{"lab": {"display_title": "4DN DCIC, HMS", "status": "current", "@type": ["Lab", "Item"], "uuid": "828cd4fe-ebb0-4b36-a94a-d2e3a36cc989", "@id": "/labs/4dn-dcic-lab/", "principals_allowed": {"view": ["system.Everyone"], "edit": ["group.admin", "role.lab_submitter", "submits_for.828cd4fe-ebb0-4b36-a94a-d2e3a36cc989"]}}, "award": {"@id": "/awards/1U01CA200059-01/", "display_title": "4D NUCLEOME NETWORK DATA COORDINATION AND INTEGRATION CENTER - PHASE I", "uuid": "b0b9c607-f8b4-4f02-93f4-9895b461334b", "status": "current", "@type": ["Award", "Item"], "principals_allowed": {"view": ["system.Everyone"], "edit": ["group.admin"]}}, "title": "DNA SPRITE", "status": "released", "other_tags": ["DNA-DNA", "Multi-contact", "3D"], "date_created": "2019-03-28T18:07:16.767643+00:00", "submitted_by": {"error": "no view permissions"}, "last_modified": {"modified_by": {"error": "no view permissions"}, "date_modified": "2019-07-22T15:26:48.895872+00:00"}, "raw_file_types": "Reads (fastq) provided by lab", "reference_pubs": [{"date_published": "2018-06-07", "uuid": "4ab311b1-a442-46b4-ae4f-16c57521f52e", "@id": "/publications/4ab311b1-a442-46b4-ae4f-16c57521f52e/", "short_attribution": "Quinodoz SA et al. (2018)", "journal": "Cell", "authors": ["Quinodoz SA", "Ollikainen N", "Tabak B", "Palla A", "Schmidt JM", "Detmar E", "Lai MM", "Shishkin AA", "Bhat P", "Takei Y", "Trinh V", "Aznauryan E", "Russell P", "Cheng C", "Jovanovic M", "Chow A", "Cai L", "McDonel P", "Garber M", "Guttman M"], "display_title": "Quinodoz SA et al. (2018) doi:10.1016/j.cell.2018.05.024", "@type": ["Publication", "Item"], "status": "current", "principals_allowed": {"view": ["system.Everyone"], "edit": ["group.admin"]}}], "schema_version": "1", "static_content": [{"content": {"lab": {"uuid": "828cd4fe-ebb0-4b36-a94a-d2e3a36cc989", "display_title": "4DN DCIC, HMS", "@id": "/labs/4dn-dcic-lab/", "status": "current", "@type": ["Lab", "Item"], "principals_allowed": {"view": ["system.Everyone"], "edit": ["group.admin", "role.lab_submitter", "submits_for.828cd4fe-ebb0-4b36-a94a-d2e3a36cc989"]}}, "options": {"filetype": "html", "collapsible": false, "default_open": false, "convert_ext_links": true}, "title": "Assay Description", "name": "item-page-headers.ExperimentType.sprite2", "award": {"@id": "/awards/2U01CA200059-06/", "display_title": "4D NUCLEOME NETWORK DATA COORDINATION AND INTEGRATION CENTER - PHASE II", "status": "current", "@type": ["Award", "Item"], "uuid": "71171a4e-dca1-44cb-8375-fafd896c6923", "principals_allowed": {"view": ["system.Everyone"], "edit": ["group.admin"]}}, "content_as_html": "
SPRITE \n

\nSPRITE is a method to detect and quantify genome-wide higher-order interactions that occur simultaneously within the same nucleus. It was first published in 2018, and it aims to address certain limitations of proximity ligation and imaging methods. Compared to proximity ligation methods, this technique does not depend on the ligation of spatially close DNA fragments; therefore, it can detect interactions occurring across larger distances in the genome. Additionally, unlike both methods that can only capture simultaneous interactions between a small number of genomic regions (2-3), this technique is able to capture simultaneous interactions between a larger number of genomic regions.\n

\n

\nThe protocol involves cross-linking the cells to form links between physically adjacent DNA regions and other interacting molecules such as RNA and proteins. Then, the cells are lysed, and a restriction enzyme is used to digest the chromatin into multiple fragments. The cross-linked complexes are coupled to magnetic beads. A split-pool tagging strategy is performed that consists of splitting the cross-linked complexes across a 96 well plate, and ligating a tag sequence unique to each well to each molecule. The wells are then pooled and this process is repeated several times. The molecules located in the same complex will stick together throughout the entire split-pool process, resulting in them having the same barcode combination at the end, while the molecules located in other complexes will have their own distinct barcode combinations. The molecules are sequenced, and all the reads containing the same unique barcode combination are grouped together into a cluster. Initial processing results in the generation of a clusters file where each cluster occupies one line that includes the barcode name and genomic alignments of that cluster. This can be used for additional analysis and to create visualizations.\n\nSee Quinodoz et. al. Cell 2018 for more details.\n

\n
\n\n\n\n
", "uuid": "205f35ec-92cd-4c02-bd35-b0d38dd72a90", "@id": "/static-sections/205f35ec-92cd-4c02-bd35-b0d38dd72a90/", "display_title": "Assay Description", "status": "released", "content": " SPRITE \n

\nSPRITE is a method to detect and quantify genome-wide higher-order interactions that occur simultaneously within the same nucleus. It was first published in 2018, and it aims to address certain limitations of proximity ligation and imaging methods. Compared to proximity ligation methods, this technique does not depend on the ligation of spatially close DNA fragments; therefore, it can detect interactions occurring across larger distances in the genome. Additionally, unlike both methods that can only capture simultaneous interactions between a small number of genomic regions (2-3), this technique is able to capture simultaneous interactions between a larger number of genomic regions.\n

\n

\nThe protocol involves cross-linking the cells to form links between physically adjacent DNA regions and other interacting molecules such as RNA and proteins. Then, the cells are lysed, and a restriction enzyme is used to digest the chromatin into multiple fragments. The cross-linked complexes are coupled to magnetic beads. A split-pool tagging strategy is performed that consists of splitting the cross-linked complexes across a 96 well plate, and ligating a tag sequence unique to each well to each molecule. The wells are then pooled and this process is repeated several times. The molecules located in the same complex will stick together throughout the entire split-pool process, resulting in them having the same barcode combination at the end, while the molecules located in other complexes will have their own distinct barcode combinations. The molecules are sequenced, and all the reads containing the same unique barcode combination are grouped together into a cluster. Initial processing results in the generation of a clusters file where each cluster occupies one line that includes the barcode name and genomic alignments of that cluster. This can be used for additional analysis and to create visualizations.\n\nSee Quinodoz et. al. Cell 2018 for more details.\n

\n\n
\n\n\n\n
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A 4DN Data Processing pipeline is not yet available for SPRITE. \nPreliminary processed files for SPRITE experiments are \navailable in the Supplementary Files tab of the Experiment Set\n and were generated by analysis pipelines of the attributed \nlab.\n\n

\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n
File TypeFile FormatDescription
Clusters.clusters.gzSPRITE clusters are contained in gzipped tab-delimited files, where the first column is the combination of barcodes for reads in the cluster, and the subsequent columns are the start of the mapping location of each read in the cluster. Lines have variable numbers of columns. Generally the clusters from individual replicate experiments will be merged into a single clusters file for the experiment set. Code for the analysis of SPRITE clusters is available here.
Contact Matrix.mcoolSPRITE clusters can be converted to pairwise contact matrices in .mcool format. For each cluster, all possible combinations of pairs are generated, generally with a downweighted count of 2/n, where n is the number of reads in the cluster. The pairs are then streamed into Cooler to generate a .cool file, after which a multi-resolution .mcool is generated. These can be visualized on the portal with HiGlass.
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\n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n
File TypeFile FormatDescription
Clusters.clusters.gzSPRITE clusters are contained in gzipped tab-delimited files, where the first column is the combination of barcodes for reads in the cluster, and the subsequent columns are the start of the mapping location of each read in the cluster. Lines have variable numbers of columns. Generally the clusters from individual replicate experiments will be merged into a single clusters file for the experiment set. Code for the analysis of SPRITE clusters is available here.
Contact Matrix.mcoolSPRITE clusters can be converted to pairwise contact matrices in .mcool format. For each cluster, all possible combinations of pairs are generated, generally with a downweighted count of 2/n, where n is the number of reads in the cluster. The pairs are then streamed into Cooler to generate a .cool file, after which a multi-resolution .mcool is generated. These can be visualized on the portal with HiGlass.
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