KASP: a genotyping method to rapid identification of resistance in Plasmodium falciparum

The final selection was based on species-specific identification by nested-PCR [18, 19] and only samples with unique infection with P. falciparum were chosen for the study.

DNA was extracted from 200 µl of whole blood, collected in ethylenediamine tetraacetic acid (EDTA) tubes, using the QIAamp DNA mini blood kit (QIAGEN^®, Hilden, Germany) according to the manufacturer’s instructions, resuspended in a final volume of 100 µl of distilled water. The DNA is stored at 4 °C until use, using 5 µl per reaction.

Genotyping of Pfmdr1, Pfcytb and PfK13 genes was carried by real time PCR modified from the original methods [20‐22]. Reaction mixture consists of 1 × QUANTIMIX HotSplit Probes kit (Biotools, Madrid, Spain) 0.25 μM of each primer (Table 1) and 1 µM EvaGreen^® dye (Biotium, Hayward, CA, USA) in a final volume of 20 µl. The thermal cycle was performed in a Qiagen Rotor Gene Q 5 Plex HRM (QIAGEN^®, Hilden, Germany). The amplification conditions for the Pfmdr1 and Pfcytb genes were an initial cycle of denaturation of 10 min at 95 °C, followed by 45 cycles of 15 s at 95 °C, 15 s at 54 °C and 30 s at 68 °C, ending with a melting step (62 °C to 92 °C). In the case of the PfK13 gene, the conditions were an initial denaturation cycle of 7 min at 94 °C, followed by 40 cycles of 30 s at 94 °C, 1 min at 60 °C and 1 min at 72 °C, ending with a melting step (62 °C to 92 °C).

Specificity of amplification was determined by post reaction analysis using the melting temperature (Tm) curve of the amplified fragments (76.8 °C and 76.5 °C for Pfmdr1 fragment A and B respectively, 79.5 °C for Pfcytb, and 82.0 °C for PfK13).

Amplicons were purified using Illustra DNA and Gel Band Purification Kit (General Electric Healthcare, England), then sequenced, with its specific primers (Table 1), using Big Dye Terminator v3.1 Kit in an ABI PRISM^® DNA Analyzer 3700. All amplified products were sequenced in both directions, twice. Blast tool from NCBI was used to confirm correct target amplification. Multiple nucleotide sequence alignments and analysis were performed using BioEdit version 7.0.5.3 [23] using sequences from 3D7 strain as wild-type for comparison.

Plasmodium falciparum genotyping was performed by characterizing two merozoite surface membrane genes (msp-1 and msp-2) by PCR described elsewhere [24, 25]. Multiplicity of infection (MOI) defined as the number of genetically distinct parasite strains co-infecting a single host, was determined as the largest number of different alleles present at one of the two loci studied.

Sequences flanking SNPs were submitted for KASP ™ assay design to Biosearch Technologies (California, USA). KASP assay was carried out following the instructions of the manufacturer [6]. The reaction mix per reaction consists of 5.1 µl of the KASP Master Mix, which include the two allele specific primers and one reverse primer (Table 2), and 0.138 µl of the Assay Mix, containing universal fluorescent probes, Taq polymerase and dNTPs in an optimized buffer solution.

To five µl of this reaction mix, five µl of DNA from the sample to be analysed, are added. PCRs and fluorescent readings were performed in a Qiagen Rotor Gene Q 5 Plex HRM (QIAGEN^®, Hilden, Germany) following the recommended thermal cycling conditions (Table 3).

To analyse and interpret genotypic data, an Excel sheet is used, although it can also be done using the Thermo Fisher Cloud Genotyping application [26]. In a KASP general assay, a sample that is homozygous for the allele reported by the X-signal oligonucleotide will only generate X-signal fluorescence during the end-point genotyping reaction. This data point will be plotted close to the X-axis, representing a high X-signal and no Y-signal. A sample that is homozygous for the allele reported by the Y-signal oligonucleotide will only generate Y-signal fluorescence during the end-point genotyping reaction. This data point will be plotted close to the Y-axis, representing a high Y-signal and no X-signal. A heterozygous sample will contain both the allele reported by the X-signal oligonucleotide and the allele reported by the Y-signal oligonucleotide. This sample will generate half as much X-signal fluorescence and half as much Y-signal fluorescence as the samples that are homozygous for these alleles. This data point will be plotted in the center of the plot, representing half X-signal and half Y-signal. In falciparum malaria, the situation is more complicated, since, in the blood phase infection, Plasmodium is haploid, but P. falciparum infections are usually multi-infection so different levels of “heterozygosis” can occur depending on the number of populations present in each infection (MOI). Thus, the points are scattered on the plot but always close to the corresponding axis if only one allele is present, while infections with both alleles will be located in the centre of the plot. Furthermore, to ensure the proper performance of the assay always is useful to include an end-point genotyping reaction without any template DNA as a negative control (referred to as no template control or NTC) that should appear near zero in the cluster plot.