Your search keyword '"Capture Hi-C"' showing total 17 results

1. Targeted Chromosome Conformation Capture (HiCap)

Author

Zhigulev, Artemy, Sahlén, Pelin, Zhigulev, Artemy, and Sahlén, Pelin

Abstract

Targeted chromosome conformation capture (HiCap) is an experimental method for detecting spatial interactions of genomic features such as promoters and/or enhancers. The protocol first describes the design of sequence capture probes. After that, it provides details on the chromosome conformation capture adapted for next-generation sequencing (Hi-C). Finally, the methodology for coupling Hi-C with sequence capture technology is described., QC 20230502

Published

2022

2. Targeted Chromosome Conformation Capture (HiCap)

Author

Zhigulev, Artemy, Sahlén, Pelin, Zhigulev, Artemy, and Sahlén, Pelin

Abstract

Targeted chromosome conformation capture (HiCap) is an experimental method for detecting spatial interactions of genomic features such as promoters and/or enhancers. The protocol first describes the design of sequence capture probes. After that, it provides details on the chromosome conformation capture adapted for next-generation sequencing (Hi-C). Finally, the methodology for coupling Hi-C with sequence capture technology is described., QC 20230502

Published

2022

3. KSHV Topologically Associating Domains in Latent and Reactivated Viral Chromatin.

Author

Campbell, Mel, Jung, Jae U1, Campbell, Mel, Chantarasrivong, Chanikarn, Yanagihashi, Yuichi, Inagaki, Tomoki, Davis, Ryan R, Nakano, Kazushi, Kumar, Ashish, Tepper, Clifford G, Izumiya, Yoshihiro, Campbell, Mel, Jung, Jae U1, Campbell, Mel, Chantarasrivong, Chanikarn, Yanagihashi, Yuichi, Inagaki, Tomoki, Davis, Ryan R, Nakano, Kazushi, Kumar, Ashish, Tepper, Clifford G, and Izumiya, Yoshihiro

Abstract

Eukaryotic genomes are structurally organized via the formation of multiple loops that create gene expression regulatory units called topologically associating domains (TADs). Here we revealed the KSHV TAD structure at 500 bp resolution and constructed a 3D KSHV genomic structural model with 2 kb binning. The latent KSHV genome formed very similar genomic architectures in three different naturally infected PEL cell lines and in an experimentally infected epithelial cell line. The majority of the TAD boundaries were occupied by structural maintenance of chromosomes (SMC1) cohesin complex and CCCTC-binding factor (CTCF), and the KSHV transactivator was recruited to those sites during reactivation. Triggering KSHV gene expression decreased prewired genomic loops within the regulatory unit, while contacts extending outside of regulatory borders increased, leading to formation of a larger regulatory unit with a shift from repressive to active compartments (B to A). The 3D genomic structural model proposes that the immediate early promoter region is localized on the periphery of the 3D viral genome during latency, while highly inducible noncoding RNA regions moved toward the inner space of the structure, resembling the configuration of a "bird cage" during reactivation. The compartment-like properties of viral episomal chromatin structure and its reorganization during the transition from latency may help facilitate viral gene transcription. IMPORTANCE The 3D architecture of chromatin allows for efficient arrangement, expression, and replication of genetic material. The genomes of all organisms studied to date have been found to be organized through some form of tiered domain structures. However, the architectural framework of the genomes of large double-stranded DNA viruses such as the herpesvirus family has not been reported. Prior studies with Kaposi's sarcoma-associated herpesvirus (KSHV) have indicated that the viral chromatin shares many biological properties exhibit

Published

2022

4. Low input promoter capture Hi-C method enables to decipher the molecular mechanisms underlying genetically complex diseases

Author

López-Martí, Paula, Javierre, Biola M, Valencia, Alfonso, López-Martí, Paula, Javierre, Biola M, and Valencia, Alfonso

Abstract

Interactions between promoters and their regulatory elements (e.g., enhancers) are cell-type specific. Moreover, these promoter-enhancer contacts have been shown to be crucial for proper gene expression levels, and their alteration promotes disease [1, 2]. The most widely used experimental methods require tens of millions of cells to obtain the whole high-resolution promoter associations, also called promoter interactome, independently of their activity. This requirement precludes the genome-wide analysis of regulatory promoter interactions in disease-relevant patient samples. This gap of knowledge is particularly problematic for understanding the molecular mechanism underlying inherited risk factors for common human diseases and acquired mutations and epimutations, which all are all highly enriched at regulatory elements. To provide novel insight into global genomic regulatory mechanisms and gene pathways underlying disease pathologies, Javierre et al. implemented promoter capture Hi- C (PCHi-C) method [1]. It allows systematic genome-wide identification of the genomic regions, including distal regulatory regions, in physical proximity with more than 22,000 promoters independently of the activity status of the interacting regions. In addition, due to PCHi-C method relying just on the sequence capture technology, but not in antibody immunoprecipitation as other methods do, it enables the robust compassion between conditions or cell types and the customization to interrogate any specific interactomes (e.g., enhancer interactome or the interactome in which a collection of variants). Applying this method, it has been possible to associate non-coding disease-associated variants to their distal target promoters, identifying hundreds of potential new disease-candidate genes and/or gene pathways. However, PCHi-C relies on the availability of millions of cells, typically from 20 to 50 million per biological replicate, which prohibits the analysis of rare cell populations su

Published

2022

5. KSHV Topologically Associating Domains in Latent and Reactivated Viral Chromatin.

Author

Campbell, Mel, Jung, Jae U1, Campbell, Mel, Chantarasrivong, Chanikarn, Yanagihashi, Yuichi, Inagaki, Tomoki, Davis, Ryan R, Nakano, Kazushi, Kumar, Ashish, Tepper, Clifford G, Izumiya, Yoshihiro, Campbell, Mel, Jung, Jae U1, Campbell, Mel, Chantarasrivong, Chanikarn, Yanagihashi, Yuichi, Inagaki, Tomoki, Davis, Ryan R, Nakano, Kazushi, Kumar, Ashish, Tepper, Clifford G, and Izumiya, Yoshihiro

Abstract

Eukaryotic genomes are structurally organized via the formation of multiple loops that create gene expression regulatory units called topologically associating domains (TADs). Here we revealed the KSHV TAD structure at 500 bp resolution and constructed a 3D KSHV genomic structural model with 2 kb binning. The latent KSHV genome formed very similar genomic architectures in three different naturally infected PEL cell lines and in an experimentally infected epithelial cell line. The majority of the TAD boundaries were occupied by structural maintenance of chromosomes (SMC1) cohesin complex and CCCTC-binding factor (CTCF), and the KSHV transactivator was recruited to those sites during reactivation. Triggering KSHV gene expression decreased prewired genomic loops within the regulatory unit, while contacts extending outside of regulatory borders increased, leading to formation of a larger regulatory unit with a shift from repressive to active compartments (B to A). The 3D genomic structural model proposes that the immediate early promoter region is localized on the periphery of the 3D viral genome during latency, while highly inducible noncoding RNA regions moved toward the inner space of the structure, resembling the configuration of a "bird cage" during reactivation. The compartment-like properties of viral episomal chromatin structure and its reorganization during the transition from latency may help facilitate viral gene transcription. IMPORTANCE The 3D architecture of chromatin allows for efficient arrangement, expression, and replication of genetic material. The genomes of all organisms studied to date have been found to be organized through some form of tiered domain structures. However, the architectural framework of the genomes of large double-stranded DNA viruses such as the herpesvirus family has not been reported. Prior studies with Kaposi's sarcoma-associated herpesvirus (KSHV) have indicated that the viral chromatin shares many biological properties exhibit

Published

2022

6. Targeted Chromosome Conformation Capture (HiCap)

Author

Zhigulev, Artemy, Sahlén, Pelin, Zhigulev, Artemy, and Sahlén, Pelin

Abstract

Targeted chromosome conformation capture (HiCap) is an experimental method for detecting spatial interactions of genomic features such as promoters and/or enhancers. The protocol first describes the design of sequence capture probes. After that, it provides details on the chromosome conformation capture adapted for next-generation sequencing (Hi-C). Finally, the methodology for coupling Hi-C with sequence capture technology is described., QC 20230502

Published

2022

7. Targeted Chromosome Conformation Capture (HiCap)

Author

Zhigulev, Artemy, Sahlén, Pelin, Zhigulev, Artemy, and Sahlén, Pelin

Abstract

Targeted chromosome conformation capture (HiCap) is an experimental method for detecting spatial interactions of genomic features such as promoters and/or enhancers. The protocol first describes the design of sequence capture probes. After that, it provides details on the chromosome conformation capture adapted for next-generation sequencing (Hi-C). Finally, the methodology for coupling Hi-C with sequence capture technology is described., QC 20230502

Published

2022

8. Targeted Chromosome Conformation Capture (HiCap)

Author

Zhigulev, Artemy, Sahlén, Pelin, Zhigulev, Artemy, and Sahlén, Pelin

Abstract

Targeted chromosome conformation capture (HiCap) is an experimental method for detecting spatial interactions of genomic features such as promoters and/or enhancers. The protocol first describes the design of sequence capture probes. After that, it provides details on the chromosome conformation capture adapted for next-generation sequencing (Hi-C). Finally, the methodology for coupling Hi-C with sequence capture technology is described., QC 20230502

Published

2022

9. Chromatin interactions in differentiating keratinocytes reveal novel atopic dermatitis- and psoriasis-associated genes

Author

Sahlén, Pelin, Spalinskas, Rapolas, Asad, Samina, Mahapatra, Kunal Das, Höjer, Pontus, Anil, Anandashankar, Eisfeldt, Jesper, Srivastava, Ankit, Nikamo, Pernilla, Mukherjee, Anaya, Kim, Kyu-Han, Bergman, Otto, Ståhle, Mona, Sonkoly, Enikö, Pivarcsi, Andor, Wahlgren, Carl-Fredrik, Nordenskjöld, Magnus, Taylan, Fulya, Bradley, Maria, Tapia-Páez, Isabel, Sahlén, Pelin, Spalinskas, Rapolas, Asad, Samina, Mahapatra, Kunal Das, Höjer, Pontus, Anil, Anandashankar, Eisfeldt, Jesper, Srivastava, Ankit, Nikamo, Pernilla, Mukherjee, Anaya, Kim, Kyu-Han, Bergman, Otto, Ståhle, Mona, Sonkoly, Enikö, Pivarcsi, Andor, Wahlgren, Carl-Fredrik, Nordenskjöld, Magnus, Taylan, Fulya, Bradley, Maria, and Tapia-Páez, Isabel

Abstract

BACKGROUND: Hundreds of variants associated with atopic dermatitis (AD) and psoriasis, 2 common inflammatory skin disorders, have previously been discovered through genome-wide association studies (GWASs). The majority of these variants are in noncoding regions, and their target genes remain largely unclear. OBJECTIVE: We sought to understand the effects of these noncoding variants on the development of AD and psoriasis by linking them to the genes that they regulate. METHODS: We constructed genomic 3-dimensional maps of human keratinocytes during differentiation by using targeted chromosome conformation capture (Capture Hi-C) targeting more than 20,000 promoters and 214 GWAS variants and combined these data with transcriptome and epigenomic data sets. We validated our results with reporter assays, clustered regularly interspaced short palindromic repeats activation, and examination of patient gene expression from previous studies. RESULTS: We identified 118 target genes of 82 AD and psoriasis GWAS variants. Differential expression of 58 of the 118 target genes (49%) occurred in either AD or psoriatic lesions, many of which were not previously linked to any skin disease. We highlighted the genes AFG1L, CLINT1, ADO, LINC00302, and RP1-140J1.1 and provided further evidence for their potential roles in AD and psoriasis. CONCLUSIONS: Our work focused on skin barrier pathology through investigation of the interaction profile of GWAS variants during keratinocyte differentiation. We have provided a catalogue of candidate genes that could modulate the risk of AD and psoriasis. Given that only 35% of the target genes are the gene nearest to the known GWAS variants, we expect that our work will contribute to the discovery of novel pathways involved in AD and psoriasis.

Published

2021

10. Chromatin interactions in differentiating keratinocytes reveal novel atopic dermatitis- and psoriasis-associated genes

Author

Sahlén, Pelin, Spalinskas, Rapolas, Asad, Samina, Mahapatra, Kunal Das, Höjer, Pontus, Anil, Anandashankar, Eisfeldt, Jesper, Srivastava, Ankit, Nikamo, Pernilla, Mukherjee, Anaya, Kim, Kyu-Han, Bergman, Otto, Ståhle, Mona, Sonkoly, Enikö, Pivarcsi, Andor, Wahlgren, Carl-Fredrik, Nordenskjöld, Magnus, Taylan, Fulya, Bradley, Maria, Tapia-Páez, Isabel, Sahlén, Pelin, Spalinskas, Rapolas, Asad, Samina, Mahapatra, Kunal Das, Höjer, Pontus, Anil, Anandashankar, Eisfeldt, Jesper, Srivastava, Ankit, Nikamo, Pernilla, Mukherjee, Anaya, Kim, Kyu-Han, Bergman, Otto, Ståhle, Mona, Sonkoly, Enikö, Pivarcsi, Andor, Wahlgren, Carl-Fredrik, Nordenskjöld, Magnus, Taylan, Fulya, Bradley, Maria, and Tapia-Páez, Isabel

Abstract

BACKGROUND: Hundreds of variants associated with atopic dermatitis (AD) and psoriasis, 2 common inflammatory skin disorders, have previously been discovered through genome-wide association studies (GWASs). The majority of these variants are in noncoding regions, and their target genes remain largely unclear. OBJECTIVE: We sought to understand the effects of these noncoding variants on the development of AD and psoriasis by linking them to the genes that they regulate. METHODS: We constructed genomic 3-dimensional maps of human keratinocytes during differentiation by using targeted chromosome conformation capture (Capture Hi-C) targeting more than 20,000 promoters and 214 GWAS variants and combined these data with transcriptome and epigenomic data sets. We validated our results with reporter assays, clustered regularly interspaced short palindromic repeats activation, and examination of patient gene expression from previous studies. RESULTS: We identified 118 target genes of 82 AD and psoriasis GWAS variants. Differential expression of 58 of the 118 target genes (49%) occurred in either AD or psoriatic lesions, many of which were not previously linked to any skin disease. We highlighted the genes AFG1L, CLINT1, ADO, LINC00302, and RP1-140J1.1 and provided further evidence for their potential roles in AD and psoriasis. CONCLUSIONS: Our work focused on skin barrier pathology through investigation of the interaction profile of GWAS variants during keratinocyte differentiation. We have provided a catalogue of candidate genes that could modulate the risk of AD and psoriasis. Given that only 35% of the target genes are the gene nearest to the known GWAS variants, we expect that our work will contribute to the discovery of novel pathways involved in AD and psoriasis.

Published

2021

11. Chromatin interactions in differentiating keratinocytes reveal novel atopic dermatitis- and psoriasis-associated genes

Author

Sahlén, Pelin, Spalinskas, Rapolas, Asad, Samina, Mahapatra, Kunal Das, Höjer, Pontus, Anil, Anandashankar, Eisfeldt, Jesper, Srivastava, Ankit, Nikamo, Pernilla, Mukherjee, Anaya, Kim, Kyu-Han, Bergman, Otto, Ståhle, Mona, Sonkoly, Enikö, Pivarcsi, Andor, Wahlgren, Carl-Fredrik, Nordenskjöld, Magnus, Taylan, Fulya, Bradley, Maria, Tapia-Páez, Isabel, Sahlén, Pelin, Spalinskas, Rapolas, Asad, Samina, Mahapatra, Kunal Das, Höjer, Pontus, Anil, Anandashankar, Eisfeldt, Jesper, Srivastava, Ankit, Nikamo, Pernilla, Mukherjee, Anaya, Kim, Kyu-Han, Bergman, Otto, Ståhle, Mona, Sonkoly, Enikö, Pivarcsi, Andor, Wahlgren, Carl-Fredrik, Nordenskjöld, Magnus, Taylan, Fulya, Bradley, Maria, and Tapia-Páez, Isabel

Abstract

BACKGROUND: Hundreds of variants associated with atopic dermatitis (AD) and psoriasis, 2 common inflammatory skin disorders, have previously been discovered through genome-wide association studies (GWASs). The majority of these variants are in noncoding regions, and their target genes remain largely unclear. OBJECTIVE: We sought to understand the effects of these noncoding variants on the development of AD and psoriasis by linking them to the genes that they regulate. METHODS: We constructed genomic 3-dimensional maps of human keratinocytes during differentiation by using targeted chromosome conformation capture (Capture Hi-C) targeting more than 20,000 promoters and 214 GWAS variants and combined these data with transcriptome and epigenomic data sets. We validated our results with reporter assays, clustered regularly interspaced short palindromic repeats activation, and examination of patient gene expression from previous studies. RESULTS: We identified 118 target genes of 82 AD and psoriasis GWAS variants. Differential expression of 58 of the 118 target genes (49%) occurred in either AD or psoriatic lesions, many of which were not previously linked to any skin disease. We highlighted the genes AFG1L, CLINT1, ADO, LINC00302, and RP1-140J1.1 and provided further evidence for their potential roles in AD and psoriasis. CONCLUSIONS: Our work focused on skin barrier pathology through investigation of the interaction profile of GWAS variants during keratinocyte differentiation. We have provided a catalogue of candidate genes that could modulate the risk of AD and psoriasis. Given that only 35% of the target genes are the gene nearest to the known GWAS variants, we expect that our work will contribute to the discovery of novel pathways involved in AD and psoriasis.

Published

2021

12. Chromatin interactions in differentiating keratinocytes reveal novel atopic dermatitis- and psoriasis-associated genes

Author

Sahlén, Pelin, Spalinskas, Rapolas, Asad, Samina, Mahapatra, Kunal Das, Höjer, Pontus, Anil, Anandashankar, Eisfeldt, Jesper, Srivastava, Ankit, Nikamo, Pernilla, Mukherjee, Anaya, Kim, Kyu-Han, Bergman, Otto, Ståhle, Mona, Sonkoly, Enikö, Pivarcsi, Andor, Wahlgren, Carl-Fredrik, Nordenskjöld, Magnus, Taylan, Fulya, Bradley, Maria, Tapia-Páez, Isabel, Sahlén, Pelin, Spalinskas, Rapolas, Asad, Samina, Mahapatra, Kunal Das, Höjer, Pontus, Anil, Anandashankar, Eisfeldt, Jesper, Srivastava, Ankit, Nikamo, Pernilla, Mukherjee, Anaya, Kim, Kyu-Han, Bergman, Otto, Ståhle, Mona, Sonkoly, Enikö, Pivarcsi, Andor, Wahlgren, Carl-Fredrik, Nordenskjöld, Magnus, Taylan, Fulya, Bradley, Maria, and Tapia-Páez, Isabel

Abstract

BACKGROUND: Hundreds of variants associated with atopic dermatitis (AD) and psoriasis, 2 common inflammatory skin disorders, have previously been discovered through genome-wide association studies (GWASs). The majority of these variants are in noncoding regions, and their target genes remain largely unclear. OBJECTIVE: We sought to understand the effects of these noncoding variants on the development of AD and psoriasis by linking them to the genes that they regulate. METHODS: We constructed genomic 3-dimensional maps of human keratinocytes during differentiation by using targeted chromosome conformation capture (Capture Hi-C) targeting more than 20,000 promoters and 214 GWAS variants and combined these data with transcriptome and epigenomic data sets. We validated our results with reporter assays, clustered regularly interspaced short palindromic repeats activation, and examination of patient gene expression from previous studies. RESULTS: We identified 118 target genes of 82 AD and psoriasis GWAS variants. Differential expression of 58 of the 118 target genes (49%) occurred in either AD or psoriatic lesions, many of which were not previously linked to any skin disease. We highlighted the genes AFG1L, CLINT1, ADO, LINC00302, and RP1-140J1.1 and provided further evidence for their potential roles in AD and psoriasis. CONCLUSIONS: Our work focused on skin barrier pathology through investigation of the interaction profile of GWAS variants during keratinocyte differentiation. We have provided a catalogue of candidate genes that could modulate the risk of AD and psoriasis. Given that only 35% of the target genes are the gene nearest to the known GWAS variants, we expect that our work will contribute to the discovery of novel pathways involved in AD and psoriasis.

Published

2021

13. Chromatin interactions in differentiating keratinocytes reveal novel atopic dermatitis- and psoriasis-associated genes

Author

Sahlén, Pelin, Spalinskas, Rapolas, Asad, Samina, Mahapatra, Kunal Das, Höjer, Pontus, Anil, Anandashankar, Eisfeldt, Jesper, Srivastava, Ankit, Nikamo, Pernilla, Mukherjee, Anaya, Kim, Kyu-Han, Bergman, Otto, Ståhle, Mona, Sonkoly, Enikö, Pivarcsi, Andor, Wahlgren, Carl-Fredrik, Nordenskjöld, Magnus, Taylan, Fulya, Bradley, Maria, Tapia-Páez, Isabel, Sahlén, Pelin, Spalinskas, Rapolas, Asad, Samina, Mahapatra, Kunal Das, Höjer, Pontus, Anil, Anandashankar, Eisfeldt, Jesper, Srivastava, Ankit, Nikamo, Pernilla, Mukherjee, Anaya, Kim, Kyu-Han, Bergman, Otto, Ståhle, Mona, Sonkoly, Enikö, Pivarcsi, Andor, Wahlgren, Carl-Fredrik, Nordenskjöld, Magnus, Taylan, Fulya, Bradley, Maria, and Tapia-Páez, Isabel

Abstract

BACKGROUND: Hundreds of variants associated with atopic dermatitis (AD) and psoriasis, 2 common inflammatory skin disorders, have previously been discovered through genome-wide association studies (GWASs). The majority of these variants are in noncoding regions, and their target genes remain largely unclear. OBJECTIVE: We sought to understand the effects of these noncoding variants on the development of AD and psoriasis by linking them to the genes that they regulate. METHODS: We constructed genomic 3-dimensional maps of human keratinocytes during differentiation by using targeted chromosome conformation capture (Capture Hi-C) targeting more than 20,000 promoters and 214 GWAS variants and combined these data with transcriptome and epigenomic data sets. We validated our results with reporter assays, clustered regularly interspaced short palindromic repeats activation, and examination of patient gene expression from previous studies. RESULTS: We identified 118 target genes of 82 AD and psoriasis GWAS variants. Differential expression of 58 of the 118 target genes (49%) occurred in either AD or psoriatic lesions, many of which were not previously linked to any skin disease. We highlighted the genes AFG1L, CLINT1, ADO, LINC00302, and RP1-140J1.1 and provided further evidence for their potential roles in AD and psoriasis. CONCLUSIONS: Our work focused on skin barrier pathology through investigation of the interaction profile of GWAS variants during keratinocyte differentiation. We have provided a catalogue of candidate genes that could modulate the risk of AD and psoriasis. Given that only 35% of the target genes are the gene nearest to the known GWAS variants, we expect that our work will contribute to the discovery of novel pathways involved in AD and psoriasis.

Published

2021

14. Promoter anchored interaction landscape of THP-1 macrophages captures early immune response processes

Author

Pradhananga, Sailendra, Spalinskas, Rapolas, Poujade, Flore-Anne, Eriksson, Per, Sahlén, Pelin, Pradhananga, Sailendra, Spalinskas, Rapolas, Poujade, Flore-Anne, Eriksson, Per, and Sahlén, Pelin

Abstract

Macrophages are highly plastic immune cells with temporally distinct transcriptome changes upon lipopolysaccride (LPS) activation. However, to what extent transcriptome reprogramming is mediated via spatial chromatin looping is not well studied. We generated high resolution chromatin interaction maps for LPS-stimulated THP-1 macrophages (0 and 2 h) using capture Hi-C. Success of LPS stimulation was validated with transcriptome sequencing. Circa 2900 genes changed their interaction profile upon LPS stimulation and those gaining interactions were enriched for LPS response relevant processes, suggesting a substantial role for distal regulation. Immune and cardiovascular risk variants were enriched within the interacting regions, thereby providing insights into macrophage biology., QC 20200915

Published

2020

15. Systematic comparison of gene regulatory datasets using experimentally validated enhancers

Author

Dong, Xue and Dong, Xue

Abstract

Promoter-enhancer interactions are essential for gene regulating, Capture Hi-C is a chromosome conformation capture method to map promoter-enhancer interactions at high resolution. We have Capture Hi-C data forGM12878 cells, immortalized primary B lymphocytes, in three replicates. Although Capture Hi-C maps enhancer elements together with the promoters they regulate, the overlap between enhancer datasets produced by other methods such as ChIP-seq and Capture Hi-C is lower than expected. In order to understand the reasons for lower overlap, we investigated the enhancer potential of replicated and non-replicated Capture Hi-C interactors, as well as enhancer overlapping and non-overlapping Capture Hi-C interactors. We performed a systematic comparison between our interactor and experimental regulatory and transcriptomic datasets to determine the extent of enhancer mapping. The results show replicated interactors have higher enhancer potential than non-replicated ones. However, there is evidence that interactors not overlapping with experimental validated regulatory datasets can also potentially be true enhancers.

Published

2020

16. Chromatin interactions in differentiating keratinocytes reveal novel atopic dermatitis– and psoriasis-associated genes

Author

Sahlén, Pelin, Spalinskas, Rapolas, Asad, S., Mahapatra, K. D., Höjer, Pontus, Anil, Anandashankar, Eisfeldt, J., Srivastava, A., Nikamo, P., Mukherjee, A., Kim, K. -H, Bergman, O., Ståhle, M., Sonkoly, E., Pivarcsi, A., Wahlgren, C. -F, Nordenskjöld, M., Taylan, F., Bradley, M., Tapia-Páez, I., Sahlén, Pelin, Spalinskas, Rapolas, Asad, S., Mahapatra, K. D., Höjer, Pontus, Anil, Anandashankar, Eisfeldt, J., Srivastava, A., Nikamo, P., Mukherjee, A., Kim, K. -H, Bergman, O., Ståhle, M., Sonkoly, E., Pivarcsi, A., Wahlgren, C. -F, Nordenskjöld, M., Taylan, F., Bradley, M., and Tapia-Páez, I.

Abstract

Background: Hundreds of variants associated with atopic dermatitis (AD) and psoriasis, 2 common inflammatory skin disorders, have previously been discovered through genome-wide association studies (GWASs). The majority of these variants are in noncoding regions, and their target genes remain largely unclear. Objective: We sought to understand the effects of these noncoding variants on the development of AD and psoriasis by linking them to the genes that they regulate. Methods: We constructed genomic 3-dimensional maps of human keratinocytes during differentiation by using targeted chromosome conformation capture (Capture Hi-C) targeting more than 20,000 promoters and 214 GWAS variants and combined these data with transcriptome and epigenomic data sets. We validated our results with reporter assays, clustered regularly interspaced short palindromic repeats activation, and examination of patient gene expression from previous studies. Results: We identified 118 target genes of 82 AD and psoriasis GWAS variants. Differential expression of 58 of the 118 target genes (49%) occurred in either AD or psoriatic lesions, many of which were not previously linked to any skin disease. We highlighted the genes AFG1L, CLINT1, ADO, LINC00302, and RP1-140J1.1 and provided further evidence for their potential roles in AD and psoriasis. Conclusions: Our work focused on skin barrier pathology through investigation of the interaction profile of GWAS variants during keratinocyte differentiation. We have provided a catalogue of candidate genes that could modulate the risk of AD and psoriasis. Given that only 35% of the target genes are the gene nearest to the known GWAS variants, we expect that our work will contribute to the discovery of novel pathways involved in AD and psoriasis., QC 20210308

Published

2020

17. Systematic comparison of gene regulatory datasets using experimentally validated enhancers

Author

Dong, Xue and Dong, Xue

Abstract

Promoter-enhancer interactions are essential for gene regulating, Capture Hi-C is a chromosome conformation capture method to map promoter-enhancer interactions at high resolution. We have Capture Hi-C data forGM12878 cells, immortalized primary B lymphocytes, in three replicates. Although Capture Hi-C maps enhancer elements together with the promoters they regulate, the overlap between enhancer datasets produced by other methods such as ChIP-seq and Capture Hi-C is lower than expected. In order to understand the reasons for lower overlap, we investigated the enhancer potential of replicated and non-replicated Capture Hi-C interactors, as well as enhancer overlapping and non-overlapping Capture Hi-C interactors. We performed a systematic comparison between our interactor and experimental regulatory and transcriptomic datasets to determine the extent of enhancer mapping. The results show replicated interactors have higher enhancer potential than non-replicated ones. However, there is evidence that interactors not overlapping with experimental validated regulatory datasets can also potentially be true enhancers.

Published

2020