A novel tomato SUMO E3 ligase,SlSIZ1, confers drought tolerance in transgenic tobacco

SUMOylation is an important post‐translational modification process that regulates different cellular functions in eukaryotes. SIZ/PIAS‐type SAP and Miz1 (SIZ1) proteins exhibit SUMO E3 ligase activity, which modulates SUMOylation. However, SIZ1 in tomato has been rarely investigated. In this study, a tomato SIZ1 gene (SlSIZ1) was isolated and its molecular characteristics and role in tolerance to drought stress are described. SlSIZ1 was up‐regulated by cold, sodium chloride (NaCl), polyethylene glycol (PEG), hydrogen peroxide (H₂O₂) and abscisic acid (ABA), and the corresponding proteins were localized in the nucleus. The expression of SlSIZ1 in Arabidopsis thaliana (Arabidopsis) siz1‐2 mutants partially complemented the phenotypes of dwarf, cold sensitivity and ABA hypersensitivity. SlSIZ1 also exhibited the activity of SUMO E3 ligase to promote the accumulation of SUMO conjugates. Under drought stress, the ectopic expression of SlSIZ1 in transgenic tobacco lines enhanced seed germination and reduced the accumulation of reactive oxygen species. SlSIZ1 overexpression conferred the plants with improved growth, high free proline content, minimal malondialdehyde accumulation and increased accumulation of SUMO conjugates. SlSIZ1 is a functional homolog of Arabidopsis SIZ1 with SUMO E3 ligase activity. Therefore, overexpression of SlSIZ1 enhanced the tolerance of transgenic tobacco to drought stress.     

Sumoylation, a post-translational regulatory process in plants

The reversible conjugation of the small ubiquitin-related modifier (SUMO) peptide to protein substrates (sumoylation) is emerging as a major post-translational regulatory process in animals and other eukaryotes, including plants. Database annotation, and genetic and biochemical analyses indicate that components of the SUMO conjugation and deconjugation systems are conserved in plants such as Arabidopsis, rice, tomato, and Medicago. Specifically, Arabidopsis AtSUMO1/2 and SUMO E2 conjugation enzyme AtSCE1a are implicated in abscisic acid (ABA) responses and the ubiquitin-like SUMO protease 1 (ULP1) AtESD4 in flowering time regulation. The AtSIZ1 SUMO E3 ligase functions in phosphate starvation responses, cold tolerance, basal thermotolerance, salicylic acid (SA)-dependent pathogen defense, and flowering time regulation. Following is a brief overview of the current understanding of SUMO conjugation and deconjugation determinants, and biological processes that are regulated in plants.     

SUMO E3 Ligases GmSIZ1a and GmSIZ1b regulate vegetative growth in soybean

SIZ1 is a small ubiquitin‐related modifier (SUMO) E3 ligase that mediates post‐translational SUMO modification of target proteins and thereby regulates developmental processes and hormonal and environmental stress responses in Arabidopsis. However, the role of SUMO E3 ligases in crop plants is largely unknown. Here, we identified and characterized two Glycine max (soybean) SUMO E3 ligases, GmSIZ1a and GmSIZ1b. Expression of GmSIZ1a and GmSIZ1b was induced in response to salicylic acid (SA), heat, and dehydration treatment, but not in response to cold, abscisic acid (ABA), and NaCl treatment. Although GmSIZ1a was expressed at higher levels than GmSIZ1b, both genes encoded proteins with SUMO E3 ligase activity in vivo. Heterologous expression of GmSIZ1a or GmSIZ1b rescued the mutant phenotype of Arabidopsis siz1‐2, including dwarfism, constitutively activated expression of pathogen‐related genes, and ABA‐sensitive seed germination. Simultaneous downregulation of GmSIZ1a and GmSIZ1b (GmSIZ1a/b) using RNA interference (RNAi)‐mediated gene silencing decreased heat shock‐induced SUMO conjugation in soybean. Moreover, GmSIZ1RNAi plants exhibited reduced plant height and leaf size. However, unlike Arabidopsis siz1‐2 mutant plants, flowering time and SA levels were not significantly altered in GmSIZ1RNAi plants. Taken together, our results indicate that GmSIZ1a and GmSIZ1b mediate SUMO modification and positively regulate vegetative growth in soybean.     

OsSIZ1 Regulates the Vegetative Growth and Reproductive Development in Rice

SAP and MIZ (SIZ) is a small ubiquitin-related modifier (SUMO) E3 ligase that facilitates conjugation of SUMO to protein substrates. Although there have been a number of reports about the functions of SIZ1 in Arabidopsis in the regulation of diverse life processes, no information regarding the role of SIZ in other plants is available yet. In this work, two homologous genes from rice (Oryza sativa) were isolated and designated as OsSIZ1 and OsSIZ2 based on amino acid sequence homology to AtSIZ1 and their phylogenetic relationship. The function in the vegetative growth and reproductive development in rice was investigated using OsSIZ1 mutants containing a T-DNA insertion. The results showed that the mutant Ossiz1 exhibited the significant changes in several growth and developmental parameters, including primary root length, adventitious root number, plant height, leaf and panicle length, flower formation, and seed-setting rate compared with wild type. Taking together these results indicate that OsSIZ1 plays an important role in regulating growth and development in rice.     

Overexpression of CpSIZ1, a SIZ/PIAS-Type SUMO E3 Ligase from Wintersweet (Chimonanthus praecox), Delays Flowering,Accelerates Leaf Senescence and Enhances Cold Tolerance in Arabidopsis

Wintersweet (Chimonanthus praecox L.) is a traditional winter-flowering plant in China and a popular cut flower in winter. Its unique flowering characteristics under cold stress may involve the regulation of a large number of proteins. Protein post-translational modification is an important regulating type for the gene function. However, little is known about the post-translational modification in wintersweet. SUMOylation is an important post-translational modification in eukaryotes. Small ubiquitin-like modifier (SUMO) E3 ligases perform multiple functional regulatory activities in plants via SUMOylation. Here, we cloned and identified a SIZ/PIAS-type SUMO E3 ligase, CpSIZ1, from wintersweet. CpSIZ1 shared high similarity with other SIZ1 proteins. Quantitative real-time PCR (qRT-PCR) indicated that CpSIZ1 was expressed in all tissues tested, with the highest expression in flower wither period of stage 6, and followed by mature leaves except for different flower development stages. The ectopic expression of CpSIZ1 in Arabidopsis, including the CpSIZ1 overexpression in siz1-2 mutant (HB line) and CpSIZ1 overexpression in WT (OE line), not only promoted vegetative growth, delayed flowering and accelerated leaf senescence, but also improve the cold tolerance in Arabidopsis. Therefore, our studies have enrich the understanding of function of SIZ1 gene in woody plant, and provide a good foundation for further research on the post-translational modification regulation mechanism in this winter-flowering plant.

     

Flowering time regulation by the SUMO E3 ligase SIZ1

Flowering is a developmental process, which is influenced by chemical and environmental stimuli. Recently, our research established that the Arabidopsis SUMO E3 ligase, AtSIZ1, is a negative regulator of transition to flowering through mechanisms that reduce salicylic acid (SA) accumulation and involve SUMO modification of FLOWERING LOCUS D (FLD). FLD is an autonomous pathway determinant that represses the expression of FLOWERING LOCUS C (FLC), a floral repressor. This addendum postulates mechanisms by which SIZ1-mediated SUMO conjugation regulates SA accumulation and FLD activity.Key words: SIZ1, SA, flowering, SUMO, FLD, FLCSUMO conjugation and deconjugation are post-translational processes implicated in plant defense against pathogens, abscisic acid (ABA) and phosphate (Pi) starvation signaling, development, and drought and temperature stress tolerance, albeit only a few of the modified proteins have been identified.^1–8 The Arabidopsis AtSIZ1 locus encodes a SUMO E3 ligase that regulates floral transition and leaf development.^8,9 siz1 plants accumulate substantial levels of SA, which is the primary cause for dwarfism and early short-day flowering exhibited by these plants.^1,9 How SA promotes transition to flowering is not yet known but apparently, it is through a mechanism that is independent of the known floral signaling pathways.^9,10 Exogenous SA reduces expression of AGAMOUS-like 15 (AGL15), a floral repressor that functions redundantly with AGL18.^11,12 A possible mechanism by which SA promotes transition to flowering may be by repressing expression of AGL15 and AGL18 (Fig. 1).Open in a separate windowFigure 1Model of how SUMO conjugation and deconjugation regulate plant development in Arabidopsis. SIZ1 and Avr proteins regulate biosynthesis and accumulation of SA, a plant stress hormone that is involved in plant innate immunity, leaf development and regulation of flowering time. SA promotes transition to flowering may through AGL15/AGL18 dependent and independent pathways. FLC expression is activated by FRIGIDA but repressed by the autonomous pathway gene FLD, and SIZ1-mediated sumoylation of FLD represses its activity. Lines with arrows indicate upregulation (activation), and those with bars identify downregulation (repression).siz1 mutations also cause constitutive induction of pathogenesis-related protein genes leading to enhanced resistance against biotrophic pathogens.¹ Several bacterial type III effector proteins, such as YopJ, XopD and AvrXv4, have SUMO isopeptidase activity.^13–15 PopP2, a member of YopJ/AvrRxv bacterial type III effector protein family, physically interacts with the TIR-NBS-LRR type R protein RRS1, and possibly stabilizes the RRS1 protein.¹⁶ Phytopathogen effector and plant R protein interactions lead to increased SA biosynthesis and accumulation, which in turn activates expression of pathogenesis-related proteins that facilitate plant defense.¹⁷ SIZ1 may participate in SUMO conjugation of plant R proteins to regulate Avr and R protein interactions leading to SA accumulation, which, in turn, affects phenotypes such as diseases resistance, dwarfism and flowering time (Fig. 1).Our recent work revealed also that AtSIZ1 facilitates FLC expression, negatively regulating flowering.⁹ AtSIZ1 promotes FLC expression by repressing FLD activity.⁹ Site-specific mutations that prevent SUMO1/2 conjugation to FLD result in enhanced activity of the protein to represses FLC expression, which is associated with reduced acetylation of histone 4 (H4) in FLC chromatin.⁹ FLD, an Arabidopsis ortholog of Lysine-Specific Demethylase 1 (LSD1), is a floral activator that downregulates methylation of H3K4 in FLC chromatin and represses FLC expression.^18,19 Interestingly, bacteria expressing recombinant FLD protein did not demethylate H3K4me2, inferring that the demethylase activity requires additional co-factors as are necessary for LSD1.^18,20 Together, these results suggest that SIZ1-mediated SUMO modification of FLD may affect interactions between FLD and co-factors, which is necessary for FLC chromatin modification.Despite our results that implicate SA in flowering time control, how SIZ1 regulates SA accumulation and the identity of the effectors involved remain to be discovered. In addition, it remains to be determined if SIZ1 is involved in other mechanisms that modulate FLD activity and FLC expression, or the function of other autonomous pathway determinants.     

Overexpression of dehydrin tas14 gene improves the osmotic stress imposed by drought and salinity in tomato

One strategy to increase the level of drought and salinity tolerance is the transfer of genes codifying different types of proteins functionally related to macromolecules protection, such as group 2 of late embryogenesis abundant (LEA) proteins or dehydrins. The TAS14 dehydrin was isolated and characterized in tomato and its expression was induced by osmotic stress (NaCl and mannitol) and abscisic acid (ABA) [Godoy et al., Plant Mol Biol 1994;26:1921-1934], yet its function in drought and salinity tolerance of tomato remains elusive. In this study, transgenic tomato plants overexpressing tas14 gene under the control of the 35SCaMV promoter were generated to assess the function of tas14 gene in drought and salinity tolerance. The plants overexpressing tas14 gene achieved improved long-term drought and salinity tolerance without affecting plant growth under non-stress conditions. A mechanism of osmotic stress tolerance via osmotic potential reduction and solutes accumulation, such as sugars and K(+) is operating in tas14 overexpressing plants in drought conditions. A similar mechanism of osmotic stress tolerance was observed under salinity. Moreover, the overexpression of tas14 gene increased Na(+) accumulation only in adult leaves, whereas in young leaves, the accumulated solutes were K(+) and sugars, suggesting that plants overexpressing tas14 gene are able to distribute the Na(+) accumulation between young and adult leaves over a prolonged period in stressful conditions. Measurement of ABA showed that the action mechanism of tas14 gene is associated with an earlier and greater accumulation of ABA in leaves during short-term periods. A good feature for the application of this gene in improving drought and salt stress tolerance is the fact that its constitutive expression does not affect plant growth under non-stress conditions, and tolerance induced by overexpression of tas14 gene was observed at the different stress degrees applied to the long term.     

The PHD domain of plant PIAS proteins mediates sumoylation of bromodomain GTE proteins

Covalent attachment of small ubiquitin-like modifier (SUMO) to proteins regulates multiple processes in the eukaryotic cell. In numerous cases sumoylation is facilitated by protein inhibitor of activated STAT (PIAS) proteins, characterized by the presence of a SP-RING domain related to the RING finger of many ubiquitin E3 ligases. The importance of SP-RING relies on its capacity to bind the E2 enzyme of the pathway. Additional domains may participate in SUMO ligase function and target selection. We have studied the Arabidopsis SUMO ligase AtSIZ1, belonging to the PIAS family, and describe self-sumoylation and AtSIZ1-mediated sumoylation of the E2 enzyme AtSCE1 and GTE3, a bromodomain protein interacting with AtSIZ1. Modification of GTE3 modulates its capacity to bind acetyl-histone H3 in vitro. Interestingly, AtSIZ1, as other plant PIAS proteins, also includes a PHD domain. We found that the PHD domain binds AtSCE1 and contributes to the SUMO ligase function, being partially and absolutely required for AtSCE1 and GTE3 sumoylation, respectively. Based on the capacity of AtSCE1 and GTE3 to associate with both the PHD and SP-RING domains, we propose a model of interactions to explain AtSIZ1-mediated sumoylation of GTE3 and ligase function of the PHD domain.     

Erratum to: Constitutive expression of CaXTH3, a hot pepper xyloglucan endotransglucosylase/hydrolase, enhanced tolerance to salt and drought stresses without phenotypic defects in tomato plants (Solanum lycopersicum cv. Dotaerang)

The hot pepper xyloglucan endo-trans-gluco-sylase/hydrolase (CaXTH3) gene that was inducible by a broad spectrum of abiotic stresses in hot pepper has been reported to enhance tolerance to drought and high salinity in transgenic Arabidopsis. To assess whether CaXTH3 is a practically useful target gene for improving the stress tolerance of crop plants, we ectopically over-expressed the full-length CaXTH3 cDNA in tomato (Solanum lycopersicum cv. Dotaerang) and found that the 35S:CaXTH3 transgenic tomato plants exhibited a markedly increased tolerance to salt and drought stresses. Transgenic tomato plants exposed to a salt stress of 100 mM NaCl retained the chlorophyll in their leaves and showed normal root elongation. They also remained green and unwithered following exposure to 2 weeks of dehydration. A high proportion of stomatal closures in 35S:CaXTH3 was likely to be conferred by increased cell-wall remodeling activity of CaXTH3 in guard cell, which may reduce transpirational water loss in response to dehydration stress. Despite this increased stress tolerance, the transgenic tomato plants showed no detectable phenotype defects, such as abnormal morphology and growth retardation, under normal growth conditions. These results raise the possibility that CaXTH3 gene is appropriate for application in genetic engineering strategies aimed at improving abiotic stress tolerance in agriculturally and economically valuable crop plants.     

Abscisic acid root and leaf concentration in relation to biomass partitioning in salinized tomato plants

Salinization is one of the most important causes of crop productivity reduction in many areas of the world. Mechanisms that control leaf growth and shoot development under the osmotic phase of salinity are still obscure, and opinions differ regarding the Abscisic acid (ABA) role in regulation of biomass allocation under salt stress. ABA concentration in roots and leaves was analyzed in a genotype of processing tomato under two increasing levels of salinity stress for five weeks: 100 mM NaCl (S10) and 150 mM NaCl (S15), to study the effect of ABA changes on leaf gas exchange and dry matter partitioning of this crop under salinity conditions. In S15, salinization decreased dry matter by 78% and induced significant increases of Na⁺ and Cl⁻ in both leaves and roots. Dry matter allocated in different parts of plant was significantly different in salt-stressed treatments, as salinization increased root/shoot ratio 2-fold in S15 and 3-fold in S15 compared to the control. Total leaf water potential (Ψ_w) decreased from an average value of approximately −1.0 MPa, measured on control plants and S10, to −1.17 MPa in S15. In S15, photosynthesis was reduced by 23% and stomatal conductance decreased by 61%. Moreover, salinity induced ABA accumulation both in tomato leaves and roots of the more stressed treatment (S15), where ABA level was higher in roots than in leaves (550 and 312 ng g⁻¹ fresh weight, respectively). Our results suggest that the dynamics of ABA and ion accumulation in tomato leaves significantly affected both growth and gas exchange-related parameters in tomato. In particular, ABA appeared to be involved in the tomato salinity response and could play an important role in dry matter partitioning between roots and shoots of tomato plants subjected to salt stress.