a basic helix loop helix transcription factor controls ... · a basic helix loop helix...
TRANSCRIPT
A basic helix loop helix transcription factor controls cell growth
and size in root hairs
Keke Yi1,2, Benoît Menand
1,3, Elizabeth Bell
1, Liam Dolan
1,4
Supplementary note
Low soil phosphate availability (low phosphate stress) induces the elongation of root hairs 1
and enhances the capture of phosphate for plant growth 2. Plants grown in medium containing 10
µM phosphate are considered to be subject to low phosphate stress and root hairs are longer (698 ± 6 µm) than on plants grown with an adequate supply of phosphate (1000 µM phosphate) which develop shorter root hairs (338 ± 6 µm). To demonstrate a requirement for RSL4 in the
response to low phosphate, we compared root hair growth of rhd6-3 rsl1-1 double mutants and
rhd6-3 rsl1-1 rsl4-1 triple mutants in low phosphate. Low phosphate induces the development of a
few hairs in the rhd6-3 rsl1-1 mutant indicating that hairs could respond to the low phosphate
growth stimulus. In contrast no hairs developed on the rhd6-3 rsl1-1 rsl4-1 triple mutant
(Supplementary Fig. 8a). This indicates that RSL4 is required for the increase in root hair growth
that occurs when roots are grown in low phosphate. Further support for the role of RSL4 comes
from the observation that low phosphate stress did not induce growth in rsl2-1 rsl4-1 double
mutant (Supplementary Fig. 8a). Together, these data indicate that RSL4 activity is required for the
root hair growth response induced by low phosphate stress.
To confirm that low phosphate stress controls growth by modulating RSL4 activity, we
determined the RSL4 transcript and protein levels in roots grown under phosphate stress and
Nature Genetics: doi:10.1038/ng.529
control conditions. The levels of RSL4 transcript were 2 to 3 times higher in plants grown in
conditions where phosphate was in short supply compared to those grown in high phosphate,
while the transcript level of RSL2 did not change (Supplementary Fig. 8b). Furthermore, the
steady state levels of GFP-RSL4 protein increased under the low phosphate stress, while the levels
of GFP-RSL2 remain unchanged (Supplementary Fig. 8c). To verify that the induction of RSL4
was due to low phosphate and not another stress, we examined RSL4 induction under low
phosphate stress in plants with defective low phosphate stress root responses 3. LPR1 and LPR2
are multicopper oxidases involved in triggering the root response to low phosphate stress signal 3.
The root hair response to low phosphate is partially repressed in the lpr1 lpr2 double mutant (a
gift from Thierry Desnos, CEA Cadarache, France); wild type root hairs grown in low phosphate
stress are 100% longer than wild type hairs grown in control conditions. In contrast, the root hairs
of lpr1 lpr2 double mutants are only 40% longer in low phosphate than in high phosphate (lpr1
lpr2 HP: 350 ± 6 μm; lpr1 lpr2 LP: 489 ± 6 μm). As expected, the induction of RSL4
mRNA by low phosphate stress is defective in the lpr1 lpr2 double mutant background
(Supplementary Fig. 6b). These data indicate that low phosphate stress controls root hair length by
modulating steady state levels of RSL4 transcript and protein and requires the phosphate signalling
activity of LPR1 and LPR2.
1. Bates, T.R. & Lynch, J.P. Stimulation of root hair elongation in Arabidopsis thaliana by low
phosphorus availability. Plant, Cell & Environment 19, 529-538 (1996).
2. Bates, T.R. & Lynch, J.P. The efficiency of Arabidopsis thaliana (Brassicaceae) root hairs in
phosphorus acquisition. Am.J.Bot. 87, 964-970 (2000).
3. Svistoonoff, S. et al. Root tip contact with low-phosphate media reprograms plant root
architecture. Nat Genet 39, 792-796 (2007).
Nature Genetics: doi:10.1038/ng.529
Supplementary Fig. 1
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Supplementary Fig. 1 Expression pattern of RSL4. (a) The distribution of RSL4 protein partially
overlaps with RHD6. From left to right are GFP-RSL4, mCherry-RHD6, overlay and bright field;
(b) RSL4 mRNA was only present in the roots (R). No detectable mRNA transcript was present in
the rosette leaf (RL), cauline leaf (CL) stem (St) and flower (F); (c) GUS expression in an RSL4
gene trap line (CSHL_GT13756 from Cold Spring Harbor Laboratory) was detected only in the
root hair cells, not in any other tissues including shoots, leaves and flowers.
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Supplementary Fig. 2
Supplementary Fig. 2 qRT-PCR analysis of RSL4 relative expression levels in the RSL4 RNAi
lines. Values represent mean±s.d., n=3.
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Supplementary Fig. 3
Supplementary Fig. 3: Constitutive expression of RSL4 results in constitutive growth until root
hair cells undergo programmed cell death. (a) Root hair phenotype of Col-0 (left side) and a plant
transformed with 35S:RSL4 (right side) grown in half strength Johnson media. (b) Gray scale
pictures are DIC images of root hairs of Col-0 (left side) and 35S:RSL4 (right side). Colour images
above each DIC image are pseudo colour of root hairs grown in half strength Johnson media with
10 nM Rhodamine 123 showing the mitochondrial membrane potential (∆ψm). The ruler above
indicates the fluorescent intensity of the pseudo colour images. The absence of fluorescence
intensity is an indicator of cell death.
Nature Genetics: doi:10.1038/ng.529
Supplementary Fig. 4
Supplementary Fig. 4 Morphologies of 35S::RSL4 plants. Wild type (left) and 35S::RSL4 (right)
plants are morphologically identical except that the root hairs are much longer in the 35S::RSL4
plants.
Nature Genetics: doi:10.1038/ng.529
Supplementary Fig. 5
Supplementary Fig. 5: Nuclear volume is the same in wild type and in plants transformed with
35S::RSL4. DAPI staining of Col-0 and plants transformed with 35S::RSL4 root hairs indicates
that the nuclear size is the same in these two genotypes.
Nature Genetics: doi:10.1038/ng.529
Supplementary Fig. 6
Supplementary Fig. 6: RSL2 regulates root hair tip growth. (a) Root hair morphology of Col-0 (the
left panel) and rsl2-1 (the right panel). (b) Root hair length distributions of Col-0 and rsl2-1. (c)
GFP:RSL2 accumulates in initiating and growing root hair cells similarly to GFP:RSL4. (d) RSL2
is not a direct target of RHD6. qRT-PCR analysis of RNAs from rhd6-3 rsl1-1 harboring
GR:RHD6 treated with DEX for 2h (open bar), 24h (black bar) and DEX/CHX for 2h (hatched
bar).
Nature Genetics: doi:10.1038/ng.529
Supplementary Fig. 7
Supplementary Fig. 7: RSL2 and RSL4 regulate root hair development. (a) Cryo-SEM images of
Col-0 (left panel) and rsl2-1 rsl4-1 (right panel); (b) Genomic DNA fragments of RSL2 and RSL4
complement the rsl2 and rsl4 mutations.
Nature Genetics: doi:10.1038/ng.529
Supplementary Fig. 8
Supplementary Fig. 8: Low phosphate stress modulates RSL4 expression to control hair cell
growth. (a) Root hair morphologies of Col-0, rhd6-3 rsl1-1, rhd6-3 rsl1-1 rsl4-1 and rsl2-1 rsl4-1
under HP and LP treatments show that LP stress can induce root hair growth in Col-0 and rhd6-3
rsl1-1, but not in rhd6-3 rsl1-1 rsl4-1 and rsl2-1 rsl4-1. (b) qRT-PCR analysis of mRNAs isolated
from Col-0 and the lpr1 lpr2 double mutant under high phosphate and low phosphate treatments
show that the induction of RSL4 transcripts by low phosphate stress is compromised in the lpr1
lpr2 double mutant background. Values represent mean±s.d., n=3. (c) Pseudo colour images of GFP:RSL2 (upper panel) and GFP:RSL4 (lower panel) under high phosphate and low phosphate
treatments showing low phosphate stress induces the accumulation of RSL4 but not RSL2.
Nature Genetics: doi:10.1038/ng.529
Supplementary Fig. 9
Supplementary Fig. 9 RSL4 positively regulates the expression of genes that promote growth in
root hair cells. (a) Hierarchical clustering of the 83 genes positively regulated by RSL4. (b)
qRT-PCR analysis of AtEXP7, MRH3 and MRH4 expression from mRNAs isolated from plants
with wild type levels of RSL4 expression (Col-0, rsl2-1), higher levels of RSL4 expression
(35S::RSL4) or plants that lack RSL4 expression (rsl4-1 and rsl2-1 rsl4-1). These data show that
RSL4 positively regulates AtEXP 7, MRH3 and MRH4 expression. Values represent mean±s.d., n=3.
Nature Genetics: doi:10.1038/ng.529
Supplementary Fig. 10
Supplementary Fig. 10 A working model showing that RSL4 integrates the internal and external
signals to regulate root hair cell growth. The left diagram is a SEM picture of Arabidopsis primary
root. The white dot line marks the area where RHD6 and RSL1 are expressed in the root hair cells,
while the white line marks the area where RSL2 and RSL4 are expressed in the root hair cells. The
partial overlapping of these two white lines indicates the slight overlapping expression of RHD6
with RSL2 and RSL4. The black arrows indicate the genetic relationships.
Nature Genetics: doi:10.1038/ng.529
Supplementary Table 1 RSL4 positively regulated genes
Probe Set ID Fold change
(35S-RSL4 vs
Col-0)
P.Value Fold change
(Col-0 vs
rsl4-1)
P.Value AGI Gene Symbol Related to root
hair or not
261647_at 6.9774275 3.88E-08 32.11583 1.81E-08 AT1G27740 RSL4
261005_at 3.716045 6.76E-05 1.999287 0.004193 AT1G26420 FAD-binding domain-containing
protein
248374_at 3.6520593 0.002671 1.590485 1.31E-06 AT5G51870 AGL71
262564_at 3.1257668 0.000119 2.224049 0.000125 AT1G34330 putative peroxidase
246872_at 2.8688257 0.000416 2.035858 0.050767 AT5G26080 proline-rich family protein
253763_at 2.8459804 0.000111 1.561432 0.003106 AT4G28850 xyloglucan:xyloglucosyl transferase,
putative
261157_at 2.7505617 0.000111 2.409713 0.00033 AT1G34510 peroxidase, putative
259525_at 2.7038248 4.81E-05 1.614617 0.004123 AT1G12560 ATEXPA7 root hair
specific
expression
257418_at 2.6325424 0.000912 4.881911 1.4E-05 AT1G30850 RHS4 root hair
specific
expression
261185_at 2.6233034 7.64E-05 3.165163 0.001092 AT1G34540 CYP94D1
249934_at 2.5732727 0.001595 3.590064 0.000417 AT5G22410 RHS18 root hair
specific
expression
251176_at 2.5624392 0.004345 1.934799 0.00035 AT3G63380 calcium-transporting ATPase
263376_at 2.5410964 0.000209 2.443631 0.002455 AT2G20520 FLA6
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256352_at 2.4212208 0.000341 3.854431 2.29E-06 AT1G54970 RHS7/ATPRP1 root hair
specific
expression
254534_at 2.4156563 0.000717 2.610299 0.000494 AT4G19680 IRT2
263482_at 2.4023705 0.000376 2.348453 0.000115 AT2G03980 GDSL-motif lipase/hydrolase family
protein
245966_at 2.327236 0.000399 1.643065 0.010408 AT5G19790 RAP2.11 root hair
specific
expression
246991_at 2.3102367 0.003002 1.828836 0.007424 AT5G67400 RHS19 root hair
specific
expression
254107_at 2.2860358 5.08E-05 1.567657 0.002999 AT4G25220 RHS15 root hair
specific
expression
247871_at 2.2854035 0.000414 7.870044 5.47E-08 AT5G57530 xyloglucan:xyloglucosyl transferase,
putative
259720_at 2.2823784 0.000208 2.765547 0.003631 AT1G61080 proline-rich family protein
258765_at 2.1845784 0.000644 1.987284 0.001748 AT3G10710 RHS12 root hair
specific
expression
254338_s_at 2.1527658 0.000399 2.509884 0.007497 AT4G22080
///
AT4G22090
RHS14 root hair
specific
expression
264567_s_at 2.1359873 0.001321 2.427884 0.000235 AT1G05240
///
peroxidase, putative
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AT1G05250
245874_at 2.1276755 0.004988 3.314086 0.000955 AT1G26250 proline-rich extensin, putative
255516_at 2.1002178 0.001516 2.063465 0.000404 AT4G02270 RHS13 root hair
specific
expression
254025_at 2.0846293 0.000719 2.45537 1E-05 AT4G25790 allergen V5/Tpx-1-related family
protein
251410_at 2.056107 0.001227 3.141587 0.018312 AT3G60280 UCC3
247536_at 2.0454068 0.011561 1.905908 0.013521 AT5G61650 CYCP4;2
253613_at 1.987907 0.000794 3.441541 0.000265 AT4G30320 allergen V5/Tpx-1-related family
protein
249348_at 1.9292821 0.004165 2.502332 0.004223 AT5G40860 unknown protein
245967_at 1.9241055 0.00095 2.043032 0.000531 AT5G19800 hydroxyproline-rich glycoprotein
family protein
255307_at 1.907704 0.002567 3.185133 0.006978 AT4G04900 RIC10
259576_at 1.9030424 0.000208 1.852405 0.003631 AT1G35330 zinc finger (C3HC4-type RING finger)
family protein
249101_at 1.8985797 0.001383 2.088197 0.001704 AT5G43580 Predicted to encode a PR peptide
252833_at 1.894271 0.002298 2.06192 0.000693 AT4G40090 AGP3
263614_at 1.8699329 0.000777 2.407115 0.000189 AT2G25240 serine-type endopeptidase inhibitor
251970_at 1.8643738 0.04818 2.320804 0.059478 AT3G53150 UGT73D1
254044_at 1.8169075 0.002148 1.999282 0.000408 AT4G25820 XTR9
259120_at 1.7933358 0.011856 1.580698 0.000112 AT3G02240 unknown protein
247581_at 1.7881445 0.006449 2.498752 6.96E-05 AT5G61350 protein kinase family protein
264580_at 1.7870426 0.003211 1.720841 0.000189 AT1G05340 unknown protein
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250683_x_at 1.7841561 0.002009 2.10878 0.000611 AT5G06640 proline-rich extensin-like family
protein
249950_at 1.7841265 0.01353 2.024164 0.010165 AT5G18910 protein kinase family protein
262756_at 1.7839128 0.004474 1.681966 0.016099 AT1G16370 ATOCT6
247914_at 1.7706201 0.002671 5.805789 1.31E-06 AT5G57540 xyloglucan:xyloglucosyl transferase,
putative
266299_at 1.766686 0.003644 1.550043 0.013554 AT2G29450 ATGSTU5
264029_at 1.7581513 0.0051 2.433681 0.000408 AT2G03720 MRH6 defective in root
hair growth
259316_at 1.7478582 0.00539 1.656341 0.001116 AT3G01175 unknown protein
251226_at 1.73925 0.00132 2.14811 0.000154 AT3G62680 PRP3 root hair
specific
expression
255432_at 1.7323341 0.009001 1.533634 0.007428 AT4G03330 SYP123 root hair
specific
expression
261099_at 1.7313373 6.76E-05 1.516547 0.004193 AT1G62980 ATEXPA18 root hair
specific
expression
246969_at 1.7225919 0.011977 1.851566 0.000215 AT5G24880 unknown protein
262898_at 1.7206964 0.007433 2.236743 0.002399 AT1G59850 binding, biological process unknown
249868_at 1.7085866 0.006617 2.77432 0.004052 AT5G23030 TET12
245636_at 1.7032975 0.004988 2.074212 0.000955 AT1G25240 epsin N-terminal homology (ENTH)
domain-containing protein
246582_at 1.6940663 0.00095 1.635799 0.000531 AT1G31750 proline-rich family protein
262412_at 1.6918312 0.000829 1.500515 0.030982 AT1G34760 RHS5/GRF11 root hair
Nature Genetics: doi:10.1038/ng.529
specific
expression
248441_at 1.685181 0.055904 2.847512 0.02273 AT5G51270 protein kinase family protein
253244_at 1.6673543 0.007162 2.140779 0.001864 AT4G34580 COW1 defective in root
hair growth
254772_at 1.6536554 0.029042 4.478019 7.46E-07 AT4G13390 proline-rich extensin-like family
protein
255541_s_at 1.6480447 0.001516 1.59744 0.000404 AT4G01820
///
AT4G01830
PGP5
247531_at 1.6122633 0.00093 2.441822 7.74E-05 AT5G61550 protein kinase family protein
266765_at 1.606342 0.006123 2.501496 7.49E-05 AT2G46860 ATPPA3
262828_at 1.5926627 0.004474 1.504132 0.016099 AT1G14950 major latex protein-related /
MLP-related
250905_at 1.5886785 0.004345 1.807837 0.00035 AT5G03640 protein kinase family protein
267622_at 1.5838516 0.009955 1.774268 0.002433 AT2G39690 unknown protein
263028_at 1.5821946 0.007433 2.7072 0.002399 AT1G24030 protein kinase family protein
255140_x_at 1.5790453 0.00322 2.398313 0.015543 AT4G08410 proline-rich extensin-like family
protein
256283_at 1.5737044 0.002227 1.68598 0.007608 AT3G12540 unknown protein
261453_at 1.5729337 0.002537 3.329812 0.009046 AT1G21130 O-methyltransferase, putative
265102_at 1.5696362 0.005322 3.471569 0.001748 AT1G30870 cationic peroxidase
262517_at 1.5655074 0.007903 3.43951 1.79E-06 AT1G17180 ATGSTU25
261541_at 1.5557078 0.018363 1.861052 0.048122 AT1G63600 protein kinase-related
264775_at 1.554045 0.003211 1.510692 0.000189 AT1G22880 ATCEL5
246367_at 1.543545 0.00095 2.023907 0.000531 AT1G51880 RHS6 root hair
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specific
expression
255632_at 1.5423801 0.033234 1.786571 0.002352 AT4G00680 ADF8 root hair
specific
expression
248564_at 1.5420673 0.055904 2.058809 0.02273 AT5G49700 DNA-binding protein-related
258832_at 1.5399139 0.012022 2.925771 2.85E-05 AT3G07070 protein kinase family protein
267051_at 1.5304104 0.006123 2.006302 7.49E-05 AT2G38500 unknown protein
266743_at 1.5287263 0.005096 1.719269 0.013834 AT2G02990
///
AT2G16300
RNS1
249263_at 1.510736 0.006934 2.481844 0.019384 AT5G41730 protein kinase family protein
250632_at 1.5085515 0.002206 2.793871 3.1E-05 AT5G07450 CYCP4;3
263876_at 1.5048211 0.000777 1.551579 0.000189 AT2G21880 AtRABG2
Nature Genetics: doi:10.1038/ng.529
Supplementary Table 2 Primers used in this study
rsl2-1 LB F: CTCGTCCCCAATGGAACAAAGGT
rsl2-1 LB R: TAGCATCTGAATTTCATAACCAACTCGATACAC
rsl2-1 homozygote F: CTCGTCCCCAATGGAACAAAGGT
rsl2-1 homozygote R: CGAACGTGACTCTCCATTTCTCTCA
rsl4-1 LB F: GGGAACCGGTATTTTTGTTCGG
rsl4-1 LB R: TTGTAAGCCAATGGTGCGTACAT
rsl4-1 homozygote F: GAAAGCTTCGGTCACAAGTGTTAAA
rsl4-1 homozygote R: TTGTAAGCCAATGGTGCGTACAT
35SRSL4F(KpnI): cgg ggtacc ATGGACGTTTTTGTTGATGGT
35SRSL4R(BamHI): cgc ggatcc TCACATAAGCCGAGACAAAAG
PRSL2::GFP:RSL2
GFPattB1F GGGG ACA AGT TTG TAC AAA AAA GCA GGC TCA ATG AGT AAA GGA GAA GAA CTT TTC
Nature Genetics: doi:10.1038/ng.529
GFPattB2R GGGG AC CAC TTT GTA CAA GAA AGC TGG GTA TTT GTA TAG TTC ATC CAT GCC
RSL2P_ATTB4F: GGGG ACA ACT TTG TAT AGA AAA GTT G tgc atg tca cct ttc ttt gc
RSL2P _ATTB1R: GGGG AC TGC TTT TTT GTA CAA ACT TG a ttc tcc cat ggc ttc cat t
RSL2:3’UTRATTB2F: GGGG ACA GCT TTC TTG TAC AAA GTG G gg agc aac aac ctc gga gga at
RSL2:3’UTRATTB3R: GGGG AC AAC TTT GTA TAA TAA AGT TG g cca ctt tta aat gct ttg gac
PRSL4::GFP:RSL4
RSL4P_ATTB4F: GGGG ACA ACT TTG TAT AGA AAA GTT G at acg cgt tgg gct taa atg
RSL4P _ATTB1R: GGGG AC TGC TTT TTT GTA CAA ACT TG c aaa aac gtc cat cgc tct
RSL4:3’UTRATTB2F: GGGG ACA GCT TTC TTG TAC AAA GTG G tg gac gtt ttt gtt gat ggt
RSL4:3’UTRATTB3R: GGGG AC AAC TTT GTA TAA TAA AGT TG acgatacggtttggtttgactaat
PRHD6::mCherry:RHD6
mCherryattB1F GGGG ACA AGT TTG TAC AAA AAA GCA GGC TTA atg gtg agc aag ggc gag ga
mCherryattB2R GGGG AC CAC TTT GTA CAA GAA AGC TGG GT A CTT GTA CAG CTC GTC CAT GCC G
Nature Genetics: doi:10.1038/ng.529
RHD6P_ATTB4F GGGG ACA ACT TTG TAT AGA AAA GTT Gtt ctc aaa gag gga caa gac caa agc cca tga c
RHD6P_ATTB1R GGGG AC TGC TTT TTT GTA CAA ACT TGc tag aca cta ata agt ttg ata agt gat ttt ttg t
RHD6:3’UTRATTB2F GGGG ACA GCT TTC TTG TAC AAA GTG Gcc atg gca ctc gtt aat gac cat ccc aac gag a
RHD6:3’UTRATTB3R GGGG AC AAC TTT GTA TAA TAA AGT TGc tga taa atc gag atc tta ggt atg tcg tcc
GR ATTB1F GGGG ACA AGT TTG TAC AAA AAA GCA GGC T CT ATG GAT CCT GAA GCT CGA AAA ACA
AA
GR ATTB2R GGGG AC CAC TTT GTA CAA GAA AGC TGG GTT TTT TTG ATG AAA CAG AAG CTT TTT G
RSL2 genomic DNA
RSL2genomicUATTB1: GGGG ACA AGT TTG TAC AAA AAA GCA GGC T tgcatgtcacctttctttgc
RSL2genomicLATTB2: GGGG AC CAC TTT GTA CAA GAA AGC TGG GT gccacttttaaatgctttggac
RSL4 genomic DNA
RSL4genomicUATTB1: GGGG ACA AGT TTG TAC AAA AAA GCA GGC T at acg cgt tgg gct taa atg
RSL4genomicLATTB2: GGGG AC CAC TTT GTA CAA GAA AGC TGG GT acgatacggtttggtttgactaat
Nature Genetics: doi:10.1038/ng.529
qRT-PCR primers
RSL2-F TCCCCAATGGAACAAAGGTC
RSL2-R TCTCGGTGAGCTGAGACCAA
RSL4-F GTGCCAAACGGGACAAAAGT
RSL4-R TTGTGATGGAACCCCATGTC
AtEXP7-F ATCCCAGTTGCATACCGAAG
AtEXP7-R TATCCAATTCGTCCGGCTAC
MRH3-pair1-F GATGACCTAGACCACCACTAT
MRH3-pair1-R GCCTTCAATTCCAGGACTTGAC
MRH4-pair1-F CGAGGGTTGGCTCTGTCC
MRH4-pair1-R GGTGGTGATTGTTGTGTTGAC
EF1α-F GGTGGTGGCATCCATCTTGTTACA
EF1α-R TGAGCACGCTCTTCTTGCTTTCA
Nature Genetics: doi:10.1038/ng.529