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 (original) (raw)
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Plant physiology, 1994
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 equiv...
Plant Molecular Biology, 1991
In previous studies we have identified several mRNAs which accumulate after addition of 2,4-dichlorophenoxyacetic-acid (2,4-D) to auxin-starved tobacco cells [45, 46]. The mRNAs corresponding to cDNA clone pCNT103 were found to accumulate transiently prior to the cell division response due to auxin treatment. In this study we determined the sequences of three 103-like cDNAs and two 103-like genes, GNT1 and GNT35. To further study the regulation of the expression of these genes their 5' regions were translationally fused with the fl-D-glucuronidase reporter gene (GUS). The GNT1 5' region led to GUS expression only in the root tips of transgenic plants. By using transgenic hairy-root cultures and transformed cell suspension cultures it was shown that the 5' regions of both GNT1 and GNT35 lead to 2,4-D-inducible expression of GUS activity. The homology of the 103-like genes with other auxinregulated genes is evaluated.
1993
We have described the modulation of four auxin-regulated genes during the growth cycle of suspension-cultured tobacco (Nicotiana tabacum (LI var White Burley) cells. lhe genes were transiently expressed 2 to 8 h after transfer of stationary phase cells to fresh medium, during the transition from the quiescent phase of cells leaving the mitotic cycle to the synthesis phase of the cell cycle. After this transient induction, the cells showed a decreased sensi- tivity to auxin. Although the expression pattern suggests that in- duction of these genes might be important for cell division, over- production of antisense mRNA for one of these genes (pCNT103) did not influence cell division in transgenic tobacco cells. Further- more, stimuli such as salicylic acid were capable of inducing gene expression but were unable to restore cell division. Although these data do not conclusively exclude a role for these genes in cell division, their significance in this process is discussed in view of t...
An Auxin-Responsive Promoter Is Differentially Induced by Auxin Gradients during Tropisms
THE PLANT CELL ONLINE, 1991
We constructed a chimeric gene consisting of a soybean small auxin up RNA (SAUR) promoter and leader sequence fused to an Escherichia coli P-glucuronidase (GUS) open reading frame and a 3' untranslated nopaline synthase sequence from Agrobacterium tumefaciens. This chimeric gene was used to transform tobacco by Agrobacteriummediated transformation. In R2 etiolated transgenic tobacco seedlings, GUS expression occurred primarily in elongation regions of hypocotyls and roots. In green plants, GUS was expressed primarily in the epidermis and cortex of stems and petioles, as well as in elongation regions of anther filaments in developing flowers. GUS expression was responsive to exogenous auxin in the range of 10-* to 10m3 M. During gravitropism and phototropism, the GUS activity became greater on the more rapidly elongating side of tobacco stems. Auxin transport inhibitors and other manipulations that blocked gravitropism also blocked the asymmetric distribution of GUS activity in gravistimulated stems. Light treatment of dark-grown seedlings resulted in a rapid decrease in GUS activity. Lightinduced decay in GUS activity was fully reversed by application of auxin. Taken together, our results add support for the formation of an asymmetric distribution of auxin at sites of action during tropism.
Functional evidence for an auxin receptor at the plasmalemma of tobacco mesophyll protoplasts
Proceedings of the National Academy of Sciences, 1989
Tobacco mesophyll protoplasts were previously shown to respond to naphthaleneacetic acid by modifying their transmembrane potential difference. In the present work, evacuolated protoplasts were used to show that this response resides only at the plasmalemma. This electrical response was investigated by using polyclonal antibodies directed against plasma membrane antigens presumably involved in the reception and transduction of the auxin signal. An IgG fraction from an antiserum directed against the membrane auxin-binding protein from maize coleoptile completely inhibited the naphthaleneacetic acid-induced response of tobacco protoplasts. The suppression of the auxin-induced variation in the transmembrane potential difference by an IgG preparation directed against the plasmalemma ATPase from yeast demonstrated the involvement of the ATPase in the electrical response. Variation induced by fusicoccin in the transmembrane potential difference of tobacco protoplasts was unaffected by the anti-auxin-binding protein IgG fraction but was completely suppressed by the anti-ATPase IgG preparation. These results demonstrate the presence of a membrane receptor for auxin at the plasmalemma, the binding of the hormone to this receptor leading to the activation of the proton-pumping ATPase. They also show that at least the primary steps of activation by naphthaleneacetic acid are distinct from those of the fusicoccin-induced response.
Journal of Plant Growth Regulation, 2003
Transgenic Arabidopsis thaliana plants harboring the Agrobacterium tumefaciens phytohormone-biosynthetic genes iaaM and iaaH display an altered development indicative of elevated auxin levels. These plants exhibit an increased apical dominance, increased hypocotyl and petiole length and epinastic leaves and cotyledons. In addition, the transgenic plants display the formation of necrotic spots on leaves and bracts in soil and an altered behavior of axillary buds in tissue culture. Despite transcriptional activity of the iaaM and iaaH promoters in the vasculature of root tissue, root development of young iaaM/iaaH transgenic plants is identical to wild type. However, transgenic iaaM/iaaH plants grown under tissue culture conditions for a prolonged period display both vigorous and ectopic root growth. The level of free IAA in the rosette of the iaaM/iaaH transgenic plants is increased approximately 2-fold compared to wild type. The number of cells comprising the vascular tissue in hypocotyls and inflorescence stems of the transgenic plants is reduced and these plants exhibit a reduced basipetal polar auxin transport in the inflorescence stems. This reduced polar auxin transport probably accounts for the rapid auxin effect on the aerial part of the transgenic plants and the late effect on root development.