Your search keyword '"ORMDL3"' showing total 2 results

1. High-resolution targeted bisulfite sequencing reveals blood cell type-specific DNA methylation patterns in IL13 and ORMDL3.

Author

Söderhäll, Cilla, Reinius, Lovisa E., Salmenperä, Pertteli, Gentile, Massimiliano, Acevedo, Nathalie, Konradsen, Jon R., Nordlund, Björn, Hedlin, Gunilla, Scheynius, Annika, Myllykangas, Samuel, and Kere, Juha

Subjects

*DNA methylation, *BLOOD cells, *LEUCOCYTES, *METHYLATION, *BLOOD grouping & crossmatching, *WHEEZE

Abstract

Background: Methylation of DNA at CpG sites is an epigenetic modification and a potential modifier of disease risk, possibly mediating environmental effects. Currently, DNA methylation is commonly assessed using specific microarrays that sample methylation at a few % of all methylated sites. Methods: To understand if significant information on methylation can be added by a more comprehensive analysis of methylation, we set up a quantitative method, bisulfite oligonucleotide-selective sequencing (Bs-OS-seq), and compared the data with microarray-derived methylation data. We assessed methylation at two asthma-associated genes, IL13 and ORMDL3, in blood samples collected from children with and without asthma and fractionated white blood cell types from healthy adult controls. Results: Our results show that Bs-OS-seq can uncover vast amounts of methylation variation not detected by commonly used array methods. We found that high-density methylation information from even one gene can delineate the main white blood cell lineages. Conclusions: We conclude that high-resolution methylation studies can yield clinically important information at selected specific loci missed by array-based methods, with potential implications for future studies of methylation-disease associations. [ABSTRACT FROM AUTHOR]

Published

2021

2. High-resolution targeted bisulfite sequencing reveals blood cell type-specific DNA methylation patterns in IL13 and ORMDL3

Author

Annika Scheynius, Cilla Söderhäll, Gunilla Hedlin, Lovisa E. Reinius, Massimiliano Gentile, Samuel Myllykangas, Jon R Konradsen, Nathalie Acevedo, Pertteli Salmenperä, Björn Nordlund, Juha Kere, STEMM - Stem Cells and Metabolism Research Program, Juha Kere / Principal Investigator, and Research Programs Unit

Subjects

0301 basic medicine, Adult, Epigenomics, Male, 450&#160, Adolescent, Bisulfite sequencing, CpG sites, CHILDHOOD, Biology, Epigenesis, Genetic, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, 450 k, MICROARRAY, Genetics, Humans, Sulfites, Epigenetics, Epigenetic profiling, Child, Molecular Biology, Genetics (clinical), Bs-OS-sequencing, DNA methylation, Interleukin-13, Research, ORMDL3, High-Throughput Nucleotide Sequencing, Membrane Proteins, Methylation, Asthma, Bisulfite, 030104 developmental biology, 030228 respiratory system, CpG site, chemistry, Case-Control Studies, Female, 3111 Biomedicine, IL13, DNA microarray, DNA, Developmental Biology

Abstract

Background Methylation of DNA at CpG sites is an epigenetic modification and a potential modifier of disease risk, possibly mediating environmental effects. Currently, DNA methylation is commonly assessed using specific microarrays that sample methylation at a few % of all methylated sites. Methods To understand if significant information on methylation can be added by a more comprehensive analysis of methylation, we set up a quantitative method, bisulfite oligonucleotide-selective sequencing (Bs-OS-seq), and compared the data with microarray-derived methylation data. We assessed methylation at two asthma-associated genes, IL13 and ORMDL3, in blood samples collected from children with and without asthma and fractionated white blood cell types from healthy adult controls. Results Our results show that Bs-OS-seq can uncover vast amounts of methylation variation not detected by commonly used array methods. We found that high-density methylation information from even one gene can delineate the main white blood cell lineages. Conclusions We conclude that high-resolution methylation studies can yield clinically important information at selected specific loci missed by array-based methods, with potential implications for future studies of methylation-disease associations.

Published

2021