Integration Of Transferred DNA Research Articles

DNA methylation and histone modification patterns around Agrobacterium T-DNA integrations in woodland strawberry Fragaria vesca

Agrobacterium transformation is widely used for plant genome manipulation, which is completed by integration of transfer DNA (T-DNA) into the plant genome. Application of new biotechnology such as genome editing in many horticultural crops is mediated by Agrobacterium transformation. Currently, our knowledge on the chromatin environment around the T-DNA integration sites is limited. In this study, we mapped the genomic locations of T-DNA integrations in woodland strawberry (Fragaria vesca) to the telomere-to-telomere genome, and found that T-DNA integrations recovered under antibiotic selections were biased towards TE-poor euchromatic sequences. We further performed bisulfite sequencing and chromatin immunoprecipitation to analyze DNA methylation and histone modifications of the integration sites. T-DNA integration sites had low levels of DNA methylation, as well as low levels of 24-nt small RNAs which were associated with RNA-dependent DNA methylation. In addition, the sequences flanking T-DNA integration sites had low levels of a silent mark histone 3 lysine 27 trimethylation, and high levels of an active mark histone 3 lysine 9/lysine 14 acetylation. Such structure indicates an open chromatin environment favored by T-DNA integration and/or antibiotic selection in strawberries. This study provides clues for increasing the transformation efficiency for molecular breeding in Rosaceae species in the future.

Characterization of integration sites and transfer DNA structures in Agrobacterium-mediated transgenic events of maize inbred B104.

In maize, the community-standard transformant line B104 is a useful model for dissecting features of transfer DNA (T-DNA) integration due to its compatibility with Agrobacterium-mediated transformation and the availability of its genome sequence. Knowledge of transgene integration sites permits the analysis of the genomic environment that governs the strength of gene expression and phenotypic effects due to the disruption of an endogenous gene or regulatory element. In this study, we optimized a fusion primer and nested integrated PCR (FPNI-PCR) technique for T-DNA detection in maize to characterize the integration sites of 89 T-DNA insertions in 81 transformant lines. T-DNA insertions preferentially occurred in gene-rich regions and regions distant from centromeres. Integration junctions with and without microhomologous sequences as well as junctions with de novo sequences were detected. Sequence analysis of integration junctions indicated that T-DNA was incorporated via the error-prone repair pathways of nonhomologous (predominantly) and microhomology-mediated (minor) end-joining. This report provides a quantitative assessment of Agrobacterium-mediated T-DNA integration in maize with respect to insertion site features, the genomic distribution of T-DNA incorporation, and the mechanisms of integration. It also demonstrates the utility of the FPNI-PCR technique, which can be adapted to any species of interest.

The translocated virulence protein VirD5 causes DNA damage and mutation during Agrobacterium-mediated transformation of yeast.

The soil bacterium Agrobacterium tumefaciens is a preferred gene vector not only for plants but also for fungi. Agrobacterium delivers a small set of virulence proteins into host cells concomitantly with transferred DNA (T-DNA) to support the transformation process. Here, we find that expression of one of these proteins, called VirD5, in yeast host cells causes replication stress and DNA damage. This can result in both genomic rearrangements and local mutations, especially small deletions. Delivery of VirD5 during cocultivation with Agrobacterium led to mutations in the yeast genome that were unlinked to the integration of T-DNA. This load of mutations can be prevented by using a virD5 mutant for genome engineering, but this leads to a lower transformation frequency.

T-DNA integration and its effect on gene expression in dual Bt gene transgenic Populus ×euramericana cv. Neva

The integration of Bacillus thuringiensis (Bt) genes is often accompanied by unintended effects along with the improved resistance to targeted pests. The insertion information of transfer DNA (T-DNA) and the expression information of upstream and downstream genes are of great significance for related research on unexpected effects and molecular-level mechanisms. In this study, six dual Bt transgenic Populus × euramericana cv. Neva (poplar 107) lines were used as research objects. We determined growth and physiological indices, and characterized the T-DNA integration using next-generation sequencing technology. The transgenic and non-transgenic lines showed no significant difference in growth index. However, while insect resistance was enhanced, effects related to the integration sites of the Bt gene occurred. A total of 15 insertion sites were detected among the six transgenic lines, and T-DNA preferentially inserted into AT-rich regions of the poplar genome. RNA sequencing and weighted gene co-expression network analysis were used to explore the effects of T-DNA insertion on the gene expression of poplar 107. As a result, the metabolic pathways most affected by the Bt gene were starch and sucrose metabolism and pentose and gluconate conversion. The expression of exogenous Bt had a greater impact than the insertion position or copy number on poplar 107 gene expression, and the Cry1Ac toxin protein also played a major role. This study provides theoretical support for the cultivation and management of poplar 107 new varieties, and provides reference for Poplar insect resistance breeding and its molecular response to Bt gene.

Modulation of plant DNA damage response gene expression during Agrobacterium infection

Agrobacterium T-DNA (transfer DNA) integration into the plant genome relies mostly on host proteins involved in the DNA damage repair pathways. However, conflicting results have been obtained using plants with mutated or down-regulated genes involved in these pathways. Here, we chose a different approach by following the expression of a series of genes, encoding proteins involved in the DNA damage response, during early stages of Agrobacterium infection in tobacco. First, we identified tobacco homologs of Arabidopsis genes induced upon DNA damage and demonstrated that their expression was activated by bleomycin, a DNA-break causing agent. Then, we showed that Agrobacterium infection induces the expression of several of these genes markers of the host DNA damage response, with different patterns of transcriptional response. This induction largely depends on Agrobacterium virulence factors, but not on the T-DNA, suggesting that the DNA damage response activation may rely on Agrobacterium-encoded virulence proteins. Our results suggest that Agrobacterium modulates the plant DNA damage response machinery, which might facilitate the integration of the bacterial T-DNA into the DNA breaks in the host genome.

A rare transgenic event of rice with Agrobacterium binary vector backbone integration at the right T-DNA border junction

Agrobacterium tumefaciens precisely transfers the transferred DNA (T-DNA) between the right border (RB) and the left border (LB) and integrates it in the plant genome. However, transfer of the binary vector backbone (BVB) at the LB junction has been frequently reported. Here, we describe a complex T-DNA integration in the rice transgenic event CG27 with BVB at the RB junction. Amplification of an RB-plant DNA junction fragment by genome walking and its sequencing revealed that the T-DNA portion ended at the 1st bp of RB, but is followed by a binary vector backbone (BVB) along with an RB-flanking T-DNA portion, both in an inverse orientation. This is followed by a 5-bp filler sequence and the rice chromosome 1 sequence. The configuration of the BVB integration at the RB junction was independently confirmed by PCR. Disruption of native chromosome 1 sequence was confirmed by PCR with chromosome 1-specific primers designed from either side of the T-DNA integration site. BVB sequence close to the RB is transferred and integrated into the CG27 plant genome by a mechanism that does not involve LB-skipping and RB read-through. Therefore, a check for BVB sequences at both LB and RB junctions in a transgenic crop is important in biosafety evaluation.

Assessment of Pigeonpea (Cajanus cajan L.) transgenics expressing Bt ICPs, Cry2Aa and Cry1AcF under nethouse containment implicated an effective control against herbivory by Helicoverpa armigera (Hübner).

Pigeonpea is a source of quality proteins and the main constituent of a well-balanced diet for majority of Indian population. One of the major constraints in the production of pigeonpea is a polyphagous insect pest, Helicoverpa armigera. Non-availability of resistant sources in the germplasm and limitations in conventional breeding have been key factors for continued yield losses. Additionally, hazards of chemical fertilizers on the environment have prompted the scientific community to develop alternative strategies. Bacillus thuringiensis (Bt) insecticidal proteins (ICPs) have emerged as the most reliable source for the control of insect pests through transgenics. Transgenic pigeonpea plants harboring validated Bt ICPs, Cry2Aa and Cry1AcF were developed by a non-tissue culture based in planta transformation strategy and assessed for integration of Transfer-DNA (T-DNA) and efficacy against pod borer under in vitro conditions. For the first time this study demonstrates the successful evaluation of 19 transgenic pigeonpea events (11 with cry2Aa and 8 with cry1AcF) under soil and pot conditions in a nethouse containment. The stability in the performance was assessed stringently by deliberate H. armigera larval challenging. The trial identified ten promising events of both the genes that portrayed reduced damage to the herbivore. We present the first ever successful evaluation of pigeonpea transgenics with the ability to mitigate pod borer under nethouse conditions. The transgenics depicted molecular evidence for the stability of T-DNA integration, consistency in the expression of Cry proteins and resistance against H. armigera. These events can form a pool of useful transgenics to manage the devastating pod borer. © 2019 Society of Chemical Industry.

The complex architecture and epigenomic impact of plant T-DNA insertions.

The bacterium Agrobacterium tumefaciens has been the workhorse in plant genome engineering. Customized replacement of native tumor-inducing (Ti) plasmid elements enabled insertion of a sequence of interest called Transfer-DNA (T-DNA) into any plant genome. Although these transfer mechanisms are well understood, detailed understanding of structure and epigenomic status of insertion events was limited by current technologies. Here we applied two single-molecule technologies and analyzed Arabidopsis thaliana lines from three widely used T-DNA insertion collections (SALK, SAIL and WISC). Optical maps for four randomly selected T-DNA lines revealed between one and seven insertions/rearrangements, and the length of individual insertions from 27 to 236 kilobases. De novo nanopore sequencing-based assemblies for two segregating lines partially resolved T-DNA structures and revealed multiple translocations and exchange of chromosome arm ends. For the current TAIR10 reference genome, nanopore contigs corrected 83% of non-centromeric misassemblies. The unprecedented contiguous nucleotide-level resolution enabled an in-depth study of the epigenome at T-DNA insertion sites. SALK_059379 line T-DNA insertions were enriched for 24nt small interfering RNAs (siRNA) and dense cytosine DNA methylation, resulting in transgene silencing via the RNA-directed DNA methylation pathway. In contrast, SAIL_232 line T-DNA insertions are predominantly targeted by 21/22nt siRNAs, with DNA methylation and silencing limited to a reporter, but not the resistance gene. Additionally, we profiled the H3K4me3, H3K27me3 and H2A.Z chromatin environments around T-DNA insertions using ChIP-seq in SALK_059379, SAIL_232 and five additional T-DNA lines. We discovered various effect s ranging from complete loss of chromatin marks to the de novo incorporation of H2A.Z and trimethylation of H3K4 and H3K27 around the T-DNA integration sites. This study provides new insights into the structural impact of inserting foreign fragments into plant genomes and demonstrates the utility of state-of-the-art long-range sequencing technologies to rapidly identify unanticipated genomic changes.

An Insight into T-DNA Integration Events in Medicago sativa.

The molecular mechanisms of transferred DNA (T-DNA) integration into the plant genome are still not completely understood. A large number of integration events have been analyzed in different species, shedding light on the molecular mechanisms involved, and on the frequent transfer of vector sequences outside the T-DNA borders, the so-called vector backbone (VB) sequences. In this work, we characterized 46 transgenic alfalfa (Medicago sativa L.) plants (events), generated in previous works, for the presence of VB tracts, and sequenced several T-DNA/genomic DNA (gDNA) junctions. We observed that about 29% of the transgenic events contained VB sequences, within the range reported in other species. Sequence analysis of the T-DNA/gDNA junctions evidenced larger deletions at LBs compared to RBs and insertions probably originated by different integration mechanisms. Overall, our findings in alfalfa are consistent with those in other plant species. This work extends the knowledge on the molecular events of T-DNA integration and can help to design better transformation protocols for alfalfa.

Cascade of chromosomal rearrangements caused by a heterogeneous T-DNA integration supports the double-stranded break repair model for T-DNA integration.

Transferred DNA (T-DNA) from Agrobacterium tumefaciens can be integrated into the plant genome. The double-stranded break repair (DSBR) pathway is a major model for T-DNA integration. From this model, we expect that two ends of a T-DNA molecule would invade into a single DNA double-stranded break (DSB) or independent DSBs in the plant genome. We call the later phenomenon a heterogeneous T-DNA integration, which has never been observed. In this work, we demonstrated it in an Arabidopsis T-DNA insertion mutant seb19. To resolve the chromosomal structural changes caused by T-DNA integration at both the nucleotide and chromosome levels, we performed inverse PCR, genome resequencing, fluorescence insitu hybridization and linkage analysis. We found, in seb19, a single T-DNA connected two different chromosomal loci and caused complex chromosomal rearrangements. The specific break-junction pattern in seb19 is consistent with the result of heterogeneous T-DNA integration but not of recombination between two T-DNA insertions. We demonstrated that, in seb19, heterogeneous T-DNA integration evoked a cascade of incorrect repair of seven DSBs on chromosomes 4 and 5, and then produced translocation, inversion, duplication and deletion. Heterogeneous T-DNA integration supports the DSBR model and suggests that two ends of a T-DNA molecule could be integrated into the plant genome independently. Our results also show a new origin of chromosomal abnormalities.

Transformation of the cucurbit powdery mildew pathogen Podosphaera xanthii by Agrobacterium tumefaciens.

The obligate biotrophic fungal pathogen Podosphaera xanthii is the main causal agent of powdery mildew in cucurbit crops all over the world. A major limitation of molecular studies of powdery mildew fungi (Erysiphales) is their genetic intractability. In this work, we describe a robust method based on the promiscuous transformation ability of Agrobacterium tumefaciens for reliable transformation of P.xanthii. The A.tumefaciens-mediated transformation (ATMT) system yielded transformants of P.xanthii with diverse transferred DNA (T-DNA) constructs. Analysis of the resultant transformants showed the random integration of T-DNA into the P.xanthii genome. The integrations were maintained in successive generations in the presence of selection pressure. Transformation was found to be transient, because in the absence of selection agent, the introduced genetic markers were lost due to excision of T-DNA from the genome. The ATMT system represents a potent tool for genetic manipulation of P.xanthii and will likely be useful for studying other biotrophic fungi. We hope that this method will contribute to the development of detailed molecular studies of the intimate interaction established between powdery mildew fungi and their host plants.

Blocking single-stranded transferred DNA conversion to double-stranded intermediates by overexpression of yeast DNA REPLICATION FACTOR A.

Agrobacterium tumefaciens delivers its single-stranded transferred DNA (T-strand) into the host cell nucleus, where it can be converted into double-stranded molecules. Various studies have revealed that double-stranded transfer DNA (T-DNA) intermediates can serve as substrates by as yet uncharacterized integration machinery. Nevertheless, the possibility that T-strands are themselves substrates for integration cannot be ruled out. We attempted to block the conversion of T-strands into double-stranded intermediates prior to integration in order to further investigate the route taken by T-DNA molecules on their way to integration. Transgenic tobacco (Nicotiana benthamiana) plants that overexpress three yeast (Saccharomyces cerevisiae) protein subunits of DNA REPLICATION FACTOR A (RFA) were produced. In yeast, these subunits (RFA1-RFA3) function as a complex that can bind single-stranded DNA molecules, promoting the repair of genomic double strand breaks. Overexpression of the RFA complex in tobacco resulted in decreased T-DNA expression, as determined by infection with A. tumefaciens cells carrying the β-glucuronidase intron reporter gene. Gene expression was not blocked when the reporter gene was delivered by microbombardment. Enhanced green fluorescent protein-assisted localization studies indicated that the three-protein complex was predominantly nuclear, thus indicating its function within the plant cell nucleus, possibly by binding naked T-strands and blocking their conversion into double-stranded intermediates. This notion was further supported by the inhibitory effect of RFA expression on the cell-to-cell movement of Bean dwarf mosaic virus, a single-stranded DNA virus. The observation that RFA complex plants dramatically inhibited the transient expression level of T-DNA and only reduced T-DNA integration by 50% suggests that double-stranded T-DNA intermediates, as well as single-stranded T-DNA, play significant roles in the integration process.

The roles of bacterial and host plant factors in Agrobacterium-mediated genetic transformation

The genetic transformation of plants mediated by Agrobacterium tumefaciens represents an essential tool for both fundamental and applied research in plant biology. For a successful infection, culminating in the integration of its transferred DNA (T-DNA) into the host genome, Agrobacterium relies on multiple interactions with host-plant factors. Extensive studies have unraveled many of such interactions at all major steps of the infection process: activation of the bacterial virulence genes, cell-cell contact and macromolecular translocation from Agrobacterium to host cell cytoplasm, intracellular transit of T-DNA and associated proteins (T-complex) to the host cell nucleus, disassembly of the T-complex, T-DNA integration, and expression of the transferred genes. During all these processes, Agrobacterium has evolved to control and even utilize several pathways of host-plant defense response. Studies of these Agrobacterium-host interactions substantially enhance our understanding of many fundamental cellular biological processes and allow improvements in the use of Agrobacterium as a gene transfer tool for biotechnology.

Formation of Complex Extrachromosomal T-DNA Structures in Agrobacterium tumefaciens-Infected Plants

Agrobacterium tumefaciens is a unique plant pathogenic bacterium renowned for its ability to transform plants. The integration of transferred DNA (T-DNA) and the formation of complex insertions in the genome of transgenic plants during A. tumefaciens-mediated transformation are still poorly understood. Here, we show that complex extrachromosomal T-DNA structures form in A. tumefaciens-infected plants immediately after infection. Furthermore, these extrachromosomal complex DNA molecules can circularize in planta. We recovered circular T-DNA molecules (T-circles) using a novel plasmid-rescue method. Sequencing analysis of the T-circles revealed patterns similar to the insertion patterns commonly found in transgenic plants. The patterns include illegitimate DNA end joining, T-DNA truncations, T-DNA repeats, binary vector sequences, and other unknown "filler" sequences. Our data suggest that prior to T-DNA integration, a transferred single-stranded T-DNA is converted into a double-stranded form. We propose that termini of linear double-stranded T-DNAs are recognized and repaired by the plant's DNA double-strand break-repair machinery. This can lead to circularization, integration, or the formation of extrachromosomal complex T-DNA structures that subsequently may integrate.

Induction of chromosomal inversion by integration of T-DNA in the rice genome

Transfer DNA (T-DNA) of Agrobacterium tumefaciens integration in the plant genome may lead to rearrangements of host plant chromosomal fragments, including inversions. However, there is very little information concerning the inversion. The present study reports a transgenic rice line selected from a T-DNA tagged population, which displays a semi-dwarf phenotype. Molecular analysis of this mutant indicated an insertion of two tandem copies of T-DNA into a locus on the rice genome in a head to tail mode. This insertion of T-DNA resulted in the inversion of a 4.9 Mb chromosomal segment. Results of sequence analysis suggest that the chromosomal inversion resulted from the insertion of T-DNA with the help of sequence microhomology between insertion region of T-DNA and target sequence of the host plant.

New insights into an old story: Agrobacterium-induced tumour formation in plants by plant transformation

Agrobacterium tumefaciens causes tumour formation in plants. Plant signals induce in the bacteria the expression of a range of virulence (Vir) proteins and the formation of a type IV secretion system (T4SS). On attachment to plant cells, a transfer DNA (T-DNA) and Vir proteins are imported into the host cells through the bacterial T4SS. Through interaction with a number of host proteins, the Vir proteins suppress the host innate immune system and support the transfer, nuclear targeting, and integration of T-DNA into host cell chromosomes. Owing to extensive genetic analyses, the bacterial side of the plant-Agrobacterium interaction is well understood. However, progress on the plant side has only been achieved recently, revealing a highly complex molecular choreography under the direction of the Vir proteins that impinge on multiple processes including transport, transcription, and chromosome status of their host cells.

Evaluation of the uniformity and stability of T-DNA integration and gene expression in transgenic apple plants

The generation of transgenic apple plants relies on the molecular analysis of transgene integration and expression based on polymerase chain reaction (PCR) analysis, blotting techniques and enzymatic assays on vitro leaves of putative transgenic regenerates. In order to assess the uniformity and the stability of transfer DNA (T-DNA) integration and gene expression, we studied 26 transgenic apple lines carrying the attacin E gene from Hyalophora cecropia , the β-glucuronidase gene, and the nptII gene. Plants were evaluated using standard molecular techniques, such as PCR, Southern blot, reverse transcription PCR (RT-PCR) and Enzyme Linked Immunosorbent Assay (ELISA), and propagated in vitro on non-selective antibiotic-free media for four years to mimic natural conditions in the field. In some T-lines transgene integration and expression did not remain stable; differences were also found between distinct plants of a single T-line. Individual plants with partially or completely silenced transgenes were identified as well as plants with non-detectable T-DNA. Several lines appeared chimeric or partially silenced. Although most molecular techniques can reliably detect the presence of transgenic cells, they often fail to detect mixtures of transformed and non-transformed cells, or cells with silenced transgenes. This should be taken into consideration, especially in the case of vegetatively propagated trees, where non-transformed or silenced plant parts could mistakenly be used as propagation material.

Characterization of T-DNA insertion patterns in the genome of rice blast fungus Magnaporthe oryzae

Agrobacterium tumefaciens-mediated transformation (ATMT) has been proven to be a powerful strategy for gene disruption in plants and fungi. Patterns associated with transferred DNA (T-DNA) integration in plants and yeast have been studied comprehensively, whereas no detailed analysis of T-DNA integration has been reported yet in filamentous fungi. Here, we reported the T-DNA insertion patterns in the genome of filamentous fungus Magnaporthe oryzae. Using ATMT, a T-DNA tagged population consisting of 6,179 transformants of M. oryzae was constructed. With thermal asymmetric interlaced-PCR (TAIL-PCR), 623 right border (RB) flanking sequences and 124 left border (LB) flanking sequences were generated. Analysis of these flanking sequences indicated a significant integration bias toward non-coding sequences, suggesting distribution of T-DNAs was not random. Comparing to T-DNA RB, LB was nicked inaccurately and truncated frequently during integration. Chromosomal rearrangements, such as deletion, inversion, and translocation, were associated with T-DNA integration in some transformants. Our data suggest that, comparing with plant cells, T-DNA integrates into this filamentous fungus with more precise and simpler patterns. Some phenotypic mutants were observed in our T-DNA tagged population, and these transformants will be very useful for functional genomics research of M. oryzae.

Identification and Characterization of Plant Genes Involved inAgrobacterium-Mediated Plant Transformation by Virus-Induced Gene Silencing

Genetic transformation of plant cells by Agrobacterium tumefaciens represents a unique case of trans-kingdom sex requiring the involvement of both bacterial virulence proteins and plant-encoded proteins. We have developed in planta and leaf-disk assays in Nicotiana benthamiana for identifying plant genes involved in Agrobacterium-mediated plant transformation using virus-induced gene silencing (VIGS) as a genomics tool. VIGS was used to validate the role of several genes that are either known or speculated to be involved in Agrobacterium-mediated plant transformation. We showed the involvement of a nodulin-like protein and an alpha-expansin protein (alpha-Exp) during Agrobacterium infection. Our data suggest that alpha-Exp is involved during early events of Agrobacterium-mediated transformation but not required for attaching A. tumefaciens. By employing the combination of the VIGS-mediated forward genetics approach and an in planta tumorigenesis assay, we identified 21 ACG (altered crown gall) genes that, when silenced, produced altered crown gall phenotypes upon infection with a tumorigenic strain of A. tumefaciens. One of the plant genes identified from the screening, Histone H3 (H3), was further characterized for its biological role in Agrobacterium-mediated plant transformation. We provide evidence for the role of H3 in transfer DNA integration. The data presented here suggest that the VIGS-based approach to identify and characterize plant genes involved in genetic transformation of plant cells by A. tumefaciens is simple, rapid, and robust and complements other currently used approaches.

A rice gene activation/knockout mutant resource for high throughput functional genomics

Using transfer DNA (T-DNA) with functions of gene trap and gene knockout and activation tagging, a mutant population containing 55,000 lines was generated. Approximately 81% of this population carries 1-2 T-DNA copies per line, and the retrotransposon Tos17 was mostly inactive in this population during tissue culture. A total of 11,992 flanking sequence tags (FSTs) have been obtained and assigned to the rice genome. T-DNA was preferentially ( approximately 80%) integrated into genic regions. A total of 19,000 FSTs pooled from this and another T-DNA tagged population were analyzed and compared with 18,000 FSTs from a Tos17 tagged population. There was difference in preference for integrations into genic, coding, and flanking regions, as well as repetitive sequences and centromeric regions, between T-DNA and Tos17; however, T-DNA integration was more evenly distributed in the rice genome than Tos17. Our T-DNA contains an enhancer octamer next to the left border, expression of genes within genetics distances of 12.5 kb was enhanced. For example, the normal height of a severe dwarf mutant, with its gibberellin 2-oxidase (GA2ox) gene being activated by T-DNA, was restored upon GA treatment, indicating GA2ox was one of the key enzymes regulating the endogenous level of GA. Our T-DNA also contains a promoterless GUS gene next to the right border. GUS activity screening facilitated identification of genes responsive to various stresses and those regulated temporally and spatially in large scale with high frequency. Our mutant population offers a highly valuable resource for high throughput rice functional analyses using both forward and reverse genetic approaches.