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1. Targeted Insertion of the mPing Transposable Element

   Strother, Ashley E.; Diaz, Stephanie S.; Baker, Mary E.; and Hancock, C. Nathan (January 2018, Journal of the South Carolina Academy of Science)

   Class II DNA Transposable Elements (TEs) are moved from one location to another in the genome by the action of transposase proteins that bind to repeat sequences at the ends of the elements. Although the location TE insertion is mostly random, the addition of DNA binding domains to the transposase proteins has allowed for targeted insertion of some elements. In this study, the Gal4 binding domain was added to the transposase proteins, ORF1 and TPase, which mobilize the mPing element from rice. The Gal4:TPase construct was capable of increasing the number of mPing insertions into the Gal2 and Gal4 promoter sequences in yeast. While this confirms that mPing insertion preference can be manipulated, the target specificity is relatively low. Thus, the CRISPR/Cas9 system was tested for its ability to generate targeted insertion of mPing. A dCas9:TPase fusion protein had a low transposition rate suggesting that the addition of this large protein disrupts TPase function. Unfortunately, the use of a MS2 binding domain to localize the TPase to the MS2 hairpin containing gRNA failed to produce targeted insertion. Thus, our results suggest that the addition of small DNA binding domain to the N-terminal of TPase is the best strategy for targeted insertion of mPing. 

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2. Transposase expression, element abundance, element size, and DNA repair determine the mobility and heritability of PIF/Pong/Harbinger transposable elements

   https://doi.org/10.3389/fcell.2023.1184046  

   Redd, Priscilla S.; Payero, Lisette; Gilbert, David M.; Page, Clinton A.; King, Reese; McAssey, Edward V.; Bodie, Dalton; Diaz, Stephanie; Hancock, C. Nathan (June 2023, Frontiers in Cell and Developmental Biology)

   Introduction: Class II DNA transposable elements account for significant portions of eukaryotic genomes and contribute to genome evolution through their mobilization. To escape inactivating mutations and persist in the host genome over evolutionary time, these elements must be mobilized enough to result in additional copies. These elements utilize a “cut and paste” transposition mechanism that does not intrinsically include replication. However, elements such as the rice derived mPing element have been observed to increase in copy number over time. Methods: We used yeast transposition assays to test several parameters that could affect the excision and insertion of mPing and its related elements. This included development of novel strategies for measuring element insertion and sequencing insertion sites. Results: Increased transposase protein expression increased the mobilization frequency of a small (430 bp) element, while overexpression inhibition was observed for a larger (7,126 bp) element. Smaller element size increased both the frequency of excision and insertion of these elements. The effect of yeast ploidy on element excision, insertion, and copy number provided evidence that homology dependent repair allows for replicative transposition. These elements were found to preferentially insert into yeast rDNA repeat sequences. Discussion: Identifying the parameters that influence transposition of these elements will facilitate their use for gene discovery and genome editing. These insights in to the behavior of these elements also provide important clues into how class II transposable elements have shaped eukaryotic genomes. 

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3. Mobility of mPing and its associated elements is regulated by both internal and terminal sequences

   https://doi.org/10.1186/s13100-023-00289-3  

   Redd, Priscilla S.; Diaz, Stephanie; Weidner, David; Benjamin, Jazmine; Hancock, C. Nathan (February 2023, Mobile DNA)

   Abstract BackgroundDNA transposable elements are mobilized by a “cut and paste” mechanism catalyzed by the binding of one or more transposase proteins to terminal inverted repeats (TIRs) to form a transpositional complex. Study of the rice genome indicates that themPingelement has experienced a recent burst in transposition compared to the closely relatedPingandPongelements. A previously developed yeast transposition assay allowed us to probe the role of both internal and terminal sequences in the mobilization of these elements. ResultsWe observed thatmPingand a syntheticmPongelement have significantly higher transposition efficiency than the related autonomousPingandPongelements. Systematic mutation of the internal sequences of bothmPingandmPongidentified multiple regions that promote or inhibit transposition. Simultaneous alteration of single bases on bothmPingTIRs resulted in a significant reduction in transposition frequency, indicating that each base plays a role in efficient transposase binding. Testing chimericmPingandmPongelements verified the important role of both the TIRs and internal regulatory regions.Previous experiments showed that the G at position 16, adjacent to the 5′ TIR, allows mPingto have higher mobility. Alteration of the 16th and 17th base frommPing’s3′ end or replacement of the 3′ end withPong3′ sequences significantly increased transposition frequency. ConclusionsAs the transposase proteins were consistent throughout this study, we conclude that the observed transposition differences are due to the element sequences. The presence of sub-optimal internal regions and TIR bases supports a model in which transposable elements self-limit their activity to prevent host damage and detection by host regulatory mechanisms. Knowing the role of the TIRs, adjacent sub-TIRs, and internal regulatory sequences allows for the creation of hyperactive elements. 

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4. The Use of RelocaTE and Unassembled Short Reads to Produce High-Resolution Snapshots of Transposable Element Generated Diversity in Rice

   https://doi.org/10.1534/g3.112.005348  

   Robb, Sofia M; Lu, Lu; Valencia, Elizabeth; Burnette, James M; Okumoto, Yutaka; Wessler, Susan R; Stajich, Jason E (June 2013, G3 Genes|Genomes|Genetics)

   Abstract Transposable elements (TEs) are dynamic components of genomes that often vary in copy number among members of the same species. With the advent of next-generation sequencing TE insertion-site polymorphism can be examined at an unprecedented level of detail when combined with easy-to-use bioinformatics software. Here we report a new tool, RelocaTE, that rapidly identifies specific TE insertions that are either polymorphic or shared between a reference and unassembled next-generation sequencing reads. Furthermore, a novel companion tool, CharacTErizer, exploits the depth of coverage to classify genotypes of nonreference insertions as homozygous, heterozygous or, when analyzing an active TE family, as rare somatic insertion or excision events. It does this by comparing the numbers of RelocaTE aligned reads to reads that map to the same genomic position without the TE. Although RelocaTE and CharacTErizer can be used for any TE, they were developed to analyze the very active mPing element which is undergoing massive amplification in specific strains of Oryza sativa (rice). Three individuals of one of these strains, A123, were resequenced and analyzed for mPing insertion site polymorphisms. The majority of mPing insertions found (~97%) are not present in the reference, and two siblings from a self-crossed of this strain were found to share only ~90% of their insertions. Private insertions are primarily heterozygous but include both homozygous and predicted somatic insertions. The reliability of the predicted genotypes was validated by polymerase chain reaction. 

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5. Combined analysis of transposable elements and structural variation in maize genomes reveals genome contraction outpaces expansion

   https://doi.org/10.1371/journal.pgen.1011086  

   Munasinghe, Manisha; Read, Andrew; Stitzer, Michelle C.; Song, Baoxing; Menard, Claire C.; Ma, Kristy Yubo; Brandvain, Yaniv; Hirsch, Candice N.; Springer, Nathan (December 2023, PLOS Genetics)

   VITTE, Clémentine (Ed.)

   Structural differences between genomes are a major source of genetic variation that contributes to phenotypic differences. Transposable elements, mobile genetic sequences capable of increasing their copy number and propagating themselves within genomes, can generate structural variation. However, their repetitive nature makes it difficult to characterize fine-scale differences in their presence at specific positions, limiting our understanding of their impact on genome variation. Domesticated maize is a particularly good system for exploring the impact of transposable element proliferation as over 70% of the genome is annotated as transposable elements. High-quality transposable element annotations were recently generated forde novogenome assemblies of 26 diverse inbred maize lines. We generated base-pair resolved pairwise alignments between the B73 maize reference genome and the remaining 25 inbred maize line assemblies. From this data, we classified transposable elements as either shared or polymorphic in a given pairwise comparison. Our analysis uncovered substantial structural variation between lines, representing both simple and complex connections between TEs and structural variants. Putative insertions in SNP depleted regions, which represent recently diverged identity by state blocks, suggest some TE families may still be active. However, our analysis reveals that within these recently diverged genomic regions, deletions of transposable elements likely account for more structural variation events and base pairs than insertions. These deletions are often large structural variants containing multiple transposable elements. Combined, our results highlight how transposable elements contribute to structural variation and demonstrate that deletion events are a major contributor to genomic differences. 

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