Calling them names: variants of Plasmodium ovale

Population genomics of Plasmodium ovale species in sub-Saharan Africa

Plasmodium ovale curtisi (Poc) and Plasmodium ovale wallikeri (Pow) are relapsing malaria parasites endemic to Africa and Asia that were previously thought to represent a single species. Amid increasing detection of ovale malaria in sub-Saharan Africa, we present a population genomic study of both species across the continent. We conducted whole-genome sequencing of 25 isolates from Central and East Africa and analyzed them alongside 20 previously published African genomes. Isolates are predominantly monoclonal (43/45), with their genetic similarity aligning with geography. Pow shows lower average nucleotide diversity (1.8×10-4) across the genome compared to Poc (3.0×10-4) (p < 0.0001). Signatures of selective sweeps involving the dihydrofolate reductase gene have been found in both species, as are signs of balancing selection at the merozoite surface protein 1 gene. Differences in the nucleotide diversity of Poc and Pow may reflect unique demographic history, even as similar selective forces facilitate their resilience to malaria control interventions.

Population genomics of Plasmodium ovale species in sub-Saharan Africa

Plasmodium ovale curtisi (Poc) and Plasmodium ovale wallikeri (Pow) are relapsing malaria parasites endemic to Africa and Asia that were previously thought to represent a single species. Amid increasing detection of ovale malaria in sub-Saharan Africa, we performed a population genomic study of both species across the continent. We conducted whole-genome sequencing of 25 isolates from Central and East Africa and analyzed them alongside 20 previously published African genomes. Isolates were predominantly monoclonal (43/45), with their genetic similarity aligning with geography. Pow showed lower average nucleotide diversity (1.8×10-4) across the genome compared to Poc (3.0×10-4) (p < 0.0001). Signatures of selective sweeps involving the dihydrofolate reductase gene were found in both species, as were signs of balancing selection at the merozoite surface protein 1 gene. Differences in the nucleotide diversity of Poc and Pow may reflect unique demographic history, even as similar selective forces facilitate their resilience to malaria control interventions.

Development of new real-time PCR assays for detection and species differentiation of Plasmodium ovale

BACKGROUND

The parasite species Plasmodium ovalecurtisi (P. ovalecurtisi) and Plasmodium ovalewallikeri (P. ovalewallikeri), formerly known as Plasmodium ovale, are endemic across multiple African countries. These species are thought to differ in clinical symptomatology and latency, but only a small number of existing diagnostic assays can detect and distinguish them. In this study, we sought to develop new assays for the detection and differentiation of P. ovalecurtisi and P. ovalewallikeri by leveraging recently published whole-genome sequences for both species.

METHODS

Repetitive sequence motifs were identified in available P. ovalecurtisi and P. ovalewallikeri genomes and used for assay development and validation. We evaluated the analytical sensitivity of the best-performing singleplex and duplex assays using synthetic plasmids. We then evaluated the specificity of the duplex assay using a panel of samples from Tanzania and the Democratic Republic of the Congo (DRC), and validated its performance using 55 P. ovale samples and 40 non-ovale Plasmodium samples from the DRC.

RESULTS

The best-performing P. ovalecurtisi and P. ovalewallikeri targets had 9 and 8 copies within the reference genomes, respectively. The P. ovalecurtisi assay had high sensitivity with a 95% confidence lower limit of detection (LOD) of 3.6 parasite genome equivalents/μl, while the P. ovalewallikeri assay had a 95% confidence LOD of 25.9 parasite genome equivalents/μl. A duplex assay targeting both species had 100% specificity and 95% confidence LOD of 4.2 and 41.2 parasite genome equivalents/μl for P. ovalecurtisi and P. ovalewallikeri, respectively.

CONCLUSIONS

We identified promising multi-copy targets for molecular detection and differentiation of P. ovalecurtisi and P. ovalewallikeri and used them to develop real-time PCR assays. The best performing P. ovalecurtisi assay performed well in singleplex and duplex formats, while the P. ovalewallikeri assay did not reliably detect low-density infections in either format. These assays have potential use for high-throughput identification of P. ovalecurtisi, or for identification of higher density P. ovalecurtisi or P. ovalewallikeri infections that are amenable to downstream next-generation sequencing.

New reference genomes to distinguish the sympatric malaria parasites, Plasmodium ovale curtisi and Plasmodium ovale wallikeri

Despite Plasmodium ovale curtisi (Poc) and wallikeri (Pow) being important human-infecting malaria parasites that are widespread across Africa and Asia, little is known about their genome diversity. Morphologically identical, Poc and Pow are indistinguishable and commonly misidentified. Recent rises in the incidence of Poc/Pow infections have renewed efforts to address fundamental knowledge gaps in their biology, and to develop diagnostic tools to understand their epidemiological dynamics and malaria burden. A major roadblock has been the incompleteness of available reference assemblies (PocGH01, PowCR01; ~ 33.5 Mbp). Here, we applied multiple sequencing platforms and advanced bioinformatics tools to generate new reference genomes, Poc221 (South Sudan; 36.0 Mbp) and Pow222 (Nigeria; 34.3 Mbp), with improved nuclear genome contiguity (> 4.2 Mbp), annotation and completeness (> 99% Plasmodium spp., single copy orthologs). Subsequent sequencing of 6 Poc and 15 Pow isolates from Africa revealed a total of 22,517 and 43,855 high-quality core genome SNPs, respectively. Genome-wide levels of nucleotide diversity were determined to be 2.98 × 10-4 (Poc) and 3.43 × 10-4 (Pow), comparable to estimates for other Plasmodium species. Overall, the new reference genomes provide a robust foundation for dissecting the biology of Poc/Pow, their population structure and evolution, and will contribute to uncovering the recombination barrier separating these species.