Project description:Targeted suppression of siRNA biogenesis in Arabidopsis pollen

Project description:We used the RNaseIII-like protein RTL1 to suppress siRNA biogenesis specifically in Arabidopsis pollen, and found distinct siRNA subsets produced in the sperm and vegetative cell lineages via the RNA polymerase IV (Pol IV).

Project description:We used the RNaseIII-like protein RTL1 to suppress siRNA biogenesis specifically in Arabidopsis pollen, and found distinct siRNA subsets produced in the sperm and vegetative cell lineages via the RNA polymerase IV (Pol IV).

Project description:We used the RNaseIII-like protein RTL1 to suppress siRNA biogenesis specifically in Arabidopsis pollen, and found distinct siRNA subsets produced in the sperm and vegetative cell lineages via the RNA polymerase IV (Pol IV).

Project description:Targeted suppression of siRNA biogenesis in Arabidopsis pollen [bisulfite-seq]

Project description:Targeted suppression of siRNA biogenesis in Arabidopsis pollen [RNA-seq]

Project description:This SuperSeries is composed of the SubSeries listed below.

Project description:The mutagenic activity of transposable elements (TEs) is suppressed by epigenetic silencing and small interfering RNAs (siRNAs), especially in gametes that would transmit transposed elements to the next generation. In pollen from the model plant Arabidopsis, we show that TEs are unexpectedly reactivated and transpose, but only in the pollen vegetative nucleus, which accompanies the sperm cells but does not provide DNA to the fertilized zygote. TE expression coincides with down-regulation of the heterochromatin remodeler DECREASE IN DNA METHYLATION 1 and of most TE siRNAs. However, 21 nucleotide siRNA from Athila retrotransposons is generated in pollen and accumulates in sperm, indicating that siRNA from TEs activated in the vegetative nucleus can target silencing in gametes. We propose a conserved role for reprogramming in germline companion cells, such as nurse cells in insects and vegetative nuclei in plants, to reveal intact TEs in the genome and regulate their activity in gametes.

Project description:To assay siRNA movement in the pollen grain, we took advantage of the known behavior of 22nt siRNAs to target transcripts for cleavage and initiate secondary siRNA biogenesis. Previous research has demonstrated that when targeted by a 22nt microRNA, a transcript containing a truncated non-fluorescent ~400 bp version of GFP (trGFP) will produce GFP secondary siRNAs that can target a second copy of a functional full-length GFP mRNA in trans. Therefore, we created a ~400 bp non-fluorescent version of trGFP with a 5’ 22nt microRNA target site driven by the vegetative cell-specific KRP6 promoter and transformed this construct into a line homozygous for the sperm-specific functional full-length GFP driven by the MGH3 promoter. If cleaved by a 22nt microRNA, the vegetative cell-driven trGFP will be cleaved into secondary siRNAs, and if the RNA components of this system are mobile and transferred into the sperm cells, the sperm-specific fluorescence of GFP will be reduced. We used two versions of the microRNA target site, which included a mock target site that is not targeted by small RNAs, the target site of microRNA173 (which is a 22nt known to induce the production of secondary siRNAs). We demonstrate that when the 22nt microRNA173 target site is used in the vegetative cell transcript, a corresponding decrease in sperm cell fluorescence is observed. In the mock small RNA target site this reduction in fluorescence was not observed. To ensure the transitive silencing sperm cell transcripts is occurring via secondary small RNAs, we transferred this trGFP experiment into a dcl2/dcl4 mutant background that is defective in TE 21-22nt siRNA silencing. In dcl2/dcl4 double mutants with the trGFP system, we find that the GFP fluorescence of the mock target site transgene does not change, while the repression found in wild-type pollen with the 22nt microRNA173 target site is alleviated. The data for microRNA173 is particularly important, as DCL2 and DCL4 are not necessary for microRNA173 production, and therefore this demonstrates that specifically secondary siRNAs acting downstream of microRNA action are required to silence the sperm cell GFP. We further analyzed the production of sRNAs derived from GFP in pollen grains of transgenic lines expressing the 22nt miR173 or 22nt mock target sites inserted on the 5’ region of the trGFP transgene in both wt and dcl2/dcl4 backgrounds.

Project description:The mutagenic activity of transposable elements (TEs) is suppressed by epigenetic silencing and small interfering RNAs (siRNAs), especially in gametes that would transmit transposed elements to the next generation. In pollen from the model plant Arabidopsis, we show that TEs are unexpectedly reactivated and transpose, but only in the pollen vegetative nucleus, which accompanies the sperm cells but does not provide DNA to the fertilized zygote. TE expression coincides with down-regulation of the heterochromatin remodeler DECREASE IN DNA METHYLATION 1 and of most TE siRNAs. However, 21 nucleotide siRNA from Athila retrotransposons is generated in pollen and accumulates in sperm, indicating that siRNA from TEs activated in the vegetative nucleus can target silencing in gametes. We propose a conserved role for reprogramming in germline companion cells, such as nurse cells in insects and vegetative nuclei in plants, to reveal intact TEs in the genome and regulate their activity in gametes. Mature pollen was collected from Columbia reference strain plants by vacuum filtration (Johnson-Brousseau and McCormick, 2004). DNA and RNA were isolated from a ddm1-2 plant in the Columbia reference background. Small RNAs of 19–28 nt were size selected by denaturing 15% PAGE, and cloned as in Brennecke et al. (2007). Additional details regarding the cloning of small RNAs are found in the Supplemental Data. The small RNA libraries were sequenced on Illumina 1G sequencer. The total number of sequences perfectly matching the Arabidopsis genome were as follows: WT inflorescence, 4,158,848 (2,286,133 unique); WT pollen, 1,034,665 (437,984 unique); ddm1 inflorescence, 4,098,772 (1,637,771 unique); and WT sperm, 760,651 (429,972 unique).