Abstract
In many countries targeting malaria elimination, persistent malaria infections can have parasite loads significantly below the lower limit of detection (LLOD) of standard diagnostic techniques, making them difficult to identify and treat. The most sensitive diagnostic methods involve amplification and detection of Plasmodium DNA by polymerase chain reaction (PCR), which requires expensive thermal cycling equipment and is difficult to deploy in resource-limited settings. Isothermal DNA amplification assays have been developed, but they require complex primer design, resulting in high nonspecific amplification, and show a decrease in sensitivity than PCR methods. Here, we have used a computational approach to design a novel isothermal amplification assay with a simple primer design to amplify P. falciparum DNA with analytical sensitivity comparable to PCR. We have identified short DNA sequences repeated throughout the parasite genome to be used as primers for DNA amplification and demonstrated that these primers can be used, without modification, to isothermally amplify P. falciparum parasite DNA via strand displacement amplification. Our novel assay shows a LLOD of ∼1 parasite/μL within a 30 min amplification time. The assay was demonstrated with clinical samples using patient blood and saliva. We further characterized the assay using direct amplicon next-generation sequencing and modified the assay to work with a visual readout. The technique developed here achieves similar analytical sensitivity to current gold standard PCR assays requiring a fraction of time and resources for PCR. This highly sensitive isothermal assay can be more easily adapted to field settings, making it a potentially useful tool for malaria elimination.
Highlights
According to the 2018 World Malaria report, there were 217 million reported malaria cases in 2017, resulting in 435,000 deaths; this represents an increase of about 3.6 million cases from the previous year
We developed a room-temperature, centrifuge-free DNA extraction method and a lateral flow strip-based visual readout method to simplify adaptation of the iso-Identical Multi-Repeat Sequence (IMRS) assay to point of care (POC)
The algorithm identified two unique primers, a forward primer binding in 52 independent loci and a reverse primer binding in 55 independent loci across four chromosome regions in the P. falciparum genome (Figure S1)
Summary
According to the 2018 World Malaria report, there were 217 million reported malaria cases in 2017, resulting in 435,000 deaths; this represents an increase of about 3.6 million cases from the previous year. Real-time amplification curves, LOD comparison to the LAMP isothermal assay, predicted amplicon product sizes, amplicon alignment to the P. falciparum genome, LFS optimization, and iso-IMRS troubleshooting (PDF). Observed the lateral flow detection of several samples with DNA concentration below the expected LLOD for iso-IMRS, including samples that were below the qPCR limit of quantification These results indicate that iso-IMRS LFS detection may be more sensitive than fluorescence readout in this case, potentially due to the detection of partial amplified products. There were no false-positive LFS results from whole blood samples without parasites because the LFS binding reaction adds stringency to the assay by selecting for specific amplification products These results further support that the iso-IMRS LFS readout of samples with
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