Small RNA in rice genome

Rice has many characteristics of a model plant. The recent completion of the draft of the rice genome represents an important advance in our knowledge of plant biology and also has an important contribution to the understanding of general genomic evolution. Besides the rice genome finishing map, the next urgent step for rice researchers is to annotate the genes and noncoding functional sequences. The recent work shows that noncoding RNAs (ncRNAs) play significant roles in biological systems. We have explored all the known small RNAs (a kind of ncRNA) within rice genome and other six species sequences, including Arabidopsis, maize, yeast, worm, mouse and pig. As a result we find 160 out of 552 small RNAs (sRNAs) in database have homologs in 108 rice scaffolds, and almost all of them (99.41%) locate in intron regions of rice by gene predication. 19 sRNAs only appear in rice. More importantly, we find two special LJ14 sRNAs: one is located in a set of sRNA ZMU14SNR9(s) which only appears in three plants, 86% sequences of them can be compared as the same sequence in rice, Arabidopsis and maize; the other conserved sRNA XLHS7CU14 has a segment which appears in almost all these species from plants to animals. All these results indicate that sRNA do not have evident borderline between plants and animals.     

Small RNA in rice genome

Rice has many characteristics of a model plant. The recent completion of the draft of the rice genome represents an important advance in our knowledge of plant biology and also has an important contribution to the understanding of general genomic evolution. Besides the rice genome finishing map, the next urgent step for rice researchers is to annotate the genes and non-coding functional sequences. The recent work shows that noncoding RNAs (ncRNAs) play significant roles in biological systems. We have explored all the known small RNAs (a kind of ncRNA) within rice genome and other six species sequences, including Arabidopsis, maize, yeast, worm, mouse and pig. As a result we find 160 out of 552 small RNAs (sRNAs) in database have ho-mologs in 108 rice scaffolds, and almost all of them (99.41 %) locate in intron regions of rice by gene predication. 19 sRNAs only appear in rice. More importantly, we find two special U14 sRNAs: one is located in a set of sRNA ZMU14SNR9(s) which only appears in three plants,     

Ancestral genome duplication in rice.

The recent availability of the pseudochromosome sequences of rice allows for the first time the investigation of the extent of intra-genomic duplications on a large scale in this agronomically important species. Using a dot-matrix plotter as a tool to display pairwise comparisons of ordered predicted coding sequences along rice pseudochromosomes, we found that the rice genome contains extensive chromosomal duplications accounting for 53% of the available sequences. The size of duplicated blocks is considerably larger than previously reported. In the rice genome, a duplicated block size of >1 Mb appears to be the rule and not the exception. Comparative mapping has shown high genetic colinearity among chromosomes of cereals, promoting rice as a model for studying grass genomes. Further comparative genome analysis should allow the study of the conservation and evolution of these duplication events in other important cereals such as rye, barley, and wheat.     

The institute for genomic research Osa1 rice genome annotation database

We have developed a rice (Oryza sativa) genome annotation database (Osa1) that provides structural and functional annotation for this emerging model species. Using the sequence of O. sativa subsp. japonica cv Nipponbare from the International Rice Genome Sequencing Project, pseudomolecules, or virtual contigs, of the 12 rice chromosomes were constructed. Our most recent release, version 3, represents our third build of the pseudomolecules and is composed of 98% finished sequence. Genes were identified using a series of computational methods developed for Arabidopsis (Arabidopsis thaliana) that were modified for use with the rice genome. In release 3 of our annotation, we identified 57,915 genes, of which 14,196 are related to transposable elements. Of these 43,719 non-transposable element-related genes, 18,545 (42.4%) were annotated with a putative function, 5,777 (13.2%) were annotated as encoding an expressed protein with no known function, and the remaining 19,397 (44.4%) were annotated as encoding a hypothetical protein. Multiple splice forms (5,873) were detected for 2,538 genes, resulting in a total of 61,250 gene models in the rice genome. We incorporated experimental evidence into 18,252 gene models to improve the quality of the structural annotation. A series of functional data types has been annotated for the rice genome that includes alignment with genetic markers, assignment of gene ontologies, identification of flanking sequence tags, alignment with homologs from related species, and syntenic mapping with other cereal species. All structural and functional annotation data are available through interactive search and display windows as well as through download of flat files. To integrate the data with other genome projects, the annotation data are available through a Distributed Annotation System and a Genome Browser. All data can be obtained through the project Web pages at http://rice.tigr.org.     

Gene identification using rice genome sequences

Identifying useful gene(s) is one of the most important objectives of plant geneticists. Various strategies can be used, which are based on the characteristics of plant reproduction and available technology. Rice is the first model crop whose whole genome sequence has been reported. In addition, information on the whole genome sequences of two important rice subspecies (japonica and indica rice) is also available. Rice is a self-pollinating crop and methods of artificial crossing are relatively easy to perform; such methods enable the production of numerous seeds for genetic analyses. Based on these features, a map-based cloning (i.e., positional cloning) strategy has been successfully applied over the last decade to identify rice genes. Recently, advanced next-generation sequencing (NGS) technology was used to ascertain the genome sequences of individual plants, opening up a new strategy for gene identification. This strategy has been used successfully to identify the genes responsible for certain qualitative traits in rice. However, to identify the gene(s) involved in a quantitative trait, a map-based cloning strategy is still required after quantitative trait loci analysis using NGS technology. In this review, we discuss both map-based cloning (which is still the primary strategy used to identify rice genes) and NGS-based strategies.     

Deciphering variation of 239 elite japonica rice genomes for whole genome sequences-enabled breeding

Revealing genomic variation of representative and diverse germplasm is the cornerstone of deploying genomics information into genetic improvement programs of species of agricultural importance. Here we report the re-sequencing of 239 japonica rice elites representing the genetic diversity of japonica germplasm in China, Japan and Korea. A total of 4.8 million SNPs and PAV of 35,634 genes were identified. The elites from Japan and Korea are closely related and relatively less diverse than those from China. A japonica rice pan-genome was constructed, and 35 Mb non-redundant novel sequences were identified, from which 1131 novel genes were predicted. Strong selection signals of genomic regions were detected on most of the chromosomes. The heading date genes Hd1 and Hd3a have been artificially selected during the breeding process. The results from this study lay the foundation for future whole genome sequences-enabled breeding in rice and provide a paradigm for other species.     

Rapid generation of genetic diversity by multiplex CRISPR/Cas9 genome editing in rice

The clustered regularly interspaced short palindromic repeats(CRISPR)-associated endonuclease 9(CRISPR/Cas9) system has emerged as a promising technology for specific genome editing in many species. Here we constructed one vector targeting eight agronomic genes in rice using the CRISPR/Cas9 multiplex genome editing system. By subsequent genetic transformation and DNA sequencing, we found that the eight target genes have high mutation efficiencies in the T_0 generation. Both heterozygous and homozygous mutations of all editing genes were obtained in T_0 plants. In addition, homozygous sextuple, septuple, and octuple mutants were identified. As the abundant genotypes in T_0 transgenic plants, various phenotypes related to the editing genes were observed. The findings demonstrate the potential of the CRISPR/Cas9 system for rapid introduction of genetic diversity during crop breeding.     

International Rice Genome Sequencing Project: the effort to completely sequence the rice genome

The International Rice Genome Sequencing Project (IRGSP) involves researchers from ten countries who are working to completely and accurately sequence the rice genome within a short period. Sequencing uses a map-based clone-by-clone shotgun strategy; shared bacterial artificial chromosome/P1-derived artificial chromosome libraries have been constructed from Oryza sativa ssp. japonica variety 'Nipponbare'. End-sequencing, fingerprinting and marker-aided PCR screening are being used to make sequence-ready contigs. Annotated sequences are immediately released for public use and are made available with supplemental information at each IRGSP member's website. The IRGSP works to promote the development of rice and cereal genomics in addition to producing genome sequence data.     

Towards an accurate sequence of the rice genome

Several more- or less-elaborated rice genome sequences have been produced recently using different strategies. It has become possible to compare them and to unravel the major features of the rice genome in terms of nucleotide composition, repeats, gene content and variability. It has also become possible to compare the rice and Arabidopsis genomes and to evaluate rice as a model genome.     

Insights into cereal genomes from two draft genome sequences of rice

Draft genome sequences have been reported for two subspecies of rice. The drafts include the sequences of an estimated 99% of all rice genes and provide major advances in our understanding of the content and complexity of cereal genomes in general and the rice genome in particular.     

Genetic innovations: Transposable element recruitment and de novo formation lead to the birth of orphan genes in the rice genome

Orphan genes are genetic innovations that lack homologs in other lineages. Orphan genes can rapidly originate and become substantially functional, yet the mechanisms underlying their origins are still largely unknown in plants. Here, we investigated the origin of orphan genes in the Oryza sativa ssp. japonica “Nipponbare” genome using genome‐wide comparisons with 10 closely related Oryza species. We identified a total of 37 orphan genes in the Nipponbare genome that show short sequence lengths, elevated GC content, and absence of introns. Interestingly, half of the identified orphan genes originated by way of a distinctive mechanism that involved the generation of new coding sequences through independent and rapid divergence within the inserted transposable element. Our results provide valuable insight into genetic innovations in the model rice genome that formed on a very short timescale.     

Evidence of multiple complex patterns of T-DNA integration into the rice genome

The transfer of the long T-DNA (T-DNA and non-T-DNA) of a binary plasmid from Agrobacterium into the rice genome was investigated at both molecular and genetic levels. Out of 226 independent transgenic plants, 33% of the transformants contained non-T-DNA sequences. There was no major difference in the frequency of non-T-DNA transfer among three Agrobacterium tumefaciens strains.Four T1 plants containing a single putative long T-DNA insertion were selected for Southern analysis. Three of them were confirmed to have a long T-DNA insertion with a size of greater-than-unit-length of the binary plasmid. This was further confirmed by rescuing the intact binary plasmid from these plants. Our results suggest that long T-DNA transfer by rolling-circle replication from Agrobacterium to rice occurs frequently, and that the high frequency of non-T-DNA transfer should be considered when producing transgenic rice for commercial production. Received: 22 April 1999 / Accepted: 22 June 1999     

Development of a new transformation-competent artificial chromosome (TAC) vector and construction of tomato and rice TAC libraries

Recent research has shown that BIBAC (binary bacterial artificial chromosome) and TAC (transformation-competent artificial chromosome) vector systems are very useful tools for map-based cloning of agronomically important genes in plant species. We have developed a new TAC vector that is suitable for both dicot and monocot transformation. Using this new TAC vector, we constructed large-insert genomic libraries of tomato and rice. The tomato library contains 96,996 clones (28.3-38.5 kb insert size) and has 3.18 haploid genome equivalents. The rice TAC library has 32.7 kb average insert size and has 9.24 haploid genome equivalents. The quality of these two libraries was tested using PCR to verify genome coverage. Individual clones were characterized to confirm insert integrity by Southern analysis, end sequencing and genetic mapping. To investigate the potential application of these TAC libraries in map-based cloning, TAC constructs containing a 45 kb fragment were introduced into the rice genome via Agrobacterium-mediated transformation. Molecular analysis indicates that the 45 kb fragment was successfully transferred into the rice genome. Although rearrangements of the introduced DNA were detected, 50% of regenerated plants contained at least one intact copy of the 45 kb clone and associated vector sequences. These libraries provide us with a valuable resource to rapidly isolate important genes in tomato and rice.     

Identification of microsatellite markers for fragrance in rice by analysis of the rice genome sequence

Several chemical constituents are important to the fragrance of cooked rice. However, the chemical compound 2-acetyl-1-pyrroline (AP) is regarded as the most important component of fragrance in the basmati- and jasmine-style fragrant rices. AP is found in all parts of the plant except the roots. It is believed that a single recessive gene is responsible for the production of fragrance in most rice plants. The detection of fragrance can be carried out via sensory or chemical methods, although each has their disadvantages. To overcome these difficulties, we have identified an (AT)₄₀ repeat microsatellite or simple sequence repeat (SSR) marker for fragrant and non-fragrant alleles of the fgr gene. Identification of this marker was facilitated through use of both the publicly available and restricted access sequence information of the Monsanto rice sequence databases. Fifty F₂ individuals from a mapping population were genotyped for the polymorphic marker. This marker has a high polymorphism information content (PIC = 0.9). Other SSR markers linked to fragrance could be identified in the same way of use in other populations. This study demonstrates that analysis of the rice genome sequence is an effective option for identification of markers for use in rice improvement.     

Rice genome organization: the centromere and genome interactions

Over the last decade, many varied resources have become available for genome studies in rice. These resources include over 4000 DNA markers, several bacterial artificial chromosome (BAC) libraries, P-1 derived artificial chromosome (PAC) libraries and yeast artificial chromosome (YAC) libraries (genomic DNA clones, filters and end-sequences), retrotransposon tagged lines, and many chemical and irradiated mutant lines. Based on these, high-density genetic maps, cereal comparative maps, YAC and BAC physical maps, and quantitative trait loci (QTL) maps have been constructed, and 93 % of the genome has also been sequenced. These data have revealed key features of the genetic and physical structure of the rice genome and of the evolution of cereal chromosomes. This Botanical Briefing examines aspects of how the rice genome is organized structurally, functionally and evolutionarily. Emphasis is placed on the rice centromere, which is composed of long arrays of centromere-specific repetitive sequences. Differences and similarities amongst various cereal centromeres are detailed. These indicate essential features of centromere function. Another view of various kinds of interactive relationships within and between genomes, which could play crucial roles in genome organization and evolution, is also introduced. Constructed genetic and physical maps indicate duplication of chromosomal segments and spatial association between specific chromosome regions. A genome-wide survey of interactive genetic loci has identified various reproductive barriers that may drive speciation of the rice genome. The significance of these findings in genome organization and evolution is discussed.