Your search keyword '"MPRA"' showing total 6 results

1. Linking environmental factors and gene regulation

Author

Signe Penner-Goeke and Elisabeth B Binder

Subjects

epigenome, methylation, biological embedding, early life adversity, MPRA, epigenetics, Medicine, Science, Biology (General), QH301-705.5

Abstract

A technique called mSTARR-seq sheds light on how DNA methylation may shape responses to external stimuli by altering the activity of sequences that control gene expression.

Published

2024

2. DNA methylation-environment interactions in the human genome

Author

Rachel A Johnston, Katherine A Aracena, Luis B Barreiro, Amanda J Lea, and Jenny Tung

Subjects

epigenome, methylation, biological embedding, early life adversity, MPRA, IFNA, Medicine, Science, Biology (General), QH301-705.5

Abstract

Previously, we showed that a massively parallel reporter assay, mSTARR-seq, could be used to simultaneously test for both enhancer-like activity and DNA methylation-dependent enhancer activity for millions of loci in a single experiment (Lea et al., 2018). Here, we apply mSTARR-seq to query nearly the entire human genome, including almost all CpG sites profiled either on the commonly used Illumina Infinium MethylationEPIC array or via reduced representation bisulfite sequencing. We show that fragments containing these sites are enriched for regulatory capacity, and that methylation-dependent regulatory activity is in turn sensitive to the cellular environment. In particular, regulatory responses to interferon alpha (IFNA) stimulation are strongly attenuated by methyl marks, indicating widespread DNA methylation-environment interactions. In agreement, methylation-dependent responses to IFNA identified via mSTARR-seq predict methylation-dependent transcriptional responses to challenge with influenza virus in human macrophages. Our observations support the idea that pre-existing DNA methylation patterns can influence the response to subsequent environmental exposures—one of the tenets of biological embedding. However, we also find that, on average, sites previously associated with early life adversity are not more likely to functionally influence gene regulation than expected by chance.

Published

2024

3. Regulatory dissection of the severe COVID-19 risk locus introgressed by Neanderthals

Author

Evelyn Jagoda, Davide Marnetto, Gayani Senevirathne, Victoria Gonzalez, Kaushal Baid, Francesco Montinaro, Daniel Richard, Darryl Falzarano, Emmanuelle V LeBlanc, Che C Colpitts, Arinjay Banerjee, Luca Pagani, and Terence D Capellini

Subjects

MPRA, COVID-19, Neandertal introgression, cis-regulation, CCR1, CCR5, Medicine, Science, Biology (General), QH301-705.5

Abstract

Individuals infected with the SARS-CoV-2 virus present with a wide variety of symptoms 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 response to COVID-19. 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 genetic predisposition to severe COVID-19 outcomes. 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 a 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 four introgressed alleles that are strong functional candidates for driving the association between this locus and severe COVID-19. Using reporter assays in the presence/absence of SARS-CoV-2, we find evidence that these variants respond to viral infection. These variants likely drive the locus’ impact on severity by 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.

Published

2023

4. Analysis of long and short enhancers in melanoma cell states

Author

David Mauduit, Ibrahim Ihsan Taskiran, Liesbeth Minnoye, Maxime de Waegeneer, Valerie Christiaens, Gert Hulselmans, Jonas Demeulemeester, Jasper Wouters, and Stein Aerts

Subjects

melanoma, enhancers, MPRA, Medicine, Science, Biology (General), QH301-705.5

Abstract

Understanding how enhancers drive cell-type specificity and efficiently identifying them is essential for the development of innovative therapeutic strategies. In melanoma, the melanocytic (MEL) and the mesenchymal-like (MES) states present themselves with different responses to therapy, making the identification of specific enhancers highly relevant. Using massively parallel reporter assays (MPRAs) in a panel of patient-derived melanoma lines (MM lines), we set to identify and decipher melanoma enhancers by first focusing on regions with state-specific H3K27 acetylation close to differentially expressed genes. An in-depth evaluation of those regions was then pursued by investigating the activity of overlapping ATAC-seq peaks along with a full tiling of the acetylated regions with 190 bp sequences. Activity was observed in more than 60% of the selected regions, and we were able to precisely locate the active enhancers within ATAC-seq peaks. Comparison of sequence content with activity, using the deep learning model DeepMEL2, revealed that AP-1 alone is responsible for the MES enhancer activity. In contrast, SOX10 and MITF both influence MEL enhancer function with SOX10 being required to achieve high levels of activity. Overall, our MPRAs shed light on the relationship between long and short sequences in terms of their sequence content, enhancer activity, and specificity across melanoma cell states.

Published

2021

5. Parallel functional testing identifies enhancers active in early postnatal mouse brain

Author

Jason T Lambert, Linda Su-Feher, Karol Cichewicz, Tracy L Warren, Iva Zdilar, Yurong Wang, Kenneth J Lim, Jessica L Haigh, Sarah J Morse, Cesar P Canales, Tyler W Stradleigh, Erika Castillo Palacios, Viktoria Haghani, Spencer D Moss, Hannah Parolini, Diana Quintero, Diwash Shrestha, Daniel Vogt, Leah C Byrne, and Alex S Nord

Subjects

enhancer, MPRA, neurodevelopment, Medicine, Science, Biology (General), QH301-705.5

Abstract

Enhancers are cis-regulatory elements that play critical regulatory roles in modulating developmental transcription programs and driving cell-type-specific and context-dependent gene expression in the brain. The development of massively parallel reporter assays (MPRAs) has enabled high-throughput functional screening of candidate DNA sequences for enhancer activity. Tissue-specific screening of in vivo enhancer function at scale has the potential to greatly expand our understanding of the role of non-coding sequences in development, evolution, and disease. Here, we adapted a self-transcribing regulatory element MPRA strategy for delivery to early postnatal mouse brain via recombinant adeno-associated virus (rAAV). We identified and validated putative enhancers capable of driving reporter gene expression in mouse forebrain, including regulatory elements within an intronic CACNA1C linkage disequilibrium block associated with risk in neuropsychiatric disorder genetic studies. Paired screening and single enhancer in vivo functional testing, as we show here, represents a powerful approach towards characterizing regulatory activity of enhancers and understanding how enhancer sequences organize gene expression in the brain.

Published

2021

6. The cis-regulatory effects of modern human-specific variants

Author

Carly V Weiss, Lana Harshman, Fumitaka Inoue, Hunter B Fraser, Dmitri A Petrov, Nadav Ahituv, and David Gokhman

Subjects

expression, Neanderthal, Denisovan, ape, MPRA, SNP, Medicine, Science, Biology (General), QH301-705.5

Abstract

The Neanderthal and Denisovan genomes enabled the discovery of sequences that differ between modern and archaic humans, the majority of which are noncoding. However, our understanding of the regulatory consequences of these differences remains limited, in part due to the decay of regulatory marks in ancient samples. Here, we used a massively parallel reporter assay in embryonic stem cells, neural progenitor cells, and bone osteoblasts to investigate the regulatory effects of the 14,042 single-nucleotide modern human-specific variants. Overall, 1791 (13%) of sequences containing these variants showed active regulatory activity, and 407 (23%) of these drove differential expression between human groups. Differentially active sequences were associated with divergent transcription factor binding motifs, and with genes enriched for vocal tract and brain anatomy and function. This work provides insight into the regulatory function of variants that emerged along the modern human lineage and the recent evolution of human gene expression.

Published

2021