Skip to main content
Advertisement
  • Loading metrics

A Novel Tiller Angle Gene, TAC3, together with TAC1 and D2 Largely Determine the Natural Variation of Tiller Angle in Rice Cultivars

  • Haijiao Dong,

    Affiliation National Key Laboratory of Crop Genetic Improvement and National Center of Plant Gene Research (Wuhan), Huazhong Agricultural University, China

  • Hu Zhao,

    Affiliation National Key Laboratory of Crop Genetic Improvement and National Center of Plant Gene Research (Wuhan), Huazhong Agricultural University, China

  • Weibo Xie,

    Affiliation National Key Laboratory of Crop Genetic Improvement and National Center of Plant Gene Research (Wuhan), Huazhong Agricultural University, China

  • Zhongmin Han,

    Affiliation National Key Laboratory of Crop Genetic Improvement and National Center of Plant Gene Research (Wuhan), Huazhong Agricultural University, China

  • Guangwei Li,

    Affiliation National Key Laboratory of Crop Genetic Improvement and National Center of Plant Gene Research (Wuhan), Huazhong Agricultural University, China

  • Wen Yao,

    Affiliation National Key Laboratory of Crop Genetic Improvement and National Center of Plant Gene Research (Wuhan), Huazhong Agricultural University, China

  • Xufeng Bai,

    Affiliation National Key Laboratory of Crop Genetic Improvement and National Center of Plant Gene Research (Wuhan), Huazhong Agricultural University, China

  • Yong Hu,

    Affiliation National Key Laboratory of Crop Genetic Improvement and National Center of Plant Gene Research (Wuhan), Huazhong Agricultural University, China

  • Zilong Guo,

    Affiliation National Key Laboratory of Crop Genetic Improvement and National Center of Plant Gene Research (Wuhan), Huazhong Agricultural University, China

  • Kai Lu,

    Affiliation National Key Laboratory of Crop Genetic Improvement and National Center of Plant Gene Research (Wuhan), Huazhong Agricultural University, China

  • Lin Yang,

    Affiliation National Key Laboratory of Crop Genetic Improvement and National Center of Plant Gene Research (Wuhan), Huazhong Agricultural University, China

  • Yongzhong Xing

    yzxing@mail.hzau.edu.cn

    Affiliations National Key Laboratory of Crop Genetic Improvement and National Center of Plant Gene Research (Wuhan), Huazhong Agricultural University, China, Hubei Collaborative Innovation Center for Grain Industry, China

Abstract

Tiller angle is one of the most important components of the ideal plant architecture that can greatly enhance rice grain yield. Understanding the genetic basis of tiller angle and mining favorable alleles will be helpful for breeding new plant-type varieties. Here, we performed genome-wide association studies (GWAS) to identify genes controlling tiller angle using 529 diverse accessions of Oryza sativa including 295 indica and 156 japonica accessions in two environments. We identified 7 common quantitative trait loci (QTLs), including the previously reported major gene Tiller Angle Control 1 (TAC1), in the two environments, 10 and 13 unique QTLs in Hainan and Wuhan, respectively. More QTLs were identified in indica than in japonica, and three major QTLs (qTA3, qTA1b/DWARF2 (D2) and qTA9c/TAC1) were fixed in japonica but segregating in indica, which explained the wider variation observed in indica compared with that in japonica. No common QTLs were identified between the indica and japonica subpopulations. Mutant analysis for the candidate gene of qTA3 on chromosome 3 indicated a novel gene, Tiller Angle Control 3 (TAC3), encoding a conserved hypothetical protein controlling tiller angle. TAC3 is preferentially expressed in the tiller base. The ebisu dwarf (d2) mutant exhibited a decreased tiller angle, in addition to its previously described abnormal phenotype. A nucleotide diversity analysis revealed that TAC3, D2 and TAC1 have been subjected to selection during japonica domestication. A haplotype analysis identified favorable alleles of TAC3, D2 and TAC1, which may be used for breeding plants with an ideal architecture. In conclusion, there is a diverse genetic basis for tiller angle between the two subpopulations, and it is the novel gene TAC3 together with TAC1, D2, and other newly identified genes in this study that controls tiller angle in rice cultivars.

Author Summary

Tiller angle is the key component of plant architecture that greatly affect grain yield. However, few tiller angle-related genes that can be used for improving rice plant architecture have been isolated based on natural variation. Here, we identified 7 common tiller angle-related QTLs by a genome-wide association study, including the previously reported major gene TAC1, in two environments in the 529 diverse rice accessions and dozens of QTLs specially identified in one environment. Two QTLs were validated by mutant analysis: A novel gene TAC3, encoding a conserved hypothetical protein and preferentially expressing in the tiller base, was the candidate gene of qTA3; d2 mutant exhibited a decreased tiller angle, in addition to its previously described abnormal phenotype. A haplotype analysis identified favorable alleles of TAC3, D2 and TAC1 in indica, which may be used for breeding plants with an ideal architecture, while they were all subjected to selection and fixed in japonica. In conclusion, there is a diverse genetic basis for tiller angle between the two subpopulations, and it is the novel gene TAC3, together with TAC1 and D2 that greatly controls tiller angle in rice cultivars.

Introduction

As a key factor in rice plant architecture, tiller angle determines the planting density per unit area and contributes greatly to grain yield. The tiller angle is defined as the angle between the main culm and the side tillers [1]. A favorable rice tiller angle is an important component of the ideal plant architecture that has been selected by humans in the long history of domestication and genetic improvement [2]. Oryza rufipogon, the progenitor of cultivated rice (Oryza sativa), shows a spread-out growth pattern that allows it to escape some diseases induced by high humidity, but this pattern occupies too much space and increases shading and lodging, thus decreasing the photosynthetic efficiency and grain yield per unit area accordingly. By contrast, cultivated rice usually exhibits a better plant architecture, with a smaller tiller angle that leads to high potential yields.

Tiller angle changes dynamically throughout the life cycle of rice to achieve efficient resource use. At tillering stage, tiller angle increases, which enables young plant to occupy a large empty space for subsequent tiller development and simultaneously inhibits weed growth. At later stages, tiller angle decreases, especially at heading stage, when it reaches its minimum, allowing the mature plant to reduce leaf shade and increase its photosynthetic efficiency. Heading stage is a key developmental period in rice, and the planting density per unit area is mainly determined by the tiller angle at this stage.

Due to its importance in rice production, increasing attention has been paid to dissecting the genetic basis of tiller angle over recent decades. Dozens of tiller angle-related quantitative trait loci (QTLs) have been explored in rice via classical bi-parental cross mapping [38]. However, most of these QTLs are seldom used for marker-aided selection, due mainly to their minor effects. Recently, a few genes controlling tiller angle have been cloned. PROSTRATE GROWTH 1 (PROG1) has been accepted as a domestication-related gene that controls tiller angle and tiller number during both tillering and heading stages in wild rice. PROG1 encodes a zinc finger nuclear transcription factor and is located on chromosome 7. Amino acid changes in the PROG1 protein and regulatory changes during domestication led to loss of the function of this gene, which promoted the transition from the prostrate growth tillers of wild rice to erect growth tiller of domesticated rice [9,10]. Tiller Angle Control 1 (TAC1) is a major QTL located on chromosome 9 that controls tiller angle during heading stage in cultivated rice and encodes an expressed protein without homologous genes in rice. A mutation in the 3’-splicing site of the 1.5-kb intron ‘GGGA’, which exists in 88 compact japonica rice accessions, decreases the level of tac1 and leads to a smaller tiller angle; ‘AGGA’ is present in 21 wild rice and 43 indica rice accessions with spread-out tillers [11].

Rice shoot gravitropism is suggested to be a key factor affecting plant architecture. The rice la mutant, which exhibits a wider tiller angle, has been intensively studied for decades [1217]. However, the LAZY1 (LA1) gene was not identified until 2007. LA1 encodes a novel, grass-specific protein that controls shoot gravitropism by regulating polar auxin transport (PAT) [18,19]. Loose Plant Architecture 1 (LPA1) is an INDETERMINATE DOMAIN protein involved in shoot gravitropism that regulates both tiller angle and leaf angle in rice during the vegetative and reproductive stages [20]. Suppression of OsPIN1 or over-expression of OsPIN2 (two auxin efflux transporters) alters PAT and increases tiller angle [21,22]. Recent research has demonstrated that strigalactones (SLs), a group of newly identified plant hormones, inhibit auxin biosynthesis and attenuate rice shoot gravitropism primarily by decreasing local indoleacetic acid contents. Multiple SOLs (suppressors of lazy1) involved in SL biosynthesis, such as dwarf 17 (d17), d10 and d27, or in SL signaling pathways, such as d14 and d3, can rescue the spreading phenotype of lazy1 [23]. Suppressing the expression of OsLIC1 (Oryza sativa leaf and tiller angle increased controller), a novel CCCH-type zinc finger gene, increases leaf and tiller angles via the BR signaling pathway [24].

Although the identification of these tiller angle-related genes is helpful for understanding the mechanism of tiller angle formation, few genes that can be used for improving rice plant architecture have been isolated based on natural variation. Therefore, mapping additional genes that contribute to the natural variation of tiller angle is required for breeding varieties with an ideal plant architecture resulting in high grain yields. Genome-wide association studies (GWAS) offer a powerful approach to establishing the relationship between DNA markers and phenotypic traits in crops [25]. With the assessment of millions of single nucleotide polymorphisms (SNPs), GWAS can take full advantage of ancient recombination events to identify the genetic loci underlying complex traits at a high resolution using a large number of crop varieties [26]. Many QTLs for agronomic traits have been identified in cultivated rice through GWAS [2729]. Recently, several novel loci and candidate genes for tiller angle at tillering stage have been identified by GWAS and the elite alleles have been explored for plant architecture improvement [30].

Here, we investigated the tiller angle of 529 O. sativa accessions at heading stage and performed GWAS separately in the full population and the indica and japonica subpopulations. We isolated a novel gene, TAC3, as well as several novel QTLs in this study. We also identified distinct genetic regulatory mechanisms for tiller angle between the two subpopulations, providing information on how to improve tiller angle in indica and japonica rice.

Results

Phenotypic variation of the tiller angle in rice during heading stage

The worldwide rice collection exhibited a distinctive population structure and was classified into nine subpopulations: indI, indII, indica intermediate, Tej, Trj, japonica intermediate, Aus, VI, and intermediate [31]. Of these 529 accessions, 295 were classified into the indica subpopulation, including indI, indII and indica intermediate, and 156 were classified into the japonica subpopulation, including Tej, Trj and japonica intermediate. There were large variations in tiller angle throughout the population in both environments. The tiller angle ranged from 2.5° to 34.4° in Hainan and from 1.8° to 31.5° in Wuhan. The largest number of accessions fell into a small range of tiller angles, from 2° to 16° (Fig 1a). The variations observed in the two environments showed a similar distribution, skewed towards smaller tiller angles. A significant correlation was observed between the two environments in the whole population (r = 0.66). However, there was a significant difference in tiller angle between the indica and japonica subpopulations (Fig 1b and 1c). On average, indica rice exhibits a larger tiller angle (11.7 ± 5.8° in Hainan; 10.5 ± 5.6°in Wuhan) than japonica rice (8.8 ± 3.6° in Hainan; 9.1 ± 3.6° in Wuhan), and the variation within indica is greater than in japonica. The correlation coefficients between Hainan and Wuhan were 0.71 and 0.49 within the indica and japonica subpopulations, respectively. Two-way analysis of variance (ANOVA) revealed that tiller angle was dominantly controlled by genetic factors but was also influenced by interactions between genotype and environment (Table 1). In the japonica subpopulation in particular, the interaction between genotype and environment accounted for 22.6% of the variation in tiller angle (Table 1). Tiller angle had a high heritability of 0.82.

thumbnail
Fig 1. Phenotypic distribution of rice tiller angle.

Histogram showing distributions of tiller angle in the full population (a), in indica accessions (b) and in japonica accessions (c) in Hainan and Wuhan, respectively.

https://doi.org/10.1371/journal.pgen.1006412.g001

thumbnail
Table 1. Summary of variances resolved by two-way ANOVA for rice tiller angle in two environments.

https://doi.org/10.1371/journal.pgen.1006412.t001

QTLs commonly identified in the two environments

We performed GWAS separately in the whole population and in the indica and japonica subpopulations for each year. Manhattan plots and quantile-quantile plots of the rice tiller angles among the three populations are illustrated with the results obtained from both the linear mixture method (LMM) (S1 Fig) and linear regression (LR) approaches (S2 Fig). A total of 30 tiller angle-related QTLs were detected (Table 2 and S1 Table and S2 Table). Of them, seven were commonly detected in Wuhan and Hainan. Three QTLs (qTA1b, 3 and 7a) were only identified through LR, while the remaining was identified through both LMM and LR (Table 2). Among these seven QTLs, 3 (qTA1b, 7a and 8b) were detected only in the whole population, 2 (qTA3 and 7b) were identified only in the indica subpopulation, and two QTLs (qTA8a and 9c) were commonly detected in the whole population and the indica subpopulation. No significant association signals were commonly detected in the japonica subpopulation in the two environments (Table 2). Two QTLs (qTA1b and 3) on chromosomes 1 and 3 individually explained more than approximately 15% of the variation in the whole population and in the indica subpopulation, respectively. Two QTLs (qTA8a and 8b) on chromosome 8 presented different contributions to the tiller angle in the two environments. The QTL of qTA8a exhibited the major effect in the indica subpopulation.

thumbnail
Table 2. Significant association loci for rice tiller angle detected in both Hainan and Wuhan using the LMM and LR.

https://doi.org/10.1371/journal.pgen.1006412.t002

Associations uniquely identified in one environment

In addition to these 7 QTLs commonly detected in both environments, 10 and 13 QTLs were specifically detected in Hainan (S1 Table) and Wuhan (S2 Table), respectively. In Hainan, 5, 4 and 3 QTLs were detected in the whole population and in the indica and japonica subpopulations, respectively. Two QTLs (qTA7d and qTA12a) were commonly detected in the whole population and in the indica subpopulation. Three QTLs were located on chromosome 7. In Wuhan, 4, 3 and 6 QTLs were detected in the whole population and in the indica and japonica subpopulations, respectively. However, no QTLs were commonly detected in either population. There were 3 QTLs on each of chromosomes 1 and 7.

Co-localization of associated sites with previously reported QTLs for the tiller angle

In the past decade, ~11 genes were reported to control tiller angle in rice [32]. However, in the present study, only TAC1 was detected in the local LD region via GWAS in both Hainan and Wuhan (Table 2). To evaluate the results of GWAS, we compared the localization of associated sites with those 11 tiller angle QTLs detected in cultivated rice from the gramene web site (http://www.gramene.org) and 14 significant tiller angle loci detected via GWAS in the previous study[30]. A total of 7 associated sites were found to co-localize with 6 previously reported QTLs (S3 Table). Of them, four QTLs were commonly identified in both environments. qTA1b and qTA9c were found in the regions of QTa1 and qTA-9a, respectively; Both qTA8a and qTA8b were located in a large QTL interval covered a 4-Mb genome region [8, 30]. qTA4 and qTA7h detected only in Wuhan and qTA9b detected in Hainan were identified in QTL regions. The co-localization of QTLs detected through linkage analysis and GWAS indicated their roles in controlling tiller angle.

TAC3, the candidate gene of qTA3, controls tiller angle

The lead SNP sf0329582676 of qTA3 on chromosome 3, which was specifically identified in indica rice, is located in the second intron of Os03g51670, 5 kb upstream of Os03g51660 (Fig 2b). We quantified all 49 SNPs between Os03g51660 and Os03g51670 in 295 indica accessions, and a representation of the obtained pairwise r2 values showed that some SNPs in both genes were in high linkage disequilibrium (LD) with each other. SNPs in the 5’ end of Os03g51660 and Os03g51670 were grouped into one LD block, which made it difficult to determine the candidate gene of qTA3 (Fig 2a). A mutant (05Z11AZ62) was subsequently obtained in which a T-DNA was inserted in the 3’UTR (441 bp from stop codon) of Os03g51670 and the promoter (991 bp from start codon) of Os03g51660 (Fig 2b and 2c); this mutant showed a larger tiller angle compared with the wild type at both tillering and heading stages in 2015 and 2016 of Wuhan (Fig 2g–2i). A segregation analysis of a family of 96 plants (chi square = 3.56) indicated that a single gene controlled the tiller angle. The average tiller angle of homozygous mutants was the largest, while that of heterozygous mutants was intermediate, and wild type plants possessed the smallest tiller angle at both stages in two years (Fig 2g). An expression profiling analysis indicated that Os03g51660 was highly expressed in the tiller base, and the constitutive expression of Os03g51670 (S3d and S3e Fig) implied that Os03g51660 was the candidate gene controlling the tiller angle. We investigated the expression level of Os03g51670 and Os03g51660 between mutants and wild type. The expression level of Os03g51670 was significantly reduced only in the homozygous mutant and not in the heterozygote compared with wild type (Fig 2f). However, the expression level of Os03g51660 was significantly increased in the homozygous mutants and the heterozygotes compared with wild type (Fig 2e). That is, the Os03g51660 expression level co-segregated with the tiller angle. In addition, Os03g51660 was preferentially expressed in the tiller base, where the tiller bud is initiated and outgrown. Therefore, Os03g51660 is the gene underlying qTA3. Hereafter, this gene is referred to as TAC3, and this mutant is named as tac3-1D. To provide strong evidence for our results, another two mutants 1B-24636 (tac3-2D) with a T-DNA insertion in the 5’UTR (146 bp from start codon) of Os03g51660 and 4A-02006 with a T-DNA insertion in the first intron of Os03g51670 (Fig 2b) were investigated in 2016. The expression level of Os03g51660 in both homozygous and heterozygous tac3-2D mutants significantly increased compared with that in wild type Dongjing (Fig 2j). The average tiller angle was no significant difference between heterozygous tac3-2D and wild type Dongjing at both stages, but the tiller angle of homozygous mutant (12.3°±2.9° tillering stage and 11.4°±3.8° heading stage) was significantly larger up to 3° than DJ (9.0°±2.9° tillering stage and 8.6°±2.0° heading stage) (Fig 2l–2n). Whereas the expression of Os03g51670 was not changed in tac3-2D as compared to wild type (Fig 2k). Although expression of Os03g51670 was significantly decreased in both homozygous and heterozygous 4A-02006 mutants (S3a and S3b Fig), tiller angle of mutants was not significantly changed (S3c Fig). Therefore Os03g51660 is the identity of TAC3 controlling tiller angle.

thumbnail
Fig 2. Mutants of the candidate gene for qTA3 showing a larger tiller angle.

(a) A representation of pairwise r2 values (a measure of LD) all polymorphic sites between Os03g51660 and Os03g51670, where the darkness of the color of each box corresponds to the r2 value according to the legend. The line in red color represents lead SNP. (b) Schematic diagram of Os03g51660 and Os03g51670 structures with the T-DNA insertion. The black squares represent exons, and the black lines represent introns. The red line means the position of the lead SNP of qTA3; the triangles indicate the positions of T-DNA insertion in three mutants; L and R, left and right genomic primers; N, vector primer. (c) (d)Genotyping of the mutants tac3-1D and tac3-2D. W, wild type; H, heterozygote; M, homozygote. (e) qRT-PCR expression analysis of Os03g51660 in wild type (ZH11) and tac3-1D mutant using leaves on the beginning of tillering stage; the number of plants in each genotype (n) ≥ 9, *** significant difference between mutants and wild type at p<0.001. (f) qRT-PCR expression analysis of Os03g51670 in ZH11 and tac3-1D mutant using leaves on the beginning of tillering stage; the number of plants in each genotype (n) ≥4 plants, *** significant difference between mutants and wild type at p<0.001. (g)-(i) The tiller angle of ZH11, heterozygote (tac3-1D H) and homozygote (tac3-1D M) mutant at tillering and heading stages; ** and *** significant difference between mutants and wild type at p<0.01 and p<0.001, respectively. (j) qRT-PCR expression analysis of Os03g51660 in wild type (DJ) and tac3-2D mutant using leaves on the beginning of tillering stage; the number of plants in each genotype (n) ≥4 plants, *** significant difference between mutants and wild type at p<0.001. (k) qRT-PCR expression analysis of Os03g51670 in DJ and tac3-2D mutant using leaves on the beginning of tillering stage; the number of plants in each genotype (n) ≥4 plants. (l)-(n) The tiller angle of DJ, heterozygote (tac3-2D H) and homozygote (tac3-2D M) mutant at tillering and heading stages; the total plant number (n) = 62 plants, ** significant difference between mutants and wild type at p<0.01.

https://doi.org/10.1371/journal.pgen.1006412.g002

Characterization of TAC3

The genomic DNA sequence of TAC3 is 1,717 bp in length, with five exons and four introns (Fig 2b). Its coding sequence is 459 bp in length (S3f Fig), and it encodes a conserved hypothetical protein of 152 amino acids (http://rice.plantbiology.msu.edu/).

We detected 3 major haplotypes based on 10 SNPs (Minor Allele Frequency (MAF) ≥ 0.05) in TAC3 among the 295 indica accessions (Table 3). The tiller angle of Hap1 was significantly wider than that of Hap2 and Hap3 in both environments (p≤0.01). However, only 1 G/T SNP (sf0329577726) was found in the japonica subpopulation, and all but two accessions carried the ‘T’ allele, which indicated that a major allele dominated in japonica; by contrast, the ‘G’ allele was present in all but 10 indica accessions. Nucleotide diversity analysis showed that both TAC3 (π = 1.9e-5) and its surrounding genomic region (π = 1.1e-4) of 100 kb upstream and downstream presented significantly decreased values compared with the average nucleotide diversity across the whole japonica genome (π = 1.45e-3), indicating that TAC3 was selected during japonica domestication and genetic improvement (Table 4).

thumbnail
Table 3. Comparison of genetic effects among qTA3/TAC3 haplotypes on tiller angle in indica subpopulation.

https://doi.org/10.1371/journal.pgen.1006412.t003

thumbnail
Table 4. The nucleotide diversity (π = 10−3) of the genes and their surrounding 100-kb regions in indica, japonica and wild rice.

https://doi.org/10.1371/journal.pgen.1006412.t004

TAC1, the candidate gene of qTA9c

qTA9c was closely linked to TAC1, a previously reported rice tiller angle-related gene [11], and its lead SNP was located 1.4 kb upstream to TAC1. Assessment of the LD between the lead SNPs and all polymorphic sites in TAC1 showed that the lead SNP sf0920735688 (PLMM = 4.2e-14) was in high linkage disequilibrium with most polymorphic sites in TAC1 containing GGGA/AGGA (sf0920731363) sites, which are known functional nucleotide polymorphic sites (FNPs) of TAC1 (Fig 3). Therefore, TAC1 was assumed to be the candidate gene of qTA9c. We further investigated a total of 13 SNPs (MAF≥0.05) throughout TAC1 among 529 O. sativa accessions, and 16 haplotypes were detected. The vast majority (285 indica and 156 japonica accessions) of the accessions belonged to Hap1, Hap2 and Hap3 (Table 5). All but one of the japonica accessions were classified into Hap3 with the ‘GGGA’ allele. Most of the indica accessions fell into Hap1 and Hap2, which both contain the ‘AGGA’ allele, whereas 35 indica accessions carried Hap3. There was a highly significant difference (p<0.01) in the tiller angle between Hap1 and Hap3 in the indica subpopulation in both environments (Table 5). These results explained why TAC1 was detected in the whole population and the indica subpopulation, but not in the japonica subpopulation. The nucleotide diversity of TAC1 and its flanking region was subsequently analyzed. Accordingly, a significant reduction in nucleotide diversity was observed at TAC1 in the japonica subpopulation (π = 9.4e-5) compared with both wild rice (π = 1.45e-3) and the average diversity of the whole japonica genome (π = 1.45e-3) (Table 4). We also observed a lower level of nucleotide diversity (π = 1.7e-4) in the 100-kb region surrounding TAC1 in the japonica subpopulation compared with the whole japonica genome. However, no obvious changes were found in the indica subpopulation (π = 3.0e-3).

thumbnail
Fig 3. Schematic diagram of TAC1 structure and linkage disequilibrium (measured as pairwise r2 values) between the lead SNP of qTA9c and all polymorphic sites in TAC1.

The white box and black box in the gene represent UTR and exon region. The darkness of each box corresponds to the r2 value according to the legend. The SNP ID in yellow and red represent FNP and lead SNP respectively.

https://doi.org/10.1371/journal.pgen.1006412.g003

thumbnail
Table 5. Comparison of genetic effect among TAC1 haplotypes on tiller angle in indica and japonica subpopulations.

https://doi.org/10.1371/journal.pgen.1006412.t005

D2, the candidate gene of qTA1b

Brassinosteroid, as one of the main plant hormones, is considered to be an important factor in plant development, including the tiller angle. The lead SNP sf0105241388 of qTA1b is located in the last intron of DWARF 2 (D2). A representation of the obtained pairwise r2 values showed that all SNPs in D2 were in one LD block (Fig 4a). The d2-1 and d2-2 mutant shows a brassinosteroid-deficient phenotype including an erect leaf angle and a short plant height, but the tiller angle of this mutant was not mentioned [33]. Thus, the tiller angle of a mutant we named d2-3 (04Z11MY27) with a T-DNA insertion in the third intron of D2 was investigated (Fig 4b). Genotyping (Fig 4c) and an expression analysis (Fig 4d) suggested that the d2-3 mutant exhibited abnormal growth, including a smaller tiller angle (Fig 4e–4g). This result suggested D2 as the candidate gene of qTA1b. We further investigated the tiller angle of d2-1 and d2-2 to solid our study, and found the tiller angles of both mutants (d2-1: 5.2°±1.3° tillering stage and 3.6°±1.2° heading stage; d2-2: 6.3°±1.5° tillering stage and 3.8°±1.2° heading stage) were significantly decreased as compared with that in wild type T65 (11.3°±3.1° tillering stage and 7.6°±1.5° heading stage) (Fig 4h–4j).

thumbnail
Fig 4. The mutant of D2, the candidate gene of qTA1b, showing decreased tiller angle.

(a) A representation of pairwise r2 values (a measure of LD) all polymorphic sites in D2, where the darkness of the color of each box corresponds to the r2 value according to the legend. The line in red color represent lead SNP. (b) Schematic diagram of D2 gene structure with the T-DNA insertion. The black squares represent exons, and the black lines represent introns. The red arrow indicates the position of lead SNP of qTA1b; the triangle indicates the position of T-DNA insertion; L and R, left and right genomic primers; N, vector primer. (c) genotyping of the d2-3 mutant. W, the wild type; H, heterozygote; M, homozygote. (d) qRT-PCR expression analysis of D2 in wild type ZH11, heterozygote (d2-3 H)and homozygote (d2-3 M) mutant using the tissues aboveground at the seedling stage; the number of plants in each genotype (n)≥3 plants, *** significant difference between mutants and wild type at p<0.001.(e)-(g) Phenotypes of ZH11 and d2-3 mutant (right) at tillering stage and heading stage; the total plant number (n) = 96 plants, *** significant difference between mutants and wild type at p<0.001 (h)-(j) Phenotypes of T65, d2-1 and d2-2 mutant at tillering stage and heading stage; the number of plants in each genotype (n)≥15 plants, *** significant difference between mutants and wild type at p<0.001.

https://doi.org/10.1371/journal.pgen.1006412.g004

To better understand the natural variation of D2, we further analyzed its haplotypes. We constructed the haplotypes of D2 within two subpopulations based on the SNPs with an MAF ≥ 0.05. In the japonica subpopulation, we obtained four main haplotypes excluding the lead SNP sf0105241388 because all but one accession carried the same allele, ‘A’, at this site. Most of the accessions (112) fell into one haplotype. Only 13, 11 and 10 accessions fell into the other three haplotypes. The tiller angle showed no significant differences among these haplotypes (Table 6). In the indica subpopulation, we also obtained four main haplotypes that were different from those in the japonica subpopulation (Table 7). Hap1 and Hap4 exhibited significantly smaller tiller angles compared with Hap2 and Hap3 (p≤0.01). Hap1 and Hap4 carried the allele ‘A’ at the lead SNP site, whereas Hap2 and Hap3 carried the ‘G’ allele. Significantly decreased nucleotide diversity (π = 1.6e-4) was observed only in the japonica subpopulation compared with the average nucleotide diversity of its whole genome (Table 4).

thumbnail
Table 6. Comparison of genetic effects among D2 haplotypes on tiller angle in japonica subpopulation.

https://doi.org/10.1371/journal.pgen.1006412.t006

thumbnail
Table 7. Comparison of genetic effects among D2 haplotypes on tiller angle in indica subpopulation.

https://doi.org/10.1371/journal.pgen.1006412.t007

The effect of three-gene combinations on the tiller angle

According to the results described above, it is clear that TAC3, D2 and TAC1 together, along with other genes, contribute to the natural variation in tiller angle in cultivated rice. Thus, the combinations of TAC3, D2 and TAC1 would be expected to result in wide variation of tiller angles in cultivars.

A total of 77 combinations of the genes TAC3, D2 and TAC1 were observed in the 295 indica accessions, but only 9 combinations that were each found in more than 10 accessions were used for the comparative analysis (Table 8). In Wuhan and Hainan, combinations 1 and 2 both pyramided three haplotypes that increased the tiller angle, resulting in the largest tiller angle. Combinations 3–7 with decreased tiller angle haplotypes of D2 and TAC3, independent of TAC1 showed similar compact plant architecture in both environments. Combination 8 pyramided increasing tiller angle haplotypes of D2 and TAC3, but a decreased tiller angle haplotype of TAC1 resulted in a large tiller angle. Combination 9 carried increasing tiller angle haplotypes of TAC1 and TAC3 but a decreasing tiller angle haplotype of D2, and accordingly exhibited a large tiller angle as well. These results indicated that D2 and TAC3 were the major QTLs in the indica cultivars. Among all 295 indica accessions, 5 carried two combinations with decreasing tiller angle haplotypes at three gene loci. Accessions W066 and W155 (TAC3-Hap3/D2-Hap1/TAC1-Hap3) showed more compact tiller angles (W066: 3.8° in Hainan and 3.5° in Wuhan; W155: 6.0° in Hainan and 5.5° in Wuhan). Similarly, accessions W161, W243 and W244 (TAC3-Hap2/D2-Hap1/TAC1-Hap3) also presented smaller tiller angles (5.2–6.7° in Hainan and 5.2–5.7° in Wuhan).

thumbnail
Table 8. The performance of tiller angle for three-gene combinations in indica subpopulation.

https://doi.org/10.1371/journal.pgen.1006412.t008

Discussion

Diverse genetic basis of the tiller angle between the indica and japonica subpopulations

In general, indica rice exhibits a wide plant type, and japonica rice exhibits a compact plant type. In this study, the indica subpopulation presented wider variation in tiller angle compared with the japonica subpopulation (Fig 1). Although genetic effects explained more of the variation in tiller angle (Table 1), Genotype by environment interactions also significantly affected tiller angle. Moreover, genetic factors contributed more to the variation in tiller angle in indica than in japonica. These results indicated that there are probably different genetic bases underlying the tiller angle in the two subpopulations. Coincidently, GWAS identified more QTLs for the tiller angle in the indica subpopulation than in the japonica subpopulation in both environments. This result indicates that the greater number of QTLs controlling the tiller angle in indica rice would contribute to wider natural variation.

Although a dozen QTLs were identified in each subpopulation, there were no common QTLs detected in both subpopulations in this study. Two QTLs, qTA8a and qTA9c, were found in both the whole population and the indica subpopulation, but not in the japonica subpopulation. It is likely that both QTLs were fixed for one major haplotype in the japonica accessions, resulting in failed detection. For example, the locus qTA9c/TAC1 was not identified in japonica because TAC1 is dominantly fixed with Hap3 in this subpopulation (Table 5). The tiller angle associated with Hap3 was significantly reduced compared with that of Hap1, the major haplotype in indica, which explains the compact plant architecture of japonica rice. There was only one SNP observed in qTA3/TAC3 in japonica, and all but two accessions carried the dominant allele. Thus, the japonica accessions were almost fixed with one haplotype for TAC3. Accordingly, the haplotype analysis of the full population suggested the existence of indica-japonica differentiation for D2: no significant differences in tiller angle were observed among the four main haplotypes within the japonica subpopulation (Table 6), while there was a significant difference in the indica subpopulation (p≤0.01) (Table 7). This suggested that the major QTLs are fixed in japonica. Two QTLs, qTA7a and qTA8b, were only identified in the whole population and were not identified in either the indica or japonica subpopulation. A possible explanation for this finding is that the gene was fixed with different haplotypes in the two subpopulations. When GWAS was performed in each subpopulation, the QTLs were not detected because no polymorphism was present in sequence; however, when GWAS was conducted in the whole population, these QTLs were identified because variation occurred. Hence, it is recommended that GWAS should be performed separately in different populations to discover more QTLs for tiller angle or other traits. According to the above results, we propose that there is diverse genetic basis controlling the tiller angle between the two subpopulations.

TAC1, TAC3 and other genes, regulate tiller angle in rice cultivars rather than PROG1 and LA1

Tiller angle is a domestication-related trait in rice, and selective signatures of domestication include a reduction of nucleotide diversity and altered allele frequencies at domestication-related loci [34,35]. The functional SNPs of PROG1, a gene controlling prostrate growth, only exist in wild rice [9,10]. In addition, PROG1 was detected via GWAS in 446 O. rufipogon accessions and was screened for strong selection signals [36]. In this study, PROG1 was not identified in the examined cultivars. LA1 is another major gene isolated from a mutant that controls the tiller angle, and loss of function of LA1 destroys rice shoot gravitropsim through altering the polar transport of auxin [19]. The lazy1 mutant shows a wider tiller angle of more than 60°, especially during the mature stage, associated with a prostrate growth phenotype [18], which was never observed in our collection. Therefore, la1 and PROG1 do not contribute to the variation of tiller angle in our cultivars.

In this study, GWAS and a mutant analysis demonstrated that TAC3 regulates tiller angle. The nucleotide diversity of TAC3 in japonica (π = 1.9e-5) was approximately 55-fold lower than that of 111 randomly chosen gene fragments from japonica (π = 1.1e-3) [37], which is equivalent to the japonica whole genome estimation in our global collection (π = 1.45e-3). This result suggested that the low TAC3 nucleotide diversity observed in japonica cannot be explained by a population bottleneck alone and indicated that TAC3 was strongly selected probably due to its function in controlling tiller angle during the domestication and improvement of japonica. Accordingly, GWAS, a mutant analysis and nucleotide diversity analysis demonstrated that D2 regulates the tiller angle. Thus, TAC3 and D2 contributed to the natural variation in the tiller angle and have been subjected to selection in japonica. Interestingly, the major TAC1 haplotype in japonica, Hap3, was carried by only a small subset of indica accessions and probably introgressed from japonica. Our study on the selection of TAC1 was consistent with the previous report [38]. qTA8a and qTA8b were approximately 400 kb away on chromosome 8 and were detected via both the LMM and LR approaches. Interestingly, a locus (marker seq-rs3945) associated with tiller angle at tillering stage in indica rice was fallen into the region of qTA8a and several candidate genes on this QTL were predicted by expression analysis [30]. Thus, the 400-kb region containing qTA8a and qTA8b should be further studied by developing an indica bi-parental mapping population. Additionally, there were several QTLs that co-localized with previously reported QTLs, while some QTLs were novel. Hence, TAC3, D2, TAC1 and other unknown genes contribute to the tiller angle variation observed in the cultivars.

Favorable haplotypes/alleles for the improvement of tiller angle in rice

Rice tiller angle is a major component of plant architecture that has been subject to selection from both nature and humans over a long time period. Mining of more favorable alleles of tiller angle genes is required to achieve ideal plant architecture in rice. At the single-gene level, we identified favorable haplotypes for three tiller angle genes. Hap2 (represented by Yuexiangzhan) and Hap3 (represented by 9311) of TAC3 decrease tiller angle, as does Hap3 (represented by Zhenshan 97 in indica and Zhonghua 11 in japonica) of TAC1. Hap1 (represented by Minghui 63 and 9311) and Hap4 (represented by IR72) of D2 also decrease tiller angle. A three-gene combination analysis of D2, TAC3 and TAC1 in indica showed that these three genes cause wide variation in the tiller angle, ranging from 5.2° to 15.4° on average, and combinations pyramiding decreased tiller angle haplotypes result in a more compact plant architecture. These results indicated that these genes function in the regulation of tiller angle and that their effects could be additive. Therefore, optimized haplotype-combinations among these three genes could serve as targets for designed breeding. More specifically, most of the indica cultivars carried TAC1 haplotypes that increased tiller angle; thus, the TAC1 haplotype Hap3 is the first option for improving plant architecture in indica. As most japonica cultivars carried compact haplotypes for TAC1, TAC3 and D2, selecting for the haplotypes of other unknown genes that decrease the tiller angle would be the first option for improving the tiller angle in japonica.

In summary, the tiller angle of cultivated rice is mainly controlled by genetic factors but is also affected, to some extent, by interactions between genotype and environment. The genetic basis of tiller angle is diverse between indica and japonica rice. TAC3, D2 and TAC1 were found to be the main factors regulating tiller angle. Introgression between two subpopulations would be an efficient means of optimizing the plant architecture through designed molecular breeding.

Materials and Methods

Plant materials and field experiments

An association panel consisting of 529 O. sativa landraces and elite accessions was sown at the experimental farm of Huazhong Agricultural University in the winter of 2013 in Hainan and in the 2014 rice growing season in Wuhan (China). The 2-year field experiment was designed with 2 replicates per year. Seven 25-day-old seedlings from these accessions were transplanted in a single row with a distance of 16.5 cm between plants and 26.4 cm between rows on December 30, 2013 and May 12, 2014. The 5 plants in the middle were used to investigate the tiller angle at the heading stage. A protractor was employed to measure the angle between the most distant tillers on the two sides of the culm base, and half of the angle was treated as the tiller angle of the individual plant. The average tiller angle across 2 replicates within one year was used for GWAS. The SNPs of the 529 O. sativa accessions are available in the RiceVarMap (http://ricevarmap.ncpgr.cn/) [39]. The tiller angles of the 529 O. sativa accessions are listed in S4 Table.

Two-way analysis of variance and heritability

Two-way analyses of variance were separately used to test significant difference between environments and genotypes for the whole population and two subpopulations. The analysis was run in the program Statistica 7.0 (StatSoft. Tulsa, OK, USA). Broad-sense heritability (H2) of rice tiller angle in the whole population was calculated based on the experiments using the formula: , where , and were the estimates of genetic, genotype by environment and error variances derived from the mean square expectations of two-way analysis of variance (ANOVA), respectively; n was the number of environments and r was the number of replicates.

Linkage disequilibrium and haplotype analyses

Linkage disequilibrium (LD) was investigated based on standardized disequilibrium coefficients (D’), and squared allele-frequency correlations (r2) for pairs of SNP loci were determined using the TASSEL5.0 program. The extent of genome-wide and chromosome-wide LD were recently reported [40], and the average distances of LD decay at the genome-wide level in all, indica and japonica populations were 167 kb, 93 kb and 171 kb, respectively. The distances of LD decay in the regions surrounding lead SNPs identified in this study were calculated as below: First, r2 values were calculated between lead SNP and all SNPs in its upstream and downstream 2 Mb regions. Then averaged r2 of the top ten percent of r2 values in the region from 1.5 Mb to 2 Mb away from lead SNP were taken as background r2. Finally the LD region was defined a continue region where r2 was 0.2 larger than background r2. LD plots were generated with Haploview4.2, and LD is indicated using r2 values between pairs of SNPs multiplied by 100; white, r2 = 0; shades of gray, 0<r2<1; black, r2 = 1 [41,42]. The SNPs of targeted genes in the 529 O. sativa samples were obtained from the RiceVarMap (http://ricevarmap.ncpgr.cn/) using the gene ID [39]. The haplotypes were classified based on all SNPs with an MAF ≥ 0.05 in a target gene. The haplotypes contains at least 10 investigated accessions were used for comparative analysis. Duncan’s test was employed to compare the differences in the tiller angle among haplotypes using the SSPE program [43].

Genome-wide association analyses

The whole population was previously demonstrated to present a distinct population structure [31]. The indica and japonica subpopulations and the whole population were subjected to GWAS separately because they presented sample sizes of greater than one hundred. A total of 3,916,415, 2,767,159 and 1,857,845 SNPs (minor allele frequency (MAF) ≥ 0.05; the number of accessions with minor alleles ≥ 6) were employed for GWAS using the linear mixture method (LMM) and linear regression (LR) method in the FaST-LMM program [44]. The population structure of Q matrix and kinship (K matrix) was taken into account as cofactor when performing association mapping using the LMM method. The effective numbers of independent SNPs and suggestive thresholds were calculated using a method described by Li et al. [45], and 757,578, 571,843 and 245,348 effective independent SNPs were found in the whole population and the indica and japonica subpopulations, respectively. The suggestive p values used as thresholds for the significance of association signals that were commonly detected in both environments by LMM were 1.3×10−6 for the whole population, 1.8×10−6 for indica and 4.1×10−6 for japonica. However, for significant association signals that were only detected in one environment, we utilized the more stringent p value of 6.0×10−7 as the threshold. A suggestive p value of 1.0×10−8 was employed as the threshold for the significance of association signals detected by LR, but only the top 5 loci detected by LR in each environment are presented in the results. The loci that were commonly identified by LR in both environments, but were not in the top 5 are also presented. For loci that were commonly detected by two methods, only the results of LMM are presented. To obtain independent association signals, multiple SNPs exceeding the threshold in a 5-Mb region were clustered based on an r2 of LD ≥ 0.25; the SNPs showing the minimum p value in a cluster were considered to be lead SNPs.

Nucleotide diversity analyses

The whole genomic DNA sequences of the 529 cultivar accessions were genotyped with approximately 2.5× coverage, and the genome was sequenced using a bar-coded multiplex sequencing approach on an Illumina Genome Analyzer II [31]. We obtained the genome sequences from RiceVarMap (http://ricevarmap.ncpgr.cn/) [39]. A total of 446 O. rufipogon accessions were used to calculate nucleotide diversity (π). The details of these accessions and their sequencing data have been previously reported [36]. π values were estimated at the whole-genome level, the single gene level, and the 100-kb flanking region level using SAMtools [46].

Genotyping of mutant plants

The d2-3 (04Z11MY27), tac3-1D (05Z11AZ62), tac3-2D (1B-24636) and 4A-02006 mutants were obtained from rice T-DNA insertion libraries from the ZH11 variety [47,48] and DJ variety [49,50]. We identified the genotypes of the mutants via PCR using the genomic primers L and R and the vector primer N (S4 Table). PCR was conducted with an initial incubation step at 95°C for 5 min; a second step of 35 cycles at 95°C for 30 s, 58°C for 30 s, and 72°C for 1 min; and a final extension at 72°C for 7 min.

RNA extraction and expression analysis

Total RNA was extracted from different plant tissues with an RNA extraction kit using TRIzol reagent (Invitrogen) for quantitative real-time reverse transcription-polymerase chain reaction (qRT-PCR). The total RNA (4g) was reverse-transcribed using M-MLV reverse transcriptase (Invitrogen). qRT-PCR was carried out in a total volume of 10 μl containing 2.5 μl of the reverse-transcribed products, 0.25 μM gene-specific primers and 5 μl of Fast Start Universal SYBR Green Master (Rox) superMIX (Roche, Mannheim, Germany) in a QuantStudio (TM) 6 Flex System, according to the manufacturer’s introductions. Measurements were obtained using the relative quantification method. Expression levels were normalized against expression of an ubiquitin (UBQ) gene. Error bars indicate standard deviations (n = 3). All primers employed for qRT-PCR are listed in S5 Table.

Supporting Information

S1 Fig. Genome-wide association study for tiller angle in the whole population, the indica and the japonica subpopulations by LMM.

Manhattan plots and quantile-quantile plots for tiller angle in the full population (a), indica subpopulation (b) and japonica subpopulation (c). The horizontal dashed lines of the Manhattan plots indicate the significance thresholds that are defined in the section of materials and methods. Lambda of quantile-quantile plots represents the expected null distribution and the observed p value.

https://doi.org/10.1371/journal.pgen.1006412.s001

(TIF)

S2 Fig. Genome-wide association study for tiller angle in the whole population, the indica and the japonica subpopulations by LR.

Manhattan plots and quantile-quantile plot for tiller angle in the full population (a), indica subpopulation (b) and japonica subpopulation (c). The horizontal dashed lines of the Manhattan plots indicate the significance thresholds that are defined in the section of materials and methods. Lambda of quantile-quantile plots represents the expected null distribution and the observed p value.

https://doi.org/10.1371/journal.pgen.1006412.s002

(TIF)

S3 Fig. Expression profiles of Os03g51660 (TAC3) and Os03g51670 and the sequence of TAC3 cDNA.

(a) Genotyping of the 4A-02006 mutant. W, the wild type; H, heterozygote; M, homozygote. (b) qRT-PCR expression analysis of Os03g51670 in wild type DJ, heterozygote (4A-02006 H)and homozygote (4A-02006 M) mutant using the leaves of tillering stage; the number of plants in each genotype (n)≥3, *** p<0.001. (c) Phenotypes of wild type (n = 16), 4A-02006 H (n = 47) and 4A-02006 M (n = 21) at tillering stage and heading stage. (d), (e) Expression of Os03g51660 (TAC3) and Os03g51670, the tissues followed by 1 and 2 were collected at tillering stage and heading stage, respectively. (f) TAC3 cDNA is of 459 bp.

https://doi.org/10.1371/journal.pgen.1006412.s003

(TIF)

S1 Table. Significant signals for tiller angle detected only in Hainan using the LMM and LR methods.

https://doi.org/10.1371/journal.pgen.1006412.s004

(DOC)

S2 Table. Significant signals for tiller angle detected only in Wuhan using the LMM and LR methods.

https://doi.org/10.1371/journal.pgen.1006412.s005

(DOC)

S3 Table. Co-localization of associated sites with the previously detected tiller angle-related QTLs in rice.

https://doi.org/10.1371/journal.pgen.1006412.s006

(DOC)

S4 Table. The tiller angle of 529 O. sativa in Hainan and Wuhan.

https://doi.org/10.1371/journal.pgen.1006412.s007

(XLS)

Acknowledgments

We thank Mr. J.B. Wang for his excellent work in field management. We appreciate Professor Changyin Wu (Huazhong Agricultural University) kindly providing 04Z11MY27 and 05Z11AZ62 mutants, Professor Makoto Matsuoka (Nagoya University) kindly providing d2-1 and d2-2 mutants and Professor Gynheung An (Kyung Hee University) kindly providing 1B-24636 and 4A-02006 mutants.

Author Contributions

  1. Conceived and designed the experiments: YX.
  2. Performed the experiments: HD XB KL LY.
  3. Analyzed the data: HD HZ WX ZH GL WY ZG.
  4. Contributed reagents/materials/analysis tools: YX WX HD HZ GL YH.
  5. Wrote the paper: HD YX.

References

  1. 1. Wang Y, Li J (2008) Molecular basis of plant architecture. Annu Rev Plant Biol 59: 253–279. pmid:18444901
  2. 2. Wang Y, Li J (2008) Rice, rising. Nature genetics 40: 1273–1275. pmid:18957983
  3. 3. Li C, Zhou A, Sang T (2006) Genetic analysis of rice domestication syndrome with the wild annual species, Oryza nivara. New phytologist 170: 185–194. pmid:16539615
  4. 4. Li Z, Paterson AH, Pinson SR, Stansel JW (1999) RFLP facilitated analysis of tiller and leaf angles in rice (Oryza sativa L.). Euphytica 109: 79–84.
  5. 5. Qian Q, He P, Teng S, Zeng D-L, Zhu L-H (2000) [QTLs analysis of tiller angle in rice (Oryza sativa L.)]. Yi chuan xue bao = Acta genetica Sinica 28: 29–32.
  6. 6. Thomson M, Tai T, McClung A, Lai X, Hinga M, et al. (2003) Mapping quantitative trait loci for yield, yield components and morphological traits in an advanced backcross population between Oryza rufipogon and the Oryza sativa cultivar Jefferson. Theoretical and applied genetics 107: 479–493. pmid:12736777
  7. 7. Xu Y, Shen Z, Xu J, Zhu H, Chen Y, et al. (1995) Interval mapping of quantitative trait loci by molecular markers in rice (Oryza sativa L). Science in China Series B, Chemistry, life sciences & earth sciences 38: 422–428.
  8. 8. Yan J, Zhu J, He C, Benmoussa M, Wu P (1999) Molecular marker-assisted dissection of genotype× environment interaction for plant type traits in rice (Oryza sativa L.). Crop science 39: 538–544.
  9. 9. Jin J, Huang W, Gao J-P, Yang J, Shi M, et al. (2008) Genetic control of rice plant architecture under domestication. Nature genetics 40: 1365–1369. pmid:18820696
  10. 10. Tan L, Li X, Liu F, Sun X, Li C, et al. (2008) Control of a key transition from prostrate to erect growth in rice domestication. Nature genetics 40: 1360–1364. pmid:18820699
  11. 11. Yu B, Lin Z, Li H, Li X, Li J, et al. (2007) TAC1, a major quantitative trait locus controlling tiller angle in rice. The Plant Journal 52: 891–898. pmid:17908158
  12. 12. Abe K, Suge H (1993) Role of gravitropic response in the dry matter production of rice (Oryza sativa L.): an experiment with a line having lazy gene. Journal of plant research 106: 337–343.
  13. 13. Abe K, TakAhashi H, Suge H (1994) Graviresponding sites in shoots of normal and ‘lazy’rice seedlings. Physiologia Plantarum 92: 371–374.
  14. 14. Abe K, Takahashi H, Suge H (1996) Lazy gene (la) responsible for both an agravitropism of seedlings and lazy habit of tiller growth in rice (Oryza sativa L.). Journal of plant research 109: 381–386. pmid:11539861
  15. 15. JONES JW, ADAIR CR (1938) A “lazy” mutation in rice. Journal of Heredity 29: 315–318.
  16. 16. Yamazaki Y (1985) Lazy rice gotten up with tryptophan. The botanical magazine = Shokubutsu-gaku-zasshi 98: 193–198.
  17. 17. Godbole R, Takahashi H, Hertel R (1999) The Lazy mutation in rice affects a step between statoliths and gravity‐induced lateral auxin transport. Plant Biology 1: 379–381.
  18. 18. Yoshihara T, Iino M (2007) Identification of the gravitropism-related rice gene LAZY1 and elucidation of LAZY1-dependent and-independent gravity signaling pathways. Plant and cell physiology 48: 678–688. pmid:17412736
  19. 19. Li P, Wang Y, Qian Q, Fu Z, Wang M, et al. (2007) LAZY1 controls rice shoot gravitropism through regulating polar auxin transport. Cell research 17: 402–410. pmid:17468779
  20. 20. Wu X, Tang D, Li M, Wang K, Cheng Z (2013) Loose Plant Architecture1, an INDETERMINATE DOMAIN protein involved in shoot gravitropism, regulates plant architecture in rice. Plant physiology 161: 317–329. pmid:23124325
  21. 21. Xu M, Zhu L, Shou H, Wu P (2005) A PIN1 family gene, OsPIN1, involved in auxin-dependent adventitious root emergence and tillering in rice. Plant and cell physiology 46: 1674–1681. pmid:16085936
  22. 22. Chen Y, Fan X, Song W, Zhang Y, Xu G (2012) Over‐expression of OsPIN2 leads to increased tiller numbers, angle and shorter plant height through suppression of OsLAZY1. Plant biotechnology journal 10: 139–149. pmid:21777365
  23. 23. Sang D, Chen D, Liu G, Liang Y, Huang L, et al. (2014) Strigolactones regulate rice tiller angle by attenuating shoot gravitropism through inhibiting auxin biosynthesis. Proceedings of the National Academy of Sciences 111: 11199–11204.
  24. 24. Wang L, Xu Y, Zhang C, Ma Q, Joo S-H, et al. (2008) OsLIC, a novel CCCH-type zinc finger protein with transcription activation, mediates rice architecture via brassinosteroids signaling. PloS one 3: e3521–e3521. pmid:18953406
  25. 25. Rafalski JA (2010) Association genetics in crop improvement. Current opinion in plant biology 13: 174–180. pmid:20089441
  26. 26. Huang X, Han B (2014) Natural variations and genome-wide association studies in crop plants. Annual review of plant biology 65: 531–551. pmid:24274033
  27. 27. Huang X, Wei X, Sang T, Zhao Q, Feng Q, et al. (2010) Genome-wide association studies of 14 agronomic traits in rice landraces. Nature genetics 42: 961–967. pmid:20972439
  28. 28. Huang X, Zhao Y, Wei X, Li C, Wang A, et al. (2012) Genome-wide association study of flowering time and grain yield traits in a worldwide collection of rice germplasm. Nature genetics 44: 32–39.
  29. 29. Zhao K, Tung C-W, Eizenga GC, Wright MH, Ali ML, et al. (2011) Genome-wide association mapping reveals a rich genetic architecture of complex traits in Oryza sativa. Nature communications 2: 467. pmid:21915109
  30. 30. Lu Q, Zhang M, Niu X, Wang S, Xu Q, et al. (2015) Genetic variation and association mapping for 12 agronomic traits in indica rice. Bmc Genomics 16: 1–17.
  31. 31. Chen W, Gao Y, Xie W, Gong L, Lu K, et al. (2014) Genome-wide association analyses provide genetic and biochemical insights into natural variation in rice metabolism. Nature genetics 46: 714–721. pmid:24908251
  32. 32. Roychoudhry S, Kepinski S (2015) Shoot and root branch growth angle control—the wonderfulness of lateralness. Current opinion in plant biology 23: 124–131. pmid:25597285
  33. 33. Hong Z, Ueguchi-Tanaka M, Umemura K, Uozu S, Fujioka S, et al. (2003) A rice brassinosteroid-deficient mutant, ebisu dwarf (d2), is caused by a loss of function of a new member of cytochrome P450. The Plant Cell 15: 2900–2910. pmid:14615594
  34. 34. Xu X, Liu X, Ge S, Jensen JD, Hu F, et al. (2012) Resequencing 50 accessions of cultivated and wild rice yields markers for identifying agronomically important genes. Nature biotechnology 30: 105–111.
  35. 35. Doebley JF, Gaut BS, Smith BD (2006) The molecular genetics of crop domestication. Cell 127: 1309–1321. pmid:17190597
  36. 36. Huang X, Kurata N, Wei X, Wang Z-X, Wang A, et al. (2012) A map of rice genome variation reveals the origin of cultivated rice. Nature 490: 497–501. pmid:23034647
  37. 37. Caicedo AL, Williamson SH, Hernandez RD, Boyko A, Fledel-Alon A, et al. (2007) Genome-wide patterns of nucleotide polymorphism in domesticated rice. PLoS Genet 3: 1745–1756. pmid:17907810
  38. 38. Jiang J, Tan L, Zhu Z, Fu Y, Liu F, et al. (2012) Molecular evolution of the TAC1 gene from rice (Oryza sativa L.). Journal of Genetics and Genomics 39: 551–560. pmid:23089365
  39. 39. Zhao H, Yao W, Ouyang Y, Yang W, Wang G, et al. (2015) RiceVarMap: a comprehensive database of rice genomic variations. Nucleic acids research 43: D1018–D1022. pmid:25274737
  40. 40. Xie W, Wang G, Yuan M, Yao W, Lyu K, et al. (2015) Breeding signatures of rice improvement revealed by a genomic variation map from a large germplasm collection. Proceedings of the National Academy of Sciences of the United States of America 112: 5411–5419.
  41. 41. Barrett JC (2009) Haploview: Visualization and analysis of SNP genotype data. Cold Spring Harbor Protocols 2009: pdb. ip71.
  42. 42. Gabriel SB, Schaffner SF, Nguyen H, Moore JM, Roy J, et al. (2002) The structure of haplotype blocks in the human genome. Science 296: 2225–2229. pmid:12029063
  43. 43. Lu L, Shao D, Qiu X, Sun L, Yan W, et al. (2013) Natural variation and artificial selection in four genes determine grain shape in rice. New Phytologist 200: 1269–1280. pmid:23952103
  44. 44. Lippert C, Listgarten J, Liu Y, Kadie CM, Davidson RI, et al. (2011) FaST linear mixed models for genome-wide association studies. Nature Methods 8: 833–835. pmid:21892150
  45. 45. Li M-X, Yeung JM, Cherny SS, Sham PC (2012) Evaluating the effective numbers of independent tests and significant p-value thresholds in commercial genotyping arrays and public imputation reference datasets. Human genetics 131: 747–756. pmid:22143225
  46. 46. Li H, Handsaker B, Wysoker A, Fennell T, Ruan J, et al. (2009) The sequence alignment/map format and SAMtools. Bioinformatics 25: 2078–2079. pmid:19505943
  47. 47. Wu C, Li X, Yuan W, Chen G, Kilian A, et al. (2003) Development of enhancer trap lines for functional analysis of the rice genome. The Plant Journal 35: 418–427. pmid:12887592
  48. 48. Zhang J, Guo D, Chang Y, You C, Li X, et al. (2007) Non‐random distribution of T‐DNA insertions at various levels of the genome hierarchy as revealed by analyzing 13 804 T‐DNA flanking sequences from an enhancer‐trap mutant library. The Plant Journal 49: 947–959. pmid:17253985
  49. 49. Dong J, Zhao CG (2006) Generation of a flanking sequence-tag database for activation-tagging lines in japonica rice. Plant Journal 45: 123–132. pmid:16367959
  50. 50. Jeon JS, Lee S, Jung KH, Jun SH, Jeong DH, et al. (2000) T-DNA insertional mutagenesis for functional genomics in rice. Plant Journal for Cell & Molecular Biology 22: 561–570.