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Although buprenorphine and methadone are both effective treatments for opioid dependence, their efficacy can vary significantly among patients. Genetic differences may explain some of the variability in treatment outcome. Understanding the interactions between genetic background and pharmacotherapy may result in more informed treatment decisions. This study is a pharmacogenetic analysis of the effects of genetic variants in OPRD1, the gene encoding the δ-opioid receptor, on the prevalence of opioid-positive urine tests in African-Americans (n=77) or European-Americans (n=566) undergoing treatment for opioid dependence. Patients were randomly assigned to treatment with either methadone or buprenorphine/naloxone (Suboxone) over a 24-week open-label clinical trial, in which illicit opioid use was measured by weekly urinalysis. In African-Americans, the intronic SNP rs678849 predicted treatment outcome for both medications. Methadone patients with the CC genotype were less likely to have opioid-positive urine tests than those in the combined CT and TT genotypes group (relative risk (RR)=0.52, 95% confidence interval (CI)=0.44-0.60, p=0.001). In the buprenorphine treatment group, however, individuals with the CC genotype were more likely to have positive opioid drug screens than individuals in the combined CT and TT genotypes group (RR=2.17, 95% CI=1.95-2.68, p=0.008). These findings indicate that the genotype at rs678849 predicts African-American patient response to two common treatments for opioid dependence, suggesting that matching patients to treatment type based on the genotype at this locus may improve overall treatment efficacy. This observation requires confirmation in an independent population.

Emerging data indicate that alterations in cytokine synthesis may play a role in inflammatory bowel disease (IBD) pathogenesis. The differential production of cytokines has been linked to single nucleotide polymorphisms in gene promoter regions, signal sequences, and gene introns. The aim of this study was to assess the relationship between polymorphisms involving five cytokine genes (TNF-alpha, TGF-beta, IL-10, IL-6, and IFN-gamma), and IBD susceptibility and disease phenotype. Cytokine genotyping was performed utilizing polymerase chain reaction. The specific gene polymorphisms that were probed for included: -1082(G/A), -819(T/C), and -592(A/C) in the IL-10 promoter, -308(G/A) in the TNF-alpha promoter, codon 10 (T/C), and codon 25 (G/C) of the TGF-beta signal sequence, +874(T/A) of intron 1 of IFN-gamma, and -174(C/G) in the IL-6 promoter. A total of 193 IBD patients (138 Crohn's disease (CD) and 55 ulcerative colitis (UC)) and 92 controls were evaluated. No association between IBD, UC, or CD susceptibility and the cytokine gene polymorphisms were found. Patients with ileocolonic CD were more likely to possess the IL-6 -174 GG genotype compared to those with nonileocolonic disease (p= 0.006). Patients with ileal CD were more likely to possess the IL-6 -174 GC genotype compared to those with nonileal disease (p= 0.0004). An increased number of CD patients with isolated colonic disease possessed the IL-6 -174 CC genotype compared to those with nonisolated colonic disease (p= 0.032). The cytokine gene polymorphisms studied here do not appear to influence IBD susceptibility. There does, however, appear to be an influence on disease phenotype, particularly on CD site.

While splicing changes caused by somatic mutations in SF3B1 are known, identifying full-length isoform changes may better elucidate the functional consequences of these mutations. We report nanopore sequencing of full-length cDNA from CLL samples with and without SF3B1 mutation, as well as normal B cell samples, giving a total of 149 million pass reads. We present FLAIR (Full-Length Alternative Isoform analysis of RNA), a computational workflow to identify high-confidence transcripts, perform differential splicing event analysis, and differential isoform analysis. Using nanopore reads, we demonstrate differential 3’ splice site changes associated with SF3B1 mutation, agreeing with previous studies. We also observe a strong downregulation of intron retention events associated with SF3B1 mutation. Full-length transcript analysis links multiple alternative splicing events together and allows for better estimates of the abundance of productive versus unproductive isoforms. Our work demonstrates the potential utility of nanopore sequencing for cancer and splicing research. Long-read sequencing is useful in determining exon-connectivity of full-length mRNA isoforms. Here, by long-read nanopore sequencing, the authors report that intron retention is downregulated in SF3B1 mutant chronic lymphocytic leukemia cells than normal B cells.

Removal of introns from messenger RNA precursors (pre-mRNA splicing) is an essential step for the expression of most eukaryotic genes. Alternative splicing enables the regulated generation of multiple mRNA and protein products from a single gene. Cancer cells have general as well as cancer type-specific and subtype-specific alterations in the splicing process that can have prognostic value and contribute to every hallmark of cancer progression, including cancer immune responses. These splicing alterations are often linked to the occurrence of cancer driver mutations in genes encoding either core components or regulators of the splicing machinery. Of therapeutic relevance, the transcriptomic landscape of cancer cells makes them particularly vulnerable to pharmacological inhibition of splicing. Small-molecule splicing modulators are currently in clinical trials and, in addition to splice site-switching antisense oligonucleotides, offer the promise of novel and personalized approaches to cancer treatment.Alternative splicing enables the regulated generation of multiple mRNA and protein products from a single gene. This Review outlines the splicing process and its alterations in cancer before highlighting related opportunities for the development of innovative therapeutic approaches.

Salamanders serve as important tetrapod models for developmental, regeneration and evolutionary studies. An extensive molecular toolkit makes the Mexican axolotl ( Ambystoma mexicanum ) a key representative salamander for molecular investigations. Here we report the sequencing and assembly of the 32-gigabase-pair axolotl genome using an approach that combined long-read sequencing, optical mapping and development of a new genome assembler (MARVEL). We observed a size expansion of introns and intergenic regions, largely attributable to multiplication of long terminal repeat retroelements. We provide evidence that intron size in developmental genes is under constraint and that species-restricted genes may contribute to limb regeneration. The axolotl genome assembly does not contain the essential developmental gene Pax3 . However, mutation of the axolotl Pax3 paralogue Pax7 resulted in an axolotl phenotype that was similar to those seen in Pax3 −/− and Pax7 −/− mutant mice. The axolotl genome provides a rich biological resource for developmental and evolutionary studies. Sequencing and assembly of the 32-Gb genome of the Mexican axolotl reveals that it lacks the developmental gene Pax3 , which is essential in other vertebrates; the genome sequence could improve our understanding of the evolution of the axolotl’s remarkable regenerative capabilities. Axolotl genome sequence Elly Tanaka, Eugene Myers and colleagues report the genome sequence of the axolotl, a model organism for developmental, regeneration and evolutionary studies. To sequence and assemble this large and complex genome, the authors used a combination of long- and short-read sequencing, optical mapping and a new genome assembly pipeline, MARVEL, optimized for long-read sequencing of complex genomes. The genome assembly shows an expansion of long terminal repeat retroelements and the presence of a large HoxA cluster, but also a reduction in the number of Pax-family genes in the genome of this popular salamander.

Genomic analysis of 5,303 Chinese women with recurrent major depressive disorder (MDD) enables the identification and replication of two genome-wide significant loci contributing to risk of MDD on chromosome 10: one near the SIRT1 gene; the other in an intron of the LHPP gene. Genetic risk factors for depression This genomic analysis of more than 5,000 Chinese women with recurrent major depressive disorder (MDD) has identified and replicated two genome-wide significant loci contributing to risk of MDD on chromosome 10. One is near the sirtuin1 ( SIRT1 ) gene, and the other is in an intron of the phospholysine phosphohistidine inorganic pyrophosphate phosphatase ( LHPP ) gene. The authors suggest that the association close to SIRT1 may implicate abnormalities in mitochondria as risk factors for the disease. Major depressive disorder (MDD), one of the most frequently encountered forms of mental illness and a leading cause of disability worldwide 1 , poses a major challenge to genetic analysis. To date, no robustly replicated genetic loci have been identified 2 , despite analysis of more than 9,000 cases 3 . Here, using low-coverage whole-genome sequencing of 5,303 Chinese women with recurrent MDD selected to reduce phenotypic heterogeneity, and 5,337 controls screened to exclude MDD, we identified, and subsequently replicated in an independent sample, two loci contributing to risk of MDD on chromosome 10: one near the SIRT1 gene ( P  = 2.53 × 10 −10 ), the other in an intron of the LHPP gene ( P = 6.45 × 10 −12 ). Analysis of 4,509 cases with a severe subtype of MDD, melancholia, yielded an increased genetic signal at the SIRT1 locus. We attribute our success to the recruitment of relatively homogeneous cases with severe illness.

Covalently closed single-stranded circular RNAs (circRNAs) consist of introns or exons and are widely present in eukaryotic cells. CircRNAs generally have low expression levels and relatively stable structures compared with messenger RNAs (mRNAs), most of which are located in the cytoplasm and often act in cell type and tissue-specific manners, indicating that they may serve as novel biomarkers. In recent years, circRNAs have gradually become a hotspot in the field of RNA and cancer research, but the functions of most circRNAs have not yet been discovered. Known circRNAs can affect the biogenesis of cancers in diverse ways, such as functioning as a microRNA (miRNA) sponges, combining with RNA binding proteins (RBPs), working as a transcription factor and translation of proteins. In this review, we summarize the characteristics and types of circRNAs, introduce the biogenesis of circRNAs, discuss the emerging functions and databases on circRNAs and present the current challenges of circRNAs studies.

Late-onset ataxia is common, often idiopathic, and can result from cerebellar, proprioceptive, or vestibular impairment; when in combination, it is also termed cerebellar ataxia, neuropathy, vestibular areflexia syndrome (CANVAS). We used non-parametric linkage analysis and genome sequencing to identify a biallelic intronic AAGGG repeat expansion in the replication factor C subunit 1 ( RFC1 ) gene as the cause of familial CANVAS and a frequent cause of late-onset ataxia, particularly if sensory neuronopathy and bilateral vestibular areflexia coexist. The expansion, which occurs in the poly(A) tail of an AluSx3 element and differs in both size and nucleotide sequence from the reference (AAAAG) 11 allele, does not affect RFC1 expression in patient peripheral and brain tissue, suggesting no overt loss of function. These data, along with an expansion carrier frequency of 0.7% in Europeans, implies that biallelic AAGGG expansion in RFC1 is a frequent cause of late-onset ataxia. Biallelic expansion of an intronic AAGGG repeat in RFC1 is identified here as a common cause of late-onset ataxia. This expansion occurs in the poly(A) tail of an AluSx3 element and is observed at a carrier frequency of 0.7% in populations of European ancestry.

Cancer therapies that target epigenetic repressors can mediate their effects by activating retroelements within the human genome. Retroelement transcripts can form double-stranded RNA (dsRNA) that activates the MDA5 pattern recognition receptor 1 – 6 . This state of viral mimicry leads to loss of cancer cell fitness and stimulates innate and adaptive immune responses 7 , 8 . However, the clinical efficacy of epigenetic therapies has been limited. To find targets that would synergize with the viral mimicry response, we sought to identify the immunogenic retroelements that are activated by epigenetic therapies. Here we show that intronic and intergenic SINE elements, specifically inverted-repeat Alus, are the major source of drug-induced immunogenic dsRNA. These inverted-repeat Alus are frequently located downstream of ‘orphan’ CpG islands 9 . In mammals, the ADAR1 enzyme targets and destabilizes inverted-repeat Alu dsRNA 10 , which prevents activation of the MDA5 receptor 11 . We found that ADAR1 establishes a negative-feedback loop, restricting the viral mimicry response to epigenetic therapy. Depletion of ADAR1 in patient-derived cancer cells potentiates the efficacy of epigenetic therapy, restraining tumour growth and reducing cancer initiation. Therefore, epigenetic therapies trigger viral mimicry by inducing a subset of inverted-repeats Alus, leading to an ADAR1 dependency. Our findings suggest that combining epigenetic therapies with ADAR1 inhibitors represents a promising strategy for cancer treatment. Inverted-repeat Alu elements are the main source of drug-induced immunogenic double-stranded RNAs, which are destabilized by the RNA deaminase ADAR1, thereby limiting activation of the immune response.