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Malaria Journal
Published in: Malaria Journal 1/2015

Open Access 01-12-2015 | Methodology

COIL: a methodology for evaluating malarial complexity of infection using likelihood from single nucleotide polymorphism data

Authors: Kevin Galinsky, Clarissa Valim, Arielle Salmier, Benoit de Thoisy, Lise Musset, Eric Legrand, Aubrey Faust, Mary Lynn Baniecki, Daouda Ndiaye, Rachel F Daniels, Daniel L Hartl, Pardis C Sabeti, Dyann F Wirth, Sarah K Volkman, Daniel E Neafsey

Published in: Malaria Journal | Issue 1/2015

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Abstract

Background

Complex malaria infections are defined as those containing more than one genetically distinct lineage of Plasmodium parasite. Complexity of infection (COI) is a useful parameter to estimate from patient blood samples because it is associated with clinical outcome, epidemiology and disease transmission rate. This manuscript describes a method for estimating COI using likelihood, called COIL, from a panel of bi-allelic genotyping assays.

Methods

COIL assumes that distinct parasite lineages in complex infections are unrelated and that genotyped loci do not exhibit significant linkage disequilibrium. Using the population minor allele frequency (MAF) of the genotyped loci, COIL uses the binomial distribution to estimate the likelihood of a COI level given the prevalence of observed monomorphic or polymorphic genotypes within each sample.

Results

COIL reliably estimates COI up to a level of three or five with at least 24 or 96 unlinked genotyped loci, respectively, as determined by in silico simulation and empirical validation. Evaluation of COI levels greater than five in patient samples may require a very large collection of genotype data, making sequencing a more cost-effective approach for evaluating COI under conditions when disease transmission is extremely high. Performance of the method is positively correlated with the MAF of the genotyped loci. COI estimates from existing SNP genotype datasets create a more detailed portrait of disease than analyses based simply on the number of polymorphic genotypes observed within samples.

Conclusions

The capacity to reliably estimate COI from a genome-wide panel of SNP genotypes provides a potentially more accurate alternative to methods relying on PCR amplification of a small number of loci for estimating COI. This approach will also increase the number of applications of SNP genotype data, providing additional motivation to employ SNP barcodes for studies of disease epidemiology or control measure efficacy. The COIL program is available for download from GitHub, and users may also upload their SNP genotype data to a web interface for simple and efficient determination of sample COI.
Appendix
Available only for authorised users
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Metadata
Title
COIL: a methodology for evaluating malarial complexity of infection using likelihood from single nucleotide polymorphism data
Authors
Kevin Galinsky
Clarissa Valim
Arielle Salmier
Benoit de Thoisy
Lise Musset
Eric Legrand
Aubrey Faust
Mary Lynn Baniecki
Daouda Ndiaye
Rachel F Daniels
Daniel L Hartl
Pardis C Sabeti
Dyann F Wirth
Sarah K Volkman
Daniel E Neafsey
Publication date
01-12-2015
Publisher
BioMed Central
Published in
Malaria Journal / Issue 1/2015
Electronic ISSN: 1475-2875
DOI
https://doi.org/10.1186/1475-2875-14-4

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