ARTICLE

Received 7 Sep 2011 | Accepted 31 Jan 2012 | Published 20 Mar 2012 DOI: 10.1038/ncomms1716

Qibing Lin1,*, Dan Wang1,*, Hui Dong2,*, Suhai Gu1, Zhijun Cheng1, Jie Gong2, Ruizhen Qin1, Ling Jiang2, Gang Li3, Jiu Lin Wang1, Fuqing Wu1, Xiuping Guo1, Xin Zhang1, Cailin Lei1, Haiyang Wang1 & Jianmin Wan1,2

Rice MONOCULM 1 (MOC1) and its orthologues LS/LAS (lateral suppressor in tomato and Arabidopsis) are key promoting factors of shoot branching and tillering in higher plants. However, the molecular mechanisms regulating MOC1/LS/LAS have remained elusive. Here we show that the rice tiller enhancer (te) mutant displays a drastically increased tiller number. We demonstrate that TE encodes a rice homologue of Cdh1, and that TE acts as an activator of the anaphase promoting complex/cyclosome (APC/C) complex. We show that TE coexpresses with MOC1 in the axil of leaves, where the APC/CTE complex mediates the degradation of MOC1 by the ubiquitin26S proteasome pathway, and consequently downregulates the expression of the meristem identity gene Oryza sativa homeobox 1, thus repressing axillary meristem initiation and formation. We conclude that besides having a conserved role in regulating cell cycle, APC/ CTE has a unique function in regulating the plant-specic postembryonic shoot branching and tillering, which are major determinants of plant architecture and grain yield.

Rice APC/CTE controls tillering by mediating the degradation of MONOCULM 1

1 National Key Facility for Crop Gene Resources and Genetic Improvement, Institute of Crop Science, Chinese Academy of Agricultural Sciences, Beijing 100081, China. 2 National Key Laboratory for Crop Genetics and Germplasm Enhancement, Jiangsu Plant Gene Engineering Research Center, Nanjing Agricultural University, Nanjing 210095, China. 3 Department of Molecular, Cellular, and Developmental Biology, Yale University, New Haven, Connecticut 06520-8104, USA. *These authors contributed equally to this work. Correspondence and requests for materials should be addressed to J.W. (email: [email protected]).

NATURE COMMUNICATIONS | 3:752 | DOI: 10.1038/ncomms1716 | www.nature.com/naturecommunications

2012 Macmillan Publishers Limited. All rights reserved.

ARTICLE

NATURE COMMUNICATIONS | DOI: 10.1038/ncomms1716

Targeted protein degradation through the ubiquitinprotea-some system is a major regulatory mechanism of cell-cycle progression. Cdh1 (also known as Hct1 in budding yeast,

Ste9 or Srw1 in ssion yeast, Fzr in human and CCS52 in plants) is a substrate-recognition and -binding factor of the multimeric APC/C E3 ubiquitin ligase1. It is thought that Cdh1 activates APC/C in late mitosis and during G0/G1 by targeted degradation of key cell-cycle regulators (such as cyclins or inhibitors of cyclin-dependent kinases) by the 26S proteasome to promote mitotic exit, maintain G0/G1 phase and regulate the endocycle in animals17. Studies in Arabidopsis thaliana, legumes and tomato have also demonstrated that APC/CCCS52 regulates cell division, cell expansion, endocycle and root meristem maintenance3,4,812. However, other than mitotic cyclins, no substrates of APC/CCCS52 have been identied yet, and the regulatory mechanisms of APC/CCCS52 have remained essentially unknown in plants.

Tillering and branching, the formation of lateral shoots, is an important determinant of plant architecture and crop yield13,14, and a complex process that is regulated by several genetic pathways1521. The rice gene MOC1 and its orthologues LS/LAS encode transcriptional regulators of the GRAS family and are key promoting factors of tillering and branching in both monocot and dicot species1517. Previous studies have shown that the LAS and MOC1 act upstream of SHOOT-MERISTEMLESS (STM) in Arabidopsis and OSH1 (the homologue of Knotted-1 in maize) during the initiation and establishment of AM16,17,2224. However, the regulatory mechanisms of MOC1/LS/LAS have remained elusive.

Here we report the identication of a tiller enhancer (te) mutant with many more tillers than wild-type rice. We show that TE is a rice homologue of Cdh1, and it acts as an activator of APC/C to control rice tillering by mediating the degradation of MOC1 protein and, subsequently, reducing the expression of the meristem identity gene OSH1. Our results provide new insights into the function and regulatory mechanisms of APC/CTE(Cdh1) E3 ligases in higher plants.

ResultsThe te mutant displays the pleiotropic phenotypes. Rice-plant architecture is crucial for grain yield and is determined by tiller number and angle, plant height, panicle morphology, leaf structure and root systems13,25. To identify new regulators of rice architecture, we isolated the rice te mutant from a mutant pool26. te had a similar number of tillers as wild-type (WT) plants till the seventh leaf stage (Fig. 1a). However, by the heading stage, the total tiller number of te was about 3-fold that of WT, resulting from additional tillers produced on both low nodes and high nodes (Fig. 1bd). In addition to increased tillers, the te mutant shows a dwarf phenotype with much shorter internodes IIV (Fig. 1e,f). Microscopy observation revealed that the shortening of te stem was mainly due to a reduction in cell number, as the cell sizes in internodes were largely comparable between WT and te (Fig. 1g,h). Moreover, the te mutant also displays a twisted ag leaf and panicle phenotype (Fig. 1ik).

TE encodes a rice homologue of Cdh1. We used a map-based approach to place the TE locus within a 23-kb DNA region on the BAC098695 clone of chromosome 3, which contains four predicted genes. Two mutations, a deletion of nucleotide 38 (C) and a substitution of nucleotide 40 (CG) downstream of the ATG initiation codon, were identied in the rst exon of one of the predicted genes (LOC_Os03g03150) (Fig. 1l). These mutations result in a frame-shi and a 216-amino acid truncated protein product (Supplementary Fig. S1). Genetic complementation showed that a genomic fragment containing the wild-type DNA (pGTE) completely rescued the te mutant phenotypes (Fig. 1m). We thus concluded that LOC_Os03g03150 corresponds to the TE gene. Sequence and phylogenetic analyses revealed that TE encodes a rice homologue of Cdh1 class proteins with a conserved WD-40 repeats domain and

four motifs (C-box, CSM, RVL and IR) commonly found in other Cdh1 homologues (Supplementary Figs S1 and S2).

Quantitative reverse transcriptasePCR analysis revealed that TE is widely expressed in roots, shoots, leaves and panicles (Fig. 2a). RNA in situ hybridization analysis demonstrated that TE is primarily expressed in the AM in axils from P1 to P5 leaf stage, shoot apical meristem and root meristem, and actively proliferative tissues such as young leaves (Fig. 2be). Thus, the expression pattern of TE is consistent with the phenotypes of te mutant.

As reported for other Cdh1 homologues such as AtCCS52A1 and AtCCS52A28, transient expression analysis in Arabidopsis protoplasts revealed that the TEGFP fusion protein is predominantly targeted to the nucleus (Fig. 2f). Overexpression of TE in Schizosaccharomyces pombe inhibited cell division and caused cell enlargement (Fig. 3a,b). Consistent with this observation, ow cytometry and 4,6-diamidino-2-phenylindole staining analyses showed that some cells in the te ag leaves had 4C DNA content and were binucleated compared with WT, suggesting a delay in mitotic exit in some te leaf cells (Fig. 3cf). Notably, more binucleated cells have been observed in mice Fzr1 / mouse embryonic broblasts (Cdh1- decient cells) because of delayed mitotic exit27. Taken together, these results support the notion that TE has an evolutionarily conserved role in cell-cycle regulation2,27,28.

TE physically interacts with MOC1 and OsCDC27. It has been reported previously that Cdh1 mainly recognizes the D-box (RxxLxxxxN/D/E) and KEN-box in the amino-terminal region of its substrates to target them for ubiquitination and degradation by the 26S proteasome1,7. The enhanced tillering phenotype in the loss-of-function te mutant suggests that TE could participate in targeted degradation of a positive regulator(s) of tillering. Through extensive analysis of known positive regulators of tillering and branching, we identied a typical D-box in the N-terminal region of the MOC1/LS/LAS protein (Supplementary Fig. S3a). Previous studies have reported a loss-of-function moc1 mutant that has dramatically reduced tiller number, whereas MOC1-overexpressing lines have increased tiller number17. Thus, we tested whether TE physically interacts with MOC1. A yeast two-hybrid assay showed that TE interacted with MOC1, but not with MOC1-d (deletion of 107 amino acids in the N-terminal region) or MOC1-m (in which the typical D-box was mutated) (Fig. 4a). In addition, an in vitro pull-down assay showed that MBPTE protein but not the MBP control pulled down MOC1 protein from the total protein extracts of WT rice plants (Fig. 4b). Moreover, biomolecular uorescence complementation (BiFC) assay showed that TE interacted with MOC1 in Nicotiana benthamiana leaf cells (Fig. 4c). These results suggest that TE directly interacts with MOC1 and that the D-box in the N-terminal region of MOC1 is required for its physical interaction with TE.

Cdh1 activates the activity of APC/CCdh1 E3 ubiquitin ligase by coupling to the CDC27 subunit of the APC/C complex1,7. The rice genome contains a single CDC27 gene, OsCDC27 (Supplementary Fig. S3b,c). We conrmed that TE indeed physically interacts with OsCDC27 using yeast two-hybrid, in vitro pull-down and BiFC assays (Fig. 4ac). These results support the notion that TE acts as an activator of APC/C E3 ubiquitin ligase by directly coupling to the OsCDC27 subunit of the APC/C complex.

TE mediates the degradation of MOC1. We next conducted a series of biochemical experiments to test whether TE mediates the proteolysis of MOC1. An in vitro ubiquitination assay showed that MOC1 was polyubiquitinated by the total protein extracts of WT plants, but not by extracts of te plants (Fig. 5a, Supplementary Fig. S4), indicating that TE is required for MOC1s ubiquitination. In addition, a cell-free degradation study showed that puried recombinant MBPMOC1 protein, but not the MBPMOC1-m protein

NATURE COMMUNICATIONS | 3:752 | DOI: 10.1038/ncomms1716 | www.nature.com/naturecommunications

2012 Macmillan Publishers Limited. All rights reserved.

NATURE COMMUNICATIONS | DOI: 10.1038/ncomms1716

ARTICLE

a c d

b

Tiller number

60

50

30

20

10

40

WT

te

WT te WT te

0 TTs

LTs

HTs

e f g h i j

Length (cm)

80

70

60

50

40

30

20

10

WT

k

V

0 WT te WT te

WT te

te

l m

V

WT te

Chr. 3

Markers

IV

23 kb

g105

g118 RM523 g62

BAC098695

RM22

g41

III

IV

2 5 Recombinants

III

II II

I I

LOC_Os03g03150

n = 1,800

40CG

38C deletion

te pGTE

Figure 1 | Phenotype characterization of te mutant and map-based cloning of TE. (a) Phenotype of WT and te plants at the seventh leaf stage. (b) Phenotype of WT and te plants at the heading stage. (c) WT produces un-elongated lateral bud (left panel, arrowhead) on the elongated upper internodes, whereas te mutant produces additional tillers (right panel, arrowhead) from the elongated internodes. (d) Tiller number comparison between WT (blue) and te (red) plants at the heading stage. TTs, total tillers; LTs, lower node tillers; HTs, higher node tillers. LTs are the tillers outgrown fromthe un-elongated basal internodes. HTs are the tillers outgrown from the elongated internodes. (e) Stem structure of WT and te. (f) Internode length comparison between WT and te. I (light blue), II (purple), III (green), IV (red) and V (blue) indicate the rst, the second, the third, fourth and fth internode, respectively. (g,h) Longitudinal sections of the corresponding parts of the fth internode (V) between WT (g) and te (h) (marked by white boxes in e). Scale bar, 50 m. (i) The twisted panicle and ag leaf phenotype of te mutant. (j,k) Cross section images of ag leaf of WT (j) and te mutant (k) showing the highly twisted ag leaf structure of te mutant. (l) Mapping of TE locus (LOC_Os03g03150) and the molecular lesions in the te mutant. (m) pGTE rescued the te mutant phenotype. Data are mean s.d. (n = 30 plants) in d,f. (a,b,c,e,i,m) Scale bar, 10 cm, (g,h) 50 m and (j,k) 500 m.

and MBP control, was rapidly degraded by the total protein extracts of WT plants, but not by extracts of te plants (Fig. 5b). Moreover, MG132, a specic inhibitor of the 26S proteasome, blocked the degradation of MBPMOC1 in the total protein extracts (Fig. 5b). Further, MOC1 protein level was markedly higher in te plants compared with WT plants (Fig. 5c) whereas TE-overexpression lines (TE-OE) had reduced MOC1 accumulation and reduced tiller number (Fig. 5df). Taken together, these results support the view that TE regulates tillering in rice by mediating the degradation of MOC1 by the ubiquitin26S proteasome pathway.

To further determine the genetic interaction between TE and MOC1, we isolated a new allele of moc1, termed moc1-5, and

constructed the te moc1-5 double mutant. Map-based cloning and sequence analysis identied a deletion of nucleotide 38 (C) downstream of the ATG initiation codon of the MOC1 gene (LOC_ Os06g40780) in the moc1-5 mutant (Supplementary Fig. S5a), leading to a frame-shi and a 267-amino acid truncated protein product. Western blot analysis conrmed the absence of the MOC1 protein in moc1-5 mutant (Supplementary Fig. S5b). Like the moc1-5 mutant, the te moc1-5 double mutant had signicantly reduced number of tillers (Fig. 5g), suggesting that MOC1 acts downstream of TE in control of tillering. Consistent with this, the expression of OSH124,29,30 (a key meristem identity gene) and OsTB131 (a rice homologue of maize TB132) was markedly lower in our TE-OE

NATURE COMMUNICATIONS | 3:752 | DOI: 10.1038/ncomms1716 | www.nature.com/naturecommunications

2012 Macmillan Publishers Limited. All rights reserved.

ARTICLE

NATURE COMMUNICATIONS | DOI: 10.1038/ncomms1716

a

b c

2.0

0.0

YL

P3

Relative expression

1.5

P2

1.0

P1

0.5

AM

AM

AM SAM

R S L P

RM

d YL e

f

GFP Chloroplast DIC Merged

P4

TEGFP GFP

AM

P5

AM

RM

RM

Figure 2 | TE expression pattern and subcelluar localization of TE protein. (a) Quantitative RTPCR analysis showing the relative expression levels of TE in root (R), shoot (S), leaf (L) and panicle (P). Error bars represent s.e.m. (n = 3). (b) RNA in situ hybridization in longitudinal section showing that TEis preferentially expressed in the AM in axils of P1 and P2 leaf, P1 leaf primordia and young leaves (YL) at P2 leaf stage. (c) RNA in situ hybridization in longitudinal section showing that TE is preferentially expressed in the shoot apical meristem (SAM), AM in axils of P3 leaf, root meristem (RM) and YL at P3 leaf stage. (d) RNA in situ hybridization in longitudinal section showing that TE is preferentially expressed in the AM in axils of P4 leaf and P5 leaf, RM and YL at P4 leaf stage. (e) The sense probe of TE was used as a negative control. (f) TEGFP fusion protein is predominantly localized to the nuclei of Arabidopsis protoplasts (upper images); GFP protein itself is distributed throughout the cytoplasm of Arabidopsis protoplasts (lower images). (be) Scale bar, 100 m and (f) 7.5 m.

lines as in moc1 mutant17 (Fig. 5h,i), further supporting the notion that TE and MOC1 act in the same genetic pathway in control of tillering.

Discussion

Tillering or formation of shoot branches is a postembryonic developmental process unique to higher plants. The shoot branches originate from AMs that are produced in the axils of the leaves. Several key regulators involved in AM formation have been identied in plants, including REVOLUTA33, LAS16 and Regulator of Axillary Meristem34 in Arabidopsis, LS15,16 and Blind in tomato35, Barren Stalk1 (BA1)19 in maize, MOC117, Lax Panicle118,36 and Lax Panicle221 in rice. Here, we have identied a new negative regulator of tillering in rice, TE, and demonstrated that it acts as an activator of APC/C E3 ubiquitin ligase. We further showed that TE has a conserved role in cell-cycle regulation and that it regulates rice tillering by mediating the degradation of MOC1 (Fig. 5j), and consequently downregulates the expression of the meristem identity gene OSH1 (Fig. 5h), thus repressing AM initiation and formation. These results indicate that plants and animals could use conserved cell-cycle machineries to regulate distinct developmental processes. To our knowledge, MOC1 is the rst reported substrate of APC/CCCS52 that is not a mitotic cyclins in plants, and its orthologues in tomato (LS) and Arabidopsis (LAS) have also been shown to have a similar role in regulating lateral branching (shoot and panicle branching)15,16. In addition, the putative orthologues of TE (CCS52 proteins in Arabidopsis, maize, tomato and legume)4,8,12,37 and OSH1 (KN1 in maize and STM in Arabidopsis)22,23 could be identied in both monocot and dicot species. Further, previous studies have shown that LAS acts upstream of REVOLUTA, which is needed to activate the expression of STM in Arabidopsis16,33. These results together suggest that a conserved genetic pathway (TE(CCS52A)

MOC1(LAS)OSH1(STM)) likely operates in both monocots and dicots to control tillering and shoot branching. The observed overlap of TE and MOC1 expression in the axil from P2 to P3 leaf stage (Fig. 2bd, refs 17 and 36) suggests that a link probably exists between the levels of TE and MOC1 proteins to the state of stem cell-like cells in the axils from P1 to P3 leaf stage. We speculate that TE might act to maintain these stem cell-like cells in a mitotically inactive and indeterminate state through targeted proteolysis of MOC1, a key AM-initiation-promoting factor (refs 17 and 36). In further support of this notion, we have demonstrated that TE-OE lines have much fewer tillers concomitant with reduced level of MOC1 protein accumulation, whereas the loss-of-function te mutants have much more tillers concomitant with the elevated level of MOC1 protein accumulation (Fig. 5).

In addition to cell-cycle regulation, APC/CCdh1 has been reported to have important roles in regulating hematopoiesis, neurogenesis, lens development, myogenesis, genomic stability and tumour suppression by targeted degradation of specic key regulators of these developmental processes in animals2,28,38. APC/CCCS52 has also been shown to regulate root development in plants8. In this study, we found that the te mutant displayed a pleiotropic pheno-type, including shortened stem and ag leaves, twisted ag leaves and panicles (Fig. 1ek), suggesting that, as in animals, APC/ CCCS52A also has important roles in regulating a variety of developmental processes in plants. Further investigation of the detailed mechanisms of APC/CTE(CCS52A) regulating plant morphogenesis, and the functional relationship of the (TE(CCS52A)-MOC1(LAS)-OSH1(STM)) pathway with other developmental pathways regulating branching pattern (such as the Lax Panicle1/BA1 pathway18,19,36 and the MAX/RMS/D pathway39), may provide new strategies for genetic improvement of crop architecture to optimize grain yield.

NATURE COMMUNICATIONS | 3:752 | DOI: 10.1038/ncomms1716 | www.nature.com/naturecommunications

2012 Macmillan Publishers Limited. All rights reserved.

NATURE COMMUNICATIONS | DOI: 10.1038/ncomms1716

ARTICLE

a c d

+Thiamine Thiamine

pREP1

pREP1-TE

1

200 100% 2C 75% 2C

25% 4C

WT leaf te leaf

10 100 1 10 100

pREP1-TE

150 120

200 150 120

Cell number

80 40

0 0 200 400 600 DNA content

800 1,000 0 200 400 600 DNA content

800 1,000

Cell number

80 40

0

b e f

pREP1

LM

UV

WT te

Figure 3 | Conserved role of TE in cell-cycle regulation. (a) Growth of S. pombe transformed with the empty vector pREP1 and pREP1-TE in the presence ( + thiamine, the expression of TE is repressed in the presence of thiamine) or absence of thiamine ( thiamine, the expression of TE is induced in the absence of thiamine). (b) The observation of S. pombe cells under light microscopy and 4,6-diamidino-2-phenylindole (DAPI)-stained cells under UV light showing the S. pombe cells transformed with pREP1-TE in the absence of thiamine became much larger and longer concomitant with bigger nuclei compared with pREP1. LM, light microscopy; UV, observation of DAPI-stained cells under UV light. (c,d) Flow cytometry analysis showing that some (about 25%) ag leaf cells of te mutant (d) have 4C DNA content compared with WT (c). (e,f) Microscopy images of transverse sections (stained with DAPI) showing that the ag leaves of te (f) have more cells with two nuclei (indicated by arrowheads) compared with WT ag leaves (e). The inset magnied parts in f showing two nuclei in one cell. (b) Scale bar, 10 m and (e,f) 50 m.

a

AD-TE

c

eYFP

ER marker DIC

Merged

TE-eYNE +

MOC1-eYCE

BD

RDLLLACAD

ADLALACAD

BD-MOC1

BD-MOC1d

BD-MOC1-m

AD

MOC1

MOC1d

MOC1-m

108aa

eYNE +

MOC1-eYCE

BD-OsCDC27

TE-eYNE +

OsCDC27-eYCE

b

MBP

55 kDa

43 kDa

Anti-MOC1

95 kDa

Anti-OsCDC27

72 kDa

eYNE +

OsCDC27-eYCE

CBB

MBP-TE

Figure 4 | TE physically interacts with MOC1 and OsCDC27. (a) Yeast two-hybrid assay showing that TE interacts with MOC1 and OsCDC27, but not with MOC1d and MOC1-m. The protein structure of MOC1 and MOC1d and the amino-acid substitutions in MOC1-m are shown on the right. (b) In vitro pull-down assay showing that MBPTE, but not MBP itself, pulled down MOC1 (upper image) and OsCDC27 (middle image) from plant extracts. Coomassie blue staining (CBB) showing that roughly equal amounts of puried MBP-TE and MBP proteins were used in the pull-down assay (lower image). (c) BiFC assay showing that TE can interact with MOC1 and OsCDC27 in the nuclei of leaf cells of N. benthamiana. The signals of eYFP were not detected in the corresponding negative controls. White arrowheads indicate the nuclear membrane. Scale bar, 20 m.

NATURE COMMUNICATIONS | 3:752 | DOI: 10.1038/ncomms1716 | www.nature.com/naturecommunications

2012 Macmillan Publishers Limited. All rights reserved.

ARTICLE

NATURE COMMUNICATIONS | DOI: 10.1038/ncomms1716

a b

min Extracts

0

c

30

30 WT

te

MG132

+MG132

60

min

0

30

60

30

170 kDa

130 kDa

WT+MBP-MOC1

55 kDa

43 kDa

95 kDa

Anti-MOC1

Rubisco

72 kDa

WT+MBP-MOC1-m

te+MBP-MOC1

WT+MBP

WT te

55 kDa

MOC1

43 kDa

Anti-MBP

Anti-MOC1

MOC1-(Ub)n

d

e f

j

10

60

E1

Ub Ub

E2

50

APC complexes

CDC27

Degradation by proteasome

TE

Relative expression

8

55 kDa

40

Tiller number

43 kDa

Anti-MOC1

TE

6

MOC1

30

Rubisco

4

20

WT

OE17

OE22

OE65

Ub

Ub

Ub

2

10

0

0

MOC1

MOC1 MOC1

TE

g

h

i

MOC1 MOC1

1.4

1.4

Relative expression

Relative expression

1.2

1.2

MOC1

MOC1

MOC1

1.0

1.0

MOC1

te WT TE-OE

0.8

0.8

0.6

0.6

0.4

0.4

0.2

0.2

0

0

te moc1-5 te moc1-5

te

OSH1 OsTB1

Figure 5 | TE mediates the degradation of MOC1 and it acts upstream of MOC1. (a) In vitro ubiquitination assay showing that MOC1 is ubiquitinated by WT plant extracts but not by te plant extracts. (b) Cell-free degradation assay showing that MBP-MOC1, but not MBP-MOC1-m and MBP, was degraded in WT plant extracts after 60 min incubation, whereas MBP-MOC1 remained relatively stable in te plant extracts. The degradation of MBP-MOC1 by plant extracts was blocked in the presence of 40 M MG132 ( + MG132). (c) Western blot analysis showing that MOC1 protein accumulated to a higher level in the te plants compared with WT (top). Rubisco strips showing a roughly equal loading of total proteins (bottom). (d) Quantitative RTPCR assay showing that the expression level of TE is dramatically upregulated in OE17 (green), OE22 (light blue) and OE65 (orange), compared with WT (blue) or te (red). (e) OE17 (green), OE22 (light blue) and OE65 (orange) had reduced tiller numbers in comparison with WT (blue) or te (red). Data are mean s.

d. (n = 15 plants). (f) Western blot analysis showing that there was less MOC1 protein in the TE-OE lines compared with WT and te (top). Rubisco strips showing the roughly equal loading of total proteins (bottom). (g) The te moc1-5 double mutant have reduced tiller number as the moc1-5 parent. Scale bar,10 cm. (h,i) Quantitative RTPCR assay showing that the expression levels of OSH1 and OsTB1 were drastically reduced in OE17 (green), OE22 (light blue) and OE65 (orange) transgenic lines, but slightly increased in te (red) mutant, in comparison with WT (blue). (j) A model showing that TE activates the APC/C E3 ubiquitin ligase activity and targets MOC1 for degradation through interacting with the D-box, and consequently represses tillering. Error bars represent s.e.m. in d,h,i (n = 3).

Methods

Plant materials. The te mutant was identied from the F4 osprings of pollen culture plants derived from the tetraploid hybrid H5409 (H2088xH3811)26. The normal ospring of pollen culture plants, with a nearly identical genetic background to te, was viewed as the wild type (WT) of te in this study. Genetic analysis showed that the twisted leaf phenotype of te is controlled by a single recessive nuclear locus, TE. To map the TE locus, we generated an F2 mapping population derived from a cross between the te and the cultivar Zhenshan 97B.

Map-based cloning of TE. The TE locus was mapped to a 23-kb region between the simple sequence repeat marker RM523 and the InDel marker g62 on chromosome 3 using 1,800 F2 mutant plants with additionally molecular markers developed in this work (Supplementary Table S1). The cDNA of the candidate gene, LOC_Os03g03150, was amplied from both te and WT using primers (Rt-1F 5-ACCTTCCTCTCCTCTCCTCCC-3 and Rt-1R 5-TCAGTGTTTGCCATCTT CGCT-3), and the PCR products were conrmed by sequencing.

Construction of te moc1-5 double mutant. The moc1-5 mutant was isolated from a population of Nipponbare treated by 60Co- irradiation. The mutation locus was mapped with markers developed in this study (Supplementary Table S2). The te moc1-5 double mutants were identied from F2 osprings of the hybrids

between te and moc1-5 mutant.

Complementation test and overexpression of TE in te plants. A 6.2-kb genomic DNA fragment (consisting of a 1.2-kb upstream sequence, the entire TE gene including ten exons and nine introns, and a 1.1-kb downstream region) was amplied using primers pGR-3F (5-TGAATCTTACTCTTCTATATATTGCCTCAC-3) and pGR-4R (5-GGATCCCATAACCTTATTTATTTTTCTAGT-3), and thePCR product was inserted into the binary vector pCAMBIA1305.1 to generate the transformation plasmid pGTE. The 1.8-kb cDNA sequence of TE was amplied using primers RT-2LF (5-ATCCCCAAATCTCTCGCCCCCACCCA-3) and RT-2LR (5-TCGCTCCTACAAAGCCAATGAATAAA-3), and the PCR fragment was inserted into the downstream of the ubiquitin promoter in the vector pCUBi 1390, resulting in plasmid pUBiTE. The te was transformed with Agrobacterium tumefaciens strain EHA105 harbouring the plasmid pGTE or pUBiTE.

RNA in situ hybridization. Shoot apexes of rice seedlings at the third and fourth leaf stages were xed with an formalin acetic-acid alcohol (RNase-free) xative solution at 4 C overnight, followed by a series of dehydration steps and then embedded in paraffin (Paraplast Plus, Sigma). RNA in situ hybridization was performed as described previously40. The 5 end of TE was amplied with primers pf2 (5-ACTGAGATGTGGAGCGAAGATGG-3) and pr2 (5-TTGACATAGATCA GTACAAAGTTG-3) and cloned into the pGEM-T Easy vector (Promega). Digoxigenin-labelled probes were prepared from linearized templates amplied from the pGEM-T plasmid containing the 5 end of TE using primer Yt7 (5-CCCA

NATURE COMMUNICATIONS | 3:752 | DOI: 10.1038/ncomms1716 | www.nature.com/naturecommunications

2012 Macmillan Publishers Limited. All rights reserved.

NATURE COMMUNICATIONS | DOI: 10.1038/ncomms1716

ARTICLE

GTCACGACGTTGTAAA-3) and Ysp6 (5-CACACAGGAAACAGCTATGAC-3). Digoxigenin-labelled RNA probes were prepared using a DIG Northern Starter Kit (Cat. No. 2039672, Roche) following the instructions of manufacturer. The slides were observed under bright eld with a microscope (Leica DM5000B) and photographed using a camera (Leica DFC490).

Subcellular localization. A 1,569-bp coding sequence of TE was amplied with the primer 52aXF (5-CTAGATCTCGAGATGGATCACCACCACCACCACCTG-3) and 52aSR (5-CTAGACTAGTCGGATGTAGCTCCTAACAAATGATG-3), and the PCR product was inserted into the XhoI/SpeI sites of the PA7 vector, to fuse to the upstream of GFP, resulting in the TEGFP fusion protein-expressing plasmid PA7-TE, and then transformed into Arabidopsis protoplasts, as reported previously41. PA7 plasmid was used as the control.

Flow cytometry. About 30 ag leaves were chopped in 10 ml of a cold nuclear isolation buer (10 mM MgSO4, 50 mM KCl, 5 mM hepes (4-(2-hydroxyethyl)

piperazine-1-ethanesulfonic acid), 3 mM dithiothreitol, pH 8.0. Triton X-100 at a nal concentration of 0.25% before use). The crude extract with isolated cells was ltered (48 m), then stained with 2.5 g ml 1 4,6-diamidino-2-phenylindole (DAPI, Roche) and immediately analysed on an FACStar Plus cytometer (Becton Dickinson).

Overexpression of TE in Schizosaccharomyces pombe. The coding sequence of TE was amplied using primer 52aNF (5-GGAATTCCATATGATGGATCACCAC CACCACCACCTG-3) and 52aBR (5-CTAGGAAGATCTTCACCGGATGTAG CTCCTAACAAATG-3), and the PCR product was cloned into the pREP1 vector and veried by sequencing. In the absence of thiamine (-thiamine), overexpression of TE was induced in S. pombe as reported3.

Construction of protein expression plasmids. MOC1 and TE were amplied with the primers shown in Supplementary Table S3, and the PCR products were cloned into the pMAL-C2x vector (NEB), resulting in the plasmids pMALC2xMBP-MOC1 and pMAL-C2xMBP-Te. The D-box of MOC1 was mutated using a Phusion Site-Directed Mutagenesis Kit (NEB) with the primers listed in Supplementary Table S3.

In vitro pull-down assay. The seedlings of wild type were planted in the pots and grown in a climate chamber (HP1500GS, Ruihua) with a 14.5-h light (30 C) 9.5 h darkness (25 C) photocycle. Total proteins were subsequently extracted in a degradation buer42. The total protein concentration was determined by the Bio-Rad protein assay. For pull-down assay, roughly equal amounts of puried MBP and MBPTE fusion proteins (about 1 g) were affixed to Amylose Resin (NEB), and incubated in 400 l of plant extract (containing 1.6 mg total proteins) in the presence of 42 M MG132 gently shaken at 28 C for 30 min. The pull-down analyses were performed as reported43,44 and detected with anti-MOC1 or anti-OsCDC27 antibodies at 1:200 dilution. The horseradish peroxidase (HRP)-conjugated anti-rabbit IG (H + L) (1:5,000 dilution, MBL) was used as the second antibody. The western blots were developed with enhanced chemiluminescence (ECL) reagent (GE Healthcare).

Cell-free degradation assay. The total protein extracts were prepared as in the pull-down assay from te and WT seedlings, and were adjusted to equal concentration in the degradation buer42. Then MG132 (Calbiochem) was selectively added to various in vitro degradation assays as indicated. For degradation of puried MBP, MBP-MOC1 and MBP-MOC1-m proteins, equal amounts of these puried proteins (about 500 ng) were incubated in 50 l of rice total-protein extract (containing about 200 g total proteins) at 28 C for each assay. For mock controls, an equal amount of solvent for each drug was used. The extracts were incubated at 28 C, and the samples were taken at the indicated intervals for determination of MBP, MBP-MOC1 and MBP-MOC1-m protein abundance by western blots with the HRP-conjugated Anti-MBP monoclonal antibody at 1:5,000 dilution (E8038L, NEB). The western blots were developed with ECL reagent (GE Healthcare).

Yeast two-hybrid assay. The coding sequences of TE, OsCDC27, MOC1, MOC1d and MOC1-m were amplied using gene-specic primers (Supplementary Table S4). TE was inserted into the pGADT7 vector (Clonetech), and MOC1, MOC1d, MOC1-m and OsCDC27 were inserted into the pGBKT7 vector (Clonetech), respectively. The yeast two-hybrid assay was performed following the manufacturers instructions.

Antibody preparation and western blot analysis. MOC1 CDS was inserted into the pET32a vector. Puried His-MOC1 fusion protein was injected into rabbitsto produce polyclonal antibodies of MOC1. Western blots were performed using antiserum against MOC1 and visualized by an enhanced HRP-DAB substrate kit (PA110, TIANGEN). For OsCDC27, the polypeptide FNQSSDSVPRRSAR was synthesized, and conjugated with keyhole limpet hemocyanin (KLH) to form KLH-FNQSSDSVPRRSAR. Subsequently, the conjugates were injected into rabbits to produce polyclonal antibodies against OsCDC27.

In vitro ubiquitination assay. The puried MBPMOC1 protein bound to the Amylose Resin (NEB) was incubated at 28 C with equal amounts of rice seedling crude extract in a buer containing 25 mM TrisHCl pH 7.5, 10 mM MgCl2, 5 mM dithiothreitol, 10 mM NaCl, 10 mM adenosine triphosphate and 40 M MG132.

Aer incubation at 28 C for the intervals as indicated, the MBPMOC1 and MBPMOC1-(Ub)n fusion proteins were cleaved at room temperature by Factor Xa (NEB), following the manufacturers instruction. The supernatant containing MOC1 or MOC1-(Ub)n was added with SDSPAGE-loading buer, then loaded on SDSPAGE gel and western blots were performed using antibodies against MOC1 or antibodies against polyubiquitin (Beijing Protein Innovation, http:// www.proteomics.org.cn/) at 1:200 dilution. The HRP-conjugated anti-rabbit IG(H + L) (1:5,000 dilution, MBL) was used as the second antibody. The western blots were developed with ECL reagent (GE Healthcare).

Quantitative RTPCR analysis. RNA was extracted from frozen samples using the RNAprep Pure Plant Kit (Tiagen) following the manufacturers instructions. Quantitative RTPCRs were performed by a SYBR Premix Ex Taq RTPCR kit (Takara) following the manufacturers instructions with the primers listed in Supplementary Table S5.

BiFC assay. CDS of TE was amplied with primer 52aSF (5-GGAATTCACTAG TATGGATCACCACCACCACCACCTG-3) and 52aKR (5-CTAGGAGGTAC CCCGGATGTAGCTCCTAACAAATG-3), then cloned into the SpeI/KpnI sites of the vector pSPYNE173 (eYNE)45 to form the TE-eYNE plasmid. CDS of MOC1 was amplied with primer MOC1BF (5-AGATTCGGATCCATGCTC CGGTCACTCCACTCCTC-3) and MOC1KR (5-CTAGGAGGTACCCGAC GACGACGGCTGC-3), then cloned into the Bam HI/Kpn I sites of the vector pSPYCE(M) (eYCE)45 to form the MOC1-eYCE plasmid. CDS of OsCDC27 was amplied with primer CDC27SF (5-GGAATTCACTAGTATGGAAACCCTAAT GGTGGACCG-3) and CDC27XR (5-CTAGGACTCGAGAATCTCATCAT CATCATCATCATCATCC-3), then cloned into the SpeI/XhoI sites of the vector pSPYCE(M) to form the CDC27-eYCE plasmid.

For transient expression, A. tumefaciens strain AH109 carrying the BiFC constructs were used together with the p19 strain46 and ER marker, mCherry ER-rk CD3-95947, for inltration of 56-week-old N. benthamiana leaves, as described in Waadt and Kudla48. Inltrated leaves were observed 4872 h aer inltration using a laser confocal scanning microscope (ZEISS Microsystems LSM 700, http://www. zeiss.com.cn/microscopy). The eYFP and mCherry uorescent signals from the expressed fusion constructs were monitored sequentially. The excitation and detection wavelengths for eYFP and mCherry were 514 and 587 nm for excitation, and 527 and 610 nm for detection, respectively.

References

1. Peters, J. The anaphase promoting complex/cyclosome: a machine designed to destroy. Nat. Rev. Mol. Cell Biol. 7, 644656 (2006).

2. Li, M. & Zhang, P. The function of APC/CCdh1 in cell cycle and beyond. Cell Div. 4, 2 (2009).

3. Tarayre, S., Vinardell, J. M., Cebolla, A., Kondorosi, A. & Kondorosi, E. Two classes of the Cdh1-type activators of the anaphase-promoting complex in plants: novel functional domains and distinct regulation. Plant Cell 16, 422434 (2004).

4. Cebolla, A. et al. The mitotic inhibitor ccs52 is required for endoreduplication and ploidy-dependent cell enlargement in plants. EMBO. J. 18, 44764484 (1999).

5. Schaeer, V., Althauser, C., Shcherbata, H. R., Deng, W. M. & Ruohola-Baker, H. Notch-dependent Fizzy-related/Hec1/Cdh1 expression is required for the mitotic-to-endocycle transition in Drosophila follicle cells. Curr. Biol. 14, 630636 (2004).6. Narbonne-Reveau, K. et al. APC/CFzr/Cdh1 promotes cell cycle progression during the Drosophila endocycle. Development 135, 14511461 (2008).7. Da, F. P. et al. Structures of APC/C(Cdh1) with substrates identify Cdh1 and Apc10 as the D-box co-receptor. Nature 470, 274278 (2011).

8. Vanstraelen, M. et al. APC/CCCS52A complexes control meristem maintenance in the Arabidopsis root. Proc. Natl Acad. Sci. USA 106, 1180611811 (2009).

9. Lammens, T. et al. Atypical E2F activity restrains APC/CCCS52A2 function obligatory for endocycle onset. Proc. Natl Acad. Sci. USA 105, 1472114726 (2008).

10. Larson-Rabin, Z., Li, Z., Masson, P. H. & Day, C. D. FZR2/CCS52A1 expression is a determinant of endoreduplication and cell expansion in Arabidopsis. Plant Physiol. 149, 874884 (2009).

11. Kasili, R. et al. SIAMESE cooperates with the CDH1-like protein CCS52A1 to establish endoreplication in Arabidopsis thaliana trichomes. Genetics 185, 257268 (2010).

12. Mathieu-Rivet, E. et al. Functional analysis of the anaphase promoting complex activator CCS52A highlights the crucial role of endo-reduplication for fruit growth in tomato. Plant J. 62, 727741 (2010).

13. Wang, Y. & Li, J. Molecular basis of plant architecture. Annu. Rev. Plant Biol. 59, 253279 (2008).

14. Xing, Y. & Zhang, Q. Genetic and molecular bases of rice yield. Annu. Rev. Plant Biol. 61, 421442 (2010).

NATURE COMMUNICATIONS | 3:752 | DOI: 10.1038/ncomms1716 | www.nature.com/naturecommunications

2012 Macmillan Publishers Limited. All rights reserved.

ARTICLE

NATURE COMMUNICATIONS | DOI: 10.1038/ncomms1716

15. Schumacher, K., Schmitt, T., Rossberg, M., Schmitz, G. & Theres, K. The Lateral suppressor (Ls) gene of tomato encodes a new member of the VHIID protein family. Proc. Natl Acad. Sci. USA 96, 290295 (1999).

16. Greb, T. et al. Molecular analysis of the LATERAL SUPPRESSOR gene in Arabidopsis reveals a conserved control mechanism for axillary meristem formation. Genes Dev. 17, 11751187 (2003).

17. Li, X. et al. Control of tillering in rice. Nature 422, 618621 (2003).18. Komatsu, K. et al. LAX and SPA: Major regulators of shoot branching in rice. Proc. Natl Acad. Sci. USA 100, 1176511770 (2003).

19. Gallavotti, A. et al. The role of barren stalk1 in the architecture of maize. Nature 432, 630635 (2004).

20. Gomez-Roldan, V. et al. Strigolactone inhibition of shoot branching. Nature 455, 189194 (2008).

21. Tabuchi, H. et al. LAX PANICLE2 of rice encodes a novel nuclear protein and regulates the formation of axillary meristems. Plant Cell 23, 32763287 (2011).

22. Long, J. A., Moan, E. I., Medford, J. I. & Barton, M. K. A member of the KNOTTED class of homeodomain proteins encoded by the STM gene of Arabidopsis. Nature 379, 6669 (1996).

23. Vollbrecht, E., Veit, B., Sinha, N. & Hake, S. The developmental gene Knotted-1 is a member of a maize homeobox gene family. Nature 350, 241243 (1991).

24. Matsuoka, M. et al. Expression of a rice homeobox gene causes altered morphology of transgenic plants. Plant Cell 5, 10391048 (1993).

25. Khush, G. Productivity improvements in rice. Nutr. Rev. 61, S114S116 (2003).26. Qin, R., Cheng, Z. & Guo, X. The establishment of mutant pool using anther culture of autotetrapolyploid rice. ACTA AGRONOMICA SINICA 31, 392394 (2005).

27. Garci-Higuera, I. et al. Genomic stability and tumour suppression by the APC/C cofactor Cdh1. Nat. Cell Biol. 10, 802811 (2008).

28. Wasch, R., Robbins, J. A. & Cross, F. R. The emerging role of APC/CCdh1 in controlling dierentiation, genomic stability and tumor suppression. Oncogene 29, 110 (2010).

29. Kano-Murakami, Y., Yanai, T., Tagiri, A. & Matsuoka, M. A rice homeotic gene, OSH1, causes unusual phenotypes in transgenic tobacco. FEBS Lett. 334, 365368 (1993).

30. Sato, Y. et al. A rice homeobox gene, OSH1, is expressed before organ dierentiation in a specic region during early embryogenesis. Proc. Natl Acad. Sci. USA 93, 81178122 (1996).

31. Takeda, T. et al. The OsTB1 gene negatively regulates lateral branching in rice. Plant J. 33, 513520 (2003).

32. Doebley, J., Stec, A. & Hubbard, L. The evolution of apical dominance in maize. Nature 386, 485488 (1997).

33. Otsuga, D., DeGuzman, B., Prigge, M. J., Drews, G. N. & Clark, S. E. REVOLUTA regulates meristem initiation at lateral positions. Plant J. 25, 223236 (2001).

34. Keller, T., Abbott, J., Moritz, T. & Doerner, P. Arabidopsis REGULATOR OF AXILLARY MERISTEMS1 controls a leaf Axil stem cell niche and modulates vegetative development. Plant Cell 18, 598611 (2006).

35. Schmitz, G. et al. The tomato Blind gene encodes a MYB transcription factor that controls the formation of lateral meristems. Proc. Natl Acad. Sci. USA 99, 10641069 (2002).

36. Oikawa, T. & Kyozuka, J. Two-step regulation of LAX PANICLE1 protein accumulation in axillary meristem formation in rice. Plant Cell 21, 10951108 (2009).

37. Vinardell, J. M. et al. Endoreduplication mediated by the anaphase-promoting complex activator CCS52A Is required for symbiotic cell dierentiation in Medicago truncatula nodules. Plant Cell 15, 20932105 (2003).

38. Hu, D., Qiao, X., Wu, G. & Wan, Y. The emerging role of APC/CCdh1 in development. Semin. Cell Dev. Biol. 22, 579585 (2011).

39. Beveridge, C. A. & Kyozuka, J. New genes in the strigolactone-related shoot branching pathway. Curr. Opin. Plant Biol. 13, 3439 (2010).

40. Bradley, D., Carpenter, R., Sommer, H., Hartley, N. & Coen, E. Complementary oral homeotic phenotypes result from opposite orientations of a transposon at the plena locus of Antirrhinum. Cell 72, 8595 (1993).

41. Sheen, J. A transient expression assay using Arabidopsis mesophyll protoplasts, http://genetics.mgh.harvard.edu/sheenweb/ (2002).

42. Wang, F. et al. Biochemical insights on degradation of Arabidopsis DELLA proteins gained from a cell-free assay system. Plant Cell 21, 23782390 (2009).

43. Miernyk, J. A. & Thelen, J. J. Biochemical approaches for discovering protein-protein interactions. Plant J. 53, 597609 (2008).

44. Tagwerker, C. et al. A tandem affinity tag for two-step purication under fully denaturing conditions: application in ubiquitin proling and protein complex identication combined with in vivo cross-linking. Mol. Cell Proteomics 5, 737748 (2006).

45. Waadt, R. et al. Multicolor bimolecular uorescence complementation reveals simultaneous formation of alternative CBL/CIPK complexes in planta. Plant J. 56, 505516 (2008).

46. Voinnet, O., Rivas, S., Mestre, P. & Baulcombe, D. An enhanced transient expression system in plants based on suppression of gene silencing by the p19 protein of tomato bushy stunt virus. Plant J. 33, 949956 (2003).

47. Nelson, B. K., Cai, X. & Nebenfuhr, A. A multicolored set of in vivo organelle markers for co-localization studies in Arabidopsis and other plants. Plant J. 51, 11261136 (2007).

48. Waadt, R. & Kudla, J. In Planta Visualization of Protein Interactions Using Bimolecular Fluorescence Complementation (BiFC). Cold Spring Harbor

Protocols 2008, t4995 (2008).

Acknowledgements

This work was supported by 973 National Basic Research Program of China (2010CB125904-4), National Natural Science Foundation (Grant 31000667), 863 National High-tech R&D Program of China (2012AA100101) and Ministry of Agriculture of the Peoples Republic of China. We thank Dr. Lilin Du of NIBS for providing the yeast vector pREP1, Dr. Hongquan Yang (Shanghai Jiaotong University, China) for the gi of plasmid PA7-GFP and Dr. Mao-Yun She (Institute of Crop Science, Chinese Academy of Agricultural Sciences, Beijing) for technical assistance with ow cytometry assay. We thank Dr. Zhenbiao Yang (UC-Riverside), Dr. Roger Pennell (Ceres, Inc.) and Dr. Chentao Lin (UC-Los Angeles) for critical reading and comments on the manuscript.

Author contributions

J.W. and H.W. supervised the project. Z.C., J.G., R.Q. and J.L.W. identied the te mutant and performed genetic analysis and mapping of TE. Q.L., D.W., H.D. and S.G. performed other experiments and data analysis. J.W., Q.L. and H.W. wrote the manuscript.

Additional information

Supplementary Information accompanies this paper at http://www.nature.com/ naturecommunications

Competing nancial interests: The authors declare no competing nancial interests.

Reprints and permission information is available online at http://npg.nature.com/ reprintsandpermissions/

How to cite this article: Lin, Q. et al. Rice APC/CTE controls tillering by mediating the degradation of MONOCULM 1. Nat. Commun. 3:752 doi: 10.1038/ncomms1716 (2012).

License: This work is licensed under a Creative Commons Attribution-NonCommercial-Share Alike 3.0 Unported License. To view a copy of this license, visit http:// creativecommons.org/licenses/by-nc-sa/3.0/

NATURE COMMUNICATIONS | 3:752 | DOI: 10.1038/ncomms1716 | www.nature.com/naturecommunications

2012 Macmillan Publishers Limited. All rights reserved.