Kompetitive allele specific PCR

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Schematic drawing of kompetitive allele specific PCR Schematic drawing of the KASP method (Kompetitive Allele Specific PCR).png
Schematic drawing of kompetitive allele specific PCR

Kompetitive allele specific PCR (KASP) is a homogenous, fluorescence-based genotyping variant of polymerase chain reaction. It is based on allele-specific oligo extension and fluorescence resonance energy transfer for signal generation.

Contents

A single-nucleotide polymorphism (SNP) occurs when a single nucleotide in a DNA sequence differs between members of the same species or a paired chromosome. SNPs work as molecular markers that help locate genes associated with disease and are used for genotype sequencing. [1]

Genotyping by next generation sequencing using SNPs is expensive, time-consuming, and has some missing data. There are many other SNP techniques that can be used depending on the purpose of the research considering throughput, data turnaround time, ease of use, performance (sensitivity, reliability, reproducibility, accuracy) flexibility, requirements, and cost. For the highest throughput for large scale studies, it is best to choose multiplexed chip-based technology. Multiplex technologies generate anywhere from 100 to over a million SNPs per run but are not economical to use for small to moderate numbers of SNPs. [2] For a smaller number of SNPs, a uniplex assay like KASP can be used.

Methodology

There are three components that are critical to the KASP assay: 1) a purified DNA sample, 2) two allele-specific forward primers, and 3) a common reverse primer. A minimum of 5-10 ng of the extracted DNA sample is required for the method to function properly. The DNA sample is purified by adding a mixture of chemicals to the buffer solution. [2] In the first round of PCR, a KASP primer mix that contains the two allele-specific forward primers and the single reverse primer is added to the mixture. The specific nature of the forward primers allows for the primer to bind solely at the SNP of interest, allowing DNA polymerase to lay down the rest of the complementary nucleotides. During this time, the common reverse primer begins to lay down complementary nucleotides on the opposite strand of DNA. This ends the first round of PCR. [2]

In the second round of PCR, the complementary strand to the allele-specific forward primer is generated when the common reverse primer binds to the amplicon formed in the first round of PCR. Finally, the thermocycling of the PCR reaction continues, starting the third portion of the KASP method. A fluorescently labeled primer is present in the master mix where it is quenched due to hybridization with its complementary part that has a quencher at the end. The fluorescent-labelled primer complements the tail sequence of the allele-specific forward primer, allowing for elongation to occur. This occurs multiple times throughout the thermocycling settings and the fluorescent signalling becomes stronger as more fluorescent primers are used in the amplification process. Fluorescent tags normally used are FAM and HEX [3]

Advantages and disadvantages

The KASP method is more cost-effective than multiplex methods--$15 per assay versus $50 per assay. There is also a much shorter turn around time to receive the results with the KASP method than other multiplex methods—24 hours versus a week. Additionally, there is a lower genotyping error rate of 0.7-1.6%. The KASP method is more flexible than other methods in that it can be used when there are many SNPs in a few samples or when there are few SNPs in many samples. However, the multiplex methods are currently the most high-throughput platforms for SNP genotyping. [2]

Applications

This technology has many applications in quality control (QC) genotyping, quantitative trait locus (QTL) mapping, marker-assisted selection (MAS), and allele mining. For example, the KASP platform has been used in qualitative control analyses for maize. In maize, homogeneity is important in cultivating the crops that the grower had selected. Slight variations in allelic frequencies may have large impacts on the crop's quality and can occur in a variety of ways including through cross-contamination of pollen and/or seeds and in seed regeneration. QC analysis can be used at the various events in which changes in allelic frequency can be expected so long as samples are taken from the parental and the F1 crop generations. This ensures that the allele frequencies haven't changed much between the two generations and ensures the purity of the line based on the set SNPs for the maize. For maize there have been between 50-100 SNPs identified that can be used to conduct this type of analysis. [2]

Quality analysis (QC analysis) is used to maintain the purity of the inbred line. QC genotype protocol uses 50-100 SNPs to determine non-homogeneity within a sample and establish genetic identity. QC can be used at any time during the breeding.

If QC is to be used for mapping population non-parental alleles are discarded and alleles for which more than 90% of SNPs are polymorphic between the parents are kept.

QTL mapping

QTL mapping identifies a subset of markers that are significantly associated with one or more QTLs influencing the expression of the trait of interest.

  1. Select or develop a biparental mapping population.
  2. Phenotype the population for a trait under greenhouse or field conditions.
  3. Choose a molecular marking system – genotype parents of the mapping population and F1s with large numbers of markers, then select 200-400 markers exhibiting polymorphism between the parents.
  4. Choose a genotyping approach, then generate molecular data for polymorphic markers
  5. Identify the molecular markers associated with major QTLs by using statistical programs.

For QTL mapping in maize:

  1. use KASP to genotype parents and F1s with 1250 SNPs
  2. Identify the polymorphic SNPs
  3. Genotype the entire population with polymorphic SNPs

Related Research Articles

In molecular biology, restriction fragment length polymorphism (RFLP) is a technique that exploits variations in homologous DNA sequences, known as polymorphisms, in order to distinguish individuals, populations, or species or to pinpoint the locations of genes within a sequence. The term may refer to a polymorphism itself, as detected through the differing locations of restriction enzyme sites, or to a related laboratory technique by which such differences can be illustrated. In RFLP analysis, a DNA sample is digested into fragments by one or more restriction enzymes, and the resulting restriction fragments are then separated by gel electrophoresis according to their size.

Genotyping is the process of determining differences in the genetic make-up (genotype) of an individual by examining the individual's DNA sequence using biological assays and comparing it to another individual's sequence or a reference sequence. It reveals the alleles an individual has inherited from their parents. Traditionally genotyping is the use of DNA sequences to define biological populations by use of molecular tools. It does not usually involve defining the genes of an individual.

<span class="mw-page-title-main">Molecular beacon</span>

Molecular beacons, or molecular beacon probes, are oligonucleotide hybridization probes that can report the presence of specific nucleic acids in homogenous solutions. Molecular beacons are hairpin-shaped molecules with an internally quenched fluorophore whose fluorescence is restored when they bind to a target nucleic acid sequence. This is a novel non-radioactive method for detecting specific sequences of nucleic acids. They are useful in situations where it is either not possible or desirable to isolate the probe-target hybrids from an excess of the hybridization probes.

A molecular marker is a molecule, sampled from some source, that gives information about its source. For example, DNA is a molecular marker that gives information about the organism from which it was taken. For another example, some proteins can be molecular markers of Alzheimer's disease in a person from which they are taken. Molecular markers may be non-biological. Non-biological markers are often used in environmental studies.

Single-base extension (SBE) is a method for determining the identity of a nucleotide base at a specific position along a nucleic acid. The method is used to identify a single-nucleotide polymorphism (SNP).

A dark quencher is a substance that absorbs excitation energy from a fluorophore and dissipates the energy as heat; while a typical (fluorescent) quencher re-emits much of this energy as light. Dark quenchers are used in molecular biology in conjunction with fluorophores. When the two are close together, such as in a molecule or protein, the fluorophore's emission is suppressed. This effect can be used to study molecular geometry and motion.

SNP genotyping is the measurement of genetic variations of single nucleotide polymorphisms (SNPs) between members of a species. It is a form of genotyping, which is the measurement of more general genetic variation. SNPs are one of the most common types of genetic variation. An SNP is a single base pair mutation at a specific locus, usually consisting of two alleles. SNPs are found to be involved in the etiology of many human diseases and are becoming of particular interest in pharmacogenetics. Because SNPs are conserved during evolution, they have been proposed as markers for use in quantitative trait loci (QTL) analysis and in association studies in place of microsatellites. The use of SNPs is being extended in the HapMap project, which aims to provide the minimal set of SNPs needed to genotype the human genome. SNPs can also provide a genetic fingerprint for use in identity testing. The increase of interest in SNPs has been reflected by the furious development of a diverse range of SNP genotyping methods.

<span class="mw-page-title-main">Bisulfite sequencing</span> Lab procedure detecting 5-methylcytosines in DNA

Bisulfitesequencing (also known as bisulphite sequencing) is the use of bisulfite treatment of DNA before routine sequencing to determine the pattern of methylation. DNA methylation was the first discovered epigenetic mark, and remains the most studied. In animals it predominantly involves the addition of a methyl group to the carbon-5 position of cytosine residues of the dinucleotide CpG, and is implicated in repression of transcriptional activity.

An allele-specific oligonucleotide (ASO) is a short piece of synthetic DNA complementary to the sequence of a variable target DNA. It acts as a probe for the presence of the target in a Southern blot assay or, more commonly, in the simpler Dot blot assay. It is a common tool used in genetic testing, forensics, and Molecular Biology research.

Marker assisted selection or marker aided selection (MAS) is an indirect selection process where a trait of interest is selected based on a marker linked to a trait of interest, rather than on the trait itself. This process has been extensively researched and proposed for plant and animal breeding.

<span class="mw-page-title-main">Nucleic acid test</span> Group of techniques to detect a particular nucleic acid sequence

A nucleic acid test (NAT) is a technique used to detect a particular nucleic acid sequence and thus usually to detect and identify a particular species or subspecies of organism, often a virus or bacterium that acts as a pathogen in blood, tissue, urine, etc. NATs differ from other tests in that they detect genetic materials rather than antigens or antibodies. Detection of genetic materials allows an early diagnosis of a disease because the detection of antigens and/or antibodies requires time for them to start appearing in the bloodstream. Since the amount of a certain genetic material is usually very small, many NATs include a step that amplifies the genetic material—that is, makes many copies of it. Such NATs are called nucleic acid amplification tests (NAATs). There are several ways of amplification, including polymerase chain reaction (PCR), strand displacement assay (SDA), or transcription mediated assay (TMA).

The versatility of polymerase chain reaction (PCR) has led to a large number of variants of PCR.

<span class="mw-page-title-main">MAGIChip</span>

MAGIChips, also known as "microarrays of gel-immobilized compounds on a chip" or "three-dimensional DNA microarrays", are devices for molecular hybridization produced by immobilizing oligonucleotides, DNA, enzymes, antibodies, and other compounds on a photopolymerized micromatrix of polyacrylamide gel pads of 100x100x20µm or smaller size. This technology is used for analysis of nucleic acid hybridization, specific binding of DNA, and low-molecular weight compounds with proteins, and protein-protein interactions.

Diversity Arrays Technology (DArT) is a high-throughput genetic marker technique that can detect allelic variations to provides comprehensive genome coverage without any DNA sequence information for genotyping and other genetic analysis. The general steps involve reducing the complexity of the genomic DNA with specific restriction enzymes, choosing diverse fragments to serve as representations for the parent genomes, amplify via polymerase chain reaction (PCR), insert fragments into a vector to be placed as probes within a microarray, then fluorescent targets from a reference sequence will be allowed to hybridize with probes and put through an imaging system. The objective is to identify and quantify various forms of DNA polymorphism within genomic DNA of sampled species.

Multiplex polymerase chain reaction refers to the use of polymerase chain reaction to amplify several different DNA sequences simultaneously. This process amplifies DNA in samples using multiple primers and a temperature-mediated DNA polymerase in a thermal cycler. The primer design for all primers pairs has to be optimized so that all primer pairs can work at the same annealing temperature during PCR.

In genetics, association mapping, also known as "linkage disequilibrium mapping", is a method of mapping quantitative trait loci (QTLs) that takes advantage of historic linkage disequilibrium to link phenotypes to genotypes, uncovering genetic associations.

Molecular Inversion Probe (MIP) belongs to the class of Capture by Circularization molecular techniques for performing genomic partitioning, a process through which one captures and enriches specific regions of the genome. Probes used in this technique are single stranded DNA molecules and, similar to other genomic partitioning techniques, contain sequences that are complementary to the target in the genome; these probes hybridize to and capture the genomic target. MIP stands unique from other genomic partitioning strategies in that MIP probes share the common design of two genomic target complementary segments separated by a linker region. With this design, when the probe hybridizes to the target, it undergoes an inversion in configuration and circularizes. Specifically, the two target complementary regions at the 5’ and 3’ ends of the probe become adjacent to one another while the internal linker region forms a free hanging loop. The technology has been used extensively in the HapMap project for large-scale SNP genotyping as well as for studying gene copy alterations and characteristics of specific genomic loci to identify biomarkers for different diseases such as cancer. Key strengths of the MIP technology include its high specificity to the target and its scalability for high-throughput, multiplexed analyses where tens of thousands of genomic loci are assayed simultaneously.

COLD-PCR is a modified polymerase chain reaction (PCR) protocol that enriches variant alleles from a mixture of wildtype and mutation-containing DNA. The ability to preferentially amplify and identify minority alleles and low-level somatic DNA mutations in the presence of excess wildtype alleles is useful for the detection of mutations. Detection of mutations is important in the case of early cancer detection from tissue biopsies and body fluids such as blood plasma or serum, assessment of residual disease after surgery or chemotherapy, disease staging and molecular profiling for prognosis or tailoring therapy to individual patients, and monitoring of therapy outcome and cancer remission or relapse. Common PCR will amplify both the major (wildtype) and minor (mutant) alleles with the same efficiency, occluding the ability to easily detect the presence of low-level mutations. The capacity to detect a mutation in a mixture of variant/wildtype DNA is valuable because this mixture of variant DNAs can occur when provided with a heterogeneous sample – as is often the case with cancer biopsies. Currently, traditional PCR is used in tandem with a number of different downstream assays for genotyping or the detection of somatic mutations. These can include the use of amplified DNA for RFLP analysis, MALDI-TOF genotyping, or direct sequencing for detection of mutations by Sanger sequencing or pyrosequencing. Replacing traditional PCR with COLD-PCR for these downstream assays will increase the reliability in detecting mutations from mixed samples, including tumors and body fluids.

<span class="mw-page-title-main">Restriction site associated DNA markers</span> Type of genetic marker

Restriction site associated DNA (RAD) markers are a type of genetic marker which are useful for association mapping, QTL-mapping, population genetics, ecological genetics and evolutionary genetics. The use of RAD markers for genetic mapping is often called RAD mapping. An important aspect of RAD markers and mapping is the process of isolating RAD tags, which are the DNA sequences that immediately flank each instance of a particular restriction site of a restriction enzyme throughout the genome. Once RAD tags have been isolated, they can be used to identify and genotype DNA sequence polymorphisms mainly in form of single nucleotide polymorphisms (SNPs). Polymorphisms that are identified and genotyped by isolating and analyzing RAD tags are referred to as RAD markers. Although genotyping by sequencing presents an approach similar to the RAD-seq method, they differ in some substantial ways.

In the field of genetic sequencing, genotyping by sequencing, also called GBS, is a method to discover single nucleotide polymorphisms (SNP) in order to perform genotyping studies, such as genome-wide association studies (GWAS). GBS uses restriction enzymes to reduce genome complexity and genotype multiple DNA samples. After digestion, PCR is performed to increase fragments pool and then GBS libraries are sequenced using next generation sequencing technologies, usually resulting in about 100bp single-end reads. It is relatively inexpensive and has been used in plant breeding. Although GBS presents an approach similar to restriction-site-associated DNA sequencing (RAD-seq) method, they differ in some substantial ways.

References

  1. "What are Single Nucleotide Polymorphisms (SNPs)?". U.S. National Library of Medicine. Retrieved 7 April 2014.
  2. 1 2 3 4 5 Semagn, Kassa; Babu, Raman; Hearne, Sarah; Olsen, Michael (10 July 2013). "Single nucleotide polymorphism genotyping using Kompetitive Allele Specific PCR (KASP): overview of the technology and its application in crop improvement". Molecular Breeding. 33 (1): 1–14. doi:10.1007/s11032-013-9917-x. S2CID   14272035.
  3. "How does KASP work?". LGC Genomics. Retrieved 7 April 2014.
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