Project description:To identify a causative variant and effector gene responsible for a 2-fold increased risk of severe COVID-19, a multi-omics platform was deployed. A combination of ATAC-seq, ChIP-seq, Micro Capture-C and NuTi Capture-C were used to characterize a range of cell types, including epithelial, fibroblast, endothelial, immune and erythroid cells.

Project description:To identify regulatory interactions in erythroid, fibroblast and endothelial cells Micro Caputre-C was carried outfrom the promoters of active genes as well as the rs17713054 containing enhancer.

Project description:To identify regions of open chromatin ATAC-seq was carried out in Blood outgrowth endothelial cells (BOECs) and NCI-H441 Epithelial cells

Project description:To identify regulation by the CEBPB transcription factor in epithelial, fibroblast and endothelial cells ChIP-seq was carried out for both the transcription factor and marks of active transcription (H3K27ac).

Project description:Identification of LZTFL1 as a candidate effector gene at a COVID-19 risk locus

Project description:Identification of LZTFL1 as a candidate effector gene at a COVID-19 risk locus (MCC)

Project description:Identification of LZTFL1 as a candidate effector gene at a COVID-19 risk locus (ATAC-seq)

Project description:Identification of LZTFL1 as a candidate effector gene at a COVID-19 risk locus (ChIP-seq)

Project description: Not available

Project description:Individuals infected with the SARS-CoV-2 virus present with a wide variety of phenotypes ranging from asymptomatic to severe and even lethal outcomes. Past research has revealed a genetic haplotype on chromosome 3 that entered the human population via introgression from Neanderthals as the strongest genetic risk factor for the severe COVID-19 phenotype. However, the specific variants along this introgressed haplotype that contribute to this risk and the biological mechanisms that are involved remain unclear. Here, we assess the variants present on the risk haplotype for their likelihood of driving the severe COVID-19 phenotype. We do this by first exploring their impact on the regulation of genes involved in COVID-19 infection using a variety of population genetics and functional genomics tools. We then perform an locus-specific massively parallel reporter assay to individually assess the regulatory potential of each allele on the haplotype in a multipotent immune-related cell line. We ultimately reduce the set of over 600 linked genetic variants to identify 4 introgressed alleles that are strong functional candidates for driving the association between this locus and the severe COVID-19. These variants likely drive the locus’ impact on severity by putatively modulating the regulation of two critical chemokine receptor genes: CCR1 and CCR5. These alleles are ideal targets for future functional investigations into the interaction between host genomics and COVID-19 outcomes.