Regional mutagenesis using Dissociation in maize

We describe genetic screens, molecular methods and web resources newly available to utilize Dissociation (Ds) as an insertional mutagen in maize. Over 1700 Ds elements have been distributed throughout the maize genome to serve as donor elements for local or regional mutagenesis. Two genetic screens are described to identify Ds insertions in genes-of-interest (goi). In scheme I, Ds is used to generate insertion alleles when a recessive reference allele is available. A Ds insertion will enable the cloning of the target gene and can be used to create an allelic series. In scheme II, Ds insertions in a goi are identified using a PCR-based screen to identify the rare insertion alleles among a population of testcross progeny. We detail an inverse PCR protocol to rapidly amplify sequences flanking Ds insertion alleles and describe a high-throughput 96-well plate-based DNA extraction method for the recovery of high-quality genomic DNA from seedling tissues. We also describe several web-based tools for browsing, searching and accessing the genetic materials described. The development of these Ds insertion lines promises to greatly accelerate functional genomics studies in maize.     

Genome-Wide Distribution of Transposed Dissociation Elements in Maize

The maize (Zea mays) transposable element Dissociation (Ds) was mobilized for large-scale genome mutagenesis and to study its endogenous biology. Starting from a single donor locus on chromosome 10, over 1500 elements were distributed throughout the genome and positioned on the maize physical map. Genetic strategies to enrich for both local and unlinked insertions were used to distribute Ds insertions. Global, regional, and local insertion site trends were examined. We show that Ds transposed to both linked and unlinked sites and displayed a nonuniform distribution on the genetic map around the donor r1-sc:m3 locus. Comparison of Ds and Mutator insertions reveals distinct target preferences, which provide functional complementarity of the two elements for gene tagging in maize. In particular, Ds displays a stronger preference for insertions within exons and introns, whereas Mutator insertions are more enriched in promoters and 5′-untranslated regions. Ds has no strong target site consensus sequence, but we identified properties of the DNA molecule inherent to its local structure that may influence Ds target site selection. We discuss the utility of Ds for forward and reverse genetics in maize and provide evidence that genes within a 2- to 3-centimorgan region flanking Ds insertions will serve as optimal targets for regional mutagenesis.     

Spectrum of T-DNA integrations for insertional mutagenesis of Histoplasma capsulatum

Agrobacterium-mediated transformation is being increasingly used for insertional mutagenesis of fungi. To better evaluate its effectiveness as a mutagen for the fungal pathogen Histoplasma capsulatum, we analyzed a collection of randomly selected T-DNA insertion mutants. Testing of different T-DNA element vectors engineered for transformation of fungi showed that pBHt2 provides the highest transformation efficiency and the lowest rate of vector backbone carryover. Sixty-eight individual T-DNA integrations were characterized by recovery of T-DNA ends and flanking genomic sequences. The right border (RB) end of the T-DNA is largely preserved whereas the left border (LB) end is frequently truncated. Analysis of T-DNA insertion sites confirms the lack of any integration hotspots in the Histoplasma genome. Relative to genes, T-DNA integrations show significant bias towards promoter regions at the expense of coding sequences. With consideration for potential promoter interruption and the demonstrated efficacy of intronic insertions, 61 % of mapped T-DNA insertions should impair gene expression or function. Mapping of T-DNA flanking sequences demonstrates 67 % of T-DNA integrations are integrations at a single chromosomal site and 31 % of T-DNA integrations are associated with large-scale chromosomal rearrangements. This characterization of T-DNA insertions in mutants selected without regard to phenotype supports application of Agrobacterium-mediated transformation as an insertional mutagen for genome-based screens and functional discovery of genes in Histoplasma.     

A collection of sequenced and mapped Ds transposon insertion sites in Arabidopsis thaliana

Insertional mutagenesis is a powerful tool for generating knockout mutations that facilitate associating biological functions with as yet uncharacterized open reading frames (ORFs) identified by genomic sequencing or represented in EST databases. We have generated a collection of Dissociation(Ds) transposon lines with insertions on all 5 Arabidopsischromosomes. Here we report the insertion sites in 260 independent single-transposon lines, derived from four different Ds donor sites. We amplified and determined the genomic sequence flanking each transposon, then mapped its insertion site by identity of the flanking sequences to the corresponding sequence in the Arabidopsisgenome database. This constitutes the largest collection of sequence-mapped Ds insertion sites unbiased by selection against the donor site. Insertion site clusters have been identified around three of the four donor sites on chromosomes 1 and 5, as well as near the nucleolus organizers on chromosomes 2 and 4. The distribution of insertions between ORFs and intergenic sequences is roughly proportional to the ratio of genic to intergenic sequence. Within ORFs, insertions cluster near the translational start codon, although we have not detected insertion site selectivity at the nucleotide sequence level. A searchable database of insertion site sequences for the 260 transposon insertion sites is available at http://sgio2.biotec.psu.edu/sr. This and other collections of Arabidopsislines with sequence-identified transposon insertion sites are a valuable genetic resource for functional genomics studies because the transposon location is precisely known, the transposon can be remobilized to generate revertants, and the Ds insertion can be used to initiate further local mutagenesis.     

Functional characterization of transposon-tagged abiotic stress-responsive rice genes and their molecular polymorphisms among various stress-tolerant genotypes

Dissociation (Ds) insertional mutagenesis has been regarded as an efficient tool to generate insertion mutants for functional genomics and molecular breeding. However, little is known about the application of the tool on exploring biological functions of abiotic stress-related genes and their molecular breeding experience. In this study, a total of 833 Ds insertion lines have been obtained, which showed significantly higher tolerance or sensitivity to high salinity, drought or cold stress, by screening around 20,000 Ds lines. Analysis of Ds flanking sequence tags revealed that 165 rice genes were tagged by Ds insertion. Gene Ontology (GO) and gene set enrichment analysis showed that over-represented Ds-tagged genes might function in the response to exogenous stimuli. These Ds-tagged genes showed expression divergence among five high salinity and five drought tolerant rice lines under either high salinity or drought stress. Higher percentages of Ds-tagged genes were down- or up-regulated by these abiotic stresses. These Ds-tagged genes were also frequently reduced or suppressed by various phytohormones including abscisic acid and jasmonate. On the other hand, we have also detected single nucleotide polymorphisms (SNPs) and 1–10 base pairs of insertion and deletions (indels) of these Ds-tagged genes among ten high salinity/drought tolerant rice lines by comparing with the reference genome Nipponbare. Our data showed that SNPs were detected among 102 out of 165 genes and indels were identified in 39 out of 165 genes. All the data provided additional information to further explore the biological functions of these genes or to carry out molecular breeding.     

Genome-wide mutagenesis of <Emphasis Type="Italic">Zea mays</Emphasis> L. using <Emphasis Type="Italic">RescueMu</Emphasis> transposons

Derived from the maize Mu1 transposon, RescueMu provides strategies for maize gene discovery and mutant phenotypic analysis. 9.92 Mb of gene-enriched sequences next to RescueMu insertion sites were co-assembled with expressed sequence tags and analyzed. Multiple plasmid recoveries identified probable germinal insertions and screening of RescueMu plasmid libraries identified plants containing probable germinal insertions. Although frequently recovered parental insertions and insertion hotspots reduce the efficiency of gene discovery per plasmid, RescueMu targets a large variety of genes and produces knockout mutants.     

Ac/Ds transposon mutagenesis in Arabidopsis thaliana: mutant spectrum and frequency of Ds insertion mutants

Using a two-component Ac/Ds system consisting of a stabilized Ac element (Ac_c1) and a non-autonomous element (Ds_A), 650 families of plants carrying independent germinal Ds_A excisions/transpositions were isolated. Progenies of 559 of these Ac_c1/Ds_A families, together with 43 families of plants selected for excision/transposition of wild-type (wt)Ac, were subjected to a broad screening program for mutants exhibiting visible alterations. This resulted in the identification of 48 mutants showing a wide variety of mutant phenotypes, including embryo lethality (24 mutants), chlorophyll defects (5 mutants), defective seedlings (2 mutants), reduced fertility (5 mutants), reduced size (3 mutants), altered leaf morphology (2 mutants), dark green, unexpanded rosette leaves (3 mutants), and aberrant flower or shoot morphology (4 mutants). To test whether these mutants were due to transposon insertions, a series of Southern blot experiments was performed on 28 families, comparing in each case several mutant plants with others showing the wild-type phenotype. A preliminary analysis revealed in 4 of the 28 families analyzed a common, novel Ds_A fragment in all mutant plants, which was present only in heterozygous plants with wt phenotype, as expected for Ds_A insertion mutations. These four mutants included two showing embryo lethality, one with dark green, unexpanded rosette leaves and stunted inflorescences, and one with curly growth of stems, leaves and siliques. Further evidence for Ds_A insertion mutations was obtained for one embryo lethal mutant and for the stunted mutant, while in case of the second embryo lethal mutant, the Ds_A insertion could be separated from the mutant locus by genetic recombination.     

Clonal Expansion Analysis of Transposon Insertions by High-Throughput Sequencing Identifies Candidate Cancer Genes in a PiggyBac Mutagenesis Screen

Somatic transposon mutagenesis in mice is an efficient strategy to investigate the genetic mechanisms of tumorigenesis. The identification of tumor driving transposon insertions traditionally requires the generation of large tumor cohorts to obtain information about common insertion sites. Tumor driving insertions are also characterized by their clonal expansion in tumor tissue, a phenomenon that is facilitated by the slow and evolving transformation process of transposon mutagenesis. We describe here an improved approach for the detection of tumor driving insertions that assesses the clonal expansion of insertions by quantifying the relative proportion of sequence reads obtained in individual tumors. To this end, we have developed a protocol for insertion site sequencing that utilizes acoustic shearing of tumor DNA and Illumina sequencing. We analyzed various solid tumors generated by PiggyBac mutagenesis and for each tumor >10⁶ reads corresponding to >10⁴ insertion sites were obtained. In each tumor, 9 to 25 insertions stood out by their enriched sequence read frequencies when compared to frequencies obtained from tail DNA controls. These enriched insertions are potential clonally expanded tumor driving insertions, and thus identify candidate cancer genes. The candidate cancer genes of our study comprised many established cancer genes, but also novel candidate genes such as Mastermind-like1 (Mamld1) and Diacylglycerolkinase delta (Dgkd). We show that clonal expansion analysis by high-throughput sequencing is a robust approach for the identification of candidate cancer genes in insertional mutagenesis screens on the level of individual tumors.     

Factors affecting the excision frequency of the maize transposable element Ds in Arabidopsis thaliana

A two-element transposon system based on the maize elements Ac and Ds is currently being used for insertional mutagenesis in Arabidopsis. With the aim of making this system as efficient as possible we have continued to analyse several parameters which affect Ds activity in Arabidopsis. The influence of genomic position on Ds excision has been analysed in five lines carrying Ds integrated in different genomic locations. Differences in both somatic and germinal excision were observed between the different lines. The relationship between somatic and germinal excision, the timing of excision events and environmental influences on transposition frequency have been investigated. The effect of varying dosage of the different elements was also analysed. A strong positive dosage effect was observed for the transposase source, but not for the Ds element. Analysis of germinal excision events showed that the majority of them occurred very late in the development of the plant, resulting in the majority of Ds transpositions being independent events.     

α-Domain of human metallothionein IA can bind to metals in transgenic tobacco plants

We have introduced a genetically marked Dissociation transposable element (Ds ^HPT ) into tomato (Lycopersicon esculentum) by Agrobacterium tumefaciens-mediated transformation. Probes for the flanking regions of the T-DNA and transposed Ds ^HPT elements were obtained with the inverse polymerase chain reaction (IPCR) technique and used in RFLP linkage analyses. The RFLP map location of 11 T-DNAs carrying Ds ^HPT was determined. The T-DNAs are distributed on 7 of the 12 tomato chromosomes. To explore the feasibility of gene tagging strategies in tomato using Ds ^HPT , we examined the genomic distribution of Ds ^HPT receptor sites relative to the location of two different, but very closely linked, T-DNA insertion sites. After crosses with plants expressing Ac transposase, the hygromycin phosphotransferase (HPT) marker on the Ds element and the excision markers β-glucuronidase (GUS) and Basta resistance (BAR) facilitated the identification of plants bearing germinally transposed Ds ^HPT elements. RFLP mapping of 21 transposed Ds ^HPT elements originating from the two different T-DNA insertions revealed distinct patterns of reintegration sites.     

Construction of Signature-tagged Mutant Library in Mesorhizobium loti as a Powerful Tool for Functional Genomics

Rhizobia are nitrogen-fixing soil bacteria that establish endosymbiosis with some leguminous plants. The completion of several rhizobial genome sequences provides opportunities for genome-wide functional studies of the physiological roles of many rhizobial genes. In order to carry out genome-wide phenotypic screenings, we have constructed a large mutant library of the nitrogen-fixing symbiotic bacterium, Mesorhizobium loti, by transposon mutagenesis. Transposon insertion mutants were generated using the signature-tagged mutagenesis (STM) technique and a total of 29 330 independent mutants were obtained. Along with the collection of transposon mutants, we have determined the transposon insertion sites for 7892 clones, and confirmed insertions in 3680 non-redundant M. loti genes (50.5% of the total number of M. loti genes). Transposon insertions were randomly distributed throughout the M. loti genome without any bias toward G+C contents of insertion target sites and transposon plasmids used for the mutagenesis. We also show the utility of STM mutants by examining the specificity of signature tags and test screenings for growth- and nodulation-deficient mutants. This defined mutant library allows for genome-wide forward- and reverse-genetic functional studies of M. loti and will serve as an invaluable resource for researchers to further our understanding of rhizobial biology.Key words: Mesorhizobium loti, signature-tagged mutagenesis, mutant library, reverse genetics     

Molecular analysis of high-copy insertion sites in maize

High-copy transposon mutagenesis is an effective tool for creating gene disruptions in maize. In order to molecularly define transposon-induced disruptions on a genome-wide scale, we optimized TAIL-PCR to amplify genomic DNA flanking maize Robertson’s Mutator insertions. Sample sequencing from 43 Mutator stocks and the W22 inbred line identified 676 non-redundant insertions, and only a small fraction of the flanking sequences showed significant similarity to maize repetitive sequences. We further designed and tested 79 arbitrary primers to identify 12 primers that amplify all Mutator insertions within a DNA sample at 3.1-fold redundancy. Importantly, the products are of sufficient size to use as substrates or probes for hybridization-based identification of gene disruptions. Our adaptation simplifies previously published TAIL-PCR protocols and should be transferable to other high-copy insertional mutagens.     

Site-selected insertional mutagenesis of tomato with maizeAc andDs elements

Site-selected insertion (SSI) is a PCR-based technique which uses primers located within the transposon and a target gene for detection of transposon insertions into cloned genes. We screened tomato plants bearing single or multiple copies of maizeAc orDs transposable elements for somatic insertions at one close-range target and two long-range targets. Eight close-rangeDs insertions near the right border of the T-DNA were recovered. Sequence analysis showed a precise junction between the transposon and the target for all insertions. Two insertions in separate plants occurred at the same site, but others appeared dispersed in the region of the right T-DNA border with no target specificity. However, insertions showed a preference for one orientation of the transposon. Use of plants with multipleAc (HiAc) orDs (HiDs) elements allowed detection of somatic insertions at two single-copy genes,PG (polygalacturonase) andDFR (dihydroflavonol 4-reductase). Certain HiDs plants showed much higher rates of insertion intoPG than others. Insertions inPG andDFR were found throughout the gene regions monitored and, with the exception of one insertion inPG, the junctions between transposon and target were exact. SSI analysis of progeny from the HiDs parents revealed that in some cases the tendency to incur high levels of somatic insertions inPG was inherited. Inheritance of this character is an indication that SSI could be used to direct a search for germinalPG insertions in tomato.     

<Emphasis Type="Italic">Ds</Emphasis> insertion mutagenesis as an efficient tool to produce diverse variations for rice breeding

The availability of diversified germplasm resources is the most important for developing improved rice varieties with higher seed yield or tolerance to various biotic or abiotic stresses. Here we report an efficient tool to create increased variations in rice by maize Ac/Ds transposon (a gene trap system) insertion mutagenesis. We have generated around 20,000 Ds insertion rice lines of which majority are homozygous for Ds element. We subjected these lines to phenotypic and abiotic stress screens and evaluated these lines with respect to their seed yields and other agronomic traits as well as their tolerance to drought, salinity and cold. Based on this evaluation, we observed that random Ds insertions into rice genome have led to diverse variations including a range of morphological and conditional phenotypes. Such differences in phenotype among these lines were accompanied by differential gene expression revealed by GUS histochemical staining of gene trapped lines. Among the various phenotypes identified, some Ds lines showed significantly higher grain yield compared to wild-type plants under normal growth conditions indicating that rice could be improved in grain yield by disrupting certain endogenous genes. In addition, several 1,000s of Ds lines were subjected to abiotic stresses to identify conditional mutants. Subsequent to these screens, over 800 lines responsive to drought, salinity or cold stress were obtained, suggesting that rice has the genetic potential to survive under abiotic stresses when appropriate endogenous genes were suppressed. The mutant lines that have higher seed yielding potential or display higher tolerance to abiotic stresses may be used for rice breeding by conventional backcrossing combining with molecular marker-assisted selection. In addition, by exploiting the behavior of Ds to leave footprints upon remobilization, we have shown an alternative strategy to develop new rice varieties without foreign DNA sequences in their genome. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Generation and Characterization of the Western Regional Research Center Brachypodium T-DNA Insertional Mutant Collection

The model grass Brachypodium distachyon (Brachypodium) is an excellent system for studying the basic biology underlying traits relevant to the use of grasses as food, forage and energy crops. To add to the growing collection of Brachypodium resources available to plant scientists, we further optimized our Agrobacterium tumefaciens-mediated high-efficiency transformation method and generated 8,491 Brachypodium T-DNA lines. We used inverse PCR to sequence the DNA flanking the insertion sites in the mutants. Using these flanking sequence tags (FSTs) we were able to assign 7,389 FSTs from 4,402 T-DNA mutants to 5,285 specific insertion sites (ISs) in the Brachypodium genome. More than 29% of the assigned ISs are supported by multiple FSTs. T-DNA insertions span the entire genome with an average of 19.3 insertions/Mb. The distribution of T-DNA insertions is non-uniform with a larger number of insertions at the distal ends compared to the centromeric regions of the chromosomes. Insertions are correlated with genic regions, but are biased toward UTRs and non-coding regions within 1 kb of genes over exons and intron regions. More than 1,300 unique genes have been tagged in this population. Information about the Western Regional Research Center Brachypodium insertional mutant population is available on a searchable website (http://brachypodium.pw.usda.gov) designed to provide researchers with a means to order T-DNA lines with mutations in genes of interest.     

Molecular re-confirmation and floral characteristics of drooping leaf (DL) mutants generated by insertional mutagenesis in rice

Transposon tagging and insertional mutagenesis provide one of the most powerful tools in gene function studies. Here, we report a comparison between two novel drooping leaf (DL) mutants from transposon and T-DNA insertion lines of rice. DL is distinct from well-known ABC genes and a member of the YABBY gene family, and it is closely related to the CRABS CLAW (CRC) gene of Arabidopsis thaliana. Based on phenotypic analysis, DL regulated midrib formation by promoting cell proliferation in the central region of rice leaf and was necessary for the specification of carpel identity. We identified two DL mutants by screening the Ac/Ds and T-DNA insertional mutant pool of rice. Flanking sequence tag analysis indicated that both Ds and T-DNA segments were inserted in the promoter region at 3.4 kbs and 5.4 kb upstream, respectively, of the previously known OsYABBY domain. Interestingly, the progenies of DL lines of two different pools showed various degrees of leaf drooping and abnormal carpel formation. Flower structures revealed that there were more than two stigmas with normal stamens and pistils per panicle in the Ds-induced mutants. However, T-DNA induced mutant had extra stamens with staminoid carpels. These results indicate that the promoter region of DL plays an important function in regulating anther and carpel formation.     

Ac/Ds transposon mutagenesis in Arabidopsis thaliana: mutant spectrum and frequency of Ds insertion mutants

Using a two-component Ac/Ds system consisting of a stabilized Ac element (Ac_c1) and a non-autonomous element (Ds_A), 650 families of plants carrying independent germinal Ds_A excisions/transpositions were isolated. Progenies of 559 of these Ac_c1/Ds_A families, together with 43 families of plants selected for excision/transposition of wild-type (wt)Ac, were subjected to a broad screening program for mutants exhibiting visible alterations. This resulted in the identification of 48 mutants showing a wide variety of mutant phenotypes, including embryo lethality (24 mutants), chlorophyll defects (5 mutants), defective seedlings (2 mutants), reduced fertility (5 mutants), reduced size (3 mutants), altered leaf morphology (2 mutants), dark green, unexpanded rosette leaves (3 mutants), and aberrant flower or shoot morphology (4 mutants). To test whether these mutants were due to transposon insertions, a series of Southern blot experiments was performed on 28 families, comparing in each case several mutant plants with others showing the wild-type phenotype. A preliminary analysis revealed in 4 of the 28 families analyzed a common, novel Ds_A fragment in all mutant plants, which was present only in heterozygous plants with wt phenotype, as expected for Ds_A insertion mutations. These four mutants included two showing embryo lethality, one with dark green, unexpanded rosette leaves and stunted inflorescences, and one with curly growth of stems, leaves and siliques. Further evidence for Ds_A insertion mutations was obtained for one embryo lethal mutant and for the stunted mutant, while in case of the second embryo lethal mutant, the Ds_A insertion could be separated from the mutant locus by genetic recombination.