Ubiquitylation activates a peptidase that promotes cleavage and destabilization of its activating E3 ligases and diverse growth regulatory proteins to limit cell proliferation in <i>Arabidopsis</i>

Dong, Hui; Dumenil, Jack; Lu, Fu; Ma, Lijiao; Vanhaeren, Hannes; Naumann, Christin; Klecker, Maria; Prior, Rachel; Smith, Caroline; McKenzie, Neil; Saalbach, Gerhard; Chen, Liangliang; Xia, Tian; González, Nathalie; Séguéla, Mathilde; Inzé, Dirk; Dißmeyer, Nico; Li, Yunhai; Bevan, Michael W.

doi:10.1101/gad.292235.116

Cited by 125 publications

(115 citation statements)

References 42 publications

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“…Family M102 (DA1 peptidase), omitting contaminants, is restricted to Streptophyta and had its origin presumably in the ancestor to that phylum. The DA1 peptidase is ubiquitin-dependent and degrades a deubiquitinating enzyme, and regulates cell proliferation [60]. Family N11 (intein-containing chloroplast ATPdependent peptide lyase) probably originated in the ancestor of chlorophytes, but homologues, presumably the result of horizontal gene transfers, are also found in some euryarchaeotes, bacteria, fungi and dsDNA viruses.…”

Section: Peptidase Families With An Origin In Plantsmentioning

confidence: 99%

Origins of peptidases

Rawlings

Bateman

2019

Biochimie

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a b s t r a c tThe distribution of all peptidase homologues across all phyla of organisms was analysed to determine within which kingdom each of the 271 families originated. No family was found to be ubiquitous and even peptidases thought to be essential for life, such as signal peptidase and methionyl aminopeptides are missing from some clades. There are 33 peptidase families common to archaea, bacteria and eukaryotes and are assumed to have originated in the last universal common ancestor (LUCA). These include peptidases with different catalytic types, exo-and endopeptidases, peptidases with different tertiary structures and peptidases from different families but with similar structures. This implies that the different catalytic types and structures pre-date LUCA. Other families have had their origins in the ancestors of viruses, archaea, bacteria, fungi, plants and animals, and a number of families have had their origins in the ancestors of particular phyla. The evolution of peptidases is compared to recent hypotheses about the evolution of organisms.

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Section: Peptidase Families With An Origin In Plantsmentioning

confidence: 99%

Origins of peptidases

Rawlings

Bateman

2019

Biochimie

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“…Recently, increasing evidence has indicated that the ubiquitin receptor DA1, a conserved component of the ubiquitin-proteasome pathway, has important functions in regulating seed size. In Arabidopsis thaliana, DA1 functions partially redundantly with one of its homologs, DA1-RELATED 1 (DAR1), to control seed size by restricting the period of cell proliferation in maternal integuments (Dong et al, 2017;Li et al, 2008). The dominant-negative mutant da1-1 carries a G-to-A mutation in DA1, causing an R-to-K change in the conserved amino acid at position 358 (DA1 R358K ).…”

Section: Introductionmentioning

confidence: 99%

“…In rapeseed (Brassica napus) and maize (Zea mays), the overexpression of a similar mutant form of DA1 or DAR1 homologs also improved their seed weights and organ sizes, thereby increasing the overall grain yield and biomass (Wang et al, 2017a;Xie et al, 2018). Furthermore, a loss-of-function T-DNA DA1 mutant (da1-ko1) in Arabidopsis also caused an increase in seed size, indicating that DA1 can be studied relatively independently of DAR1 in regulating seed size (Dong et al, 2017).…”

Section: Introductionmentioning

confidence: 99%

“…The RING finger-type E3 ubiquitin ligases BIG BROTHER (BB) and DA2 restrict organ growth (Disch et al, 2006;Xia et al, 2013) and function synergistically with DA1 in organ size determination (Li et al, 2008;Xia et al, 2013). A recent study showed that BB and DA2 ubiquitylate DA1 and activate its peptidase activity, and then activated DA1 cleaves and destabilizes BB and DA2 in a feedback mechanism (Dong et al, 2017). In addition, DA2 physically interacts with DA1, which may enable DA1 to recognize specific substrates for degradation (Xia et al, 2013).…”

Section: Introductionmentioning

confidence: 99%

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TaDA1, a conserved negative regulator of kernel size, has an additive effect with TaGW2 in common wheat (Triticum aestivum L.)

Hao

et al. 2019

Plant Biotechnology Journal

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Summary Kernel size is an important trait determining cereal yields. In this study, we cloned and characterized TaDA1, a conserved negative regulator of kernel size in wheat (Triticum aestivum). The overexpression of TaDA1 decreased the size and weight of wheat kernels, while its down‐regulation using RNA interference (RNAi) had the opposite effect. Three TaDA1‐A haplotypes were identified in Chinese wheat core collections, and a haplotype association analysis showed that TaDA1‐A‐HapI was significantly correlated with the production of larger kernels and higher kernel weights in modern Chinese cultivars. The haplotype effect resulted from a difference in TaDA1‐A expression levels between genotypes, with TaDA1‐A‐HapI resulting in lower TaDA1‐A expression levels. This favourable haplotype was found having been positively selected during wheat breeding over the last century. Furthermore, we demonstrated that TaDA1‐A physically interacts with TaGW2‐B. The additive effects of TaDA1‐A and TaGW2‐B on kernel weight were confirmed not only by the phenotypic enhancement arising from the simultaneous down‐regulation of TaDA1 and TaGW2 expression, but also by the combinational haplotype effects estimated from multi‐environment field data from 348 wheat cultivars. A comparative proteome analysis of developing transgenic and wild‐type grains indicated that TaDA1 and TaGW2 are involved in partially overlapping but relatively independent protein regulatory networks. Thus, we have identified an important gene controlling kernel size in wheat and determined its interaction with other genes regulating kernel weight, which could have beneficial applications in wheat breeding.

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“…The latest example of an N-end rule substrate identified using such information is that of the organ-size regulator BIG BROTHER, which is cleaved by the protease DA1 in Arabidopsis. The resulting C-terminal fragment then appears to be targeted for degradation by the N-recognin PRT1 (Dong et al, 2017). It is also worth noting that the recently discovered defensive functions of the Ac/ and Arg/N-end rule pathways are coherent with a potential role of defense-related plant proteases (including MetAPs) in generating N-end rule substrates.…”

Section: Met-pro Promentioning

confidence: 96%

Life and death of proteins after protease cleavage: protein degradation by the N‐end rule pathway

2017

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Contents Summary929I.Introduction: conservation and diversity of N‐end rule pathways929II.Defensive functions of the N‐end rule pathway in plants930III.Proteases and degradation by the N‐end rule pathway930IV.New proteomics approaches for the identification of N‐end rule substrates932V.Concluding remarks932Acknowledgements934References934 Summary The N‐end rule relates the stability of a protein to the identity of its N‐terminal residue and some of its modifications. Since its discovery in the 1980s, the repertoire of N‐terminal degradation signals has expanded, leading to a diversity of N‐end rule pathways. Although some of these newly discovered N‐end rule pathways remain largely unexplored in plants, recent discoveries have highlighted roles of N‐end rule‐mediated protein degradation in plant defense against pathogens and in cell proliferation during organ growth. Despite this progress, a bottleneck remains the proteome‐wide identification of N‐end rule substrates due to the prerequisite for endoproteolytic cleavage and technical limitations. Here, we discuss the recent diversification of N‐end rule pathways and their newly discovered functions in plant defenses, stressing the role of proteases. We expect that novel proteomics techniques (N‐terminomics) will be essential for substrate identification. We review these methods, their limitations and future developments.

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Ubiquitylation activates a peptidase that promotes cleavage and destabilization of its activating E3 ligases and diverse growth regulatory proteins to limit cell proliferation in Arabidopsis

Cited by 125 publications

References 42 publications

Origins of peptidases

Origins of peptidases

TaDA1, a conserved negative regulator of kernel size, has an additive effect with TaGW2 in common wheat (Triticum aestivum L.)

Life and death of proteins after protease cleavage: protein degradation by the N‐end rule pathway

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