Project description:Purpose: A-to-I RNA editing is critical for many cellular processes. The sites of A-I RNA editing can be identified through RNA-seq and matching the reads to the annotated database like RADAR. The goals of this study is to compare A-I RNA editing profile among wild type, ADAR2 overexpressing and ADAR2+SRSF9 overexpressing 293T cells to evaluate the influence of SRSF9 repressive action on A-I RNA editing Methods: A-I RNA editing profile and gene expression profiles were generated by deep sequencing from all the samples, using NEBNext® Ultra™ Directional RNA Library Prep Kit. The sequence reads that passed quality filters were analyzed for identifying the A-I RNA editing sites using RADAR Database Results: Upon overexpression of ADAR2, we found that 18,174 sites were differentially edited compared to control cells, of which 97.0% showed a significant increase in their editing levels as expected (P < 0.05, Fisher’s test). Furthermore, when we overexpressed both ADAR2 and SRSF9 together, we found that 6,994 sites were differentially edited compared to overexpression of the deaminase alone (P < 0.05, Fisher’s test). Importantly, the editing of 92.5% of these sites was down-regulated, consistent with the function of SRSF9 as a repressor of editing. Conclusions: Our study reports a detailed analysis of the effect of SRSF9 on A-I RNA editing of ADAR2-specific targets. We Conclude that this SRSF9 regulon is significantly enriched for brain-specific editing sites despite our unbiased approach.

Project description:Purpose: A-to-I RNA editing is critical for many cellular processes. The sites of A-I RNA editing can be identified through RNA-seq and matching the reads to the annotated database like RADAR. The goals of this study is to compare A-I RNA editing profile among wild type, ADAR2 overexpressing and ADAR2+SRSF9 overexpressing 293T cells to evaluate the influence of SRSF9 repressive action on A-I RNA editing Methods: A-I RNA editing profile and gene expression profiles were generated by deep sequencing from all the samples, using NEBNext® Ultra™ Directional RNA Library Prep Kit. The sequence reads that passed quality filters were analyzed for identifying the A-I RNA editing sites using RADAR Database Results: Upon overexpression of ADAR2, we found that 18,174 sites were differentially edited compared to control cells, of which 97.0% showed a significant increase in their editing levels as expected (P < 0.05, Fisher’s test). Furthermore, when we overexpressed both ADAR2 and SRSF9 together, we found that 6,994 sites were differentially edited compared to overexpression of the deaminase alone (P < 0.05, Fisher’s test). Importantly, the editing of 92.5% of these sites was down-regulated, consistent with the function of SRSF9 as a repressor of editing. Conclusions: Our study reports a detailed analysis of the effect of SRSF9 on A-I RNA editing of ADAR2-specific targets. We Conclude that this SRSF9 regulon is significantly enriched for brain-specific editing sites despite our unbiased approach.

Project description:Adenosine DeAminases acting on RNA (ADAR) catalyzes adenosine-to-inosine (A-to-I) conversion within RNA duplex structures. While A-to-I editing is often dynamically regulated in a spatial-temporal manner, the mechanisms underlying its tissue-selective restriction remain elusive. We have previously reported that transcripts of voltage-gated calcium channel CaV1.3 are subject to brain-selective A-to-I RNA editing by ADAR2. Here, we show that editing of CaV1.3 mRNA is dependent on a 40 bp RNA duplex formed between exon 41 and an evolutionarily conserved editing site complementary sequence (ECS) located within the preceding intron. Heterologous expression of a mouse minigene that contained the ECS, intermediate intronic sequence and exon 41 with ADAR2 yielded robust editing. Interestingly, editing of CaV1.3 was potently inhibited by serine/arginine-rich splicing factor 9 (SRSF9). Mechanistically, the inhibitory effect of SRSF9 required direct RNA interaction. Selective down-regulation of SRSF9 in neurons provides a basis for the neuron-specific editing of CaV1.3 transcripts.

Project description:Adenosine deaminases (ADARs) are RNA binding proteins that bind to double stranded RNA and convert adenosine to inosine. Editing creates multiple isoforms of neurotransmitter receptors, including AMPA-subtype Glutamate channels such as Gria2 that is edited to introduce a Q to R amino acid change. Adar2 knock out mice die of seizures shortly after birth, but if the Gria2 Q/R editing site is mutated to mimic the edited version then the animals are viable. We performed RNA-Seq on the frontal cortices of Adar2-/- Gria2R/R mice and their Adar2+/+ Gria2R/R littermates, quantifying overall gene expression, splicing, and A to I editing in a transcriptome-wide fashion. We found 56 editing sites whose level of editing was significantly diminished in the Adar2 deficient animals. The majority of Adar2 responsive editing sites were in the coding regions of genes. Interestingly, other than Adar2 expression, there were only two additional statistically significant differentially expressed genes, Flnb and Cdh13. There were also only three exons that showed statistically significant differences in expression levels between the two genotypes. This work illustrates that ADAR2 is important in site-specific changes of protein coding sequences but has only modest effects on gene expression or splicing in vivo. 6 ADAR2 Knock out frontal cortices and 6 litter mate control frontal cortices from male mice

Project description:Background: Adenosine deaminases that act on RNA (ADARs) bind to double-stranded and structured RNAs and deaminate adenosines to inosines. This A to I editing is widespread and required for normal life and development. Besides mRNAs and repetitive elements, ADARs can target miRNA precursors. Editing of miRNA precursors can affect processing efficiency and alter target specificity. Interestingly, ADARs can also influence miRNA abundance independent of RNA-editing. In mouse embryos where editing levels are low, ADAR2 was found to be the major ADAR protein that affects miRNA abundance. Here we extend our analysis to adult mouse brains where high editing levels are observed. Results: Using Illumina deep sequencing we compare the abundances of mature miRNAs and editing events within them, between wild-type and ADAR2 knockout mice in the adult mouse brain. Reproducible changes in abundance of specific miRNAs are observed in ADAR2 deficient mice. Most of these quantitative changes seem unrelated to A to I editing events. However, many A to G transitions in cDNAs prepared from mature miRNA sequences, reflecting A to I editing events in the RNA, are observed with frequencies reaching up to 80%. About half of these editing events are primarily caused by ADAR2 while a few miRNAs show increased editing in the absence of ADAR2, suggesting preferential editing by ADAR1. Moreover, novel, previously unknown editing events were identified in several miRNAs. In general 64% of all editing events are located within the seed region of mature miRNAs. In one of these cases retargeting of the edited miRNA could be verified in reporter assays. Also, altered processing efficiency upon editing near a processing site could be experimentally verified. Conclusions: ADAR2 can significantly influence the abundance of certain miRNAs in the brain. Only in a few cases changes in miRNA abundance can be explained by miRNA editing. Thus, ADAR2 binding to miRNA precursors, without editing them, may influence their processing and thereby abundance. ADAR1 and ADAR2 have both overlapping and distinct specificities for editing of miRNA editing sites. Over 60% of editing occurs in the seed region possibly changing target specificities for many edited miRNAs. Examination of the effect of ADAR2 on mature miRNA abundance and sequence in adult mouse brain.

Project description:Background: Adenosine deaminases that act on RNA (ADARs) bind to double-stranded and structured RNAs and deaminate adenosines to inosines. This A to I editing is widespread and required for normal life and development. Besides mRNAs and repetitive elements, ADARs can target miRNA precursors. Editing of miRNA precursors can affect processing efficiency and alter target specificity. Interestingly, ADARs can also influence miRNA abundance independent of RNA-editing. In mouse embryos where editing levels are low, ADAR2 was found to be the major ADAR protein that affects miRNA abundance. Here we extend our analysis to adult mouse brains where high editing levels are observed. Results: Using Illumina deep sequencing we compare the abundances of mature miRNAs and editing events within them, between wild-type and ADAR2 knockout mice in the adult mouse brain. Reproducible changes in abundance of specific miRNAs are observed in ADAR2 deficient mice. Most of these quantitative changes seem unrelated to A to I editing events. However, many A to G transitions in cDNAs prepared from mature miRNA sequences, reflecting A to I editing events in the RNA, are observed with frequencies reaching up to 80%. About half of these editing events are primarily caused by ADAR2 while a few miRNAs show increased editing in the absence of ADAR2, suggesting preferential editing by ADAR1. Moreover, novel, previously unknown editing events were identified in several miRNAs. In general 64% of all editing events are located within the seed region of mature miRNAs. In one of these cases retargeting of the edited miRNA could be verified in reporter assays. Also, altered processing efficiency upon editing near a processing site could be experimentally verified. Conclusions: ADAR2 can significantly influence the abundance of certain miRNAs in the brain. Only in a few cases changes in miRNA abundance can be explained by miRNA editing. Thus, ADAR2 binding to miRNA precursors, without editing them, may influence their processing and thereby abundance. ADAR1 and ADAR2 have both overlapping and distinct specificities for editing of miRNA editing sites. Over 60% of editing occurs in the seed region possibly changing target specificities for many edited miRNAs. Examination of the effect of ADAR2 on gene expression in mature mouse wildtype and ADAR2 knockout brain using AffymetrixM-BM-. GeneChipM-BM-. Whole Transcript (WT) Expression Arrays (Analysis by KFB Regensburg, Germany)

Project description:Adenosine deaminases (ADARs) are RNA binding proteins that bind to double stranded RNA and convert adenosine to inosine. Editing creates multiple isoforms of neurotransmitter receptors, including AMPA-subtype Glutamate channels such as Gria2 that is edited to introduce a Q to R amino acid change. Adar2 knock out mice die of seizures shortly after birth, but if the Gria2 Q/R editing site is mutated to mimic the edited version then the animals are viable. We performed RNA-Seq on the frontal cortices of Adar2-/- Gria2R/R mice and their Adar2+/+ Gria2R/R littermates, quantifying overall gene expression, splicing, and A to I editing in a transcriptome-wide fashion. We found 56 editing sites whose level of editing was significantly diminished in the Adar2 deficient animals. The majority of Adar2 responsive editing sites were in the coding regions of genes. Interestingly, other than Adar2 expression, there were only two additional statistically significant differentially expressed genes, Flnb and Cdh13. There were also only three exons that showed statistically significant differences in expression levels between the two genotypes. This work illustrates that ADAR2 is important in site-specific changes of protein coding sequences but has only modest effects on gene expression or splicing in vivo.

Project description:Purpose: Measure gene expression and RNA editing changes in Adar-WT and Adar2-KO MEFs Methods: Performed PolyA+ RNA-seq (single end, one sample each) of Adar2-WT and Adar2-KO MEFs Results: Observed changes in editing and gene expression of several genes Conclusion: Adar2 influences gene expression and editing of transcripts

Project description:Background: Adenosine deaminases that act on RNA (ADARs) bind to double-stranded and structured RNAs and deaminate adenosines to inosines. This A to I editing is widespread and required for normal life and development. Besides mRNAs and repetitive elements, ADARs can target miRNA precursors. Editing of miRNA precursors can affect processing efficiency and alter target specificity. Interestingly, ADARs can also influence miRNA abundance independent of RNA-editing. In mouse embryos where editing levels are low, ADAR2 was found to be the major ADAR protein that affects miRNA abundance. Here we extend our analysis to adult mouse brains where high editing levels are observed. Results: Using Illumina deep sequencing we compare the abundances of mature miRNAs and editing events within them, between wild-type and ADAR2 knockout mice in the adult mouse brain. Reproducible changes in abundance of specific miRNAs are observed in ADAR2 deficient mice. Most of these quantitative changes seem unrelated to A to I editing events. However, many A to G transitions in cDNAs prepared from mature miRNA sequences, reflecting A to I editing events in the RNA, are observed with frequencies reaching up to 80%. About half of these editing events are primarily caused by ADAR2 while a few miRNAs show increased editing in the absence of ADAR2, suggesting preferential editing by ADAR1. Moreover, novel, previously unknown editing events were identified in several miRNAs. In general 64% of all editing events are located within the seed region of mature miRNAs. In one of these cases retargeting of the edited miRNA could be verified in reporter assays. Also, altered processing efficiency upon editing near a processing site could be experimentally verified. Conclusions: ADAR2 can significantly influence the abundance of certain miRNAs in the brain. Only in a few cases changes in miRNA abundance can be explained by miRNA editing. Thus, ADAR2 binding to miRNA precursors, without editing them, may influence their processing and thereby abundance. ADAR1 and ADAR2 have both overlapping and distinct specificities for editing of miRNA editing sites. Over 60% of editing occurs in the seed region possibly changing target specificities for many edited miRNAs.

Project description:Background: Adenosine deaminases that act on RNA (ADARs) bind to double-stranded and structured RNAs and deaminate adenosines to inosines. This A to I editing is widespread and required for normal life and development. Besides mRNAs and repetitive elements, ADARs can target miRNA precursors. Editing of miRNA precursors can affect processing efficiency and alter target specificity. Interestingly, ADARs can also influence miRNA abundance independent of RNA-editing. In mouse embryos where editing levels are low, ADAR2 was found to be the major ADAR protein that affects miRNA abundance. Here we extend our analysis to adult mouse brains where high editing levels are observed. Results: Using Illumina deep sequencing we compare the abundances of mature miRNAs and editing events within them, between wild-type and ADAR2 knockout mice in the adult mouse brain. Reproducible changes in abundance of specific miRNAs are observed in ADAR2 deficient mice. Most of these quantitative changes seem unrelated to A to I editing events. However, many A to G transitions in cDNAs prepared from mature miRNA sequences, reflecting A to I editing events in the RNA, are observed with frequencies reaching up to 80%. About half of these editing events are primarily caused by ADAR2 while a few miRNAs show increased editing in the absence of ADAR2, suggesting preferential editing by ADAR1. Moreover, novel, previously unknown editing events were identified in several miRNAs. In general 64% of all editing events are located within the seed region of mature miRNAs. In one of these cases retargeting of the edited miRNA could be verified in reporter assays. Also, altered processing efficiency upon editing near a processing site could be experimentally verified. Conclusions: ADAR2 can significantly influence the abundance of certain miRNAs in the brain. Only in a few cases changes in miRNA abundance can be explained by miRNA editing. Thus, ADAR2 binding to miRNA precursors, without editing them, may influence their processing and thereby abundance. ADAR1 and ADAR2 have both overlapping and distinct specificities for editing of miRNA editing sites. Over 60% of editing occurs in the seed region possibly changing target specificities for many edited miRNAs.