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. 1994 Oct 17;13(20):4729–4736. doi: 10.1002/j.1460-2075.1994.tb06798.x

Auxin inducibility and developmental expression of axi 1: a gene directing auxin independent growth in tobacco protoplasts.

R Walden 1, H Hayashi 1, H Lubenow 1, I Czaja 1, J Schell 1
PMCID: PMC395411  PMID: 7957043

Abstract

We describe the characterization of axi 1, a tobacco gene isolated by activation T-DNA tagging which apparently plays a role in auxin action. Upon deregulated expression, axi 1 confers on protoplasts the ability to grow in culture not only in the absence of auxin but also in high auxin concentrations where maximal frequencies of cell division are not observed in wild-type protoplasts. In wild-type plants axi 1 is transcribed principally in root tissue. In the tagged plant line, axi 159, axi 1 RNA can be detected in all tissues tested. Freshly isolated wild-type protoplasts require auxin for the accumulation of detectable levels of axi 1 transcript and this precedes maximal levels of cell division. In contrast, axi 1 RNA appears in protoplasts isolated from axi 159 plants in the absence of auxin. axi 1 was localized to 6.2 kb of plant genomic DNA flanking the right T-DNA border sequence. axi 1 is interrupted by nine introns and in tobacco it is a member of a small gene family. Database searching reveals no similarity within the coding region with other genes. Sequences within the fourth intron are similar to those located in the non-coding regions of other plant genes, some of which are known to be auxin inducible. A DNA fragment containing the conserved sequence acts as an auxin responsive element in transient expression assays in wild-type protoplasts and this response is higher in axi 159 protoplasts. This suggests that auxin induced axi 1 expression may be mediated by a region contained within an intron sequence and that the axi 1 product might play a role in this induction.

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