Description

This track shows short genetic variants (up to approximately 50 base pairs) from dbSNP build 153: single-nucleotide variants (SNVs), small insertions, deletions, and complex deletion/insertions, relative to the reference genome assembly. Most variants in dbSNP are rare, not true polymorphisms, and some variants are known to be pathogenic.

For hg38 (GRCh38), approximately 667 million distinct variants (RefSNP clusters with rs# ids) have been mapped to over 702 million genomic locations including alternate haplotype and fix patch sequences. dbSNP remapped variants from hg38 to hg19 (GRCh37); approximately 658 million distinct variants were mapped to over 683 million genomic locations including alternate haplotype and fix patch sequences (not all of which are included in UCSC's hg19).

This track includes four subtracks of variants:

• All dbSNP (153): the entire set (683 million for hg19, 702 million for hg38)
• Common dbSNP (153): approximately 15 million variants with a minor allele frequency (MAF) of at least 1% (0.01) in the 1000 Genomes Phase 3 dataset. Variants in the Mult. subset (below) are excluded.
• ClinVar dbSNP (153): approximately 455,000 variants mentioned in ClinVar. Note: that includes both benign and pathogenic (as well as uncertain) variants. Variants in the Mult. subset (below) are excluded.
• Mult. dbSNP (153): variants that have been mapped to multiple chromosomes, for example chr1 and chr2, raising the question of whether the variant is really a variant or just a difference between duplicated sequences. There are some exceptions in which a variant is mapped to more than one reference sequence, but not culled into this set:
  • A variant may appear in both X and Y pseudo-autosomal regions (PARs) without being included in this set.
  • A variant may also appear in a main chromosome as well as an alternate haplotype or fix patch sequence assigned to that chromosome.

A fifth subtrack highlights coordinate ranges to which dbSNP mapped a variant but with genomic coordinates that are not internally consistent, i.e. different coordinate ranges were provided when describing different alleles. This can occur due to a bug with mapping variants from one assembly sequence to another when there is an indel difference between the assembly sequences:

• Map Err (153): around 120,000 mappings of 55,000 distinct rsIDs for hg19 and 149,000 mappings of 86,000 distinct rsIDs for hg38.

Interpreting and Configuring the Graphical Display

SNVs and pure deletions are displayed as boxes covering the affected base(s). Pure insertions are drawn as single-pixel tickmarks between the base before and the base after the insertion.

Insertions and/or deletions in repetitive regions may be represented by a half-height box showing uncertainty in placement, followed by a full-height box showing the number of deleted bases, or a full-height tickmark to indicate an insertion. When an insertion or deletion falls in a repetitive region, the placement may be ambiguous. For example, if the reference genome contains "TAAAG" but some individuals have "TAAG" at the same location, then the variant is a deletion of a single A relative to the reference genome. However, which A was deleted? There is no way to tell whether the first, second or third A was removed. Different variant mapping tools may place the deletion at different bases in the reference genome. In order to reduce errors in merging variant calls made with different left vs. right biases, dbSNP made a major change in its representation of deletion/insertion variants in build 152. Now, instead of assigning a single-base genomic location at one of the A's, dbSNP expands the coordinates to encompass the whole repetitive region, so the variant is represented as a deletion of 3 A's combined with an insertion of 2 A's. In the track display, there will be a half-height box covering the first two A's, followed by a full-height box covering the third A, in order to show a net loss of one base but an uncertain placement within the three A's.

Variants are colored according to functional effect on genes annotated by dbSNP. Protein-altering variants and splice site variants are red, synonymous codon variants are green, and non-coding transcript or Untranslated Region (UTR) variants are blue.

On the track controls page, several variant properties can be included or excluded from the item labels: rs# identifier assigned by dbSNP, reference/alternate alleles, major/minor alleles (when available) and minor allele frequency (when available). Allele frequencies are reported independently by twelve projects (some of which may have overlapping sets of samples):

• 1000Genomes: The 1000 Genomes Phase 3 dataset contains data for 2,504 individuals from 26 populations.
• GnomAD exomes: The gnomAD v2.1 exome dataset comprises a total of 16 million SNVs and 1.2 million indels from 125,748 exomes in 14 populations.
• TOPMED: The TOPMED dataset contains phase 3 data from freeze 5 panel that include over 60,000 individuals. The approximate ethnic breakdown is European(52%), African (31%), Hispanic or Latino (10%), and East Asian (7%) ancestry.
• ExAC: The Exome Aggregation Consortium (ExAC) dataset contains 60,706 unrelated individuals sequenced as part of various disease-specific and population genetic studies. Individuals affected by severe pediatric disease have been removed.
• PAGE STUDY: The PAGE Study: How Genetic Diversity Improves Our Understanding of the Architecture of Complex Traits.
• GnomAD genomes: The gnomAD v2.1 genome dataset includes 229 million SNVs and 33 million indels from 15,708 genomes in 9 populations.
• GoESP: The NHLBI Grand Opportunity Exome Sequencing Project (GO-ESP) dataset contains 6503 samples drawn from multiple ESP cohorts and represents all of the ESP exome variant data.
• Estonian: Genetic variation in the Estonian population: pharmacogenomics study of adverse drug effects using electronic health records.
• ALSPAC: The UK10K - Avon Longitudinal Study of Parents and Children project contains 1927 sample including individuals obtained from the ALSPAC population. This population contains more than 14,000 mothers enrolled during pregnancy in 1991 and 1992.
• TWINSUK: The UK10K - TwinsUK project contains 1854 samples from the Department of Twin Research and Genetic Epidemiology (DTR). The DTR dataset contains data obtained from the 11,000 identical and non-identical twins between the ages of 16 and 85 years old.
• NorthernSweden: Whole-genome sequenced control population in northern Sweden reveals subregional genetic differences. This population consists of 300 whole genome sequenced human samples selected from the county of Vasterbotten in northern Sweden. To be selected for inclusion into the population, the individuals had to have reached at least 80 years of age and have no diagnosed cancer.
• Vietnamese: The Vietnamese Genetic Variation Database includes about 25 million variants (SNVs and indels) from 406 genomes and 305 exomes of unrelated healthy Kinh Vietnamese (KHV) people.

Using the track controls, variants can be filtered by

• minimum minor allele frequency (MAF)
• variation class/type (e.g. SNV, insertion, deletion)
• functional effect on a gene (e.g. synonymous, frameshift, intron, upstream)
• assorted features and anomalies noted by UCSC during processing of dbSNP's data

dbSNP has collected genetic variant reports from researchers worldwide for over 20 years. Since the advent of next-generation sequencing methods and the population sequencing efforts that they enable, dbSNP has grown exponentially, requiring a new data schema, computational pipeline, web infrastructure, and download files. (Holmes et al.) The same challenges of exponential growth affected UCSC's presentation of dbSNP variants, so we have taken the opportunity to change our internal representation and import pipeline. Most notably, flanking sequences are no longer provided by dbSNP, since most submissions have been genomic variant calls in VCF format as opposed to independent sequences.

We downloaded dbSNP's JSON files available from ftp://ftp.ncbi.nlm.nih.gov/snp/archive/b153/JSON/, extracted a subset of the information about each variant, and collated it into a bigBed file using the bigDbSnp.as schema with the information necessary for filtering and displaying the variants, as well as a separate file containing more detailed information to be displayed on each variant's details page (dbSnpDetails.as schema).

Data Access

The raw data underlying the UCSC Genome Browser track can be explored interactively with the Table Browser or Data Integrator. For automated analysis, the track data files can be downloaded from the downloads server for hg38 and hg19 (dbSnp153.bb); the detailed variant properties can be downloaded from hgFixed (dbSnp153Details.tab.gz).

Please refer to our mailing list archives for questions and example queries, or our Data Access FAQ for more information.

References

Holmes JB, Moyer E, Phan L, Maglott D, Kattman B. SPDI: Data Model for Variants and Applications at NCBI. Bioinformatics. 2019 Nov 18;. PMID: 31738401

Sayers EW, Agarwala R, Bolton EE, Brister JR, Canese K, Clark K, Connor R, Fiorini N, Funk K, Hefferon T et al. Database resources of the National Center for Biotechnology Information. Nucleic Acids Res. 2019 Jan 8;47(D1):D23-D28. PMID: 30395293; PMC: PMC6323993

Sherry ST, Ward MH, Kholodov M, Baker J, Phan L, Smigielski EM, Sirotkin K. dbSNP: the NCBI database of genetic variation. Nucleic Acids Res. 2001 Jan 1;29(1):308-11. PMID: 11125122; PMC: PMC29783