The Variant Annotation Integrator (VAI) is a research tool for associating
annotations from the UCSC database with your uploaded set of variant calls.
It uses gene annotations to predict functional effects of variants on transcripts.
For example, a variant might be located in the coding sequence
of one transcript, but in the intron of an alternatively spliced transcript
of the same gene; the VAI will return the predicted functional effect
for each transcript. The VAI can optionally add several other
types of relevant information: the dbSNP identifier if the variant
is found in
protein damage scores for missense variants from the
Database of Non-synonymous Functional Predictions (dbNSFP),
and conservation scores computed from multi-species alignments.
The VAI can optionally filter results to retain only specific functional
effect categories, variant properties and multi-species conservation status.
The VAI is only a research tool, meant to be used by those who have been
properly trained in the interpretation of genetic data,
and should never be used to make any kind of medical decision.
We urge users seeking information about a personal medical or genetic
condition to consult with a qualified physician for diagnosis and for
answers to personal questions.
Submitting your variant calls
In order to use the VAI, you must provide variant calls in either the
Personal Genome SNP (pgSnp) or
pgSnp-formatted variants may be uploaded as a
Compressed and indexed VCF files must be on a web server (HTTP, HTTPS or FTP)
and configured as Custom Tracks, or if you happen to have a
as hub tracks.
Protein-coding gene transcript effect predictions
Any gene prediction track in the UCSC Genome Browser database or in a track hub
can be selected as the VAI's source of transcript annotations for prediction
of functional effects.
Sequence Ontology (SO) terms are used to describe the effect
of each variant on genes in terms of transcript structure as follows:
||A sequence variant located in the intergenic region, between genes.|
||A sequence variant located 5' of a gene. (VAI searches within 5,000 bases.)|
||A sequence variant located 3' of a gene. (VAI searches within 5,000 bases.)|
||A variant located in the 5' untranslated region (UTR) of a gene.|
||A variant located in the 3' untranslated region (UTR) of a gene.|
||A sequence variant where there is no resulting change to the encoded amino acid.|
||A sequence variant, that changes one or more bases, resulting in a
different amino acid sequence but where the length is preserved.|
||An inframe non synonymous variant that inserts bases into in the coding sequence.|
||An inframe non synonymous variant that deletes bases from the coding sequence.|
||A sequence variant which causes a disruption of the translational
reading frame, because the number of nucleotides inserted or deleted is not
a multiple of three.|
||A codon variant that changes at least one base of the first codon of a transcript.|
||A sequence variant where at least one base of the final codon of an
incompletely annotated transcript is changed.|
||A sequence variant where at least one base of the terminator codon
(stop) is changed, resulting in an elongated transcript.|
||A sequence variant where at least one base in the terminator codon is
changed, but the terminator remains.|
||A sequence variant whereby an exon is lost from the transcript.
(VAI assigns this term when an entire exon is deleted.)|
||A sequence variant whereby at least one base of a codon is changed,
resulting in a premature stop codon, leading to a shortened transcript.|
||A variant in a transcript that is already the target of nonsense-mediated decay (NMD),
i.e. stop codon is not in last exon nor within 50 bases of the end of the second-to-last
||A transcript variant occurring within an intron.|
||A splice variant that changes the 2-base region at the 5' end of an intron.|
||A splice variant that changes the 2 base region at the 3' end of an intron.|
||A sequence variant in which a change has occurred within the region
of the splice site, either within 1-3 bases of the exon or 3-8 bases of
||A transcript variant with a complex insertion or deletion (indel) that
spans an exon/intron border or a coding sequence/UTR border.|
||A sequence variant that changes exon sequence of a non-coding gene.|
||A variant that causes no change to the transcript sequence and/or
specifies only the reference allele, no alternate allele.
In rare cases when the transcript sequence (e.g. from RefSeq) differs from the
reference genome assembly, a difference from the reference genome may restore
the transcript sequence instead of altering it.|
In addition to protein-coding genes, some genome assemblies offer other sources of
annotations that can be included in the output for each variant.
Database of Non-synonymous Functional Predictions (dbNSFP)
dbNSFP annotations are available only for hg19/GRCh37 (dbNSFP release 2.0) and
hg38/GRCh38 (release 3.1a).
(Liu et al. 2011)
provides pre-computed scores and predictions of functional
significance from a variety of tools. Every possible coding change to
(for hg19: release 9, Ensembl 64, Dec. 2011;
for hg38, release 22, Ensembl 79, Mar. 2015)
gene predictions has been evaluated.
dbNSFP includes only single-nucleotide missense changes;
its data do not apply to indels, multi-nucleotide variants,
non-coding or synonymous changes.
dbNSFP provides scores and predictions from several tools that use various
machine learning techniques to estimate the likelihood that a single-nucleotide
missense variant would damage a protein's structure and function:
- SIFT (Sorting Intolerant From Tolerant)
uses sequence homology and the physical properties of amino acids
to predict whether an amino acid substitution affects protein function.
Scores less than 0.05 are classified as Damaging ("D" in output);
higher scores are classified as Tolerated ("T").
(Ng and Henikoff, 2003)
- PolyPhen-2 (Polymorphism Phenotyping v2)
applies a naive Bayes classifier using
several sequence-based and structure-based predictive features
including refined multi-species alignments.
PolyPhen-2 was trained on two datasets, and dbNSFP provides
scores for both.
The HumDiv training set is intended for evaluating rare alleles
potentially involved in complex phenotypes, for example in
genome-wide association studies (GWAS).
Predictions are derived from scores, with these ranges for HumDiv:
"probably damaging" ("D") for scores in [0.957, 1];
"possibly damaging" ("P") for scores in [0.453, 0.956];
"benign" ("B") for scores in [0, 0.452].
HumVar is intended for studies of Mendelian diseases, for which
mutations with drastic effects must be sorted out from abundant
mildly deleterious variants.
Predictions are derived from scores, with these ranges for HumDiv:
"probably damaging" ("D") for scores in [0.909, 1];
"possibly damaging" ("P") for scores in [0.447, 0.908];
"benign" ("B") for scores in [0, 0.446].
(Adzhubei et al., 2010)
- MutationTaster applies a naive Bayes classifier
trained on a large dataset
(>390,000 known disease mutations from HGMD Professional and
>6,800,000 presumably harmless SNP and Indel polymorphisms
from the 1000 Genomes Project).
Variants that cause a premature stop codon resulting in
nonsense-mediated decay (NMD), as well as
variants marked as probable-pathogenic or pathogenic in
are automatically presumed to be disease-causing ("A").
Variants with all three genotypes present in HapMap or with
at least 4 heterozygous genotypes in 1000 Genomes are automatically
presumed to be harmless polymorphisms ("P").
Variants not automatically determined to be disease-causing or polymorphic
are predicted to be "disease-causing" ("D") or
polymorphisms ("N") by the classifier.
Probability scores close to 1 indicate high "security" of
the prediction; probabilities close to 0 for an automatic prediction
("A" or "P")
can indicate that the classifier predicted a different outcome.
(Schwarz et al., 2010)
uses sequence homologs grouped into families and sub-families by
combinatorial entropy formalism to compute a Functional Impact Score
(FIS). It is intended for use in cancer studies, in which both gain
of function and loss of function are important; the authors also
identify a third category, "switch of function."
A prediction of "high" or "medium" indicates that the
variant probably has some functional impact, while "low" or
"neutral" indicate that the variant is probably function-neutral.
(Reva et al., 2011)
- LRT (Likelihood Ratio Test)
uses comparative genomics to identify variants that disrupt highly conserved
Variants are predicted to be deleterious ("D"), neutral ("N")
or unknown ("U").
(Chun and Fay, 2009)
- VEST (Variant Effect Scoring Tool)
(available only for hg38/GRCh38)
uses a classifier that was trained with ~45,000 disease mutations from HGMD
and ~45,000 high frequency missense variants (putatively neutral) from the
Exome Sequencing Project.
(Carter et al., 2013)
In addition, dbNSFP provides
InterPro protein domains where available
(Hunter et al., 2012) and two measures
of conservation computed by
(Davydov et al., 2010).
Some of the gene prediction tracks have additional annotations
to indicate the amount or quality of supporting evidence for each transcript.
When the track selected in the "Select Genes" section has such annotations,
these can be enabled under "Transcript Status". The options depend on which
gene prediction track is selected.
- GENCODE tags:
when GENCODE Genes are selected in the "Select Genes" section,
GENCODE tags associated with a transcript can be added to output.
- RefSeq status:
when RefSeq Genes are selected in the "Select Genes" section,
status can be included in output.
- Canonical UCSC transcripts:
when UCSC Genes (labeled GENCODE V22 in hg38/GRCh38)
are selected in the "Select Genes" section,
the flag "CANONICAL=YES" is added when the transcript
has been chosen as "canonical" (see the "Related Data" section of the
UCSC Genes track description).
If the selected genome assembly has a SNPs track (derived from
when a variant has the same start and end coordinates as a variant in
the VAI includes the reference SNP (rs#) identifier in the output.
Currently, the VAI does not compare alleles due to the frequency of strand
anomalies in dbSNP.
If the selected genome assembly has a Conservation track with phyloP scores
and/or phastCons scores and conserved elements,
those can be included in the output.
Both phastCons and phyloP are part of the
see the Conservation track description in the Genome Browser
for more details.
The volume of unrestricted output can be quite large,
making it difficult to identify variants of particular interest.
Several filters can be applied to keep only those variants
that have specific properties.
By default, all variants are included in the output regardless of
predicted functional effect. If you would like to keep only variants
that have a particular type of effect, you can uncheck the checkboxes
of other effect types.
The detailed functional effect predictions are categorized as follows:
- upstream/downstream of gene:
- 5' or 3' UTR:
- CDS - synonymous coding change:
- CDS - non-synonymous (missense, stop gain/loss, frameshift etc):
- splice site or splice region:
- exon of non-coding gene:
(applicable only to assemblies that have "Common SNPs" and
"Mult SNPs" tracks)
By default, all variants appear in output regardless of overlap with known
dbSNP variants that map to multiple locations (a possible red flag),
or that have a global minor allele frequency (MAF) of 1% or higher.
Those categories of known variants can be used to exclude overlapping variants
from output by unchecking the corresponding checkbox.
(applicable only to assemblies that have "Conservation" tracks)
If desired, output can be restricted to only those variants that overlap
conserved elements computed by phastCons.
Currently, the VAI produces output comparable to Ensembl's
Variant Effect Predictor (VEP), in either tab-separated
text format or HTML.
Columns are described
When text output is selected, entering an output file name causes output to
be saved in a local file instead of appearing in the browser, optionally
compressed by gzip (compression reduces file size and network traffic,
which results in faster downloads).
When HTML is selected, output always appears in the browser window and the
output file name is ignored.
Anyone familiar with Ensembl's
Variant Effect Predictor (VEP) will doubtless notice
similarities in options and interface. In collaboration with our colleagues
at Ensembl, we have made an effort to limit the differences between the tools
by using Sequence Ontology terms to describe variants' functional effects and
by creating a "VEP" output format.
Any bugs in the VAI, however, are in the VAI only.