Project description:Mu killer contains a partial inverted duplication of the mudrA transposase gene and two copies of the terminal inverted repeat A (TIRA) region of the master MuDR element of maize. Mu killer can effectively silence single copy MuDR/Mu lines, and it is proposed that a ∼4 kb hairpin RNA is generated by read through transcription from a flanking gene and that this transcript serves as a substrate for siRNA production. Mu killer was sequenced, except for a recalcitrant portion in the center of the locus, and shown to be co-linear with mudrA as originally proposed. The ability of the dominant Mu killer locus to silence a standard high copy number MuDR/Mu transposon line was evaluated. After two generations of exposure, about three quarters of individuals were silenced indicating reasonable effectiveness as measured by the absence of mudrA transposase transcripts. Mu killer individuals that effectively silenced MuDR expressed two short antisense transcripts. In contrast, Mu killer individuals that failed to silence MuDR expressed multiple sense transcripts, derived from read through transcription initiating in a flanking gene, but no antisense transcripts were detected.

Project description:Robertson's Mutator (Mu) system has been used in large scale mutagenesis in maize, exploiting its high mutation frequency, controllability, preferential insertion in genes, and independence of donor location. Eight Mutator elements have been fully characterized (Mu1, Mu2 /Mu1.7, Mu3, Mu4, Mu5, Mu6/7, Mu8, MuDR), and three are defined by TIR (Mu10, Mu11 and Mu12). The genome sequencing revealed a complex family of Mu-like-elements (MULEs) in the B73 genome. In this article, we report the identification of a new Mu element, named Mu13. Mu13 showed typical Mu characteristics by having a ?220 bp TIR, creating a 9 bp target site duplication upon insertion, yet the internal sequence is completely different from previously identified Mu elements. Mu13 is not present in the B73 genome or a Zea mays subsp. parviglumis accession, but in W22 and several inbreds that found the Robertson's Mutator line. Analysis of mutants isolated from the UniformMu mutagenic population indicated that the Mu13 element is active in transposition. Two novel insertions were found in expressed genes. To test other unknown Mu elements, we selected six new Mu elements from the B73 genome. Southern analysis indicated that most of these elements were present in the UniformMu lines. From these results, we conclude that Mu13 is a new and active Mu element that significantly contributed to the mutagenesis in the UniformMu population. The Robertson's Mutator line may harbor other unknown active Mu elements.

Project description:Mu killer contains a partial inverted duplication of the mudrA transposase gene and two copies of the terminal inverted repeat A region of MuDR. Mu killer can effectively silence single copy MuDR/Mu lines but failed to silence about 25% of the time in multiple copy lines. Mu killer was partially sequenced and shown to be collinear with mudrA. Mu killer individuals that silenced MuDR contained two short antisense transcripts, while individuals that failed to silence MuDR contained multiple sense transcripts but no antisense transcripts. Transcriptomes from Mu killer-silenced individuals were compared to epigenetically silenced lines; the 2 silencing mechanisms were shown to affect different pathways.

Project description:Three closely related parthenogenetic species of root-knot nematodes, collectively termed the Meloidogyne incognita-group, are economically significant pathogens of diverse crop species. Remarkably, these asexual root-knot nematodes are capable of acquiring heritable changes in virulence even though they lack sexual reproduction and meiotic recombination. Characterization of a near isogenic pair of M. javanica strains differing in response to tomato with the nematode resistance gene Mi-1 showed that the virulent strain carried a deletion spanning a gene called Cg-1. Herein, we present evidence that the Cg-1 gene lies within a member of a novel transposable element family (Tm1; Transposon in Meloidogyne-1). This element family is defined by composite terminal inverted repeats of variable lengths similar to those of Foldback (FB) transposable elements and by 9 bp target site duplications. In M. incognita, Tm1 elements can be classified into three general groups: 1) histone-hairpin motif elements; 2) MITE-like elements; 3) elements encoding a putative transposase. The predicted transposase shows highest similarity to gene products encoded by aphids and mosquitoes and resembles those of the Phantom subclass of the Mutator transposon superfamily. Interestingly, the meiotic, sexually-reproducing root-knot nematode species M. hapla has Tm1 elements with similar inverted repeat termini, but lacks elements with histone hairpin motifs and contains no elements encoding an intact transposase. These Tm1 elements may have impacts on root-knot nematode genomes and contribute to genetic diversity of the asexual species.

Project description:Mu killer contains a partial inverted duplication of the mudrA transposase gene and two copies of the terminal inverted repeat A region of MuDR. Mu killer can effectively silence single copy MuDR/Mu lines but failed to silence about 25% of the time in multiple copy lines. Mu killer was partially sequenced and shown to be collinear with mudrA. Mu killer individuals that silenced MuDR contained two short antisense transcripts, while individuals that failed to silence MuDR contained multiple sense transcripts but no antisense transcripts. Transcriptomes from Mu killer-silenced individuals were compared to epigenetically silenced lines; the 2 silencing mechanisms were shown to affect different pathways. 4 replicates of the Mu-active and Mu-inactive lines at 2 anther stages (1.0mm, 2.00mm) with a balanced dye-swap design. Normalized intensities for each channel are provided.

Project description:Most angiosperm nuclear DNA is repetitive and derived from silenced transposable elements (TEs). TE silencing requires substantial resources from the plant host, including the production of small interfering RNAs (siRNAs). Thus, the interaction between TEs and siRNAs is a critical aspect of both the function and the evolution of plant genomes. Yet the co-evolutionary dynamics between these two entities remain poorly characterized. Here we studied the organization of TEs within the maize (Zea mays ssp mays) genome, documenting that TEs fall within three groups based on the class and copy numbers. These groups included DNA elements, low copy RNA elements and higher copy RNA elements. The three groups varied statistically in characteristics that included length, location, age, siRNA expression and 24:22 nucleotide (nt) siRNA targeting ratios. In addition, the low copy retroelements encompassed a set of TEs that had previously been shown to decrease expression within a 24 nt siRNA biogenesis mutant (mop1). To investigate the evolutionary dynamics of the three groups, we estimated their abundance in two landraces, one with a genome similar in size to that of the maize reference and the other with a 30% larger genome. For all three accessions, we assessed TE abundance as well as 22 nt and 24 nt siRNA content within leaves. The high copy number retroelements are under targeted similarly by siRNAs among accessions, appear to be born of a rapid bust of activity, and may be currently transpositionally dead or limited. In contrast, the lower copy number group of retrolements are targeted more dynamically and have had a long and ongoing history of transposition in the maize genome.

Project description:Imprinting is a form of epigenetic gene regulation in which alleles are differentially regulated according to the parent of origin. The Mez1 gene in maize is imprinted such that the maternal allele is expressed in the endosperm while the paternal allele is not expressed. Three novel Mez1 alleles containing Mutator transposon insertions within the promoter were identified. These mez1-mu alleles do not affect vegetative expression levels or result in morphological phenotypes. However, these alleles can disrupt imprinted expression of Mez1. Maternal inheritance of the mez-m1 or mez1-m4 alleles results in activation of the normally silenced paternal allele of Mez1. Paternal inheritance of the mez1-m2 or mez1-m4 alleles can also result in a loss of silencing of the paternal Mez1 allele. The paternal disruption of imprinting by transposon insertions may reflect a requirement for sequence elements involved in targeting silencing of the paternal allele. The maternal disruption of imprinting by transposon insertions within the Mez1 promoter suggests that maternally produced MEZ1 protein may be involved in silencing of the paternal Mez1 allele. The endosperms with impaired imprinting did not exhibit phenotypic consequences associated with bi-allelic Mez1 expression.

Project description:We have cloned and sequenced a 1.7-kb Mu element from a Mutator line of maize and compared its structure to Mu1, a 1.4-kb element. With the exception of a 385-bp block of DNA present in the 1.7-kb element, these transposable elements are structurally similar, sharing terminally inverted and internal direct repeated sequences. Derivation of 1.4-kb elements from the 1.7-kb class via deletion of internal sequence is suggested by the finding that a portion of the extra DNA in Mu1.7 is part of a truncated direct repeat sequence in the 1.4-kb element. An abundant poly(A)+ RNA homologous to a portion of this extra DNA is present in several tissues of both Mutator and non-Mutator lines. Analysis of transcripts from an unstable mutant bronze 1 (bz) allele containing a Mu1.7 element inserted in an exon of the gene detects three species of poly(A)+ RNA that hybridize to a Bz1 (Bronze) gene probe: the largest contains the entire Mu1.7 element in the Bz1 gene transcript; another appears to be a spliced, chimeric transcript; the smallest is normal size Bz1 mRNA. The latter is most likely encoded by the normal-size alleles detected by Southern analysis of tissue expressing purple pigment, suggesting that normal gene function is restored by excision of the Mu1.7 element.

Project description:BackgroundThe spread of maize cultivation to the highlands of central Mexico was accompanied by substantial introgression from the endemic wild teosinte Zea mays ssp. mexicana, prompting the hypothesis that the transfer of beneficial variation facilitated local adaptation.MethodsWe used whole-genome sequence data to map regions of Zea mays ssp. mexicana introgression in three Mexican highland maize individuals. We generated a genetic linkage map and performed Quantitative Trait Locus mapping in an F2 population derived from a cross between lowland and highland maize individuals.ResultsIntrogression regions ranged in size from several hundred base pairs to Megabase-scale events. Gene density within introgression regions was comparable to the genome as a whole, and over 1,000 annotated genes were located within introgression events. Quantitative Trait Locus mapping identified a small number of loci linked to traits characteristic of Mexican highland maize.DiscussionAlthough there was no strong evidence to associate quantitative trait loci with regions of introgression, we nonetheless identified many Mexican highland alleles of introgressed origin that carry potentially functional sequence variants. The impact of introgression on stress tolerance and yield in the highland environment remains to be fully characterized.

Project description:Mutator is a powerful system for generating new mutants in maize. Mutator activity is attributable to a family of transposable, multicopy Mu elements, but none of the known elements is an autonomous (regulatory) element. This paper reports the discovery of Mu9, a 4942-base-pair Mu element that was cloned after it transposed into the Bronze-2 locus. Like other Mu elements, Mu9 has approximately 215-base-pair terminal inverted repeats and creates a 9-base-pair host sequence duplication upon insertion. A small gene family of elements that cross-hybridize to Mu9 has been found in all maize lines, and one of the other known Mu elements, Mu5, probably arose as a deletion of Mu9. Mu9 has several of the properties expected for the proposed regulator of Mutator activity. (i) The presence of Mu9 parallels the presence of Mutator activity in individuals from a line that genetically segregates for the Mu regulator. (ii) Lines that transmit Mutator to greater than 90% of their progeny have multiple copies of Mu9. (iii) Most maize lines that lack Mutator activity and that are not descended from Mutator lines lack the Mu9 element. (iv) Transcripts that hybridize to Mu9 are abundant in active Mutator lines, but they are absent from lines that have epigenetically lost Mutator activity. These correlations suggest that Mu9 is a candidate for the autonomous Mutator element.