A homologous gene of OsREL2/ASP1, ASP-LSLregulates pleiotropic phenotype including long sterile lemma in rice

Background

Panicle is a harvesting organ of rice, and its morphology and development are closely associated with grain yield. The current study was carried on a mutant screened through an EMS (ethyl-methane sulphonate) mutagenized population of a Japonica cultivar Kitaake (WT)．

Results

A mutant, named asasp-lsl(aberrant spikelet-long sterile lemma), showed a significant decrease in plant height, number of tillers, thousand-grains weight, seed setting rate, spikelet length, kernel length and effective number of grains per panicle as compared to WT.Asp-lslshowed a pleiotropic phenotype coupled with the obvious presence of a long sterile lemma. Cross-sections of lemma showed an increase in the cell volume rather than the number of cells. Genetic segregation analysis revealed its phenotypic trait is controlled by a single recessive nuclear gene. Primary and fine mapping indicated that candidate gene controlling the phenotype ofasp-lslwas located in an interval of 212 kb on the short arm of chromosome 8 between RM22445 and RM22453. Further sequencing and indels markers analysis revealedLOC_Os08g06480harbors a single base substitution (G→A), resulting in a change of 521st amino acid(Gly→Glu. The homology comparison and phylogenetic tree analysis revealed mutation was occurred in a highly conserved domain and had a high degree of similarity in Arabidopsis, corn, and sorghum. The CRISPR/Cas9 mutant line ofASP-LSLproduced a similar phenotype as that ofasp-lsl．亚细胞定位ASP-LSL透露那t its protein is localized in the nucleus. Relative expression analysis revealedASP-LSLwas preferentially expressed in panicle, stem, and leaves. The endogenous contents of GA, CTK, and IAA were found significantly decreased inasp-lslas compared to WT.

Conclusions

Current study presents the novel phenotype ofasp-lsland also validate the previously reported function ofOsREL2 (ROMOSA ENHANCER LOCI2), /ASP1(ABERRANT SPIKELET AND PANICLE 1).

Rice is the world’s main food crop, and its yield is essential for food security. Spikelet development is one of the most important traits for yield. Rice is considered a model crop for monocotyledons due to its unique structural unit of spikelet compared to dicotyledons. Grasses spikelet consists of two sterile glumes (rudimentary glumes), empty glumes, and a pair of fertile glumes that are further called lemma and palea [1,2]. According to previous studies, spikelet development can be roughly divided into the following eight stages: the first stage (Sp1) includes the formation of the incomplete rudimentary glume primordia. From second to fourth stage (Sp2-Sp4), glume primordium differentiates into lemma and palea primordium. The formation of lodicule and stamen occur at the fifth (Sp5) and sixth (Sp6) stage of spikelet development, respectively. The seventh (Sp7) and eighth (Sp8) stages involve the formation of carpel primordium and development of ovule and pollen, respectively [3]. So far, numerous genes have been cloned that function at different stages of spikelet development. Mutants with abnormal spikelet development showing hindrance at various stages can be used as important materials for studying molecular mechanism.

In terms of floral organs development, there are certain differences between monocotyledonous and dicotyledonous plants. However, homologous sequence alignment and transgene analysis showed that ABCDE model of dicotyledons applies to monocotyledons to a certain extent. Hence, above-mentioned model can also be applied to understand developmental mode of rice floral organs [4,5,6,7,8,9,10,11]. According to ABCDE model, so far, five types of MADS-box genes have been cloned and divided based on their function. These floral genes e.g., A, B, C, D and E regulate different independent or coordinated actions for a final phenotype of floret.

According to ABCDE model of rice, contrary to Arabidopsis, class A genes are mainly expressed in the outer two whorls of floral organs e.g.,OsMADS14[12,13],OsMADS15andOsMADS18[14] are all AP1 (ACITVATOR PROTEIN 1)-like genes [15,16]. Exceptionally,OsMADS14expresses in spikelet meristem (SM), inner lemma, palea, pistil, and stamen at maturity [17].OsMADS14affected the flowering period, and its overexpression leads to early flowering in rice [18].OsMADS15normally expressed in lemma and lodicules, and mutants ofOsMADS15exhibited elongation of inner and outer glumes [19].OsMADS18has transcripts in all floral tissues and affected the flowering period. It’s overexpression caused early flowering but RNAi-silencing did not affect the phenotype compared with its wild type (WT) [20].

In rice, class B genes include e.g.,OsMADS2, OsMADS4, andOsMADS16/SUPERWOMAN1 (SPW1)[21]. These are also conserved in angiosperms.OsMADS2andOsMADS4are homologous to the Arabidopsis PI(PSEUDOGENE)gene, and OsMADS16 is homologous gene of Arabidopsis AP3 gene [22,23]. The transgenic plants ofOsMADS2通过基因沉默显示elongat异常ion of lodicule [24].OsMADS2played a key role in the development of rice panicle by controlling the function of lodicule and stamens [25]. Loss of function ofOsMADS4引发palea-like大闪蝶鳞片展示logy, and stamens exhibited a carpel-like morphology. Similarly, loss of function ofOsMADS16caused the stamens and lodicules to transform into carpels and palea-like structures, respectively [26].

In rice, class C genes include e.g.OsMADS3[5],OsMADS58[27] andDROOPING LEAF (DL)[28]. Among them,OsMADS3andOsMADS58are homologous genes of Arabidopsis AG gene[29], and DL is homologous to ArabidopsisCRC (CRABSCLAW)．OsMADS3normally expressed in carpels and stamens [30], which mainly controls the development of stamens [31] and inhibits lodicule development. Loss of function ofOsMADS3showed decisive loss of floral meristem (FM), and stamens turn into a pulp-like structure.OsMADS58mainly controls the development of FM and its RNAi transgenic plant produced cup-shaped carpel [32].DLregulates the development of FM, and a mutation indl改变了心皮成雄蕊(27].

In rice, class D genes mainly refer toOsMADS13, which is the STK (SERINE/THREONINE KINAS) gene of Arabidopsis and homologous toFBP7 (F-BOX PROTEIN 67)/FBP11of petunia.OsMADS13is only expressed in the carpel and mainly concentrated in the ovule. [30,31,32].

In rice, E genes include several types of genes e.g.,SEP (SEPALLATA), LOFSEP (LOSS OF TRANSCRIPTION FACTOR OF SEP), andAGL6 (AGAMOUS-LIKE 6)[33,34]:OsMADS7(OsMADS45) andOsMADS8 (OsMADS24)are homologous to ArabidopsisSEP[35,36]; while, LOFSEP includeOsMADS1/LEAFY HULL STERILE 1 (LHS1)[37,38].OsMADS5 (OsM5)andOsMADS34/PANlCLE PHYTOMER2 (PAP2) are included inAGL6and mainly refers toOsMADS6/MOSAIC FLRALORGANS 1 (MFO1)[39]. In rice, theLHS1regulates the development of lemma and lemma coupled with the development of FM. Its ectopic expression can lead to the elongation of the spikelet [38,40,41,42].OsMADS6regulates the development of FM and floral organs and interacts withDLto jointly regulate the development of palea, making palea to a lemma-like structure [43].OsMADS34has pleiotropic effect and its mutation not only turns the SM abnormal but also transformed the rudimentary glume into an elongated palea [37,44].

Genes such asOsMADS34andG1can regulate the characteristics of rice glume development, and its mutations caused the glume to exhibit the phenotype of a lemma-like structures [45].MULTI-FLORET SPIKELET2 (MFS2)encodes a MYB transcription factor and controls the identity of palea.MFS2is a transcriptional repressor (TRP) and interacts with TOPLESS (TPL)-related proteins and forms a complex; as a result number of floral organs were increased inmfs2[46]. OsREL2 (ROMOSA ENHANCER LOCI2), orthologous to Arabidopsis TPL, showed a pleiotropic effect including long sterile lemma and defects in panicle heading [47]. Similarly,OsLIS-L1 (LISSENCEPHALY TYPE-1-LIKE-1)encodes a protein with WD (Trp-Asp) domain repeats and revealed semi-dwarfism and defects in fertility [48].ASP1 (ABERRANT SPIKELET AND PANICLE 1)encodes a TPL protein and control pleiotropic phenotype, including change in the meristem, phyllotaxy, and branching meristem by the intervention of auxin [49].

In this study, we have screened a mutant created by EMS mutagenized population of a wild type cultivar Kitaake (WT). Phenotype, genetic, and expression analysis revealed this gene is homologous to already reportedREL2andASP1.Although similar phenotypes have already been reported inasp1, but presence of some different phenotypes especially long sterile lemma encouraged us to study further. Our findings not only validate pleiotropic effect ofASP1andOsREL2but also present some more phenotypic defects e.g., dwarfism, spikelet shortness and long sterile lemma, that we are reporting for first time.

The phenotypic observation and measurement of agronomic traits revealed pleiotropic effect ofASP-LSL

Data of agronomic traits ofasp-lsl和WT (Kitaake) reveale测量和结果d that plant height, length of panicle, grain length, number of seeds per panicle, thousand-grain weight, seed setting rate and length of sterile lemma were significantly different inasp-lsl．Compared with its WT, theasp-lslhas reduced plant height by 23.2 %, panicle length by 21.1 %, seed setting rate by 29.2 %, 1000-kernel weight by 28.9 %, spikelet length by 34.4 %, and kernel length by 22.3 %. The most prominent spikelet variation ofasp-lslmutant was its increased and widened sterile lemma, as compared to its WT (Fig.1）.The glume length and width were 4.7 and 2.7 times increased inasp-lslthan that of WT, respectively. Protective glumes accounted ~ 1.9 % of the thousand-grain weight inasp-lsl．After removing glumes, compared with its WT,asp-lslcaryopsis became slender and thousand-grain weight decreased by 33.1 % (as shown in Table1）.It indicates that changes in grain type ofasp-lslled to the decrease in thousand-grain weight, and ultimately decrease in yield.

asp-lslshowed delayed germination and decreased seed viability

Compared with the WT seeds, theasp-lslseeds were slender but not filled properly. Observation and statistics of germination record revealed not only the emergence rate ofasp-lslwas lower but the germination was also significantly delayed. The germination rate ofasp-lslon the third day of germination was only 8 %, which was significantly lower than 72.3 % of its WT. The overall germination rate ofasp-lslwas 69 % that was significantly lower than WT (88.3 %). Results of germination assay revealed that seed viability was significantly decreased inasp-lsl(Fig.2）.

Analysis of inter-node length of stem

To further analyze of dwarfing ofasp-lsl, we measured each stem internode at the maturity stage. Comparison of results showed the first, second, third, and fourth internodes ofasp-lslwere shorter in length than those of WT (Fig.3A). The relative change in length of the first, second, third, and fourth internode betweenasp-lslis given in Fig.3B. Among them, the difference in the first internode was more significant (Table2）.Analysis of the internode length ofasp-lsland WT revealed that dwarfing was mainly caused by the shortening of internodal distance.

Spikelet morphology and fertility observation ofasp-lsl

The spikelet ofasp-lslhas a similar floret structure to WT except a longer sterile lemma (Fig.4A and B). Pollen viability was checked using KI-I₂staining, and results revealed no significant changes in fertility between WT andasp-lsl(Fig.4C and D). To further look down minor changes in lemma morphology, paraffin cross-sections were prepared (Fig.4E and F). The results of lemma morphology observation revealed the presence of larger cell volume. However, there was no significant change in the number of cells of sterile lemma. So, larger lemma was produced as result of the change in cells volume rather than the number of cells.

asp-lslshowed significant changes GA, CTK, and IAA phytohormones

In order to compare changes in the shape ofasp-lslarchitecture, we determined the relevant hormones e.g., GA (Gibberellins), IAA (Indole acetic acid), and CTK (cytokinin) content in stem and panicle. The results showed GA, CTK, and IAA ofasp-lslhad significant changes as compared with its WT (Fig.5）.GA, CTK, and IAA ofasp-lslwere found significantly lower in stem and young panicle than that of WT.

A single recessive gene controls the phenotype inasp-lsl

Using Yixiang 1B and KTK as male parents andasp-lslas female parent, were crossed to get two mapping populations (asp-lsl*YXB andasp-lsl*KTK). Both populations were observed for phenotypes in F₁and F₂．The results showed that the phenotype of all F₁plants were consistent with the WT phenotype. F₁were selfed to get F₂progeny; in later one, plants appeared with the both (WT andasp-lsl) type of phenotype. χ2 (Chi-square) test of segregation ratio between of WT vs.asp-lslwas in accordance with the Mendelian ratio of 3:1 (Table3）.The phenotypic segregation ratio of both F₂population can validate that mutant phenotype is controlled by a single recessive gene.

Primary and fine mapping ofASP-LSL

An F₂segregated population, constructed from the cross ofasp-lsland Yixiang 1B was used for gene mapping. Primarily, 456 pairs of SSR markers were used for primary gene mapping and locus was initially positioned between RM22418 and RM22529 (Fig.6）.In order to further locate, different Indel markers were applied and the interval was narrowed down to a region of 212 kb between Indel-1 and Indel-2. Twenty-six candidate genes were present in an interval of 212 kb. Analyzing all genes in this interval, it was found that theLOC_Os08g06480contains an SNP. Using WT andASP-LSLcDNA as templates, the gene was amplified and sequenced. An SNP was detected that changed cDNA (1562nd nucleotide) ofLOC_Os08g06480from G (guanine) → A (adenine). As a result of single frame-shift mutation, 521th amino acid was changed from G (glycine) → E (glutamic acid). So, we regarded theASP-LSLgene as a candidate gene for the given phenotype ofasp-lsl．To verify the mutation, 20 single plants were selected from the WT andasp-lslfrom the F₂segregated population and verified using Tetra-Primer ARMS PCR.

Knock out ofASP-LSLplants showedasp-lslphenotype

In order to verify, theASP-LSLgene is responsible for the above-mentioned mutant phenotype (Fig.7A). A CRISPR/Cas9 vector targeted at the first exon (ATCCTGCAGTTCCTCGATGAGG) ofASP-LSL．The knock-out line-1 (ko-1) showed an increased length of sterile lemma, short plant height coupled with phenotype ofasp-lsl(Fig.7B). Meanwhile, we analyzed gene expression by RT-qPCR, and results showed a significant decrease in the expressionASP-LSLin knock-out lines (Fig.7D). The chromatogram ofko-1showed a 2 bp deletion as compared to its WT (Fig.7E). Number of days of maturity, plant height, panicle length, seed setting rate, grain width and grain length have been significantly decreased inko-1as compared to WT (Fig.7F).

Phylogenetic analysis ofASP-LSL

A complete comparison of amino acid sequence ofASP-LSLwas used for construction of a phylogenetic tree at threshold of 70-99 %. As shown in the figure, all the reported mutations were occurred in a highly conserved action site, similar as in the mutantasp-lsl(Fig.8A). The ASP-LSL protein has highest homology with a TOPLESS- protein in higher plants (Fig.8B).

Subcellular localization ofASP-LSL

We constructedASP-LSL-YFPand empty YFP vectors and transformed them into rice protoplasts. Compared with WT, nuclear colocalization ofASP-LSLrevealed yellow fluorescence that overlaps with the red and formed an orange fluorescence as a nuclear localization signal (Fig.9）.Results of subcellular localization showed ASP-LSL is a nuclear protein.

Relative expression of floral development-related genes inASP-LSL

Development ofasp-lslwas different than that of WT, to know which related genes were involved in expressing the different phenotype ofasp-lsl.Young panicle at different growth periods were selected to detect the expression of different panicle development related genes. Different MADS genes e.g.,MFS1, OsMADS3, OsMADS4andOsMADS16showed a significant change inasp-lslas compared to WT. Quantitative expression of floral development-related genes showed different expression levels at different stages. The expression level ofMFS1in the mutants was higher than that of WT at P3 and P4 stages (Fig.10）.OsMADS4andOsMADS16had higher expression levels inasp-lslat the later stage of young panicle development, whileOsMADS3showed the highest expression level at P1-P5. The sequence of primers used for relative expression analysis is given in Table4．

ASP-LSLencodes a single recessive nuclear transactional repressor gene

In this study, an aberrant spikelet mutant was obtained by EMS mutagenesis of a wild cultivar, Kitaake. Through the inspection and comparison of agronomic traits,asp-lslshowed multiple defects including, the structure of spikelet and major agronomic yield traits e.g., plant height, number of tillers, seed setting rate, 1000-kernel weight, and number of effective grains per panicle were significantly compromised. Segregation and gene mapping analysis revealed its phenotypes were controlled by a single recessive nuclear.LOC_Os08g06480encodes a TPR/TPL nuclear transcriptional co-repressor. Transcriptional co-repressors have been already reported to play their role in controlling the spikelet, seed size and weight in rice and Arabidopsis [33,50]. Phylogenetic analysis revealed that mutation was occurred in highly conserved site and have been reported in maize, sorghum and rice [1,49]. This site can be targeted by molecular breeder to solve the specific problem of germination in hybrid rice [51]. Protein of this site may have specific binding activity to some other genes that regulate different traits including the development of lemma [48]. In recent years, many genes controlling flower development in rice have been cloned. Most of them are homologous to Arabidopsis and have a certain degree of conservation. These findings provide a basis for studying more about the regulation mechanism of rice flower development, without disturbing other major agronomic yield traits [51,52]. In grasses, these homologous proteins can interact with ETHYLENE RESPONSE FACTOR (ERF), Jasmonic acid (JA), and IAA [47,49]. Endogenous measurement of phytohormone contents suggested thatASP-LSLis sensitive to IAA that has an extensive role in plant growth and development activities.ASP-LSLalso showed the action of IAA in regard to transition meristem fate and phyllotaxy during the vegetative phase [49,53,54]. The different phenotype ofASP-LSLcould be a result of its molecular interaction with other spikelet development and auxin signaling pathway genes.

ASP-LSLcontrols the novel phenotype in japonica cv. Kitaake

According to National Rice Data Center (ricedata.cn),ASP-LSLlocus has already been reported in different articles. All the previous materials that were identified and reported so far belong to Nipponbare and Dongjin. Inasp-lsl, site of mutation (521th amino acid Gly to Glu) is also novel, and this mutation has not been reported before. Moreover, all previous studies used T-DNA mutations, while we used EMS as a source of mutagenesis. Moreover,asp-lslshowed different salient features as compared to other mutants, which are given below.

1. (1)

   OsREL2produced pleiotropic phenotype e.g., a greater number of secondary branches than primary branches and reduced number of floral organs etc., as compared to WT. T-DNA insertion mutant,osrel2also showed phenotype defects in panicle development. Contrary toOsREL2, ASP-LSLhas an extra-long sterile lemma that bypasses the whole length of its spikelet. While inosrel2sterile lemma merely passes the half of the length of spikelet [47].

2. (2)

   OsLIS-L1was a single recessive gene, reported to regulate pleiotropic phenotype and considered essential for fertility and internode elongation.OsLIS-L1encodes a protein that contains a WD40 motif, which is necessary for human brain development.OsLIS-L1was highly expressed in rice stems and panicles, but its expression in panicles showed dynamic changes at different developmental stages. Two independent alleles,oslis-1-1andoslis-1-2both showed reduced male gamete fertility, semi-dwarfism and shorter length of panicle.OsLIS-L1plays an important role in the elongation of the inverted internodes and the formation of male gametophytes [48]. The apparent difference ofOsLIS-L1andASP-LSLis the presence of a long sterile lemma in a later one.

3. (3)

   ASP1encodes a transcriptional co-repressor, homologous toTPLof Arabidopsis andREL2in maize. Multiple phenotypic defects inasp1mutants were occurring, possibly due to the activation of multiple genes involved in meristem function.Aps1showed disorganized phyllotaxy and transition from branch to meristem formation was also compromised. The mutant with the loss of function ofASP1also revealed the bleaching of branches and spikelets. [55] A salient and novel feature ofASP-LSLwith respect toASP1is also the presence of long sterile lemma. Inasp1the sterile lemma length reaches up merely to half of spikelet.

All of above three genes were located at the same gene locus as that ofASP-LSL, but mutant used in the current study contain conserved structure of the mutation site, a different source of germplasm, and the mode of mutagenesis was also different. Current study not only analyzes the biological function of this gene in more detail but also provide new germplasm resources for mutant bank pool. Current research was focused on the functional and phenotypic analysis ofASP-LSL．In the future, more in-depth work on the interaction and molecular regulation ofASP-LSLwould be carried out.

Current study reports the novel phenotype ofasp-lslthat showed a significant decrease in plant height, number of tillers, thousand-grains weight, seed setting rate, spikelet length, kernel length and effective number of grains per panicle as compared to its WT.Asp-lslshowed delayed germination, deceased seed viability and shorter internodal distance than that of WT. Segregation and gene mapping analysis revealed its phenotypes were controlled by a single recessive nuclear. Subcellular localization ofASP-LSLrevealed that its protein is localized in the nucleus. The knockout line ofASP-LSLproduced a similar phenotype as that ofasp-lsl．In the Hybrid seed production, spike germination is a prominent factor that affects the overall yield and milling quality of rice. Molecular breeders can manipulate the genes related to the pathway of long sterile lemma to solve the problem of spike germination with minimal damage to the other major agronomic traits.

Materials

A wild type (WT) japonica variety (Kitaake) was mutagenized by ethyl-methane sulfonate (EMS), and a mutant showing long sterile lemma coupled with other phenotypic defects was selected from M₂population and named asasp-lsl．Its phenotypic traits were found to be inherited stably after multiple generations of selfing. Two indica varieties Yixiang 1B and Kitaake were used as male parents and crossed withasp-lslto construct F₂segregating populations. The materials used in experiment were planted under field conditions alternately at the experimental sites of Rice Research Institute, Sichuan Agricultural University in Lingshui (N18.47°, E110.04°), Hainan and Chongzhou (N30.67°, E103.67°), Sichuan, China. The sampling of material and experimental data was recorded with the permission and regular legislation of Rice Research Institute, Sichuan Agricultural University, China.

Measurement of agronomic traits

At the maturity period of mutant and WT, 10 plants were randomly selected and data of plant height, ear length, grain length, grain width, thousand-grain weight, seed setting rate, inner and outer glume length and number of first branches, etc. were measured. The data were finally represented as an average of 10 individual plants for each of the corresponding trait index.

Histology observations and identification of pollen fertility

Under normal field growth conditions, several primary differentiation stages of panicles were used for histology observation. The different tissue parts of mutant and WT panicles, lemma and glume at panicle elongation, grain filling and fully mature stage were fixed in FAA fixative at 4℃. After rinsing with series of 50 %, 70 %, and 80 % ethanol, and pictures were taken using a scanning electron microscope (FEI QUANTA 450). Fresh spikelets of mutant and WT with their pollens were observed under a microscope using potassium iodide staining.

Dynamic observation of growth and development

To explore the difference between mutant and WT, a seed germination test was carried out in the laboratory. The specific parameters that were followed are given below.

Indoor germination test

One hundred healthy seeds of WT and mutant with their three biological repetitions were germinated at 37℃ in a light incubator. Germination rate was observed after 3 and 7 days, respectively.

Seed vigor examination

In order to verify the accuracy of the germination test results, 100 seeds were selected and cut down longitudinally and finally soaked in a 0.1 % tri-phenyltetrazolium chloride (TTC) solution for 3 h at 35 °C. After dyeing, TTC solution was poured out, and seeds were washed with clean water twice, and the stained number of embryos were counted.

Observation of seedling emergence time in an incubator

Fifty white seeds (stained) of WT and mutant were selected and sown in plastic pots using the soil culture method. Pots were kept under continuous observations, and emergence time from one-leaf to the five-leaves stage was recorded.

Observation of root growth parameters

The WT and mutant plants were grown in a nutrient solution for 7 and 14 days were selected for root parameters observation. At the same time, the change of hypocotyl length was also measured in the absence of light at 32℃ in order to determine the relationship betweenasp-lsland IAA. To explore its relationship with hormone transport and signal response, IAA solution was sprayed on the mutant plants grown for three days on culture. Whereas only distilled water was used as control treatment.

Construction of the genetic map

For hundred fifty-six pairs of SSR markers constructed that were evenly distributed on all chromosomes of rice, were selected as primers, and the DNA of individual F₂populations was used as a template for PCR amplification. Bulk segregant analysis (BSA) was used to construct WT and mutant mixed DNA pools to screen out polymorphic differences through linkage markers. For confirmation of mutant phenotype, DNA of F₂progeny of single plant was used as DNA template. During primary gene mapping, the sequence of polymorphic loci was acquired from the biological database RGP (http://rgp.dna.affrc.go.jp/)and NCBI (https://blast.ncbi.nlm.nih.gov/Blast.cgi)and compared it with the sequence of model indica (9311) and japonica (nipponbare) varieties. SSR markers were designed using public databases e.g., RIS (http://rice.genomics.org.cn/rice/index2.jsp)and RGP (http://rgp.dna.affrc.go.jp/）.To further fine map, indels markers were constructed and applied to the mutant DNA template. Chengdu Kinco Biological Co., Ltd synthesized the primers.

PCR amplification

The specific quantity of ingredients used in PCR amplification was as follows; DNA (2 µl), F-Primer (1 µl), R-Primer (1 µl), dNTP (10mM) mixture (0.3 µl), Taq(5U/µl)0.2 µl, 10×Buffer mg²⁺2 µl and ddH₂O(13.5µl)。特定的PCR扩增过程ure was as follows: 95 °C pre-denaturation for 5 min; 95 °C denaturation for 30 s, 56 °C annealing for 30 s, 72 °C extension for 1 min, 34 cycles; 72 °C extension for 7 min, 4 °C storage for 1 min. The PCR products were separated on 3 % agarose gel electrophoresis and photographed under a Gel Documentation System (Bio-Rad Gel Doc 2000).

Sequence analysis

Primer premier 6.0 and lingo 7.0 software were used primer designing and sequence analysis. As the target geneASP-LSL相对更大的尺寸,我们使用了segmente吗d amplification method and divided the gene into four fragments for easier amplification. PCR product was processed with Tiangen DNA recovery kit that is used for purification and separation. Recovered products were sent to Sichuan Qingke Biological Company (Ltd.) for gene sequencing.

Genetic segregation analysis and knock out line development

The mutation sites were analyzed by dCAPS molecular marker primers, which were designed on(http://helix.wustl.edu/dcaps/dcaps.html）.Twenty plants from F₂segregated population of WT and mutant were taken for DNA extraction, and PCR amplification was performed with a restriction endonuclease. A CRISPR/Cas9 vector targeted at the first exon ofASP-LSLwas developed using BG Biotech Kit (BGK03), purchased from Hongzhou Bioge Biotechnology Co., Ltd and followed the protocol given by the manufacturer (http://www.biogle.cn/index/excrispr）.ASP-LSL19-bp PAM sequence was selected, and the Oligo sequence was generated online using BioGe website (www.bioge.cn）.防止off-targe选择目标站点t effects in the BLAST database (http://www.gramene.org/)特异性。合成低聚糖dissolved in 10 ul of water. The following (buffer aneal 18ul, forward Oligo 1 ul, and reverse Oligo 1 ul) ingredients were mixed on ice and heated in a PCR apparatus at 95 °C for 3 min. The temperature was decreased to 20 °C at the rate of 0.2 °C/s. According to the manufacturer’s instruction, oligo dimer was constructed into CRISPR/Cas9 vector, each component (Oligo primer 1 ul, the CRISPR/Cas Vector 2 ul, enzyme mix 1 ul, 6 ul H₂O) was evenly mixed on the ice and reacted in the PCR apparatus (20℃) for 60 min after mixing.

The recombinant system was transformed intoE. coliaccording to the reference procedure. 10 ul of the reaction solution was added to 100 ul of competent cells, and then the mixture was mixed and placed in an ice bath for 30 min (do not shake during this period and keep standing strictly). The reaction mixture was gently taken out at 42℃ for 90 s, immediately placed on ice for 2 min, added 500 ul preheated LB liquid medium, and cultured at 37℃/200 RPM for 1 h. An appropriate amount of bacterial liquid was coated on the LB plate containing Kanamycin and placed upside down at 37℃ for overnight culture. The constructed vector was sent to Wuhan Boyuan Biotechnology Co., Ltd for genetic transformation.

Quantitative relative expression analysis

The total RNA of mutant and WT roots, stems, leaves, and spikelets at the young panicle and early flowering stage were extracted using the RNA extraction kit. The purified RNA was reversed transcribed into cDNA. The sequence of a specific gene and its other homologous genes were quantified using primers. The template and reference gene (actin) was used in three biological repeats with two NTC (no template control) repeats. Quantitative expression was analyzed by Bio-Rad CFX Manager V2 that is based on^△△CT method.

Bioinformatics analysis

Amino acid sequence homology was compared using NCBI (https://blast.ncbi.nlm.nih.gov/Blast.cgi)tool. Clustal X and MEGA software were used to perform comparison of complete sequence and construction of NJ evolutionary tree.

Subcellular localization

The subcellular localization was predicted online using ChloroP 1.1 and TargetP 1.1 server. The full-length ofASP-LSLcDNA was amplified from its WT using specific primers (F: 5′ATGTCGTCGCTTAGCAGG-3′; R: 5′GACTTCTGGTTTGTTAGCT–3′) with BamHI at 5′-end and a SalI at 3′-end. The target fragments were cloned into pC1300-35 S-eYFP vector at the N-terminus of YELLOW FLUORESCENT PROTEIN (YFP). The constructs were transformed into rice protoplasts and incubated before the examination. YFP fluorescence signals were detected using a Laser Scanning Confocal Microscope (Nikon A1).

The datasets supporting the conclusions of this article are included within the article.

A:

Amyloplast

AP1:

ACITVATOR PROTEIN 1

ASP1:

ABERRANT SPIKELET AND PANICLE 1

asp-lsl:

Aberrant spikelet-long sterile lemma

BG:

Before grouting

CC:

Companion cells

CRC:

CRABSCLAW

CTK:

Cytokinin

DL:

DROOPING LEAF

EC:

Epidermis cell

EMS:

Ethyl-methane sulphonate

FBP:

F-BOX PROTEIN

FM:

Floral meristem

GA:

Gibberellins

GL:

Grain length

GW:

Grain weight

IAA:

Indole acetic acid

LHS1:

LEAFY HULL STERILE 1

LOFSEP:

LOSS OF TRANSCRIPTION FACTOR OF SEP

MFO1:

MOSAIC FLRALORGANS 1

MFS2:

MULTI-FLORET SPIKELET2

MS:

Mature stage

OsLIS-L1:

LISSENCEPHALY TYPE-1-LIKE-1

OsREL2:

ROMOSA ENHANCER LOCI2

OsREL2:

ROMOSA ENHANCER LOCI2

PAP2:

PANlCLE PHYTOMER2

PH:

Plant height

PI:

PSEUDOGENE

PL:

Panicle length

PMD:

Plant maturity days

S:

Stem

SC:

Silicide cell

SEP:

SEPALLATA

SM:

Spikelet meristem

SPW1:

SUPERWOMAN1

SR:

Seed setting rate

STK:

SERINE/THREONINE KINAS

TPL:

TOPLESS

VBS:

Vascular bundle sheath

Ve:

Vessel

WT:

Wild type

YP:

Young panicle

Not Applicable.

We acknowledge grants-in-aid from Department of Science and Technology of Sichuan Province (2021YFYZ0020, 2018JY0144), NSFC (National Natural Science Foundation of China) Grant No. 31771763 and a Breeding Research Project (21ZDYF2186). The funding bodies played no role in the design of the study and collection, analysis, and interpretation of data and in writing the manuscript.

Author notes

1. Tingkai Wu, Asif Ali and Jinhao Wang contributed equally to this work.

Affiliations

1. State Key Laboratory of Crop Gene Exploration and Utilization in Southwest China, Rice Research Institute, Sichuan Agricultural University, 611130, Chengdu, China

   Tingkai Wu, Asif Ali, Jinhao Wang, Jiahe Song, Yongqiong Fang, Tingting Zhou, Yi Luo, Hongyu Zhang, Xiaoqiong Chen, Yongxiang Liao, Yutong Liu, Peizhou Xu & Xianjun Wu

Contributions

JW, TW, XP designed the study. AA, and XW wrote of manuscript. TW, JS, YF, TZ and YL1 performed experiments and analyses. HZ, AA, YX, YL2, CS, and JW planted materials and carried out analysis for proteomes. AA and XW revised the manuscript content. All authors read and approved the final manuscript.

Corresponding authors

Correspondence to Peizhou Xu orXianjun Wu．

Ethics approval and consent to participate

Not Applicable.

Consent for publication

Not Applicable.

Competing interests

The authors declare that they have no competing interests.

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