Two distinct signaling pathways participate in auxin-induced swelling of pea epidermal protoplasts

Protoplast swelling was used to investigate auxin signaling in the growth-limiting stem epidermis. The protoplasts of epidermal cells were isolated from elongating internodes of pea (Pisum sativum). These protoplasts swelled in response to auxin, providing the clearest evidence that the epidermis can directly perceive auxin. The swelling response to the natural auxin IAA showed a biphasic dose response curve but that to the synthetic auxin 1-naphthalene acetic acid (NAA) showed a simple bell-shaped dose response curve. The responses to IAA and NAA were further analyzed using antibodies raised against ABP1 (auxin-binding protein 1), and their dependency on extracellular ions was investigated. Two signaling pathways were resolved for IAA, an ABP1-dependent pathway and an ABP1-independent pathway that is much more sensitive to IAA than the former. The response by the ABP1 pathway was eliminated by anti-ABP1 antibodies, had a higher sensitivity to NAA, and did not depend on extracellular Ca(2+). In contrast, the response by the non-ABP1 pathway was not affected by anti-ABP1 antibodies, had no sensitivity to NAA, and depended on extracellular Ca(2+). The swelling by either pathway required extracellular K(+) and Cl(-). The auxin-induced growth of pea internode segments showed similar response patterns, including the occurrence of two peaks in the dose response curve for IAA and the difference in Ca(2+) requirements. It is suggested that two signaling pathways participate in auxin-induced internode growth and that the non-ABP1 pathway is more likely to be involved in the control of growth by constitutive concentrations of endogenous auxin.     

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.     

Alterations of auxin perception in rolB-transformed tobacco protoplasts. Time course of rolB mRNA expression and increase in auxin sensitivity reveal multiple control by auxin.

Expression and physiological effects of the root-inducing rolB gene of Agrobacterium rhizogenes T-DNA were studied simultaneously in tobacco (Nicotiana tabacum) mesophyll protoplasts. The kinetic study of the expression of rolB mRNA following exogenous auxin application showed that auxin transiently stimulated rolB expression, with mRNA levels starting to accumulate 6 to 9 h after auxin was supplied and increasing 300-fold after 12 to 18 h. The parallel study of the auxin sensitivity of rolB-transformed protoplasts, as assayed by their electrical response to the hormone, showed that the auxin treatment generated an increase in sensitivity by a factor of up to 100,000, whereas in untransformed protoplasts the same auxin treatment induced an increase in auxin sensitivity that never exceeded 30- to 50-fold. This reflects a strong cooperative effect of auxin and rolB in transformed protoplasts. Surprisingly, the maximal increase in sensitivity was observed several hours before the maximal accumulation of rolB mRNA, suggesting that the dramatic control of auxin sensitivity by auxin in rolB-transformed protoplasts requires only low levels of rolB expression. Antibodies directed against ZmER-abp1, the major auxin-binding protein from maize, differentially altered the auxin sensitivity of the electrical response of rolB-transformed and normal protoplasts. This suggests that alterations of the auxin reception-transduction pathway at the plasma membrane of rolB-transformed protoplasts may account for their increased auxin sensitivity.     

Elementary auxin response chains at the plasma membrane involve external abp1 and multiple electrogenic ion transport proteins

Studies of membrane electrical responses of isolated protoplasts to auxin have demonstrated the existence of elementary response chains to auxin at the plasma membrane, presently defined only by their uttermost ends. At one side, as demonstrated by several lines of evidence, the auxin perception unit involves proteins homologous to ZmER-abp1 (abp1), the most abundant auxin-binding protein from maize coleoptiles. At the other side, multiple ion transport proteins appear as targets of the auxin signal; the proton pump ATPase, an anion channel and potassium channels. We investigated early electrical responses to auxin at the plasma membrane of tobacco protoplasts. The work presented here will initially focus on abp1 and its functional role at the membrane. The C-terminus abp1 peptide (Pz151–163) was recently reported to modulate K⁺ currents at the plasma membrane of intact guard cells from broad bean [23] and induce plasma membrane hyperpolarisation of tobacco mesophyll protoplasts. These results further demonstrate that proteins involved in plasma membrane responses to auxin are related to maize abp1, and provide clues as to the region of the protein possibly involved in the interaction of abp1 with the plasma membrane. Secondly, this report concentrates on one of the targets of auxin, a voltage-dependent and ATP-regulated anion channel that we characterised on protoplasts from tobacco cell suspensions. This anion channel was specifically modulated by auxin, as already observed for the anion channel of guard cells [14]. Further work will be needed to assess if this auxin modulation involves a direct interaction between the hormone and the anion channel protein(s), or follows from the activation of a perception chain including abp1 homologues.     

Overexpression of auxin-binding protein enhances the sensitivity of guard cells to auxin

To explore the role of auxin-binding protein (ABP1) in planta, a number of transgenic tobacco (Nicotiana tabacum) lines were generated. The wild-type KDEL endoplasmic reticulum targeting signal was mutated to HDEL, another common retention sequence in plants, and to KEQL or KDELGL to compromise its activity. The auxin-binding kinetics of these forms of ABP1 were found to be similar to those of ABP1 purified from maize (Zea mays). To test for a physiological response mediated by auxin, intact guard cells of the transgenic plants were impaled with double-barreled microelectrodes, and auxin-dependent changes in K(+) currents were recorded under voltage clamp. Exogenous auxin affected inwardly and outwardly rectifying K(+) currents in a dose-dependent manner. Auxin sensitivity was markedly enhanced in all plants overexpressing ABP1, irrespective of the form present. Immunogold electron microscopy was used to investigate the localization of ABP1 in the transgenic plants. All forms were detected in the endoplasmic reticulum and the KEQL and KDELGL forms passed further across the Golgi stacks than KDEL and HDEL forms. However, neither electron microscopy nor silver-enhanced immunogold epipolarization microscopy revealed differences in cell surface ABP1 abundance for any of the plants, including control plants, which indicated that overexpression of ABP1 alone was sufficient to confer increased sensitivity to added auxin. Jones et al. ([1998] Science 282: 1114-1117) found increased cell expansion in transgenic plants overexpressing wild-type ABP1. Single cell recordings extend this observation, with the demonstration that the auxin sensitivity of guard cell K(+) currents is mediated, at least in part, by ABP1.     

The auxin signal for protoplast swelling is perceived by extracellular ABP1

Protoplasts of corn coleoptiles and Arabidopsis hypocotyls respond to the plant hormone auxin with a rapid change in volume. We checked the effect of antibodies directed against epitopes of auxin-binding protein 1 from Arabidopsis thaliana (AtERabp1) and Zea mays (ZmERabp1), respectively. Antibodies raised against the C-terminus of AtERabp1 inhibited the response to auxin, while antibodies raised against a part of box a, the putative auxin-binding domain, induced a swelling response similar to that caused by auxin treatment. Synthetic C-terminal oligopeptides of ZmERabp1 also caused a swelling response. These effects occurred regardless of whether the experiments were carried out with homologous (anti-AtERabp1 antibodies on Arabidopsis protoplasts or anti-ZmERabp1 antibodies in maize protoplasts) or heterologous immunological tools. The results indicate that the auxin signal for protoplast swelling is perceived by extracellular ABP1.     

The auxin-binding protein Nt-ERabp1 alone activates an auxin-like transduction pathway

Hyperpolarization of tobacco protoplasts is amongst the earliest auxin responses described. It has been proposed that the auxin-binding protein, ABP1, or a related protein could be involved in the first step of auxin perception at the plasma membrane. Using for the first time homologous conditions for interaction between the protein Nt-ERabp1 or a synthetic peptide corresponding to the C-terminus and tobacco protoplasts, we have demonstrated that both can induce the hyperpolarization response. The results show that Nt-ERabp1 or the C-terminal peptide alone activates the auxin pathway from the outer face of the plasma membrane.     

Patch-clamp analysis establishes a role for an auxin binding protein in the auxin stimulation of plasma membrane current in Zea mays protoplasts

The electrical response of Zea mays protoplasts to different auxins and to antibodies raised against an ER-located auxin binding protein from maize (Zm-ERabp1), was investigated using the patch-clamp technique (whole-cell configuration). Following a lag-phase of 30–40 seconds, indole-3-acetic acid and 1-naphthylacetic acid induced an outwardly directed current of positive charge in a concentration-dependent manner. This current was further increased by the fungal toxin fusicoccin (FC). The current was observed only in the presence of Mg²⁺-ATP in the patch-pipette and was abolished after addition of erythrosin B, an inhibitor of H⁺-ATPase, to the protoplasts indicating that the plasma membrane H⁺-ATPase is activated by auxins and fusicoccin. Addition of antibodies directed against Zm-ERabp1 abolished the current induced by auxins, without affecting the response of protoplasts to fusicoccin. Antibodies directed against a peptide representing part of the putative auxin binding domain of Zm-ERabp1 showed auxin agonist activity, stimulating an outwardly directed membrane current in the absence of auxin. These results suggest that (i) Zm-ERabp1 or antigenically related proteins represent a site for auxin perception through which the plasma membrane H⁺-ATPase is activated, and (ii) that the activation of the H⁺-ATPase by such proteins is initiated from outside the plasma membrane.     

The auxin-binding protein 1 is essential for the control of cell cycle

The phytohormone auxin has been known for >50 years to be required for entry into the cell cycle. Despite the critical effects exerted by auxin on the control of cell division, the molecular mechanism by which auxin controls this pathway is poorly understood, and how auxin is perceived upstream of any change in the cell cycle is unknown. Auxin Binding Protein 1 (ABP1) is considered to be a candidate auxin receptor, triggering early modification of ion fluxes across the plasma membrane in response to auxin. ABP1 has also been proposed to mediate auxin-dependent cell expansion, and is essential for early embryonic development. We investigated whether ABP1 has a role in the cell cycle. Functional inactivation of ABP1 in the model plant cell system BY2 was achieved through cellular immunization via the conditional expression of a single-chain fragment variable (scFv). This scFv was derived from a well characterized anti-ABP1 monoclonal antibody previously shown to block the activity of the protein. We demonstrate that functional inactivation of ABP1 results in cell-cycle arrest, and provide evidence that ABP1 plays a critical role in regulation of the cell cycle by acting at both the G1/S and G2/M checkpoints. We conclude that ABP1 is essential for the auxin control of cell division and is likely to constitute the first step of the auxin-signalling pathway mediating auxin effects on the cell cycle.     

The auxin-binding pocket of auxin-binding protein 1 comprises the highly conserved boxes a and c

The auxin-binding protein 1 (ABP1) has already been proved to be an extracellular receptor of auxin in single cell systems. Protoplasts of maize coleoptiles respond to auxin with an increase in volume. The 2-naphthaleneacetic acid (2-NAA), an inactive auxin analog, acts as an anti-auxin in protoplast swelling, as it suppresses the effect of indole-3-acetic acid (IAA). Antibodies raised against box a of ABP1 induce protoplast swelling in the absence of auxin. This response is inhibited by pre-incubation with 2-NAA. The effect of 2-NAA on swelling induced by agonistic antibodies appears to depend on the binding characteristics of the antibody. ScFv12, an antibody directed against box a, box c and the C-terminal domain of ABP1 also exhibits auxin-agonist activity which is, however, not abolished by 2-NAA. Neither does 2-NAA affect the activity of the C-terminal peptide of ABP1, which is predicted to interact with putative binding proteins of ABP1. These results support the view that box a and box c of ABP1 are auxin-binding domains.     

The rolB Gene of Agrobacterium rhizogenes Does Not Increase the Auxin Sensitivity of Tobacco Protoplasts by Modifying the Intracellular Auxin Concentration

Phenotypical alterations observed in rolB-transformed plants have been proposed to result from a rise in intracellular free auxin due to a RolB-catalyzed hydrolysis of auxin conjugates(J.J. Estruch, J. Schell, A. Spena [1991] EMBO J 10: 3125-3128).We have investigated this hypothesis in detail using tobacco (Nicotiana tabacum) mesophyll protoplasts isolated from plants transformed with the rolB gene under the control of its own promoter (BBGUS 6 clone) or the cauliflower mosaic virus 35S promoter (CaMVBT 3 clone). Protoplasts expressing rolB showed an increased sensitivity to the auxin-induced hyperpolarization of the plasma membrane when triggered with exogenous auxin. Because this phenotypical trait was homogeneously displayed over the entire population, protoplasts were judged to be a more reliable test system than the tissue fragments used in previous studies to monitor rolB gene effects on cellular auxin levels. Accumulation of free 1-[3H]-naphthaleneacetic acid (NAA) was equivalent in CaMVBT 3, BBGUS 6, and wild-type protoplasts, Naphthyl-[beta]-glucose ester, the major NAA metabolite in protoplasts, reached similar levels in CaMVBT 3 protoplasts, reached similar levels in CaMVBT 3 and normal protoplasts and was hydrolyzed at the same rate in BBGUS 6 and normal protoplasts. Furthermore, NAA accumulation and metabolism in BBGUS 6 protoplasts were independent of the rolB gene expression level. Essentially similar results were obtained with indoleacetic acid. Thus, it was concluded that the rolB-dependent behavior of transgenic tobacco protoplasts is not a consequence of modifying the intracellular auxin concentration but likely results from changes in the auxin perception pathway.     

The<Emphasis Type="Italic"> diageotropica</Emphasis> mutation of tomato disrupts a signalling chain using extracellular auxin binding protein 1 as a receptor

The diageotropica (dgt) mutant of tomato (Lycopersicon esculentum Mill.) is known to lack a number of typical auxin responses. Here we show that rapid auxin-induced growth of seedling hypocotyls is completely abolished by the mutation over the full range of auxin concentrations tested, and also in early phases of the time course. Protoplasts isolated from wild-type hypocotyls respond to auxin by a rapid increase in cell volume, which we measured by image analysis at a high temporal resolution. A similar swelling could be triggered by antibodies directed against a part of the putative auxin-binding domain (box-a) of the auxin-binding protein 1 (ABP1). Induction of swelling both by auxin and by the antibody was not observed in the protoplasts isolated from the dgt mutant. However, dgt protoplasts are able to respond to the stimulator of the H⁺-ATPase, fusicoccin, with normal swelling. We propose that dgt is a signal-transduction mutation interfering with an auxin-signalling pathway that uses ABP1 as a receptor.Abbreviations ABP auxin-binding protein - CCD charge-coupled device - 2,4-D 2,4-dichlorophenoxyacetic acid - dgt diageotropica - FC fusicoccin     

Auxin effect on the transmembrane potential difference of wild-type and mutant tobacco protoplasts exhibiting a differential sensitiity to auxin

The effects of 1-naphthaleneacetic acid (NAA) and other auxin analogs on the transmembrane potential difference (Em) were compared on tobacco protoplasts isolated from two genotypes differing in their sensitivity to auxins. For both types, NAA modifies Em by inducing at low doses a hyperpolarization, the amplitude of which increased with auxin concentration. Above an optimal concentration this hyperpolarization was reduced and even nullified. However, for the mutant type, this electrical response was shifted toward higher NAA concentrations, as its growth response. In the presence of structural analogs of auxin which have been showed to modify the dose-response curve for growth, the Em was altered: the growth-stimulatory molecule (picloram) initiated hyperpolarization, whereas the growth-inhibitory substance (4-bromophenylacetic acid) caused depolarization. These results provide evidence for a specific action of auxin at the membrane level related to its biological activity.     

Comparison of the growth promoting activities and toxicities of various auxin analogs on cells derived from wild type and a nonrooting mutant of tobacco

A naphthaleneacetic acid tolerant mutant isolated from a mutagenized culture of tobacco mesophyll protoplasts and impaired in root morphogenesis has been previously characterized by genetic analysis. To understand the biochemical basis for naphthaleneacetic acid resistance, cells derived from this mutant and from wild-type tobacco were compared for their ability to respond to various growth regulators. The growth promoting abilities and cytotoxicities of auxin analogs were different for mutant and wild-type cells. These different activities were not correlated with increased rate of conjugation or breakdown of the auxins by mutant cells. These observations, as well as previous studies on the interaction of the mutant with Agrobacterium, suggest that mutant resistance to auxins is not a result of a specific modification of the process by which auxins induce cell killing, but to a more general alteration of the cellular response to auxin. A screening of auxin-related molecules which induce cell death in wild-type cells but not mutant cells without promoting growth in either was performed. p-Bromophenyleacetic acid was found to display these characteristics.     

Plasmalemma hyperpolarity and culture of sense and antisenseabp transgenic tobacco protoplasts

The relationship among transfer and expression of auxin binding protein gene (abp), auxin (NAA)-induced plasmalemma hyperpolarity and sensibility to auxin during protoplast culture was studied by measuring transmembrane potential difference (Em) and culturing the protoplasts of sense and antisenseabp transgenic tobacco. The concentration of NAA inducing the highest degree of hyperpolarity of senseabp transgenic tobacco protoplasts was lower than the control, and in protoplast culture, their sensibility to auxin increased. The concentration of antisenseabp transgenic tobacco protoplasts was higher than the control, and in protoplast culture, their sensibility to auxin decreased. These results demonstrated that ABP synthesized in endoplasmic reticulum needed to transport to cell membrane and functioned there.     

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.     

Plasmalemma hyperpolarity and culture of sense and antisense abp transgenic tobacco protoplasts

Ａｕｘｉｎｉｓａｔｙｐｅｏｆｐｌａｎｔｈｏｒｍｏｎｅｅｘｉｓｔｉｎｇｅｘｔｅｎｓｉｖｅｌｙ[1].Ｉｔｒｅｇｕｌａｔｅｓｍａｎｙｐｒｏｃｅｓｓｅｓｉｎｐｌａｎｔｄｅｖｅｌｏｐｍｅｎｔ[2,3].Ａｃｃｏｒｄｉｎｇｔｏｔｈｅ“ａｃｉｄｇｒｏｗｔｈｔｈｅｏｒｙ”,ａｕｘｉｎｓｔｉｍｕｌａｔｅｓａｓｅｒｉｅｓｏｆｒｅａｃｔｉｏｎａｎｄｔｈｅｎｐｒｏｍｏｔｅｓｃｅｌｌｇｒｏｗｔｈｂｙｂｉｎｄｉｎｇｔｈｅＡＢＰｌｏｃａｔｅｄｉｎｃｅｌｌｍｅｍｂｒａｎｅ[4,5].Ｔｈｅｓｔｕｄｉｅｓｏｎｔｏｂａｃｃｏｍｕｔａｎｔｅｘｈｉ…     

A novel immunological approach establishes that the auxin-binding protein, Nt-abp1, is an element involved in auxin signaling at the plasma membrane.

Interactions of a collection of monoclonal antibodies (mAbs) to the recombinant Nicotiana tabacum auxin-binding protein 1 (Nt-abp1) were extensively characterized using surface plasmon resonance. Dynamic interaction studies using combinations of Nt-abp1, synthetic peptides corresponding to conserved sequences within auxin-binding proteins, and the mAbs have shown that a number of the mAbs recognized discontinuous epitopes revealing the junction of distinct domains in the folded protein. In particular, the two putative auxin binding domains and the C terminus of the protein were shown to interact with each other in the folded protein. Using the auxin-induced electrical response of tobacco protoplasts as a functional assay, all the mAbs exhibited either auxin antagonist or hormonomimetic properties. These effects, measured for the first time in homologous conditions, confirm that Nt-abp1 is present at the plasma membrane and is involved in the activation of the auxin-dependent electrical response of tobacco protoplasts. Based on our surface plasmon resonance data, we propose that the key event leading to the activation of this auxin electrical response consists of a conformational change in Nt-abp1.