Conserved N-terminal cysteine dioxygenases transduce responses to hypoxia in animals and plants

Masson, Norma; Keeley, Thomas P.; Giuntoli, Beatrice; White, Mark D.; Puerta, Mikel Lavilla; Perata, Pierdomenico; Hopkinson, Richard J.; Flashman, Emily; Licausi, Francesco; Ratcliffe, Peter J.

doi:10.1126/science.aaw0112

Cited by 157 publications

(188 citation statements)

References 31 publications

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“…Thus, cysteine dioxygenase enzymes, which are common in plants, have been characterized in mammalian tissues, and these nonheme iron-containing enzymes can oxidize N-terminal Cys residues to the sulfinic acid. Interestingly, these enzymes also contain an internal Cys-Tyr thioether cross-link, which markedly enhances the enzymatic activity (195). These enzymes are key regulators of hypoxia responses in both animals and plants (195).…”

Section: Detection and Quantification Of Productsmentioning

confidence: 99%

“…Interestingly, these enzymes also contain an internal Cys-Tyr thioether cross-link, which markedly enhances the enzymatic activity (195). These enzymes are key regulators of hypoxia responses in both animals and plants (195). Furthermore, there is abundant evidence for enzymatic Cys oxidation occurring by way of redox relays involving proteins with highly-reactive Cys residues, such as peroxiredoxins and STAT3, with initial oxidation of one protein by oxidants such as H 2 O 2 allowing subsequent oxidative transfer to target proteins in a controlled and specific manner.…”

Section: Detection and Quantification Of Productsmentioning

confidence: 99%

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Detection, identification, and quantification of oxidative protein modifications

Hawkins

Davies

2019

Journal of Biological Chemistry

265

184

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Edited by Ruma Banerjee Exposure of biological molecules to oxidants is inevitable and therefore commonplace. Oxidative stress in cells arises from both external agents and endogenous processes that generate reactive species, either purposely (e.g. during pathogen killing or enzymatic reactions) or accidentally (e.g. exposure to radiation, pollutants, drugs, or chemicals). As proteins are highly abundant and react rapidly with many oxidants, they are highly susceptible to, and major targets of, oxidative damage. This can result in changes to protein structure, function, and turnover and to loss or (occasional) gain of activity. Accumulation of oxidatively-modified proteins, due to either increased generation or decreased removal, has been associated with both aging and multiple diseases. Different oxidants generate a broad, and sometimes characteristic, spectrum of post-translational modifications. The kinetics (rates) of damage formation also vary dramatically. There is a pressing need for reliable and robust methods that can detect, identify, and quantify the products formed on amino acids, peptides, and proteins, especially in complex systems. This review summarizes several advances in our understanding of this complex chemistry and highlights methods that are available to detect oxidative modifications-at the amino acid, peptide, or protein level-and their nature, quantity, and position within a peptide sequence. Although considerable progress has been made in the development and application of new techniques, it is clear that further development is required to fully assess the relative importance of protein oxidation and to determine whether an oxidation is a cause, or merely a consequence, of injurious processes.

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Section: Detection and Quantification Of Productsmentioning

confidence: 99%

Section: Detection and Quantification Of Productsmentioning

confidence: 99%

Detection, identification, and quantification of oxidative protein modifications

Hawkins

Davies

2019

Journal of Biological Chemistry

265

184

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“…One observation of interest is that a number of Solanaceae rgsCaM proteins possess amino-terminal cysteine residues (Fig. S5) that are characteristic of proteins regulated by hypoxia through the N-degron pathway (Masson et al, 2019).…”

Section: Discussionmentioning

confidence: 99%

Regulator of Gene Silencing-Calmodulin associates with mRNA granules and the autophagy protein ATG8

Conner

Lokdarshi

Roberts

2019

Preprint

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“…The Arg/N‐degron pathway has a hierarchical structure that enzymatically funnels substrates to the N‐recognin by sequential alteration of tertiary to secondary destabilizing Nt‐residues, that are then arginylated to provide an N‐terminus with a primary destabilizing residue (Figure A). Eukaryotic tertiary destabilizing residues Gln and Asn can be converted to Glu and Asp by Nt‐Glu‐ (NTAQ1 (Wang et al )) or Nt‐Asn‐ (NTAN1 (Grigoryev et al )) amidohydrolases, respectively, (represented in Saccharomyces cerevisiae , hereafter yeast, by a single enzyme NTA1 (Baker and Varshavsky )) and Cys to Cys‐sulphinic acid by PLANT CYSTEINE OXIDASE (PCO) enzymes in plants (Weits et al ; White et al ) and an equivalent function in animals, cysteamine (2‐aminoethanethiol) dioxygenase (ADO) (Masson et al ). Secondary destabilizing residues can be Nt‐arginylated by ARGINYL‐tRNA TRANSFERASEs (ATEs) to deliver substrates with Nt‐Arg‐ (Manahan and App ).…”

Section: What Are N‐degron Pathways?mentioning

confidence: 99%

“…Importantly, the PCOs have K m app (O 2 ) values that are within a physiologically relevant range for response to external or internal oxygen deficit, indicating that they have the capacity to function as oxygen sensors for ecologically important variables, including flooding (White et al ). Following the identification of plant enzymes, an animal ADO enzyme with similar function in regulating mammalian Nt‐Cys substrates was identified (Masson et al ).…”

Section: Enzymatic Components Of Plant N‐degron Pathwaysmentioning

confidence: 99%

The plant N‐degron pathways of ubiquitin‐mediated proteolysis

Holdsworth

Vicente

Sharma

et al. 2019

JIPB

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The amino-terminal residue of a protein (or amino-terminus of a peptide following protease cleavage) can be an important determinant of its stability, through the Ubiquitin Proteasome System associated N-degron pathways. Plants contain a unique combination of N-degron pathways (previously called the N-end rule pathways) E3 ligases, PROTEOLYSIS (PRT)6 and PRT1, recognizing non-overlapping sets of amino-terminal residues, and others remain to be identified. Although only very few substrates of PRT1 or PRT6 have been identified, substrates of the oxygen and nitric oxide sensing branch of the PRT6 N-degron pathway include key nuclear-located transcription factors (ETHYLENE RESPONSE FACTOR VIIs and LITTLE ZIPPER 2) and the histone-modifying Polycomb Repressive Complex 2 component VERNALIZATION 2. In response to reduced oxygen or nitric oxide levels (and other mechanisms that reduce pathway activity) these stabilized substrates regulate diverse aspects of growth and development, including response to flooding, salinity, vernalization (cold-induced flowering) and shoot apical meristem function. The N-degron pathways show great promise for use in the improvement of crop performance and for biotechnological applications. Upstream proteases, components of the different pathways and associated substrates still remain to be identified and characterized to fully appreciate how regulation of protein stability through the amino-terminal residue impacts plant biology.

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Conserved N-terminal cysteine dioxygenases transduce responses to hypoxia in animals and plants

Cited by 157 publications

References 31 publications

Detection, identification, and quantification of oxidative protein modifications

Detection, identification, and quantification of oxidative protein modifications

Regulator of Gene Silencing-Calmodulin associates with mRNA granules and the autophagy protein ATG8

The plant N‐degron pathways of ubiquitin‐mediated proteolysis

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