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

201. Altered A-to-I RNA editing in human embryogenesis.

Author

Shtrichman R, Germanguz I, Mandel R, Ziskind A, Nahor I, Safran M, Osenberg S, Sherf O, Rechavi G, and Itskovitz-Eldor J

Subjects

Adaptor Proteins, Signal Transducing genetics, Adenosine genetics, Adenosine metabolism, Adenosine Deaminase genetics, Adenosine Deaminase metabolism, Alu Elements, BRCA1 Protein genetics, CARD Signaling Adaptor Proteins genetics, Cell Cycle Proteins genetics, Cells, Cultured, Contractile Proteins genetics, Embryonal Carcinoma Stem Cells, Embryonic Stem Cells, Fanconi Anemia Complementation Group C Protein genetics, Filamins, Gene Expression, Gene Expression Regulation, Developmental, Guanylate Cyclase genetics, Humans, Inosine genetics, Inosine metabolism, Intracellular Signaling Peptides and Proteins genetics, Microfilament Proteins genetics, Neoplasm Proteins genetics, Nuclear Proteins genetics, Protein Isoforms genetics, Protein Isoforms metabolism, Proto-Oncogene Proteins genetics, RNA, Messenger genetics, RNA-Binding Proteins, Embryonic Development, RNA Editing, RNA, Messenger metabolism

Abstract

Post-transcriptional events play an important role in human development. The question arises as to whether Adenosine to Inosine RNA editing, catalyzed by the ADAR (Adenosine Deaminase acting on RNA) enzymes, differs in human embryogenesis and in adulthood. We tested the editing of various target genes in coding (FLNA, BLCAP, CYFIP2) and non-coding sequences at their Alu elements (BRCA1, CARD11, RBBP9, MDM4, FNACC), as well as the transcriptional levels of the ADAR1 enzymes. This analysis was performed on five fetal and adult human tissues: brain, heart, liver, kidney, and spleen, as well as on human embryonic stem cells (hESCs), which represent the blastocyst stage in early human development. Our results show substantially greater editing activity for most adult tissue samples relative to fetal ones, in six of the eight genes tested. To test the effect of reduced A-to-I RNA editing activity in early human development we used human embryonic stem cells (hESCs) as a model and tried to generate hESC clones that overexpress the ADAR1-p110 isoform. We were unable to achieve overexpression of ADAR1-p110 by either transfection or lentiviral infection, though we easily generated hESC clones that expressed the GFP transgene and overexpressed ADAR1-p110 in 293T cells and in primary human foreskin fibroblast (HFF) cells. Moreover, in contrast to the expected overexpression of ADAR1-p110 protein following its introduction into hESCs, the expression levels of this protein decreased dramatically 24-48 hr post infection. Similar results were obtained when we tried to overexpress ADAR1-p110 in pluripotent embryonal carcinoma cells. This suggests that ADAR1 protein is substantially regulated in undifferentiated pluripotent hESCs. Overall, our data suggest that A-to-I RNA editing plays a critical role during early human development.

Published

2012

202. A novel computational strategy to identify A-to-I RNA editing sites by RNA-Seq data: de novo detection in human spinal cord tissue.

Author

Picardi E, Gallo A, Galeano F, Tomaselli S, and Pesole G

Subjects

Adenosine genetics, Algorithms, Brain metabolism, Computational Biology methods, Databases, Genetic, Exome, Gene Expression Regulation, Genome, Human, Genomics, Homeostasis, Humans, Inosine genetics, Neurodegenerative Diseases metabolism, Reproducibility of Results, Software, Spinal Cord metabolism, Transcriptome, RNA Editing, Spinal Cord pathology

Abstract

RNA editing is a post-transcriptional process occurring in a wide range of organisms. In human brain, the A-to-I RNA editing, in which individual adenosine (A) bases in pre-mRNA are modified to yield inosine (I), is the most frequent event. Modulating gene expression, RNA editing is essential for cellular homeostasis. Indeed, its deregulation has been linked to several neurological and neurodegenerative diseases. To date, many RNA editing sites have been identified by next generation sequencing technologies employing massive transcriptome sequencing together with whole genome or exome sequencing. While genome and transcriptome reads are not always available for single individuals, RNA-Seq data are widespread through public databases and represent a relevant source of yet unexplored RNA editing sites. In this context, we propose a simple computational strategy to identify genomic positions enriched in novel hypothetical RNA editing events by means of a new two-steps mapping procedure requiring only RNA-Seq data and no a priori knowledge of RNA editing characteristics and genomic reads. We assessed the suitability of our procedure by confirming A-to-I candidates using conventional Sanger sequencing and performing RNA-Seq as well as whole exome sequencing of human spinal cord tissue from a single individual.

Published

2012

203. Visualizing adenosine-to-inosine RNA editing in the Drosophila nervous system.

Author

Jepson JE, Savva YA, Jay KA, and Reenan RA

Subjects

Adenosine Deaminase chemistry, Animals, Drosophila melanogaster, Genes, Reporter, Green Fluorescent Proteins genetics, Adenosine genetics, Adenosine Deaminase metabolism, Inosine genetics, Nervous System metabolism, RNA Editing

Abstract

Informational recoding by adenosine-to-inosine RNA editing diversifies neuronal proteomes by chemically modifying structured mRNAs. However, techniques for analyzing editing activity on substrates in defined neurons in vivo are lacking. Guided by comparative genomics, here we reverse-engineered a fluorescent reporter sensitive to Drosophila melanogaster adenosine deaminase that acts on RNA (dADAR) activity and alterations in dADAR autoregulation. Using this artificial dADAR substrate, we visualized variable patterns of RNA-editing activity in the Drosophila nervous system between individuals. Our results demonstrate the feasibility of structurally mimicking ADAR substrates as a method to regulate protein expression and, potentially, therapeutically repair mutant mRNAs. Our data suggest variable RNA editing as a credible molecular mechanism for mediating individual-to-individual variation in neuronal physiology and behavior.

Published

2011

204. Adenosine-to-inosine RNA editing meets cancer.

Author

Dominissini D, Moshitch-Moshkovitz S, Amariglio N, and Rechavi G

Subjects

Adenosine chemistry, Animals, Humans, Inosine chemistry, Adenosine genetics, Inosine genetics, Neoplasms genetics, RNA Editing

Abstract

The role of epigenetics in tumor onset and progression has been extensively addressed. Discoveries in the last decade completely changed our view on RNA. We now realize that its diversity lies at the base of biological complexity. Adenosine-to-inosine (A-to-I) RNA editing emerges a central generator of transcriptome diversity and regulation in higher eukaryotes. It is the posttranscriptional deamination of adenosine to inosine in double-stranded RNA catalyzed by enzymes of the adenosine deaminase acting on RNA (ADAR) family. Thought at first to be restricted to coding regions of only a few genes, recent bioinformatic analyses fueled by high-throughput sequencing revealed that it is a widespread modification affecting mostly non-coding repetitive elements in thousands of genes. The rise in scope is accompanied by discovery of a growing repertoire of functions based on differential decoding of inosine by the various cellular machineries: when recognized as guanosine, it can lead to protein recoding, alternative splicing or altered microRNA specificity; when recognized by inosine-binding proteins, it can result in nuclear retention of the transcript or its degradation. An imbalance in expression of ADAR enzymes with consequent editing dysregulation is a characteristic of human cancers. These alterations may be responsible for activating proto-oncogenes or inactivating tumor suppressors. While unlikely to be an early initiating 'hit', editing dysregulation seems to contribute to tumor progression and thus should be considered a 'driver mutation'. In this review, we examine the contribution of A-to-I RNA editing to carcinogenesis.

Published

2011

205. Identification of widespread ultra-edited human RNAs.

Author

Carmi S, Borukhov I, and Levanon EY

Subjects

Adenosine chemistry, Adenosine genetics, Adenosine Deaminase chemistry, Base Pair Mismatch genetics, Base Pairing genetics, Base Sequence, Exons, Expressed Sequence Tags chemistry, Genome, Genomics, Guanosine chemistry, Guanosine genetics, Humans, Inosine chemistry, Molecular Sequence Data, RNA chemistry, RNA, Double-Stranded chemistry, RNA-Binding Proteins, Adenosine Deaminase genetics, Alu Elements genetics, Inosine genetics, RNA genetics, RNA Editing genetics, RNA, Double-Stranded genetics

Abstract

Adenosine-to-inosine modification of RNA molecules (A-to-I RNA editing) is an important mechanism that increases transciptome diversity. It occurs when a genomically encoded adenosine (A) is converted to an inosine (I) by ADAR proteins. Sequencing reactions read inosine as guanosine (G); therefore, current methods to detect A-to-I editing sites align RNA sequences to their corresponding DNA regions and identify A-to-G mismatches. However, such methods perform poorly on RNAs that underwent extensive editing ("ultra"-editing), as the large number of mismatches obscures the genomic origin of these RNAs. Therefore, only a few anecdotal ultra-edited RNAs have been discovered so far. Here we introduce and apply a novel computational method to identify ultra-edited RNAs. We detected 760 ESTs containing 15,646 editing sites (more than 20 sites per EST, on average), of which 13,668 are novel. Ultra-edited RNAs exhibit the known sequence motif of ADARs and tend to localize in sense strand Alu elements. Compared to sites of mild editing, ultra-editing occurs primarily in Alu-rich regions, where potential base pairing with neighboring, inverted Alus creates particularly long double-stranded RNA structures. Ultra-editing sites are underrepresented in old Alu subfamilies, tend to be non-conserved, and avoid exons, suggesting that ultra-editing is usually deleterious. A possible biological function of ultra-editing could be mediated by non-canonical splicing and cleavage of the RNA near the editing sites., Competing Interests: The authors have declared that no competing interests exist.

Published

2011

206. Identification of A-to-I RNA editing: dotting the i's in the human transcriptome.

Author

Kiran A, Loughran G, O'Mahony JJ, and Baranov PV

Subjects

Adenosine metabolism, Genome, Human, Humans, Inosine metabolism, Adenosine genetics, Computational Biology methods, High-Throughput Nucleotide Sequencing methods, Inosine genetics, RNA Editing, Transcriptome

Abstract

The phenomenon of adenosine-to-inosine (A-to-I) RNA editing has attracted considerable attention from the scientific community due to its potential relationship to the evolution of cognition in animals. While A-to-I editing exists in all organisms with neurons, including those with primitive neuronal systems (hydra and nematodes), it is particularly frequent in organisms with a highly developed central nervous system (primates, especially humans). Diversification of RNA transcript sequences via A-to-I editing serves a number of different functional roles, such as altering the genome-templated identity of particular amino acids in proteins or altering splice site junctions and modulating regulation of alternatively spliced mRNA variants. Here we provide an overview of current computational and experimental methods for the high-throughput discovery of edited RNA nucleotides in the human transcriptome, as well as a survey of the existing RNA editing bioinformatics resources and an outlook of future perspectives.

Published

2011

207. A-to-I RNA editing modulates the pharmacology of neuronal ion channels and receptors.

Author

Streit AK and Decher N

Subjects

Adenosine metabolism, Animals, Humans, Inosine metabolism, Ion Channels metabolism, Nervous System Diseases metabolism, Receptors, Cell Surface genetics, Receptors, Cell Surface metabolism, Adenosine genetics, Inosine genetics, Ion Channels genetics, Nervous System Diseases drug therapy, Nervous System Diseases genetics, Neurotransmitter Agents pharmacology, RNA Editing

Abstract

The regulation of neuronal excitability is complex, as ion channels and neurotransmitter receptors are underlying a large variety of modulating effects. Alterations in the expression patterns of receptors or channel subunits as well as differential splicing contribute to the regulation of neuronal excitability. RNA editing is another and more recently explored mechanism to increase protein diversity, as the genomic recoding leads to new gene products with novel functional and pharmacological properties. In humans A-to-I RNA editing targets several neuronal receptors and channels, including GluR2/5/6 subunits, the Kv1.1 channel, and the 5-HT(2C) receptor. Our review summarizes that RNA editing of these proteins does not only change protein function, but also the pharmacology and presumably the drug therapy in human diseases.

Published

2011

208. Adenosine-to-inosine RNA editing affects trafficking of the gamma-aminobutyric acid type A (GABA(A)) receptor.

Author

Daniel C, Wahlstedt H, Ohlson J, Björk P, and Ohman M

Subjects

Adenosine genetics, Adenosine metabolism, Adult, Amino Acid Substitution, Animals, Brain metabolism, HEK293 Cells, Humans, Inosine genetics, Inosine metabolism, Mice, Protein Transport physiology, Rats, Receptors, GABA-A genetics, Recombinant Proteins genetics, Gene Expression, RNA Editing physiology, Receptors, GABA-A biosynthesis, Recombinant Proteins biosynthesis

Abstract

Recoding by adenosine-to-inosine RNA editing plays an important role in diversifying proteins involved in neurotransmission. We have previously shown that the Gabra-3 transcript, coding for the α3 subunit of the GABA(A) receptor is edited in mouse, causing an isoleucine to methionine (I/M) change. Here we show that this editing event is evolutionarily conserved from human to chicken. Analyzing recombinant GABA(A) receptor subunits expressed in HEK293 cells, our results suggest that editing at the I/M site in α3 has functional consequences on receptor expression. We demonstrate that I/M editing reduces the cell surface and the total number of α3 subunits. The reduction in cell surface levels is independent of the subunit combination as it is observed for α3 in combination with either the β2 or the β3 subunit. Further, an amino acid substitution at the corresponding I/M site in the α1 subunit has a similar effect on cell surface presentation, indicating the importance of this site for receptor trafficking. We show that the I/M editing during brain development is inversely related to the α3 protein abundance. Our results suggest that editing controls trafficking of α3-containing receptors and may therefore facilitate the switch of subunit compositions during development as well as the subcellular distribution of α subunits in the adult brain.

Published

2011

209. Perturbing A-to-I RNA editing using genetics and homologous recombination.

Author

Staber CJ, Gell S, Jepson JE, and Reenan RA

Subjects

Animals, Cloning, Molecular methods, Mutagenesis, Site-Directed methods, Polymerase Chain Reaction methods, Adenosine genetics, Drosophila melanogaster genetics, Inosine genetics, RNA genetics, RNA Editing, Recombination, Genetic

Abstract

Evidence for the chemical conversion of adenosine-to-inosine (A-to-I) in messenger RNA (mRNA) has been detected in numerous metazoans, especially those "most successful" phyla: Arthropoda, Mollusca, and Chordata. The requisite enzymes for A-to-I editing, ADARs (adenosine deaminases acting on RNA) are highly conserved and are present in every higher metazoan genome sequenced to date. The fruit fly, Drosophila melanogaster, represents an ideal model organism for studying A-to-I editing, both in terms of fundamental biochemistry and in relation to determining adaptive downstream effects on physiology and behavior. The Drosophila genome contains a single structural gene for ADAR (dAdar), yet the fruit fly transcriptome has the widest range of conserved and validated ADAR targets in coding mRNAs of any known organism. In addition, many of the genes targeted by dADAR have been genetically identified as playing a role in nervous system function, providing a rich source of material to investigate the biological relevance of this intriguing process. Here, we discuss how recent advances in the use of ends-out homologous recombination (HR) in Drosophila make possible both the precise control of the editing status for defined adenosine residues and the engineering of flies with globally altered RNA editing of the fly transcriptome. These new approaches promise to significantly improve our understanding of how mRNA modification contributes to insect physiology and ethology.

Published

2011

210. Substitution by inosine at the 3'-ultimate and penultimate positions of 16S rRNA gene universal primers.

Author

Ben-Dov E, Siboni N, Shapiro OH, Arotsker L, and Kushmaro A

Subjects

Animals, Anthozoa microbiology, Bacteria classification, Gene Library, Sensitivity and Specificity, Bacteria genetics, DNA Primers genetics, Ecology methods, Genetic Techniques, Inosine genetics, RNA, Ribosomal, 16S genetics

Abstract

Universal 16S rRNA gene primers (8F and 518R) bearing inosine substitutions at either the 3'-ultimate or the 3'-ultimate and penultimate base positions were exploited for the first time to study the bacterial community associated with coral polymicrobial Black Band Disease (BBD). Inosine-modified universal primer pairs display some shifting in the composition of 16S rRNA gene libraries, as well as expanding the observed diversity of a BBD bacterial community at the family/class level. Possible explanations for the observed shifts are discussed. These results thus point to the need for adopting multiple approaches in designing 16S rRNA universal primers for PCR amplification and subsequent construction of 16S rRNA gene libraries or pyrosequencing in the exploration of complex microbial communities.

Published

2011

211. Biochemical identification of A-to-I RNA editing sites by the inosine chemical erasing (ICE) method.

Author

Sakurai M and Suzuki T

Subjects

Adenosine genetics, Animals, Inosine genetics, Mice, RNA genetics, Adenosine analysis, Inosine analysis, RNA chemistry, RNA Editing, Reverse Transcriptase Polymerase Chain Reaction methods, Sequence Analysis, RNA methods

Abstract

Adenosine-to-inosine (A-to-I) RNA editing is a biologically important posttranscriptional processing event involved in the transcriptome diversification. The most conventional method of editing site identification is to compare the cDNA sequence with its corresponding genomic sequence; however, using this method, it is difficult to discriminate between guanosine residue that originated from inosine and errors or noise in the sequencing chromatograms. To address this issue, we developed the inosine chemical erasing (ICE) method to identify inosines in RNA strands utilizing inosine cyanoethylation and reverse transcription PCR. Since this method requires only a limited quantity of total RNA, it can be used in the genome-wide profiling of A-to-I editing sites in tissues and cells from various organisms, including clinical specimens.

Published

2011

212. RNA editing by mammalian ADARs.

Author

Hogg M, Paro S, Keegan LP, and O'Connell MA

Subjects

Adenosine genetics, Adenosine metabolism, Amyotrophic Lateral Sclerosis genetics, Amyotrophic Lateral Sclerosis metabolism, Amyotrophic Lateral Sclerosis physiopathology, Animals, Central Nervous System metabolism, Genetic Association Studies, Humans, Inosine genetics, Inosine metabolism, Male, Mammals genetics, Mammals metabolism, Mice, Mice, Transgenic, Neurons metabolism, Protein Binding genetics, RNA Interference, RNA-Binding Proteins, Rats, Adenosine Deaminase genetics, Adenosine Deaminase metabolism, Alu Elements, RNA Editing, RNA, Double-Stranded metabolism

Abstract

The main type of RNA editing in mammals is the conversion of adenosine to inosine which is translated as if it were guanosine. The enzymes that catalyze this reaction are ADARs (adenosine deaminases that act on RNA), of which there are four in mammals, two of which are catalytically inactive. ADARs edit transcripts that encode proteins expressed mainly in the CNS and editing is crucial to maintain a correctly functioning nervous system. However, the majority of editing has been found in transcripts encoding Alu repeat elements and the biological role of this editing remains a mystery. This chapter describes in detail the different ADAR enzymes and the phenotype of animals that are deficient in their activity. Besides being enzymes, ADARs are also double-stranded RNA-binding proteins, so by binding alone they can interfere with other processes such as RNA interference. Lack of editing by ADARs has been implicated in disorders such as forebrain ischemia and Amyotrophic Lateral Sclerosis (ALS) and this will also be discussed., (Copyright © 2011 Elsevier Inc. All rights reserved.)

Published

2011

213. Consistent levels of A-to-I RNA editing across individuals in coding sequences and non-conserved Alu repeats.

Author

Greenberger S, Levanon EY, Paz-Yaacov N, Barzilai A, Safran M, Osenberg S, Amariglio N, Rechavi G, and Eisenberg E

Subjects

Cell Line, Humans, Nuclear Proteins genetics, Organ Specificity genetics, Proto-Oncogene Proteins c-fyn genetics, Skin metabolism, Adenosine genetics, Alu Elements genetics, Conserved Sequence genetics, Inosine genetics, Open Reading Frames genetics, RNA Editing genetics

Abstract

Background: Adenosine to inosine (A-to-I) RNA-editing is an essential post-transcriptional mechanism that occurs in numerous sites in the human transcriptome, mainly within Alu repeats. It has been shown to have consistent levels of editing across individuals in a few targets in the human brain and altered in several human pathologies. However, the variability across human individuals of editing levels in other tissues has not been studied so far., Results: Here, we analyzed 32 skin samples, looking at A-to-I editing level in three genes within coding sequences and in the Alu repeats of six different genes. We observed highly consistent editing levels across different individuals as well as across tissues, not only in coding targets but, surprisingly, also in the non evolutionary conserved Alu repeats., Conclusions: Our findings suggest that A-to-I RNA-editing of Alu elements is a tightly regulated process and, as such, might have been recruited in the course of primate evolution for post-transcriptional regulatory mechanisms.

Published

2010

214. Electrochemical genotyping and detection of single-nucleotide polymorphisms based on junction-probe containing 2'-deoxyinosine.

Author

Zhang J, Wu X, Chen P, Lin N, Chen J, Chen G, and Fu F

Subjects

DNA chemistry, DNA genetics, Electrochemistry, Genotype, Inosine chemistry, Inosine genetics, Oligonucleotide Probes chemistry, Biosensing Techniques, Inosine analogs & derivatives, Oligonucleotide Probes genetics, Polymorphism, Single Nucleotide genetics

Abstract

A novel electrochemical biosensor for the genotyping/detection of single-nucleotide polymorphisms (SNPs) of trace oral-cancer salivary DNA based on junction probes containing 2'-deoxyinosine (dI) residues is described.

Published

2010

215. Age-related gene-specific changes of A-to-I mRNA editing in the human brain.

Author

Nicholas A, de Magalhaes JP, Kraytsberg Y, Richfield EK, Levanon EY, and Khrapko K

Subjects

Adaptor Proteins, Signal Transducing genetics, Adaptor Proteins, Signal Transducing metabolism, Adenosine genetics, Adult, Aged, Aged, 80 and over, Aging genetics, Female, Humans, Inosine genetics, Male, Middle Aged, Receptors, GABA-A genetics, Receptors, GABA-A metabolism, Young Adult, Adenosine metabolism, Aging metabolism, Cerebral Cortex metabolism, Inosine metabolism, RNA Editing

Abstract

A-to-I editing is an adenosine-to-inosine modification of mRNA particularly widespread in the human brain, where it affects thousands of genes. A growing body of evidence suggests that A-to-I RNA editing is necessary for normal development and maintenance in mammals and that its deficiencies contribute to a number of pathological states. In this study, we examined whether mRNA editing levels of two mRNA species, CYFIP2 and GABRA3, change with aging. CYFIP2 has been implicated in synaptic maintenance, while GABRA3 is a GABA receptor subunit, a part of the major inhibitory neurotransmitter system in the CNS. The levels of mRNA editing were assessed in cortex samples of 20 subjects 22-102 years old. The data show an age-dependent statistically significant decrease in editing in CYFIP2. GABRA3 editing remained much more stable with age, implying that age-related decline of RNA editing is gene-specific. This is the first report of age-dependent decline in A-to-I editing. Further examination of these and other vulnerable genes may reveal specific RNA editing mechanisms that contribute to the aging phenotype., ((c) 2010 Elsevier Ireland Ltd. All rights reserved.)

Published

2010

216. A computational screen for site selective A-to-I editing detects novel sites in neuron specific Hu proteins.

Author

Ensterö M, Akerborg O, Lundin D, Wang B, Furey TS, Ohman M, and Lagergren J

Subjects

Adenosine metabolism, Alu Elements genetics, Animals, Base Sequence, Computational Biology methods, Mice, Molecular Sequence Data, Phylogeny, RNA chemistry, RNA metabolism, RNA-Binding Proteins metabolism, Sequence Analysis, RNA, Adenosine genetics, Genome, Inosine genetics, Neurons metabolism, RNA Editing, RNA-Binding Proteins chemistry

Abstract

Background: Several bioinformatic approaches have previously been used to find novel sites of ADAR mediated A-to-I RNA editing in human. These studies have discovered thousands of genes that are hyper-edited in their non-coding intronic regions, especially in alu retrotransposable elements, but very few substrates that are site-selectively edited in coding regions. Known RNA edited substrates suggest, however, that site selective A-to-I editing is particularly important for normal brain development in mammals., Results: We have compiled a screen that enables the identification of new sites of site-selective editing, primarily in coding sequences. To avoid hyper-edited repeat regions, we applied our screen to the alu-free mouse genome. Focusing on the mouse also facilitated better experimental verification. To identify candidate sites of RNA editing, we first performed an explorative screen based on RNA structure and genomic sequence conservation. We further evaluated the results of the explorative screen by determining which transcripts were enriched for A-G mismatches between the genomic template and the expressed sequence since the editing product, inosine (I), is read as guanosine (G) by the translational machinery. For expressed sequences, we only considered coding regions to focus entirely on re-coding events. Lastly, we refined the results from the explorative screen using a novel scoring scheme based on characteristics for known A-to-I edited sites. The extent of editing in the final candidate genes was verified using total RNA from mouse brain and 454 sequencing., Conclusions: Using this method, we identified and confirmed efficient editing at one site in the Gabra3 gene. Editing was also verified at several other novel sites within candidates predicted to be edited. Five of these sites are situated in genes coding for the neuron-specific RNA binding proteins HuB and HuD.

Published

2010

217. Adenosine-to-inosine genetic recoding is required in the adult stage nervous system for coordinated behavior in Drosophila.

Author

Jepson JE and Reenan RA

Subjects

Adenosine genetics, Adenosine metabolism, Adenosine Deaminase genetics, Adenosine Deaminase metabolism, Animals, Behavior, Animal, Drosophila Proteins genetics, Drosophila Proteins metabolism, Drosophila melanogaster enzymology, Drosophila melanogaster genetics, Female, Inosine genetics, Inosine metabolism, Locomotion, Male, Nervous System growth & development, Nervous System metabolism, Drosophila melanogaster growth & development, Drosophila melanogaster physiology, RNA Editing

Abstract

Adenosine deaminases acting on RNA (ADARs) catalyze the deamination of adenosine to inosine in double-stranded RNA templates, a process known as RNA editing. In Drosophila, multiple ADAR isoforms are generated from a single locus (dAdar) via post-transcriptional modifications. Collectively, these isoforms act to edit a wide range of transcripts involved in neuronal signaling, as well as the precursors of endogenous small interfering RNAs. The phenotypic consequences of a loss of dADAR activity have been well characterized and consist of profound behavioral defects manifested at the adult stage, including extreme uncoordination, seizures, and temperature-sensitive paralysis. However, the spatio-temporal requirements of adenosine to inosine editing for correct behavior are unclear. Using transgenic RNA interference, we show that network-wide editing in the nervous system is required for normal adult locomotion. Regulated restoration of editing activity demonstrates that the neuronal requirement of dADAR activity has a significant adult stage component. Furthermore we show that in relation to behavior there are no observable genetic interactions between dAdar and several loci encoding RNA interference components, suggesting that editing of neuronal transcripts is the key mode of ADAR activity for normal behavior in Drosophila.

Published

2009

218. RNA-specific adenosine deaminase ADAR1 suppresses measles virus-induced apoptosis and activation of protein kinase PKR.

Author

Toth AM, Li Z, Cattaneo R, and Samuel CE

Subjects

Adenosine genetics, Adenosine metabolism, Adenosine Deaminase genetics, Animals, Chlorocebus aethiops, HeLa Cells, Humans, Inosine genetics, Inosine metabolism, Interferon Regulatory Factor-3 genetics, Interferon Regulatory Factor-3 metabolism, Measles enzymology, Measles genetics, Measles virus genetics, Mutation, RNA Editing genetics, RNA, Double-Stranded genetics, RNA, Viral genetics, RNA-Binding Proteins, Vero Cells, eIF-2 Kinase genetics, Adenosine Deaminase metabolism, Apoptosis, Measles virus growth & development, RNA, Double-Stranded metabolism, RNA, Viral metabolism, eIF-2 Kinase metabolism

Abstract

ADAR1 (adenosine deaminase acting on RNA) catalyzes the conversion of adenosine to inosine, a process known as A-to-I editing. Extensive A-to-I editing has been described in viral RNAs isolated from the brains of patients persistently infected with measles virus, although the precise role of ADAR during measles virus infection remains unknown. We generated human HeLa cells stably deficient in ADAR1 ("ADAR1(kd) cells") through short hairpin RNA-mediated knockdown, and using these cells, we tested the effect of ADAR1 deficiency on measles virus (MVvac strain) growth and virus-induced cell death. We found that the growth of mutant viruses lacking expression of the viral accessory proteins V and C (V(ko) and C(ko), respectively) was decreased in ADAR1-deficient cells compared with ADAR1-sufficient cells. In addition, apoptosis was enhanced in ADAR1-deficient cells following infection with wild type and V(ko) virus but not following infection with C(ko) virus or treatment with tumor necrosis factor-alpha or staurosporine. Furthermore, in C(ko)-infected ADAR1-sufficient cells when ADAR1 did not protect against apoptosis, caspase cleavage of the ADAR1 p150 protein was detected. Finally, enhanced apoptosis in ADAR1(kd) cells following infection with wild type and V(ko) virus correlated with enhanced activation of PKR kinase and interferon regulatory factor IRF-3. Taken together, these results demonstrate that ADAR1 is a proviral, antiapoptotic host factor in the context of measles virus infection and suggest that the antiapoptotic activity of ADAR1 is achieved through suppression of activation of proapoptotic and double-stranded RNA-dependent activities, as exemplified by PKR and IRF-3.

Published

2009

219. Large-scale mRNA sequencing determines global regulation of RNA editing during brain development.

Author

Wahlstedt H, Daniel C, Ensterö M, and Ohman M

Subjects

Adenosine genetics, Adenosine Deaminase genetics, Adenosine Deaminase metabolism, Alternative Splicing, Animals, Blotting, Western, Brain embryology, DNA, Complementary chemistry, DNA, Complementary genetics, Gene Expression Regulation, Developmental, Inosine genetics, Mice, Mice, Inbred Strains, RNA-Binding Proteins, Receptor, Serotonin, 5-HT2C genetics, Receptor, Serotonin, 5-HT2C metabolism, Receptors, GABA-A genetics, Receptors, GABA-A metabolism, Reverse Transcriptase Polymerase Chain Reaction, Time Factors, Brain metabolism, RNA Editing, RNA, Messenger genetics, Sequence Analysis, DNA methods

Abstract

RNA editing by adenosine deamination has been shown to generate multiple isoforms of several neural receptors, often with profound effects on receptor function. However, little is known about the regulation of editing activity during development. We have developed a large-scale RNA sequencing protocol to determine adenosine-to-inosine (A-to-I) editing frequencies in the coding region of genes in the mammalian brain. Using the 454 Life Sciences (Roche) Amplicon Sequencing technology, we were able to determine even low levels of editing with high accuracy. The efficiency of editing for 28 different sites was analyzed during the development of the mouse brain from embryogenesis to adulthood. We show that, with few exceptions, the editing efficiency is low during embryogenesis, increasing gradually at different rates up to the adult mouse. The variation in editing gave receptors like HTR2C and GABA(A) (gamma-aminobutyric acid type A) a different set of protein isoforms during development from those in the adult animal. Furthermore, we show that this regulation of editing activity cannot be explained by an altered expression of the ADAR proteins but, rather, by the presence of a regulatory network that controls the editing activity during development.

Published

2009

220. A regulatory role of the Bateman domain of IMP dehydrogenase in adenylate nucleotide biosynthesis.

Author

Pimkin M, Pimkina J, and Markham GD

Subjects

Adenosine genetics, Catalysis, Escherichia coli genetics, Escherichia coli growth & development, Escherichia coli Proteins genetics, IMP Dehydrogenase genetics, Inosine genetics, Inosine metabolism, Mutation, Protein Structure, Tertiary, Adenosine biosynthesis, Escherichia coli enzymology, Escherichia coli Proteins metabolism, Guanosine Monophosphate biosynthesis, IMP Dehydrogenase metabolism

Abstract

The Bateman domain (CBS subdomain) of IMP dehydrogenase (IMPDH), a rate-limiting enzyme of the de novo GMP biosynthesis, is evolutionarily conserved but has no established function. Deletion of the Bateman domain has no effect on the in vitro IMPDH activity. We report that in vivo deletion of the Bateman domain of IMPDH in Escherichia coli (guaB(DeltaCBS)) sensitizes the bacterium to growth arrest by adenosine and inosine. These nucleosides exert their growth inhibitory effect via a dramatic increase in the intracellular adenylate nucleotide pool, which results in the enhanced allosteric inhibition of PRPP synthetase and consequently a PRPP deficit. The ensuing starvation for pyrimidine nucleotides culminates in growth arrest. Thus, deletion of the Bateman domain of IMPDH derepresses the synthesis of AMP from IMP. The growth inhibitory effect of inosine can be rescued by second-site suppressor mutations in the genes responsible for the conversion of inosine to AMP (gsk, purA, and purB) as well as by the prsA1 allele, which encodes a PRPP synthetase that is insensitive to allosteric inhibition by adenylate nucleotides. Importantly, the guaB(DeltaCBS) phenotype can be complemented in trans by a mutant guaB allele, which encodes a catalytically disabled IMPDH(C305A) protein containing an intact Bateman domain. We conclude that the Bateman domain of IMPDH is a negative trans-regulator of adenylate nucleotide synthesis, and that this role is independent of the catalytic function of IMPDH in the de novo GMP biosynthesis.

Published

2009

221. Gene regulation by SINES and inosines: biological consequences of A-to-I editing of Alu element inverted repeats.

Author

Chen LL and Carmichael GG

Subjects

Animals, Humans, Adenine metabolism, Alu Elements genetics, Gene Expression Regulation, Inosine genetics, Inverted Repeat Sequences genetics, RNA Editing genetics

Abstract

The Alu elements are conserved approximately 300 nucleotide long repeat sequences that belong to the SINE family of retrotransposons found abundantly in primate genomes. Although the vast majority of Alu elements appear to be genetically inert, it has been tempting to consider the great majority of them as "junk DNA." However, a growing line of evidence suggests that transcribed Alu RNAs are in fact functionally involved in a number of diverse biological processes. Pairs of inverted Alu repeats in RNA can form duplex structures that lead to A-to-I editing by the ADAR enzymes. In this review we discuss the possible biological effects of Alu editing, with particular focus on the regulation of gene expression by inverted Alu repeats in the 3'-UTR regions of mRNAs.

Published

2008

222. Newly identified ADAR-mediated A-to-I editing positions as a tool for ALS research.

Author

Kwak S, Nishimoto Y, and Yamashita T

Subjects

Animals, Humans, RNA-Binding Proteins, Adenosine genetics, Adenosine Deaminase metabolism, Amyotrophic Lateral Sclerosis enzymology, Amyotrophic Lateral Sclerosis genetics, Inosine genetics, RNA Editing, Research

Abstract

Among the extensively occurring adenosine to inosine (A-to-I) conversions in RNA, RNA editing at the GluR2 Q/R site is crucial for the survival of mammalian organisms. Editing at this site is incomplete in the motor neurons of patients with sporadic amyotrophic lateral sclerosis (ALS). Adenosine deaminase acting on RNA type 2 (ADAR2) specifically mediates GluR2 Q/R site-editing, hence, it is likely a molecule relevant to the pathogenesis of sporadic ALS. Since no other transcript with ADAR2-mediated A-to-I positions is abundantly expressed in most neurons, the editors at the newly identified A-to-I positions were investigated. CYFIP2 and FLNA mRNAs were identified together with mRNAs having known ADAR2-mediated editing positions in ADAR2-immunoprecipitates of the human cerebellum, indicating that these mRNAs probably possessed ADAR2-mediated positions. Furthermore, an in vitro RNAi knockdown system demonstrated that the CYFIP2 mRNA K/E site and the BLCAP mRNA Y/C site were edited predominantly by ADAR2 and ADAR1, respectively. CYFIP2 mRNA was ubiquitously expressed and particularly abundant in the central nervous system. The extent of CYFIP2 K/E site-editing was between 30% and 80% in the central nervous system. Therefore, the extent of CYFIP2 K/E site-editing may be an additional marker for ADAR2 activity in neuronal and other types of cells in vivo, as well as in vitro, and thus is considered to be a good tool for sporadic ALS research.

Published

2008

223. A-to-I RNA editing and cancer: from pathology to basic science.

Author

Gallo A and Galardi S

Subjects

Adenosine Deaminase metabolism, Animals, Humans, Neoplasms enzymology, Neoplasms pathology, RNA-Binding Proteins, Substrate Specificity, Adenosine genetics, Inosine genetics, Neoplasms genetics, RNA Editing genetics

Abstract

In eukaryotes mRNA transcripts are extensively processed by different post-transcriptional events such as alternative splicing and RNA editing in order to generate many different mRNAs from the same gene, increasing the transcriptome and then the proteome. The most frequent RNA editing mechanism in mammals involves the conversion of specific adenosines into inosines by the ADAR family of enzymes. This editing event can change both the sequence and the secondary structure of RNA molecules, with important consequences on both the final proteins and regulatory RNAs. Alteration in RNA editing has been connected to numerous human pathologies and recent studies have demonstrated its importance in tumor progression.

Published

2008

224. Miscoding properties of 2'-deoxyinosine, a nitric oxide-derived DNA Adduct, during translesion synthesis catalyzed by human DNA polymerases.

Author

Yasui M, Suenaga E, Koyama N, Masutani C, Hanaoka F, Gruz P, Shibutani S, Nohmi T, Hayashi M, and Honma M

Subjects

Base Sequence, DNA biosynthesis, DNA Adducts metabolism, DNA Primers metabolism, DNA Replication physiology, DNA-Directed DNA Polymerase physiology, Humans, Inosine genetics, Inosine pharmacology, Models, Biological, Molecular Sequence Data, Mutation physiology, Nitric Oxide metabolism, Nitric Oxide pharmacology, Substrate Specificity, Templates, Genetic, DNA Adducts pharmacology, DNA Repair drug effects, DNA Replication drug effects, DNA-Directed DNA Polymerase metabolism, Inosine analogs & derivatives

Abstract

Chronic inflammation involving constant generation of nitric oxide (*NO) by macrophages has been recognized as a factor related to carcinogenesis. At the site of inflammation, nitrosatively deaminated DNA adducts such as 2'-deoxyinosine (dI) and 2'-deoxyxanthosine are primarily formed by *NO and may be associated with the development of cancer. In this study, we explored the miscoding properties of the dI lesion generated by Y-family DNA polymerases (pols) using a new fluorescent method for analyzing translesion synthesis. An oligodeoxynucleotide containing a single dI lesion was used as a template in primer extension reaction catalyzed by human DNA pols to explore the miscoding potential of the dI adduct. Primer extension reaction catalyzed by pol alpha was slightly retarded prior to the dI adduct site; most of the primers were extended past the lesion. Pol eta and pol kappaDeltaC (a truncated form of pol kappa) readily bypassed the dI lesion. The fully extended products were analyzed by using two-phased PAGE to quantify the miscoding frequency and specificity occurring at the lesion site. All pols, that is, pol alpha, pol eta, and pol kappaDeltaC, promoted preferential incorporation of 2'-deoxycytidine monophosphate (dCMP), the wrong base, opposite the dI lesion. Surprisingly, no incorporation of 2'-deoxythymidine monophosphate, the correct base, was observed opposite the lesion. Steady-state kinetic studies with pol alpha, pol eta, and pol kappaDeltaC indicated that dCMP was preferentially incorporated opposite the dI lesion. These pols bypassed the lesion by incorporating dCMP opposite the lesion and extended past the lesion. These relative bypass frequencies past the dC:dI pair were at least 3 orders of magnitude higher than those for the dT:dI pair. Thus, the dI adduct is a highly miscoding lesion capable of generating A-->G transition. This ()NO-induced adduct may play an important role in initiating inflammation-driven carcinogenesis.

Published

2008

225. Identification and relative quantification of adenosine to inosine editing in serotonin 2c receptor mRNA by CE.

Author

Poyau A, Vincent L, Berthommé H, Paul C, Nicolas B, Pujol JF, and Madjar JJ

Subjects

Adenosine genetics, Animals, Base Sequence, Brain metabolism, DNA Primers genetics, DNA, Complementary genetics, DNA, Complementary isolation & purification, Inosine genetics, Mice, Mice, Inbred BALB C, Rats, Rats, Wistar, Electrophoresis, Capillary methods, RNA Editing, RNA, Messenger genetics, RNA, Messenger metabolism, Receptor, Serotonin, 5-HT2C genetics

Abstract

A new method has been developed allowing the identification and relative quantification of different forms of mRNA after RNA editing. This method was applied to the serotonin 2c receptor mRNA that potentially exhibits 32 different forms after adenosine to inosine editing at five different sites located in a row of 13 nucleotides. CE was used to characterize fluorescently labeled ssDNA molecules on the basis of their conformational polymorphism. The relative amount of these 32 mRNA forms has been estimated by measuring the fluorescence intensity of each individual DNA strand. Accuracy of quantification was established by diluting one form into another or into a mixture of cDNA, showing linear and precise proportion of each form (0.06

Published

2007

226. RNA binding-independent dimerization of adenosine deaminases acting on RNA and dominant negative effects of nonfunctional subunits on dimer functions.

Author

Valente L and Nishikura K

Subjects

Adenosine metabolism, Adenosine Deaminase genetics, Catalytic Domain genetics, Dimerization, Humans, Inosine genetics, Point Mutation, Protein Binding genetics, RNA, Double-Stranded genetics, RNA-Binding Proteins, Substrate Specificity genetics, Adenosine Deaminase metabolism, RNA Editing physiology, RNA, Double-Stranded metabolism

Abstract

RNA editing that converts adenosine to inosine in double-stranded RNA (dsRNA) is mediated by adenosine deaminases acting on RNA (ADAR). ADAR1 and ADAR2 form respective homodimers, and this association is essential for their enzymatic activities. In this investigation, we set out experiments aiming to determine whether formation of the homodimer complex is mediated by an amino acid interface made through protein-protein interactions of two monomers or via binding of the two subunits to a dsRNA substrate. Point mutations were created in the dsRNA binding domains (dsRBDs) that abolished all RNA binding, as tested for two classes of ADAR ligands, long and short dsRNA. The mutant ADAR dimer complexes were intact, as demonstrated by their ability to co-purify in a sequential affinity-tagged purification and also by their elution at the dimeric fraction position on a size fractionation column. Our results demonstrated ADAR dimerization independent of their binding to dsRNA, establishing the importance of protein-protein interactions for dimer formation. As expected, these mutant ADARs could no longer perform their catalytic function due to the loss in substrate binding. Surprisingly, a chimeric dimer consisting of one RNA binding mutant monomer and a wild type partner still abolished its ability to bind and edit its substrate, indicating that ADAR dimers require two subunits with functional dsRBDs for binding to a dsRNA substrate and then for editing activity to occur.

Published

2007

227. Towards elucidation of the mechanism of UV1C, a deoxyribozyme with photolyase activity.

Author

Chinnapen DJ and Sen D

Subjects

Base Sequence, Catalysis drug effects, Cross-Linking Reagents pharmacology, Deoxyribose chemistry, Deoxyribose metabolism, Guanine metabolism, Inosine genetics, Models, Biological, Molecular Sequence Data, Nucleic Acid Conformation drug effects, Point Mutation genetics, Pyrimidine Dimers chemistry, Pyrimidine Dimers metabolism, RNA chemistry, Ribose chemistry, Ribose metabolism, Substrate Specificity drug effects, DNA, Catalytic metabolism, Deoxyribodipyrimidine Photo-Lyase metabolism

Abstract

Among the unexpected chemistries that can be catalyzed by nucleic acid enzymes is photochemistry. We have reported the in vitro selection of a small, cofactor-independent deoxyribozyme, UV1C, capable of repairing thymine dimers in a DNA substrate, most optimally with light at a wavelength of >300 nm. We hypothesized that a guanine quadruplex functioned both as a light antenna and an electron source for the repair of the substrate within the enzyme-substrate complex. Here, we report structural and mechanistic investigations of that hypothesis. Contact-crosslinking and guanosine to inosine mutational studies reveal that the thymine dimer and the guanine quadruplex are positioned close to each other in the deoxyribozyme-substrate complex, and permit us to refine the structure and topology of the folded deoxyribozyme. In exploring the substrate utilization capabilities of UV1C, we find it to be able to repair uracil dimers as well as thymine dimers, as long as they are present in an overall deoxyribonucleotide milieu. Some surprising similarities with bacterial CPD photolyase enzymes are noted.

Published

2007

228. High-throughput screening for functional adenosine to inosine RNA editing systems.

Author

Pokharel S and Beal PA

Subjects

Animals, Base Sequence, Humans, Models, Molecular, Molecular Sequence Data, Nucleic Acid Conformation, Plasmids, RNA, Messenger genetics, RNA-Binding Proteins, Saccharomyces cerevisiae enzymology, Saccharomyces cerevisiae genetics, Substrate Specificity, Adenosine chemistry, Adenosine genetics, Adenosine Deaminase genetics, Adenosine Deaminase metabolism, Inosine chemistry, Inosine genetics, RNA Editing genetics, RNA, Messenger chemistry

Abstract

Deamination of adenosines within messenger RNAs catalyzed by adenosine deaminases that act on RNA (ADAR) enzymes generates inosines at the corresponding nucleotide positions. Because inosine is decoded as guanosine, this reaction can lead to codon changes and the introduction of amino acids into a gene product not encoded in the gene. Translation of the different coding strands created by this process leads to protein structural diversity in the parent organism and is necessary for nervous system function in metazoa. The basis for selective editing of adenosines within certain codons is not well understood at the structural/biochemical level. Here we describe a high-throughput screen for ADAR/substrate combinations capable of RNA editing that can be carried out in the yeast Saccharomyces cerevisiae growing on agar plates. Results from the screening of libraries of human ADAR2 mutants and libraries of RNA substrates shed light on structure-activity relationships in the ADAR-catalyzed adenosine to inosine RNA editing reaction.

Published

2006

229. A-to-I pre-mRNA editing of the serotonin 2C receptor: comparisons among inbred mouse strains.

Author

Du Y, Davisson MT, Kafadar K, and Gardiner K

Subjects

Adenosine genetics, Animals, Base Sequence, Brain metabolism, Cloning, Molecular, Exons, Genetic Variation, Inosine genetics, Introns, Mice, Mice, Inbred Strains, Protein Isoforms genetics, Species Specificity, RNA Editing, RNA Precursors genetics, RNA Precursors metabolism, Receptor, Serotonin, 5-HT2C genetics

Abstract

The serotonin receptor 5HT2CR pre-mRNA is subject to adenosine deamination (RNA editing) at five residues located within a 15 nucleotide stretch of the coding region. Such changes of adenosine to inosine (A-to-I) can produce 32 mRNA variants, encoding 24 different protein isoforms, some of which vary in biochemical and pharmacological properties. Because serotonin mediates diverse neurological processes relevant to behavior and because inbred mouse strains vary in their responses to tests of learning and behavior, we have examined the A-to-I editing patterns of the 5HT2CR mRNA in whole brains from eight mouse strains. By sequencing approximately 100 clones from individual mice, we generated detailed information on levels of editing at each site and patterns of editing that identify a total of 28 mRNA and 20 protein isoforms. Significant differences between individuals from different strains were found in total editing frequency, in the proportion of transcripts with 1 and 4 edited sites, in editing frequency at the A, B, E and D sites, in amino acid frequencies at positions 157 and 161, and in subsets of major protein isoforms. Primer extension assays were used to show that individuals within strains (six C3H.B-+rd1 and four 129SvImrJ) displayed no significant differences in any feature. These findings suggest that genetic background contributes to subtle variation in 5HT2CR mRNA editing patterns which may have consequences for pharmacological treatments and behavioral testing.

Published

2006

230. Advantage of using inosine at the 3' termini of 16S rRNA gene universal primers for the study of microbial diversity.

Author

Ben-Dov E, Shapiro OH, Siboni N, and Kushmaro A

Subjects

Bacteria genetics, Ecosystem, Genes, rRNA, Industrial Waste, Inosine genetics, Molecular Sequence Data, Phylogeny, Sequence Analysis, DNA, Sodium Chloride, Water Microbiology, Bacteria classification, DNA Primers genetics, Genetic Variation, Polymerase Chain Reaction methods, RNA, Ribosomal, 16S genetics

Abstract

To overcome the shortcomings of universal 16S rRNA gene primers 8F and 907R when studying the diversity of complex microbial communities, the 3' termini of both primers were replaced with inosine. A comparison of the clone libraries derived using both primer sets showed seven bacterial phyla amplified by the altered primer set (8F-I/907R-I) whereas the original set amplified sequences belonging almost exclusively to Proteobacteria (95.8%). Sequences belonging to Firmicutes (42.6%) and Thermotogae (9.3%) were more abundant in a library obtained by using 8F-I/907R-I at a PCR annealing temperature of 54 degrees C, while Proteobacteria sequences were more frequent (62.7%) in a library obtained at 50 degrees C, somewhat resembling the result obtained using the original primer set. The increased diversity revealed by using primers 8F-I/907R-I confirms the usefulness of primers with inosine at the 3' termini in studying the microbial diversity of environmental samples.

Published

2006

231. Adenosine-to-inosine RNA editing: perspectives and predictions.

Author

Hoopengardner B

Subjects

Adenosine chemistry, Animals, Genetic Variation genetics, Genome genetics, Humans, Inosine chemistry, Adenosine genetics, Inosine genetics, RNA Editing genetics

Abstract

Adenosine-to-Inosine RNA editing introduces changes in RNA transcripts via a post-transcriptional mechanism, the hydrolytic deamination of adenosine (A) to inosine (I) which is interpreted as guanosine by cellular machineries. Adenosine deaminases that act on RNA (ADAR) enzymes catalyze editing in double-stranded (ds) RNA substrates.

Published

2006

232. Extensive adenosine-to-inosine editing detected in Alu repeats of antisense RNAs reveals scarcity of sense-antisense duplex formation.

Author

Kawahara Y and Nishikura K

Subjects

Adenosine genetics, Humans, Inosine genetics, Introns genetics, Untranslated Regions genetics, Alu Elements genetics, Base Pairing genetics, RNA Editing genetics, RNA, Antisense genetics, RNA, Double-Stranded genetics

Abstract

One type of RNA editing converts adenosine residues to inosine in double-stranded regions. Recent transcriptome analysis has revealed that numerous Alu repeats, present within introns and untranslated regions of human transcripts, are subject to this A-->I RNA editing. Furthermore, it revealed global transcription of antisense RNAs. Here, we demonstrate that antisense RNAs are also edited extensively but only in their Alu repeat sequences, and editing does not extend to the surrounding sequence. Our findings imply that sense and antisense RNAs form two separate intramolecular double-stranded RNAs consisting of inversely oriented Alu repeats, but rarely form intermolecular duplexes.

Published

2006

233. A-to-I RNA editing and human disease.

Author

Maas S, Kawahara Y, Tamburro KM, and Nishikura K

Subjects

Adenosine genetics, Amino Acid Sequence, Amyotrophic Lateral Sclerosis genetics, Animals, Epilepsy genetics, Humans, Inosine genetics, Measles genetics, Mice, Models, Genetic, Molecular Sequence Data, Mutation, RNA Processing, Post-Transcriptional, Skin Diseases genetics, Adenosine chemistry, Inosine chemistry, RNA Editing genetics

Abstract

The post-transcriptional modification of mammalian transcripts by A-to-I RNA editing has been recognized as an important mechanism for the generation of molecular diversity and also regulates protein function through recoding of genomic information. As the molecular players of editing are characterized and an increasing number of genes become identified that are subject to A-to-I modification, the potential impact of editing on the etiology or progression of human diseases is realized. Here we review the recent knowledge on where disturbances in A-to-I RNA editing have been correlated with human disease phenotypes.

Published

2006

234. Letter from the editor: Adenosine-to-inosine RNA editing in Alu repeats in the human genome.

Author

Levanon K, Eisenberg E, Rechavi G, and Levanon EY

Subjects

Base Sequence, Computational Biology methods, Humans, Species Specificity, Adenosine genetics, Alu Elements genetics, Evolution, Molecular, Genome, Human, Inosine genetics, RNA Editing genetics

Abstract

Adenosine-to-inosine (A-to-I) RNA editing increases the complexity of the human transcriptome and is essential for maintenance of normal life in mammals. Most A-to-I substitutions occur within repetitive elements in the genome, mainly in Alu repeats. The phenomenon of A-to-I editing is far less abundant in mice, rats, chickens and flies than in humans, which correlates with the relative under-representation of Alu repeats in these non-primate genomes. Here, we review the recent results of bioinformatic and laboratory approaches that have estimated the extent of the editing phenomenon. We discuss the possible biological relevance of the editing pathway, its possible interaction with other cellular pathways that respond to double-stranded RNA and its possible contribution to the accelerated evolution of primates.

Published

2005

235. A bioinformatic screen for novel A-I RNA editing sites reveals recoding editing in BC10.

Author

Clutterbuck DR, Leroy A, O'Connell MA, and Semple CA

Subjects

Adenosine genetics, Animals, Base Sequence, Humans, Inosine genetics, Mice, Molecular Sequence Data, Sequence Homology, Nucleic Acid, Algorithms, Chromosome Mapping methods, Neoplasm Proteins genetics, RNA Editing genetics, Sequence Alignment methods, Sequence Analysis, RNA methods

Abstract

Motivation: Recent studies have demonstrated widespread adenosine-inosine RNA editing in non-coding sequence. However, the extent of editing in coding sequences has remained unknown. For many of the known sites, editing can be observed in multiple species and often occurs in well-conserved sequences. In addition, they often occur within imperfect inverted repeats and in clusters. Here we present a bioinformatic approach to identify novel sites based on these shared features. Mismatches between genomic and expressed sequences were filtered to remove the main sources of false positives, and then prioritized based on these features. This protocol is tailored to identifying specific recoding editing sites, rather than sites in non-coding repeat sequences., Results: Our protocol is more sensitive for identifying known coding editing sites than any previously published mammalian screen. A novel multiply edited transcript, BC10, was identified and experimentally verified. BC10 is highly conserved across a range of metazoa and has been implicated in two forms of cancer.

Published

2005

236. Inosine substitutions demonstrate that intramolecular DNA quadruplexes adopt different conformations in the presence of sodium and potassium.

Author

Risitano A and Fox KR

Subjects

Animals, DNA genetics, G-Quadruplexes, Humans, Inosine genetics, Oligonucleotides chemistry, Tetrahymena genetics, DNA chemistry, Inosine chemistry, Nucleic Acid Conformation, Potassium chemistry, Sodium chemistry

Abstract

We have examined the stability of fluorescently-labelled oligonucleotides that are based on the human telomeric repeat [(GGGTTA)(3)GGG], in which one of the guanines in turn is substituted with inosine. We show that the relative stability of the substitutions is different in the presence of sodium and potassium. The data for potassium suggest a parallel arrangement of the strands, while the sodium form is mixed parallel and antiparallel.

Published

2005

237. Molecular determinants and guided evolution of species-specific RNA editing.

Author

Reenan RA

Subjects

Adenosine genetics, Amino Acid Sequence, Animals, Base Sequence, Exons genetics, Inosine genetics, Introns genetics, Models, Molecular, Molecular Sequence Data, Mutation genetics, Phylogeny, RNA Precursors genetics, RNA Precursors metabolism, Species Specificity, Synaptotagmin I, Synaptotagmins, Time Factors, Calcium-Binding Proteins genetics, Evolution, Molecular, Genomics, Membrane Glycoproteins genetics, Nerve Tissue Proteins genetics, RNA Editing genetics

Abstract

Most RNA editing systems are mechanistically diverse, informationally restorative, and scattershot in eukaryotic lineages. In contrast, genetic recoding by adenosine-to-inosine RNA editing seems common in animals; usually, altering highly conserved or invariant coding positions in proteins. Here I report striking variation between species in the recoding of synaptotagmin I (sytI). Fruitflies, mosquitoes and butterflies possess shared and species-specific sytI editing sites, all within a single exon. Honeybees, beetles and roaches do not edit sytI. The editing machinery is usually directed to modify particular adenosines by information stored in intron-mediated RNA structures. Combining comparative genomics of 34 species with mutational analysis reveals that complex, multi-domain, pre-mRNA structures solely determine species-appropriate RNA editing. One of these is a previously unreported long-range pseudoknot. I show that small changes to intronic sequences, far removed from an editing site, can transfer the species specificity of editing between RNA substrates. Taken together, these data support a phylogeny of sytI gene editing spanning more than 250 million years of hexapod evolution. The results also provide models for the genesis of RNA editing sites through the stepwise addition of structural domains, or by short walks through sequence space from ancestral structures.

Published

2005

238. Structure of an oligodeoxynucleotide containing a butadiene oxide-derived N1 beta-hydroxyalkyl deoxyinosine adduct in the human N-ras codon 61 sequence.

Author

Scholdberg TA, Merritt WK, Dean SM, Kowalcyzk A, Harris CM, Harris TM, Rizzo CJ, Lloyd RS, and Stone MP

Subjects

Alkylating Agents chemistry, Alkylating Agents metabolism, Base Sequence, Butadienes metabolism, Codon metabolism, DNA Adducts genetics, DNA Adducts metabolism, Epoxy Compounds metabolism, Humans, Inosine genetics, Inosine metabolism, Magnetic Resonance Spectroscopy methods, Models, Molecular, Mutagenesis, Site-Directed, Nucleic Acid Conformation, Oligodeoxyribonucleotides genetics, Oligodeoxyribonucleotides metabolism, Protons, Thermodynamics, Butadienes chemistry, Codon chemistry, Codon genetics, DNA Adducts chemistry, Epoxy Compounds chemistry, Genes, ras genetics, Inosine analogs & derivatives, Inosine chemistry, Oligodeoxyribonucleotides chemistry

Abstract

The solution structure of the N1-(1-hydroxy-3-buten-2(S)-yl)-2'-deoxyinosine adduct arising from the alkylation of adenine N1 by butadiene epoxide (BDO), followed by deamination to deoxyinosine, was determined, in the oligodeoxynucleotide d(CGGACXAGAAG).d(CTTCTCGTCCG). This oligodeoxynucleotide contained the BDO adduct at the second position of codon 61 of the human N-ras protooncogene, and was named the ras61 S-N1-BDO-(61,2) adduct. (1)H NMR revealed a weak C(5) H1' to X(6) H8 NOE, followed by an intense X(6) H8 to X(6) H1' NOE. Simultaneously, the X(6) H8 to X(6) H3' NOE was weak. The resonance arising from the T(17) imino proton was not observed. (1)H NOEs between the butadiene moiety and the DNA positioned the adduct in the major groove. Structural refinement based upon a total of 364 NOE-derived distance restraints yielded a structure in which the modified deoxyinosine was in the high syn conformation about the glycosyl bond, and T(17), the complementary nucleotide, was stacked into the helix, but not hydrogen bonded with the adducted inosine. The refined structure provided a plausible hypothesis as to why this N1 deoxyinosine adduct strongly coded for the incorporation of dCTP during trans lesion DNA replication, both in Escherichia coli [Rodriguez, D. A., Kowalczyk, A., Ward, J. B. J., Harris, C. M., Harris, T. M., and Lloyd, R. S. (2001) Environ. Mol. Mutagen. 38, 292-296], and in mammalian cells [Kanuri, M., Nechev, L. N., Tamura, P. J., Harris, C. M., Harris, T. M., and Lloyd, R. S. (2002) Chem. Res. Toxicol. 15, 1572-1580]. Rotation of the N1 deoxyinosine adduct into the high syn conformation may facilitate incorporation of dCTP via Hoogsteen-type templating with deoxyinosine, thus generating A-to-G mutations.

Published

2005

239. P-site pairing subtleties revealed by the effects of different tRNAs on programmed translational bypassing where anticodon re-pairing to mRNA is separated from dissociation.

Author

Bucklin DJ, Wills NM, Gesteland RF, and Atkins JF

Subjects

Anticodon genetics, Arginine genetics, Base Sequence, Codon genetics, Codon metabolism, Cytosine metabolism, DNA, Bacterial genetics, DNA, Bacterial metabolism, Guanine metabolism, Inosine genetics, Nucleic Acid Conformation, Nucleoside Q genetics, Nucleoside Q metabolism, RNA, Messenger genetics, RNA, Transfer genetics, Ribosomes metabolism, Serine genetics, Valine genetics, Anticodon metabolism, Protein Biosynthesis, RNA, Messenger metabolism, RNA, Transfer metabolism

Abstract

Programmed ribosomal bypassing occurs in decoding phage T4 gene 60 mRNA. Half the ribosomes bypass a 50 nucleotide gap between codons 46 and 47. Peptidyl-tRNA dissociates from the "take-off" GGA, codon 46, and re-pairs to mRNA at a matched GGA "landing site" codon directly 5' of codon 47 where translation resumes. The system described here allows the contribution of peptidyl-tRNA re-pairing to be measured independently of dissociation. The matched GGA codons have been replaced by 62 other matched codons, giving a wide range of bypassing efficiencies. Codons with G or C in either or both of the first two codon positions yielded high levels of bypassing. The results are compared with those from a complementary study of non-programmed bypassing, where the combined effects of peptidyl-tRNA dissociation and reassociation were measured. The wild-type, GGA, matched codons are the most efficient in their gene 60 context in contrast to the relatively low value in the non-programmed bypassing study.

Published

2005

240. Editing the message from A to I.

Author

Nishikura K

Subjects

Base Pair Mismatch genetics, Base Pairing genetics, Base Sequence, Expressed Sequence Tags, Humans, Molecular Sequence Data, Sequence Alignment methods, Sequence Homology, Nucleic Acid, Adenosine genetics, Chromosome Mapping methods, Inosine genetics, RNA Editing genetics, Sequence Analysis, DNA methods, Sequence Analysis, RNA methods, Transcription Factors genetics

Published

2004

241. Systematic identification of abundant A-to-I editing sites in the human transcriptome.

Author

Levanon EY, Eisenberg E, Yelin R, Nemzer S, Hallegger M, Shemesh R, Fligelman ZY, Shoshan A, Pollock SR, Sztybel D, Olshansky M, Rechavi G, and Jantsch MF

Subjects

Base Pair Mismatch genetics, Base Pairing genetics, Base Sequence, Expressed Sequence Tags, Humans, Molecular Sequence Data, Sequence Alignment methods, Sequence Homology, Nucleic Acid, Adenosine genetics, Chromosome Mapping methods, Inosine genetics, RNA Editing genetics, Sequence Analysis, DNA methods, Sequence Analysis, RNA methods, Transcription Factors genetics

Abstract

RNA editing by members of the ADAR (adenosine deaminases acting on RNA) family leads to site-specific conversion of adenosine to inosine (A-to-I) in precursor messenger RNAs. Editing by ADARs is believed to occur in all metazoa, and is essential for mammalian development. Currently, only a limited number of human ADAR substrates are known, whereas indirect evidence suggests a substantial fraction of all pre-mRNAs being affected. Here we describe a computational search for ADAR editing sites in the human transcriptome, using millions of available expressed sequences. We mapped 12,723 A-to-I editing sites in 1,637 different genes, with an estimated accuracy of 95%, raising the number of known editing sites by two orders of magnitude. We experimentally validated our method by verifying the occurrence of editing in 26 novel substrates. A-to-I editing in humans primarily occurs in noncoding regions of the RNA, typically in Alu repeats. Analysis of the large set of editing sites indicates the role of editing in controlling dsRNA stability.

Published

2004

242. Sequence saturation mutagenesis (SeSaM): a novel method for directed evolution.

Author

Wong TS, Tee KL, Hauer B, and Schwaneberg U

Subjects

Deoxyadenine Nucleotides genetics, Green Fluorescent Proteins, Inosine genetics, Luminescent Proteins genetics, Mutagenesis, Insertional, Sequence Deletion, Thionucleotides genetics, DNA genetics, Directed Molecular Evolution methods, Inosine analogs & derivatives, Mutagenesis, Point Mutation genetics

Abstract

Sequence saturation mutagenesis (SeSaM) is a conceptually novel and practically simple method that truly randomizes a target sequence at every single nucleotide position. A SeSaM experiment can be accomplished within 2-3 days and comprises four steps: generating a pool of DNA fragments with random length, 'tailing' the DNA fragments with universal base using terminal transferase at 3'-termini, elongating DNA fragments in a PCR to the full-length genes using a single-stranded template and replacing the universal bases by standard nucleotides. Random mutations are created at universal sites due to the promiscuous base-pairing property of universal bases. Using enhanced green fluorescence protein as the model system and deoxyinosine as the universal base, we proved by sequencing 100 genes the concept of the SeSaM method and achieved a random distribution of mutations with the mutational bias expected for deoxyinosine.

Published

2004

243. RNA editing and alternative splicing of human serotonin 2C receptor in schizophrenia.

Author

Dracheva S, Elhakem SL, Marcus SM, Siever LJ, McGurk SR, and Haroutunian V

Subjects

Adenosine genetics, Aged, Case-Control Studies, Female, Humans, Inosine genetics, Male, Prefrontal Cortex metabolism, Protein Isoforms genetics, Protein Isoforms metabolism, RNA, Messenger metabolism, Reverse Transcriptase Polymerase Chain Reaction methods, Schizophrenia metabolism, Alternative Splicing, RNA Editing, Receptor, Serotonin, 5-HT2C genetics, Schizophrenia genetics

Abstract

Serotonin 2C receptor (5-HT2CR) heterogeneity in the brain occurs mostly from two different sources: (i) 5-HT2CR mRNA undergoes adenosine-to-inosine editing events at five positions, which leads to amino acid substitutions that produce receptor variants with different pharmacological properties; (ii) 5-HT2CR mRNA is alternatively spliced, resulting in a truncated mRNA isoform (5-HT2CR-tr) which encodes a non-functional serotonin receptor. 5-HT2CR mRNA editing efficiencies and the expression of the full-length and the truncated 5-HT2CR mRNA splice isoforms were analyzed in the prefrontal cortex of elderly subjects with schizophrenia vs. matched controls (ns = 15). No significant differences were found, indicating that there are no alterations in editing or alternative splicing of 5-HT2CRs that are associated with schizophrenia in persons treated with antipsychotic medications. Quantitation of 5-HT2CR and 5-HT2CR-tr mRNA variants revealed that the expression of 5-HT2CR-tr was approximately 50% of that observed for the full-length isoform.

Published

2003

244. ADAR2 A-->I editing: site selectivity and editing efficiency are separate events.

Author

Källman AM, Sahlin M, and Ohman M

Subjects

Adenosine genetics, Adenosine metabolism, Adenosine Deaminase metabolism, Animals, Base Sequence, Binding Sites genetics, Electrophoretic Mobility Shift Assay, Inosine genetics, Inosine metabolism, Molecular Sequence Data, Nucleic Acid Conformation, Oligoribonucleotides chemistry, Oligoribonucleotides genetics, Oligoribonucleotides metabolism, RNA Precursors chemistry, RNA Precursors genetics, RNA Precursors metabolism, RNA-Binding Proteins metabolism, Rats, Receptors, AMPA genetics, Recombinant Proteins metabolism, Substrate Specificity, Adenosine Deaminase genetics, RNA Editing

Abstract

ADAR enzymes, adenosine deaminases that act on RNA, form a family of RNA editing enzymes that convert adenosine to inosine within RNA that is completely or largely double-stranded. Site-selective A-->I editing has been detected at specific sites within a few structured pre-mRNAs of metazoans. We have analyzed the editing selectivity of ADAR enzymes and have chosen to study the naturally edited R/G site in the pre-mRNA of the glutamate receptor subunit B (GluR-B). A comparison of editing by ADAR1 and ADAR2 revealed differences in the specificity of editing. Our results show that ADAR2 selectively edits the R/G site, while ADAR1 edits more promiscuously at several other adenosines in the double-stranded stem. To further understand the mechanism of selective ADAR2 editing we have investigated the importance of internal loops in the RNA substrate. We have found that the immediate structure surrounding the editing site is important. A purine opposite to the editing site has a negative effect on both selectivity and efficiency of editing. More distant internal loops in the substrate were found to have minor effects on site selectivity, while efficiency of editing was found to be influenced. Finally, changes in the RNA structure that affected editing did not alter the binding abilities of ADAR2. Overall these findings suggest that binding and catalysis are independent events.

Published

2003

245. Molecular cloning of an unusual bicistronic cholecystokinin receptor mRNA expressed in chicken brain: a structural and functional expression study.

Author

Nilsson IB, Svensson SP, and Monstein HJ

Subjects

Amino Acid Sequence, Animals, Benzodiazepinones pharmacology, COS Cells, Chickens, Cloning, Molecular, DNA, Complementary genetics, Devazepide pharmacology, Gastrins chemistry, Gastrins pharmacology, Inosine analogs & derivatives, Inosine genetics, Molecular Sequence Data, Phenylurea Compounds pharmacology, Polymerase Chain Reaction methods, RNA, Messenger genetics, Radioligand Assay, Receptors, Cholecystokinin antagonists & inhibitors, Sequence Homology, Amino Acid, Sincalide pharmacology, Tetragastrin pharmacology, Brain metabolism, RNA, Messenger biosynthesis, Receptors, Cholecystokinin genetics, Receptors, Cholecystokinin metabolism

Abstract

This report describes the molecular cloning and pharmacological characterization of a transiently expressed chicken brain cholecystokinin receptor (CCK-CHR) in COS-7 cells. A polymerase chain reaction (PCR)-based cloning strategy was applied using: (1) an initial PCR with deoxyinosine-containing primers designed to target conserved regions in CCK receptors, followed by (2) rapid amplification of cDNA ends (RACE), and (3) full-length PCR of the CCK-CHR cDNA. The full-length cloned bicistronic CCK-CHR cDNA contained a short upstream open reading frame (uORF) coding for a putative six-amino-acid-long peptide of unknown function, followed by a long open reading frame (lORF) encoding the 436-amino-acid-long CCK-CHR receptor protein. At the amino acid level, the CCK-CHR shared approximately 50% homology with mammalian and Xenopus laevis CCK receptors. The pharmacological profile of CCK-CHR resembled that of CCK-B receptors using agonists (CCK-8, CCK-4, gastrin-17), whereas CCK-CHR showed higher affinity for the CCK-A receptor antagonist, devazepide, than for the CCK-B receptor antagonist, L-365,260. To the best of our knowledge, this is the first description and functional expression study of a cloned chicken CCK receptor cDNA.

Published

2003

246. Widespread inosine-containing mRNA in lymphocytes regulated by ADAR1 in response to inflammation.

Author

Yang JH, Luo X, Nie Y, Su Y, Zhao Q, Kabir K, Zhang D, and Rabinovici R

Subjects

Acute Disease, Adenosine Deaminase metabolism, Animals, Cell Division genetics, Cells, Cultured, Endotoxins, Inflammation immunology, Lymphocyte Activation genetics, Male, Mice, Mice, Inbred C57BL, RNA, Double-Stranded genetics, RNA, Messenger genetics, RNA-Binding Proteins, Up-Regulation, Adenosine Deaminase physiology, Inflammation genetics, Inosine genetics, RNA Editing, T-Lymphocyte Subsets immunology

Abstract

Adenosine-to-inosine (A-to-I) RNA editing is a post-transcriptional modification of pre-mRNA catalysed by an RNA-specific adenosine deaminase (ADAR). A-to-I RNA editing has been previously reported in the pre-mRNAs of brain glutamate and serotonin receptors and in lung tissue during inflammation. Here we report that systemic inflammation markedly induces inosine-containing mRNA to approximately 5% of adenosine in total mRNA. Induction was the result of up-regulation of A-to-I RNA editing as both dsRNA editing activity and ADAR1 expression were increased in the spleen, thymus and peripheral lymphocytes from endotoxin-treated mice. Up-regulation of ADAR1 was confirmed in vitro in T lymphocytes and macrophages stimulated with a variety of inflammatory mediators including tumour necrosis factor-alpha and interferon-gamma. A late induction of RNA editing was detected in concanavalin A-activated splenocytes stimulated with interleukin-2 in vitro. Taken together, these data suggest that a large number of inosine-containing mRNAs are produced during acute inflammation via up-regulation of ADAR1-mediated RNA editing. These events may affect the inflammatory and immune response through modulation of protein production.

Published

2003

247. Factors that contribute to efficient catalytic activity of a small Ca2+-dependent deoxyribozyme in relation to its RNA cleavage function.

Author

Okumoto Y, Tanabe Y, and Sugimoto N

Subjects

Base Pair Mismatch genetics, Catalysis, Catalytic Domain genetics, Cations, Divalent, DNA, Catalytic chemical synthesis, DNA, Catalytic genetics, Deoxyadenosines chemical synthesis, Deoxyadenosines genetics, Deoxycytidine chemical synthesis, Deoxycytidine genetics, Deoxyguanosine chemical synthesis, Deoxyguanosine genetics, Guanosine chemical synthesis, Guanosine genetics, Hydrogen-Ion Concentration, Hydrolysis, Inosine chemical synthesis, Inosine genetics, Mutation, Nucleic Acid Heteroduplexes chemical synthesis, Nucleic Acid Heteroduplexes genetics, Oligonucleotides chemical synthesis, Oligonucleotides genetics, RNA, Catalytic chemical synthesis, Calcium chemistry, DNA, Catalytic chemistry, Guanosine analogs & derivatives, Inosine analogs & derivatives, RNA, Catalytic chemistry

Abstract

Recently, we found a small Ca(2+)-dependent deoxyribozyme (unmodified), d(GCCTGGCAG(1)G(2)C(3)T(4)A(5)C(6)A(7)A(8)C(9)G(10)A(11)GTCCCT), with cleavage activity for its RNA substrate, r(AGGGACA downward arrow UGCCAGGC) ( downward arrow denotes the RNA cleavage site), in the presence of Ca(2+) and developed a functional SPR sensor chip with this deoxyribozyme [Okumoto, Y., Ohmichi, T., and Sugimoto, N. (2002) Biochemistry 41, 2769-2773]. In the study presented here, to clarify the factors contributing to the efficient catalytic activity of the unmodified deoxyribozyme, RNA cleavage reactions were carried out using 24 mutant deoxyribozymes containing one unnatural DNA nucleotide, such as dI (2'-deoxyinosine), 7-deaza-dG, 2-aminopurine, 7-deaza-dA, 2-amino-dA, dm(5)C (5-methyl-2'-deoxycytosine), or d(P)C (5-propynyl-2'-deoxycytosine). The K(m) values (Michaelis constants) with the mutants that lacked N7 and O6 of G(1) and O6 of G(2) were 4.5 and 6.6 times that of the unmodified one, respectively. The k(cat) value (cleavage rate constant) with the mutants that lacked O6 of G(10) was 0.025 times that of the unmodified one. The results of UV melting curves, SPR kinetics, and CD spectra supported the quantitative idea that the catalytic activity of the unmodified form was achieved using Ca(2+). On the basis of these results, a preliminary model for two G(1) x A(8) and G(2) x A(7) mismatched base pairs such as G(anti) x A(anti) formed in the catalytic loop is proposed. The factor of 10 increase in the k(cat)/K(m) value of the mutant deoxyribozyme, which has C(9) substituted with d(P)C, suggests that the base stacking interaction between the substituted propynyl group in dC and the nearest-neighbor base grew stronger. Thus, substituting d(P)C for dC in the catalytic loop would be one of the best ways to increase the catalytic activity of the deoxyribozyme.

Published

2003

248. Mutagenic spectrum of butadiene-derived N1-deoxyinosine adducts and N6,N6-deoxyadenosine intrastrand cross-links in mammalian cells.

Author

Kanuri M, Nechev LV, Tamura PJ, Harris CM, Harris TM, and Lloyd RS

Subjects

Animals, Base Sequence, Butadienes chemistry, Butadienes metabolism, COS Cells, DNA Adducts chemistry, DNA Adducts metabolism, DNA Mutational Analysis, DNA, Complementary genetics, Deoxyadenosines chemistry, Deoxyadenosines metabolism, Escherichia coli genetics, Genetic Vectors, Humans, Inosine chemistry, Inosine metabolism, Molecular Sequence Data, Mutagenesis, Site-Directed, Nucleic Acid Conformation, Polymorphism, Single Nucleotide, Stereoisomerism, Butadienes toxicity, DNA Adducts genetics, Deoxyadenosines genetics, Inosine analogs & derivatives, Inosine genetics

Abstract

Reactive metabolites of 1,3-butadiene, including 1,2-epoxy-3-butene (BDO), 1,2:3,4-diepoxybutane (BDO(2)), and 3,4-epoxy-1,2-butanediol (BDE), form both stable and unstable base adducts in DNA and have been implicated in producing genotoxic effects in rodents and human cells. N1 deoxyadenosine adducts are unstable and can undergo either hydrolytic deamination to yield N1 deoxyinosine adducts or Dimroth rearrangement to yield N(6) adducts. The dominant point mutation observed at AT sites in both in vivo and in vitro mutagenesis studies using BD and its epoxides has been A --> T transversions followed by A --> G transitions. To understand which of the butadiene adducts are responsible for mutations at AT sites, the present study focuses on the N1 deoxyinosine adduct at C2 of BDO and N(6),N(6)-deoxyadenosine intrastrand cross-links derived from BDO(2). These lesions were incorporated site-specifically and stereospecifically into oligodeoxynucleotides which were engineered into mammalian shuttle vectors for replication bypass and mutational analyses in COS-7 cells. Replication of DNAs containing the R,R-BDO(2) intrastrand cross-link between N(6) positions of deoxyadenosine yielded a high frequency (59%) of single base substitutions at the 3' adducted base, while 19% mutagenesis was detected using the S,S-diastereomer. Comparable studies using the R- and S-diastereomers of the N1 deoxyinosine adduct gave rise to approximately 50 and 80% A --> G transitions with overall mutagenic frequencies of 59 and 90%, respectively. Collectively, these data establish a molecular basis for A --> G transitions that are observed following in vivo and in vitro exposures to BD and its epoxides, but fail to reveal the source of the A --> T transversions that are the dominant point mutation.

Published

2002

249. A-to-I editing: new and old sites, functions and speculations.

Author

Seeburg PH

Subjects

Adenosine genetics, Adenosine metabolism, Adenosine Deaminase genetics, Adenosine Deaminase metabolism, Animals, Humans, Inosine genetics, Inosine metabolism, Ion Channels genetics, Nervous System growth & development, RNA-Binding Proteins, Receptors, Neurotransmitter genetics, Ion Channels biosynthesis, Nervous System metabolism, Presynaptic Terminals metabolism, RNA Editing physiology, Receptors, Neurotransmitter biosynthesis

Abstract

Nuclear pre-mRNA editing by selective adenosine deamination (A-to-I editing) occurs in all organisms from C. elegans to humans. This rare posttranscriptional mechanism can alter codons and hence the structure and function of proteins. New findings report new sites, give evidence that the efficiency of editing can be regulated by neurotransmitter, and reveal that an amino acid substitution introduced by editing into a neurotransmitter-gated ion channel subunit serves as a determinant for controlling the maturation, intracellular trafficking, and assembly with other subunits of this transmembrane protein.

Published

2002

250. The effect of amino groups on the stability of DNA duplexes and triplexes based on purines derived from inosine.

Author

Cubero E, Güimil-García R, Luque FJ, Eritja R, and Orozco M

Subjects

Base Sequence, Computer Simulation, DNA chemical synthesis, DNA genetics, Hydrogen Bonding, Inosine chemistry, Inosine genetics, Models, Molecular, Molecular Structure, Mutation, Nucleic Acid Conformation, Nucleic Acid Denaturation, Oligodeoxyribonucleotides chemical synthesis, Oligodeoxyribonucleotides chemistry, Oligodeoxyribonucleotides genetics, Oligodeoxyribonucleotides metabolism, Quantum Theory, Thermodynamics, DNA chemistry, DNA metabolism, Inosine metabolism

Abstract

The effect of amino groups attached at positions 2 and 8 of the hypoxanthine moiety in the structure, reactivity and stability of DNA duplexes and triplexes is studied by means of quantum mechanical calculations, as well as extended molecular dynamics (MD) and thermodynamic integration (MD/TI) simulations. Theoretical estimates of the change in stability related to 2'-deoxyguanosine (G) --> 2'-deoxyinosine (I) --> 8-amino-2'-deoxyinosine (8AI) mutations have been experimentally verified, after synthesis of the corresponding compounds. An amino group placed at position 2 stabilizes the duplex, as expected, and surprisingly also the triplex. The presence of an amino group at position 8 of the hypoxanthine moiety stabilizes the triplex but, surprisingly, destabilizes the duplex. The subtle electronic redistribution occurring upon the introduction of an amino group on the purine seems to be responsible for this surprising behavior. Interesting 'universal base' properties are found for 8AI.

Published

2001