-This track represents genome-wide predicted binding sites for TF -(transcription factor) binding profiles in the -JASPAR -CORE collection. This open-source database contains a curated, non-redundant -set of binding profiles derived from published collections of experimentally -defined transcription factor binding sites for eukaryotes.
+This track represents the genome-wide predicted binding +sites for TF (transcription factor) binding profiles in the +JASPAR +database CORE collection. +Shaded boxes represent predicted binding sites for each of the TF profiles in the JASPAR CORE collection. The shading of the boxes indicates the p-value of the profile's match to that position (scaled between 0-1000 scores, where 0 corresponds to a p-value of 1 and 1000 to a p-value ≤ 10-10). Thus, the darker the shade, the lower (better) the p-value.
The default view shows only predicted binding sites with scores of 400 or greater but can be adjusted in the track settings. Multi-select filters allow viewing of particular transcription factors. At window sizes of greater than 10,000 base pairs, this track turns to density graph mode. Zoom to a smaller region and click into an item to see more detail.
From BED format documentation:
| shade | |||||||||
| score in range | ≤ 166 | 167-277 | 278-388 | 389-499 | 500-611 | 612-722 | 723-833 | 834-944 | ≥ 945 |
Conversion table:
| Item score | 0 | 100 | 131 | 200 | 300 | 400 | 500 | 600 | 700 | 800 | 900 | 1000 |
| p-value | 1 | 0.1 | 0.049 | 10-2 | 10-3 | 10-4 | 10-5 | 10-6 | 10-7 | 10-8 | 10-9 | ≤ 10-10 |
+For each TF binding profile in the JASPAR database CORE collection, genomes were scanned for matches. +
++For the computation of relative scores and p-values, we used PWMScan (Ambrosini et al. 2018). +We selected TFBS predictions with a PWM relative score ≥ 0.8 and a p-value < 0.05. +P-values were scaled between 0 (corresponding to a p-value of 1) and 1000 (p-value ≤ 10-10) +for colouring of the genome tracks and to allow for comparison of prediction confidence between +different profiles. +
++Please refer to the supplementary information of the JASPAR 2020 manuscript for more details. +
+JASPAR 2026 features a deep learning (DL) collection, providing a paradigm shift in modeling and characterizing TF-DNA interactions with 1259 BPNet models trained on Homo sapiens ENCODE chromatin immunoprecipitation followed by sequencing (ChIP-seq) datasets from 240 TFs and interpreted to reveal predictive motif patterns for the models. The motifs associated with the same TF were clustered to provide a summary of the binding properties, resulting in 240 primary and 113 alternative motif patterns in the DL collection. See the JASPAR 2026 publication for more information.
The JASPAR 2024 update expanded the JASPAR CORE collection by 20% (329 added and 72 upgraded profiles). The new profiles were introduced after manual curation, in which 26 629 TF binding motifs were curated and obtained as PFMs or discovered from ChIP-seq/-exo or DAP-seq data. 2500 profiles from JASPAR 2022 were revised to either promote them to the CORE collection, update the associated metadata, or remove them because of validation inconsistencies or poor quality. The JASPAR database stores and focuses mostly on PFMs as the model of choice for TF-DNA interactions. More information on the methods can be found in the JASPAR 2024 publication or on the JASPAR website.
JASPAR 2022 contains updated transcription factor binding sites with additional transcription factor profiles. More information on the methods can be found in the JASPAR 2022 publication JASPAR 2022 publication or on the JASPAR website.
JASPAR 2020 scanned DNA sequences with JASPAR CORE TF-binding profiles for each taxa independently using PWMScan. TFBS predictions were selected with a PWM relative score ≥ 0.8 and a p-value < 0.05. P-values were scaled between 0 (corresponding to a p-value of 1) and 1000 (p-value ≤ 10-10) for coloring of the genome tracks and to allow for comparison of prediction confidence between different profiles.
JASPAR 2018 used the TFBS Perl module (Lenhard and Wasserman 2002) and FIMO (Grant, Bailey, and Noble 2011), as distributed within the MEME suite (version 4.11.2) (Bailey et al. 2009). For scanning genomes with the BioPerl TFBS module, profiles were converted to PWMs and matches were kept with a relative score ≥ 0.8. For the FIMO scan, profiles were reformatted to MEME motifs and matches with a p-value < 0.05 were kept. TFBS predictions that were not consistent between the two methods (TFBS Perl module and FIMO) were removed. The remaining TFBS predictions were colored according to their FIMO p-value to allow for comparison of prediction confidence between different profiles.
--Please refer to the JASPAR 2024, 2022, 2020, and 2018 publications for more -details (citation below).
-JASPAR Transcription Factor Binding data includes billions of items. Limited regions can be explored interactively with the Table Browser and cross-referenced with Data Integrator, although positional queries that are too big can lead to timing out. This results in a black page or truncated output. In this case, you may try reducing the chromosomal query to a smaller window.
For programmatic access, the track can be accessed using the Genome Browser's REST API. JASPAR annotations can be downloaded from the Genome Browser's download server as a bigBed file. This compressed binary format can be remotely queried through command line utilities. Please note that some of the download files can be quite large.
The utilities for working with bigBed-formatted binary files can be downloaded here. Run a utility with no arguments to see a brief description of the utility and its options.
bigBedToBed http://hgdownload.soe.ucsc.edu/gbdb/$db/jaspar/JASPAR2024.bb -chrom=chr1 -start=200000 -end=200400 stdout
All data are freely available. Additional resources are available directly from the JASPAR group:
The JASPAR group provides TFBS predictions for many additional species and genomes. The 2026 release is available as a native track on the following genomes, and additionally on mm10 and araTha1 by connection to their Public Hub or by clicking the assembly links below:
| Species | Genome assembly versions |
| Human - Homo sapiens | hg38 |
| Mouse - Mus musculus | mm39 |
| Zebrafish - Danio rerio | danRer11 |
| Fruitfly - Drosophila melanogaster | dm6 |
| Nematode - Caenorhabditis elegans | ce11 |
| Vase tunicate - Ciona intestinalis | ci3 |
| Thale cress - Arabidopsis thaliana | araTha1 |
| Yeast - Saccharomyces cerevisiae | sacCer3 |
| Chicken - Gallus gallus | galGal6 |
-The JASPAR database is a joint effort between several labs -(please see the latest JASPAR paper, below). -Binding site predictions and UCSC tracks were computed by the Wasserman Lab. For -enquiries about the data please contact Oriol Fornes -( -oriol@cmmt. -ubc.ca -).
+The JASPAR database is a joint effort between several labs (please see the latest JASPAR +paper, below). Binding site predictions and UCSC tracks were computed by the CBGR team +at NCMBM using code developed at the Wasserman Lab. For enquiries about the data, +please contact Anthony Mathelier ( +) or Ieva Rauluseviciute ( +). +-- -Wasserman Lab
- Centre for Molecular Medicine and Therapeutics
- BC Children's Hospital Research Institute
- Department of Medical Genetics
- University of British Columbia
- Vancouver, Canada +CBGR
+Computational Biology & Gene Regulation
+Norwegian Centre for Molecular Biosciences and Medicine (NCMBM)
+University of Oslo
+Oslo, Norway
-Castro-Mondragon JA, Riudavets-Puig R, Rauluseviciute I, Berhanu Lemma R, Turchi L, Blanc-Mathieu R, -Lucas J, Boddie P, Khan A, Manosalva Pérez N et al. - -JASPAR 2022: the 9th release of the open-access database of transcription factor binding -profiles. -Nucleic Acids Res. 2021 Nov 30;. -PMID: 34850907 -
- --Fornes O, Castro-Mondragon JA, Khan A, van der Lee R, Zhang X, Richmond PA, -Modi BP, Correard S, Gheorghe M, Baranašić D et al. - -JASPAR 2020: update of the open-access database of transcription factor -binding profiles. -Nucleic Acids Res. 2020 Jan 8;48(D1):D87-D92. -PMID: 31701148; PMC: PMC7145627 +
+-Wasserman Lab
+
+Centre for Molecular Medicine and Therapeutics
+BC Children's Hospital Research Institute
+Department of Medical Genetics
+University of British Columbia
+Vancouver, Canada
-Khan A, Fornes O, Stigliani A, Gheorghe M, Castro-Mondragon JA, van der Lee R, -Bessy A, Chèneby J, Kulkarni SR, Tan G et al. - -JASPAR 2018: update of the open-access database of transcription factor -binding profiles and its web framework. -Nucleic Acids Res. 2018 Jan 4;46(D1):D260-D266. -PMID: 29140473; PMC: PMC5753243 -
+Ovek Baydar D, Rauluseviciute I, Aronsen DR, Blanc-Mathieu R, Bonthuis I, de Beukelaer H, Ferenc K, Jegou A, Kumar V, Lemma RB et al. -JASPAR 2026: expansion of transcription factor binding profiles and integration of deep learning -models. -Nucleic Acids Res. 2026 Jan 6;54(D1):D184-D193. -PMID: 41325984; PMC: PMC12807658 +JASPAR 2026: expansion of transcription factor binding profiles and integration of deep learning models. +Nucleic Acids Res. 2026; +PMID: 41325984; PMC: PMC12807658
-Rauluseviciute I, Riudavets-Puig R, Blanc-Mathieu R, Castro-Mondragon JA, Ferenc K, Kumar V, Lemma -RB, Lucas J, Chèneby J, Baranasic D et al. - -JASPAR 2024: 20th anniversary of the open-access database of transcription factor binding -profiles. -Nucleic Acids Res. 2023 Nov 14;. -PMID: 37962376 +Sandelin A, Alkema W, Engstrom P, Wasserman WW, Lenhard B. + +JASPAR: an open-access database for eukaryotic transcription factor binding profiles. +Nucleic Acids Res. 2004;. +PMID: 14681366
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