The ABI1 and ABI2 protein phosphatases 2C act in a negative feedback regulatory loop of the abscisic acid signalling pathway

The Arabidopsis ABI1 and ABI2 genes encode two protein serine/threonine phosphatases 2C (PP2C). These genes have been originally identified by the dominant mutations abi1--1 and abi2--1, which reduce the plant's responsiveness to the hormone abscisic acid (ABA). However, recessive mutants of ABI1 were recently shown to be supersensitive to ABA, which demonstrated that the ABI1 phosphatase is a negative regulator of ABA signalling. We report here the isolation and characterisation of the first reduction-of-function allele of ABI2, abi2--1R1. The in vitro phosphatase activity of the abi2--1R1 protein is approximately 100-fold lower than that of the wild-type ABI2 protein. Abi2--1R1 plants displayed a wild-type ABA sensitivity. However, doubly mutant plants combining the abi2--1R1 allele and a loss-of-function allele at the ABI1 locus were more responsive to ABA than each of the parental single mutants. These data indicate that the wild-type ABI2 phosphatase is a negative regulator of ABA signalling, and that the ABI1 and ABI2 phosphatases have overlapping roles in controlling ABA action. Measurements of PP2C activity in plant extracts showed that the phosphatase activity of ABI1 and ABI2 increases in response to ABA. These results suggest that ABI1 and ABI2 act in a negative feedback regulatory loop of the ABA signalling pathway.     

The Arabidopsis ABSCISIC ACID-INSENSITIVE2 (ABI2) and ABI1 genes encode homologous protein phosphatases 2C involved in abscisic acid signal transduction.

Abscisic acid (ABA) mediates seed maturation and adaptive responses to environmental stress. In Arabidopsis, the ABA-INSENSITIVE1 (ABI1) protein phosphatase 2C is required for proper ABA responsiveness both in seeds and in vegetative tissues. To determine whether the lack of recessive alleles at the corresponding locus could be explained by the existence of redundant genes, we initiated a search for ABI1 homologs. One such homolog turned out to be the ABI2 locus, whose abi2-1 mutation was previously known to decrease ABA sensitivity. Whereas abi1-1 is (semi)dominant, abi2-1 has been described as recessive and maternally controlled at the germination stage. Unexpectedly, the sequence of the abi2-1 mutation showed that it converts Gly-168 to Asp, which is precisely the same amino acid substitution found in abi1-1 and at the coincidental position within the ABI1 phosphatase domain (Gly-180 to Asp). In vitro assays and functional complementation studies in yeast confirmed that the ABI2 protein is an active protein phosphatase 2C and that the abi2-1 mutation reduced phosphatase activity as well as affinity to Mg2+. Although a number of differences between the two mutants in adaptive responses to stress have been reported, quantitative comparisons of other major phenotypes showed that the effects of both abi1-1 and abi2-1 on these processes are nearly indistinguishable. Thus, the homologous ABI1 and ABI2 phosphatases appear to assume partially redundant functions in ABA signaling, which may provide a mechanism to maintain informational homeostasis.     

The abi1-1 mutation blocks ABA signaling downstream of cADPR action

Arabidopsis thaliana abscisic acid insensitive 1-1 (abi1-1) is a dominant mutant that is insensitive to the inhibition of germination and growth by the plant hormone, abscisic acid (ABA). The mutation severely decreases the catalytic activity of the ABI1 type 2C protein phosphatase (PP2C). However, the site of action of the abi1-1/ABI1 in the ABA signal transduction pathway has not yet been determined. Using single cell assays, we showed that microinjecting mutant abi1-1 protein inhibited the activation of RD29A-GUS and KIN2-GUS in response to ABA, cyclic ADP-ribose (cADPR), and Ca2+. The inhibitory effect of the mutant protein, however, was reversed by co-microinjection of an excess amount of the ABI1 protein. In transgenic Arabidopsis plants, overexpression of abi1-1 rendered the plants insensitive to ABA during germination, whereas overexpression of ABI1 did not have any apparent effect. Moreover, transgenic plants overexpressing abi1-1 were blocked in the induction of ABA-responsive genes; however, overexpression of ABI1 did not affect gene expression. Taken together, our results demonstrate that abi1-1 is likely to be a dominant negative mutation and ABI1 likely acts downstream of cADPR in the ABA-signaling pathway. Our results on ABI1 overexpression in Arabidopsis are not compatible with a negative regulatory role of this phosphatase in ABA responses.     

Importance of the B2 domain of the Arabidopsis ABI3 protein for Em and 2S albumin gene regulation

Genetic and molecular studies have shown that the Arabidopsis ABSCISIC ACID-INSENSITIVE3 (ABI3) protein plays a prominent role in the control of seed maturation. The ABI3 protein and its orthologues from various other plant species share four domains of high sequence identity, including three basic domains designated as B1, B2 and B3. The leaky abi3-1 mutation is a single amino acid substitution within the B3 domain. A new abi3 allele, abi3-7, was generated by mutagenizing abi3-1 seeds. The abi3-7 line contains, in addition to the abi3-1 mutation, a point mutation that converts residue Ala-458 into Thr within the B2 domain of the ABI3 protein. This Ala residue is absolutely conserved in all known ABI3 orthologues. Abi3-7 seeds display reductions in dormancy and in sensitivity to abscisic acid which are intermediate between those of the leaky abi3-1 and of the severe abi3-4 and abi3-5 mutants. Accumulation and distribution of At2S1 and At2S2 albumin mRNA as well as of AtEm1 and AtEm6 late embryogenesis-abundant proteins and mRNA have been analyzed. Both At2S1 and At2S2 mRNA are reduced in abi3-7, but distribution of At2S2 is spatially restricted. Accumulation of AtEm6 protein is more sensitive to abi3-7 mutation than AtEm1. However both mRNAs are considerably reduced in this mutant. Their distribution is also differentially affected. These results provide genetic evidence for the importance of the conserved B2 domain for ABI3 function in vivo.     

Blue light‐induced apoplastic acidification of Arabidopsis thaliana guard cells: Inhibition by ABA is mediated through protein phosphatases

The phytohormone abscisic acid (ABA) inhibits blue light‐induced apoplastic acidification of guard cells. The signal transduction pathway of ABA, mediating this response, was studied using ABA‐insensitive ( abi ) mutants of Arabidopsis thaliana . Apoplastic acidification was monitored with a flat tipped pH‐electrode placed on epidermal strips, in which only guard cells were viable. Blue light‐induced apoplastic acidification was reduced by vanadate and diethylstilbestrol (DES), indicating involvement of plasma membrane‐bound H⁺‐ATPases. In wild type epidermal strips, ABA reduced blue light‐induced acidification to 63%. The inhibition did not result from an increased cytoplasmic free Ca²⁺ concentration in guard cells, since factors that increase the Ca²⁺ concentration stimulated apoplastic acidification. Apoplastic acidification was not inhibited by ABA in abi1 and abi2 mutants. In abi1 epidermal strips ABA had no effect on the acidification rate, while it stimulated apoplastic acidification in abi2 . The ABA response in both mutants could be partially restored with protein kinase and phosphatase inhibitors. The abi1 guard cells became ABA responsive in the presence of okadaic acid, a protein phosphatase inhibitor. In abi2 guard cells the wild type ABA response was partially restored by K‐252a, a protein kinase inhibitor. Apoplastic inhibition is thus mediated through the protein phosphatases encoded by ABI1 and ABI2 . The results with protein kinase and protein phosphatase inhibitors indicate that ABI1 and ABI2 are involved in separate signal transduction pathways.     

ABI3 affects plastid differentiation in dark-grown Arabidopsis seedlings

The Arabidopsis ABSCISIC ACID-INSENSITIVE3 (ABI3) protein has been identified previously as a crucial regulator of late seed development. Here, we show that dark-grown abi3 plants, or abi3 plants returned to the dark after germination in the light, developed and maintained an etioplast with a prominent prolamellar body at developmental stages in which the wild type did not. Overexpression of ABI3 led to the preservation of the plastid ultrastructure that was present at the onset of darkness. These observations suggest that ABI3 plays a role in plastid differentiation pathways in vegetative tissues. Furthermore, the analysis of deetiolated (det1) abi3 double mutants revealed that DET1 and ABI3 impinge on a multitude of common processes. During seed maturation, ABI3 required DET1 to achieve its full expression. Mature det1 abi3 seeds were found to be in a highly germinative state, indicating that germination is controlled by both DET1 and ABI3. During plastid differentiation in leaves of dark-grown plants, DET1 is required for the action of ABI3 as it is during seed development. Together, the results suggest that ABI3 is at least partly regulated by light.     

ABI1 protein phosphatase 2C is a negative regulator of abscisic acid signaling.

The plant hormone abscisic acid (ABA) is a key regulator of seed maturation and germination and mediates adaptive responses to environmental stress. In Arabidopsis, the ABI1 gene encodes a member of the 2C class of protein serine/threonine phosphatases (PP2C), and the abi1-1 mutation markedly reduces ABA responsiveness in both seeds and vegetative tissues. However, this mutation is dominant and has been the only mutant allele available for the ABI1 gene. Hence, it remained unclear whether ABI1 contributes to ABA signaling, and in case ABI1 does regulate ABA responsiveness, whether it is a positive or negative regulator of ABA action. In this study, we isolated seven novel alleles of the ABI1 gene as intragenic revertants of the abi1-1 mutant. In contrast to the ABA-resistant abi1-1 mutant, these revertants were more sensitive than the wild type to the inhibition of seed germination and seedling root growth by applied ABA. They also displayed increases in seed dormancy and drought adaptive responses that are indicative of a higher responsiveness to endogenous ABA. The revertant alleles were recessive to the wild-type ABI1 allele in enhancing ABA sensitivity, indicating that this ABA-supersensitive phenotype results from a loss of function in ABI1. The seven suppressor mutations are missense mutations in conserved regions of the PP2C domain of ABI1, and each of the corresponding revertant alleles encodes an ABI1 protein that lacked any detectable PP2C activity in an in vitro enzymatic assay. These results indicate that a loss of ABI1 PP2C activity leads to an enhanced responsiveness to ABA. Thus, the wild-type ABI1 phosphatase is a negative regulator of ABA responses.     

The ABSCISIC ACID-INSENSITIVE3, FUSCA3, and LEAFY COTYLEDON1 loci act in concert to control multiple aspects of Arabidopsis seed development.

Previous studies have shown that recessive mutations at the Arabidopsis ABSCISIC ACID-INSENSITIVE3 (ABI3), FUSCA3 (FUS3), and LEAFY COTYLEDON1 (LEC1) loci lead to various abnormalities during mid-embryogenesis and late embryogenesis. In this study, we investigated whether these loci act in independent regulatory pathways or interact in controlling certain facets of seed development. Several developmental responses were quantified in abi3, fus3, and lec1 single mutants as well as in double mutants combining either the weak abi3-1 or the severe abi3-4 mutations with either fus3 or lec1 mutations. Our data indicate that ABI3 interacts genetically with both FUS3 and LEC1 in controlling each of the elementary processes analyzed, namely, accumulation of chlorophyll and anthocyanins, sensitivity to abscisic acid, and expression of individual members of the 12S storage protein gene family. In addition, both FUS3 and LEC1 regulate positively the abundance of the ABI3 protein in the seed. These results suggest that in contrast to previous models, the ABI3, FUS3, and LEC1 genes act synergistically to control multiple elementary processes during seed development.     

ABA plays a central role in mediating the regulatory effects of nitrate on root branching in Arabidopsis

The formation of lateral roots (LR) is a major post-embryonic developmental event in plants. In Arabidopsis thaliana, LR development is inhibited by high concentrations of NO3(-). Here we present strong evidence that ABA plays an important role in mediating the effects of NO3(-) on LR formation. Firstly, the inhibitory effect of NO3(-) is significantly reduced in three ABA insensitive mutants, abi4-1, abi4-2 and abi5-1, but not in abi1-1, abi2-1 and abi3-1. Secondly, inhibition by NO3(-) is significantly reduced, but not completely abolished, in four ABA synthesis mutants, aba1-1, aba2-3, aba2-4 and aba3-2. These results indicate that there are two regulatory pathways mediating the inhibitory effects of NO3(-) in A. thaliana roots. One pathway is ABA-dependent and involves ABI4 and ABI5, whereas the second pathway is ABA-independent. In addition, ABA also plays a role in mediating the stimulation of LR elongation by local NO3(-) applications.