A novel RT-QPCR-based assay for the relative quantification of residue specific m6A RNA methylation

N6-methyladenosine (m6A) is the most common and abundant RNA modification. Recent studies have shown its importance in the regulation of several biological processes, including the immune response, and different approaches have been developed in order to map and quantify m6A marks. However, site specific detection of m6A methylation has been technically challenging, and existing protocols are long and tedious and often involve next-generation sequencing. Here, we describe a simple RT-QPCR based approach for the relative quantification of candidate m6A regions that takes advantage of the diminished capacity of BstI enzyme to retrotranscribe m6A residues. Using this technique, we have been able to confirm the recently described m6A methylation in the 3′UTR of SOCS1 and SOCS3 transcripts. Moreover, using the method presented here, we have also observed alterations in the relative levels of m6A in specific motifs of SOCS genes in celiac disease patients and in pancreatic β-cells exposed to inflammatory stimuli.J.R.B. is funded by Project ISCIII-PI16/00258 and co-funded by the European Union ERDF/ESF “A way to make Europe”. I.S. is funded by a research project grant 2015111068 of the Basque Department of Health. A.C.R. was funded by a Juan de la Cierva reincorporation and an Ikerbasque fellowships and a research project grant from Asociación Celiacos Madrid. I.R.G., A.O.G. and A.J.M. are supported by predoctoral fellowship grants from the UPV/EHU and the Basque Department of Education

The Role of lncRNAs in Gene Expression Regulation through mRNA Stabilization

mRNA stability influences gene expression and translation in almost all living organisms, and the levels of mRNA molecules in the cell are determined by a balance between production and decay. Maintaining an accurate balance is crucial for the correct function of a wide variety of biological processes and to maintain an appropriate cellular homeostasis. Long non-coding RNAs (lncRNAs) have been shown to participate in the regulation of gene expression through different molecular mechanisms, including mRNA stabilization. In this review we provide an overview on the molecular mechanisms by which lncRNAs modulate mRNA stability and decay. We focus on how lncRNAs interact with RNA binding proteins and microRNAs to avoid mRNA degradation, and also on how lncRNAs modulate epitranscriptomic marks that directly impact on mRNA stability.LncRNA work in author’s laboratory is supported by European Foundation for the Study of Diabetes (EFSD)-EFSD/JDRF/Lilly Programme on Type 1 Diabetes Research and the Spanish Ministry of Science, Innovation and Universities (PID2019-104475GA-I00) to I.S; and Spanish Ministry of Science, Innovation and Universities (SAF2017-91873-EXP and PGC2018-097573-A-I00) to ACR. M.S.D. and I.G.M. are supported by a Predoctoral Fellowship Grant from the UPV/EHU (Universidad del País Vasco/Euskal Herriko Unibertsitatea) and A.O.G. is supported by a Predoctoral Fellowship Grant from the Education Department of Basque Government

Implication of m6A mRNA Methylation in Susceptibility to Inflammatory Bowel Disease

Inflammatory bowel disease (IBD) is a chronic inflammatory condition of the gastrointestinal tract that develops due to the interaction between genetic and environmental factors. More than 160 loci have been associated with IBD, but the functional implication of many of the associated genes remains unclear. N6-Methyladenosine (m6A) is the most abundant internal modification in mRNA. m6A methylation regulates many aspects of mRNA metabolism, playing important roles in the development of several pathologies. Interestingly, SNPs located near or within m6A motifs have been proposed as possible contributors to disease pathogenesis. We hypothesized that certain IBD-associated SNPs could regulate the function of genes involved in IBD development via m6A-dependent mechanisms. We used online available GWAS, m6A and transcriptome data to find differentially expressed genes that harbored m6A-SNPs associated with IBD. Our analysis resulted in five candidate genes corresponding to two of the major IBD subtypes: UBE2L3 and SLC22A4 for Crohn’s Disease and TCF19, C6orf47 and SNAPC4 for Ulcerative Colitis. Further analysis using in silico predictions and co-expression analyses in combination with in vitro functional studies showed that our candidate genes seem to be regulated by m6A-dependent mechanisms. These findings provide the first indication of the implication of RNA methylation events in IBD pathogenesis.This work was supported by Spanish Ministry of Science, Innovation and Universities (grant PGC2018-097573-A-I00) to A.C.-R. I.S. was funded by research project grant 2015111068 of the Basque Department of Health and a Research Grant from the European Foundation for the Study of Diabetes. M.S.-d. and I.G.-M. are predoctoral fellows funded by grants from the University of Basque Country and A.O.-G. is a predoctoral fellow funded by Basque Department of Education, Universities and Research

Implication of m6A mRNA Methylation in Susceptibility to Inflammatory Bowel Disease

Inflammatory bowel disease (IBD) is a chronic inflammatory condition of the gastrointestinal tract that develops due to the interaction between genetic and environmental factors. More than 160 loci have been associated with IBD, but the functional implication of many of the associated genes remains unclear. N6-Methyladenosine (m6A) is the most abundant internal modification in mRNA. m6A methylation regulates many aspects of mRNA metabolism, playing important roles in the development of several pathologies. Interestingly, SNPs located near or within m6A motifs have been proposed as possible contributors to disease pathogenesis. We hypothesized that certain IBD-associated SNPs could regulate the function of genes involved in IBD development via m6A-dependent mechanisms. We used online available GWAS, m6A and transcriptome data to find differentially expressed genes that harbored m6A-SNPs associated with IBD. Our analysis resulted in five candidate genes corresponding to two of the major IBD subtypes: UBE2L3 and SLC22A4 for Crohn’s Disease and TCF19, C6orf47 and SNAPC4 for Ulcerative Colitis. Further analysis using in silico predictions and co-expression analyses in combination with in vitro functional studies showed that our candidate genes seem to be regulated by m6A-dependent mechanisms. These findings provide the first indication of the implication of RNA methylation events in IBD pathogenesis.This work was supported by Spanish Ministry of Science, Innovation and Universities (grant PGC2018-097573-A-I00) to A.C.-R. I.S. was funded by research project grant 2015111068 of the Basque Department of Health and a Research Grant from the European Foundation for the Study of Diabetes. M.S.-d. and I.G.-M. are predoctoral fellows funded by grants from the University of Basque Country and A.O.-G. is a predoctoral fellow funded by Basque Department of Education, Universities and Research

MAGI2 Gene Region and Celiac Disease

Celiac disease (CD) patients present a loss of intestinal barrier function due to structural alterations in the tight junction (TJ) network, the most apical unions between epithelial cells. The association of TJ-related gene variants points to an implication of this network in disease susceptibility. This work aims to characterize the functional implication of TJ-related, disease-associated loci in CD pathogenesis. We performed an association study of 8 TJ-related gene variants in a cohort of 270 CD and 91 non-CD controls. The expression level of transcripts located in the associated SNP region was analyzed by RT-PCR in several human tissues and in duodenal biopsies of celiac patients and non-CD controls. (si)RNA-driven silencing combined with gliadin in the Caco2 intestinal cell line was used to analyze the implication of transcripts from the associated region in the regulation of TJ genes. We replicated the association of rs6962966*A variant [p = 0.0029; OR = 1.88 (95%1.24-2.87)], located in an intron of TJ-related MAGI2 coding gene and upstream of RP4-587D13.2 transcript, bioinformatically classified as a long non-coding RNA (lncRNA). The expression of both genes is correlated and constitutively downregulated in CD intestine. Silencing of lncRNA decreases the levels of MAGI2 protein. At the same time, silencing of MAGI2 affects the expression of several TJ-related genes. The associated region is functionally altered in disease, probably affecting CD-related TJ genes.This work was partially funded by the Basque Department of Education grant IT1281-19 and ISCIII Research Project PI16/00258, cofunded by the European Union ERDF, A way to make Europe to JB. AC-R is supported by an Ikerbasque Fellowship and funded by a research project grant 2017111082 from the Basque Goverment. IS was funded by a research project grant 2015111068 from the Basque Department of Health. AJ-M and AO-G are predoctoral fellows funded by FPI grants from the Basque Department of Education, Universities and Research and IR-G and MS are predoctoral fellows funded by the University of Basque Country

A long non-coding RNA that harbors a SNP associated with type 2 diabetes regulates the expression of TGM2 gene in pancreatic beta cells

IntroductionMost of the disease-associated single nucleotide polymorphisms (SNPs) lie in non- coding regions of the human genome. Many of these variants have been predicted to impact the expression and function of long non-coding RNAs (lncRNA), but the contribution of these molecules to the development of complex diseases remains to be clarified. MethodsHere, we performed a genetic association study between a SNP located in a lncRNA known as LncTGM2 and the risk of developing type 2 diabetes (T2D), and analyzed its implication in disease pathogenesis at pancreatic beta cell level. Genetic association study was performed on human samples linking the rs2076380 polymorphism with T2D and glycemic traits. The pancreatic beta cell line EndoC-bH1 was employed for functional studies based on LncTGM2 silencing and overexpression experiments. Human pancreatic islets were used for eQTL analysis. ResultsWe have identified a genetic association between LncTGM2 and T2D risk. Functional characterization of the LncTGM2 revealed its implication in the transcriptional regulation of TGM2, coding for a transglutaminase. The T2Dassociated risk allele in LncTGM2 disrupts the secondary structure of this lncRNA, affecting its stability and the expression of TGM2 in pancreatic beta cells. Diminished LncTGM2 in human beta cells impairs glucose-stimulated insulin release. ConclusionsThese findings provide novel information on the molecular mechanisms by which T2D-associated SNPs in lncRNAs may contribute to disease, paving the way for the development of new therapies based on the modulation of lncRNAs.This work was supported by grants from the Ministerio de Ciencia, Innovación y Universidades (PID2019-104475GA-I00 to I.S, and PGC2018-097573-A-I00 to AC-R) and the European Foundation for the Study of Diabetes (EFSD) - EFSD/JDRF/Lilly Programme on Type 1 Diabetes Research to IS. FO (MS19/00109) is recipient of the Miguel Servet scheme, and AL (FI19/00045) was supported by the Instituto de Salud Carlos III (ISCIII); Ministerio de Ciencia, Innovación y Universidades, Gobierno de España (ES). HR-M (PRE2019-089350) is supported by predoctoral grant from the Ministerio de Ciencia, Innovacion y Universidades, Gobierno de España (ES) IG-M, MS-C, JM-S and AO-G were supported by Predoctoral Fellowship Grants from the UPV/EHU (Universidad del Pais Vasco/EuskalHerrikoUnibertsitatea) and the Basque Department of Education. MC is supported by the Fonds National de la RechercheScientifique (FNRS), the Francophone Foundation for Diabetes Research (sponsored by the French Diabetes Federation, Abbott, Eli Lilly, Merck Sharp & Dohme, and Novo Nordisk) and FF and MC by the EFSD/BoehringerIngelheim European Research Programme on Multi-System Challenges in Diabetes. The funders were not involved in the study design, collection, analysis, interpretation of data, the writing of this article, or the decision to submit it for publication

A Novel Noninvasive Method Based on Salivary Inflammatory Biomarkers for the Screening of Celiac Disease

This study was supported by a grant from theSpanish Ministry of Science, Universities andInnovation (SAF2017-91873-EXP), a grant fromthe Department of Health from the BasqueGovernment (EJ-2017111082), and a researchfellowship from the Asociación de Celiacos ySensibles al Gluten de Madrid (A.C.R.). Alsosupported by a predoctoral fellowship from theUniversity of the Basque Country (M.S.dlC.) andthe Basque Government (A.O.G.)

Gluten-induced RNA methylation changes regulate intestinal inflammation via allele-specific XPO1 translation in epithelial cells

[EN] Objectives Coeliac disease (CD) is a complex autoimmune disorder that develops in genetically susceptible individuals. Dietary gluten triggers an immune response for which the only available treatment so far is a strict, lifelong gluten free diet. Human leucocyte antigen (HLA) genes and several non-HLA regions have been associated with the genetic susceptibility to CD, but their role in the pathogenesis of the disease is still essentially unknown, making it complicated to develop much needed non-dietary treatments. Here, we describe the functional involvement of a CD-associated single-nudeotide polymorphism (SNP) located in the 5'UTR of XPO1 in the inflammatory environment characteristic of the coeliac intestinal epithelium. Design The function of the CD-associated SNP was investigated using an intestinal cell line heterozygous for the SNP, N6-methyladenosine (m(6)A)-related knock-out and HLA-DQ2 mice, and human samples from patients with CD. Results Individuals harbouring the risk allele had higher m(6)A methylation in the 5'UTR of XPO1 RNA, rendering greater XPO1 protein amounts that led to downstream nuclear factor kappa B (NFkB) activity and subsequent inflammation. Furthermore, gluten exposure increased overall m(6)A methylation in humans as well as in in vitro and in vivo models. Conclusion We identify a novel m(6)A-XPO1-NFkB pathway that is activated in CD patients. The findings will prompt the development of new therapeutic approaches directed at m(6)A proteins and XPO1, a target under evaluation for the treatment of intestinal disorders.This study was supported by a grant from the Spanish Ministry of Science, Universities and Innovation (PGC2018-097573-A-I00) to AC-R. JRB was funded by ISCIII Research project PI16/00258, cofinanced by the Spanish Ministry of Economy and Competitiveness and by the European Union ERDF/ESF 'A way to make Europe'. AO-G and MS-D were funded by predoctoral fellowships from the Basque Government and the University of the Basque Country respectively. DS and LH were funded by the Spanish Ministry (MINECO) (SAF2017-83813-C3-1-R) and cofunded by the ERDF, the Centro de Investigacion Biomedica en Red de Fisiopatologia de la Obesidad y la Nutricion (CIBEROBN) (Grant CB06/03/0001 to DS), the Government of Catalonia (2017SGR278 to DS), and the Fundacio La Marato de TV3 (201627-30 to DS). CH is a Howard Hughes Medical Institute Investigator and has been funded by the National Institute of Health HG008935. We would like to thank Xuechen Yu and Justin Vargas for processing the adult CD biopsy samples obtained from Columbia University. EFV is supported by a CIHR grant 168840 and holds a Canada Research Chair

Aldaera ez-kodetzaileak eta epitranskriptomika: eritasun zeliakoarekin asoziatutako eremu baten azterketa funtzionala

146 p.Eritasun Zeliakoa (EZ) genetikoki sentikorrak diren pertsonetan garatzen den gaixotasun autoimmunekonplexua da. Glutenak erantzun immunea eragiten die eta gaur egun dagoen tratamendu bakarra biziosorako glutenik gabeko dieta zorrotza jarraitzea da. EZri lotutako sentikortasun genetikoa HLA geneekin eta HLAtik kanpoko hainbat eremu genomikorekin asoziaturik dagoela jakina den arren, haien ekarpena gaixotasunean oraindik ez dago guztiz deskribatua. Horrek zaildu egiten du beharrezkoak diren dietaz besteko tratamendu berrien garapena. Lan honetan XPO1en 5'UTRan kokatutako EZri lotutako nukleotido bakarreko polimorfismoaren (SNP) inplikazio funtzionala deskribatzen dugu zeliakoen hesteko epitelioan ezaugarri den hantura-ingurunean.Arrisku aleloak m6A metilazio handiagoa eragiten du XPO1en 5'UTRan, XPO1 proteina kopuru handiagoak eta ur-beherako NF-kB bidezko hantura eraginez. Gainera, glutenaren esposizioak m6A metilazio orokorra areagotzen duela erakutsi dugu gizakietan, baita in vitro eta in vivo ereduetan ere.Hala, EZ gaixoetan aktibatzen den m6A-XPO1-NF-kB bide berri bat deskribatu dugu, hurbilketa terapeutiko berriak garatzea bultzatu dezakeena

Non-coding variants and epitranscriptomics: a functional study of a celiac disease associated

151 p.Eritasun Zeliakoa (EZ) genetikoki sentikorrak diren pertsonetan garatzen den gaixotasun autoimmunekonplexua da. Glutenak erantzun immunea eragiten die eta gaur egun dagoen tratamendu bakarra biziosorako glutenik gabeko dieta zorrotza jarraitzea da. EZri lotutako sentikortasun genetikoa HLA geneekin eta HLAtik kanpoko hainbat eremu genomikorekin asoziaturik dagoela jakina den arren, haien ekarpena gaixotasunean oraindik ez dago guztiz deskribatua. Horrek zaildu egiten du beharrezkoak diren dietaz besteko tratamendu berrien garapena. Lan honetan XPO1en 5'UTRan kokatutako EZri lotutako nukleotido bakarreko polimorfismoaren (SNP) inplikazio funtzionala deskribatzen dugu zeliakoen hesteko epitelioan ezaugarri den hantura-ingurunean.Arrisku aleloak m6A metilazio handiagoa eragiten du XPO1en 5'UTRan, XPO1 proteina kopuru handiagoak eta ur-beherako NF-kB bidezko hantura eraginez. Gainera, glutenaren esposizioak m6A metilazio orokorra areagotzen duela erakutsi dugu gizakietan, baita in vitro eta in vivo ereduetan ere.Hala, EZ gaixoetan aktibatzen den m6A-XPO1-NF-kB bide berri bat deskribatu dugu, hurbilketa terapeutiko berriak garatzea bultzatu dezakeena