is the same as that on cauline leav

is the same as that on cauline leaves. In 35S:SPL10SRDX
plants, fl owers continued to produce trichomes on all
four sepals even in later developmental stages ( Fig. 3H ).
They gradually decreased on successive flowers, but the
timing was later than in the wild-type plants. These results
suggest that the morphological changes of cauline leaves
and fl owers associated with shoot maturation are delayed in
35S:SPL10SRDX plants.
To elucidate the function of SPL11 and SPL2 , we generated
transgenic plants that expressed chimeric repressors for
SPL11 or SPL2 ( 35S:SPL11SRDX , ProSPL11:SPL11SRDX and
35S:SPL2SRDX ). These plants showed reduced apical dominance
and delayed morphological change in the reproductive
phase similarly to 35S:SPL10SRDX plants (Supplementary
Fig. S4B–F). These results suggest that SPL10 , SPL11 and
SPL2 play a role in proper development of lateral organs in
association with shoot maturation during the reproductive
phase. Meanwhile, 35S:miR157b plants sometimes initiated
aerial rosette leaves (Supplementary Fig. S3B). This phenomenon
may represent severely delayed morphological
change from rosette leaves to cauline leaves, and reveal a
possible function for an SBP-box gene in shoot development
during the reproductive phase.
Loss-of-function mutants showed delayed shoot
development in reproductive development
To validate the function of SPL10 , SPL11 and SPL2 in shoot
development during the reproductive phases, we next analyzed
loss-of-function mutants for them with attention to
the reproductive phase. We could not fi nd T-DNA insertion
lines in the Col background but obtained them in the Ws
background (Supplementary Fig. S1). In addition to each
single mutant, we generated and analyzed spl10 spl2 and
spl11 spl2 double mutants. Full-length mRNA accumulation
in each homozygous mutant was blocked (Supplementary
Fig. S6A). Consistent with the results of the chimeric repressor-expressing
plants, cauline leaves and sepal trichomes
showed morphological defects, while apical dominance was
normal. The phenotypes were much weaker, even in the
double mutants, compared with 35S:SPL10/11/2SRDX plants,
although we could not compare them directly because they
have a different background and the decreasing rate of
trichome number on sepals in the Ws accession is lower than
that in the Col accession (Supplementary Fig. S5). To show
the change in lamina shape statistically, we investigated the
leaf index of cauline leaves, namely the ratio of leaf length to
leaf width ( Tsukaya 2002 ). In wild-type plants, leaves in later
stages of development had a large leaf index, i.e. narrower
cauline leaves are produced with shoot maturation. First
(basal) cauline leaves of the mutants were comparable
with those of the wild type, while the third cauline leaves
of the single mutants had a signifi cantly smaller leaf index
compared with the wild type, indicating that the mutants
had wider cauline leaves than wild-type plants (Fig. 4A ).
spl10 spl2 and spl11 spl2 double mutants had wider lamina
in the third cauline leaves than single mutants. These results
suggest that morphological change was delayed in the
mutants and that SPL10 , SPL11 and SPL2 act redundantly in
this process. In fl owers, the number of sepal trichomes
signifi cantly increased in every fl ower position of spl10
and spl2 mutants when compared with wild-type plants
( Fig. 4B ). The effect of the spl2 mutation was more obvious
than that of spl10 . spl10 spl2 double mutants had more
trichomes on sepals than each single mutant. On the other
hand, trichome numbers of spl11 and spl11 spl2 sepals were
comparable with those of the wild type and spl2 , respectively.
This might be due to compensation by SPL10 for the
impaired function of SPL11 . The analysis of the mutants
supported the results of 35S:SPL10/11/2SRDX plants. SPL10 ,
SPL11 and SPL2 play a redundant role in proper development
in association with shoot maturation during the
reproductive phase.