Arabidopsis DELLA Protein Degradation Is Controlled by a Type-One Protein Phosphatase,TOPP4

Gibberellins (GAs) are a class of important phytohormones regulating a variety of physiological processes during normal plant growth and development. One of the major events during GA-mediated growth is the degradation of DELLA proteins, key negative regulators of GA signaling pathway. The stability of DELLA proteins is thought to be controlled by protein phosphorylation and dephosphorylation. Up to date, no phosphatase involved in this process has been identified. We have identified a dwarfed dominant-negative Arabidopsis mutant, named topp4-1. Reduced expression of TOPP4 using an artificial microRNA strategy also resulted in a dwarfed phenotype. Genetic and biochemical analyses indicated that TOPP4 regulates GA signal transduction mainly via promoting DELLA protein degradation. The severely dwarfed topp4-1 phenotypes were partially rescued by the DELLA deficient mutants rga-t2 and gai-t6, suggesting that the DELLA proteins RGA and GAI are required for the biological function of TOPP4. Both RGA and GAI were greatly accumulated in topp4-1 but significantly decreased in 35S-TOPP4 transgenic plants compared to wild-type plants. Further analyses demonstrated that TOPP4 is able to directly bind and dephosphorylate RGA and GAI, confirming that the TOPP4-controlled phosphorylation status of DELLAs is associated with their stability. These studies provide direct evidence for a crucial role of protein dephosphorylation mediated by TOPP4 in the GA signaling pathway.     

Proteolysis-independent downregulation of DELLA repression in Arabidopsis by the gibberellin receptor GIBBERELLIN INSENSITIVE DWARF1

This article presents evidence that DELLA repression of gibberellin (GA) signaling is relieved both by proteolysis-dependent and -independent pathways in Arabidopsis thaliana. DELLA proteins are negative regulators of GA responses, including seed germination, stem elongation, and fertility. GA stimulates GA responses by causing DELLA repressor degradation via the ubiquitin-proteasome pathway. DELLA degradation requires GA biosynthesis, three functionally redundant GA receptors GIBBERELLIN INSENSITIVE DWARF1 (GID1a, b, and c), and the SLEEPY1 (SLY1) F-box subunit of an SCF E3 ubiquitin ligase. The sly1 mutants accumulate more DELLA proteins but display less severe dwarf and germination phenotypes than the GA biosynthesis mutant ga1-3 or the gid1abc triple mutant. Interestingly, GID1 overexpression rescued the sly1 dwarf and infertility phenotypes without decreasing the accumulation of the DELLA protein REPRESSOR OF ga1-3. GID1 rescue of sly1 mutants was dependent on the level of GID1 protein, GA, and the presence of a functional DELLA motif. Since DELLA shows increasing interaction with GID1 with increasing GA levels, it appears that GA-bound GID1 can block DELLA repressor activity by direct protein-protein interaction with the DELLA domain. Thus, a SLY1-independent mechanism for GA signaling may function without DELLA degradation.     

Role of the gibberellin receptors GID1 during fruit‐set in Arabidopsis

Gibberellins (GAs) play a critical role in fruit‐set and fruit growth. Gibberellin is perceived by its nuclear receptors GA INSENSITIVE DWARF1s (GID1s), which then trigger degradation of downstream repressors DELLAs. To understand the role of the three GA receptor genes (GID1A, GID1B and GID1C) in Arabidopsis during fruit initiation, we have examined their temporal and spatial localization, in combination with analysis of mutant phenotypes. Distinct expression patterns are revealed for each GID1: GID1A is expressed throughout the whole pistil, while GID1B is expressed in ovules, and GID1C is expressed in valves. Functional study of gid1 mutant combinations confirms that GID1A plays a major role during fruit‐set and growth, whereas GID1B and GID1C have specific roles in seed development and pod elongation, respectively. Therefore, in ovules, GA perception is mediated by GID1A and GID1B, while GID1A and GID1C are involved in GA perception in valves. To identify tissue‐specific interactions between GID1s and DELLAs, we analyzed spatial expression patterns of four DELLA genes that have a role in fruit initiation (GAI, RGA, RGL1 and RGL2). Our data suggest that GID1A can interact with RGA and GAI in all tissues, whereas GID1C–RGL1 and GID1B–RGL2 interactions only occur in valves and ovules, respectively. These results uncover specific functions of each GID1–DELLA in the different GA‐dependent processes that occur upon fruit‐set. In addition, the distribution of GA receptors in valves along with lack of expression of GA biosynthesis genes in this tissue, strongly suggests transport of GAs from the developing seeds to promote fruit growth.     

The role of two f-box proteins, SLEEPY1 and SNEEZY, in Arabidopsis gibberellin signaling

The SLEEPY1 (SLY1) F-box gene is a positive regulator of gibberellin (GA) signaling in Arabidopsis (Arabidopsis thaliana). Loss of SLY1 results in GA-insensitive phenotypes including dwarfism, reduced fertility, delayed flowering, and increased seed dormancy. These sly1 phenotypes are partially rescued by overexpression of the SLY1 homolog SNEEZY (SNE)/SLY2, suggesting that SNE can functionally replace SLY1. GA responses are repressed by DELLA family proteins. GA relieves DELLA repression when the SCF(SLY1) (for Skp1, Cullin, F-box) E3 ubiquitin ligase ubiquitinates DELLA protein, thereby targeting it for proteolysis. Coimmunoprecipitation experiments using constitutively expressed 35S:hemagglutinin (HA)-SLY1 and 35S:HA-SNE translational fusions in the sly1-10 background suggest that SNE can function similarly to SLY1 in GA signaling. Like HA-SLY1, HA-SNE interacted with the CULLIN1 subunit of the SCF complex, and this interaction required the F-box domain. Like HA-SLY1, HA-SNE coimmunoprecipitated with the DELLA REPRESSOR OF GA1-3 (RGA), and this interaction required the SLY1 or SNE carboxyl-terminal domain. Whereas HA-SLY1 overexpression resulted in a decrease in both DELLA RGA and RGA-LIKE2 (RGL2) protein levels, HA-SNE caused a decrease in DELLA RGA but not in RGL2 levels. This suggests that one reason HA-SLY1 is able to effect a stronger rescue of sly1-10 phenotypes than HA-SNE is because SLY1 regulates a broader spectrum of DELLA proteins. The FLAG-SLY1 fusion protein was found to coimmunoprecipitate with the GA receptor HA-GA-INSENSITIVE DWARF1b (GID1b), supporting the model that SLY1 regulates DELLA through interaction with the DELLA-GA-GID1 complex.     

The Arabidopsis F-box protein SLEEPY1 targets gibberellin signaling repressors for gibberellin-induced degradation

The nuclear DELLA proteins are highly conserved repressors of hormone gibberellin (GA) signaling in plants. In Arabidopsis thaliana, GA derepresses its signaling pathway by inducing proteolysis of the DELLA protein REPRESSOR OF ga1-3 (RGA). SLEEPY1 (SLY1) encodes an F-box-containing protein, and the loss-of-function sly1 mutant has a GA-insensitive dwarf phenotype and accumulates a high level of RGA. These findings suggested that SLY1 recruits RGA to the SCFSLY1 E3 ligase complex for ubiquitination and subsequent degradation by the 26S proteasome. In this report, we provide new insight into the molecular mechanism of how SLY1 interacts with the DELLA proteins for controlling GA response. By yeast two-hybrid and in vitro pull-down assays, we demonstrated that SLY1 interacts directly with RGA and GA INSENSITIVE (GAI, a closely related DELLA protein) via their C-terminal GRAS domain. The rga and gai null mutations additively suppressed the recessive sly1 mutant phenotype, further supporting the model that SCFSLY1 targets both RGA and GAI for degradation. The N-terminal DELLA domain of RGA previously was shown to be essential for GA-induced degradation. However, we found that this DELLA domain is not required for protein-protein interaction with SLY1 in yeast (Saccharomyces cerevisiae), suggesting that its role is in a GA-triggered conformational change of the DELLA proteins. We also identified a novel gain-of-function sly1-d mutation that increased GA signaling by reducing the levels of the DELLA protein in plants. This effect of sly1-d appears to be caused by an enhanced interaction between sly1-d and the DELLA proteins.     

The Arabidopsis mutant sleepy1gar2-1 protein promotes plant growth by increasing the affinity of the SCFSLY1 E3 ubiquitin ligase for DELLA protein substrates

DELLA proteins restrain the cell proliferation and enlargement that characterizes the growth of plant organs. Gibberellin stimulates growth via 26S proteasome-dependent destruction of DELLAs, thus relieving DELLA-mediated growth restraint. Here, we show that the Arabidopsis thaliana sleepy1gar2-1 (sly1gar2-1) mutant allele encodes a mutant subunit (sly1gar2-1) of an SCF(SLY1) E3 ubiquitin ligase complex. SLY1 (the wild-type form) and sly1gar2-1 both confer substrate specificity on this complex via specific binding to the DELLA proteins. However, sly1gar2-1 interacts more strongly with the DELLA target than does SLY1. In addition, the strength of the SCFSLY1-DELLA interaction is increased by target phosphorylation. Growth-promoting DELLA destruction is dependent on SLY1 availability, on the strength of the interaction between SLY1 and the DELLA target, and on promotion of the SCFSLY1-DELLA interaction by DELLA phosphorylation.     

Regulation of the gibberellin pathway by auxin and DELLA proteins

The synthesis and deactivation of bioactive gibberellins (GA) are regulated by auxin and by GA signalling. The effect of GA on its own pathway is mediated by DELLA proteins. Like auxin, the DELLAs promote GA synthesis and inhibit its deactivation. Here, we investigate the relationships between auxin and DELLA regulation of the GA pathway in stems, using a pea double mutant that is deficient in DELLA proteins. In general terms our results demonstrate that auxin and DELLAs independently regulate the GA pathway, contrary to some previous suggestions. The extent to which DELLA regulation was able to counteract the effects of auxin regulation varied from gene to gene. For Mendel’s LE gene (PsGA3ox1) no counteraction was observed. However, for another synthesis gene, a GA 20-oxidase, the effect of auxin was weak and in WT plants appeared to be completely over-ridden by DELLA regulation. For a key GA deactivation (2-oxidase) gene, PsGA2ox1, the up-regulation induced by auxin deficiency was reduced to some extent by DELLA regulation. A second pea 2-oxidase gene, PsGA2ox2, was up-regulated by auxin, in a DELLA-independent manner. In Arabidopsis also, one 2-oxidase gene was down-regulated by auxin while another was up-regulated. Monitoring the metabolism pattern of GA₂₀ showed that in Arabidopsis, as in pea, auxin can promote the accumulation of bioactive GA.     

FKF1 F-box protein promotes flowering in part by negatively regulating DELLA protein stability under long-day photoperiod in Arabidopsis

FLAVIN‐BINDING KELCH REPEAT F‐BOX 1 (FKF1) encodes an F‐box protein that regulates photoperiod flowering in Arabidopsis under long‐day conditions (LDs). Gibberellin (GA) is also important for regulating flowering under LDs. However, how FKF1 and the GA pathway work in concert in regulating flowering is not fully understood. Here, we showed that the mutation of FKF1 could cause accumulation of DELLA proteins, which are crucial repressors in GA signaling pathway, thereby reducing plant sensitivity to GA in flowering. Both in vitro and in vivo biochemical analyses demonstrated that FKF1 directly interacted with DELLA proteins. Furthermore, we showed that FKF1 promoted ubiquitination and degradation of DELLA proteins. Analysis of genetic data revealed that FKF1 acted partially through DELLAs to regulate flowering under LDs. In addition, DELLAs exerted a negative feedback on FKF1 expression. Collectively, these findings demonstrate that FKF1 promotes flowering partially by negatively regulating DELLA protein stability under LDs, and suggesting a potential mechanism linking the FKF1 to the GA signaling DELLA proteins.     

Mutations in the F-box gene SNEEZY result in decreased Arabidopsis GA signaling

We previously reported that the SLEEPY1 (SLY1) homolog, F-box gene SNEEZY/SLEEPY2 (SNE/SLY2), can partly replace SLY1 in gibberellin (GA) hormone signaling through interaction with DELLAs RGA and GAI. To determine whether SNE normally functions in GA signaling, we characterized the phenotypes of two T-DNA alleles, sne-t2 and sne-t3. These mutations result in no apparent vegetative phenotypes, but do result in increased ABA sensitivity in seed germination. Double mutants sly1-t2 sne-t2 and sly1-t2 sne-t3 result in a significant decrease in plant fertility and final plant height compared to sly1-t2. The fact that sne mutations have an additive effect with sly1 suggests that SNE normally functions as a redundant positive regulator of GA signaling.Key words: gibberellin signaling, GA, SLEEPY1, SNEEZY, DELLA, F-box proteinThis paper describes genetic evidence that the SLEEPY1 (SLY1) homolog SNEEZY/SLEEPY2 (SNE/SLY2) functions redundantly with SLY1 to stimulate gibberellin signaling. GA responses such as seed germination, stem elongation and fertility are promoted by proteolysis of DELLA proteins, negative regulators of the GA signaling.¹ In the classic GA signaling model, GA binding to the GA receptor GID1 increases GID1 affinity for DELLA protein. This GID1-GA binding to DELLA causes SLY1, the F-box subunit of an SCF E3 ubiquitin ligase complex, to recognize, bind and ubiquitinate DELLA proteins thereby targeting them for destruction by the 26S proteasome. Thus, loss of SLY1 function results in decreased GA responses, causing dwarfism, delayed flowering, infertility and seed dormancy. The sly1 mutants over-accumulate DELLA proteins due to failure to destroy them through the ubiquitin-proteasome pathway.Overexpression of the SLY1 homolog, SNE, partially rescues the germination, dwarfism and infertility of the sly1-10 mutant.^2–4 SNE overexpression in the sly1-10 background is associated with reduced accumulation of DELLA proteins RGA and GAI, but not of DELLA RGL2. Co-immunoprecipitation assays demonstrated that SNE directly binds RGA protein as well as the cullin subunit of the SCF E3 complex. These recently published data suggest that SNE forms a functional SCF E3 ubiquitin ligase complex that negatively regulates a subset of the DELLA proteins regulated by SLY1.⁴The finding that SNE overexpression rescues sly1-10 phenotypes through down-regulation of DELLA RGA and GAI suggests that SNE is normally a positive regulator of GA signaling. If this is true, then we expect sne mutations to cause phenotypes resulting from reduced GA response including reduced germination, stature and fertility. To examine this hypothesis, three sne T-DNA mutants were identified: sne-t1, sne-t2 and sne-t3. The sne-t1 allele is a SALK line containing a T-DNA insertion 183-bp upstream of the coding region.⁵ This line showed no apparent phenotype and was not further characterized. The sne-t2 allele is a Sussman T-DNA line^4,6 containing a T-DNA insertion immediately before the ATG that is the SNE translational start codon (Fig. 1A). While this insertion does not disrupt the coding region, it likely disrupts SNE protein translation as the T-DNA contains multiple stop codons. The sne-t3 allele contains a T-DNA insertion within the SNE ORF before amino acid 146 of the 157 amino acid predicted protein (FLAG_461E03).^7,8 This allele should result in loss of the last 11 SNE amino acids. We know that loss of the last 8 SLY1 amino acids in sly1-10 results in dwarfism, suggesting that loss of the last 11 SNE amino acids may also cause some loss of function in the small F-box protein. When the homozygous sne-t2 and sne-t3 lines were compared to wild-type Ws, no change was observed either in final plant height or fertility measured in seeds/silique (Fig. 1B). An ABA dose-response curve in seed germination detected a small but reproducible increase in ABA sensitivity during seed germination of sne-t2 and sne-t3 (Fig. 1C). The fact that the sne-t2 and sne-t3 mutants, like sly1-2 and sly1-10, show increased ABA sensitivity suggests that SNE and SLY1 may have similar functions in GA signaling during seed germination.²Open in a separate windowFigure 1The phenotypes of sne-t2 and sne-t3 T-DNA mutants. (A) Schematic diagram of the sne-t2 T-DNA insertion at position −1 bp and of sne-t3 at position +435 bp with respect to the translation start site. (B) Final plant height (upper) and fertility (lower) of indicated genotypes. Letters indicate statistically different classes as determine by t-test. Bars represent standard error. (C) sne mutants show increase in ABA sensitivity. Seeds of wild-type Ws, sne-t2 and sne-t3 were after-ripened for 2 weeks then sown on MS-agar containing indicated concentrations of ABA as described by Steber et al.¹¹ Germination was scored based on radical emergence after incubating 3 days at 4°C followed by 14 days at 22°C. (D) Mutations in SNE cause no significant effect on DELLA RGA, GAI and RGL2 protein accumulation. Total protein was extracted from leaves of 12-d-old seedlings (Top) or flower buds (FB, bottom) and detected as described in Ariizumi et al.⁴One possible explanation for the lack of apparent GA-insensitive phenotypes in sne T-DNA insertion lines, is that SNE function is redundant with SLY1 in GA signaling.⁹ If so, we would expect sly1 sne double mutants to show stronger GA-insensitive phenotypes than the sly1 single mutation. Double mutants were constructed containing either the sne-t2 or sne-t3 mutation in the sly-t2 null background. The sly1-t2 allele was chosen because sly1-t2, sne-t2 and sne-t3 are all in the Ws ecotype. The sly1-t2 allele contains a T-DNA insertion within the F-box domain resulting in severe GA-insensitive phenotypes including failure to germinate, reduced stature and infertility.¹⁰ The sly1-t2 sne-t2 and sly1-t2 sne-t3 double mutants showed a small but significant decrease in final plant height and fertility (seeds/silique) compared to sly1-t2 (Fig. 1B). This increase in phenotype severity was not associated with an apparent increase in DELLA RGA, GAI or RGL2 protein accumulation (Fig. 1D). It could be that DELLA protein levels in sly1-t2 are so high that any slight increase due to sne mutations is undetectable. Our previous study of SNE overexpression lines showed that SNE has the ability to downregulate RGA and GAI protein accumulation. Figure 1 shows that the chromosomal SNE gene contributes to GA signaling presumably through ubiquitination of DELLA protein.Taken together, the fact that sne mutants show only mild GA-insensitive phenotypes and that the natural SNE expression cannot compensate for lack of SLY1, indicate that SLY1 is the main E3 ubiquitin ligase stimulating GA signaling (this study, reviewed in ref. ⁴). We cannot rule out the possibility that stronger SNE alleles would show either stronger GA response phenotypes or phenotypes that are unrelated to GA signaling. Indeed, there is evidence to suggest that SNE may have unique functions. The sne-t3 (sne-1) allele results in a shortened root phenotype.⁸ That SNE is expressed in the endodermis and quiescent center of the root whereas SLY1 is expressed in the stele, suggests that SNE may function independently in the root.⁸ Moreover, SNE overexpression, but not SLY1 overexpression, results in decreased apical dominance and a prone growth habit suggesting that SNE may play a unique role in development.^2,4 Our model is that in addition to regulating DELLA proteins RGA and GAI, SNE may also regulate a yet unidentified target involved in apical dominance (Fig. 2). Future research will need to elucidate the role of SNE in Arabidopsis growth and development.Open in a separate windowFigure 2Model for SNE function in Arabidopsis. Both SLY1 and SNE act as positive regulators of GA responses via DELLA protein destruction. SNE may negatively regulate an unknown protein that maintains apical dominance.     

Seed germination of GA-insensitive sleepy1 mutants does not require RGL2 protein disappearance in Arabidopsis

We explore the roles of gibberellin (GA) signaling genes SLEEPY1 (SLY1) and RGA-LIKE2 (RGL2) in regulation of seed germination in Arabidopsis thaliana, a plant in which the hormone GA is required for seed germination. Seed germination failure in the GA biosynthesis mutant ga1-3 is rescued by GA and by mutations in the DELLA gene RGL2, suggesting that RGL2 represses seed germination. RGL2 protein disappears before wild-type seed germination, consistent with the model that GA stimulates germination by causing the SCF(SLY1) E3 ubiquitin ligase complex to trigger ubiquitination and destruction of RGL2. Unlike ga1-3, the GA-insensitive sly1 mutants show variable seed dormancy. Seed lots with high seed dormancy after-ripened slowly, with stronger alleles requiring more time. We expected that if RGL2 negatively controls seed germination, sly1 mutant seeds that germinate well should accumulate lower RGL2 levels than those failing to germinate. Surprisingly, RGL2 accumulated at high levels even in after-ripened sly1 mutant seeds with 100% germination, suggesting that RGL2 disappearance is not a prerequisite for seed germination in the sly1 background. Without GA, several GA-induced genes show increased accumulation in sly1 seeds compared with ga1-3. It is possible that the RGL2 repressor of seed germination is inactivated by after-ripening of sly1 mutant seeds.     

Blue light-dependent interactions of CRY1 with GID1 and DELLA proteins regulate gibberellin signaling and photomorphogenesis in Arabidopsis

Cryptochromes are blue light photoreceptors that mediate various light responses in plants and mammals. In Arabidopsis (Arabidopsis thaliana), cryptochrome 1 (CRY1) mediates blue light-induced photomorphogenesis, which is characterized by reduced hypocotyl elongation and enhanced anthocyanin production, whereas gibberellin (GA) signaling mediated by the GA receptor GA-INSENSITIVE DWARF1 (GID1) and DELLA proteins promotes hypocotyl elongation and inhibits anthocyanin accumulation. Whether CRY1 control of photomorphogenesis involves regulation of GA signaling is largely unknown. Here, we show that CRY1 signaling involves the inhibition of GA signaling through repression of GA-induced degradation of DELLA proteins. CRY1 physically interacts with DELLA proteins in a blue light-dependent manner, leading to their dissociation from SLEEPY1 (SLY1) and the inhibition of their ubiquitination. Moreover, CRY1 interacts directly with GID1 in a blue light-dependent but GA-independent manner, leading to the inhibition of the interaction between GID1 with DELLA proteins. These findings suggest that CRY1 controls photomorphogenesis through inhibition of GA-induced degradation of DELLA proteins and GA signaling, which is mediated by CRY1 inhibition of the interactions of DELLA proteins with GID1 and SCF^SLY1, respectively.

Blue light-dependent interactions of CRY1 with GID1 and DELLA proteins inhibit gibberellin (GA)-induced degradation of DELLA proteins to regulate GA signaling and photomorphogenesis.