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

Jupe, Florian; Rivkin, Angeline; Michael, Todd P.; Zander, Mark; Motley, S. Timothy; Sandoval, Justin P.; Slotkin, R. Keith; Chen, Huaming; Castanon, Rosa; Nery, Joseph R.; Ecker, Joseph R.

doi:10.1371/journal.pgen.1007819

Cited by 129 publications

(133 citation statements)

References 61 publications

(88 reference statements)

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“…sequencing (Jupe et al, 2019) and represents to our knowledge the only publicly available line with an insertion in the TPK3 coding region. Subsequently, we isolated homozygous tpk3-1 (SALK_049593) individuals by PCR and confirmed a T-DNA insertion in the first exon by sequencing ( Fig.…”

Section: Tpk3 Loss or Gain Of Function Does Not Affect Photosyntheticmentioning

confidence: 99%

Photosynthesis in Arabidopsis Is Unaffected by the Function of the Vacuolar K⁺ Channel TPK3

et al. 2019

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Photosynthesis is limited by the slow relaxation of nonphotochemical quenching, which primarily dissipates excess absorbed light energy as heat. Because the heat dissipation process is proportional to light-driven thylakoid lumen acidification, manipulating thylakoid ion and proton flux via transport proteins could improve photosynthesis. However, an important aspect of the current understanding of the thylakoid ion transportome is inaccurate. Using fluorescent protein fusions, we show that the Arabidopsis (Arabidopsis thaliana) two-pore K 1 channel TPK3, which had been reported to mediate thylakoid K 1 flux, localizes to the tonoplast, not the thylakoid. The localization of TPK3 outside of the thylakoids is further supported by the absence of TPK3 in isolated thylakoids as well as the inability of isolated chloroplasts to import TPK3 protein. In line with the subcellular localization of TPK3 in the vacuole, we observed that photosynthesis in the Arabidopsis null mutant tpk3-1, which carries a transfer DNA insertion in the first exon, remains unaffected. To gain a comprehensive understanding of how thylakoid ion flux impacts photosynthetic efficiency under dynamic growth light regimes, we performed long-term photosynthesis imaging of established and newly isolated transthylakoid K 1 -and Cl 2 -flux mutants. Our results underpin the importance of the thylakoid ion transport proteins potassium cation efflux antiporter KEA3 and voltage-dependent chloride channel VCCN1 and suggest that the activity of yet unknown K 1 channel(s), but not TPK3, is critical for optimal photosynthesis in dynamic light environments.Photosynthesis provides metabolic energy for nearly all life on earth. During this process, light is utilized for CO 2 fixation, growth and additional energy-dependent metabolic pathways. In oxygenic photosynthesis, light energy induces charge separations at two photosystems. At PSII, electrons are stripped from water molecules releasing protons into the lumen. These electrons move along the thylakoid electron transport chain toward PSI and finally reduce NADP 1 to NADPH. During electron transport, protons are translocated from the chloroplast stroma into the thylakoid lumen, generating a proton motive force (pmf) which drives the ATP synthase to produce ATP. The thylakoid pmf is comprised of two components, a pH gradient (DpH) and a membrane potential (Dc). In addition to providing the driving force for ATP synthesis, the luminal proton concentration has important regulatory functions. Above a certain proton concentration threshold, a photoprotective mechanism is activated that dissipates excess absorbed light energy as heat. This mechanism is called energy-dependent quenching (qE). qE involves

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Section: Tpk3 Loss or Gain Of Function Does Not Affect Photosyntheticmentioning

confidence: 99%

Photosynthesis in Arabidopsis Is Unaffected by the Function of the Vacuolar K⁺ Channel TPK3

et al. 2019

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“…Read-lengths are limited only by input DNA lengths, and validated reads as long as 2,272,580 bases have been reported [2]. Nanopore sequencing has been used for various applications, including genome sequencing of Arabidopsis and a wild tomato relative [3, 4], resolving complex T-DNA insertions [5], and disease resistance gene enrichment sequencing [6].…”

Section: Introductionmentioning

confidence: 99%

Genome assembly and characterization of a complex zfBED-NLR gene-containing disease resistance locus in Carolina Gold Select rice with Nanopore sequencing

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“…We explored the coverage of this locus in our MethylC-seq data (data not shown) and found a 12.6-kb deletion present in the aly1-2 mutant line encompassing the six genes AT4G22285 to AT4G22310 (gene annotations provided in Supplemental Figure 4A). Deletions can occur during the process of transgenesis, which was used to generate the aly1-2 line (Nacry et al, 1998;Jupe et al, 2019). We found that this deletion did not cause the loss of RdDM phenotype in aly1-2, as the deletion was not present in the aly1-1 mutant line (Supplemental Figure 4B), which displays decreased RdDM ( Figures 1A and 1C).…”

Section: Aly1 Functions In Te Silencingmentioning

confidence: 66%

The RNA Export Factor ALY1 Enables Genome-Wide RNA-Directed DNA Methylation

et al. 2019

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M.J.S.); 0000-0002-9634-6641 (A.D.M.); 0000-0001-9582-3533 (R.K.S.)RNA-directed DNA methylation (RdDM) is a set of mechanisms by which transcriptionally repressive DNA and histone methylation are targeted to viruses, transposable elements, and some transgenes. We identified an Arabidopsis (Arabidopsis thaliana) mutant in which all forms of RdDM are deficient, leading to transcriptional activation of some transposable elements and the inability to initiate transgene silencing. The corresponding gene, ALY1, encodes an RNA binding nuclear export protein. Arabidopsis ALY proteins function together to export many messenger RNAs (mRNAs), but we found that ALY1 is unique among this family for its ability to enable RdDM. Through the identification of ALY1 direct targets via RNA immunoprecipitation sequencing, coupled with mRNA sequencing of nuclear and cytoplasmic fractions, we identified mRNAs of known RdDM factors that fail to efficiently export from the nucleus in aly1 mutants. We found that loss of RdDM in aly1 is a result of deficient nuclear export of the ARGONAUTE6 mRNA and subsequent decreases in ARGONAUTE6 protein, a key effector of RdDM. One aly1 allele was more severe due to an additional loss of RNA Polymerase V function, which is also necessary for RdDM. Together, our data reconcile the broad role of ALY1 in mRNA export with the specific loss of RdDM through the activities of ARGONAUTE6 and RNA Polymerase V.

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

Cited by 129 publications

References 61 publications

Photosynthesis in Arabidopsis Is Unaffected by the Function of the Vacuolar K⁺ Channel TPK3

Photosynthesis in Arabidopsis Is Unaffected by the Function of the Vacuolar K⁺ Channel TPK3

Genome assembly and characterization of a complex zfBED-NLR gene-containing disease resistance locus in Carolina Gold Select rice with Nanopore sequencing

The RNA Export Factor ALY1 Enables Genome-Wide RNA-Directed DNA Methylation

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

Cited by 129 publications

References 61 publications

Photosynthesis in Arabidopsis Is Unaffected by the Function of the Vacuolar K+ Channel TPK3

Photosynthesis in Arabidopsis Is Unaffected by the Function of the Vacuolar K+ Channel TPK3

Genome assembly and characterization of a complex zfBED-NLR gene-containing disease resistance locus in Carolina Gold Select rice with Nanopore sequencing

The RNA Export Factor ALY1 Enables Genome-Wide RNA-Directed DNA Methylation

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Photosynthesis in Arabidopsis Is Unaffected by the Function of the Vacuolar K⁺ Channel TPK3

Photosynthesis in Arabidopsis Is Unaffected by the Function of the Vacuolar K⁺ Channel TPK3