leaf senescence in Arabidopsis and in barley.

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Section: Discussionsupporting

confidence: 50%

Section: Discussionmentioning

confidence: 99%

Section: Senescence-associated Changes Occurring At the Reproductive mentioning

confidence: 99%

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Metabolite Profiling for Leaf Senescence in Barley Reveals Decreases in Amino Acids and Glycolysis Intermediates

2017

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“…During leaf senescence in individually darkened leaves in Arabidopsis, the number of mitochondria decreases (Keech et al, 2007), probably by autophagy . The remaining mitochondria retain their motility and respiration activity until the last step of leaf senescence (Keech et al, 2007;Keech, 2011;Ruberti et al, 2014;Chrobok et al, 2016). These mitochondria are thought to provide energy and metabolites for degrading the cell components and relocating them to other younger parts of the plant (Keech et al, 2007;Keech, 2011;Ruberti et al, 2014;Chrobok et al, 2016).…”

Section: Other Factors Structures and Phenomena Related To Mitochonmentioning

confidence: 99%

Fission and Fusion of Plant Mitochondria, and Genome Maintenance

Arimura

2017

Plant Physiol.

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“…Other organelles, such as mitochondria and peroxisomes, remain active much longer and provide energy for the cell as well as take over a number of metabolic tasks during this process (Keech et al, 2007;Chrobok et al, 2016). While yeast and animals possess mitochondrial PPases (Lundin et al, 1991;Curbo et al, 2006), so far no mitochondrial PPase has been identified in plants.…”

mentioning

confidence: 99%

Triphosphate Tunnel Metalloenzyme Function in Senescence Highlights a Biological Diversification of This Protein Superfamily

et al. 2017

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ORCID IDs: 0000-0003-3889-6183 (W.M.); 0000-0002-3797-4277 (K.Y.).The triphosphate tunnel metalloenzyme (TTM) superfamily comprises a group of enzymes that hydrolyze organophosphate substrates. They exist in all domains of life, yet the biological role of most family members is unclear. Arabidopsis (Arabidopsis thaliana) encodes three TTM genes. We have previously reported that AtTTM2 displays pyrophosphatase activity and is involved in pathogen resistance. Here, we report the biochemical activity and biological function of AtTTM1 and diversification of the biological roles between AtTTM1 and 2. Biochemical analyses revealed that AtTTM1 displays pyrophosphatase activity similar to AtTTM2, making them the only TTMs characterized so far to act on a diphosphate substrate. However, knockout mutant analysis showed that AtTTM1 is not involved in pathogen resistance but rather in leaf senescence. AtTTM1 is transcriptionally up-regulated during leaf senescence, and knockout mutants of AtTTM1 exhibit delayed dark-induced and natural senescence. The double mutant of AtTTM1 and AtTTM2 did not show synergistic effects, further indicating the diversification of their biological function. However, promoter swap analyses revealed that they functionally can complement each other, and confocal microscopy revealed that both proteins are tail-anchored proteins that localize to the mitochondrial outer membrane. Additionally, transient overexpression of either gene in Nicotiana benthamiana induced senescence-like cell death upon dark treatment. Taken together, we show that two TTMs display the same biochemical properties but distinct biological functions that are governed by their transcriptional regulation. Moreover, this work reveals a possible connection of immunity-related programmed cell death and senescence through novel mitochondrial tail-anchored proteins.

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Dissecting the Metabolic Role of Mitochondria during Developmental Leaf Senescence

Cited by 88 publications

References 98 publications

Metabolite Profiling for Leaf Senescence in Barley Reveals Decreases in Amino Acids and Glycolysis Intermediates

Metabolite Profiling for Leaf Senescence in Barley Reveals Decreases in Amino Acids and Glycolysis Intermediates

Fission and Fusion of Plant Mitochondria, and Genome Maintenance

Triphosphate Tunnel Metalloenzyme Function in Senescence Highlights a Biological Diversification of This Protein Superfamily

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