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Microsatellite

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A microsatellite is a tract of repetitive DNA in which certain DNA motifs (ranging in length from one to six or more base pairs) are repeated, typically 5–50 times.<ref name="Richard 2008"/><ref>Template:Cite journal</ref> Microsatellites occur at thousands of locations within an organism's genome. They have a higher mutation rate than other areas of DNA<ref name="Brinkmann-1998"/> leading to high genetic diversity. Microsatellites are often referred to as short tandem repeats (STRs) by forensic geneticists and in genetic genealogy, or as simple sequence repeats (SSRs) by plant geneticists.<ref>Template:MeshName</ref>

Microsatellites and their longer cousins, the minisatellites, together are classified as VNTR (variable number of tandem repeats) DNA. The name "satellite" DNA refers to the early observation that centrifugation of genomic DNA in a test tube separates a prominent layer of bulk DNA from accompanying "satellite" layers of repetitive DNA.<ref name="Kit1">Template:Cite journal</ref>

They are widely used for DNA profiling in cancer diagnosis, in kinship analysis (especially paternity testing) and in forensic identification. They are also used in genetic linkage analysis to locate a gene or a mutation responsible for a given trait or disease. Microsatellites are also used in population genetics to measure levels of relatedness between subspecies, groups and individuals.

HistoryEdit

Although the first microsatellite was characterised in 1984 at the University of Leicester by Weller, Jeffreys and colleagues as a polymorphic GGAT repeat in the human myoglobin gene, the term "microsatellite" was introduced later, in 1989, by Litt and Luty.<ref name="Richard 2008"/> The name "satellite" DNA refers to the early observation that centrifugation of genomic DNA in a test tube separates a prominent layer of bulk DNA from accompanying "satellite" layers of repetitive DNA.<ref name="Kit1"/> The increasing availability of DNA amplification by PCR at the beginning of the 1990s triggered a large number of studies using the amplification of microsatellites as genetic markers for forensic medicine, for paternity testing, and for positional cloning to find the gene underlying a trait or disease. Prominent early applications include the identifications by microsatellite genotyping of the eight-year-old skeletal remains of a British murder victim (Hagelberg et al. 1991), and of the Auschwitz concentration camp doctor Josef Mengele who escaped to South America following World War II (Jeffreys et al. 1992).<ref name="Richard 2008"/>

Structures, locations, and functionsEdit

A microsatellite is a tract of tandemly repeated (i.e. adjacent) DNA motifs that range in length from one to six or up to ten nucleotides (the exact definition and delineation to the longer minisatellites varies from author to author),<ref name="Richard 2008"/><ref name="Gulcher2012"/> and are typically repeated 5–50 times. For example, the sequence TATATATATA is a dinucleotide microsatellite, and GTCGTCGTCGTCGTC is a trinucleotide microsatellite (with A being Adenine, G Guanine, C Cytosine, and T Thymine). Repeat units of four and five nucleotides are referred to as tetra- and pentanucleotide motifs, respectively. Most eukaryotes have microsatellites, with the notable exception of some yeast species. Microsatellites are distributed throughout the genome.<ref name="King 1997">Template:Cite journal</ref><ref name="Richard 2008">Template:Cite journal</ref><ref>Template:Cite journal</ref> The human genome for example contains 50,000–100,000 dinucleotide microsatellites, and lesser numbers of tri-, tetra- and pentanucleotide microsatellites.<ref name="Turnpenny 2005">Template:Cite book</ref> Many are located in non-coding parts of the human genome and therefore do not produce proteins, but they can also be located in regulatory regions and coding regions.

Microsatellites in non-coding regions may not have any specific function, and therefore might not be selected against; this allows them to accumulate mutations unhindered over the generations and gives rise to variability that can be used for DNA fingerprinting and identification purposes. Other microsatellites are located in regulatory flanking or intronic regions of genes, or directly in codons of genes – microsatellite mutations in such cases can lead to phenotypic changes and diseases, notably in triplet expansion diseases such as fragile X syndrome and Huntington's disease.<ref name="Pearson 2005"/>

Telomeres are linear sequences of DNA that sit at the very ends of chromosomes and protect the integrity of genomic material (not unlike an aglet on the end of a shoelace) during successive rounds of cell division due to the "end replication problem".<ref name="Gulcher2012" /> In white blood cells, the gradual shortening of telomeric DNA has been shown to inversely correlate with ageing in several sample types.<ref>Template:Cite journal</ref> Telomeres consist of repetitive DNA, with the hexanucleotide repeat motif TTAGGG in vertebrates.Template:Citation needed They are thus classified as minisatellites. Similarly, insects have shorter repeat motifs in their telomeres that could arguably be considered microsatellites.Template:Citation needed

Mutation mechanisms and mutation ratesEdit

File:STR-Slippage Dr.Peter Forster.jpg
DNA strand slippage during replication of an STR locus. Boxes symbolize repetitive DNA units. Arrows indicate the direction in which a new DNA strand (white boxes) is being replicated from the template strand (black boxes). Three situations during DNA replication are depicted. (a) Replication of the STR locus has proceeded without a mutation. (b) Replication of the STR locus has led to a gain of one unit owing to a loop in the new strand; the aberrant loop is stabilized by flanking units complementary to the opposite strand. (c) Replication of the STR locus has led to a loss of one unit owing to a loop in the template strand. (Forster et al. 2015)

Unlike point mutations, which affect only a single nucleotide, microsatellite mutations lead to the gain or loss of an entire repeat unit, and sometimes two or more repeats simultaneously. Thus, the mutation rate at microsatellite loci is expected to differ from other mutation rates, such as base substitution rates.<ref>Template:Cite journal</ref><ref name="Andreasson">Template:Cite journal</ref> The mutation rate at microsatellite loci depends on the repeat motif sequence, the number of repeated motif units and the purity of the canonical repeated sequence.<ref name="Molecular basis of genetic instabil">Template:Cite journal</ref> A variety of mechanisms for mutation of microsatellite loci have been reviewed,<ref name="Molecular basis of genetic instabil"/><ref>Template:Cite journal</ref> and their resulting polymorphic nature has been quantified.<ref name="Biological effects">Template:Cite journal</ref> The actual cause of mutations in microsatellites is debated.

One proposed cause of such length changes is replication slippage, caused by mismatches between DNA strands while being replicated during meiosis.<ref name="Tautz 1994">Template:Cite journal</ref> DNA polymerase, the enzyme responsible for reading DNA during replication, can slip while moving along the template strand and continue at the wrong nucleotide. DNA polymerase slippage is more likely to occur when a repetitive sequence (such as CGCGCG) is replicated. Because microsatellites consist of such repetitive sequences, DNA polymerase may make errors at a higher rate in these sequence regions. Several studies have found evidence that slippage is the cause of microsatellite mutations.<ref name="Klintschar 2004">Template:Cite journal</ref><ref name="Forster 2015">Template:Cite journal</ref> Typically, slippage in each microsatellite occurs about once per 1,000 generations.<ref name="Weber 1993">Template:Cite journal</ref> Thus, slippage changes in repetitive DNA are three orders of magnitude more common than point mutations in other parts of the genome.<ref name="Jarne 1996">Template:Cite journal</ref> Most slippage results in a change of just one repeat unit, and slippage rates vary for different allele lengths and repeat unit sizes,<ref name="Brinkmann-1998">Template:Cite journal</ref> and within different species.<ref name="Kruglyak 1998">Template:Cite journal</ref><ref>Template:Cite journal</ref><ref name="Mutation mechanisms and rates">Template:Cite journal</ref> If there is a large size difference between individual alleles, then there may be increased instability during recombination at meiosis.<ref name="Jarne 1996"/>

Another possible cause of microsatellite mutations are point mutations, where only one nucleotide is incorrectly copied during replication. A study comparing human and primate genomes found that most changes in repeat number in short microsatellites appear due to point mutations rather than slippage.<ref name="Amos-2010">Template:Cite journal</ref>

Microsatellite mutation ratesEdit

Direct estimates of microsatellite mutation rates have been made in numerous organisms, from insects to humans. In the desert locust Schistocerca gregaria, the microsatellite mutation rate was estimated at 2.1 × 10−4 per generation per locus.<ref name="Chapuis-2015">Template:Cite journal</ref> The microsatellite mutation rate in human male germ lines is five to six times higher than in female germ lines and ranges from 0 to 7 × 10−3 per locus per gamete per generation.<ref name="Brinkmann-1998"/> In the nematode Pristionchus pacificus, the estimated microsatellite mutation rate ranges from 8.9 × 10−5 to 7.5 × 10−4 per locus per generation.<ref name="Molnar-2012">Template:Cite journal</ref>

Microsatellite mutation rates vary with base position relative to the microsatellite, repeat type, and base identity.<ref name="Amos-2010"/> Mutation rate rises specifically with repeat number, peaking around six to eight repeats and then decreasing again.<ref name="Amos-2010"/> Increased heterozygosity in a population will also increase microsatellite mutation rates,<ref name="Amos-2016">Template:Cite journal</ref> especially when there is a large length difference between alleles. This is likely due to homologous chromosomes with arms of unequal lengths causing instability during meiosis.<ref name="Amos-Rubinsztein-1996">Template:Cite journal</ref>

Biological effects of microsatellite mutationsEdit

Many microsatellites are located in non-coding DNA and are biologically silent. Others are located in regulatory or even coding DNA – microsatellite mutations in such cases can lead to phenotypic changes and diseases. A genome-wide study estimates that microsatellite variation contributes 10–15% of heritable gene expression variation in humans.<ref name="Gymrek 22–29">Template:Cite journal</ref><ref name="Biological effects"/>

Effects on proteinsEdit

In mammals, 20–40% of proteins contain repeating sequences of amino acids encoded by short sequence repeats.<ref name="Marcotte 1998">Template:Cite journal</ref> Most of the short sequence repeats within protein-coding portions of the genome have a repeating unit of three nucleotides, since that length will not cause frame-shifts when mutating.<ref name="Sutherland 1995">Template:Cite journal</ref> Each trinucleotide repeating sequence is transcribed into a repeating series of the same amino acid. In yeasts, the most common repeated amino acids are glutamine, glutamic acid, asparagine, aspartic acid and serine.

Mutations in these repeating segments can affect the physical and chemical properties of proteins, with the potential for producing gradual and predictable changes in protein action.<ref name="Hancock 2005">Template:Cite journal</ref> For example, length changes in tandemly repeating regions in the Runx2 gene lead to differences in facial length in domesticated dogs (Canis familiaris), with an association between longer sequence lengths and longer faces.<ref name="Fondon 2004">Template:Cite journal</ref> This association also applies to a wider range of Carnivora species.<ref name="Sears 2007">Template:Cite journal</ref> Length changes in polyalanine tracts within the HOXA13 gene are linked to hand-foot-genital syndrome, a developmental disorder in humans.<ref name="Utsch 2002">Template:Cite journal</ref> Length changes in other triplet repeats are linked to more than 40 neurological diseases in humans, notably trinucleotide repeat disorders such as fragile X syndrome and Huntington's disease.<ref name="Pearson 2005">Template:Cite journal</ref> Evolutionary changes from replication slippage also occur in simpler organisms. For example, microsatellite length changes are common within surface membrane proteins in yeast, providing rapid evolution in cell properties.<ref name="Bowen 2006">Template:Cite journal</ref> Specifically, length changes in the FLO1 gene control the level of adhesion to substrates.<ref name="Verstrepen 2005">Template:Cite journal</ref> Short sequence repeats also provide rapid evolutionary change to surface proteins in pathenogenic bacteria; this may allow them to keep up with immunological changes in their hosts.<ref name="Moxon 1994">Template:Cite journal</ref> Length changes in short sequence repeats in a fungus (Neurospora crassa) control the duration of its circadian clock cycles.<ref name="Michael 2007">Template:Cite journal</ref>

Effects on gene regulationEdit

Length changes of microsatellites within promoters and other cis-regulatory regions can change gene expression quickly, between generations. The human genome contains many (>16,000) short sequence repeats in regulatory regions, which provide 'tuning knobs' on the expression of many genes.<ref name="Gymrek 22–29"/><ref name="Rockman 2002">Template:Cite journal</ref>

Length changes in bacterial SSRs can affect fimbriae formation in Haemophilus influenzae, by altering promoter spacing.<ref name="Moxon 1994" /> Dinucleotide microsatellites are linked to abundant variation in cis-regulatory control regions in the human genome.<ref name="Rockman 2002" /> Microsatellites in control regions of the Vasopressin 1a receptor gene in voles influence their social behavior, and level of monogamy.<ref name="Hammock 2005">Template:Cite journal</ref>

In Ewing sarcoma (a type of painful bone cancer in young humans), a point mutation has created an extended GGAA microsatellite which binds a transcription factor, which in turn activates the EGR2 gene which drives the cancer.<ref>Template:Cite journal</ref> In addition, other GGAA microsatellites may influence the expression of genes that contribute to the clinical outcome of Ewing sarcoma patients.<ref>Template:Cite journal</ref>

Effects within intronsEdit

Microsatellites within introns also influence phenotype, through means that are not currently understood. For example, a GAA triplet expansion in the first intron of the X25 gene appears to interfere with transcription, and causes Friedreich's ataxia.<ref name="Bidichandani 1998">Template:Cite journal</ref> Tandem repeats in the first intron of the Asparagine synthetase gene are linked to acute lymphoblastic leukaemia.<ref name="Akagi 2008">Template:Cite journal</ref> A repeat polymorphism in the fourth intron of the NOS3 gene is linked to hypertension in a Tunisian population.<ref name="Jemaa 2008">Template:Cite journal</ref> Reduced repeat lengths in the EGFR gene are linked with osteosarcomas.<ref name="Kersting 2008">Template:Cite journal</ref>

An archaic form of splicing preserved in zebrafish is known to use microsatellite sequences within intronic mRNA for the removal of introns in the absence of U2AF2 and other splicing machinery. It is theorized that these sequences form highly stable cloverleaf configurations that bring the 3' and 5' intron splice sites into close proximity, effectively replacing the spliceosome. This method of RNA splicing is believed to have diverged from human evolution at the formation of tetrapods and to represent an artifact of an RNA world.<ref>Template:Cite journal</ref>

Effects within transposonsEdit

Almost 50% of the human genome is contained in various types of transposable elements (also called transposons, or 'jumping genes'), and many of them contain repetitive DNA.<ref name="Sherer 2008">Template:Cite book</ref> It is probable that short sequence repeats in those locations are also involved in the regulation of gene expression.<ref name="Tomilin 2008">Template:Cite journal</ref>

ApplicationsEdit

Microsatellites are used for assessing chromosomal DNA deletions in cancer diagnosis. Microsatellites are widely used for DNA profiling, also known as "genetic fingerprinting", of crime stains (in forensics) and of tissues (in transplant patients). They are also widely used in kinship analysis (most commonly in paternity testing). Also, microsatellites are used for mapping locations within the genome, specifically in genetic linkage analysis to locate a gene or a mutation responsible for a given trait or disease. As a special case of mapping, they can be used for studies of gene duplication or deletion. Researchers use microsatellites in population genetics and in species conservation projects. Plant geneticists have proposed the use of microsatellites for marker assisted selection of desirable traits in plant breeding.

Cancer diagnosisEdit

In tumour cells, whose controls on replication are damaged, microsatellites may be gained or lost at an especially high frequency during each round of mitosis. Hence a tumour cell line might show a different genetic fingerprint from that of the host tissue, and, especially in colorectal cancer, might present with loss of heterozygosity.<ref name="Cancer Diagnostics">Template:Cite journal</ref><ref>Template:Cite journal</ref> Microsatellites analyzed in primary tissue therefore been routinely used in cancer diagnosis to assess tumour progression.<ref name="vanTilborg2012">Template:Cite journal</ref><ref name="Sideris&Papagrigoriadis2014">Template:Cite journal</ref><ref name="Boland1998">Template:Cite journal</ref> Genome Wide Association Studies (GWAS) have been used to identify microsatellite biomarkers as a source of genetic predisposition in a variety of cancers.<ref name="Rivero et al">Template:Cite journal</ref><ref name="Kinney">Template:Cite journal</ref><ref name="Velmurugan">Template:Cite journal</ref>

File:Str profile.jpg
A partial human STR profile obtained using the Applied Biosystems Identifiler kit

Forensic and medical fingerprintingEdit

Microsatellite analysis became popular in the field of forensics in the 1990s.<ref name=":0" /> It is used for the genetic fingerprinting of individuals where it permits forensic identification (typically matching a crime stain to a victim or perpetrator). It is also used to follow up bone marrow transplant patients.<ref name="pmid11669214">Template:Cite journal</ref>

The microsatellites in use today for forensic analysis are all tetra- or penta-nucleotide repeats, as these give a high degree of error-free data while being short enough to survive degradation in non-ideal conditions. Even shorter repeat sequences would tend to suffer from artifacts such as PCR stutter and preferential amplification, while longer repeat sequences would suffer more highly from environmental degradation and would amplify less well by PCR.<ref name="interpol">{{#invoke:citation/CS1|citation |CitationClass=web }}</ref> Another forensic consideration is that the person's medical privacy must be respected, so that forensic STRs are chosen which are non-coding, do not influence gene regulation, and are not usually trinucleotide STRs which could be involved in triplet expansion diseases such as Huntington's disease. Forensic STR profiles are stored in DNA databanks such as the UK National DNA Database (NDNAD), the American CODIS or the Australian NCIDD.

Kinship analysis (paternity testing)Edit

Autosomal microsatellites are widely used for DNA profiling in kinship analysis (most commonly in paternity testing).<ref>Template:Cite journal</ref> Paternally inherited Y-STRs (microsatellites on the Y chromosome) are often used in genealogical DNA testing.

Genetic linkage analysisEdit

During the 1990s and the first several years of this millennium, microsatellites were the workhorse genetic markers for genome-wide scans to locate any gene responsible for a given phenotype or disease, using segregation observations across generations of a sampled pedigree. Although the rise of higher throughput and cost-effective single-nucleotide polymorphism (SNP) platforms led to the era of the SNP for genome scans, microsatellites remain highly informative measures of genomic variation for linkage and association studies. Their continued advantage lies in their greater allelic diversity than biallelic SNPs, thus microsatellites can differentiate alleles within a SNP-defined linkage disequilibrium block of interest. Thus, microsatellites have successfully led to discoveries of type 2 diabetes (TCF7L2) and prostate cancer genes (the 8q21 region).<ref name="Gulcher2012">Template:Cite journal</ref><ref name="Ott2015">Template:Cite journal</ref>

Population geneticsEdit

File:Consensus neighbor-joining tree of the 249 human populations and six chimpanzee populations.svg
Consensus neighbor-joining tree of 249 human populations and six chimpanzee populations. Created based on 246 microsatellite markers.<ref name="PembertonDeGiorgio2013">Template:Cite journal</ref>

Microsatellites were popularized in population genetics during the 1990s because as PCR became ubiquitous in laboratories researchers were able to design primers and amplify sets of microsatellites at low cost. Their uses are wide-ranging.<ref>Template:Cite journal</ref> A microsatellite with a neutral evolutionary history makes it applicable for measuring or inferring bottlenecks,<ref>Template:Cite journal</ref> local adaptation,<ref>Template:Cite journal</ref> the allelic fixation index (FST),<ref>Template:Cite journal</ref> population size,<ref>Template:Cite journal</ref> and gene flow.<ref>Template:Cite journal</ref> As next generation sequencing becomes more affordable the use of microsatellites has decreased, however they remain a crucial tool in the field.<ref>Template:Cite journal</ref>

Plant breedingEdit

Marker assisted selection or marker aided selection (MAS) is an indirect selection process where a trait of interest is selected based on a marker (morphological, biochemical or DNA/RNA variation) linked to a trait of interest (e.g. productivity, disease resistance, stress tolerance, and quality), rather than on the trait itself. Microsatellites have been proposed to be used as such markers to assist plant breeding.<ref name="Miah2013">Template:Cite journal</ref>

AnalysisEdit

File:Short Tandem Repeat (STR) analysis.png
Short Tandem Repeat (STR) analysis on a simplified model using polymerase chain reaction (PCR): First, a DNA sample undergoes PCR with primers targeting certain STRs (which vary in lengths between individuals and their alleles). The resultant fragments are separated by size (such as electrophoresis).<ref>Image by Mikael Häggström, MD, using following source image: Figure 1 - available via license: Creative Commons Attribution 4.0 International", from the following article:
Template:Cite journal</ref>

Repetitive DNA is not easily analysed by next generation DNA sequencing methods, for some technologies struggle with homopolymeric tracts. A variety of software approaches have been created for the analysis or raw nextgen DNA sequencing reads to determine the genotype and variants at repetitive loci.<ref name="Analysis">Template:Cite journal</ref><ref name="Rajan-Babu">Template:Cite journal</ref> Microsatellites can be analysed and verified by established PCR amplification and amplicon size determination, sometimes followed by Sanger DNA sequencing.

In forensics, the analysis is performed by extracting nuclear DNA from the cells of a sample of interest, then amplifying specific polymorphic regions of the extracted DNA by means of the polymerase chain reaction. Once these sequences have been amplified, they are resolved either through gel electrophoresis or capillary electrophoresis, which will allow the analyst to determine how many repeats of the microsatellites sequence in question there are. If the DNA was resolved by gel electrophoresis, the DNA can be visualized either by silver staining (low sensitivity, safe, inexpensive), or an intercalating dye such as ethidium bromide (fairly sensitive, moderate health risks, inexpensive), or as most modern forensics labs use, fluorescent dyes (highly sensitive, safe, expensive).<ref name="nist">{{#invoke:citation/CS1|citation |CitationClass=web }}</ref> Instruments built to resolve microsatellite fragments by capillary electrophoresis also use fluorescent dyes.<ref name="nist"/> Forensic profiles are stored in major databanks. The British data base for microsatellite loci identification was originally based on the British SGM+ system<ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref><ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref> using 10 loci and a sex marker. The Americans<ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref> increased this number to 13 loci.<ref name="Butler 2005">Template:Cite book</ref> The Australian database is called the NCIDD, and since 2013 it has been using 18 core markers for DNA profiling.<ref name=":0">Template:Cite news</ref>

AmplificationEdit

Microsatellites can be amplified for identification by the polymerase chain reaction (PCR) process, using the unique sequences of flanking regions as primers. DNA is repeatedly denatured at a high temperature to separate the double strand, then cooled to allow annealing of primers and the extension of nucleotide sequences through the microsatellite. This process results in production of enough DNA to be visible on agarose or polyacrylamide gels; only small amounts of DNA are needed for amplification because in this way thermocycling creates an exponential increase in the replicated segment.<ref name="Griffiths">Template:Cite book</ref> With the abundance of PCR technology, primers that flank microsatellite loci are simple and quick to use, but the development of correctly functioning primers is often a tedious and costly process.

File:PAGE AgStain Microsat.jpg
A number of DNA samples from specimens of Littorina plena amplified using polymerase chain reaction with primers targeting a variable simple sequence repeat (SSR, a.k.a. microsatellite) locus. Samples were run on a 5% polyacrylamide gel and visualized using silver staining.

Design of microsatellite primersEdit

If searching for microsatellite markers in specific regions of a genome, for example within a particular intron, primers can be designed manually. This involves searching the genomic DNA sequence for microsatellite repeats, which can be done by eye or by using automated tools such as repeat masker. Once the potentially useful microsatellites are determined, the flanking sequences can be used to design oligonucleotide primers which will amplify the specific microsatellite repeat in a PCR reaction.

Random microsatellite primers can be developed by cloning random segments of DNA from the focal species. These random segments are inserted into a plasmid or bacteriophage vector, which is in turn implanted into Escherichia coli bacteria. Colonies are then developed, and screened with fluorescently–labelled oligonucleotide sequences that will hybridize to a microsatellite repeat, if present on the DNA segment. If positive clones can be obtained from this procedure, the DNA is sequenced and PCR primers are chosen from sequences flanking such regions to determine a specific locus. This process involves significant trial and error on the part of researchers, as microsatellite repeat sequences must be predicted and primers that are randomly isolated may not display significant polymorphism.<ref name="Jarne 1996" /><ref name="Queller">Template:Cite journal</ref> Microsatellite loci are widely distributed throughout the genome and can be isolated from semi-degraded DNA of older specimens, as all that is needed is a suitable substrate for amplification through PCR.

More recent techniques involve using oligonucleotide sequences consisting of repeats complementary to repeats in the microsatellite to "enrich" the DNA extracted (microsatellite enrichment). The oligonucleotide probe hybridizes with the repeat in the microsatellite, and the probe/microsatellite complex is then pulled out of solution. The enriched DNA is then cloned as normal, but the proportion of successes will now be much higher, drastically reducing the time required to develop the regions for use. However, which probes to use can be a trial and error process in itself.<ref name="Kaukinen">Template:Cite journal</ref>

ISSR-PCREdit

ISSR (for inter-simple sequence repeat) is a general term for a genome region between microsatellite loci. The complementary sequences to two neighboring microsatellites are used as PCR primers; the variable region between them gets amplified. The limited length of amplification cycles during PCR prevents excessive replication of overly long contiguous DNA sequences, so the result will be a mix of a variety of amplified DNA strands which are generally short but vary much in length.

Sequences amplified by ISSR-PCR can be used for DNA fingerprinting. Since an ISSR may be a conserved or nonconserved region, this technique is not useful for distinguishing individuals, but rather for phylogeography analyses or maybe delimiting species; sequence diversity is lower than in SSR-PCR, but still higher than in actual gene sequences. In addition, microsatellite sequencing and ISSR sequencing are mutually assisting, as one produces primers for the other.

LimitationsEdit

Repetitive DNA is not easily analysed by next generation DNA sequencing methods, which struggle with homopolymeric tracts.<ref>Template:Cite journal</ref> Therefore, microsatellites are normally analysed by conventional PCR amplification and amplicon size determination. The use of PCR means that microsatellite length analysis is prone to PCR limitations like any other PCR-amplified DNA locus. A particular concern is the occurrence of 'null alleles':

  • Occasionally, within a sample of individuals such as in paternity testing casework, a mutation in the DNA flanking the microsatellite can prevent the PCR primer from binding and producing an amplicon (creating a "null allele" in a gel assay), thus only one allele is amplified (from the non-mutated sister chromosome), and the individual may then falsely appear to be homozygous. This can cause confusion in paternity casework. It may then be necessary to amplify the microsatellite using a different set of primers.<ref name="Jarne 1996"/><ref name="Dakin">Template:Cite journal</ref> Null alleles are caused especially by mutations at the 3' section, where extension commences.
  • In species or population analysis, for example in conservation work, PCR primers which amplify microsatellites in one individual or species can work in other species. However, the risk of applying PCR primers across different species is that null alleles become likely, whenever sequence divergence is too great for the primers to bind. The species may then artificially appear to have a reduced diversity. Null alleles in this case can sometimes be indicated by an excessive frequency of homozygotes causing deviations from Hardy-Weinberg equilibrium expectations.

See alsoEdit

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ReferencesEdit

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Further readingEdit

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External linksEdit

Template:Repeated sequence Template:Authority control

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