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1. HRM-PCR Protocol
<ol>
	<li>Thaw the DNA samples. Dilute the DNA samples in 1.5 mL tubes with water to adjust them to a concentration of 10 ng/&#181;L 
	NOTE: The total volume of diluted DNA should be between 2 &#181;L and 10 &#181;L.</li>
	<li>Thaw the primer solutions. Dilute the primer solutions in 1.5-mL tubes with water to adjust them to the same concentration of 6 &#181;M. 
	NOTE: The primer sequences and reaction conditions are provided in Table 1.</li>
	<li>Thaw the HRM-PCR kit solutions and mix carefully by vortexing to ensure the recovery of all contents. Briefly spin the three vials containing the enzymatic mixture with DNA binding dye, MgCl2, and water in a microcentrifuge before opening them. Store them at room temperature.</li>
	<li>In a 1.5 mL tube at room temperature, prepare the PCR mix for one 20 &#181;L reaction by adding the following components in the order listed below:
	<ol>
		<li>10 &#181;L of enzymatic mixture with DNA binding dye;</li>
		<li>2 &#181;L of 25 mM MgCl2;</li>
		<li>1 &#181;L of primer 1, 6 &#181;M (final concentration: 300 nM);</li>
		<li>1 &#181;L of primer 2, 6 &#181;M (final concentration: 300 nM); and</li>
		<li>5 &#181;L of water. 
		NOTE: To prepare the PCR mix for more than one reaction, multiply the volumes above by the number of reactions to be run, plus one additional reaction.</li>
	</ol>
	</li>
	<li>Mix carefully by vortexing.</li>
	<li>Pipette 19 &#181;L of PCR mix, prepared above, into each well of a white multiwell plate.</li>
	<li>Add 1 &#181;L of concentration-adjusted DNA template. 
	NOTE: For control reactions, always run a negative control with the samples. To prepare a negative control, replace the template DNA with water.</li>
	<li>Seal the white multiwell plate with sealing foil.</li>
	<li>Place the white multiwell plate in the centrifuge and balance it with a suitable counterweight (i.e., another multiwell plate). Centrifuge for 1 min at 1,500 x g in a standard swing-bucket centrifuge containing a rotor for multiwell plates with suitable adaptors.</li>
	<li>Load the white multiwell plate into the HRM-PCR instrument.</li>
	<li>Start the HRM-PCR program with the following PCR conditions: 
	Denaturation: 95 &#176;C for 10 min; 1 cycle. 
	Amplification: 95 &#176;C for 10 s, 62 &#176;C for 15s, and 72 &#176;C for 20s; 47 cycles. 
	Melting curve: 95 &#176;C; ramp rate: 0.02 &#176;C/s; 25 acquisitions per &#176;C; 1 cycle. 
	Cooling: 40 &#176;C for 30 s; ramp rate 2.2 &#176;C/s; 1 cycle.</li>
</ol>
<img alt="Figure 1" src="/files/ftp_upload/21360/21360_Figure1.jpg" />
Table 1: Primers and parameters used in the high-resolution melting analysis.
2. HRM Analysis to Determine the CR1 Length Polymorphism
NOTE: The methodology described (Figure 1) is specific to our software (See the Table of Materials), although other software packages may be used.
<ol>
	<li>Open a gene scanning software to perform the CR1 length polymorphism scanning analysis.</li>
	<li>Open the experiment containing the amplification program and the melting curve program.</li>
	<li>Click Sample editor in the Module bar and then select the Scanning workflow.</li>
	<li>Define the properties of the samples (i.e., name; unknown or negative control).</li>
	<li>Click Analysis in the Module bar.</li>
	<li>In the Create New Analysis list, select Gene Scanning.</li>
	<li>Click the Normalization tab to normalize the melting curves.</li>
	<li>Click the Temperature shift tab to reset the temperature axis (x-axis) of the melting curves. 
	NOTE: The lower graph shows melting curves that are both normalized and temperature-shifted.</li>
	<li>Click the Calculate button to analyze the results and determine the grouping.</li>
	<li>Click the Difference plot tab in the charts area to view the Normalized and Shifted Melting Curves and the Normalized and Temperature Shifted Difference Plot.</li>
</ol>

<table><tbody><tr><td>Lab coat</td><td></td><td></td><td>protection</td></tr><tr><td>SensiCareIce powder-free Nitrile Exam gloves</td><td>Medline Industries, Inc, Mundelein, IL 60060, USA</td><td>486802</td><td>sample protection</td></tr><tr><td>Eppendorf Reference 2 pipette, 0.5-10&amp;micro;L</td><td>Eppendorf France SAS, F-78360 Montesson, France</td><td>4920000024</td><td>sample pipetting</td></tr><tr><td>Eppendorf Reference 2 pipette, 20-100&amp;micro;L</td><td>Eppendorf France SAS, F-78360 Montesson, France</td><td>4920000059</td><td>sample pipetting</td></tr><tr><td>Eppendorf Reference 2 pipette, 100-1000&amp;micro;L</td><td>Eppendorf France SAS, F-78360 Montesson, France</td><td>4920000083</td><td>sample pipetting</td></tr><tr><td>TipOne 10&amp;micro;L Graduated, filter tip</td><td>Starlab GmbH, D-22926 Ahrenburg, Germany</td><td>S1121-3810</td><td>sample pipetting</td></tr><tr><td>TipOne 1-100&amp;micro;L bevelled, filter tip&amp;nbsp;</td><td>Starlab GmbH, D-22926 Ahrenburg, Germany</td><td>S1120-1840</td><td>sample pipetting</td></tr><tr><td>ART 1000E Barrier Tip</td><td>Thermo Fischer Scientific , F-67403 Illkirch, France</td><td>2079E</td><td>sample pipetting</td></tr><tr><td>Eppendorf Safe-Lock Tubes, 1.5 mL, Eppendorf Quality</td><td>Eppendorf France SAS, F-78360 Montesson, France</td><td>30120086</td><td>mix</td></tr><tr><td>Vortex-Genie 2</td><td>Scientific Industries, Inc, Bohemia, NY 111716, USA</td><td>SI-0236</td><td>mix</td></tr><tr><td>Mikro 200 centrifuge</td><td>Hettich Zentrifugen, D-78532, Germany</td><td>0002020-02-00</td><td>centrifugation</td></tr><tr><td>Multipette E3</td><td>Eppendorf France SAS, F-78360 Montesson, France</td><td>4987000010</td><td>distribution</td></tr><tr><td>Light Cycler 480 multiwell plate 96, white</td><td>Roche Diagnostics GmbH, D-68305 Mannheim, Germany</td><td>4729692001</td><td>reaction place</td></tr><tr><td>Light Cycler 480 sealing foil</td><td>Roche Diagnostics GmbH, D-68305 Mannheim, Germany</td><td>4429757001</td><td>coverage</td></tr><tr><td>LightCycler 480 Instrument II, 96-well</td><td>Roche Diagnostics GmbH, D-68305 Mannheim, Germany</td><td>05015278001</td><td>high resolution melting polymerase chain reaction</td></tr><tr><td>Heraeus Megafuge 11R centrifuge</td><td>Thermo Fischer Scientific , F-67403 Illkirch, France</td><td>75004412</td><td>centrifugation</td></tr><tr><td>LightCycler 480 High Resolution Melting Master</td><td>Roche Diagnostics GmbH, D-68305 Mannheim, Germany</td><td>04909631001</td><td>reaction reagents</td></tr><tr><td>CN3 primer: 5&#039;ggccttagacttctcctgc 3&#039;</td><td>Eurogentec Biologics Division, B4102 Seraing, Belgium</td><td></td><td>reaction reagent</td></tr><tr><td>CN3re primer: 5&#039;gttgacaaattggcggcttcg 3&#039;</td><td>Eurogentec Biologics Division, B4102 Seraing, Belgium</td><td></td><td>reaction reagents</td></tr><tr><td>light cycler 480 SW 1.5.1 software</td><td>Roche Diagnostics GmbH, D-68305 Mannheim, Germany</td><td></td><td>software used for HRM-PCR CR1 polymorphism data analysis</td></tr></tbody></table>

high-resolution melting pcr to determine sequence variations in mutant dna sequences

Source: Kisserli, A., et al. <a href="https://app.jove.com/v/56012">High-resolution Melting PCR for Complement Receptor 1 Length Polymorphism Genotyping: An Innovative Tool for Alzheimer&#39;s Disease Gene Susceptibility Assessment.</a> J. Vis. Exp. (2017).
In this video, we describe a high-resolution melting PCR technique to determine the length polymorphism of DNA fragments of varying sequence lengths, based on melting temperature analysis.

<img alt="Figure 1" src="/files/ftp_upload/21360/21360_Figure2.jpg" /> 
Figure 1: Screenshots of the graphical interface of the software used in step 2 of the protocol. (A) Open the gene scanning software. (B) Amplification program and melting curve program. (C) Click on Sample editor in the Module bar. (D) Select Scanning. (E) Define the properties of the samples. ...

High-Resolution Melting PCR to Determine Sequence Variations in Mutant DNA Sequences

Source: Kisserli, A., et al. High-resolution Melting PCR for Complement Receptor 1 Length Polymorphism Genotyping: An Innovative Tool for Alzheimer&#39;s ...

High-resolution melting polymerase chain reaction, HRM-PCR, detects double-stranded DNA, dsDNA sequence variations with high precision.
Begin with a master mix containing inactive Taq polymerase, deoxyribonucleotide triphosphates &#8212; dNTPs &#8212; and the fluorescent reporter dye. Add the forward and reverse primers. Pipette the mixture to a PCR plate&#39;s wells.
Add the dsDNA template. Seal the plate, preventing mixture evaporation. Begin the PCR.
The high denaturing temperature denatures dsDNA to single-stranded DNA, ssDNA, and activates the polymerase. The reaction is then cooled to the annealing temperature, facilitating forward and reverse primer binding to ssDNAs via site-specific complementary base pairing.
Activated polymerase gets recruited, extending the DNA-primer duplex by dNTP addition.
The fluorescent reporter dye &#8212; a dsDNA-specific dye present in saturating concentrations &#8212; intercalates within the entire duplex, fluorescing brightly. The duplex undergoes multiple PCR cycles, producing several variant-containing fragments.
Post-PCR, perform melt curve analysis by re-rising the reaction temperature steadily over time.
Depending on the nucleotide sequence, the variant-containing site may denature first, releasing the dye. As the remaining dye-binding sites are saturated, the dye fails to re-intercalate, reducing fluorescence intensity. Further, dsDNA dissociates into ssDNA upon incremental heating.
Identify the melting temperature, at which half the dsDNA denatures to ssDNA with a sharp fluorescence decrease. A shift in the melt curve of the amplified DNA fragments identifies the sample&#39;s nucleotide sequence variations.

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145 Views. Source: Kisserli, A., et al. High-resolution Melting PCR for Complement Receptor 1 Length Polymorphism Genotyping: An Innovative Tool for Alzheimer's Disease Gene Susceptibility Assessment. J. Vis. Exp. (2017). In this video, we describe a high-resolution melting PCR technique to determine the length polymorphism of DNA fragments of varying sequence lengths, based on melting temperature analysis. 

Video: High-Resolution Melting PCR to Determine Sequence Variations in Mutant DNA Sequences - Concept

Identifying Mutations by High Resolution Melting in a TILLING Population of Rice

Target Induced Local Lesions In Genomes (TILLING) is a strategy of reverse genetics for the high-throughput screening of induced mutations. However, the TILLING system has less applicability for insertion/deletion (Indel) detection and traditional TILLING needs more complex steps, like CEL I nuclease digestion and gel electrophoresis. To improve the throughput and selection efficiency, and to make the screening of both Indels and single base substitions (SBSs) possible, a new high-resolution melting (HRM)-based TILLING system is developed. Here, we present a detailed HRM-TILLING protocol and show its application in mutation screening. This method can analyze the mutations of PCR amplicons by measuring the denaturation of double-stranded DNA at high temperatures. HRM analysis is directly performed post-PCR without additional processing. Moreover, a simple, safe and fast (SSF) DNA extraction method is integrated with HRM-TILLING to identify both Indels and SBSs. Its simplicity, robustness and high throughput make it potentially useful for mutation scanning in rice and other crops.

In this article, we present the protocol that is described as high-resolution melting analysis (HRM)-based Target Induced Local Lesions In Genomes (TILLING). This method utilizes fluorescence changes during the melting of the DNA duplex and is suitable for high-throughput screening of both insertion/deletion (Indel) and single base substition (SBS).

Target Induced Local Lesions In Genomes (TILLING) is a strategy of reverse genetics for the high-throughput screening of induced mutations. However, the ...

JoVE Journal

Genetics

Genetic Variant Detection in the CALR gene using High Resolution Melting Analysis

High resolution melting analysis (HRM) is a powerful method for genotyping and genetic variation scanning. Most HRM applications depend on saturating DNA dyes that detect sequence differences, and heteroduplexes that change the shape of the melting curve. Excellent instrument resolution and special data analysis software are needed to identify the small melting curve differences that identify a variant or genotype. Different types of genetic variants with diverse frequencies can be observed in the gene specific for patients with a specific disease, especially cancer and in the CALR gene in patients with Philadelphia chromosome&#8211;negative myeloproliferative neoplasms. Single nucleotide changes, insertions and/or deletions (indels) in the gene of interest can be detected by the HRM analysis. The identification of different types of genetic variants is mostly based on the controls used in the qPCR HRM assay. However, as the product length increases, the difference between wild-type and heterozygote curves becomes smaller, and the type of genetic variant is more difficult to determine. Therefore, where indels are the prevalent genetic variant expected in the gene of interest, an additional method such as agarose gel electrophoresis can be used for the clarification of the HRM result. In some instances, an inconclusive result must be re-checked/re-diagnosed by standard Sanger sequencing. In this retrospective study, we applied the method to JAK2 V617F-negative patients with MPN.

Genetic Variant Detection in the CALR gene using High Resolution Melting Analysis

High resolution melting analysis (HRM) is a sensitive and rapid solution for genetic variant detection. It depends on sequence differences that result in heteroduplexes changing the shape of the melting curve. By combing HRM and agarose gel electrophoresis, different types of genetic variants such as indels can be identified.

High resolution melting analysis (HRM) is a powerful method for genotyping and genetic variation scanning. Most HRM applications depend on saturating DNA ...

Indel Detection following CRISPR/Cas9 Mutagenesis using High-resolution Melt Analysis in the Mosquito Aedes aegypti

Mosquito gene editing has become routine in several laboratories with the establishment of systems such as transcription-activator-like effector nucleases (TALENs), zinc-finger nucleases (ZFNs), and homing endonucleases (HEs). More recently, clustered regularly interspaced short palindromic repeats (CRISPR)/CRISPR-associated protein 9 (Cas9) technology has offered an easier and cheaper alternative for precision genome engineering. Following nuclease action, DNA repair pathways will fix the broken DNA ends, often introducing indels. These out-of-frame mutations are then used for understanding gene function in the target organisms. A drawback, however, is that mutant individuals carry no dominant marker, making identification and tracking of mutant alleles challenging, especially at scales needed for many experiments. 
High-resolution melt analysis (HRMA) is a simple method to identify variations in nucleic acid sequences and utilizes PCR melting curves to detect such variations. This post-PCR analysis method uses fluorescent double-stranded DNA-binding dyes with instrumentation that has temperature ramp control data capture capability and is easily scaled to 96-well plate formats. Described here is a simple workflow using HRMA for the rapid detection of CRISPR/Cas9-induced indels and the establishment of mutant lines in the mosquito Ae. aegypti. Critically, all steps can be performed with a small amount of leg tissue and do not require sacrificing the organism, allowing genetic crosses or phenotyping assays to be performed after genotyping.

Indel Detection following CRISPR/Cas9 Mutagenesis using High-resolution Melt Analysis in the Mosquito Aedes aegypti

This article details a protocol for rapid identification of indels induced by CRISPR/Cas9 and selection of mutant lines in the mosquito Aedes aegypti using high-resolution melt analysis.

Mosquito gene editing has become routine in several laboratories with the establishment of systems such as transcription-activator-like effector nucleases ...

High-Resolution Melting PCR to Determine Sequence Variations in Mutant DNA Sequences

Transcript

High-Resolution Melting PCR to Determine Sequence Variations in Mutant DNA Sequences

Identifying Mutations by High Resolution Melting in a TILLING Population of Rice

Genetic Variant Detection in the CALR gene using High Resolution Melting Analysis

Indel Detection following CRISPR/Cas9 Mutagenesis using High-resolution Melt Analysis in the Mosquito Aedes aegypti