et al. 2003 , Matsui et al. 2005 ,

et al. 2003 , Matsui et al. 2005 , Mitsuda et al. 2005 , Mitsuda
et al. 2006 , Koyama et al. 2007 , Mitsuda et al. 2007 ). DNA
encoding the chimeric repressor, in which SPL10 was fused
to the repression domain (SRDX) in the C-terminus and
driven by the caulifl ower mosaic virus (CaMV) 35S promoter
( 35S:SPL10SRDX ), was transformed into Arabidopsis.
35S:SPL10SRDX plants showed morphological defects in
the reproductive phase. Of 76 T 1 transformants, 71 lines
(93.4 % ) showed less elongation of infl orescence stems after
fl oral transition and had an increased number of infl orescence
stems, which suggested reduced apical dominance
(Fig. 3A, B ). The other fi ve lines were phenotypically normal.
A reduced apical dominance phenotype has been observed
in miR156-overexpressing plants ( Schwab et al. 2005 , Wu
and Poethig 2006 , Schwarz et al. 2008 ). We found that
overexpression of miR157b , which has almost the same
sequence as miR156 , also caused reduced apical dominance
(Supplementary Fig. S3A). Within the reduced apical dominant
lines of 35S:SPL10SRDX, 44 lines (57.9 % ) had short
pedicels and 29 lines (38.2 % ) had short and shrunken fruits
( Fig. 3C, D ). We also expressed SPL10SRDX under the control
of the 1.9 kb SPL10 promoter ( ProSPL10:SPL10SRDX )
instead of the CaMV 35S promoter to examine the activity
of SPL10SRDX under similar conditions to that of native
SPL10. ProSPL10:SPL10SRDX plants showed a similar set of
morphological defects to 35S:SPL10SRDX plants, although
the appearance rates were low; reduced apical dominance,
short pedicel and short and shrunken fruits were observed
in 22 (47.8 % ), 17 (37.0 % ) and three (6.5 % ) lines of 46
transgenic plants, respectively (Supplementary Fig. S4A).
These results suggest that the phenotypes in 35S:SPL10SRDX
plants are not artifact effects such as regulation of off-target
genes by non-physiological expression levels. We used
35S:SPL10SRDX plants for further detailed studies.
35S:SPL10SRDX plants were also affected in the development
of cauline leaves. In the wild type, trichome distribution
of successive cauline leaves changes with shoot
maturation. Basal (early developed) cauline leaves produce
trichomes on both surfaces, and apical (later developed)
cauline leaves show a lack of trichomes on the adaxial side
( Telfer et al. 1997 ). Additionally, the lamina shape becomes
narrower with shoot maturation ( Tsukaya 1995 ). When the
traits of cauline leaves of the wild-type and 35S:SPL10SRDX
plants were compared in the same position, those of the
35S:SPL10SRDX plants had wider lamina than those of the
wild-type plants ( Fig. 3E, F ). Trichome number on the
adaxial surface of cauline leaves was >50 in 35S:SPL10SRDX
plants, while the average number in the wild type was 6.5
( n = 8). The increased number of trichomes was observed
even in a 35S:SPL10SRDX plant line with normal apical
dominance. Furthermore, trichome number on fl owers
also increased in 35S:SPL10SRDX plants. In the wild type,
trichomes develop on sepals, and their number gradually