Your search keyword '"Inosine genetics"' showing total 264 results

1. Dimerization of ADAR1 modulates site-specificity of RNA editing.

Author

Mboukou A, Rajendra V, Messmer S, Mandl TC, Catala M, Tisné C, Jantsch MF, and Barraud P

Subjects

Humans, RNA, Double-Stranded metabolism, RNA, Double-Stranded genetics, Adenosine metabolism, Inosine metabolism, Inosine genetics, Models, Molecular, Binding Sites, Protein Domains, Dimerization, Adenosine Deaminase metabolism, Adenosine Deaminase genetics, Adenosine Deaminase chemistry, RNA Editing, RNA-Binding Proteins metabolism, RNA-Binding Proteins genetics, RNA-Binding Proteins chemistry, Protein Multimerization

Abstract

Adenosine-to-inosine editing is catalyzed by adenosine deaminases acting on RNA (ADARs) in double-stranded RNA (dsRNA) regions. Although three ADARs exist in mammals, ADAR1 is responsible for the vast majority of the editing events and acts on thousands of sites in the human transcriptome. ADAR1 has been proposed to form a stable homodimer and dimerization is suggested to be important for editing activity. In the absence of a structural basis for the dimerization of ADAR1, and without a way to prevent dimer formation, the effect of dimerization on enzyme activity or site specificity has remained elusive. Here, we report on the structural analysis of the third double-stranded RNA-binding domain of ADAR1 (dsRBD3), which reveals stable dimer formation through a large inter-domain interface. Exploiting these structural insights, we engineered an interface-mutant disrupting ADAR1-dsRBD3 dimerization. Notably, dimerization disruption did not abrogate ADAR1 editing activity but intricately affected editing efficiency at selected sites. This suggests a complex role for dimerization in the selection of editing sites by ADARs, and makes dimerization a potential target for modulating ADAR1 editing activity., Competing Interests: Competing interests: The authors declare no competing interests., (© 2024. The Author(s).)

Published

2024

2. A-to-I RNA editing and hematopoiesis.

Author

Liang Z, Walkley CR, and Heraud-Farlow JE

Subjects

Animals, Humans, Mice, Immunity, Innate genetics, RNA Editing, Hematopoiesis genetics, Adenosine Deaminase genetics, Adenosine Deaminase metabolism, Adenosine metabolism, Adenosine genetics, Inosine metabolism, Inosine genetics, RNA-Binding Proteins genetics, RNA-Binding Proteins metabolism

Abstract

Adenosine-to-inosine (A-to-I) RNA editing plays essential roles in modulating normal development and homeostasis. This process is catalyzed by adenosine deaminase acting on RNA (ADAR) family proteins. The most well-understood biological processes modulated by A-to-I editing are innate immunity and neurological development, attributed to ADAR1 and ADAR2, respectively. A-to-I editing by ADAR1 is also critical in regulating hematopoiesis. This review will focus on the role of A-to-I RNA editing and ADAR enzymes, particularly ADAR1, during normal hematopoiesis in humans and mice. Furthermore, we will discuss Adar1 mouse models that have been developed to understand the contribution of ADAR1 to hematopoiesis and its role in innate immune pathways., Competing Interests: Conflict of Interest Disclosure The authors do not have any conflicts of interest to declare in relation to this work., (Copyright © 2024 International Society for Experimental Hematology. Published by Elsevier Inc. All rights reserved.)

Published

2024

3. LoDEI: a robust and sensitive tool to detect transcriptome-wide differential A-to-I editing in RNA-seq data.

Author

Torkler P, Sauer M, Schwartz U, Corbacioglu S, Sommer G, and Heise T

Subjects

Humans, Inosine metabolism, Inosine genetics, Sequence Analysis, RNA methods, N-Myc Proto-Oncogene Protein genetics, N-Myc Proto-Oncogene Protein metabolism, RNA Editing, Adenosine metabolism, Adenosine analogs & derivatives, Adenosine genetics, Transcriptome genetics, RNA-Seq methods, Adenosine Deaminase genetics, Adenosine Deaminase metabolism

Abstract

RNA editing is a highly conserved process. Adenosine deaminase acting on RNA (ADAR) mediated deamination of adenosine (A-to-I editing) is associated with human disease and immune checkpoint control. Functional implications of A-to-I editing are currently of broad interest to academic and industrial research as underscored by the fast-growing number of clinical studies applying base editors as therapeutic tools. Analyzing the dynamics of A-to-I editing, in a biological or therapeutic context, requires the sensitive detection of differential A-to-I editing, a currently unmet need. We introduce the local differential editing index (LoDEI) to detect differential A-to-I editing in RNA-seq datasets using a sliding-window approach coupled with an empirical q value calculation that detects more A-to-I editing sites at the same false-discovery rate compared to existing methods. LoDEI is validated on known and novel datasets revealing that the oncogene MYCN increases and that a specific small non-coding RNA reduces A-to-I editing., (© 2024. The Author(s).)

Published

2024

4. Dynamics of diversified A-to-I editing in Streptococcus pyogenes is governed by changes in mRNA stability.

Author

Wulff TF, Hahnke K, Lécrivain AL, Schmidt K, Ahmed-Begrich R, Finstermeier K, and Charpentier E

Subjects

Bacterial Proteins genetics, Bacterial Proteins metabolism, RNA, Bacterial metabolism, RNA, Bacterial genetics, Oxidative Stress genetics, Streptococcus pyogenes genetics, RNA Stability genetics, RNA Editing, RNA, Messenger genetics, RNA, Messenger metabolism, Adenosine metabolism, Adenosine genetics, Adenosine analogs & derivatives, Inosine metabolism, Inosine genetics, RNA, Transfer metabolism, RNA, Transfer genetics

Abstract

Adenosine-to-inosine (A-to-I) RNA editing plays an important role in the post-transcriptional regulation of eukaryotic cell physiology. However, our understanding of the occurrence, function and regulation of A-to-I editing in bacteria remains limited. Bacterial mRNA editing is catalysed by the deaminase TadA, which was originally described to modify a single tRNA in Escherichia coli. Intriguingly, several bacterial species appear to perform A-to-I editing on more than one tRNA. Here, we provide evidence that in the human pathogen Streptococcus pyogenes, tRNA editing has expanded to an additional tRNA substrate. Using RNA sequencing, we identified more than 27 editing sites in the transcriptome of S. pyogenes SF370 and demonstrate that the adaptation of S. pyogenes TadA to a second tRNA substrate has also diversified the sequence context and recoding scope of mRNA editing. Based on the observation that editing is dynamically regulated in response to several infection-relevant stimuli, such as oxidative stress, we further investigated the underlying determinants of editing dynamics and identified mRNA stability as a key modulator of A-to-I editing. Overall, our findings reveal the presence and diversification of A-to-I editing in S. pyogenes and provide novel insights into the plasticity of the editome and its regulation in bacteria., (© The Author(s) 2024. Published by Oxford University Press on behalf of Nucleic Acids Research.)

Published

2024

5. Programmed RNA editing with an evolved bacterial adenosine deaminase.

Author

Yan H and Tang W

Subjects

Humans, Open Reading Frames, Interferon Regulatory Factors genetics, Interferon Regulatory Factors metabolism, Adenosine analogs & derivatives, Adenosine metabolism, Adenosine chemistry, Inosine metabolism, Inosine genetics, CRISPR-Cas Systems, HEK293 Cells, Adenosine Deaminase metabolism, Adenosine Deaminase genetics, RNA Editing, Escherichia coli genetics, Escherichia coli metabolism

Abstract

Programmed RNA editing presents an attractive therapeutic strategy for genetic disease. In this study, we developed bacterial deaminase-enabled recoding of RNA (DECOR), which employs an evolved Escherichia coli transfer RNA adenosine deaminase, TadA8e, to deposit adenosine-to-inosine editing to CRISPR-specified sites in the human transcriptome. DECOR functions in a variety of cell types, including human lung fibroblasts, and delivers on-target activity similar to ADAR-overexpressing RNA-editing platforms with 88% lower off-target effects. High-fidelity DECOR further reduces off-target effects to basal level. We demonstrate the clinical potential of DECOR by targeting Van der Woude syndrome-causing interferon regulatory factor 6 (IRF6) insufficiency. DECOR-mediated RNA editing removes a pathogenic upstream open reading frame (uORF) from the 5' untranslated region of IRF6 and rescues primary ORF expression from 12.3% to 36.5%, relative to healthy transcripts. DECOR expands the current portfolio of effector proteins and opens new territory in programmed RNA editing., (© 2024. The Author(s), under exclusive licence to Springer Nature America, Inc.)

Published

2024

6. A highly conserved A-to-I RNA editing event within the glutamate-gated chloride channel GluClα is necessary for olfactory-based behaviors in Drosophila .

Author

Zak H, Rozenfeld E, Levi M, Deng P, Gorelick D, Pozeilov H, Israel S, Paas Y, Paas Y, Li JB, Parnas M, and Shohat-Ophir G

Subjects

Animals, Drosophila Proteins genetics, Drosophila Proteins metabolism, Smell physiology, Smell genetics, Behavior, Animal, Drosophila melanogaster genetics, Drosophila melanogaster physiology, Inosine metabolism, Inosine genetics, Odorants, Adenosine metabolism, Drosophila genetics, RNA Editing, Chloride Channels metabolism, Chloride Channels genetics

Abstract

A-to-I RNA editing is a cellular mechanism that generates transcriptomic and proteomic diversity, which is essential for neuronal and immune functions. It involves the conversion of specific adenosines in RNA molecules to inosines, which are recognized as guanosines by cellular machinery. Despite the vast number of editing sites observed across the animal kingdom, pinpointing critical sites and understanding their in vivo functions remains challenging. Here, we study the function of an evolutionary conserved editing site in Drosophila , located in glutamate-gated chloride channel ( GluCl α). Our findings reveal that flies lacking editing at this site exhibit reduced olfactory responses to odors and impaired pheromone-dependent social interactions. Moreover, we demonstrate that editing of this site is crucial for the proper processing of olfactory information in projection neurons. Our results highlight the value of using evolutionary conservation as a criterion for identifying editing events with potential functional significance and paves the way for elucidating the intricate link between RNA modification, neuronal physiology, and behavior.

Published

2024

7. Inflammation primes the murine kidney for recovery by activating AZIN1 adenosine-to-inosine editing.

Author

Heruye SH, Myslinski J, Zeng C, Zollman A, Makino S, Nanamatsu A, Mir Q, Janga SC, Doud EH, Eadon MT, Maier B, Hamada M, Tran TM, Dagher PC, and Hato T

Subjects

Animals, Mice, Humans, Kidney metabolism, Kidney pathology, Acute Kidney Injury metabolism, Acute Kidney Injury genetics, Acute Kidney Injury pathology, Endotoxemia metabolism, Endotoxemia genetics, Endotoxemia pathology, Inflammation metabolism, Inflammation genetics, Inflammation pathology, Adenosine Deaminase metabolism, Adenosine Deaminase genetics, Carrier Proteins metabolism, Carrier Proteins genetics, Male, Inosine metabolism, Inosine genetics, RNA Editing, Adenosine metabolism, Adenosine genetics

Abstract

The progression of kidney disease varies among individuals, but a general methodology to quantify disease timelines is lacking. Particularly challenging is the task of determining the potential for recovery from acute kidney injury following various insults. Here, we report that quantitation of post-transcriptional adenosine-to-inosine (A-to-I) RNA editing offers a distinct genome-wide signature, enabling the delineation of disease trajectories in the kidney. A well-defined murine model of endotoxemia permitted the identification of the origin and extent of A-to-I editing, along with temporally discrete signatures of double-stranded RNA stress and adenosine deaminase isoform switching. We found that A-to-I editing of antizyme inhibitor 1 (AZIN1), a positive regulator of polyamine biosynthesis, serves as a particularly useful temporal landmark during endotoxemia. Our data indicate that AZIN1 A-to-I editing, triggered by preceding inflammation, primes the kidney and activates endogenous recovery mechanisms. By comparing genetically modified human cell lines and mice locked in either A-to-I-edited or uneditable states, we uncovered that AZIN1 A-to-I editing not only enhances polyamine biosynthesis but also engages glycolysis and nicotinamide biosynthesis to drive the recovery phenotype. Our findings implicate that quantifying AZIN1 A-to-I editing could potentially identify individuals who have transitioned to an endogenous recovery phase. This phase would reflect their past inflammation and indicate their potential for future recovery.

Published

2024

8. Narrowing down the candidates of beneficial A-to-I RNA editing by comparing the recoding sites with uneditable counterparts.

Author

Zhao T, Ma L, Xu S, Cai W, Li H, and Duan Y

Subjects

Animals, Drosophila melanogaster genetics, Drosophila melanogaster metabolism, RNA Editing genetics, Inosine genetics, Codon, Adenosine Deaminase genetics, Adenosine Deaminase metabolism, RNA genetics, Drosophila Proteins genetics

Abstract

Adar-mediated adenosine-to-inosine (A-to-I) RNA editing mainly occurs in nucleus and diversifies the transcriptome in a flexible manner. It has been a challenging task to identify beneficial editing sites from the sea of total editing events. The functional Ser>Gly auto-recoding site in insect Adar gene has uneditable Ser codons in ancestral nodes, indicating the selective advantage to having an editable status. Here, we extended this case study to more metazoan species, and also looked for all Drosophila recoding events with potential uneditable synonymous codons. Interestingly, in D. melanogaster , the abundant nonsynonymous editing is enriched in the codons that have uneditable counterparts, but the Adar Ser>Gly case suggests that the editable orthologous codons in other species are not necessarily edited. The use of editable versus ancestral uneditable codon is a smart way to infer the selective advantage of RNA editing, and priority might be given to these editing sites for functional studies due to the feasibility to construct an uneditable allele. Our study proposes an idea to narrow down the candidates of beneficial recoding sites. Meanwhile, we stress that the matched transcriptomes are needed to verify the conservation of editing events during evolution.

Published

2024

9. Conserved A-to-I RNA editing with non-conserved recoding expands the candidates of functional editing sites.

Author

Duan Y, Ma L, Zhao T, Liu J, Zheng C, Song F, Tian L, Cai W, and Li H

Subjects

Animals, Drosophila melanogaster genetics, Drosophila melanogaster metabolism, Evolution, Molecular, Drosophila Proteins genetics, Drosophila Proteins metabolism, RNA Editing, Inosine metabolism, Inosine genetics, Drosophila genetics, Drosophila metabolism, Adenosine metabolism, Adenosine genetics

Abstract

Adenosine-to-inosine (A-to-I) RNA editing recodes the genome and confers flexibility for the organisms to adapt to the environment. It is believed that RNA recoding sites are well suited for facilitating adaptive evolution by increasing the proteomic diversity in a temporal-spatial manner. The function and essentiality of a few conserved recoding sites are recognized. However, the experimentally discovered functional sites only make up a small corner of the total sites, and there is still the need to expand the repertoire of such functional sites with bioinformatic approaches. In this study, we define a new category of RNA editing sites termed 'conserved editing with non-conserved recoding' and systematically identify such sites in Drosophila editomes, figuring out their selection pressure and signals of adaptation at inter-species and intra-species levels. Surprisingly, conserved editing sites with non-conserved recoding are not suppressed and are even slightly overrepresented in Drosophila . DNA mutations leading to such cases are also favoured during evolution, suggesting that the function of those recoding events in different species might be diverged, specialized, and maintained. Finally, structural prediction suggests that such recoding in potassium channel Shab might increase ion permeability and compensate the effect of low temperature. In conclusion, conserved editing with non-conserved recoding might be functional as well. Our study provides novel aspects in considering the adaptive evolution of RNA editing sites and meanwhile expands the candidates of functional recoding sites for future validation.

Published

2024

10. Adaptive evolution of A-to-I auto-editing site in Adar of eusocial insects.

Author

Zheng C, Liu J, and Duan Y

Subjects

Animals, Phylogeny, Insecta genetics, Hymenoptera genetics, Transcriptome, Genome, Insect, RNA Editing, Evolution, Molecular, Inosine metabolism, Inosine genetics, Adenosine metabolism, Adenosine genetics, Adenosine Deaminase genetics, Adenosine Deaminase metabolism

Abstract

Background: Adenosine-to-inosine (A-to-I) RNA editing is a co-/post-transcriptional modification introducing A-to-G variations in RNAs. There is extensive discussion on whether the flexibility of RNA editing exerts a proteomic diversification role, or it just acts like hardwired mutations to correct the genomic allele. Eusocial insects evolved the ability to generate phenotypically differentiated individuals with the same genome, indicating the involvement of epigenetic/transcriptomic regulation., Methods: We obtained the genomes of 104 Hymenoptera insects and the transcriptomes of representative species. Comparative genomic analysis was performed to parse the evolutionary trajectory of a regulatory Ile > Met auto-recoding site in Adar gene., Results: At genome level, the pre-editing Ile codon is conserved across a node containing all eusocial hymenopterans. At RNA level, the editing events are confirmed in representative species and shows considerable condition-specificity. Compared to random expectation, the editable Ile codon avoids genomic substitutions to Met or to uneditable Ile codons, but does not avoid mutations to other unrelated amino acids., Conclusions: The flexibility of Adar auto-recoding site in Hymenoptera is selectively maintained, supporting the flexible RNA editing hypothesis. We proposed a new angle to view the adaptation of RNA editing, providing another layer to explain the great phenotypical plasticity of eusocial insects., (© 2024. The Author(s).)

Published

2024

11. Learning from the Codon Table: Convergent Recoding Provides Novel Understanding on the Evolution of A-to-I RNA Editing.

Author

Ma L, Zheng C, Liu J, Song F, Tian L, Cai W, Li H, and Duan Y

Subjects

Animals, Selection, Genetic, Humans, Drosophila genetics, RNA Editing genetics, Evolution, Molecular, Inosine genetics, Adenosine genetics, Adenosine metabolism, Phylogeny, Codon genetics

Abstract

Adenosine-to-inosine (A-to-I) RNA editing recodes the genetic information. Apart from diversifying the proteome, another tempting advantage of RNA recoding is to correct deleterious DNA mutation and restore ancestral allele. Solid evidences for beneficial restorative editing are very rare in animals. By searching for "convergent recoding" under a phylogenetic context, we proposed this term for judging the potential restorative functions of particular editing site. For the well-known mammalian Gln>Arg (Q>R) recoding site, its ancestral state in vertebrate genomes was the pre-editing Gln, and all 470 available mammalian genomes strictly avoid other three equivalent ways to achieve Arg in protein. The absence of convergent recoding from His>Arg, or synonymous mutations on Gln codons, could be attributed to the strong maintenance on editing motif and structure, but the absence of direct A-to-G mutation is extremely unexpected. With similar ideas, we found cases of convergent recoding in Drosophila genus, reducing the possibility of their restorative function. In summary, we defined an interesting scenario of convergent recoding, the occurrence of which could be used as preliminary judgements for whether a recoding site has a sole restorative role. Our work provides novel insights to the natural selection and evolution of RNA editing., (© 2024. The Author(s), under exclusive licence to Springer Science+Business Media, LLC, part of Springer Nature.)

Published

2024

12. Reovirus infection induces transcriptome-wide unique A-to-I editing changes in the murine fibroblasts.

Author

Tariq A and Piontkivska H

Subjects

Animals, Mice, Adenosine metabolism, Adenosine genetics, Reoviridae Infections virology, Reoviridae Infections genetics, Host-Pathogen Interactions, RNA-Binding Proteins genetics, RNA-Binding Proteins metabolism, Reoviridae genetics, Reoviridae physiology, Fibroblasts virology, Fibroblasts metabolism, Transcriptome, RNA Editing, Inosine metabolism, Inosine genetics, Adenosine Deaminase genetics, Adenosine Deaminase metabolism

Abstract

The conversion of Adenosine (A) to Inosine (I), by Adenosine Deaminases Acting on RNA or ADARs, is an essential post-transcriptional modification that contributes to proteome diversity and regulation in metazoans including humans. In addition to its transcriptome-regulating role, ADARs also play a major part in immune response to viral infection, where an interferon response activates interferon-stimulated genes, such as ADARp150, in turn dynamically regulating host-virus interactions. A previous report has shown that infection from reoviruses, despite strong activation of ADARp150, does not influence the editing of some of the major known editing targets, while likely editing others, suggesting a potentially nuanced editing pattern that may depend on different factors. However, the results were based on a handful of selected editing sites and did not cover the entire transcriptome. Thus, to determine whether and how reovirus infection specifically affects host ADAR editing patterns, we analyzed a publicly available deep-sequenced RNA-seq dataset, from murine fibroblasts infected with wild-type and mutant reovirus strains that allowed us to examine changes in editing patterns on a transcriptome-wide scale. To the best of our knowledge, this is the first transcriptome-wide report on host editing changes after reovirus infection. Our results demonstrate that reovirus infection induces unique nuanced editing changes in the host, including introducing sites uniquely edited in infected samples. Genes with edited sites are overrepresented in pathways related to immune regulation, cellular signaling, metabolism, and growth. Moreover, a shift in editing targets has also been observed, where the same genes are edited in infection and control conditions but at different sites, or where the editing rate is increased for some and decreased for other differential targets, supporting the hypothesis of dynamic and condition-specific editing by ADARs., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 The Authors. Published by Elsevier B.V. All rights reserved.)

Published

2024

13. Bioinformatics for Inosine: Tools and Approaches to Trace This Elusive RNA Modification.

Author

Bortoletto E and Rosani U

Subjects

Humans, Animals, RNA-Binding Proteins metabolism, RNA-Binding Proteins genetics, Inosine metabolism, Inosine genetics, RNA Editing, Computational Biology methods, Adenosine Deaminase metabolism, Adenosine Deaminase genetics

Abstract

Inosine is a nucleotide resulting from the deamination of adenosine in RNA. This chemical modification process, known as RNA editing, is typically mediated by a family of double-stranded RNA binding proteins named Adenosine Deaminase Acting on dsRNA (ADAR). While the presence of ADAR orthologs has been traced throughout the evolution of metazoans, the existence and extension of RNA editing have been characterized in a more limited number of animals so far. Undoubtedly, ADAR-mediated RNA editing plays a vital role in physiology, organismal development and disease, making the understanding of the evolutionary conservation of this phenomenon pivotal to a deep characterization of relevant biological processes. However, the lack of direct high-throughput methods to reveal RNA modifications at single nucleotide resolution limited an extended investigation of RNA editing. Nowadays, these methods have been developed, and appropriate bioinformatic pipelines are required to fully exploit this data, which can complement existing approaches to detect ADAR editing. Here, we review the current literature on the "bioinformatics for inosine" subject and we discuss future research avenues in the field.

Published

2024

14. Revealing Differential RNA Editing Specificity of Human ADAR1 and ADAR2 in Schizosaccharomyces pombe .

Author

Zhang N, Chen P, Cui Z, Zhou X, Hao C, Xie B, Hao P, Ye BC, Li X, and Jing X

Subjects

Humans, Substrate Specificity, Schizosaccharomyces pombe Proteins genetics, Schizosaccharomyces pombe Proteins metabolism, Adenosine metabolism, Adenosine genetics, Inosine genetics, Inosine metabolism, Schizosaccharomyces genetics, Adenosine Deaminase genetics, Adenosine Deaminase metabolism, RNA Editing genetics, RNA-Binding Proteins genetics, RNA-Binding Proteins metabolism

Abstract

Adenosine-to-inosine (A-to-I) RNA editing is an important post-transcriptional modification mediated by the adenosine deaminases acting on RNA (ADAR) family of enzymes, expanding the transcriptome by altering selected nucleotides A to I in RNA molecules. Recently, A-to-I editing has been explored for correcting disease-causing mutations in RNA using therapeutic guide oligonucleotides to direct ADAR editing at specific sites. Humans have two active ADARs whose preferences and specificities are not well understood. To investigate their substrate specificity, we introduced hADAR1 and hADAR2, respectively, into Schizosaccharomyces pombe ( S. pombe ), which lacks endogenous ADARs, and evaluated their editing activities in vivo. Using transcriptome sequencing of S. pombe cultured at optimal growth temperature (30 °C), we identified 483 A-to-I high-confident editing sites for hADAR1 and 404 for hADAR2, compared with the non-editing wild-type control strain. However, these sites were mostly divergent between hADAR1 and hADAR2-expressing strains, sharing 33 common sites that are less than 9% for each strain. Their differential specificity for substrates was attributed to their differential preference for neighboring sequences of editing sites. We found that at the -3-position relative to the editing site, hADAR1 exhibits a tendency toward T, whereas hADAR2 leans toward A. Additionally, when varying the growth temperature for hADAR1- and hADAR2-expressing strains, we observed increased editing sites for them at both 20 and 35 °C, compared with them growing at 30 °C. However, we did not observe a significant shift in hADAR1 and hADAR2's preference for neighboring sequences across three temperatures. The vast changes in RNA editing sites at lower and higher temperatures were also observed for hADAR2 previously in budding yeast, which was likely due to the influence of RNA folding at these different temperatures, among many other factors. We noticed examples of longer lengths of dsRNA around the editing sites that induced editing at 20 or 35 °C but were absent at the other two temperature conditions. We found genes' functions can be greatly affected by editing of their transcripts, for which over 50% of RNA editing sites for both hADAR1 and hADAR2 in S. pombe were in coding sequences (CDS), with more than 60% of them resulting in amino acid changes in protein products. This study revealed the extensive differences in substrate selectivity between the two active human ADARS, i.e., ADAR1 and ADAR2, and provided novel insight when utilizing the two different enzymes for in vivo treatment of human genetic diseases using the RNA editing approach.

Published

2024

15. ADAR-Mediated A>I(G) RNA Editing in the Genotoxic Drug Response of Breast Cancer.

Author

Bernal YA, Durán E, Solar I, Sagredo EA, and Armisén R

Subjects

Humans, Female, Adenosine metabolism, Drug Resistance, Neoplasm genetics, Inosine metabolism, Inosine genetics, Animals, Guanosine metabolism, DNA Damage, RNA Editing, Adenosine Deaminase genetics, Adenosine Deaminase metabolism, Breast Neoplasms genetics, Breast Neoplasms drug therapy, RNA-Binding Proteins genetics, RNA-Binding Proteins metabolism

Abstract

Epitranscriptomics is a field that delves into post-transcriptional changes. Among these modifications, the conversion of adenosine to inosine, traduced as guanosine (A>I(G)), is one of the known RNA-editing mechanisms, catalyzed by ADARs. This type of RNA editing is the most common type of editing in mammals and contributes to biological diversity. Disruption in the A>I(G) RNA-editing balance has been linked to diseases, including several types of cancer. Drug resistance in patients with cancer represents a significant public health concern, contributing to increased mortality rates resulting from therapy non-responsiveness and disease progression, representing the greatest challenge for researchers in this field. The A>I(G) RNA editing is involved in several mechanisms over the immunotherapy and genotoxic drug response and drug resistance. This review investigates the relationship between ADAR1 and specific A>I(G) RNA-edited sites, focusing particularly on breast cancer, and the impact of these sites on DNA damage repair and the immune response over anti-cancer therapy. We address the underlying mechanisms, bioinformatics, and in vitro strategies for the identification and validation of A>I(G) RNA-edited sites. We gathered databases related to A>I(G) RNA editing and cancer and discussed the potential clinical and research implications of understanding A>I(G) RNA-editing patterns. Understanding the intricate role of ADAR1-mediated A>I(G) RNA editing in breast cancer holds significant promise for the development of personalized treatment approaches tailored to individual patients' A>I(G) RNA-editing profiles.

Published

2024

16. Detecting haplotype-specific transcript variation in long reads with FLAIR2.

Author

Tang AD, Felton C, Hrabeta-Robinson E, Volden R, Vollmers C, and Brooks AN

Subjects

Humans, Cell Line, Tumor, Polymorphism, Single Nucleotide, Adenosine Deaminase genetics, Adenosine Deaminase metabolism, RNA-Binding Proteins genetics, RNA-Binding Proteins metabolism, Lung Neoplasms genetics, RNA Splicing, Inosine metabolism, Inosine genetics, Sequence Analysis, RNA, Adenocarcinoma of Lung genetics, RNA Editing, Software, Haplotypes

Abstract

Background: RNA-seq has brought forth significant discoveries regarding aberrations in RNA processing, implicating these RNA variants in a variety of diseases. Aberrant splicing and single nucleotide variants (SNVs) in RNA have been demonstrated to alter transcript stability, localization, and function. In particular, the upregulation of ADAR, an enzyme that mediates adenosine-to-inosine editing, has been previously linked to an increase in the invasiveness of lung adenocarcinoma cells and associated with splicing regulation. Despite the functional importance of studying splicing and SNVs, the use of short-read RNA-seq has limited the community's ability to interrogate both forms of RNA variation simultaneously., Results: We employ long-read sequencing technology to obtain full-length transcript sequences, elucidating cis-effects of variants on splicing changes at a single molecule level. We develop a computational workflow that augments FLAIR, a tool that calls isoform models expressed in long-read data, to integrate RNA variant calls with the associated isoforms that bear them. We generate nanopore data with high sequence accuracy from H1975 lung adenocarcinoma cells with and without knockdown of ADAR. We apply our workflow to identify key inosine isoform associations to help clarify the prominence of ADAR in tumorigenesis., Conclusions: Ultimately, we find that a long-read approach provides valuable insight toward characterizing the relationship between RNA variants and splicing patterns., (© 2024. The Author(s).)

Published

2024

17. A-to-I Editing Is Subtype-Specific in Non-Hodgkin Lymphomas.

Author

Chen C and Bundschuh R

Subjects

Adenosine genetics, Inosine genetics, Sequence Analysis, RNA, Gene Expression, Gene Expression Profiling, Multigene Family, Lymphoma, Non-Hodgkin genetics, RNA Editing

Abstract

Cancer is a complex and heterogeneous disease, in which a number of genetic and epigenetic changes occur in tumor onset and progression. Recent studies indicate that changes at the RNA level are also involved in tumorigenesis, such as adenosine-to-inosine (A-to-I) RNA editing. Here, we systematically investigate transcriptome-wide A-to-I editing events in a large number of samples from Non-Hodgkin lymphomas (NHLs). Using a computational pipeline that determines significant differences in editing level between NHL and normal samples at known A-to-I editing sites, we identify a number of differentially edited editing sites between NHL subtypes and normal samples. Most of the differentially edited sites are located in non-coding regions, and many such sites show a strong correlation between gene expression level and editing efficiency, indicating that RNA editing might have direct consequences for the cancer cell's aberrant gene regulation status in these cases. Moreover, we establish a strong link between RNA editing and NHL by demonstrating that NHL and normal samples and even NHL subtypes can be distinguished based on genome-wide RNA editing profiles alone. Our study establishes a strong link between RNA editing, cancer and aberrant gene regulation in NHL.

Published

2024

18. Divergent landscapes of A-to-I editing in postmortem and living human brain.

Author

Rodriguez de Los Santos M, Kopell BH, Buxbaum Grice A, Ganesh G, Yang A, Amini P, Liharska LE, Vornholt E, Fullard JF, Dong P, Park E, Zipkowitz S, Kaji DA, Thompson RC, Liu D, Park YJ, Cheng E, Ziafat K, Moya E, Fennessy B, Wilkins L, Silk H, Linares LM, Sullivan B, Cohen V, Kota P, Feng C, Johnson JS, Rieder MK, Scarpa J, Nadkarni GN, Wang M, Zhang B, Sklar P, Beckmann ND, Schadt EE, Roussos P, Charney AW, and Breen MS

Subjects

Humans, Prefrontal Cortex metabolism, Postmortem Changes, Male, RNA Editing, Adenosine metabolism, Adenosine Deaminase metabolism, Adenosine Deaminase genetics, Brain metabolism, Inosine metabolism, Inosine genetics, RNA-Binding Proteins metabolism, RNA-Binding Proteins genetics, Autopsy

Abstract

Adenosine-to-inosine (A-to-I) editing is a prevalent post-transcriptional RNA modification within the brain. Yet, most research has relied on postmortem samples, assuming it is an accurate representation of RNA biology in the living brain. We challenge this assumption by comparing A-to-I editing between postmortem and living prefrontal cortical tissues. Major differences were found, with over 70,000 A-to-I sites showing higher editing levels in postmortem tissues. Increased A-to-I editing in postmortem tissues is linked to higher ADAR and ADARB1 expression, is more pronounced in non-neuronal cells, and indicative of postmortem activation of inflammation and hypoxia. Higher A-to-I editing in living tissues marks sites that are evolutionarily preserved, synaptic, developmentally timed, and disrupted in neurological conditions. Common genetic variants were also found to differentially affect A-to-I editing levels in living versus postmortem tissues. Collectively, these discoveries offer more nuanced and accurate insights into the regulatory mechanisms of RNA editing in the human brain., (© 2024. The Author(s).)

Published

2024

19. Elucidation of the Epitranscriptomic RNA Modification Landscape of Chikungunya Virus.

Author

Baquero-Pérez B, Bortoletto E, Rosani U, Delgado-Tejedor A, Medina R, Novoa EM, Venier P, and Díez J

Subjects

Humans, Chikungunya Fever virology, Inosine metabolism, Inosine genetics, RNA-Binding Proteins metabolism, RNA-Binding Proteins genetics, Adenosine metabolism, Adenosine Deaminase, Chikungunya virus genetics, RNA, Viral genetics, RNA, Viral metabolism, RNA Processing, Post-Transcriptional, Transcriptome, Genome, Viral

Abstract

The genomes of positive-sense (+) single-stranded RNA (ssRNA) viruses are believed to be subjected to a wide range of RNA modifications. In this study, we focused on the chikungunya virus (CHIKV) as a model (+) ssRNA virus to study the landscape of viral RNA modification in infected human cells. Among the 32 distinct RNA modifications analysed by mass spectrometry, inosine was found enriched in the genomic CHIKV RNA. However, orthogonal validation by Illumina RNA-seq analyses did not identify any inosine modification along the CHIKV RNA genome. Moreover, CHIKV infection did not alter the expression of ADAR1 isoforms, the enzymes that catalyse the adenosine to inosine conversion. Together, this study highlights the importance of a multidisciplinary approach to assess the presence of RNA modifications in viral RNA genomes.

Published

2024

20. Functions and mechanisms of A-to-I RNA editing in filamentous ascomycetes.

Author

Wang Z, Bian Z, Wang D, and Xu J

Subjects

Fungal Proteins genetics, Fungal Proteins metabolism, Ascomycota genetics, RNA, Fungal genetics, RNA, Fungal metabolism, Adenosine metabolism, Adenosine genetics, Inosine metabolism, Inosine genetics, Fusarium genetics, Neurospora crassa genetics, RNA Editing, Adenosine Deaminase genetics, Adenosine Deaminase metabolism

Abstract

Although lack of ADAR (adenosine deaminase acting on RNA) orthologs, genome-wide A-to-I editing occurs specifically during sexual reproduction in a number of filamentous ascomycetes, including Fusarium graminearum and Neurospora crassa. Unlike ADAR-mediated editing in animals, fungal A-to-I editing has a strong preference for hairpin loops and U at -1 position, which leads to frequent editing of UAG and UAA stop codons. Majority of RNA editing events in fungi are in the coding region and cause amino acid changes. Some of these editing events have been experimentally characterized for providing heterozygote and adaptive advantages in F. graminearum. Recent studies showed that FgTad2 and FgTad3, 2 ADAT (adenosine deaminase acting on tRNA) enzymes that normally catalyze the editing of A34 in the anticodon of tRNA during vegetative growth mediate A-to-I mRNA editing during sexual reproduction. Stage specificity of RNA editing is conferred by stage-specific expression of short transcript isoforms of FgTAD2 and FgTAD3 as well as cofactors such as AME1 and FIP5 that facilitate the editing of mRNA in perithecia. Taken together, fungal A-to-I RNA editing during sexual reproduction is catalyzed by ADATs and it has the same sequence and structural preferences with editing of A34 in tRNA., Competing Interests: The authors have declared that no competing interests exist., (Copyright: © 2024 Wang et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.)

Published

2024

21. Transfer learning enables identification of multiple types of RNA modifications using nanopore direct RNA sequencing.

Author

Wu Y, Shao W, Yan M, Wang Y, Xu P, Huang G, Li X, Gregory BD, Yang J, Wang H, and Yu X

Subjects

Humans, RNA Processing, Post-Transcriptional, Nanopores, RNA genetics, RNA metabolism, Nanopore Sequencing methods, Deep Learning, Inosine metabolism, Inosine genetics, Transcriptome genetics, Sequence Analysis, RNA methods, Oryza genetics

Abstract

Nanopore direct RNA sequencing (DRS) has emerged as a powerful tool for RNA modification identification. However, concurrently detecting multiple types of modifications in a single DRS sample remains a challenge. Here, we develop TandemMod, a transferable deep learning framework capable of detecting multiple types of RNA modifications in single DRS data. To train high-performance TandemMod models, we generate in vitro epitranscriptome datasets from cDNA libraries, containing thousands of transcripts labeled with various types of RNA modifications. We validate the performance of TandemMod on both in vitro transcripts and in vivo human cell lines, confirming its high accuracy for profiling m 6 A and m 5 C modification sites. Furthermore, we perform transfer learning for identifying other modifications such as m 7 G, Ψ, and inosine, significantly reducing training data size and running time without compromising performance. Finally, we apply TandemMod to identify 3 types of RNA modifications in rice grown in different environments, demonstrating its applicability across species and conditions. In summary, we provide a resource with ground-truth labels that can serve as benchmark datasets for nanopore-based modification identification methods, and TandemMod for identifying diverse RNA modifications using a single DRS sample., (© 2024. The Author(s).)

Published

2024

22. Unveiling the A-to-I mRNA editing machinery and its regulation and evolution in fungi.

Author

Feng C, Xin K, Du Y, Zou J, Xing X, Xiu Q, Zhang Y, Zhang R, Huang W, Wang Q, Jiang C, Wang X, Kang Z, Xu JR, and Liu H

Subjects

Humans, Gene Expression Regulation, Fungal, Evolution, Molecular, Protein Processing, Post-Translational, Inosine metabolism, Inosine genetics, Fusarium genetics, Fusarium metabolism, Fungal Proteins genetics, Fungal Proteins metabolism, RNA Editing, RNA, Messenger metabolism, RNA, Messenger genetics

Abstract

A-to-I mRNA editing in animals is mediated by ADARs, but the mechanism underlying sexual stage-specific A-to-I mRNA editing in fungi remains unknown. Here, we show that the eukaryotic tRNA-specific heterodimeric deaminase FgTad2-FgTad3 is responsible for A-to-I mRNA editing in Fusarium graminearum. This editing capacity relies on the interaction between FgTad3 and a sexual stage-specific protein called Ame1. Although Ame1 orthologs are widely distributed in fungi, the interaction originates in Sordariomycetes. We have identified key residues responsible for the FgTad3-Ame1 interaction. The expression and activity of FgTad2-FgTad3 are regulated through alternative promoters, alternative translation initiation, and post-translational modifications. Our study demonstrates that the FgTad2-FgTad3-Ame1 complex can efficiently edit mRNA in yeasts, bacteria, and human cells, with important implications for the development of base editors in therapy and agriculture. Overall, this study uncovers mechanisms, regulation, and evolution of RNA editing in fungi, highlighting the role of protein-protein interactions in modulating deaminase function., (© 2024. The Author(s).)

Published

2024

23. Temporal landscape and translational regulation of A-to-I RNA editing in mouse retina development.

Author

Yang L, Yi L, Yang J, Zhang R, Xie Z, and Wang H

Subjects

Animals, Mice, Alternative Splicing, Inosine metabolism, Inosine genetics, Adenosine metabolism, Retina metabolism, Retina embryology, RNA Editing, Protein Biosynthesis

Abstract

Background: The significance of A-to-I RNA editing in nervous system development is widely recognized; however, its influence on retina development remains to be thoroughly understood., Results: In this study, we performed RNA sequencing and ribosome profiling experiments on developing mouse retinas to characterize the temporal landscape of A-to-I editing. Our findings revealed temporal changes in A-to-I editing, with distinct editing patterns observed across different developmental stages. Further analysis showed the interplay between A-to-I editing and alternative splicing, with A-to-I editing influencing splicing efficiency and the quantity of splicing events. A-to-I editing held the potential to enhance translation diversity, but this came at the expense of reduced translational efficiency. When coupled with splicing, it could produce a coordinated effect on gene translation., Conclusions: Overall, this study presents a temporally resolved atlas of A-to-I editing, connecting its changes with the impact on alternative splicing and gene translation in retina development., (© 2024. The Author(s).)

Published

2024

24. CAR-T overdrive: harnessing inosine for metabolic rewiring and stemness induction.

Author

Farrera-Sal M and Schmueck-Henneresse M

Subjects

Humans, Immunotherapy, Adoptive, Receptors, Chimeric Antigen genetics, Receptors, Chimeric Antigen immunology, Neoplastic Stem Cells metabolism, Neoplastic Stem Cells pathology, Animals, Inosine genetics, Inosine metabolism

Published

2024

25. Ocular A-to-I RNA editing signatures associated with SARS-CoV-2 infection.

Author

Jin YY, Liang YP, Huang WH, Guo L, Cheng LL, Ran TT, Yao JP, Zhu L, and Chen JH

Subjects

Humans, Adenosine metabolism, Inosine metabolism, Inosine genetics, Transcriptome, Eye metabolism, Eye virology, RNA Editing, COVID-19 genetics, COVID-19 virology, SARS-CoV-2 genetics

Abstract

Ophthalmic manifestations have recently been observed in acute and post-acute complications of COVID-19 caused by SARS-CoV-2 infection. Our precious study has shown that host RNA editing is linked to RNA viral infection, yet ocular adenosine to inosine (A-to-I) RNA editing during SARS-CoV-2 infection remains uninvestigated in COVID-19. Herein we used an epitranscriptomic pipeline to analyze 37 samples and investigate A-to-I editing associated with SARS-CoV-2 infection, in five ocular tissue types including the conjunctiva, limbus, cornea, sclera, and retinal organoids. Our results revealed dramatically altered A-to-I RNA editing across the five ocular tissues. Notably, the transcriptome-wide average level of RNA editing was increased in the cornea but generally decreased in the other four ocular tissues. Functional enrichment analysis showed that differential RNA editing (DRE) was mainly in genes related to ubiquitin-dependent protein catabolic process, transcriptional regulation, and RNA splicing. In addition to tissue-specific RNA editing found in each tissue, common RNA editing was observed across different tissues, especially in the innate antiviral immune gene MAVS and the E3 ubiquitin-protein ligase MDM2. Analysis in retinal organoids further revealed highly dynamic RNA editing alterations over time during SARS-CoV-2 infection. Our study thus suggested the potential role played by RNA editing in ophthalmic manifestations of COVID-19, and highlighted its potential transcriptome impact, especially on innate immunity., (© 2024. The Author(s).)

Published

2024

26. New comparative genomic evidence supporting the proteomic diversification role of A-to-I RNA editing in insects.

Author

Liu J, Zheng C, and Duan Y

Subjects

Animals, Proteomics, RNA Editing genetics, Adenosine genetics, Adenosine metabolism, Inosine genetics, Inosine metabolism, Genomics, Drosophila genetics, RNA genetics, Drosophila melanogaster genetics, Drosophila melanogaster metabolism

Abstract

Adenosine-to-inosine (A-to-I) RNA editing, resembling A-to-G mutation, confers adaptiveness by increasing proteomic diversity in a temporal-spatial manner. This evolutionary theory named "proteomic diversifying hypothesis" has only partially been tested in very few organisms like Drosophila melanogaster, mainly by observing the positive selection on nonsynonymous editing events. To find additional genome-wide evidences supporting this interesting assumption, we retrieved the genomes of four Drosophila species and collected 20 deep-sequenced transcriptomes of different developmental stages and neuron populations of D. melanogaster. We systematically profiled the RNA editomes in these samples and performed meticulous comparative genomic analyses. Further evidences were found to support the diversifying hypothesis. (1) None of the nonsynonymous editing sites in D. melanogaster had ancestral G-alleles, while the silent editing sites had an unignorable fraction of ancestral G-alleles; (2) Only very few nonsynonymous editing sites in D. melanogaster had corresponding G-alleles derived in the genomes of sibling species, and the fraction of such situation was significantly lower than that of silent editing sites; (3) The few nonsynonymous editing with corresponding G-alleles had significantly more variable editing levels (across samples) than other nonsynonymous editing sites in D. melanogaster. The proteomic diversifying nature of RNA editing in Drosophila excludes the restorative role which favors an ancestral G-allele. The few fixed G-alleles in sibling species might facilitate the adaptation to particular environment and the corresponding nonsynonymous editing in D. melanogaster would introduce stronger advantage of flexible proteomic diversification. With multi-Omics data, our study consolidates the nature of evolutionary significance of A-to-I RNA editing sites in model insects., (© 2024. The Author(s), under exclusive licence to Springer-Verlag GmbH Germany, part of Springer Nature.)

Published

2024

27. The first A-to-I RNA editome of hemipteran species Coridius chinensis reveals overrepresented recoding and prevalent intron editing in early-diverging insects.

Author

Duan Y, Ma L, Liu J, Liu X, Song F, Tian L, Cai W, and Li H

Subjects

Humans, Animals, Introns, Proteomics, Inosine genetics, Insecta genetics, RNA genetics, Adenosine genetics

Abstract

Background: Metazoan adenosine-to-inosine (A-to-I) RNA editing resembles A-to-G mutation and increases proteomic diversity in a temporal-spatial manner, allowing organisms adapting to changeable environment. The RNA editomes in many major animal clades remain unexplored, hampering the understanding on the evolution and adaptation of this essential post-transcriptional modification., Methods: We assembled the chromosome-level genome of Coridius chinensis belonging to Hemiptera, the fifth largest insect order where RNA editing has not been studied yet. We generated ten head RNA-Seq libraries with DNA-Seq from the matched individuals., Results: We identified thousands of high-confidence RNA editing sites in C. chinensis. Overrepresentation of nonsynonymous editing was observed, but conserved recoding across different orders was very rare. Under cold stress, the global editing efficiency was down-regulated and the general transcriptional processes were shut down. Nevertheless, we found an interesting site with "conserved editing but non-conserved recoding" in potassium channel Shab which was significantly up-regulated in cold, serving as a candidate functional site in response to temperature stress., Conclusions: RNA editing in C. chinensis largely recodes the proteome. The first RNA editome in Hemiptera indicates independent origin of beneficial recoding during insect evolution, which advances our understanding on the evolution, conservation, and adaptation of RNA editing., (© 2024. The Author(s).)

Published

2024

28. Inosine-Induced Base Pairing Diversity during Reverse Transcription.

Author

Zheng YY, Reddy K, Vangaveti S, and Sheng J

Subjects

Base Pairing, Inosine analysis, Inosine chemistry, Inosine genetics, Adenosine Deaminase genetics, Reverse Transcription, RNA, Viral genetics

Abstract

A-to-I editing catalyzed by adenosine deaminase acting on RNAs impacts numerous physiological and biochemical processes that are essential for cellular functions and is a big contributor to the infectivity of certain RNA viruses. The outcome of this deamination leads to changes in the eukaryotic transcriptome functionally resembling A-G transitions since inosine preferentially pairs with cytosine. Moreover, hyper-editing or multiple A to G transitions in clusters were detected in measles virus. Inosine modifications either directly on viral RNA or on cellular RNA can have antiviral or pro-viral repercussions. While many of the significant roles of inosine in cellular RNAs are well understood, the effects of hyper-editing of A to I on viral polymerase activity during RNA replication remain elusive. Moreover, biological strategies such as molecular cloning and RNA-seq for transcriptomic interrogation rely on RT-polymerase chain reaction with little to no emphasis placed on the first step, reverse transcription, which may reshape the sequencing results when hypermodification is present. In this study, we systematically explore the influence of inosine modification, varying the number and position of inosines, on decoding outcomes using three different reverse transcriptases (RTs) followed by standard Sanger sequencing. We find that inosine alone or in clusters can differentially affect the RT activity. To gain structural insights into the accommodation of inosine in the polymerase site of HIV-1 reverse transcriptase (HIV-1-RT) and how this structural context affects the base pairing rules for inosine, we performed molecular dynamics simulations of the HIV-1-RT. The simulations highlight the importance of the protein-nucleotide interaction as a critical factor in deciphering the base pairing behavior of inosine clusters. This effort sets the groundwork for decrypting the physiological significance of inosine and linking the fidelity of reverse transcriptase and the possible diverse transcription outcomes of cellular RNAs and/or viral RNAs where hyper-edited inosines are present in the transcripts.

Published

2024

29. Decoding the language of immunity.

Author

Alvarez RA and James LK

Subjects

Genetic Code, Humans, RNA, Transfer genetics, RNA, Transfer metabolism, Codon Usage, Antibody Formation genetics, Inosine genetics, Inosine metabolism

Abstract

Optimized transfer RNA (tRNA) codon use can speed up antibody generation.

Published

2024

30. Antibody production relies on the tRNA inosine wobble modification to meet biased codon demand.

Author

Giguère S, Wang X, Huber S, Xu L, Warner J, Weldon SR, Hu J, Phan QA, Tumang K, Prum T, Ma D, Kirsch KH, Nair U, Dedon P, and Batista FD

Subjects

Codon genetics, Humans, Antibody Formation genetics, Codon Usage, Inosine genetics, Inosine metabolism, RNA, Transfer genetics, Antibodies genetics, B-Lymphocytes immunology, Immunoglobulin Heavy Chains genetics

Abstract

Antibodies are produced at high rates to provide immunoprotection, which puts pressure on the B cell translational machinery. Here, we identified a pattern of codon usage conserved across antibody genes. One feature thereof is the hyperutilization of codons that lack genome-encoded Watson-Crick transfer RNAs (tRNAs), instead relying on the posttranscriptional tRNA modification inosine (I34), which expands the decoding capacity of specific tRNAs through wobbling. Antibody-secreting cells had increased I34 levels and were more reliant on I34 for protein production than naïve B cells. Furthermore, antibody I34-dependent codon usage may influence B cell passage through regulatory checkpoints. Our work elucidates the interface between the tRNA pool and protein production in the immune system and has implications for the design and selection of antibodies for vaccines and therapeutics.

Published

2024

31. Transcriptome analysis reveals the role of long noncoding RNAs in specific deposition of inosine monphosphate in Jingyuan chickens.

Author

Zhao W, Cai Z, Jiang Q, Zhang J, Yu B, Feng X, Fu X, Zhang T, Hu J, and Gu Y

Subjects

Animals, Transcriptome, MicroRNAs genetics, MicroRNAs metabolism, Meat analysis, Inosine metabolism, Inosine genetics, Muscle, Skeletal metabolism, Gene Expression Regulation, RNA, Long Noncoding genetics, RNA, Long Noncoding metabolism, Chickens genetics, Chickens metabolism, Gene Expression Profiling, Inosine Monophosphate metabolism

Abstract

Inosine monphosphate (IMP) is one of the important indicators for evaluating meat flavor, and long noncoding RNAs (lncRNAs) play an important role in its transcription and post-transcriptional regulation. Currently, there is little information about how lncRNA regulates the specific deposition of IMP in chicken muscle. In this study, we used transcriptome sequencing to analyze the lncRNAs of the breast and leg muscles of the Jingyuan chicken and identified a total of 357 differentially expressed lncRNAs (DELs), of which 158 were up-regulated and 199 were down-regulated. There were 2,203 and 7,377 cis- and trans-regulated target genes of lncRNAs, respectively, and we identified the lncRNA target genes that are involved in NEGF signaling pathway, glycolysis/glucoseogenesis, and biosynthesis of amino acids pathways. Meanwhile, 621 pairs of lncRNA-miRNA-mRNA interaction networks were constructed with target genes involved in purine metabolism, fatty acid metabolism, and biosynthesis of amino acids. Next, three interacting meso-networks gga-miR-1603-LNC_000324-PGM1, gga-miR-1768-LNC_000324-PGM1, and gga-miR-21-LNC_011339-AMPD1 were identified as closely associated with IMP-specific deposition. Both differentially expressed genes (DEGs) PGM1 and AMPD1 were significantly enriched in IMP synthesis and metabolism-related pathways, and participated in the anabolic process of IMP in the form of organic matter synthesis and energy metabolism. This study obtained lncRNAs and target genes affecting IMP-specific deposition in Jingyuan chickens based on transcriptome analysis, which deepened our insight into the role of lncRNAs in chicken meat quality., (© The Author(s) 2024. Published by Oxford University Press on behalf of the American Society of Animal Science. All rights reserved. For commercial re-use, please contact reprints@oup.com for reprints and translation rights for reprints. All other permissions can be obtained through our RightsLink service via the Permissions link on the article page on our site—for further information please contact journals.permissions@oup.com.)

Published

2024

32. The role of dsRNA A-to-I editing catalyzed by ADAR family enzymes in the pathogeneses.

Author

Liu W, Wu Y, Zhang T, Sun X, Guo D, and Yang Z

Subjects

Humans, Animals, Neoplasms genetics, Neoplasms metabolism, Adenosine Deaminase metabolism, Adenosine Deaminase genetics, RNA Editing, RNA, Double-Stranded metabolism, RNA, Double-Stranded genetics, RNA-Binding Proteins metabolism, RNA-Binding Proteins genetics, Adenosine metabolism, Adenosine genetics, Adenosine analogs & derivatives, Inosine metabolism, Inosine genetics

Abstract

The process of adenosine deaminase (ADAR)-catalyzed double-stranded RNA (dsRNA) Adenosine-to-Inosine (A-to-I) editing is essential for the correction of pathogenic mutagenesis, as well as the regulation of gene expression and protein function in mammals. The significance of dsRNA A-to-I editing in disease development and occurrence is explored using inferential statistics and cluster analyses to investigate the enzymes involved in dsRNA editing that can catalyze editing sites across multiple biomarkers. This editing process, which occurs in coding or non-coding regions, has the potential to activate abnormal signalling pathways that contributes to disease pathogenesis. Notably, the ADAR family enzymes play a crucial role in initiating the editing process. ADAR1 is upregulated in most diseases as an oncogene during tumorigenesis, whereas ADAR2 typically acts as a tumour suppressor. Furthermore, this review also provides an overview of small molecular inhibitors that disrupt the expression of ADAR enzymes. These inhibitors not only counteract tumorigenicity but also alleviate autoimmune disorders, neurological neurodegenerative symptoms, and metabolic diseases associated with aberrant dsRNA A-to-I editing processes. In summary, this comprehensive review offers detailed insights into the involvement of dsRNA A-to-I editing in disease pathogenesis and highlights the potential therapeutic roles for related small molecular inhibitors. These scientific findings will undoubtedly contribute to the advancement of personalized medicine based on dsRNA A-to-I editing.

Published

2024

33. An orthology-based methodology as a complementary approach to retrieve evolutionarily conserved A-to-I RNA editing sites.

Author

Liu J, Zhao T, Zheng C, Ma L, Song F, Tian L, Cai W, Li H, and Duan Y

Subjects

Animals, Bees genetics, Conserved Sequence, Adenosine Deaminase genetics, Adenosine Deaminase metabolism, RNA Editing, Inosine genetics, Inosine metabolism, Adenosine metabolism, Adenosine genetics, Evolution, Molecular

Abstract

Adar-mediated adenosine-to-inosine (A-to-I) mRNA editing is a conserved mechanism that exerts diverse regulatory functions during the development, evolution, and adaptation of metazoans. The accurate detection of RNA editing sites helps us understand their biological significance. In this work, with an improved genome assembly of honeybee ( Apis mellifera ), we used a new orthology-based methodology to complement the traditional pipeline of ( de novo ) RNA editing detection. Compared to the outcome of traditional pipeline, we retrieved many novel editing sites in CDS that are deeply conserved between honeybee and other distantly related insects. The newly retrieved sites were missed by the traditional de novo identification due to the stringent criteria for controlling false-positive rate. Caste-specific editing sites are identified, including an Ile>Met auto-recoding site in Adar . This recoding was even conserved between honeybee and bumblebee, suggesting its putative regulatory role in shaping the phenotypic plasticity of eusocial Hymenoptera. In summary, we proposed a complementary approach to the traditional pipeline and retrieved several previously unnoticed CDS editing sites. From both technical and biological aspects, our works facilitate future researches on finding the functional editing sites and advance our understanding on the connection between RNA editing and the great phenotypic diversity of organisms.

Published

2024

34. Identification and Interpretation of A-to-I RNA Editing Events in Insect Transcriptomes.

Author

Xu Y, Liu J, Zhao T, Song F, Tian L, Cai W, Li H, and Duan Y

Subjects

RNA Editing, Reproducibility of Results, Adenosine genetics, Adenosine metabolism, DNA, Inosine genetics, Inosine metabolism, Transcriptome, RNA genetics

Abstract

Adenosine-to-inosine (A-to-I) RNA editing is the most prevalent RNA modification in the nervous systems of metazoans. To study the biological significance of RNA editing, we first have to accurately identify these editing events from the transcriptome. The genome-wide identification of RNA editing sites remains a challenging task. In this review, we will first introduce the occurrence, regulation, and importance of A-to-I RNA editing and then describe the established bioinformatic procedures and difficulties in the accurate identification of these sit esespecially in small sized non-model insects. In brief, (1) to obtain an accurate profile of RNA editing sites, a transcriptome coupled with the DNA resequencing of a matched sample is favorable; (2) the single-cell sequencing technique is ready to be applied to RNA editing studies, but there are a few limitations to overcome; (3) during mapping and variant calling steps, various issues, like mapping and base quality, soft-clipping, and the positions of mismatches on reads, should be carefully considered; (4) Sanger sequencing of both RNA and the matched DNA is the best verification of RNA editing sites, but other auxiliary evidence, like the nonsynonymous-to-synonymous ratio or the linkage information, is also helpful for judging the reliability of editing sites. We have systematically reviewed the understanding of the biological significance of RNA editing and summarized the methodology for identifying such editing events. We also raised several promising aspects and challenges in this field. With insightful perspectives on both scientific and technical issues, our review will benefit the researchers in the broader RNA editing community.

Published

2023

35. Adenosine Deaminase Acting on RNA (ADAR) Enzymes: A Journey from Weird to Wondrous.

Author

Keegan LP, Hajji K, and O'Connell MA

Subjects

Animals, Mice, Humans, Immunity, Innate, RNA, Messenger genetics, Inosine genetics, Inosine metabolism, Adenosine Deaminase genetics, Adenosine Deaminase metabolism, RNA, Double-Stranded genetics

Abstract

The adenosine deaminase acting on RNA (ADAR) enzymes that catalyze the conversion of adenosine to inosine in double-stranded (ds)RNA are evolutionarily conserved and are essential for many biological functions including nervous system function, hematopoiesis, and innate immunity. Initially it was assumed that the wide-ranging biological roles of ADARs are due to inosine in mRNA being read as guanosine by the translational machinery, allowing incomplete RNA editing in a target codon to generate two different proteins from the same primary transcript. In humans, there are approximately seventy-six positions that undergo site-specific editing in tissues at greater than 20% efficiency that result in recoding. Many of these transcripts are expressed in the central nervous system (CNS) and edited by ADAR2. Exploiting mouse genetic models revealed that transgenic mice lacking the gene encoding Adar2 die within 3 weeks of birth. Therefore, the role of ADAR2 in generating protein diversity in the nervous system is clear, but why is ADAR RNA editing activity essential in other biological processes, particularly editing mainly involving ADAR1? ADAR1 edits human transcripts having embedded Alu element inverted repeats (AluIRs), but the link from this activity to innate immunity activation was elusive. Mice lacking the gene encoding Adar1 are embryonically lethal, and a major breakthrough was the discovery that the role of Adar1 in innate immunity is due to its ability to edit such repetitive element inverted repeats which have the ability to form dsRNA in transcripts. The presence of inosine prevents activation of the dsRNA sensor melanoma differentiation-associated protein 5 (Mda5). Thus, inosine helps the cell discriminate self from non-self RNA, acting like a barcode on mRNA. As innate immunity is key to many different biological processes, the basis for this widespread biological role of the ADAR1 enzyme became evident.Our group has been studying ADARs from the outset of research on these enzymes. In this Account, we give a historical perspective, moving from the initial purification of ADAR1 and ADAR2 and cloning of their encoding genes up to the current research focus in the field and what questions still remain to be addressed. We discuss the characterizations of the proteins, their localizations, posttranslational modifications, and dimerization, and how all of these affect their biological activities. Another aspect we explore is the use of mouse and Drosophila genetic models to study ADAR functions and how these were crucial in determining the biological functions of the ADAR proteins. Finally, we describe the severe consequences of rare mutations found in the human genes encoding ADAR1 and ADAR2.

Published

2023

36. Changes in ADAR RNA editing patterns in CMV and ZIKV congenital infections.

Author

Wales-McGrath B, Mercer H, and Piontkivska H

Subjects

Animals, Humans, Mice, RNA Editing, Adenosine Deaminase genetics, Adenosine Deaminase metabolism, Adenosine metabolism, Inosine genetics, Inosine metabolism, Zika Virus, Zika Virus Infection, Cytomegalovirus Infections

Abstract

Background: RNA editing is a process that increases transcriptome diversity, often through Adenosine Deaminases Acting on RNA (ADARs) that catalyze the deamination of adenosine to inosine. ADAR editing plays an important role in regulating brain function and immune activation, and is dynamically regulated during brain development. Additionally, the ADAR1 p150 isoform is induced by interferons in viral infection and plays a role in antiviral immune response. However, the question of how virus-induced ADAR expression affects host transcriptome editing remains largely unanswered. This question is particularly relevant in the context of congenital infections, given the dynamic regulation of ADAR editing during brain development, the importance of this editing for brain function, and subsequent neurological symptoms of such infections, including microcephaly, sensory issues, and other neurodevelopmental abnormalities. Here, we begin to address this question, examining ADAR expression in publicly available datasets of congenital infections of human cytomegalovirus (HCMV) microarray expression data, as well as mouse cytomegalovirus (MCMV) and mouse/ human induced pluripotent neuroprogenitor stem cell (hiNPC) Zika virus (ZIKV) RNA-seq data., Results: We found that in all three datasets, ADAR1 was overexpressed in infected samples compared to uninfected samples. In the RNA-seq datasets, editing rates were also analyzed. In all mouse infections cases, the number of editing sites was significantly increased in infected samples, albeit this was not the case for hiNPC ZIKV samples. Mouse ZIKV samples showed altered editing of well-established protein-recoding sites such as Gria3, Grik5, and Nova1, as well as editing sites that may impact miRNA binding., Conclusions: Our findings provide evidence for changes in ADAR expression and subsequent dysregulation of ADAR editing of host transcriptomes in congenital infections. These changes in editing patterns of key neural genes have potential significance in the development of neurological symptoms, thus contributing to neurodevelopmental abnormalities. Further experiments should be performed to explore the full range of editing changes that occur in different congenital infections, and to confirm the specific functional consequences of these editing changes., (© 2023. The Author(s).)

Published

2023

37. The Many Roles of A-to-I RNA Editing in Animals: Functional or Adaptive?

Author

Zhan D, Zheng C, Cai W, Li H, and Duan Y

Subjects

Animals, Adenosine genetics, Adenosine metabolism, Inosine genetics, Inosine metabolism, Transcriptome, RNA genetics, RNA metabolism, RNA Editing

Abstract

Metazoan adenosine-to-inosine (A-to-I) RNA editing is a highly conserved mechanism that diversifies the transcriptome by post-transcriptionally converting adenosine to inosine. Millions of editing sites have been identified in different species and, based on abnormal editing observed in various disorders, it is intuitive to conclude that RNA editing is both functional and adaptive. In this review, we propose the following major points: (1) "Function/functional" only represents a molecular/phenotypic consequence and is not necessarily connected to "adaptation/adaptive"; (2) Adaptive editing should be judged in the light of evolution and emphasize advantages of temporal-spatial flexibility; (3) Adaptive editing could, in theory, be extended from nonsynonymous sites to all potentially functional sites. This review seeks to conceptually bridge the gap between molecular biology and evolutionary biology and provide a more objective understanding on the biological functions and evolutionary significance of RNA editing., Competing Interests: The authors declare no conflict of interest., (© 2023 The Author(s). Published by IMR Press.)

Published

2023

38. Library Screening Reveals Sequence Motifs That Enable ADAR2 Editing at Recalcitrant Sites.

Author

Jacobsen CS, Salvador P, Yung JF, Kragness S, Mendoza HG, Mandel G, and Beal PA

Subjects

Base Pairing, Hydrolysis, Inosine genetics, Adenosine genetics, RNA, Adenosine Deaminase

Abstract

Adenosine deaminases acting on RNA (ADARs) catalyze the hydrolytic deamination of adenosine to inosine in duplex RNA. The inosine product preferentially base pairs with cytidine resulting in an effective A-to-G edit in RNA. ADAR editing can result in a recoding event alongside other alterations to RNA function. A consequence of ADARs' selective activity on duplex RNA is that guide RNAs (gRNAs) can be designed to target an adenosine of interest and promote a desired recoding event. One of ADAR's main limitations is its preference to edit adenosines with specific 5' and 3' nearest neighbor nucleotides (e.g., 5' U, 3' G). Current rational design approaches are well-suited for this ideal sequence context, but limited when applied to difficult-to-edit sites. Here we describe a strategy for the in vitro evaluation of very large libraries of ADAR substrates (En Masse Evaluation of RNA Guides, EMERGe). EMERGe allows for a comprehensive screening of ADAR substrate RNAs that complements current design approaches. We used this approach to identify sequence motifs for gRNAs that enable editing in otherwise difficult-to-edit target sites. A guide RNA bearing one of these sequence motifs enabled the cellular repair of a premature termination codon arising from mutation of the MECP2 gene associated with Rett Syndrome. EMERGe provides an advancement in screening that not only allows for novel gRNA design, but also furthers our understanding of ADARs' specific RNA-protein interactions.

Published

2023

39. Genome-Wide Analysis on Driver and Passenger RNA Editing Sites Suggests an Underestimation of Adaptive Signals in Insects.

Author

Zhang Y and Duan Y

Subjects

Animals, Adenosine genetics, Inosine genetics, Genome, RNA genetics, Drosophila melanogaster genetics, RNA Editing genetics

Abstract

Adenosine-to-inosine (A-to-I) RNA editing leads to a similar effect to A-to-G mutations. RNA editing provides a temporo-spatial flexibility for organisms. Nonsynonymous (Nonsyn) RNA editing in insects is over-represented compared with synonymous (Syn) editing, suggesting adaptive signals of positive selection on Nonsyn editing during evolution. We utilized the brain RNA editome of Drosophila melanogaster to systematically study the LD ( r 2 ) between editing sites and infer its impact on the adaptive signals of RNA editing. Pairs of editing sites (PESs) were identified from the transcriptome. For CDS PESs of two consecutive editing sites, their occurrence was significantly biased to type-3 PES (Syn-Nonsyn). The haplotype frequency of type-3 PES exhibited a significantly higher abundance of AG than GA, indicating that the rear Nonsyn site is the driver that promotes the editing of the front Syn site (passenger). The exclusion of passenger Syn sites dramatically amplifies the adaptive signal of Nonsyn RNA editing. Our study for the first time quantitatively demonstrates that the linkage between RNA editing events comes from hitchhiking effects and leads to the underestimation of adaptive signals for Nonsyn editing. Our work provides novel insights for studying the evolutionary significance of RNA editing events.

Published

2023

40. Autorecoding A-to-I RNA editing sites in the Adar gene underwent compensatory gains and losses in major insect clades.

Author

Duan Y, Ma L, Song F, Tian L, Cai W, and Li H

Subjects

Animals, Proteome genetics, Base Sequence, Insecta genetics, Adenosine Deaminase genetics, Adenosine Deaminase metabolism, Inosine genetics, Inosine metabolism, RNA genetics, RNA Editing genetics

Abstract

As one of the most prevalent RNA modifications in animals, adenosine-to-inosine (A-to-I) RNA editing facilitates the environmental adaptation of organisms by diversifying the proteome in a temporal-spatial manner. In flies and bees, the editing enzyme Adar has independently gained two different autorecoding sites that form an autofeedback loop, stabilizing the overall editing efficiency. This ensures cellular homeostasis by keeping the normal function of target genes. However, in a broader range of insects, the evolutionary dynamics and significance of this Adar autoregulatory mechanism are unclear. We retrieved the genomes of 377 arthropod species covering the five major insect orders (Hemiptera, Hymenoptera, Coleoptera, Diptera, and Lepidoptera) and aligned the Adar autorecoding sites across all genomes. We found that the two autorecoding sites underwent compensatory gains and losses during the evolution of two orders with the most sequenced species (Diptera and Hymenoptera), and that the two editing sites were mutually exclusive among them: One editable site is significantly linked to another uneditable site. This autorecoding mechanism of Adar could flexibly diversify the proteome and stabilize global editing activity. Many insects independently selected different autorecoding sites to achieve a feedback loop and regulate the global RNA editome, revealing an interesting phenomenon during evolution. Our study reveals the evolutionary force acting on accurate regulation of RNA editing activity in insects and thus deepens our understanding of the functional importance of RNA editing in environmental adaptation and evolution., (© 2023 Duan et al.; Published by Cold Spring Harbor Laboratory Press for the RNA Society.)

Published

2023

41. Incorporation of inosine into DNA by human polymerase eta (Polη): kinetics of nucleotide misincorporation and structural basis for the mutagenicity.

Author

Zhang Q and Tretyakova N

Subjects

Humans, Kinetics, Inosine genetics, Nucleotidyltransferases, DNA genetics, Nucleotides, Mutagens

Abstract

Inosine, a purine nucleoside containing the hypoxanthine (HX) nucleobase, can form in DNA via hydrolytic deamination of adenine. Due to its structural similarity to guanine and the geometry of Watson-Crick base pairs, inosine can mispair with cytosine upon catalysis by DNA polymerases, leading to AT → GC mutations. Additionally, inosine plays an essential role in purine nucleotide biosynthesis, and inosine triphosphate is present in living cells. In a recent publication, Averill and Jung examined the possibility of polη catalyzed incorporation of deoxyinosine triphosphate (dITP) across dC and dT in a DNA template. They found that dITP can be incorporated across C or T, with the ratio of 13.7. X ray crystallography studies revealed that the mutagenic incorporation of dITP by human polη was affected by several factors including base pair geometry in the active site of the polymerase, tautomerization of nucleobases, and the interaction of the incoming dITP nucleotide with active site residues of polη. This study demonstrates that TLS incorporation of inosine monophosphate (IMP) into growing DNA chains contributes to its mutagenic potential in cells., (© 2023 The Author(s).)

Published

2023

42. Transcriptome-wide profiling of A-to-I RNA editing by Slic-seq.

Author

Wei Q, Han S, Yuan K, He Z, Chen Y, Xi X, Han J, Yan S, Chen Y, Yuan B, Weng X, and Zhou X

Subjects

Animals, Humans, Mice, Inosine genetics, Inosine metabolism, Reproducibility of Results, Exons, Cell Line, RNA Editing genetics, Transcriptome genetics

Abstract

Adenosine-to-inosine (A-to-I) RNA editing is a post-transcriptional processing event involved in diversifying the transcriptome and is responsible for various biological processes. In this context, we developed a new method based on the highly selective cleavage activity of Endonuclease V against Inosine and the universal activity of sodium periodate against all RNAs to enrich the inosine-containing RNA and accurately identify the editing sites. We validated the reliability of our method in human brain in both Alu and non-Alu elements. The conserved sites of A-to-I editing in human cells (HEK293T, HeLa, HepG2, K562 and MCF-7) primarily occurs in the 3'UTR of the RNA, which are highly correlated with RNA binding and protein binding. Analysis of the editing sites between the human brain and mouse brain revealed that the editing of exons is more conserved than that in other regions. This method was applied to three neurological diseases (Alzheimer's, epilepsy and ageing) of mouse brain, reflecting that A-to-I editing sites significantly decreased in neuronal activity genes., (© The Author(s) 2023. Published by Oxford University Press on behalf of Nucleic Acids Research.)

Published

2023

43. yaaJ , the tRNA-Specific Adenosine Deaminase, Is Dispensable in Bacillus subtilis .

Author

Soma A, Kubota A, Tomoe D, Ikeuchi Y, Kawamura F, Arimoto H, Shiwa Y, Kanesaki Y, Nanamiya H, Yoshikawa H, Suzuki T, and Sekine Y

Subjects

Adenosine Deaminase genetics, Bacillus subtilis genetics, RNA, Transfer, Arg, RNA, Transfer genetics, Adenosine genetics, Inosine genetics, Anticodon, Magnoliopsida

Abstract

Post-transcriptional modifications of tRNA are crucial for their core function. The inosine (I; 6-deaminated adenosine) at the first position in the anticodon of tRNA Arg (ICG) modulates the decoding capability and is generally considered essential for reading CGU, CGC, and CGA codons in eubacteria. We report here that the Bacillus subtilis yaaJ gene encodes tRNA-specific adenosine deaminase and is non-essential for viability. A β-galactosidase reporter assay revealed that the translational activity of CGN codons was not impaired in the yaaJ -deletion mutant. Furthermore, tRNA Arg (CCG) responsible for decoding the CGG codon was dispensable, even in the presence or absence of yaaJ . These results strongly suggest that tRNA Arg with either the anticodon ICG or ACG has an intrinsic ability to recognize all four CGN codons, providing a fundamental concept of non-canonical wobbling mediated by adenosine and inosine nucleotides in the anticodon. This is the first example of the four-way wobbling by inosine nucleotide in bacterial cells. On the other hand, the absence of inosine modification induced +1 frameshifting, especially at the CGA codon. Additionally, the yaaJ deletion affected growth and competency. Therefore, the inosine modification is beneficial for translational fidelity and proper growth-phase control, and that is why yaaJ has been actually conserved in B. subtilis .

Published

2023

44. Amphioxus adenosine-to-inosine tRNA-editing enzyme that can perform C-to-U and A-to-I deamination of DNA.

Author

Gao Z, Jiang W, Zhang Y, Zhang L, Yi M, Wang H, Ma Z, Qu B, Ji X, Long H, and Zhang S

Subjects

Animals, Deamination, Escherichia coli genetics, Escherichia coli metabolism, Adenosine Deaminase genetics, Adenosine Deaminase metabolism, RNA, Transfer metabolism, Adenosine metabolism, DNA genetics, Inosine genetics, Lancelets genetics, Lancelets metabolism

Abstract

Adenosine-to-inosine tRNA-editing enzyme has been identified for more than two decades, but the study on its DNA editing activity is rather scarce. We show that amphioxus (Branchiostoma japonicum) ADAT2 (BjADAT2) contains the active site 'HxE-PCxxC' and the key residues for target-base-binding, and amphioxus ADAT3 (BjADAT3) harbors both the N-terminal positively charged region and the C-terminal pseudo-catalytic domain important for recognition of substrates. The sequencing of BjADAT2-transformed Escherichia coli genome suggests that BjADAT2 has the potential to target E. coli DNA and can deaminate at TCG and GAA sites in the E. coli genome. Biochemical analyses further demonstrate that BjADAT2, in complex with BjADAT3, can perform A-to-I editing of tRNA and convert C-to-U and A-to-I deamination of DNA. We also show that BjADAT2 preferentially deaminates adenosines and cytidines in the loop of DNA hairpin structures of substrates, and BjADAT3 also affects the type of DNA substrate targeted by BjADAT2. Finally, we find that C89, N113, C148 and Y156 play critical roles in the DNA editing activity of BjADAT2. Collectively, our study indicates that BjADAT2/3 is the sole naturally occurring deaminase with both tRNA and DNA editing capacity identified so far in Metazoa., (© 2023. The Author(s).)

Published

2023

45. Massive Proteogenomic Reanalysis of Publicly Available Proteomic Datasets of Human Tissues in Search for Protein Recoding via Adenosine-to-Inosine RNA Editing.

Author

Levitsky LI, Ivanov MV, Goncharov AO, Kliuchnikova AA, Bubis JA, Lobas AA, Solovyeva EM, Pyatnitskiy MA, Ovchinnikov RK, Kukharsky MS, Farafonova TE, Novikova SE, Zgoda VG, Tarasova IA, Gorshkov MV, and Moshkovskii SA

Subjects

Humans, Animals, Mice, RNA metabolism, RNA Editing, Chromatography, Liquid, Tandem Mass Spectrometry, Proteome genetics, Proteome metabolism, Adenosine metabolism, Inosine genetics, Inosine metabolism, Proteomics, Proteogenomics

Abstract

The proteogenomic search pipeline developed in this work has been applied for reanalysis of 40 publicly available shotgun proteomic datasets from various human tissues comprising more than 8000 individual LC-MS/MS runs, of which 5442 .raw data files were processed in total. This reanalysis was focused on searching for ADAR-mediated RNA editing events, their clustering across samples of different origins, and classification. In total, 33 recoded protein sites were identified in 21 datasets. Of those, 18 sites were detected in at least two datasets, representing the core human protein editome. In agreement with prior artworks, neural and cancer tissues were found to be enriched with recoded proteins. Quantitative analysis indicated that recoding the rate of specific sites did not directly depend on the levels of ADAR enzymes or targeted proteins themselves, rather it was governed by differential and yet undescribed regulation of interaction of enzymes with mRNA. Nine recoding sites conservative between humans and rodents were validated by targeted proteomics using stable isotope standards in the murine brain cortex and cerebellum, and an additional one was validated in human cerebrospinal fluid. In addition to previous data of the same type from cancer proteomes, we provide a comprehensive catalog of recoding events caused by ADAR RNA editing in the human proteome.

Published

2023

46. Altered RNA Editing in Atopic Dermatitis Highlights the Role of Double-Stranded RNA for Immune Surveillance.

Author

Karmon M, Kopel E, Barzilai A, Geva P, Eisenberg E, Levanon EY, and Greenberger S

Subjects

Humans, RNA Editing genetics, Adenosine metabolism, Inosine genetics, Inosine metabolism, Adenosine Deaminase genetics, Adenosine Deaminase metabolism, RNA, Double-Stranded genetics, Dermatitis, Atopic genetics

Abstract

Atopic dermatitis (AD) is associated with dysregulated type 1 IFN‒mediated responses, in parallel with the dominant type 2 inflammation. However, the pathophysiology of this dysregulation is largely unknown. Adenosine-to-inosine RNA editing plays a critical role in immune regulation by preventing double-stranded RNA recognition by MDA5 and IFN activation. We studied global adenosine-to-inosine editing in AD to elucidate the role played by altered editing in the pathophysiology of this disease. Analysis of three RNA-sequencing datasets of AD skin samples revealed reduced levels of adenosine-to-inosine RNA editing in AD. This reduction was seen globally throughout Alu repeats as well as in coding genes and in specific pre-mRNA loci expected to create long double-stranded RNA, the main substrate of MDA5 leading to type I IFN activation. Consistently, IFN signature genes were upregulated. In contrast, global editing was not altered in systemic lupus erythematosus and systemic sclerosis, despite IFN activation. Our results indicate that altered editing leading to impairment of the innate immune response may be involved in the pathogenesis of AD. Possibly, it may be relevant for additional autoimmune and inflammatory diseases., (Copyright © 2022 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2023

47. ATTIC is an integrated approach for predicting A-to-I RNA editing sites in three species.

Author

Chen R, Li F, Guo X, Bi Y, Li C, Pan S, Coin LJM, and Song J

Subjects

Animals, Mice, Humans, RNA genetics, Adenosine genetics, Adenosine metabolism, Inosine genetics, Inosine metabolism, RNA Editing, Drosophila melanogaster genetics, Drosophila melanogaster metabolism

Abstract

A-to-I editing is the most prevalent RNA editing event, which refers to the change of adenosine (A) bases to inosine (I) bases in double-stranded RNAs. Several studies have revealed that A-to-I editing can regulate cellular processes and is associated with various human diseases. Therefore, accurate identification of A-to-I editing sites is crucial for understanding RNA-level (i.e. transcriptional) modifications and their potential roles in molecular functions. To date, various computational approaches for A-to-I editing site identification have been developed; however, their performance is still unsatisfactory and needs further improvement. In this study, we developed a novel stacked-ensemble learning model, ATTIC (A-To-I ediTing predICtor), to accurately identify A-to-I editing sites across three species, including Homo sapiens, Mus musculus and Drosophila melanogaster. We first comprehensively evaluated 37 RNA sequence-derived features combined with 14 popular machine learning algorithms. Then, we selected the optimal base models to build a series of stacked ensemble models. The final ATTIC framework was developed based on the optimal models improved by the feature selection strategy for specific species. Extensive cross-validation and independent tests illustrate that ATTIC outperforms state-of-the-art tools for predicting A-to-I editing sites. We also developed a web server for ATTIC, which is publicly available at http://web.unimelb-bioinfortools.cloud.edu.au/ATTIC/. We anticipate that ATTIC can be utilized as a useful tool to accelerate the identification of A-to-I RNA editing events and help characterize their roles in post-transcriptional regulation., (© The Author(s) 2023. Published by Oxford University Press. All rights reserved. For Permissions, please email: journals.permissions@oup.com.)

Published

2023

48. Development and evaluation of an adenosine-to-inosine RNA editing-based prognostic model for survival prediction of bladder cancer patients.

Author

Tang YC, Yang CS, Liang MX, Zhang Y, Liu Y, Zou SH, and Shi SF

Subjects

Humans, Prognosis, Adenosine, Inosine genetics, RNA Editing, Urinary Bladder Neoplasms genetics

Abstract

Adenosine-to-inosine RNA editing (ATIRE) is a common form of ribonucleic acid (RNA) editing, which has highlighted the importance of ATIRE in tumors. However, its role in bladder cancer (BLCA) remains poorly understood. To study ATIRE impact on BLCA patient prognosis, we obtained ATIRE, gene expression, and clinical data from the Cancer Genome Atlas (TCGA) database for 251 patients, randomly dividing them into training and testing groups. Univariate proportional hazards model (COX) regression identified prognosis-associated ATIRE loci, while the least absolute shrinkage and selection operator (LASSO) selected final loci to construct prognostic models and generate ATIRE scores. We developed a nomogram to predict BLCA patients' overall survival (OS) and analyzed the effect of ATIRE editing levels on host gene expression. We also compared immune cell infiltration and drug treatment between patients with high and low ATIRE scores. The ATIRE prognostic prediction model was constructed using ten ATIRE loci that are closely associated with BLCA survival. Patients with high ATIRE scores showed significantly worse OS than those with low ATIRE scores. Furthermore, the nomogram, which incorporates the ATIRE score, can better predict the prognosis of patients. Multiple functional and pathway changes associated with immune responses, as well as significant differences in immune cell infiltration levels and response to drug therapy were observed between patients with high and low ATIRE scores. This study represented the first comprehensive analysis of the role of ATIRE events in BLCA patient prognosis and provided new insights into potential prognostic markers for BLCA research., Competing Interests: The authors have no funding and conflicts of interest to disclose., (Copyright © 2023 the Author(s). Published by Wolters Kluwer Health, Inc.)

Published

2023

49. Expanding the proteome: A-to-I RNA editing provides an adaptive advantage.

Author

Lewis ZA

Subjects

RNA metabolism, Inosine genetics, Proteome genetics, Proteome metabolism, RNA Editing genetics

Published

2023

50. Identification of exceptionally potent adenosine deaminases RNA editors from high body temperature organisms.

Author

Avram-Shperling A, Kopel E, Twersky I, Gabay O, Ben-David A, Karako-Lampert S, Rosenthal JJC, Levanon EY, Eisenberg E, and Ben-Aroya S

Subjects

RNA-Binding Proteins genetics, RNA-Binding Proteins metabolism, RNA, Double-Stranded genetics, RNA, Messenger genetics, Inosine genetics, Inosine metabolism, Adenosine Deaminase metabolism, Body Temperature

Abstract

The most abundant form of RNA editing in metazoa is the deamination of adenosines into inosines (A-to-I), catalyzed by ADAR enzymes. Inosines are read as guanosines by the translation machinery, and thus A-to-I may lead to protein recoding. The ability of ADARs to recode at the mRNA level makes them attractive therapeutic tools. Several approaches for Site-Directed RNA Editing (SDRE) are currently under development. A major challenge in this field is achieving high on-target editing efficiency, and thus it is of much interest to identify highly potent ADARs. To address this, we used the baker yeast Saccharomyces cerevisiae as an editing-naïve system. We exogenously expressed a range of heterologous ADARs and identified the hummingbird and primarily mallard-duck ADARs, which evolved at 40-42°C, as two exceptionally potent editors. ADARs bind to double-stranded RNA structures (dsRNAs), which in turn are temperature sensitive. Our results indicate that species evolved to live with higher core body temperatures have developed ADAR enzymes that target weaker dsRNA structures and would therefore be more effective than other ADARs. Further studies may use this approach to isolate additional ADARs with an editing profile of choice to meet specific requirements, thus broadening the applicability of SDRE., Competing Interests: The authors have declared that no competing interests exist., (Copyright: © 2023 Avram-Shperling et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.)

Published

2023