Diana Laura Garza Amaya scite author profile

Aspartate transcarbamoylase (ATC) catalyzes the first committed step in pyrimidine de novo synthesis. As shown before, mutants with 80% reduced transcript and protein levels exhibit reduced levels of pyrimidine metabolites and thus nucleotide limitation and imbalance. Consequently, reduced photosynthetic capacity and growth, accompanied by massive transcriptional changes, were observed. Here, we show that nucleotide de novo synthesis was upregulated during cold acclimation of Arabidopsis thaliana (ecotype Columbia, Col-0) plants, but ATC knockdown mutants failed to acclimate to this condition as they did not accumulate neutral sugars and anthocyanins. A global transcriptome analysis revealed that most of the transcriptional changes observed in Col-0 plants upon cold exposure were also evident in ATC knockdown plants. However, several responses observed in cold-treated Col-0 plants could already be detected in knockdown plants when grown under standard conditions, suggesting that these mutants exhibited typical cold responses without prior cold stimulation. We believe that nucleotide signaling is involved in “cold-like priming” and “cold acclimation” in general. The observed transcript levels of genes involved in central carbon metabolism and respiration were an exception to these findings. These were upregulated in the cold but downregulated in warm-grown ATC mutants.

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Nucleotide limitation results in impaired photosynthesis, reduced growth and seed yield together with massively altered gene expression

Bellin

Melzer

Hilo

et al. 2021

Preprint

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De novo synthesis of pyrimidines is an essential and highly conserved pathway in all organisms. A peculiarity in plants is the localization of the first committed step, catalyzed by aspartate transcarbamoylase (ATC), in chloroplasts. By contrast, the third step in the pathway is catalyzed by dihydroorotate dehydrogenase (DHODH) localized in mitochondria in eukaryotes, including plants. To unravel pathway- and organelle specific functions, we analyzed knock-down mutants in ATC and DHODH in detail. ATC knock-downs were most severely affected, exhibiting low levels of pyrimidine metabolites, a low energy state, reduced photosynthetic capacity and accumulated reactive oxygen species (ROS). Furthermore, we observed altered leaf morphology and chloroplast ultrastructure in the mutants. Although less affected, DHODH knock-down mutants showed impaired seed germination and altered mitochondrial ultrastructure. Our results point to an integration of de novo pyrimidine synthesis and cellular energy states via photosynthesis and mitochondrial respiration. These findings highlight the likelihood of further regulatory roles for ATC and DHODH in pathways located in the corresponding organelles.ONE-SENTENCE SUMMARYImpaired pyrimidine nucleotide synthesis results in a low energy state, affecting photosynthesis and organellar ultrastructure, thus leading to reduced growth, reproduction, and seed yield

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Nucleotide Limitation Results in Impaired Photosynthesis, Reduced Growth and Seed Yield Together with Massively Altered Gene Expression

Bellin

Melzer

Hilo

et al. 2023

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Nucleotide limitation and imbalance is a well described phenomenon in animal research but understudied in the plant field. A peculiarity of pyrimidine de novo synthesis in plants is the complex subcellular organization. Here, we studied two organellar localized enzymes in the pathway, with chloroplast aspartate transcarbamoylase (ATC), and mitochondrial dihydroorotate dehydrogenase (DHODH). ATC knockdowns were most severely affected, exhibiting low levels of pyrimidine nucleotides, a low energy state, reduced photosynthetic capacity and accumulation of reactive oxygen species (ROS). Furthermore, altered leaf morphology and chloroplast ultrastructure were observed in ATC mutants. Although less affected, DHODH knockdown mutants showed impaired seed germination and altered mitochondrial ultrastructure. Thus, DHODH might not only be regulated by respiration, but vice versa exert a regulatory function on this process. Transcriptome analysis of an ATC-amiRNA line revealed massive alterations in gene expression with central metabolic pathways being downregulated and stress response and RNA related pathways being upregulated. In addition, genes involved in central carbon metabolism, intracellular transport and respiration were markedly downregulated in ATC mutants, being most likely responsible for the observed impaired growth. We conclude that impairment of the first committed step in pyrimidine metabolism, catalyzed by ATC, leads to nucleotide limitation and by this has far reaching consequences on metabolism and gene expression. DHODH might closely interact with mitochondrial respiration, as seen in delayed germination, being the reason for its localization in this organelle.

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Nickel and Cobalt Induced Toxicity in Paramecium: The Cellular View to Environmental Toxicants

Amaya

Thiel

Möller

et al. 2023

Preprint

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