Abstract

Regulation of protein stability and/or degradation of misfolded and damaged proteins are essential cellular processes. A part of this regulation is mediated by the so-called N-end rule proteolytic pathway, which, in concert with the ubiquitin proteasome system (UPS), drives protein degradation depending on the N-terminal amino acid sequence. One important enzyme involved in this process is arginyl-t-RNA transferase, known as ATE. This enzyme acts post-translationally by introducing an arginine residue at the N-terminus of specific protein targets to signal degradation via the UPS. However, the function of ATEs has only recently begun to be revealed. Nonetheless, the few studies to date investigating ATE activity in plants points to the great importance of the ATE/N-end rule pathway in regulating plant signaling. Plant development, seed germination, leaf morphology and responses to gas signaling in plants are among the processes affected by the ATE/N-end rule pathway. In this review, we present some of the known biological functions of plant ATE proteins, highlighting the need for more in-depth studies on this intriguing pathway.

Keywords:
ATE; N-end rule; plant; argyniltransferase; protein degradation

Introduction

Protein post-translational modifications are responsible for biological regulation of many important physiological processes and are the focus of intense research. However, the cellular functions associated with certain protein modifications described many years ago are only recently being revealed. This is the case for the incorporation of Arg residues into proteins by a mechanism that is dependent on tRNA but independent of conventional translation. Discovered in 1963 by Kaji et al. (1963aKaji A, Kaji H and Novelli GD (1963a) A soluble amino acid incorporating system. Biochem Biophys Res Commun 10:406-409.,bKaji H, Novelli GD and Kaji A (1963b) A soluble amino acid-incorporating system from rat liver. Biochim Biophys. Acta 76:474-477.), the modification known as arginylation occurs in some bacteria and all eukaryotic organisms and is mediated by the enzyme arginyltransferase (ATE). ATE genes are found in organisms ranging from yeasts to humans. The enzyme is encoded by a single gene in lower eukaryotes and by multiple isoforms in higher eukaryotes (Kwon et al., 1999Kwon YT, Kashina AS and Varshavsky A (1999) Alternative splicing results in differential expression, activity, and localization of the two forms of arginyl-tRNA-protein transferase, a component of the N-end rule pathway. Mol Cell Biol 19:182-193.; Hu et al., 2005Hu RG, Sheng J, Qi X, Xu Z, Takahashi TT and Varshavsky A (2005) The N-end rule pathway as a nitric oxide sensor controlling the levels of multiple regulators. Nature 437:981-986.; Rai and Kashina, 2005Rai R and Kashina A (2005) Identification of mammalian arginyltransferases that modify a specific subset of protein substrates. Proc Natl Acad Sci U S A 102:10123-10128.). In this short review we summarize some of the knowledge about plant ATEs, highlighting the biological process in which they modulate protein stability. Although Manahan and App (1973)Manahan CO and App AA (1973) An arginyl-transfer ribonucleic acid protein transferase from cereal embryos. Plant Physiol 52:13-16. first identified a plant arginyltransferase, approximately 30 years elapsed before further details about the cellular processes regulated by this modification emerged.

Knockouts of yeast and Caenorhabditis elegans ATE1 genes give rise to viable organisms with no obvious phenotypes, whereas ATE1 deletion in Drosophila melanogaster and Mus musculus results in embryonic lethality (Kwon et al., 2002Kwon YT, Kashina AS, Davydov IV, Hu RG, An JY, Seo JW, Du F and Varshavsky A (2002) An essential role of N-terminal arginylation in cardiovascular development. Science 297:96-99.; Crowe and Candido, 2004Crowe E and Candido EP (2004) Characterization of C. elegans RING finger protein 1, a binding partner of ubiquitin-conjugating enzyme 1. Dev Biol 265:446-459.; Mutsuddi et al., 2004Mutsuddi M, Marshall CM, Benzow KA, Koob MD and Reba YI (2004) The spinocerebellar ataxia 8 noncoding RNA causes neurodegeneration and associates with staufen in Drosophila. Curr Biol 14:302-308.). Lee et al. (2012)Lee MJ, Kim DE, Zakrzewska A, Yoo YD, Kim SH, Kim ST, Seo JW, Lee YS, Dorn 2nd GW, Oh U, et al. (2012) Characterization of arginylation branch of N-end rule pathway in G-protein-mediated proliferation and signaling of cardiomyocytes. J Biol Chem 287:24043-24052. showed that ATE1-knockout mouse embryos present cardiovascular and angiogenesis defects. These observations suggest that arginylation has acquired new functions and more specialized and essential roles in higher eukaryotes.

In plants, however, ATE is not required for viability (Yoshida et al., 2002Yoshida S, Ito M, Callis J, Nishida I and Watanabe A (2002) A delayed leaf senescence mutant is defective in arginyl-tRNA:protein arginyltransferase, a component of the N-end rule pathway in Arabidopsis. Plant J. 32:129-137.; Graciet et al., 2009Graciet E, Walter F, Maoileidigh DO, Pollmann S, Meyerowitz EM, Varshavsky A and Wellmer F (2009) The N-end rule pathway controls multiple functions during Arabidopsis shoot and leaf development. Proc Natl Acad Sci U S A 106:13618-13623.; Holman et al., 2009Holman TJ, Jones PD, Russell L, Medhurst A, Tomas S, Talloji P, Marquez J, Schmuths H, Tung SA, Taylor I, et al. (2009) The N-end rule pathway promotes seed germination and establishment through removal of ABA sensitivity in Arabidopsis. Proc Natl Acad Sci U S A 106:4549-4554.). Regardless, as presented in the following sections, Arabidopsis ATE isoform mutants have revealed important phenotypes associated with seed germination and plant development, suggesting that this post-translational modification is involved in diverse regulatory functions in eukaryotes.

Chemistry of arginylation and the N-end rule pathway of protein degradation

Arginyltransferases from eukaryotes and the related family of L/F transferases from bacteria are the only known class of enzymes that can transfer amino acid residues from aminoacyl-tRNA to proteins in a way that is independent of ribosomal protein synthesis (Kaji et al., 1963aKaji A, Kaji H and Novelli GD (1963a) A soluble amino acid incorporating system. Biochem Biophys Res Commun 10:406-409.,bKaji H, Novelli GD and Kaji A (1963b) A soluble amino acid-incorporating system from rat liver. Biochim Biophys. Acta 76:474-477., 1968Kaji H (1968) Further studies on the soluble amino acid incorporating system from rat liver. Biochemistry 7:3844-3850.; Bulinski, 2009Bulinski JC (2009) Tubulin posttranslational modifications: A Pushmi-Pullyu at work? Dev Cell 16:773-774.). Studies with partially purified ATE preparations, and more recently with recombinant mouse ATE isoforms, have revealed that ATE does not require any factors other than the target protein and charged tRNA to catalyze arginine transfer (Wang et al., 2011Wang J, Han X, Saha S, Xu T, Rai R, Zhang F, Wolf YI, Wolfson A, Yates 3rd JR and Kashina A (2011) Arginyltransferase is an ATP-independent self-regulating enzyme that forms distinct functional complexes in vivo. Chem Biol 28:121-130.). Proteins with N-terminally exposed Glu or Asp residues are typical ATE targets. The reaction is thought to result in a peptide bond between the alpha amino group of the N-terminal residue of a protein and the carboxy group of the added Arg that becomes the first residue (Kaji, 1968Kaji H (1968) Further studies on the soluble amino acid incorporating system from rat liver. Biochemistry 7:3844-3850.). However, recent studies have demonstrated that arginylation is not restricted to the N-terminus of proteins but can also occur at internal Asp and Glu side chains, adding a new layer of complexity to the reaction (Wang et al., 2011Wang J, Han X, Saha S, Xu T, Rai R, Zhang F, Wolf YI, Wolfson A, Yates 3rd JR and Kashina A (2011) Arginyltransferase is an ATP-independent self-regulating enzyme that forms distinct functional complexes in vivo. Chem Biol 28:121-130., 2014Wang J, Han X, Wong CC, Cheng H, Aslanian A, Xu T, Leavis P, Roder H, Hedstrom L, Yates 3rd JR, et al. (2014) Arginyltransferase ATE1 catalyzes midchain arginylation of proteins at side chain carboxylates in vivo. Chem Biol 20:331-337.; Wong et al., 2007Wong CCL, Xu T, Rai R, Bailey AO, Yates JR, Wolf YI, Zebroski H and Kashina A (2007) Global analysis of posttranslational protein arginylation. PLoS Biol 5:e258.). It was also demonstrated that ATE catalyzes self-arginylation and that different mouse ATE isoforms exhibit different kinetic properties and substrate specificity, which suggests that the differential expression of ATE variants is important for target selectivity (Wang et al., 2011Wang J, Han X, Saha S, Xu T, Rai R, Zhang F, Wolf YI, Wolfson A, Yates 3rd JR and Kashina A (2011) Arginyltransferase is an ATP-independent self-regulating enzyme that forms distinct functional complexes in vivo. Chem Biol 28:121-130.).

The functional implications of arginylation accompanied the observation that proteins with an N-terminally exposed Arg or arginylated proteins are unstable in the cytosol of cells from different organisms (Bachmair et al., 1986Bachmair A, Finley D and Varshanvsky A (1986) In vivo half-life of protein is a function of its amino-terminal residue. Science 234:179-186.; Gonda et al., 1989Gonda DK, Bachmair A, Wunning I, Tobias JW, Lane WS and Varshavsky A (1989) Universality and structure of the N-end rule. J Biol Chem 264:16700-16712.). Furthermore, it was shown that cellular degradation of proteins with an acidic N-terminus is dependent on arginylation and on the ubiquitin proteasome system (UPS) (Elias and Ciechanover, 1990Elias S and Ciechanover A (1990) Post-translational addition of an arginine moiety to acidic NH2 termini of proteins is required for their recognition by ubiquitin-protein ligase. J Biol Chem 265:15511-15517.). Therefore, arginylation is now considered an important aspect of the so-called N-end rule pathway of protein degradation.

The N-end rule pathway relates to a series of orderly reactions that control protein degradation depending on the nature of the N-terminal residue (Bachmair et al., 1986Bachmair A, Finley D and Varshanvsky A (1986) In vivo half-life of protein is a function of its amino-terminal residue. Science 234:179-186.). The presence of the classic destabilizing amino acids Arg, His and Lys at the N-terminus of a protein is a degradation signal, or degron, that is recognized by a specific type of E3 ubiquitin ligases, the N- recognins, called proteolysis protein or PRT in plants (Potuschak et al., 1998Potuschak T, Stary S, Schlögelhofer P, Becker F, Nejinskaia V and Bachmair A (1998) PRT1 of Arabidopsis thaliana encodes a component of the plant N-end rule pathway. Proc Natl Acad Sci U S A. 95:7904-8.; Stary et al., 2003Stary S, Yin XJ, Potuschak T, Schlögelhofer P, Nizhynska V and Bachmair A (2003) PRT1 of Arabidopsis is a ubiquitin protein ligase of the plant N-end rule pathway with specificity for aromatic amino-terminal residues. Plant Physiol 133:1360-1366.) and ubiquitin system recognition component or UBR in animals (Sriram et al., 2011Sriram SM, Kim BY and Kwon YT (2011) The N-end rule pathway: Emerging functions and molecular principles of substrate recognition. Nat Rev Mol Cell Biol 12:735-747.). In association with the destabilizing residues, the target protein must have an optimally positioned downstream Lys residue as a site for polyubiquitination and an appropriate secondary and/or tertiary structure (Tasaki et al., 2009Tasaki T, Zakrzewska A, Dudgeon DD, Jiang Y, Lazo JS and Kwon YT (2009) The substrate recognition domains of the N-end rule pathway. J Biol Chem 284:1884-1895., Varshavsky, 2011Varshavsky A (2011) The N-end rule pathway and regulation by proteolysis. Protein Sci 20:1298-1345.; Kim et al., 2013Kim ST, Tasaki T, Zakrzewska A, Yoo YD, Sa Sung K, Kim SH, Cha-Molstad H, Hwang J, Kim KA, Kim BY, et al. (2013) The N-end rule proteolytic system in autophagy. Autophagy 9:1100-1103.). E3 ubiquitin ligases direct degron-containing proteins toward degradation via the 26S proteasome (Tasaki et al., 2012Tasaki T, Sriram S, Park K and Kwon YT (2012) The N-end rule pathway. Annu Rev Biochem 81:261-289.).

The basic amino acid residues Arg, His, and Lys as well as hydrophobic Phe, Trp, Tyr, Leu, and Ile residues are called primary destabilizing amino acids because their presence at the N-terminus of a protein is a determinant for proteolysis. Asp, Glu or oxidized Cys are ATE substrates, and the protein may become a substrate for E3 ligases following arginylation. Therefore, these amino acids are known as secondary destabilizing residues. Gln, Asn and Cys are considered tertiary destabilizing amino acids; after deamidation of Gln and Asn by the action of Nt-amidase enzymes NTAN1 and NTAQ1 or Cys oxidation, these residues are converted to secondary destabilizing amino acids and consequently substrates for ATE1 (Graciet and Wellmer, 2010Graciet E and Wellmer F (2010) The plant N-end rule pathway: Structure and functions. Trends Plant Sci 15:447-453.). It is important to note that in all cases, these amino acids can act as destabilizers only if they are exposed at the N-terminus. To serve as a degradation substrate, the protein must loose the first Met by the action of a Met-aminopeptidase (MAP) (Bradshaw et al., 1998Bradshaw RA, Brickey W and Walker KW (1998) N-terminal processing: The methionine aminopeptidase and N alpha-acetyl transferase families. Trends Biochem Sci 23:263-267.). This reaction can occur during translation if the second amino acid is non-bulky, or by selective cleavage by cellular endoproteases.

It is interesting to note that N-recognins have diversified in different ways in plants and animals. Yeast cells encode a single protein, UBR1, which recognizes basic and hydrophobic N-terminal residues (Sriram et al., 2011Sriram SM, Kim BY and Kwon YT (2011) The N-end rule pathway: Emerging functions and molecular principles of substrate recognition. Nat Rev Mol Cell Biol 12:735-747.). In contrast, two types of structurally unrelated PRTs are known in plants, PRT1 and PRT6, which recognize hydrophobic and basic residues, respectively. Animals encode different UBR isoforms, but similar to yeast N-recognins, these proteins can bind to both types of primary destabilizing residues (Sriram et al., 2011Sriram SM, Kim BY and Kwon YT (2011) The N-end rule pathway: Emerging functions and molecular principles of substrate recognition. Nat Rev Mol Cell Biol 12:735-747.).

Plant ATEs and their evolutionary relationship with other ATEs

Studies comparing the N-end rule pathway of bacteria, fungi, animals and plants have shown that this is an ancient protein degradation pathway that likely evolved before the advent of the UPS in eukaryotes (Graciet et al., 2006Graciet E, Hu RG, Piatkov K, Rhee JH, Schwarz EM and Varshavsky A (2006) Aminoacyl-transfersases and the N-end rule pathway of prokaryotic/eukaryotic specificity in a human pathogen. Proc Natl Acad Sci U S A 103:3078-3083.; Xia et al., 2008Xia Z, Webster A, Du F, Piatkov K, Ghislain M and Varshavsky A (2008) Substrate-binding sites of URB1, the ubiquitin ligase of the N-end rule pathway. J Biol Chem 283:24011-24028.). Supporting this conclusion is the evidence of a common hierarchical organization and conservation of the enzymatic components involved in N-terminal protein modification, such as ATE and Nt-amidase enzymes, during evolution (Graciet and Wellmer, 2010Graciet E and Wellmer F (2010) The plant N-end rule pathway: Structure and functions. Trends Plant Sci 15:447-453.). Dissection of plant N-end rule pathway components as well as identification of two Arabidopsis Nt-amidases mediating recognition of tertiary destabilizing Nt-amino acids Asn and Gln have shown that the N-end rule pathway in plants is very similar to that in animals, highlighting a possible evolutionary common origin (Graciet and Wellmer, 2010Graciet E and Wellmer F (2010) The plant N-end rule pathway: Structure and functions. Trends Plant Sci 15:447-453.; Graciet et al., 2010Graciet E, Mesiti F and Wellmer F (2010) Structure and evolutionary conservation of the plant N-end rule pathway. Plant J 61:741-751.). The steps related to protein degradation, however, likely evolved after plant and animal divergence, as suggested by the differences in PRTs and UBR N-recognins.

ATE protein sequences contain two Pfam domains named ATE-N (PF04376) and ATE-C (PF04377), which are located at N- and C-termini, respectively (Figure 1). Comparative alignment and identity analysis of ATE proteins from human, mouse, fruit fly, yeast and Arabidopsis have revealed high conservation in domain regions but variability in inter-domain sequence and size (Figure 1A, B). Interestingly, the observed identity of more than 60% between the C-terminal ATE domains of mammals and fruit flies may reflect conserved functions or interaction partners in these taxa (Figure 1B). It is also remarkable that the plant ATE C-domain shares 50% identity with the same domain from C. elegans to human, demonstrating strong protein conservation among multicellular eukaryotes.

Plant evolutionary analysis has identified ATE orthologous genes from the green alga Chlamydomonas reinhardtii to angiosperms (Figure 2). In general, only one ATE gene is detected in a given plant species, with the two conserved ATE domains located at the N- and C-termini (Figures 1, 2). Some species, such as Arabidopsis, Populus and Sorghum, have experienced gene duplication. However, Sorghum appears to have generated a paralog gene that contains only the ATE-C domain and is likely not a functional arginyltransferase.

Recently, it was demonstrated that ATE protein abundance is spatially and temporally regulated by hormones and light and is highly abundant in meristematic cells from the moss Physcomitrella patens (Schuessele et al., 2016Schuessele C, Hoernstein SN, Mueller SJ, Rodriguez-Franco M, Lorenz T, Lang D, Igloi GL and Reski R (2016) Spatio-temporal patterning of arginyl-tRNA protein transferase (ATE) contributes to gametophytic development in a moss. New Phytol 209:1014-1027.). This work also showed that arginylation is necessary for moss gametophyte development, which is not observed in flowering plants. These findings support the conservation of N-end rule pathway components in land plants, even though the regulated processes may have diverged during evolution.

Plant ATE biological functions

Arabidopsis encodes two closely related ATE genes, AtATE1 (At5g05700) and AtATE2 (At11240), which have at least partially redundant functions. ATE1 was first functionally investigated by Yoshida et al. (2002)Yoshida S, Ito M, Callis J, Nishida I and Watanabe A (2002) A delayed leaf senescence mutant is defective in arginyl-tRNA:protein arginyltransferase, a component of the N-end rule pathway in Arabidopsis. Plant J. 32:129-137. in the mutant delayed leaf senescence1 (dls1), which exhibits extremely slow age-dependent, dark-induced leaf senescence. Such a phenotype was linked to a disrupted ATE1 in dls1. Years later, Holman et al. (2009)Holman TJ, Jones PD, Russell L, Medhurst A, Tomas S, Talloji P, Marquez J, Schmuths H, Tung SA, Taylor I, et al. (2009) The N-end rule pathway promotes seed germination and establishment through removal of ABA sensitivity in Arabidopsis. Proc Natl Acad Sci U S A 106:4549-4554. showed that the N-recognin E3 ligase PRT6 and AtATE1 and AtATE2 are involved in seed germination controlled by abscisic acid. A double mutant for AtATE1 and AtATE2 (ate1.ate2) displays lost sensitivity to this hormone and consequently uncontrolled seed germination and establishment. At the end of the same year, Graciet et al. (2009)Graciet E, Walter F, Maoileidigh DO, Pollmann S, Meyerowitz EM, Varshavsky A and Wellmer F (2009) The N-end rule pathway controls multiple functions during Arabidopsis shoot and leaf development. Proc Natl Acad Sci U S A 106:13618-13623. showed that apical dominance, stem elongation and regulation of leaf morphology were also linked to the N-end rule pathway, as demonstrated by analyzing AtATE1 and/or AtATE2 T-DNA insertion mutants (Graciet et al., 2009Graciet E, Walter F, Maoileidigh DO, Pollmann S, Meyerowitz EM, Varshavsky A and Wellmer F (2009) The N-end rule pathway controls multiple functions during Arabidopsis shoot and leaf development. Proc Natl Acad Sci U S A 106:13618-13623.; Graciet and Wellmer, 2010Graciet E and Wellmer F (2010) The plant N-end rule pathway: Structure and functions. Trends Plant Sci 15:447-453.). The arginylation branch of the N-end rule pathway is also responsible for repressing expression of the meristem-promoting brevipedicellus (BP) gene during leaf development, acting in a redundant way with the asymmetric leaves 1 (AS1) transcription factor complex, a known negative regulator of BP expression (Graciet et al., 2009Graciet E, Walter F, Maoileidigh DO, Pollmann S, Meyerowitz EM, Varshavsky A and Wellmer F (2009) The N-end rule pathway controls multiple functions during Arabidopsis shoot and leaf development. Proc Natl Acad Sci U S A 106:13618-13623.). The R-transferase target in this mechanism, however, has not yet been identified. Another important discovery by Graciet et al. (2009)Graciet E, Walter F, Maoileidigh DO, Pollmann S, Meyerowitz EM, Varshavsky A and Wellmer F (2009) The N-end rule pathway controls multiple functions during Arabidopsis shoot and leaf development. Proc Natl Acad Sci U S A 106:13618-13623. was that the N-recognin PRT6 is the E3 ligase N-recognin of plants and acts downstream of ATE.

One of the most studied and understood signaling pathways in plants controlled by arginylation is that involving the ethylene responsive transcription factor VII (ERFVII). It was observed that Arabidopsis ate1/ate2 or prt6 mutants could not degrade ERFVII, and as a consequence showed increased expression of hypoxia–responsive genes involved in fermentation and sugar consumption even under oxygen-rich conditions (Gibbs et al., 2011Gibbs DJ, Lee SC, Isa NM, Gramuglia S, Fukao T, Bassel GW, Correia CS, Corbineau F, Theodoulou FL, Bailey-Serres J, et al. (2011) Homeostatic response to hypoxia is regulated by the N-end rule pathway in plants. Nature 479:415-418.; Licausi et al., 2011Licausi F, Kosmacz M, Weits DA, Giuntoli B, Giorgi FM, Voesenek LA, Perata P and van Dongen JT (2011) Oxygen sensing in plants is mediated by an N-end rule pathway for protein destabilization. Nature 479:419-422.). The mechanism responsible for ERFVII regulation was suggested by previous studies on mammalian ATE1, which revealed that these enzymes can recognize oxidized N-terminal Cys residues as substrates for arginylation. The occurrence of this was later demonstrated in plants, with oxidized Cys also acting as a tertiary destabilizing N-terminal residue (Graciet et al., 2010Graciet E, Mesiti F and Wellmer F (2010) Structure and evolutionary conservation of the plant N-end rule pathway. Plant J 61:741-751.). Gibbs et al. (2011)Gibbs DJ, Lee SC, Isa NM, Gramuglia S, Fukao T, Bassel GW, Correia CS, Corbineau F, Theodoulou FL, Bailey-Serres J, et al. (2011) Homeostatic response to hypoxia is regulated by the N-end rule pathway in plants. Nature 479:415-418. demonstrated in vitro that all members of Arabidopsis group VII ERFs are N-end rule substrates that function as sensors of molecular oxygen via oxidation of the tertiary destabilizing cysteine residue. Arabidopsis has five ERFVII proteins: hypoxia-responsive ERF 1 and 2 (HRE1 and HRE2) and three more proteins related to apetala 2.2: RAP2.2, RAP.2.3, RAP2.12 (Nakano et al., 2006Nakano T, Suzuki K, Fujimura T and Shinshi H (2006) Genome-wide analysis of the ERF gene family in Arabidopsis and rice. Plant Physiol 140:411-432.). Alignment of the five Arabidopsis VII ERFs revealed that all share the same five first N-terminal residues (Gibbs et al., 2011Gibbs DJ, Lee SC, Isa NM, Gramuglia S, Fukao T, Bassel GW, Correia CS, Corbineau F, Theodoulou FL, Bailey-Serres J, et al. (2011) Homeostatic response to hypoxia is regulated by the N-end rule pathway in plants. Nature 479:415-418., 2015Gibbs DJ, Conde JV, Berckhan S, Prasad G, Mendiondo GM and Holdsworth MJ (2015) Group VII Ethylene Response Factors coordinate oxygen and nitric oxide signal transduction and stress responses in plants. Plant Physiol 169:23-31.), with the Nt-MCGGAII/L domain being highly conserved in flowering plants (Licausi et al., 2011Licausi F, Kosmacz M, Weits DA, Giuntoli B, Giorgi FM, Voesenek LA, Perata P and van Dongen JT (2011) Oxygen sensing in plants is mediated by an N-end rule pathway for protein destabilization. Nature 479:419-422.). Moreover, all five ERFVII proteins from Arabidopsis accumulate under conditions of low oxygen and are destabilized by the presence of oxygen. Oxidation of the N-terminal Cys residue is catalyzed by plant cysteine oxidases (PCOs) under specific conditions in which the Nt-Met residue is removed by MAP activity. Therefore, arginylation is directly involved in the mechanism that enables this transcription factor family to function as a sensor of hypoxia in plants (Gibbs et al., 2011Gibbs DJ, Lee SC, Isa NM, Gramuglia S, Fukao T, Bassel GW, Correia CS, Corbineau F, Theodoulou FL, Bailey-Serres J, et al. (2011) Homeostatic response to hypoxia is regulated by the N-end rule pathway in plants. Nature 479:415-418.; Licausi et al., 2011Licausi F, Kosmacz M, Weits DA, Giuntoli B, Giorgi FM, Voesenek LA, Perata P and van Dongen JT (2011) Oxygen sensing in plants is mediated by an N-end rule pathway for protein destabilization. Nature 479:419-422.).

Another important biological process mediated by Cys arginylation was demonstrated years later. Gibbs et al. (2014)Gibbs DJ, Md Isa N, Movahedi M, Lozano-Juste J, Mendiondo GM, Berckhan S, Marín-de la Rosa N, Vicente Conde J, Sousa Correia C, Pearce SP, et al. (2014). Nitric oxide sensing in plants is mediated by proteolytic control of group VII ERF transcriptional factors. Mol Cell 53:369-379. showed that group VII ERFs are also destabilized by nitric oxide (NO), and the same type of regulation was previously demonstrated in animal cardiovascular development. The target protein is the MC-initiating (Nt-MetCys) regulator of G-protein signaling (RGS) protein. RGS is destabilized in the presence of NO and oxygen, which mediate conversion of Nt-Cys to Cys sulfonic acid, making RGS a substrate for ATE and the N-end rule pathway (Hu et al., 2005Hu RG, Sheng J, Qi X, Xu Z, Takahashi TT and Varshavsky A (2005) The N-end rule pathway as a nitric oxide sensor controlling the levels of multiple regulators. Nature 437:981-986.; Jaba et al., 2013Jaba IM, Zhuang ZW, Li N, Jiang Y, Martin KA, Sinusas AJ, Papademetris X, Simons M, Sessa WC, Young LH, et al. (2013) NO triggers RGS4 degradation to coordinate angiogenesis and cardiomyocyte growth. J Clin Invest 123:1718-1731.). Gibbs et al. (2014)Gibbs DJ, Md Isa N, Movahedi M, Lozano-Juste J, Mendiondo GM, Berckhan S, Marín-de la Rosa N, Vicente Conde J, Sousa Correia C, Pearce SP, et al. (2014). Nitric oxide sensing in plants is mediated by proteolytic control of group VII ERF transcriptional factors. Mol Cell 53:369-379. found that the same mechanism regulates ERFVII stability in plants. In the presence of oxygen and/or NO, ERFVII degradation leads to hypocotyl growth inhibition, seed germination, photomorphogenesis, stomatal closure, and hypoxia-responsive transcriptional repression. Under hypoxia, however, accumulation of group VII ERFVs promotes hypocotyl growth, seed dormancy, photomorphogenesis repression, stomatal opening, and anaerobic-responsive gene expression (Gibbs et al., 2015Gibbs DJ, Conde JV, Berckhan S, Prasad G, Mendiondo GM and Holdsworth MJ (2015) Group VII Ethylene Response Factors coordinate oxygen and nitric oxide signal transduction and stress responses in plants. Plant Physiol 169:23-31.). Together, these studies suggest that group VII ERFs function as a central hub for the perception of oxygen and NO and that the N-end rule pathway is an important integrator of gas signaling in plants (Gibbs et al., 2014Gibbs DJ, Md Isa N, Movahedi M, Lozano-Juste J, Mendiondo GM, Berckhan S, Marín-de la Rosa N, Vicente Conde J, Sousa Correia C, Pearce SP, et al. (2014). Nitric oxide sensing in plants is mediated by proteolytic control of group VII ERF transcriptional factors. Mol Cell 53:369-379.). The regulatory role can be even broader, as ERFVII arginylation can also respond to other signals such as ethylene (Gibbs et al., 2015Gibbs DJ, Conde JV, Berckhan S, Prasad G, Mendiondo GM and Holdsworth MJ (2015) Group VII Ethylene Response Factors coordinate oxygen and nitric oxide signal transduction and stress responses in plants. Plant Physiol 169:23-31.).

By studying water submergence and starvation stress responses in N-end rule pathway mutants, Riber et al. (2015)Riber W, Müller JT, Visser EJW, Sasidharan R, Voesenek LACJ and Mustroph A (2015) The greening after extended darkness1 is an N-end rule pathway mutant with high tolerance to submergence and starvation. Plant Physiol 167:1616-1629. observed that these mutant plants were generally more tolerant to starvation conditions, such as prolonged darkness or water submergence. Interestingly, increased tolerance was a direct consequence of the impaired N-end rule pathway rather than up-regulation of the expression of genes involved with sugar consumption and fermentation (Riber et al., 2015Riber W, Müller JT, Visser EJW, Sasidharan R, Voesenek LACJ and Mustroph A (2015) The greening after extended darkness1 is an N-end rule pathway mutant with high tolerance to submergence and starvation. Plant Physiol 167:1616-1629.). This work showed the potential of regulating the ATE branch of the N-end rule pathway to generate stress-resistant plant variants.

The identification of ATE arginylation targets is an intriguing area of research and can reveal new biological processes regulated by the N-end rule pathway. Based on sequence analysis only, a large number of proteins appear to be potential substrates for ATE-mediated destabilization. However, the experimental identification and characterization of ATE substrate proteins remain technically challenging. The best characterized targets proteins are mammalian RGS proteins, especially RGS4, RGS5 and RGS16, and plant group VII ERFs (Hu et al., 2005Hu RG, Sheng J, Qi X, Xu Z, Takahashi TT and Varshavsky A (2005) The N-end rule pathway as a nitric oxide sensor controlling the levels of multiple regulators. Nature 437:981-986.; Gibbs et al., 2011Gibbs DJ, Lee SC, Isa NM, Gramuglia S, Fukao T, Bassel GW, Correia CS, Corbineau F, Theodoulou FL, Bailey-Serres J, et al. (2011) Homeostatic response to hypoxia is regulated by the N-end rule pathway in plants. Nature 479:415-418.; Licausi et al., 2011Licausi F, Kosmacz M, Weits DA, Giuntoli B, Giorgi FM, Voesenek LA, Perata P and van Dongen JT (2011) Oxygen sensing in plants is mediated by an N-end rule pathway for protein destabilization. Nature 479:419-422.; Bailey-Serres et al., 2012Bailey-Serres J, Fukao T, Gibbs DJ, Holdsworth MJ, Lee SC, Licausi F, Perata P, Voesenek LA and van Dongen JT (2012) Making sense of low oxygen sensing. Trends Plant Sci 17:129-138.; Lee, et al., 2012Lee MJ, Kim DE, Zakrzewska A, Yoo YD, Kim SH, Kim ST, Seo JW, Lee YS, Dorn 2nd GW, Oh U, et al. (2012) Characterization of arginylation branch of N-end rule pathway in G-protein-mediated proliferation and signaling of cardiomyocytes. J Biol Chem 287:24043-24052.; Gibbs et al., 2014Gibbs DJ, Md Isa N, Movahedi M, Lozano-Juste J, Mendiondo GM, Berckhan S, Marín-de la Rosa N, Vicente Conde J, Sousa Correia C, Pearce SP, et al. (2014). Nitric oxide sensing in plants is mediated by proteolytic control of group VII ERF transcriptional factors. Mol Cell 53:369-379.). As mentioned above, both RGS and ERFVII substrates have a Cys as the second Nt residue which, after oxidation, acts as a tertiary destabilizing residue dependent on ATE arginylation (Gibbs et al., 2011Gibbs DJ, Lee SC, Isa NM, Gramuglia S, Fukao T, Bassel GW, Correia CS, Corbineau F, Theodoulou FL, Bailey-Serres J, et al. (2011) Homeostatic response to hypoxia is regulated by the N-end rule pathway in plants. Nature 479:415-418.; Licausi et al., 2011Licausi F, Kosmacz M, Weits DA, Giuntoli B, Giorgi FM, Voesenek LA, Perata P and van Dongen JT (2011) Oxygen sensing in plants is mediated by an N-end rule pathway for protein destabilization. Nature 479:419-422.; Bailey-Serres et al., 2012Bailey-Serres J, Fukao T, Gibbs DJ, Holdsworth MJ, Lee SC, Licausi F, Perata P, Voesenek LA and van Dongen JT (2012) Making sense of low oxygen sensing. Trends Plant Sci 17:129-138.; Lee et al., 2012Lee MJ, Kim DE, Zakrzewska A, Yoo YD, Kim SH, Kim ST, Seo JW, Lee YS, Dorn 2nd GW, Oh U, et al. (2012) Characterization of arginylation branch of N-end rule pathway in G-protein-mediated proliferation and signaling of cardiomyocytes. J Biol Chem 287:24043-24052.). During oxygen-limiting conditions, ERFVII and RGS accumulate, leading to transcription of hypoxia-response genes in plants (Gibbs, et al., 2011Gibbs DJ, Lee SC, Isa NM, Gramuglia S, Fukao T, Bassel GW, Correia CS, Corbineau F, Theodoulou FL, Bailey-Serres J, et al. (2011) Homeostatic response to hypoxia is regulated by the N-end rule pathway in plants. Nature 479:415-418.; Licausi et al., 2011Licausi F, Kosmacz M, Weits DA, Giuntoli B, Giorgi FM, Voesenek LA, Perata P and van Dongen JT (2011) Oxygen sensing in plants is mediated by an N-end rule pathway for protein destabilization. Nature 479:419-422.; Gibbs et al., 2014Gibbs DJ, Md Isa N, Movahedi M, Lozano-Juste J, Mendiondo GM, Berckhan S, Marín-de la Rosa N, Vicente Conde J, Sousa Correia C, Pearce SP, et al. (2014). Nitric oxide sensing in plants is mediated by proteolytic control of group VII ERF transcriptional factors. Mol Cell 53:369-379.) and decreased cardiomyocyte proliferation by RGS accumulation and downregulation of G protein signaling in mammals (Lee et al., 2012Lee MJ, Kim DE, Zakrzewska A, Yoo YD, Kim SH, Kim ST, Seo JW, Lee YS, Dorn 2nd GW, Oh U, et al. (2012) Characterization of arginylation branch of N-end rule pathway in G-protein-mediated proliferation and signaling of cardiomyocytes. J Biol Chem 287:24043-24052.).

The proteins' resistance to Pseudomonas syringae 1-interacting protein 4 (RIN4), ethylene response factor 72 (EBP) and vernalization 2 (VRN2) have been identified as putative ATE substrates by transcriptome analysis of ate1.ate2 mutants. However, their modification by ATE has not been shown at the molecular level (Gibbs et al., 2011Gibbs DJ, Lee SC, Isa NM, Gramuglia S, Fukao T, Bassel GW, Correia CS, Corbineau F, Theodoulou FL, Bailey-Serres J, et al. (2011) Homeostatic response to hypoxia is regulated by the N-end rule pathway in plants. Nature 479:415-418.).

Mass spectrometry approaches are being developed to screen for arginylated proteins and to reveal new cellular processes controlled by ATE modification. To identify plant ATE substrates, Majovsky et al. (2014)Majovsky P, Naumann C, Lee CW, Lassowskat I, Trujillo M, Dissmeyer N and Hoehenwarter W (2014) Targeted proteomics analysis of protein degradation in plant signaling on an LTQ-orbitrap mass spectrometer. J Proteome Res 13:4246-4258. analyzed plant proteomes from A. thaliana ate1, ate2, prt1 and prt6 knockout mutants, and new putative substrates of ATE were identified among Nt Met-Cys proteins. The relative abundance of methylesterase 10 (MES10), nucleoside diphosphate kinase family protein (NDPK1), and two asparagine synthetases (ASNs) was augmented in ate1/ate2 mutants. The MES10 protein hydrolyzes methyl salicylate to salicylic acid, NDPK1 plays a role in the response to reactive oxygen species (ROS) stress, and ASNs are components of the L-asparagine biosynthesis pathway (Peeters et al., 2000Peeters NM, Chapron A, Giritch A, Grandjean O, Lancelin D, Lhomme T, Vivrel A and Small I (2000) Duplication and quadruplication of Arabidopsis thaliana cysteinyl- and asparaginyl-tRNA synthetase genes of organellar origin. J Mol Evol 50:413-423.; Fukamatsu et al., 2003Fukamatsu Y, Yabe N and Hasunuma K (2003) Arabidopsis NDK1 is a component of ROS signaling by interacting with three catalases. Plant Cell Physiol 44:982-989.; Yang et al., 2008Yang Y, Xu R, Ma CJ, Vlot AC, Klessig DF and Pichersky E (2008) Inactive methyl indole-3-acetic acid ester can be hydrolyzed and activated by several esterases belonging to the AtMES esterase family of Arabidopsis. Plant Physiol 147:1034-1045.). Other putative substrates found by Majovsky et al. (2014)Majovsky P, Naumann C, Lee CW, Lassowskat I, Trujillo M, Dissmeyer N and Hoehenwarter W (2014) Targeted proteomics analysis of protein degradation in plant signaling on an LTQ-orbitrap mass spectrometer. J Proteome Res 13:4246-4258. that do not have a Nt-Met-Cys were glyceraldehyde 3-phosphate dehydrogenase subunits GAPA, GAPA2 and GAPB, the granulin repeat cysteine protease family protein (RD21), glucoside (GGD), thioglucoside glucohydrolases (TGG1 and TGG2), two glycine-rich proteins (GRPs), cold circadian rhythm (CCR1 and CCR2), RNA-binding 1 and 2 and nicotinamide adenine dinucleotide-dependent malic enzyme (NAD-MED2). The functional implication of these modifications awaits experimental validation.

Other interesting roles for mammalian ATEs are emerging and could point to new functions in plants. Recently, Cha-Molstad et al. (2015a)Cha-Molstad H, Sung KS, Hwang J, Kim KA, Yu JE, Yoo YD, Jang JM, Han DH, Molstad M, Kim JG, et al. (2015a) Amino-terminal arginylation targets endoplasmic reticulum chaperone BiP for autophagy through p62 binding. Nat Cell Biol 17:917-929. showed that in human cells, ATE1 mediates N-terminal arginylation of binding immunoglobulin protein (Bip) and possibly other endoplasmic reticulum (ER)-residing chaperones. Under certain stress conditions, such as the presence of dsDNA in the cytoplasm or proteasome inhibition, Bip was directed to the cytosol, where it was arginylated by ATE. Further experiments showed that Nt-Arg residues function as a determinant of autophagic delivery to autophagosomes by acting as an activating ligand of p62, an important component of the autophagy pathway that interacts with degradation targets and drives autophagosome formation by recruiting other components of the pathway (Yamano and Youle, 2013Yamano K and Youle RJ (2013) PINK1 is degraded through the N-end rule pathway. Autophagy 9:1758-1769.; Cha-Molstad et al., 2015aCha-Molstad H, Sung KS, Hwang J, Kim KA, Yu JE, Yoo YD, Jang JM, Han DH, Molstad M, Kim JG, et al. (2015a) Amino-terminal arginylation targets endoplasmic reticulum chaperone BiP for autophagy through p62 binding. Nat Cell Biol 17:917-929.,bCha-Molstad H, Kwon YT and Kim BY (2015b) Amino-terminal arginylation as a degradation signal for selective autophagy. BMB Reports 48:487-488.). Intriguingly, ATE was also reported to act in mammals directing the degradation of caspase- and calpain-generated fragments of cohesin (Rai and Kashina, 2005Rai R and Kashina A (2005) Identification of mammalian arginyltransferases that modify a specific subset of protein substrates. Proc Natl Acad Sci U S A 102:10123-10128.; Piatkov et al., 2012Piatkov KI, Colnaghi L, Békés M, Varshavsky A and Huang TT (2012) The auto-generated fragment of the Usp1 deubiquitylase is a physiological substrate of the N-end rule pathway. Mol Cell 48:926-933., 2014Piatkov KI, Oh JH, Liu Y and Varshavsky A (2014) Calpain-generated natural protein fragments as short-lived substrates of the N-end rule pathway. Proc Natl Acad Sci U S A 111:E817-E826.). Nonetheless, the involvement of plant ATEs in the autophagy pathway and in the degradation of caspase-like and/or calpain-generated fragments in plants remains elusive. Combining these putative ATE mechanisms with those already studied in plants, we propose a model of biological processes regulated by ATE arginylation in plants (Figure 3).

Concluding remarks

Although important efforts have been made towards an understanding of the role of ATE/N-end rule functions in plants, many open questions remain, for example, the functions of different isoforms of ATE in plants, how ATE activity is regulated, and the identification of interaction partners. It is possible that plant ATEs can also arginylate internal amino acids of proteins and that this type of modification has other signaling functions.

The discovery of the physiological substrates of R-arginylation is essential for understanding N-end rule functions. In addition to its biological importance, elucidating some of the processes regulated by the N-end rule pathway in plants is relevant for biotechnological purposes, as this pathway has a direct impact on developmental processes and tolerance to starvation and/or abiotic stress.

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