Your search keyword '"Andrei Barysenka"' showing total 5 results

1. Mapping the serum proteome to neurological diseases using whole genome sequencing

Author

Grace Png, Andrei Barysenka, Linda Repetto, Pau Navarro, Xia Shen, Maik Pietzner, Eleanor Wheeler, Nicholas J. Wareham, Claudia Langenberg, Emmanouil Tsafantakis, Maria Karaleftheri, George Dedoussis, Anders Mälarstig, James F. Wilson, Arthur Gilly, and Eleftheria Zeggini

Subjects

Science

Abstract

Serum proteins are easily accessible biomarkers and drug targets. Here, the authors use whole genome sequencing data to describe the genetic architecture of neurologically-relevant serum proteins and establish causal protein-neurological disease relationships.

Published

2021

2. Gene-based whole genome sequencing meta-analysis of 250 circulating proteins in three isolated European populations

Author

Arthur Gilly, Lucija Klaric, Young-Chan Park, Grace Png, Andrei Barysenka, Joseph A. Marsh, Emmanouil Tsafantakis, Maria Karaleftheri, George Dedoussis, James F. Wilson, and Eleftheria Zeggini

Subjects

Whole-genome sequencing, Proteomics, Association studies, Gene-based tests, Internal medicine, RC31-1245

Abstract

Objective: Deep sequencing offers unparalleled access to rare variants in human populations. Understanding their role in disease is a priority, yet prohibitive sequencing costs mean that many cohorts lack the sample size to discover these effects on their own. Meta-analysis of individual variant scores allows the combination of rare variants across cohorts and study of their aggregated effect at the gene level, boosting discovery power. However, the methods involved have largely not been field-tested. In this study, we aim to perform the first meta-analysis of gene-based rare variant aggregation optimal tests, applied to the human cardiometabolic proteome. Methods: Here, we carry out this analysis across MANOLIS, Pomak and ORCADES, three isolated European cohorts with whole-genome sequencing (total N = 4,422). We examine the genetic architecture of 250 proteomic traits of cardiometabolic relevance. We use a containerised pipeline to harmonise variant lists across cohorts and define four sets of qualifying variants. For every gene, we interrogate protein-damaging variants, exonic variants, exonic and regulatory variants, and regulatory only variants, using the CADD and Eigen scores to weigh variants according to their predicted functional consequence. We perform single-cohort rare variant analysis and meta-analyse variant scores using the SMMAT package. Results: We describe 5 rare variant pQTLs (RV-pQTL) which pass our stringent significance threshold (7.45 × 10−11) and quality control procedure. These were split between four cis signals for MARCO, TEK, MMP2 and MPO, and one trans association for GDF2 in the SERPINA11 gene. We show that the cis-MPO association, which was not detectable using the single-point data alone, is driven by 5 missense and frameshift variants. These include rs140636390 and rs119468010, which are specific to MANOLIS and ORCADES, respectively. We show how this kind of signal could improve the predictive accuracy of genetic factors in common complex disease such as stroke and cardiovascular disease. Conclusions: Our proof-of-concept study demonstrates the power of gene-based meta-analyses for discovering disease-relevant associations complementing common-variant signals by incorporating population-specific rare variation.

Published

2022

3. Whole-genome sequencing analysis of the cardiometabolic proteome

Author

Arthur Gilly, Young-Chan Park, Grace Png, Andrei Barysenka, Iris Fischer, Thea Bjørnland, Lorraine Southam, Daniel Suveges, Sonja Neumeyer, N. William Rayner, Emmanouil Tsafantakis, Maria Karaleftheri, George Dedoussis, and Eleftheria Zeggini

Subjects

Science

Abstract

The human proteome represents a crucial link between complex disease and genetic/environmental factors. Here, the authors investigate 257 cardiometabolic-relevant protein biomarkers in whole genome sequencing data from 1328 individuals, revealing the genetic architecture underlying biomarker variation.

Published

2020

4. ADAMTS12, a new candidate gene for pediatric stroke.

Author

Anika Witten, Frank Rühle, Marlous de Witt, Andrei Barysenka, Michael Stach, Ralf Junker, Ulrike Nowak-Göttl, and Monika Stoll

Subjects

Medicine, Science

Abstract

We recently reported a family-based genome wide association study (GWAS) for pediatric stroke pointing our attention to two significantly associated genes of the ADAMTS (a disintegrin and metalloproteinase with thrombospondin motifs) gene family ADAMTS2 (rs469568, p = 8x10-6) and ADAMTS12 (rs1364044, p = 2.9x10-6). To further investigate these candidate genes, we applied a targeted resequencing approach on 48 discordant sib-pairs for pediatric stroke followed by genotyping of the detected non-synonymous variants in the full cohort of 270 offspring trios and subsequent fine mapping analysis. We identified eight non-synonymous SNPs in ADAMTS2 and six in ADAMTS12 potentially influencing the respective protein function. These variants were genotyped within a cohort of 270 affected offspring trios, association analysis revealed the ADAMTS12 variant rs77581578 to be significantly under-transmitted (p = 6.26x10-3) to pediatric stroke patients. The finding was validated in a pediatric venous thromboembolism (VTE) cohort of 189 affected trios. Subsequent haplotype analysis of ADAMTS12 detected a significantly associated haplotype comprising the originally identified GWAS variant. Several ADAMTS genes such as ADAMTS13 are involved in thromboembolic disease process. Here, we provide further evidence for ADAMTS12 to likely play a role in pediatric stroke. Further functional studies are warranted to assess the functional role of ADAMTS12 in the pathogenesis of stroke.

Published

2020

5. Analysis of the genomic architecture of a complex trait locus in hypertensive rat models links Tmem63c to kidney damage

Author

Angela Schulz, Nicola Victoria Müller, Nina Anne van de Lest, Andreas Eisenreich, Martina Schmidbauer, Andrei Barysenka, Bettina Purfürst, Anje Sporbert, Theodor Lorenzen, Alexander M Meyer, Laura Herlan, Anika Witten, Frank Rühle, Weibin Zhou, Emile de Heer, Marion Scharpfenecker, Daniela Panáková, Monika Stoll, and Reinhold Kreutz

Subjects

albuminuria, blood pressure, next generation sequencing, RNA sequencing, rat, zebrafish, Medicine, Science, Biology (General), QH301-705.5

Abstract

Unraveling the genetic susceptibility of complex diseases such as chronic kidney disease remains challenging. Here, we used inbred rat models of kidney damage associated with elevated blood pressure for the comprehensive analysis of a major albuminuria susceptibility locus detected in these models. We characterized its genomic architecture by congenic substitution mapping, targeted next-generation sequencing, and compartment-specific RNA sequencing analysis in isolated glomeruli. This led to prioritization of transmembrane protein Tmem63c as a novel potential target. Tmem63c is differentially expressed in glomeruli of allele-specific rat models during onset of albuminuria. Patients with focal segmental glomerulosclerosis exhibited specific TMEM63C loss in podocytes. Functional analysis in zebrafish revealed a role for tmem63c in mediating the glomerular filtration barrier function. Our data demonstrate that integrative analysis of the genomic architecture of a complex trait locus is a powerful tool for identification of new targets such as Tmem63c for further translational investigation.

Published

2019