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Single-nucleotide polymorphism

September 30, 2023

"SNPs" redirects here. For the singular, see SNP (disambiguation).

In genetics and bioinformatics, a single-nucleotide polymorphism (SNP /snɪp/; plural SNPs /snɪps/) is a germline substitution of a single nucleotide at a specific position in the genome that is present in a sufficiently large fraction of considered population (generally regarded as 1% or more).[1][2]

The upper DNA molecule differs from the lower DNA molecule at a single base-pair location (a G/A polymorphism)

For example, a G nucleotide present at a specific location in a reference genome may be replaced by an A in a minority of individuals. The two possible nucleotide variations of this SNP – G or A – are called alleles.[3]

SNPs can help explain differences in susceptibility to a wide range of diseases across a population. For example, a common SNP in the CFH gene is associated with increased risk of age-related macular degeneration.[4] Differences in the severity of an illness or response to treatments may also be manifestations of genetic variations caused by SNPs. For example, two common SNPs in the APOE gene, rs429358 and rs7412, lead to three major APO-E alleles with different associated risks for development of Alzheimer's disease and age at onset of the disease.[5]

Single nucleotide substitutions with an allele frequency of less than 1% are sometimes called single-nucleotide variants (SNVs).[6] "Variant" may also be used as a general term for any single nucleotide change in a DNA sequence,[2] encompassing both common SNPs and rare mutations, whether germline or somatic.[7][8] The term SNV has therefore been used to refer to point mutations found in cancer cells.[9] DNA variants must also commonly be taken into consideration in molecular diagnostics applications such as designing PCR primers to detect viruses, in which the viral RNA or DNA sample may contain SNVs.[citation needed] However, this nomenclature uses arbitrary distinctions (such as an allele frequency of 1%) and is not used consistently across all fields; the resulting disagreement has prompted calls for a more consistent framework for naming differences in DNA sequences between two samples.[10][11]

Types Edit

 
Types of single-nucleotide polymorphism (SNPs)

Single-nucleotide polymorphisms may fall within coding sequences of genes, non-coding regions of genes, or in the intergenic regions(regions between genes). SNPs within a coding sequence do not necessarily change the amino acid sequence of the protein that is produced, due to degeneracy of the genetic code.[12]

SNPs in the coding region are of two types: synonymous SNPs and nonsynonymous SNPs. Synonymous SNPs do not affect the protein sequence, while nonsynonymous SNPs change the amino acid sequence of protein.[13]

  • SNPs in non-coding regions can manifest in a higher risk of cancer,[14] and may affect mRNA structure and disease susceptibility.[15] Non-coding SNPs can also alter the level of expression of a gene, as an eQTL (expression quantitative trait locus).
  • SNPs in coding regions:
    • synonymous substitutions by definition do not result in a change of amino acid in the protein, but still can affect its function in other ways. An example would be a seemingly silent mutation in the multidrug resistance gene 1 (MDR1), which codes for a cellular membrane pump that expels drugs from the cell, can slow down translation and allow the peptide chain to fold into an unusual conformation, causing the mutant pump to be less functional (in MDR1 protein e.g. C1236T polymorphism changes a GGC codon to GGT at amino acid position 412 of the polypeptide (both encode glycine) and the C3435T polymorphism changes ATC to ATT at position 1145 (both encode isoleucine)).[16]
    • nonsynonymous substitutions:

SNPs that are not in protein-coding regions may still affect gene splicing, transcription factor binding, messenger RNA degradation, or the sequence of noncoding RNA. Gene expression affected by this type of SNP is referred to as an eSNP (expression SNP) and may be upstream or downstream from the gene.

Frequency Edit

More than 600 million SNPs have been identified across the human genome in the world's population.[19] A typical genome differs from the reference human genome at 4 to 5 million sites, most of which (more than 99.9%) consist of SNPs and short indels.[20]

Within a genome Edit

The genomic distribution of SNPs is not homogenous; SNPs occur in non-coding regions more frequently than in coding regions or, in general, where natural selection is acting and "fixing" the allele (eliminating other variants) of the SNP that constitutes the most favorable genetic adaptation.[21] Other factors, like genetic recombination and mutation rate, can also determine SNP density.[22]

SNP density can be predicted by the presence of microsatellites: AT microsatellites in particular are potent predictors of SNP density, with long (AT)(n) repeat tracts tending to be found in regions of significantly reduced SNP density and low GC content.[23]

Within a population Edit

There are variations between human populations, so a SNP allele that is common in one geographical or ethnic group may be much rarer in another. However, this pattern of variation is relatively rare; in a global sample of 67.3 million SNPs, the Human Genome Diversity Project "found no such private variants that are fixed in a given continent or major region. The highest frequencies are reached by a few tens of variants present at >70% (and a few thousands at >50%) in Africa, the Americas, and Oceania. By contrast, the highest frequency variants private to Europe, East Asia, the Middle East, or Central and South Asia reach just 10 to 30%."[24]

Within a population, SNPs can be assigned a minor allele frequency—the lowest allele frequency at a locus that is observed in a particular population.[25] This is simply the lesser of the two allele frequencies for single-nucleotide polymorphisms.

With this knowledge scientists have developed new methods in analyzing population structures in less studied species.[26][27][28] By using pooling techniques the cost of the analysis is significantly lowered.[citation needed] These techniques are based on sequencing a population in a pooled sample instead of sequencing every individual within the population by itself. With new bioinformatics tools there is a possibility of investigating population structure, gene flow and gene migration by observing the allele frequencies within the entire population. With these protocols there is a possibility in combining the advantages of SNPs with micro satellite markers.[29][30] However, there are information lost in the process such as linkage disequilibrium and zygosity information.

Applications Edit

  • Association studies can determine whether a genetic variant is associated with a disease or trait.[31]
  • A tag SNP is a representative single-nucleotide polymorphism in a region of the genome with high linkage disequilibrium (the non-random association of alleles at two or more loci). Tag SNPs are useful in whole-genome SNP association studies, in which hundreds of thousands of SNPs across the entire genome are genotyped.
  • Haplotype mapping: sets of alleles or DNA sequences can be clustered so that a single SNP can identify many linked SNPs.
  • Linkage disequilibrium (LD), a term used in population genetics, indicates non-random association of alleles at two or more loci, not necessarily on the same chromosome. It refers to the phenomenon that SNP allele or DNA sequence that are close together in the genome tend to be inherited together. LD can be affected by two parameters (among other factors, such as population stratification): 1) The distance between the SNPs [the larger the distance, the lower the LD]. 2) Recombination rate [the lower the recombination rate, the higher the LD].[32]
  • In genetic epidemiology SNPs are used to estimate transmission clusters.[33]

Importance Edit

Variations in the DNA sequences of humans can affect how humans develop diseases and respond to pathogens, chemicals, drugs, vaccines, and other agents. SNPs are also critical for personalized medicine.[34] Examples include biomedical research, forensics, pharmacogenetics, and disease causation, as outlined below.

Clinical research Edit

Genome-wide association study (GWAS) Edit

One of main contributions of SNPs in clinical research is genome-wide association study (GWAS).[35] Genome-wide genetic data can be generated by multiple technologies, including SNP array and whole genome sequencing. GWAS has been commonly used in identifying SNPs associated with diseases or clinical phenotypes or traits. Since GWAS is a genome-wide assessment, a large sample site is required to obtain sufficient statistical power to detect all possible associations. Some SNPs have relatively small effect on diseases or clinical phenotypes or traits. To estimate study power, the genetic model for disease needs to be considered, such as dominant, recessive, or additive effects. Due to genetic heterogeneity, GWAS analysis must be adjusted for race.

Candidate gene association study Edit

Candidate gene association study is commonly used in genetic study before the invention of high throughput genotyping or sequencing technologies.[36] Candidate gene association study is to investigate limited number of pre-specified SNPs for association with diseases or clinical phenotypes or traits. So this is a hypothesis driven approach. Since only a limited number of SNPs are tested, a relatively small sample size is sufficient to detect the association. Candidate gene association approach is also commonly used to confirm findings from GWAS in independent samples.

Homozygosity mapping in disease Edit

Genome-wide SNP data can be used for homozygosity mapping.[37] Homozygosity mapping is a method used to identify homozygous autosomal recessive loci, which can be a powerful tool to map genomic regions or genes that are involved in disease pathogenesis.

Methylation patterns Edit

 
Associations between SNPs, methylation patterns and gene expression of biological traits

Recently, preliminary results reported SNPs as important components of the epigenetic program in organisms.[38][39] Moreover, cosmopolitan studies in European and South Asiatic populations have revealed the influence of SNPs in the methylation of specific CpG sites.[40] In addition, meQTL enrichment analysis using GWAS database, demonstrated that those associations are important toward the prediction of biological traits.[40][41][42]  

Forensic sciences Edit

SNPs have historically been used to match a forensic DNA sample to a suspect but has been made obsolete due to advancing STR-based DNA fingerprinting techniques. However, the development of next-generation-sequencing (NGS) technology may allow for more opportunities for the use of SNPs in phenotypic clues such as ethnicity, hair color, and eye color with a good probability of a match. This can additionally be applied to increase the accuracy of facial reconstructions by providing information that may otherwise be unknown, and this information can be used to help identify suspects even without a STR DNA profile match.

Some cons to using SNPs versus STRs is that SNPs yield less information than STRs, and therefore more SNPs are needed for analysis before a profile of a suspect is able to be created. Additionally, SNPs heavily rely on the presence of a database for comparative analysis of samples. However, in instances with degraded or small volume samples, SNP techniques are an excellent alternative to STR methods. SNPs (as opposed to STRs) have an abundance of potential markers, can be fully automated, and a possible reduction of required fragment length to less than 100bp.[26]

Pharmacogenetics Edit

Pharmacogenetics focuses on identifying genetic variations including SNPs associated with differential responses to treatment.[43] Many drug metabolizing enzymes, drug targets, or target pathways can be influenced by SNPs. The SNPs involved in drug metabolizing enzyme activities can change drug pharmacokinetics, while the SNPs involved in drug target or its pathway can change drug pharmacodynamics. Therefore, SNPs are potential genetic markers that can be used to predict drug exposure or effectiveness of the treatment. Genome-wide pharmacogenetic study is called pharmacogenomics. Pharmacogenetics and pharmacogenomics are important in the development of precision medicine, especially for life-threatening diseases such as cancers.

Disease Edit

Only small amount of SNPs in the human genome may have impact on human diseases. Large scale GWAS has been done for the most important human diseases, including heart diseases, metabolic diseases, autoimmune diseases, and neurodegenerative and psychiatric disorders.[35] Most of the SNPs with relatively large effects on these diseases have been identified. These findings have significantly improved understanding of disease pathogenesis and molecular pathways, and facilitated development of better treatment. Further GWAS with larger samples size will reveal the SNPs with relatively small effect on diseases. For common and complex diseases, such as type-2 diabetes, rheumatoid arthritis, and Alzheimer's disease, multiple genetic factors are involved in disease etiology. In addition, gene-gene interaction and gene-environment interaction also play an important role in disease initiation and progression.[44]

Examples Edit

Databases Edit

As there are for genes, bioinformatics databases exist for SNPs.

  • dbSNP is a SNP database from the National Center for Biotechnology Information (NCBI). As of June 8, 2015, dbSNP listed 149,735,377 SNPs in humans.[52][53]
  • Kaviar[54] is a compendium of SNPs from multiple data sources including dbSNP.
  • SNPedia is a wiki-style database supporting personal genome annotation, interpretation and analysis.
  • The OMIM database describes the association between polymorphisms and diseases (e.g., gives diseases in text form)
  • dbSAP – single amino-acid polymorphism database for protein variation detection[55]
  • The Human Gene Mutation Database provides gene mutations causing or associated with human inherited diseases and functional SNPs
  • The International HapMap Project, where researchers are identifying Tag SNPs to be able to determine the collection of haplotypes present in each subject.
  • GWAS Central allows users to visually interrogate the actual summary-level association data in one or more genome-wide association studies.

The International SNP Map working group mapped the sequence flanking each SNP by alignment to the genomic sequence of large-insert clones in Genebank. These alignments were converted to chromosomal coordinates that is shown in Table 1.[56] This list has greatly increased since, with, for instance, the Kaviar database now listing 162 million single nucleotide variants (SNVs).

Chromosome Length(bp) All SNPs TSC SNPs
Total SNPs kb per SNP Total SNPs kb per SNP
1 214,066,000 129,931 1.65 75,166 2.85
2 222,889,000 103,664 2.15 76,985 2.90
3 186,938,000 93,140 2.01 63,669 2.94
4 169,035,000 84,426 2.00 65,719 2.57
5 170,954,000 117,882 1.45 63,545 2.69
6 165,022,000 96,317 1.71 53,797 3.07
7 149,414,000 71,752 2.08 42,327 3.53
8 125,148,000 57,834 2.16 42,653 2.93
9 107,440,000 62,013 1.73 43,020 2.50
10 127,894,000 61,298 2.09 42,466 3.01
11 129,193,000 84,663 1.53 47,621 2.71
12 125,198,000 59,245 2.11 38,136 3.28
13 93,711,000 53,093 1.77 35,745 2.62
14 89,344,000 44,112 2.03 29,746 3.00
15 73,467,000 37,814 1.94 26,524 2.77
16 74,037,000 38,735 1.91 23,328 3.17
17 73,367,000 34,621 2.12 19,396 3.78
18 73,078,000 45,135 1.62 27,028 2.70
19 56,044,000 25,676 2.18 11,185 5.01
20 63,317,000 29,478 2.15 17,051 3.71
21 33,824,000 20,916 1.62 9,103 3.72
22 33,786,000 28,410 1.19 11,056 3.06
X 131,245,000 34,842 3.77 20,400 6.43
Y 21,753,000 4,193 5.19 1,784 12.19
RefSeq 15,696,674 14,534 1.08
Totals 2,710,164,000 1,419,190 1.91 887,450 3.05

Nomenclature Edit

The nomenclature for SNPs include several variations for an individual SNP, while lacking a common consensus.

The rs### standard is that which has been adopted by dbSNP and uses the prefix "rs", for "reference SNP", followed by a unique and arbitrary number.[57] SNPs are frequently referred to by their dbSNP rs number, as in the examples above.

The Human Genome Variation Society (HGVS) uses a standard which conveys more information about the SNP. Examples are:

  • c.76A>T: "c." for coding region, followed by a number for the position of the nucleotide, followed by a one-letter abbreviation for the nucleotide (A, C, G, T or U), followed by a greater than sign (">") to indicate substitution, followed by the abbreviation of the nucleotide which replaces the former[58][59][60]
  • p.Ser123Arg: "p." for protein, followed by a three-letter abbreviation for the amino acid, followed by a number for the position of the amino acid, followed by the abbreviation of the amino acid which replaces the former.[61]

SNP analysis Edit

SNPs can be easily assayed due to only containing two possible alleles and three possible genotypes involving the two alleles: homozygous A, homozygous B and heterozygous AB, leading to many possible techniques for analysis. Some include: DNA sequencing; capillary electrophoresis; mass spectrometry; single-strand conformation polymorphism (SSCP); single base extension; electrochemical analysis; denaturating HPLC and gel electrophoresis; restriction fragment length polymorphism; and hybridization analysis.

Programs for prediction of SNP effects Edit

An important group of SNPs are those that corresponds to missense mutations causing amino acid change on protein level. Point mutation of particular residue can have different effect on protein function (from no effect to complete disruption its function). Usually, change in amino acids with similar size and physico-chemical properties (e.g. substitution from leucine to valine) has mild effect, and opposite. Similarly, if SNP disrupts secondary structure elements (e.g. substitution to proline in alpha helix region) such mutation usually may affect whole protein structure and function. Using those simple and many other machine learning derived rules a group of programs for the prediction of SNP effect was developed:[62]

  • SIFT This program provides insight into how a laboratory induced missense or nonsynonymous mutation will affect protein function based on physical properties of the amino acid and sequence homology.
  • LIST[63][64] (Local Identity and Shared Taxa) estimates the potential deleteriousness of mutations resulted from altering their protein functions. It is based on the assumption that variations observed in closely related species are more significant when assessing conservation compared to those in distantly related species.
  • SNAP2
  • SuSPect
  • PolyPhen-2
  • PredictSNP
  • MutationTaster: official website
  • Variant Effect Predictor from the Ensembl project
  • SNPViz 2020-08-07 at the Wayback Machine[65] This program provides a 3D representation of the protein affected, highlighting the amino acid change so doctors can determine pathogenicity of the mutant protein.
  • PROVEAN
  • PhyreRisk is a database which maps variants to experimental and predicted protein structures.[66]
  • Missense3D is a tool which provides a stereochemical report on the effect of missense variants on protein structure.[67]

See also Edit

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Further reading Edit

  • "Glossary". Nature Reviews.
  • — SNP Fact Sheet

External links Edit

 
Wikimedia Commons has media related to Single nucleotide polymorphism.
  • NCBI resources 2013-09-02 at the Wayback Machine – Introduction to SNPs from NCBI
  • – SNP search
  • NCBI dbSNP database – "a central repository for both single base nucleotide substitutions and short deletion and insertion polymorphisms"
  • HGMD – the Human Gene Mutation Database, includes rare mutations and functional SNPs
  • GWAS Central – a central database of summary-level genetic association findings
  • 1000 Genomes Project – A Deep Catalog of Human Genetic Variation
  • WatCut 2007-06-18 at the Wayback Machine – an online tool for the design of SNP-RFLP assays
  • SNPStats 2008-10-13 at the Wayback Machine – SNPStats, a web tool for analysis of genetic association studies
  • Restriction HomePage – a set of tools for DNA restriction and SNP detection, including design of mutagenic primers
  • PharmGKB – The Pharmacogenetics and Pharmacogenomics Knowledge Base, a resource for SNPs associated with drug response and disease outcomes.
  • GEN-SNiP 2010-01-19 at the Wayback Machine – Online tool that identifies polymorphisms in test DNA sequences.
  • Rules for Nomenclature of Genes, Genetic Markers, Alleles, and Mutations in Mouse and Rat
  • SNP effect predictor with galaxy integration
  • Open SNP – a portal for sharing own SNP test results
  • dbSAP 2016-12-20 at the Wayback Machine – SNP database for protein variation detection

September 30, 2023
single, nucleotide, polymorphism, snps, redirects, here, singular, disambiguation, genetics, bioinformatics, single, nucleotide, polymorphism, plural, snps, germline, substitution, single, nucleotide, specific, position, genome, that, present, sufficiently, la. SNPs redirects here For the singular see SNP disambiguation In genetics and bioinformatics a single nucleotide polymorphism SNP s n ɪ p plural SNPs s n ɪ p s is a germline substitution of a single nucleotide at a specific position in the genome that is present in a sufficiently large fraction of considered population generally regarded as 1 or more 1 2 The upper DNA molecule differs from the lower DNA molecule at a single base pair location a G A polymorphism For example a G nucleotide present at a specific location in a reference genome may be replaced by an A in a minority of individuals The two possible nucleotide variations of this SNP G or A are called alleles 3 SNPs can help explain differences in susceptibility to a wide range of diseases across a population For example a common SNP in the CFH gene is associated with increased risk of age related macular degeneration 4 Differences in the severity of an illness or response to treatments may also be manifestations of genetic variations caused by SNPs For example two common SNPs in the APOE gene rs429358 and rs7412 lead to three major APO E alleles with different associated risks for development of Alzheimer s disease and age at onset of the disease 5 Single nucleotide substitutions with an allele frequency of less than 1 are sometimes called single nucleotide variants SNVs 6 Variant may also be used as a general term for any single nucleotide change in a DNA sequence 2 encompassing both common SNPs and rare mutations whether germline or somatic 7 8 The term SNV has therefore been used to refer to point mutations found in cancer cells 9 DNA variants must also commonly be taken into consideration in molecular diagnostics applications such as designing PCR primers to detect viruses in which the viral RNA or DNA sample may contain SNVs citation needed However this nomenclature uses arbitrary distinctions such as an allele frequency of 1 and is not used consistently across all fields the resulting disagreement has prompted calls for a more consistent framework for naming differences in DNA sequences between two samples 10 11 Contents 1 Types 2 Frequency 2 1 Within a genome 2 2 Within a population 3 Applications 3 1 Importance 3 2 Clinical research 3 2 1 Genome wide association study GWAS 3 2 2 Candidate gene association study 3 2 3 Homozygosity mapping in disease 3 2 4 Methylation patterns 3 3 Forensic sciences 3 4 Pharmacogenetics 3 5 Disease 4 Examples 5 Databases 6 Nomenclature 7 SNP analysis 8 Programs for prediction of SNP effects 9 See also 10 References 11 Further reading 12 External linksTypes Edit nbsp Types of single nucleotide polymorphism SNPs Single nucleotide polymorphisms may fall within coding sequences of genes non coding regions of genes or in the intergenic regions regions between genes SNPs within a coding sequence do not necessarily change the amino acid sequence of the protein that is produced due to degeneracy of the genetic code 12 SNPs in the coding region are of two types synonymous SNPs and nonsynonymous SNPs Synonymous SNPs do not affect the protein sequence while nonsynonymous SNPs change the amino acid sequence of protein 13 SNPs in non coding regions can manifest in a higher risk of cancer 14 and may affect mRNA structure and disease susceptibility 15 Non coding SNPs can also alter the level of expression of a gene as an eQTL expression quantitative trait locus SNPs in coding regions synonymous substitutions by definition do not result in a change of amino acid in the protein but still can affect its function in other ways An example would be a seemingly silent mutation in the multidrug resistance gene 1 MDR1 which codes for a cellular membrane pump that expels drugs from the cell can slow down translation and allow the peptide chain to fold into an unusual conformation causing the mutant pump to be less functional in MDR1 protein e g C1236T polymorphism changes a GGC codon to GGT at amino acid position 412 of the polypeptide both encode glycine and the C3435T polymorphism changes ATC to ATT at position 1145 both encode isoleucine 16 nonsynonymous substitutions missense single change in the base results in change in amino acid of protein and its malfunction which leads to disease e g c 1580G gt T SNP in LMNA gene position 1580 nt in the DNA sequence CGT codon causing the guanine to be replaced with the thymine yielding CTT codon in the DNA sequence results at the protein level in the replacement of the arginine by the leucine in the position 527 17 at the phenotype level this manifests in overlapping mandibuloacral dysplasia and progeria syndrome nonsense point mutation in a sequence of DNA that results in a premature stop codon or a nonsense codon in the transcribed mRNA and in a truncated incomplete and usually nonfunctional protein product e g Cystic fibrosis caused by the G542X mutation in the cystic fibrosis transmembrane conductance regulator gene 18 SNPs that are not in protein coding regions may still affect gene splicing transcription factor binding messenger RNA degradation or the sequence of noncoding RNA Gene expression affected by this type of SNP is referred to as an eSNP expression SNP and may be upstream or downstream from the gene Frequency EditMore than 600 million SNPs have been identified across the human genome in the world s population 19 A typical genome differs from the reference human genome at 4 to 5 million sites most of which more than 99 9 consist of SNPs and short indels 20 Within a genome Edit The genomic distribution of SNPs is not homogenous SNPs occur in non coding regions more frequently than in coding regions or in general where natural selection is acting and fixing the allele eliminating other variants of the SNP that constitutes the most favorable genetic adaptation 21 Other factors like genetic recombination and mutation rate can also determine SNP density 22 SNP density can be predicted by the presence of microsatellites AT microsatellites in particular are potent predictors of SNP density with long AT n repeat tracts tending to be found in regions of significantly reduced SNP density and low GC content 23 Within a population Edit There are variations between human populations so a SNP allele that is common in one geographical or ethnic group may be much rarer in another However this pattern of variation is relatively rare in a global sample of 67 3 million SNPs the Human Genome Diversity Project found no such private variants that are fixed in a given continent or major region The highest frequencies are reached by a few tens of variants present at gt 70 and a few thousands at gt 50 in Africa the Americas and Oceania By contrast the highest frequency variants private to Europe East Asia the Middle East or Central and South Asia reach just 10 to 30 24 Within a population SNPs can be assigned a minor allele frequency the lowest allele frequency at a locus that is observed in a particular population 25 This is simply the lesser of the two allele frequencies for single nucleotide polymorphisms With this knowledge scientists have developed new methods in analyzing population structures in less studied species 26 27 28 By using pooling techniques the cost of the analysis is significantly lowered citation needed These techniques are based on sequencing a population in a pooled sample instead of sequencing every individual within the population by itself With new bioinformatics tools there is a possibility of investigating population structure gene flow and gene migration by observing the allele frequencies within the entire population With these protocols there is a possibility in combining the advantages of SNPs with micro satellite markers 29 30 However there are information lost in the process such as linkage disequilibrium and zygosity information Applications EditThis section is in list format but may read better as prose You can help by converting this section if appropriate Editing help is available May 2023 Association studies can determine whether a genetic variant is associated with a disease or trait 31 A tag SNP is a representative single nucleotide polymorphism in a region of the genome with high linkage disequilibrium the non random association of alleles at two or more loci Tag SNPs are useful in whole genome SNP association studies in which hundreds of thousands of SNPs across the entire genome are genotyped Haplotype mapping sets of alleles or DNA sequences can be clustered so that a single SNP can identify many linked SNPs Linkage disequilibrium LD a term used in population genetics indicates non random association of alleles at two or more loci not necessarily on the same chromosome It refers to the phenomenon that SNP allele or DNA sequence that are close together in the genome tend to be inherited together LD can be affected by two parameters among other factors such as population stratification 1 The distance between the SNPs the larger the distance the lower the LD 2 Recombination rate the lower the recombination rate the higher the LD 32 In genetic epidemiology SNPs are used to estimate transmission clusters 33 Importance Edit Variations in the DNA sequences of humans can affect how humans develop diseases and respond to pathogens chemicals drugs vaccines and other agents SNPs are also critical for personalized medicine 34 Examples include biomedical research forensics pharmacogenetics and disease causation as outlined below Clinical research Edit Genome wide association study GWAS Edit One of main contributions of SNPs in clinical research is genome wide association study GWAS 35 Genome wide genetic data can be generated by multiple technologies including SNP array and whole genome sequencing GWAS has been commonly used in identifying SNPs associated with diseases or clinical phenotypes or traits Since GWAS is a genome wide assessment a large sample site is required to obtain sufficient statistical power to detect all possible associations Some SNPs have relatively small effect on diseases or clinical phenotypes or traits To estimate study power the genetic model for disease needs to be considered such as dominant recessive or additive effects Due to genetic heterogeneity GWAS analysis must be adjusted for race Candidate gene association study Edit Candidate gene association study is commonly used in genetic study before the invention of high throughput genotyping or sequencing technologies 36 Candidate gene association study is to investigate limited number of pre specified SNPs for association with diseases or clinical phenotypes or traits So this is a hypothesis driven approach Since only a limited number of SNPs are tested a relatively small sample size is sufficient to detect the association Candidate gene association approach is also commonly used to confirm findings from GWAS in independent samples Homozygosity mapping in disease Edit Genome wide SNP data can be used for homozygosity mapping 37 Homozygosity mapping is a method used to identify homozygous autosomal recessive loci which can be a powerful tool to map genomic regions or genes that are involved in disease pathogenesis Methylation patterns Edit nbsp Associations between SNPs methylation patterns and gene expression of biological traitsRecently preliminary results reported SNPs as important components of the epigenetic program in organisms 38 39 Moreover cosmopolitan studies in European and South Asiatic populations have revealed the influence of SNPs in the methylation of specific CpG sites 40 In addition meQTL enrichment analysis using GWAS database demonstrated that those associations are important toward the prediction of biological traits 40 41 42 Forensic sciences Edit SNPs have historically been used to match a forensic DNA sample to a suspect but has been made obsolete due to advancing STR based DNA fingerprinting techniques However the development of next generation sequencing NGS technology may allow for more opportunities for the use of SNPs in phenotypic clues such as ethnicity hair color and eye color with a good probability of a match This can additionally be applied to increase the accuracy of facial reconstructions by providing information that may otherwise be unknown and this information can be used to help identify suspects even without a STR DNA profile match Some cons to using SNPs versus STRs is that SNPs yield less information than STRs and therefore more SNPs are needed for analysis before a profile of a suspect is able to be created Additionally SNPs heavily rely on the presence of a database for comparative analysis of samples However in instances with degraded or small volume samples SNP techniques are an excellent alternative to STR methods SNPs as opposed to STRs have an abundance of potential markers can be fully automated and a possible reduction of required fragment length to less than 100bp 26 Pharmacogenetics Edit Pharmacogenetics focuses on identifying genetic variations including SNPs associated with differential responses to treatment 43 Many drug metabolizing enzymes drug targets or target pathways can be influenced by SNPs The SNPs involved in drug metabolizing enzyme activities can change drug pharmacokinetics while the SNPs involved in drug target or its pathway can change drug pharmacodynamics Therefore SNPs are potential genetic markers that can be used to predict drug exposure or effectiveness of the treatment Genome wide pharmacogenetic study is called pharmacogenomics Pharmacogenetics and pharmacogenomics are important in the development of precision medicine especially for life threatening diseases such as cancers Disease Edit Only small amount of SNPs in the human genome may have impact on human diseases Large scale GWAS has been done for the most important human diseases including heart diseases metabolic diseases autoimmune diseases and neurodegenerative and psychiatric disorders 35 Most of the SNPs with relatively large effects on these diseases have been identified These findings have significantly improved understanding of disease pathogenesis and molecular pathways and facilitated development of better treatment Further GWAS with larger samples size will reveal the SNPs with relatively small effect on diseases For common and complex diseases such as type 2 diabetes rheumatoid arthritis and Alzheimer s disease multiple genetic factors are involved in disease etiology In addition gene gene interaction and gene environment interaction also play an important role in disease initiation and progression 44 Examples Editrs6311 and rs6313 are SNPs in the Serotonin 5 HT2A receptor gene on human chromosome 13 45 The SNP 3279C A rs3761548 is amongst the SNPs locating in the promoter region of the Foxp3 gene might be involved in cancer progression 46 A SNP in the F5 gene causes Factor V Leiden thrombophilia 47 rs3091244 is an example of a triallelic SNP in the CRP gene on human chromosome 1 48 TAS2R38 codes for PTC tasting ability and contains 6 annotated SNPs 49 rs148649884 and rs138055828 in the FCN1 gene encoding M ficolin crippled the ligand binding capability of the recombinant M ficolin 50 An intronic SNP in DNA mismatch repair gene PMS2 rs1059060 Ser775Asn is associated with increased sperm DNA damage and risk of male infertility 51 Databases EditAs there are for genes bioinformatics databases exist for SNPs dbSNP is a SNP database from the National Center for Biotechnology Information NCBI As of June 8 2015 update dbSNP listed 149 735 377 SNPs in humans 52 53 Kaviar 54 is a compendium of SNPs from multiple data sources including dbSNP SNPedia is a wiki style database supporting personal genome annotation interpretation and analysis The OMIM database describes the association between polymorphisms and diseases e g gives diseases in text form dbSAP single amino acid polymorphism database for protein variation detection 55 The Human Gene Mutation Database provides gene mutations causing or associated with human inherited diseases and functional SNPs The International HapMap Project where researchers are identifying Tag SNPs to be able to determine the collection of haplotypes present in each subject GWAS Central allows users to visually interrogate the actual summary level association data in one or more genome wide association studies The International SNP Map working group mapped the sequence flanking each SNP by alignment to the genomic sequence of large insert clones in Genebank These alignments were converted to chromosomal coordinates that is shown in Table 1 56 This list has greatly increased since with for instance the Kaviar database now listing 162 million single nucleotide variants SNVs Chromosome Length bp All SNPs TSC SNPsTotal SNPs kb per SNP Total SNPs kb per SNP1 214 066 000 129 931 1 65 75 166 2 852 222 889 000 103 664 2 15 76 985 2 903 186 938 000 93 140 2 01 63 669 2 944 169 035 000 84 426 2 00 65 719 2 575 170 954 000 117 882 1 45 63 545 2 696 165 022 000 96 317 1 71 53 797 3 077 149 414 000 71 752 2 08 42 327 3 538 125 148 000 57 834 2 16 42 653 2 939 107 440 000 62 013 1 73 43 020 2 5010 127 894 000 61 298 2 09 42 466 3 0111 129 193 000 84 663 1 53 47 621 2 7112 125 198 000 59 245 2 11 38 136 3 2813 93 711 000 53 093 1 77 35 745 2 6214 89 344 000 44 112 2 03 29 746 3 0015 73 467 000 37 814 1 94 26 524 2 7716 74 037 000 38 735 1 91 23 328 3 1717 73 367 000 34 621 2 12 19 396 3 7818 73 078 000 45 135 1 62 27 028 2 7019 56 044 000 25 676 2 18 11 185 5 0120 63 317 000 29 478 2 15 17 051 3 7121 33 824 000 20 916 1 62 9 103 3 7222 33 786 000 28 410 1 19 11 056 3 06X 131 245 000 34 842 3 77 20 400 6 43Y 21 753 000 4 193 5 19 1 784 12 19RefSeq 15 696 674 14 534 1 08Totals 2 710 164 000 1 419 190 1 91 887 450 3 05Nomenclature EditThe nomenclature for SNPs include several variations for an individual SNP while lacking a common consensus The rs standard is that which has been adopted by dbSNP and uses the prefix rs for reference SNP followed by a unique and arbitrary number 57 SNPs are frequently referred to by their dbSNP rs number as in the examples above The Human Genome Variation Society HGVS uses a standard which conveys more information about the SNP Examples are c 76A gt T c for coding region followed by a number for the position of the nucleotide followed by a one letter abbreviation for the nucleotide A C G T or U followed by a greater than sign gt to indicate substitution followed by the abbreviation of the nucleotide which replaces the former 58 59 60 p Ser123Arg p for protein followed by a three letter abbreviation for the amino acid followed by a number for the position of the amino acid followed by the abbreviation of the amino acid which replaces the former 61 SNP analysis EditSNPs can be easily assayed due to only containing two possible alleles and three possible genotypes involving the two alleles homozygous A homozygous B and heterozygous AB leading to many possible techniques for analysis Some include DNA sequencing capillary electrophoresis mass spectrometry single strand conformation polymorphism SSCP single base extension electrochemical analysis denaturating HPLC and gel electrophoresis restriction fragment length polymorphism and hybridization analysis Programs for prediction of SNP effects EditAn important group of SNPs are those that corresponds to missense mutations causing amino acid change on protein level Point mutation of particular residue can have different effect on protein function from no effect to complete disruption its function Usually change in amino acids with similar size and physico chemical properties e g substitution from leucine to valine has mild effect and opposite Similarly if SNP disrupts secondary structure elements e g substitution to proline in alpha helix region such mutation usually may affect whole protein structure and function Using those simple and many other machine learning derived rules a group of programs for the prediction of SNP effect was developed 62 SIFT This program provides insight into how a laboratory induced missense or nonsynonymous mutation will affect protein function based on physical properties of the amino acid and sequence homology LIST 63 64 Local Identity and Shared Taxa estimates the potential deleteriousness of mutations resulted from altering their protein functions It is based on the assumption that variations observed in closely related species are more significant when assessing conservation compared to those in distantly related species SNAP2 SuSPect PolyPhen 2 PredictSNP MutationTaster official website Variant Effect Predictor from the Ensembl project SNPViz Archived 2020 08 07 at the Wayback Machine 65 This program provides a 3D representation of the protein affected highlighting the amino acid change so doctors can determine pathogenicity of the mutant protein PROVEAN PhyreRisk is a database which maps variants to experimental and predicted protein structures 66 Missense3D is a tool which provides a stereochemical report on the effect of missense variants on protein structure 67 See also EditAffymetrix HapMap Illumina International HapMap Project Short tandem repeat STR Single base extension SNP array SNP genotyping SNPedia Snpstr SNV calling from NGS data Suspension array technology Tag SNP TaqMan VariomeReferences Edit Keats Bronya J B Sherman Stephanie L 2013 Population Genetics Emery and Rimoin s Principles and Practice of Medical Genetics Elsevier pp 1 12 doi 10 1016 b978 0 12 383834 6 00015 x ISBN 978 0 12 383834 6 retrieved 2023 05 02 a b Wright Alan F September 23 2005 Genetic Variation Polymorphisms and Mutations eLS Wiley doi 10 1038 npg els 0005005 ISBN 9780470016176 S2CID 82415195 Monga Isha Qureshi Abid Thakur Nishant Gupta Amit Kumar Kumar Manoj September 2017 ASPsiRNA A Resource of ASP siRNAs Having Therapeutic Potential for Human Genetic Disorders and Algorithm for Prediction of Their Inhibitory Efficacy G3 7 9 2931 2943 doi 10 1534 g3 117 044024 PMC 5592921 PMID 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Human Genetic Variants Journal of Molecular Biology 431 13 2460 2466 doi 10 1016 j jmb 2019 04 043 PMC 6597944 PMID 31075275 Ittisoponpisan S Islam SA Khanna T Alhuzimi E David A Sternberg MJ May 2019 Can Predicted Protein 3D Structures Provide Reliable Insights into whether Missense Variants Are Disease Associated Journal of Molecular Biology 431 11 2197 2212 doi 10 1016 j jmb 2019 04 009 PMC 6544567 PMID 30995449 Further reading Edit Glossary Nature Reviews Human Genome Project Information SNP Fact SheetExternal links Edit nbsp Wikimedia Commons has media related to Single nucleotide polymorphism NCBI resources Archived 2013 09 02 at the Wayback Machine Introduction to SNPs from NCBI The SNP Consortium LTD SNP search NCBI dbSNP database a central repository for both single base nucleotide substitutions and short deletion and insertion polymorphisms HGMD the Human Gene Mutation Database includes rare mutations and functional SNPs GWAS Central a central database of summary level genetic association findings 1000 Genomes Project A Deep Catalog of Human Genetic Variation WatCut Archived 2007 06 18 at the Wayback Machine an online tool for the design of SNP RFLP assays SNPStats Archived 2008 10 13 at the Wayback Machine SNPStats a web tool for analysis of genetic association studies Restriction HomePage a set of tools for DNA restriction and SNP detection including design of mutagenic primers American Association for Cancer Research Cancer Concepts Factsheet on SNPs PharmGKB The Pharmacogenetics and Pharmacogenomics Knowledge Base a resource for SNPs associated with drug response and disease outcomes GEN SNiP Archived 2010 01 19 at the Wayback Machine Online tool that identifies polymorphisms in test DNA sequences Rules for Nomenclature of Genes Genetic Markers Alleles and Mutations in Mouse and Rat HGNC Guidelines for Human Gene Nomenclature SNP effect predictor with galaxy integration Open SNP a portal for sharing own SNP test results dbSAP Archived 2016 12 20 at the Wayback Machine SNP database for protein variation detection Retrieved from https en wikipedia org w index php title Single nucleotide polymorphism amp oldid 1172116506, wikipedia, wiki, book, books, library,

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