RT Journal Article
SR Electronic
T1 The <em>ATE</em> Genes Are Responsible for Repression of Transdifferentiation into Xylem Cells in Arabidopsis
JF Plant Physiology
JO Plant Physiol.
FD American Society of Plant Biologists
SP 141
OP 148
DO 10.1104/pp.104.055145
VO 137
IS 1
A1 Sawa, Shinichrio
A1 Demura, Taku
A1 Horiguchi, Gorou
A1 Kubo, Minoru
A1 Fukuda, Hiroo
YR 2005
UL http://www.plantphysiol.org/content/137/1/141.abstract
AB We isolated three recessive mutants of Arabidopsis (Arabidopsis thaliana) showing ectopic expression of the xylem-specific marker, pAtxyn3::YFP. Genetic analysis indicated that the phenotypes were caused by mutations in three different genes, designated Abnormal Tracheary Element formation-related gene expression (ate1–3). The ate1 mutants showed a normal DR5::GUS gene expression pattern, and the ate1 mutation did not affect the abnormal vascular pattern formation in the van3 and pin1 mutants, indicating that the ate1 mutation does not affect the vascular pattern organization governed by auxin. The ate mutants showed ectopic lignin deposition, patterned secondary wall thickenings, and cell death, which are characteristic of mature tracheary elements (TEs) in cells ectopically expressing the pAtxyn3::YFP gene. Ectopic TE formation was rapidly induced in parenchymal tissue of the ate mutants in a TE-inducible system with excised hypocotyl. Furthermore, reverse transcription-polymerase chain reaction experiments showed that the expression of TE formation-related genes is up-regulated in the ate mutants. The ate1 mutation also caused ectopic expression of another xylem-specific marker gene, pAt3g62160::YFP. Overall, our results suggest that the ATE genes are responsible for the in situ repression of transdifferentiation into TEs in Arabidopsis and could be participants in the transdifferentiation-masking system.