Double Mutation of Days to Heading 2 and CONSTANS 3 Improves Agronomic Performance of Japonica Rice under Short Daylight Conditions in Southern China.

Some progress has been made in understanding the pathways related to rice heading, but their applications to breeding japonica rice varieties adapted to grow in low-latitude areas ("indica to japonica") are limited. We edited eight adaptation-related genes via a lab-established CRISPR/Cas9 system in a japonica variety, Shennong265 (SN265). All T0 plants and their progeny bearing random mutation permutations were planted in southern China and screened for changes in heading date. We found that the double mutant of Days to heading 2 (DTH2) and CONSTANS 3 (OsCO3) (dth2-osco3), two CONSTANS-like (COL) genes, showed significantly delayed heading under both short-day (SD) and long-day (LD) conditions in Guangzhou and manifested great yield increase under SD conditions. We further demonstrated that the heading-related Hd3a-OsMADS14 pathway was down-regulated in the dth2-osco3 mutant lines. The editing of the COL genes DTH2 and OsCO3 greatly improves the agronomic performance of japonica rice in Southern China.

The ties of brotherhood between japonica and indica rice for regional adaptation.

Selection of beneficial genomic variants was crucial for regional adaptation of crops during domestication, but the underlying genomic basis remains largely unexplored. Here we report a genome-wide selective-sweep analysis of 655 japonica and 1,205 indica accessions selected from 2,673 landraces through principal component analysis to identify 5,636 non-synonymous single nucleotide polymorphisms (SNPs) fixed in at least one subspecies. We classified these SNPs into three groups, jiS (japonica- and indica-selected), jS (japonica-selected only), and iS (indica-selected only), and documented evidence for selection acting on these groups, their relation to yield-related traits, such as heading date, and their practical value in cropping area prediction. We also demonstrated the role of a jiS-SNP-containing gene in temperature adaptability. Our study informs genes underpinning adaptation that may shape Green Super Rice and proposes a time-saving, cost-reducing selection strategy of genomic breeding, sweep-SNP-guided selection, for developing regionally-adapted heterosis.

Development of "Purple Endosperm Rice" by Engineering Anthocyanin Biosynthesis in the Endosperm with a High-Efficiency Transgene Stacking System.

Anthocyanins have high antioxidant activities, and engineering of anthocyanin biosynthesis in staple crops, such as rice (Oryza sativa L.), could provide health-promoting foods for improving human health. However, engineering metabolic pathways for biofortification remains difficult, and previous attempts to engineer anthocyanin production in rice endosperm failed because of the sophisticated genetic regulatory network of its biosynthetic pathway. In this study, we developed a high-efficiency vector system for transgene stacking and used it to engineer anthocyanin biosynthesis in rice endosperm. We made a construct containing eight anthocyanin-related genes (two regulatory genes from maize and six structural genes from Coleus) driven by the endosperm-specific promoters,plus a selectable marker and a gene for marker excision. Transformation of rice with this construct generated a novel biofortified germplasm "Purple Endosperm Rice" (called "Zijingmi" in Chinese), which has high anthocyanin contents and antioxidant activity in the endosperm. This anthocyanin production results from expression of the transgenes and the resulting activation (or enhancement) of expression of 13 endogenous anthocyanin biosynthesis genes that are silenced or expressed at low levels in wild-type rice endosperm. This study provides an efficient, versatile toolkit for transgene stacking and demonstrates its use for successful engineering of a sophisticated biological pathway, suggesting the potential utility of this toolkit for synthetic biology and improvement of agronomic traits in plants.

Comparative Transcriptomic Analysis of Vernalization- and Cytokinin-Induced Floral Transition in Dendrobium nobile.

Vernalization is required for floral initiation in Dendrobium. Interestingly, those beneficial effects can also be achieved by exogenous cytokinin application in greenhouses. Thus, an as yet unknown crosstalk/interaction may exist between vernalization and cytokinin signaling pathways. In this study, we showed, by de novo transcriptome assembly using RNA-seq data from both vegetative and reproductive tissue samples, that some floral transition-related genes-DnVRN1, FT, SOC1, LFY and AP1-were differentially expressed in low-temperature-challenged (LT) or thidiazuron (TDZ)-treated plants, compared to those mock-treated (CK). Both LT and TDZ upregulated SOC1, LFY and AP1, while the upregulation of DnVRN1 and FT was only LT-induced. We further found that LT promoted the upregulation of some key cytokinin signaling regulators, including several cytokinin biosynthesis-related genes and type-B response regulator (RR)-encoding genes, and that both LT and TDZ triggered the significant upregulation of some marker genes in the gibberellin (GA) signaling pathway, indicating an important low temperature-cytokinin-GA axis in flowering. Our data thus have revealed a cytokinin-GA signal network underlying vernalization, providing a novel insight into further investigation of the molecular mechanism of floral initiation in Dendrobium.

BRHIS1 suppresses rice innate immunity through binding to monoubiquitinated H2A and H2B variants.

In the absence of pathogen attack, organisms usually suppress immune responses to reduce the negative effects of disease resistance. Monoubiquitination of histone variants at specific gene loci is crucial for gene expression, but its involvement in the regulation of plant immunity remains unclear. Here, we show that a rice SWI/SNF2 ATPase gene BRHIS1 is downregulated in response to the rice blast fungal pathogen or to the defense-priming-inducing compound BIT (1,2-benzisothiazol-3(2h)-one,1, 1-dioxide). The BRHIS1-containing complex represses the expression of some disease defense-related genes, including the pathogenesis-related gene OsPBZc and the leucine-rich-repeat (LRR) receptor-like protein kinase gene OsSIRK1. This is achieved through BRHIS1 recruitment to the promoter regions of target genes through specific interaction with monoubiquitinated histone variants H2B.7 and H2A.Xa/H2A.Xb/H2A.3, in the absence of pathogen attack or BIT treatment. Our results show that rice disease defense genes are initially organized in an expression-ready state by specific monoubiquitination of H2A and H2B variants deposited on their promoter regions, but are kept suppressed by the BRHIS1 complex, facilitating the prompt initiation of innate immune responses in response to infection through the stringent regulation of BRHIS1.

A Robust CRISPR/Cas9 System for Convenient, High-Efficiency Multiplex Genome Editing in Monocot and Dicot Plants.

CRISPR/Cas9 genome targeting systems have been applied to a variety of species. However, most CRISPR/Cas9 systems reported for plants can only modify one or a few target sites. Here, we report a robust CRISPR/Cas9 vector system, utilizing a plant codon optimized Cas9 gene, for convenient and high-efficiency multiplex genome editing in monocot and dicot plants. We designed PCR-based procedures to rapidly generate multiple sgRNA expression cassettes, which can be assembled into the binary CRISPR/Cas9 vectors in one round of cloning by Golden Gate ligation or Gibson Assembly. With this system, we edited 46 target sites in rice with an average 85.4% rate of mutation, mostly in biallelic and homozygous status. We reasoned that about 16% of the homozygous mutations in rice were generated through the non-homologous end-joining mechanism followed by homologous recombination-based repair. We also obtained uniform biallelic, heterozygous, homozygous, and chimeric mutations in Arabidopsis T1 plants. The targeted mutations in both rice and Arabidopsis were heritable. We provide examples of loss-of-function gene mutations in T0 rice and T1 Arabidopsis plants by simultaneous targeting of multiple (up to eight) members of a gene family, multiple genes in a biosynthetic pathway, or multiple sites in a single gene. This system has provided a versatile toolbox for studying functions of multiple genes and gene families in plants for basic research and genetic improvement.

Robust multi-type plasmid modifications based on isothermal in vitro recombination.

A robust strategy for multi-type plasmid modifications is developed based on the isothermal in vitro recombination technology, by which any combination of the sequence modifications can be efficiently achieved in plasmids at any desired position in a seamless manner. As an example, we showed that a plasmid modification with insertion of a GFP gene, deletion of a 623-bp fragment, and substitution of an ampicillin resistance gene by a kanamycin resistance gene was accomplished simultaneously by this method. Therefore, the isothermal in vitro recombination-based multi-type plasmid modification strategy is a useful approach for broad application prospects in molecular biology studies.

One-step cloning of intron-containing hairpin RNA constructs for RNA interference via isothermal in vitro recombination system.

Hairpin RNA-based RNA interference (hpRNAi) has become a powerful tool for exploring gene function in reverse genetics. Although, several methods are available for making constructs that express hpRNAi, multiple time-consuming cloning steps are usually involved. Here, we introduce an efficient and flexible hpRNAi vector construction method via the isothermal in vitro recombination system (IR-hpRNAi). For an IR-hpRNAi reaction, two PCR products of a target gene sequence are generated, which containS complementary ends (~20 bp) to each other and to the ends of linearized vector, are fused in a way of head-to-head or tail-to-tail into the vector. This IR-hpRNAi method offers two options to construct the RNAi vectors. Using this method, we created a IR-hpRNAi construct for the Arabidopsis PDS3 gene,and verified the silencing effect via Agrobacterium-mediated transformation. The IR-hpRNAi system rules out the requirement of engineering restriction enzyme cutting sites in target DNA fragments, and is ligation-independent. Thus, this method has advantages over the other hpRNAi construction methods.

A detrimental mitochondrial-nuclear interaction causes cytoplasmic male sterility in rice.

Plant cytoplasmic male sterility (CMS) results from incompatibilities between the organellar and nuclear genomes and prevents self pollination, enabling hybrid crop breeding to increase yields. The Wild Abortive CMS (CMS-WA) has been exploited in the majority of 'three-line' hybrid rice production since the 1970s, but the molecular basis of this trait remains unknown. Here we report that a new mitochondrial gene, WA352, which originated recently in wild rice, confers CMS-WA because the protein it encodes interacts with the nuclear-encoded mitochondrial protein COX11. In CMS-WA lines, WA352 accumulates preferentially in the anther tapetum, thereby inhibiting COX11 function in peroxide metabolism and triggering premature tapetal programmed cell death and consequent pollen abortion. WA352-induced sterility can be suppressed by two restorer-of-fertility (Rf) genes, suggesting the existence of different mechanisms to counteract deleterious cytoplasmic factors. Thus, CMS-related cytoplasmic-nuclear incompatibility is driven by a detrimental interaction between a newly evolved mitochondrial gene and a conserved, essential nuclear gene.

Hybrid male sterility in rice controlled by interaction between divergent alleles of two adjacent genes.

Sterility is common in hybrids between divergent populations, such as the indica and japonica subspecies of Asian cultivated rice (Oryza sativa). Although multiple loci for plant hybrid sterility have been identified, it remains unknown how alleles of the loci interact at the molecular level. Here we show that a locus for indica-japonica hybrid male sterility, Sa, comprises two adjacent genes, SaM and SaF, encoding a small ubiquitin-like modifier E3 ligase-like protein and an F-box protein, respectively. Most indica cultivars contain a haplotype SaM(+)SaF(+), whereas all japonica cultivars have SaM(-)SaF(-) that diverged by nucleotide variations in wild rice. Male semi-sterility in this heterozygous complex locus is caused by abortion of pollen carrying SaM(-). This allele-specific gamete elimination results from a selective interaction of SaF(+) with SaM(-), a truncated protein, but not with SaM(+) because of the presence of an inhibitory domain, although SaM(+) is required for this male sterility. Lack of any one of the three alleles in recombinant plants does not produce male sterility. We propose a two-gene/three-component interaction model for this hybrid male sterility system. The findings have implications for overcoming male sterility in inter-subspecific hybrid rice breeding.

Cytoplasmic male sterility of rice with boro II cytoplasm is caused by a cytotoxic peptide and is restored by two related PPR motif genes via distinct modes of mRNA silencing.

Cytoplasmic male sterility (CMS) and nucleus-controlled fertility restoration are widespread plant reproductive features that provide useful tools to exploit heterosis in crops. However, the molecular mechanism underlying this kind of cytoplasmic-nuclear interaction remains unclear. Here, we show in rice (Oryza sativa) with Boro II cytoplasm that an abnormal mitochondrial open reading frame, orf79, is cotranscribed with a duplicated atp6 (B-atp6) gene and encodes a cytotoxic peptide. Expression of orf79 in CMS lines and transgenic rice plants caused gametophytic male sterility. Immunoblot analysis showed that the ORF79 protein accumulates specifically in microspores. Two fertility restorer genes, Rf1a and Rf1b, were identified at the classical locus Rf-1 as members of a multigene cluster that encode pentatricopeptide repeat proteins. RF1A and RF1B are both targeted to mitochondria and can restore male fertility by blocking ORF79 production via endonucleolytic cleavage (RF1A) or degradation (RF1B) of dicistronic B-atp6/orf79 mRNA. In the presence of both restorers, RF1A was epistatic over RF1B in the mRNA processing. We have also shown that RF1A plays an additional role in promoting the editing of atp6 mRNAs, independent of its cleavage function.

Amplification of genomic sequences flanking T-DNA insertions by thermal asymmetric interlaced polymerase chain reaction.

Thermal asymmetric interlaced polymerase chain reaction (TAIL-PCR) is an efficient tool for the recovery of DNA fragments adjacent to known sequences. A protocol is presented for the amplification of genomic sequences flanking DNA (T-DNA or transposon) insertions using the TAIL-PCR method. The amplified products are suitable as templates for direct sequencing, or for cloning in vectors. Examples are given in use of the protocol for T-DNA tagging in rice using the pCAMBIA binary vectors.

[Construction, characterization and screening of a transformation-competent artificial chromosome (TAC) library of wheat-Thinopyrum intermedium translocation line with resistance to barley yellow dwarf virus].

A transformation-competent artificial chromosome (TAC) library was constructed from the genomic DNA of wheat-Th. intermidium translocation line HW642 that harbor the barley yellow dwarf virus (BYDV) resistance gene derived from Th. intermidium. The library consists of 2.3 x 10(6) clones with an average insert size of 22kb, representing approximately 2.5 haploid genome equivalents and is able to give a greater than 95.77% probability of isolating single-copy DNA sequences from this library. The library was stored as frozen cultures in 24 96-well formats, each well containing approximately 1000 different clones. TAC clones containing interest gene could be identified by the pooled PCR technique. A sequence characterized amplified region (SCAR) marker cosegregated with BYDV resistance gene, derived from a simple sequence repeat (SSR) or microsatellite marker wms37 of wheat, was applied to screen the TAC library. Twelve clones were successfully selected by the pooled PCR method. PCR products were identified by hybridizing with the SCAR marker band of Th. intermidium. Out of 12 clones, 10 positive clones restricted by Hind III were shown to hybridize with genomic DNA of Th. intermidium. These results showed evidences that the 10 clones could be used as candidate clones for isolation of BYDV resistance and its related genes, and the TAC library is a useful resource for isolating genes.

Development of new transformation-competent artificial chromosome vectors and rice genomic libraries for efficient gene cloning.

The transformation-competent artificial chromosome vector (TAC) system has been shown to be very useful for efficient gene isolation in Arabidopsis thaliana (Proc. Natl. Acad. Sci. USA 96 (1998) 6535). To adapt the vector system for gene isolation in crops, two new TAC vectors and rice genomic libraries were developed. The new vectors pYLTAC17 and pYLTAC27 use the Bar gene and Hpt gene driven by the rice Act1 promoter as the plant selectable markers, respectively, and are suitable for transformation of rice and other grasses. Two representative genomic libraries (I and II) of an Indica rice variety Minghui63, a fertility restorer line for hybrid rice, were constructed with pYLTAC17 using different size classes of partially digested DNA fragments. Library I and library II consisted of 34,560 and 1.2 x 10(5) clones, with average insert sizes of approximately 77 and 39 kb, respectively. The genome coverage of the libraries I and II was estimated to be about 5 and 11 haploid genome equivalents, respectively. Clones of the library I were stored individually in ninety 384-well plates, and those of the library II were collected as bulked pools each containing 30-50 clones and stored in eight 384-well plates. A number of probes were used to hybridize high-density colony filters of the library I prepared by an improved replicating method and each detected 2-9 positive clones. A method for rapid screening of the library II by pooled colony hybridization was developed. A TAC clone having an 80 kb rice DNA insert was successfully transferred into rice genome via Agrobacterium-mediated transformation. The new vectors and the genomic libraries should be useful for gene cloning and genetic engineering in rice and other crops.

[Molecular mapping of the fertility restorer gene Rf-4 for WA cytoplasmic male sterility in rice].

The cytoplasmic male sterility for wild-abortive (CMS-WA) has been wildly used for hybrid rice breeding in China. The fertility restoration of CMS-WA is controlled mainly by two independent and dominant nuclear fertility restoring genes, Rf-3 and Rf-4. To map the Rf-4 gene with molecular markers, rice YAC clones of RGP, Japan were used to create new molecular marker. YAC contigs located between RFLP markers R1877 and G2155 on chromosome 10 were confirmed by hybridization with 12 RFLP probes. Six YAC clones, Y4630, Y2670, Y4892, Y2111, Y3821 and Y5528 were identified. Chromosome DNAs of the YAC clones were prepared and separated by CHEF. A total of 119 probes were created by sub-cloning of the YAC DNAs. RFLPs were screened between Zhenshan 97A and its near-isogenic lines with Rf-4Rf-4 genotype. Two probes, Y3-8 from Y4892 and Y1-10 from Y4630, were found to be polymorphic. Using F2 populations from crosses between Zhenshan 97A and its near-isogenic lines ZSR11, Y3-8 and Y1-10 were mapped to Rf-4 locus with genetic distances of 0.9 cM and 3.2 cM, respectively.