William T. Jones

Plant hormones in arbuscular mycorrhizal symbioses: An emerging role for gibberellins

BACKGROUND AND AIMS Arbuscular mycorrhizal symbioses are important for nutrient acquisition in >80 % of terrestrial plants. Recently there have been major breakthroughs in understanding the signals that regulate colonization by the fungus, but the roles of the known plant hormones are still emerging. Here our understanding of the roles of abscisic acid, ethylene, auxin, strigolactones, salicylic acid and jasmonic acid is discussed, and the roles of gibberellins and brassinosteroids examined. METHODS Pea mutants deficient in gibberellins, DELLA proteins and brassinosteroids are used to determine whether fungal colonization is altered by the level of these hormones or signalling compounds. Expression of genes activated during mycorrhizal colonization is also monitored. KEY RESULTS Arbuscular mycorrhizal colonization of pea roots is substantially increased in gibberellin-deficient na-1 mutants compared with wild-type plants. This is reversed by application of GA3. Mutant la cry-s, which lacks gibberellin signalling DELLA proteins, shows reduced colonization. These changes were parallelled by changes in the expression of genes associated with mycorrhizal colonization. The brassinosteroid-deficient lkb mutant showed no change in colonization. CONCLUSIONS Biologically active gibberellins suppress arbuscule formation in pea roots, and DELLA proteins are essential for this response, indicating that this role occurs within the root cells.

A functionally required unfoldome from the plant kingdom: intrinsically disordered N-terminal domains of GRAS proteins are involved in molecular recognition during plant development

The intrinsic disorder is highly abundant in eukaryotic genomes. In the animal kingdom, numerous intrinsically disordered proteins (IDPs) have been characterized, especially in cell signalling and transcription regulation. An intrinsically disordered region often folds in different structures allowing an IDP to recognize and bind different partners at various binding interfaces. In contrast, there have only been a few reports of IDPs from the plant kingdom. Plant-specific GRAS proteins play critical and diverse roles in plant development and signalling and often act as integrators of signals from multiple plant growth regulatory inputs. Using computational and bioinformatics tools, we demonstrate here that the GRAS proteins are intrinsically disordered, thus forming the first functionally required unfoldome in the plant kingdom. Furthermore, the N-terminal domains of GRAS proteins are predicted to contain numerous Molecular Recognition Features (MoRFs), short interaction-prone segments that are located within extended disorder regions and are able to recognize their interacting partners and to undergo disorder-to-order transitions upon binding to these specific partners. Overlapping with the relatively conserved motifs in the N-terminal domains of GRAS proteins, these predicted MoRFs represent the potential protein–protein binding sites and may be involved in molecular recognition during plant development. This study enables us to propose a conceptual framework that guides future experimental approaches to understand structure–function relationships of the entire GRAS family.

Multifarious Roles of Intrinsic Disorder in Proteins Illustrate Its Broad Impact on Plant Biology

Intrinsically disordered proteins (IDPs) are highly abundant in eukaryotic proteomes. Plant IDPs play critical roles in plant biology and often act as integrators of signals from multiple plant regulatory and environmental inputs. Binding promiscuity and plasticity allow IDPs to interact with multiple partners in protein interaction networks and provide important functional advantages in molecular recognition through transient protein–protein interactions. Short interaction-prone segments within IDPs, termed molecular recognition features, represent potential binding sites that can undergo disorder-to-order transition upon binding to their partners. In this review, we summarize the evidence for the importance of IDPs in plant biology and evaluate the functions associated with intrinsic disorder in five different types of plant protein families experimentally confirmed as IDPs. Functional studies of these proteins illustrate the broad impact of disorder on many areas of plant biology, including abiotic stress, transcriptional regulation, light perception, and development. Based on the roles of disorder in the protein–protein interactions, we propose various modes of action for plant IDPs that may provide insight for future experimental approaches aimed at understanding the molecular basis of protein function within important plant pathways.

GRAS proteins: the versatile roles of intrinsically disordered proteins in plant signalling

IDPs (intrinsically disordered proteins) are highly abundant in eukaryotic proteomes and important for cellular functions, especially in cell signalling and transcriptional regulation. An IDR (intrinsically disordered region) within an IDP often undergoes disorder-to-order transitions upon binding to various partners, allowing an IDP to recognize and bind different partners at various binding interfaces. Plant-specific GRAS proteins play critical and diverse roles in plant development and signalling, and act as integrators of signals from multiple plant growth regulatory and environmental inputs. Possessing an intrinsically disordered N-terminal domain, the GRAS proteins constitute the first functionally required unfoldome from the plant kingdom. Furthermore, the N-terminal domains of GRAS proteins contain MoRFs (molecular recognition features), short interaction-prone segments that are located within IDRs and are able to recognize their interacting partners by undergoing disorder-to-order transitions upon binding to these specific partners. These MoRFs represent potential protein-protein binding sites and may be acting as molecular bait in recognition events during plant development. Intrinsic disorder provides GRAS proteins with a degree of binding plasticity that may be linked to their functional versatility. As an overview of structure-function relationships for GRAS proteins, the present review covers the main biological functions of the GRAS family, the IDRs within these proteins and their implications for understanding mode-of-action.

N-terminal Domains of DELLA Proteins Are Intrinsically Unstructured in the Absence of Interaction with GID1/Gibberellic Acid Receptors

The plant growth-repressing DELLA proteins (DELLAs) are known to represent a convergence point in integration of multiple developmental and environmental signals in planta, one of which is hormone gibberellic acid (GA). Binding of the liganded GA receptor (GID1/GA) to the N-terminal domain of DELLAs is required for GA-induced degradation of DELLAs via the ubiquitin-proteasome pathway, thus derepressing plant growth. However, the conformational changes of DELLAs upon binding to GID1/GA, which are the key to understanding the precise mechanism of GID1/GA-mediated degradation of DELLAs, remain unclear. Using biophysical, biochemical, and bioinformatics approaches, we demonstrated for the first time that the unbound N-terminal domains of DELLAs are intrinsically unstructured proteins under physiological conditions. Within the intrinsically disordered N-terminal domain of DELLAs, we have identified several molecular recognition features, sequences known to undergo disorder-to-order transitions upon binding to interacting proteins in intrinsically unstructured proteins. In accordance with the molecular recognition feature analyses, we have observed the binding-induced folding of N-terminal domains of DELLAs upon interaction with AtGID1/GA. Our results also indicate that DELLA proteins can be divided into two subgroups in terms of their molecular compactness and their interactions with monoclonal antibodies.

A system for tissue-specific copper-controllable gene expression in transgenic plants : nodule-specific antisense of aspartate aminotransferase-P2

A vector system, based on copper controllable gene expression, has been developed to give control over place as well as time of expression of an introduced gene. This system consists of two elements: (1) the yeastace1 gene encoding a metallo-regulatory transcription factor, ACE1, under control of either an organ-specific or a constitutive promoter; and (2) a gene of interest under control of a chimaeric promoter consisting of the 46 bp TATA fragment of the CaMV 35S RNA promoter linked to four repeats of the ACE1 binding site. The functioning of the system in an organ-specific manner was tested in nodulatedLotus corniculatus plants which consisted of non-transformed shoots plus transformed hairy root tissue ‘wild-type tops/transgenic roots’. After addition of copper ions to the plant nutrient solution, β-glucuronidase (GUS) expression was visualized either specifically in nodules or in both roots and nodules when theace1 gene was placed under control of thenod45 promoter or the CaMV 35S RNA promoter, respectively. The nodule-specific system was used to express antisense constructs of aspartate aminotransferase-P2 in transgenicLotus corniculatus plants. When expression was induced by the addition of copper ions to the plant nutrient solution aspartate aminotranferase-P2 activity declined dramatically, and a decrease of up to 90% was observed in nodule asparagine concentration.

Characterisation of the DELLA subfamily in apple (Malus x domestica Borkh.)

The hormone gibberellic acid (GA) regulates growth and development throughout the plant life cycle. DELLA proteins are key components of the GA signalling pathway and act to repress GA responses. The “DELLA” amino acid motif is highly conserved among diverse species and is essential for GA-induced destruction of DELLA proteins, which relieves repression. Six genes encoding the DELLA motif were identified within an apple expressed sequence tag (EST) database. Full-length cDNA clones were obtained by RACE and these were designated MdRGL1a/b, MdRGL2a/b, and MdRGL3a/b. Sequence alignment of the predicted proteins indicates that the MdDELLAs are 37–93% homologous to one another and 44–65% to the Arabidopsis DELLAs. The MdDELLAs cluster into three pairs, which reflect the presumed allopolyploid origins of the Maloideae. Expression analysis using quantitative real-time PCR indicates that all three pairs of MdDELLA mRNAs are expressed at the highest levels in summer arrested shoot tips and in autumn vegetative buds. Transgenic Arabidopsis expressing MdRGL2a have smaller leaves and shorter stems, take longer to flower in short days, and exhibit a reduced response to exogenous GA3, indicating significant conservation of gene function between DELLA proteins from apple and Arabidopsis.

Molecular cloning of a cDNA encoding aspartate aminotransferase-P2 from lupin root nodules

Two isoenzymic forms of aspartate aminotransferase are present in the plant fraction of developing lupin root nodules. One of these forms, aspartate aminotransferase-P2 (AAT-P2), increases dramatically with the onset of biological nitrogen fixation and is associated with the assimilation of ammonia by the plant in the Rhizobium-legume symbiosis. A day 18 lupin nodule cDNA library in the λZapII vector was immunoscreened with a monoclonal antibody specific for AAT-P2 and yielded two near-full-length 1700 bp clones. These clones were sequenced. Amino acid sequences from three peptides derived from immunopurified AAT-P2 were aligned, and showed 100% homology with the amino acid sequence deduced from the cDNA clones. The DNA sequence showed 50% homology with AAT sequences from a range of animal sources. Conversion of the clones to the phagemid form allowed their expression in Escherichia coli where both exhibited enzyme activity that could be immunoprecipitated with AAT-P2-specific monoclonal antibodies. Western blot analysis revealed protein moieties with molecular masses of 39, 43, 45 and 55 kDa. The 5′ end of the clones coded for a hydrophobic leader sequence of about 50 amino acids indicative of a targeting sequence and consistent with the plastid localisation of nodule AAT-P2.

Inter- and intra-molecular interactions of Arabidopsis thaliana DELLA protein RGL1.

The phytohormone gibberellin and the DELLA proteins act together to control key aspects of plant development. Gibberellin induces degradation of DELLA proteins by recruitment of an F-box protein using a molecular switch: a gibberellin-bound nuclear receptor interacts with the N-terminal domain of DELLA proteins, and this event primes the DELLA C-terminal domain for interaction with the F-box protein. However, the mechanism of signalling between the N- and C-terminal domains of DELLA proteins is unresolved. In the present study, we used in vivo and in vitro approaches to characterize di- and tri-partite interactions of the DELLA protein RGL1 (REPRESSOR OF GA1-3-LIKE 1) of Arabidopsis thaliana with the gibberellin receptor GID1A (GIBBERELLIC ACID-INSENSITIVE DWARF-1A) and the F-box protein SLY1 (SLEEPY1). Deuterium-exchange MS unequivocally showed that the entire N-terminal domain of RGL1 is disordered prior to interaction with the GID1A; furthermore, association/dissociation kinetics, determined by surface plasmon resonance, predicts a two-state conformational change of the RGL1 N-terminal domain upon interaction with GID1A. Additionally, competition assays with monoclonal antibodies revealed that contacts mediated by the short helix Asp-Glu-Leu-Leu of the hallmark DELLA motif are not essential for the GID1A–RGL1 N-terminal domain interaction. Finally, yeast two- and three-hybrid experiments determined that unabated communication between N- and C-terminal domains of RGL1 is required for recruitment of the F-box protein SLY1.

Competitive ELISA employing monoclonal antibodies specific for coronafacoyl amino acid conjugates

Coronatine (COR) is composed of two structural components, coronafacic acid (CFA) and the amino acid coronamic acid (CMA), linked by an amide bond. Monoclonal antibodies (MAbs) were prepared against COR and incorporated into competitive ELISAs. MAbs were secreted by hybridoma cells which had been prepared from mice immunized with COR and conjugated, through the free carboxyl group on CMA, to ovalbumin, the available amino groups of which had been increased by derivatization with propyl diamine via free carboxyl groups. COR and coronafacoyl valine could be quantified at 6.800 ng ml‐1(0.34–40 ng/assay) using peroxidase‐labelled MAb 8H3G2 in an indirect competitive ELISA. The corresponding limit of detection was 1 ng ml∼’. Reduction and subsequent acetylation of the ketone oxygen of the CFA moiety of COR reduced the affinity of MAb 8H3G2 some 250 times, whereas methylation of the free carboxyl group on COR slightly enhanced the affinity four‐fold. These and other results suggest that CFA and the amide bond a...