Auxin receptors: recent developments

Rapid advances have been made in the study of auxin binding proteins (ABPs) in the last five years. In particular, an ABP in maize membranes has been cloned, sequenced and both monoclonal and polyclonal antibodies to this ABP have been developed. Structural and functional analysis has begun and there is good electrophysiological evidence that ABP in the plasma membrane functions as a receptor, probably involved in auxin-induced cell expansion. The role of the large amount of ABP in the endoplasmic reticulum is less clear, as is the relationship to soluble ABPs. At present there is only some circumstantial evidence relating any ABP to cell division. Receptors for synthetic inhibitors of auxin transport (phytotropins) are also of interest in relation to auxin action, but are less well characterised. Identification of new naturally-occurring phytotropins could lead to novel plant growth regulators.     

Overexpression of the Auxin Binding PROTEIN1 Modulates PIN-Dependent Auxin Transport in Tobacco Cells

Background

Auxin binding protein 1 (ABP1) is a putative auxin receptor and its function is indispensable for plant growth and development. ABP1 has been shown to be involved in auxin-dependent regulation of cell division and expansion, in plasma-membrane-related processes such as changes in transmembrane potential, and in the regulation of clathrin-dependent endocytosis. However, the ABP1-regulated downstream pathway remains elusive.

Methodology/Principal Findings

Using auxin transport assays and quantitative analysis of cellular morphology we show that ABP1 regulates auxin efflux from tobacco BY-2 cells. The overexpression of ABP1can counterbalance increased auxin efflux and auxin starvation phenotypes caused by the overexpression of PIN auxin efflux carrier. Relevant mechanism involves the ABP1-controlled vesicle trafficking processes, including positive regulation of endocytosis of PIN auxin efflux carriers, as indicated by fluorescence recovery after photobleaching (FRAP) and pharmacological manipulations.

Conclusions/Significance

The findings indicate the involvement of ABP1 in control of rate of auxin transport across plasma membrane emphasizing the role of ABP1 in regulation of PIN activity at the plasma membrane, and highlighting the relevance of ABP1 for the formation of developmentally important, PIN-dependent auxin gradients.     

Altered Expression of Auxin-binding Protein 1 Affects Cell Expansion and Auxin Pool Size in Tobacco Cells

Auxin-binding protein 1 (ABP1) has an essential role in auxin-dependent cell expansion, but its mechanisms of action remain unknown. Our previous study showed that ABP1-mediated cell expansion is auxin concentration dependent. However, auxin distribution in plant tissue is heterogeneous, complicating the interpretation of ABP1 function. In this study, we used cells in culture that have altered expression of ABP1 to address the mechanism of ABP1 action at the cellular level, because cells in culture have homogeneous cell types and could potentially circumvent the heterogeneous auxin-distributions inherent in plant tissues. We found that cells overexpressing ABP1 had altered sensitivity to auxin and were larger, with nuclei that have undergone endoreduplication, a finding consistent with other data that support an auxin extracellular receptor role for ABP1. These cells also had a higher free auxin pool size, which cannot be explained by altered auxin transport. In cells lacking detectable ABP1, a higher rate of auxin metabolism was observed. The results suggest that ABP1 has, beyond its proposed role as an auxin extracellular receptor, a role in mediating auxin availability.     

Auxin binding protein: curiouser and curiouser

Auxin is implicated in a variety of plant developmental processes, yet the molecular mechanism of auxin response remains largely unknown. Auxin binding protein 1 (ABP1) mediates cell expansion and might be involved in cell cycle control. Structural modeling shows that it is a β-barrel dimer, with the C terminus free to interact with other proteins. We do not know where ABP1 performs its receptor function. Most ABP1 is detected within the endoplasmic reticulum but the evidence indicates that it functions at the plasma membrane. ABP1 is established as a crucial component of auxin signaling, but its precise mechanism remains unclear.     

Molecular analysis of auxin-specific signal transduction

The auxin-binding protein (ABP1) of maize has been purified, cloned and sequenced. Homologues have been found in a wide range of plants and at least seven ABP sequences from four different species are now known. We have developed a range of anti-ABP antibodies and these have been applied to analysis of the structure, localization and receptor function of ABP. ABP1 is a glycoprotein with two identical subunits of apparent M _r =22 kDa. The regions recognised by our five monoclonal antibodies (MAC 256–260) and by polyclonal antisera from our own and other laboratories have been specified by epitope mapping and fragmentation studies. All polyclonal anti-ABP sera recognise two or three dominant epitopes around the single glycosylation site. Two monoclonals (MAC 256, 259) are directed at the endoplasmic reticulum (ER) retention sequence KDEL at the C-terminus. Early biochemical data pointed to six amino acids likely to be involved in the auxin binding site. Inspection of the deduced sequence of ABP1 showed a hexapeptide (HRHSCE) containing five of these residues. Antibodies were raised against a polypeptide embracing this region and recognised ABP homologs in many species, suggesting that the region is highly conserved. This is confirmed by more recent information showing that the selected polypeptide contains the longest stretch of wholly conserved sequence in ABP1. Most strikingly, the antibodies show auxin agonist activity against protoplasts in three different electrophysiological systems-hyperpolarization of tobacco transmembrane potential; stimulation of outward ATP-dependent H⁺ current in maize; modulation of anion channels in tobacco. The biological activity of these antibodies indicates that the selected peptide does form a functionally important part of the auxin binding site and strongly supports a role for ABP1 as an auxin receptor. Although ABP contains a KDEL sequence and is located mainly in the ER lumen, the electrophysiological evidence shows clearly that some ABP must reach the outer face of the plasma membrane. One possible mechanism is suggested by our earlier demonstration that the ABP C-terminus recognised by MAC 256 undergoes an auxin-induced conformational change, masking the KDEL epitope and it is of interest that this C-terminal region appears to be important in auxin signalling [22]. So far we have been unable to detect the secretion of ABP into the medium of maize cell (bms) cultures reported by Jones and Herman [7]. However, recent silver enhanced immunogold studies on maize protoplasts have succeeded in visualizing ABP at the cell surface, as well as auxin-specific clustering of the signal induced within 30 minutes. The function of ABP in the ER, as well as the mechanisms of auxin signal transduction both at plasma membrane and gene levels remain to be elucidated.     

Development of Erect Leaves in a Modern Maize Hybrid is Associated with Reduced Responsiveness to Auxin and Light of Young Seedlings In Vitro

Modern corn (Zea mays L.) varieties have been selected for their ability to maintain productivity in dense plantings. We have tested the possibility that the physiological consequence of the selection involves changes in responsiveness to light and auxin.Etiolated seedlings of two older corn hybrids 307 and 3306 elongated significantly more than seedlings of a modern corn hybrid 3394. The level of endogenous auxin and activity of PAT in 307 and 3394 were similar. Hybrid 3394 shows resistance to auxin- and light-induced responses at the seedling, cell and molecular levels. Intact 3394 plants exhibited less responsiveness to the inhibitory effect of R, FR and W, auxin, anti-auxin and inhibitors of PAT. In excised mesocotyl tissue 3394 seedlings also showed essentially low responsiveness to NAA. Cells of 3394 were insensitive to auxin- and light-induced hyperpolarization of the plasma membrane. Expression of ABP4 was much less in 3394 than in 307, and in contrast to 307, it was not upregulated by NAA, R and FR. Preliminary analysis of abp mutants suggests that ABPs may be involved in development of leaf angle in corn.Our results confirm the understanding that auxin interacts with light in the regulation of growth and development of young seedlings and suggest that in corn ABPs may be involved in growth of maize seedlings and development of leaf angle. We hypothesize that ABP4 plays an important role in the auxin- and/or light-induced growth responses. We also hypothesize that in the modern corn hybrid 3394, ABP4 is “mutated,” which may result in the observed 3394 phenotypes, including upright leaves.Key Words: auxin, auxin-binding protein, growth, leaf angle, light, maize     

Auxin-binding proteins without KDEL sequence in the moss Funaria hygrometrica

Whereas the important plant growth regulator auxin has multiple effects in flowering plants, it induces a specific cell differentiation step in the filamentous moss protonema. Here, we analyse the presence of classical auxin-binding protein (ABP1) homologues in the moss Funaria hygrometrica. Microsomal membranes isolated from protonemata of F. hygrometrica have specific indole acetic acid-binding sites, estimated to be about 3–5 pmol/mg protein with an apparent dissociation constant (K _d) between 3 and 5 μM. Western analyses with anti-ABP1 antiserum detected the canonical endoplasmic reticulum (ER)-localised 22–24 kDa ABP1 in Zea mays, but not in F. hygrometrica. Instead, polypeptides of 31–33 and 46 kDa were labelled in the moss as well as in maize. In F. hygrometrica these proteins were found exclusively in microsomal membrane fractions and were confirmed as ABPs by photo-affinity labelling with 5-azido-[7-³H]-indole-3-acetic acid. Unlike the classical corn ABP1, these moss ABPs did not contain the KDEL ER retention sequence. Consistently, the fully sequenced genome of the moss Physcomitrella patens, a close relative of F. hygrometrica, encodes an ABP1-homologue without KDEL sequence. Our study suggests the presence of putative ABPs in F. hygrometrica that share immunological epitopes with ABP1 and bind auxin but are different from the classical corn ABP1.     

Auxin transport

Polar transport of auxin is essential for normal plant growth and development. On a cellular level, directional auxin transport is primarily controlled by an efflux carrier complex that is characterized by the PIN-FORMED (PIN) family of proteins. Detailed developmental studies of PIN distribution and subcellular localization have been combined with the analysis of changes in localized auxin levels to map PIN-mediated auxin movement throughout Arabidopsis tissues. Plant orthologs of mammalian multidrug-resistance/P-glycoproteins (MDR/PGPs) also function in auxin efflux. MDR/PGPs appear to stabilize efflux complexes on the plasma membrane and to function as ATP-dependent auxin transporters, with the specificity and directionality of transport being provided by interacting PIN proteins.     

Do we have the auxin receptor yet?

Several auxin-binding proteins (ABP) have now been identified using a variety of techniques. A 43-kDa glycoprotein thought to be a dimer of 22-kDa subunits has been identified as a strong candidate for the auxin receptor that mediates cell elongation in etiolated maize shoots. The primary sequence has been deduced and several interesting structural features have been discerned. There is indirect evidence that this 22-kDa ABP has a receptor function, the most compelling being that antibodies directed against the ABP can block an auxin-induced response. There is evidence that changes in auxin-induced growth capacity in shoots correlates with changes in the abundance of the 22-kDa ABP suggesting that in some cases the 22-kDa ABP may be limiting growth. Confirmation of receptor function for one of these newly-identified ABP's should open the way for genetic manipulation of crop growth.     

Auxin perception and signal transduction

The action of auxin on whole plants is very complex, but we are starting to understand how some of the earliest events are signalled in single cells. There is now good evidence that auxin induces rapid events at the plasma membrane by binding to a population of the auxin-binding protein ABPI, which is associated with a membrane-spanning docking protein, possibly a G-protein-coupled receptor (GPCR). ABPI is targeted to the endoplasmic reticulum (ER) lumen, but it does not appear to bind auxin within the ER and its function (if any) in this location is unknown. It is also not known how the protein reaches the cell surface, but it is possible that it is exported together with its docking protein. Binding of auxin causes a conformational change affecting the C-terminus of ABPI and it is likely that this change serves to activate the receptor at the plasma membrane. The signal transduction pathway appears to involve activation of phospholipase A₂(PLA₂) leading to the production of lipid second messengers which activate the plasma membrane proton ATPase (H⁻-ATPase) by a phosphorylation-dependent mechanism. Branch points exist that could potentially lead from this pathway to responses in the nucleus, but there is not yet any firm evidence that ABP1 is involved in such responses. Since intracellular auxin concentrations are correlated with sensitivity in some cases, it is possible that there is also a site of auxin perception inside the cell.     

AUXIN BINDING PROTEIN1: the outsider

AUXIN BINDING PROTEIN1 (ABP1) is one of the first characterized proteins that bind auxin and has been implied as a receptor for a number of auxin responses. Early studies characterized its auxin binding properties and focused on rapid electrophysiological and cell expansion responses, while subsequent work indicated a role in cell cycle and cell division control. Very recently, ABP1 has been ascribed a role in modulating endocytic events at the plasma membrane and RHO OF PLANTS-mediated cytoskeletal rearrangements during asymmetric cell expansion. The exact molecular function of ABP1 is still unresolved, but its main activity apparently lies in influencing events at the plasma membrane. This review aims to connect the novel findings with the more classical literature on ABP1 and to point out the many open questions that still separate us from a comprehensive model of ABP1 action, almost 40 years after the first reports of its existence.     

生长素输出载体PIN家族研究进展

生长素极性运输调控植物的生长发育。生长素极性运输主要依赖3类转运蛋白: AUX/LAX、PIN和ABCB蛋白家族。生长素在细胞间流动的方向与PIN蛋白在细胞上的极性定位密切相关。PIN蛋白由1个中心亲水环和2个由中心亲水环隔开的疏水区组成。中心亲水环上含多个磷酸化位点,其为一些蛋白激酶的靶点。PIN蛋白受多方面调控,包...     

生长素结合蛋白cDNA的克隆及其在烟草中的表达

基于拟南芥内质网生长素结合蛋白基因的cDNA序列,设计合成了Ap5和Ap3两个引物,应用RT－PCR技术扩增了拟南芥的ABP基因。将该基因克隆在植物表达载体p35SSIN的35S启动子和Nos3’端之间,得到植物表达载体p35SE。通过农杆菌个导的方法对烟草SR1进行了转化,由分子杂交等检测证明,生长素结合蛋白基因已在烟草中表达,同时转基因烟草后代对生长素的敏感性明显增加。     

Tracking Auxin Receptors Using Functional Approaches

Functional approaches toward the identification of auxin receptors developed along two major lines: the isolation and characterization of mutants or transgenic plants affected in their responses to the hormone and the study of early auxin effects at the cell level such as expression of specific genes or modifications of plasma membrane properties. The combination of these approaches with those aiming at the molecular characterization of auxin binding proteins as putative auxin receptors allowed to bring further insight into the mechanisms of auxin perception by plant cells. Studies of membrane responses to auxin clearly demonstrated the existence of elementary response chains to auxin at the plasma membrane, the activation of auxin responsive proteins leading to changes in the membrane potential via the stimulation of the proton pump ATPase or the modulation of ion channels. A two-component model is proposed for the organization of functional auxin perception units at the plasma membrane, comprising an auxin-binding moiety related to the major auxin-binding protein from maize (ZmER-abp1), associated to a transmembrane protein. Current research investigates the relevance of this model and tries to assess whether early responses at the plasma membrane share common perception or transduction steps with gene expression responses and participate in more integrated biological responses to auxin.     

A soluble auxin-binding protein from mung bean hypocotyls has indole-3-acetaldehyde reductase activity

To clarify the roles of auxin-binding proteins (ABPs) in the action of auxin, soluble auxin-binding proteins were isolated from an extract of etiolated mung bean hypocotyls by affinity chromatography on 2,4-dichlorophenoxyacetic acid (2,4-D)-linked Sepharose 4B. A 39-kDa polypeptide was retained on the affinity column and eluted with a solution containing IAA or 2,4-D, but not with a solution containing benzoic acid. The protein was then purified by several column-chromatographic steps. The apparent molecular mass of the protein was estimated to be 77 kDa by gel filtration and 39 kDa by SDS-PAGE. We designated this protein ABP39. The partial amino acid sequences of ABP39, obtained after chemical cleavage by CNBr, revealed high homology with alcohol dehydrogenase (ADH; EC 1.2.1.1). While the ABP39 was not capable of oxidizing ethanol, it did catalyze the reduction of indole-3-acetaldehyde (IAAld) to indole-3-ethanol (IEt) with an apparent K_m of 22 μ M. The IAAld reductase (EC 1.2.3.1) is specific for NADPH as a cofactor. The ABP39 also catalyzed the reduction of other aldehydes, such as acetaldehyde, benzaldehyde, phenylacetaldehyde and propionealdehyde. Indole-3-aldehyde was a poor substrate. The enzyme activity was inhibited by both indole-3-acetic acid and 2,4-D in a competitive manner. Therefore, the enzyme is considered to be retained on the affinity column by recognition of auxin structure.     

Living markers for actin block myosin-dependent motility of plant organelles and auxin

Expression-based techniques using recombinant actin-binding proteins (ABPs) have been developed as advantageous means of visualising actin filaments. As actin function is linked to the movement of cellular cargoes, and overexpression of ABPs may compete with endogenous cytoskeletal proteins, such as myosins, secondary effects on cellular motility might be observed during actin visualisation. Cytoplasmic streaming and auxin transport were chosen as examples of cargo movement and investigated in two Arabidopsis thaliana lines stably transformed with fluorescently labelled talin (GFP-mTn) or fimbrin (GFP-FABD2). In both lines, the maximal streaming velocity of organelles was reduced to 80% in hypocotyl epidermal cells, where actin was broadly equally labelled by both ABPs. In contrast, observations of streaming and actin organisation during treatments with cytochalasin D (CD) suggested GFP-mTn-labelled actin to remain more stable. Furthermore, basipetal auxin transport was undisturbed in the GFP-FABD2 line but reduced by GFP-mTn. Remarkably, treatments with CD and 2,3-butanedione monoxime, which immobilizes myosin by impairing its ATPase, produced not only failures in organelle movement but also in basipetal auxin transport in the wild-type. These observations suggest that myosin is involved in processes of auxin translocation. In parallel, reduced motility in transgenic plants may be explained by a disturbed acto-myosin interplay, if overexpressed ABPs block the processive movement of myosin along actin filaments. This report shows that the use of live markers for actin visualisation may affect motility of cellular compounds and underlines the general need for critical investigation of actin-related processes in wild-type as well as transgenic plants prior to further interpretation.     

The AUXIN BINDING PROTEIN 1 Is Required for Differential Auxin Responses Mediating Root Growth

Background

In plants, the phytohormone auxin is a crucial regulator sustaining growth and development. At the cellular level, auxin is interpreted differentially in a tissue- and dose-dependent manner. Mechanisms of auxin signalling are partially unknown and the contribution of the AUXIN BINDING PROTEIN 1 (ABP1) as an auxin receptor is still a matter of debate.

Methodology/Principal Findings

Here we took advantage of the present knowledge of the root biological system to demonstrate that ABP1 is required for auxin response. The use of conditional ABP1 defective plants reveals that the protein is essential for maintenance of the root meristem and acts at least on the D-type CYCLIN/RETINOBLASTOMA pathway to control entry into the cell cycle. ABP1 affects PLETHORA gradients and confers auxin sensitivity to root cells thus defining the competence of the cells to be maintained within the meristem or to elongate. ABP1 is also implicated in the regulation of gene expression in response to auxin.

Conclusions/Significance

Our data support that ABP1 is a key regulator for root growth and is required for auxin-mediated responses. Differential effects of ABP1 on various auxin responses support a model in which ABP1 is the major regulator for auxin action on the cell cycle and regulates auxin-mediated gene expression and cell elongation in addition to the already well known TIR1-mediated ubiquitination pathway.