Introduction

Emergence of Plasmodium falciparum strains that evade detection by rapid diagnostic tests (RDTs) threatens progress toward malaria control and elimination in Africa1,2,3. These parasites have deletions involving the histidine-rich protein 2 and/or 3 (pfhrp2/3) genes, which encode the proteins detected by widely used RDTs throughout Africa4. Increasing reports of these parasites in select locations across Africa raise concern about the future of HRP2-based RDTs in the region5,6,7. Recent events in Eritrea, where a high frequency of false-negative RDTs due to these parasites triggered a change in national malaria diagnostic policy, emphasize the need for surveillance and a coordinated response to pfhrp2/3-deleted P. falciparum8,9.

We previously performed the first national survey of pfhrp2 deletions and reported a 6.4% national prevalence of pfhrp2-negative parasites among asymptomatic children in the Democratic Republic of the Congo (DRC)10. While this cross-sectional, nationally representative household survey enabled spatial analyses and initial population genetic analyses of pfhrp2-negative parasites in the DRC, it did not sample subjects with symptomatic malaria. In order to inform decisions about national malaria diagnostic testing policy, we undertook a cross-sectional survey of children and adults presenting to government health facilities in three provinces selected based on the prevalence of pfhrp2-negative parasites in our initial study. Based on results from our prior study of asymptomatic children and a mathematical model of the spread of pfhrp2/3-deleted P. falciparum6,10, we hypothesized that pfhrp2/3-deleted parasites were responsible for missed clinical cases of falciparum malaria in the DRC and would be more commonly identified in regions with lower transmission intensity.

Studies of pfhrp2/3-deleted P. falciparum are difficult due to the challenges of confirming the absence of these genes using conventional approaches11,12. These challenges are compounded by inconsistent laboratory methodologies across studies and inherent limitations of pfhrp2/3 assays that can suffer from variable performance and cross-reactivity13,14. In addition, false-negative RDT results are common throughout Africa and typically caused by factors other than pfhrp2/3 deletions, including operator error, lot-to-lot RDT variability, low-density infections below the RDT’s limit of detection, and infection by non-falciparum species15,16. In order to overcome these challenges, we performed a comprehensive molecular, serological, and genomic evaluation of symptomatic infections to define the causes of false-negative RDTs in the DRC and inform national diagnostic testing policy.

Methods

Study population

We conducted a cross-sectional study of subjects presenting to hospitals and health centers across three provinces (Kinshasa, Bas-Uele, and Sud-Kivu) with suspected malaria. Cases of suspected malaria were identified according to national guidelines and included those with fever, headache, convulsions, muscle or joint pain, vomiting, and other symptoms. The National Malaria Control Program considers malaria prevalence in these provinces to be urban, hyperendemic, and mesoendemic, respectively17. These provinces were selected based on results from our prior survey of asymptomatic children in the nationally representative 2013–2014 DRC Demographic and Health Survey (DHS) and included provinces with both high- (Kinshasa, Sud-Kivu) and low-prevalence (Bas-Uele) of pfhrp2-negative parasites10. We previously estimated the weighted prevalence of pfhrp2-negative P. falciparum among asymptomatic children in these provinces: 21.9% (95% confidence interval [CI] 13.9, 32.8]) in Kinshasa, 18.3% (95% CI 7.1, 39.9) in Sud-Kivu, and 0.2% (95% CI 0, 1.8) in Bas-Uele10. Two health zones were selected from each province, including one urban and one rural zone per province. Within each health zone, one general reference hospital and two health centers were selected as study sites, yielding six study sites per province and 18 study sites in total. Subjects of all ages presenting with symptoms compatible with malaria were eligible for enrollment.

Study procedures

Informed consent/assent was obtained from all study subjects prior to enrollment. Parental permission and informed consent was obtained from parents or legal guardians for all minors younger than 18 years of age, and assent was obtained from all children and adolescents 7–17 years of age. All subjects received malaria RDT testing and treatment according to DRC national guidelines. Subjects underwent a study questionnaire and finger- or heel-prick whole blood collection for diagnostic testing by RDT and microscopy and DBS collection. RDT testing was performed using the World Health Organization- (WHO-) prequalified, HRP2-based SD BIOLINE Malaria Ag P.f. (05FK50, Alere, Waltham, MA) according to manufacturer instructions. Thick-smear microscopy slides were read in the field, and thin smears fixed and transported to the National AIDS Control (PNLS) reference laboratory for confirmation and determination of parasite density. All thin smears were read by two microscopists, with discrepancies resolved by a third reader. Dried blood spot (DBS) samples (Whatmann 903 Protein Saver cards, GE Healthcare Life Sciences, Marlborough, MA) were allowed to air dry at ambient temperature in the field, and stored in individual ziplock bags with desiccant at − 20 °C prior to and after shipment to the University of North Carolina at Chapel Hill for further testing. This study was approved by the Ethical Committee of the Kinshasa School of Public Health (approval number ESP/CE/07B/2017). Analysis of de-identified samples and data was determined to constitute non-human subjects research by the UNC Institutional Review Board (study number 17-0155). The study was determined to be non-research by the Centers for Disease Control and Prevention Human Subjects office (0900f3eb81bec92c). Experiments were performed in accordance with relevant guidelines and regulations.

Pfhrp2/3 genotyping by PCR

DNA was extracted from DBS samples using Chelex and saponin18. All microscopy-positive, RDT-negative samples, in addition to an equal number of microscopy-positive, RDT-positive controls from each province were subjected to quantitative PCR (qPCR) testing targeting the single-copy P. falciparum lactate dehydrogenase (pfldh) gene19. Pfhrp2 and pfhrp3 PCR genotyping was performed as previously described13, using conventional single-step pfhrp2/3 PCR assays and a qualitative real-time PCR assay targeting the single-copy P. falciparum beta-tubulin (PfBtubulin) gene (Supplementary File)20,21,22,23. Only samples with ≥ 40 parasites/µL by qPCR (≥ tenfold higher concentration than the pfhrp2 and pfhrp3 assays’ limits of detection) were subjected to pfhrp2 and pfhrp3 PCR to reduce the risk of misclassification of deletions13. Microscopy-positive, RDT-positive controls with ≥ 40 parasites/µL by qPCR were randomly selected from the same facility for pfhrp2/3 genotyping. Samples were called pfhrp2/3-negative if they had ≥ 40 parasites/µL by pfldh qPCR, their pfhrp2 and/or pfhrp3 PCR assays were negative in duplicate, and they had successful amplification of PfBtubulin during a final confirmatory assay.

Whole-genome sequencing

All pfhrp2/3-negative samples identified during initial testing were further assessed using whole-genome sequencing. DNA from these samples was enriched for P. falciparum prior to library prep using selective whole-genome amplification (sWGA) as previously described24. In brief, two sWGA reactions were performed in parallel, one using a custom primer set designed in our lab (JP9) and another using a primer set designed by Oyola et al. (Probe_10)25. sWGA products were pooled in equal volumes and acoustically sheared using a Covaris E220 instrument prior to library preparation using the Kapa HyperPrep kit (Roche Sequencing, Pleasanton, CA). Indexed libraries were pooled and sequenced at the UNC High Throughput Sequencing Facility using the HiSeq 4000 platform (Illumina, San Diego, CA) with 150 bp, paired-end chemistry. Sequence reads were deposited into the Sequence Read Archive (BioSample accession numbers: SAMN16711875-82).

Evaluation for pfhrp2/3 deletions using whole-genome sequencing

Adapter sequences were trimmed from raw, paired sequence reads using trimmomatic and aligned to the P. falciparum 3D7 reference genome (PlasmoDB version 13.0) using bwa mem with default parameters26,27. Duplicates were marked and mate-pair information corrected using Picard Tool’s MarkDuplicates and FixMateInformation functions, respectively28. Candidate indels were identified and realigned using GATK’s RealignerTargetCreator and IndelAligner functions, respectively29. Genome coverage was calculated using bedtool’s genomecov function and visualized using ggplot2 in R (R Core Team, Vienna, Austria)30,31. Pfhrp2/3 deletions were called by visualization of aligned reads using the Integrative Genomics Viewer (Broad Institute, Cambridge, MA) and assessment of sequencing depth (the final number of reads that aligned to a specific locus) across the pfhrp2/3 genes and their flanking regions32. Variant calling was performed using the Genome Analysis Toolkit’s HaplotypeCaller29. Calls were subset to biallelic SNPs. Variant quality score recalibration was used to filter suspected false positives using the MalariaGEN P. falciparum Genetic Crosses Project (release 1.0) and Pf3k datasets (v5.1). The Fws statistic describes the relationship between within-host and population parasite heterozygosity and has been used as an index of genome-wide SNP diversity, with lower values correlated with higher multiplicity of infection, and vice versa33. Fws values were calculated using the vcfdo package to identify monoclonal infections; samples with Fws > 0.95 were considered monoclonal34.

Antigenemia assessment by Luminex

All DBS samples subjected to pfhrp2/3 genotyping by PCR were also assayed for the following Plasmodium antigens: Plasmodium genus-specific aldolase (pAldolase) and lactate dehydrogenase (pLDH), as well as P. falciparum HRP2 by a bead-based multiplex assay as previously described35. Samples were assayed at 1:20 whole-blood concentration after elution from filter paper. Thresholds for antigen positivity for the three targets were determined by assaying 92 blood samples from US resident blood donors without history of international travel and determining the lognormal mean and standard deviation of assay signal from this sample set. The lognormal mean plus three standard deviations of this sample set was used as the antigen positivity threshold (Supplementary Fig. 1).

Non-falciparum PCR assays

We used R to randomly select 1000 samples for PCR-based species identification. DNA from these samples was first subjected to a pan-Plasmodium real-time PCR assay targeting the 18S rRNA gene in duplicate36. Any sample with at least one positive pan-Plasmodium replicate was subjected to a series of four 18S rRNA real-time PCR assays specific to P. falciparum, Plasmodium malariae, Plasmodium ovale, and Plasmodium vivax in duplicate37,38,39. Species calls were only made if at least two total replicates were positive. Samples with only a single positive pan-Plasmodium replicate but negative species-specific assays were called negative. Samples in which both pan-Plasmodium replicates were positive but species-specific assays negative were subjected to a PCR assay specific to the Plasmodium knowlesi Pkr140 gene40. PCR primers and reaction conditions are described in the Supplementary File.

Data analysis

We made comparisons using the Kruskal–Wallis Rank Sum or Fisher’s exact test for categorical variables and one-way analysis of variance (ANOVA) test or the t-test for normally distributed continuous variables. Prior to statistical testing, normality was assessed by visual inspection of the frequency distributions of the raw data (histograms) for comparisons with sample sizes ≥ 30 per subgroup, and using the Lilliefors normality test for comparisons involving sample sizes < 30 per subgroup. Correlation between parasite density calculations was assessed using the Spearman’s rank-order correlation coefficient. Agreement between assays was assessed using Cohen’s kappa coefficient. Statistical analyses were performed and maps rendered using R software (version 3.6.2 and 3.6.0, respectively; R Core Team, Vienna, Austria, 2019; www.R-project.org) in RStudio (version 1.2.5033; RStudio, PBC, Boston, USA). Lilliefors test was performed using the nortest package. Maps and figures were generated using the ggplot2, sf, ggspatial, and gridExtra packages and finished in Google Slides (Alphabet, Mountain View, USA).

Disclaimer

The findings and conclusions in this report are those of the authors and do not necessarily represent the official position of the CDC.

Results

Study subjects

We enrolled 3627 subjects with symptoms compatible with malaria during November and December of the 2017 rainy season, distributed across three provinces: 1203 in Bas-Uele, 1248 in Kinshasa, and 1176 in Sud-Kivu (Fig. 1). Study sites included 18 health facilities located in 18 distinct health areas, spanning six health zones (three health areas per health zone). Baseline characteristics of and malaria diagnostic testing results from enrolled subjects are displayed in Table 1 and Supplementary Table 1. Differences in characteristics and initial malaria diagnostic testing results were observed across provinces. The majority of subjects with recorded temperature data were febrile (median temperature 38 [interquartile range 37, 39]). Study sites included facilities with high, medium, and low symptomatic malaria prevalence. RDT-positive malaria, microscopy-positive malaria, and self-reported malaria diagnosis within the past 6 months were highest in Bas-Uele and lowest in Sud-Kivu.

Figure 1
figure 1

Study sites included health facilities in eighteen health areas (triangles) in six health zones located within three provinces (n = number of facilities per province). Health areas in close proximity have overlapping points. Maps of study sites were rendered in R (R Core Team, Vienna, Austria, 2019, www.R-project.org; version 3.6.0).

Table 1 Characteristics of enrolled study subjects.

False-negative RDTs by microscopy

Among 3627 subjects tested, 1545 (42.6%) were RDT-positive and 1397 (38.7%) were microscopy-positive, with 426 (11.8%) RDT-negative but microscopy-positive (‘false-negative RDT’ by microscopy). False-negative RDT results were more likely to occur at low microscopy parasite densities, with geometric means of 959 (geometric standard deviation [SD] 4.2) and 4,675 (geom. SD 6.9) parasites/µL for RDT- versus RDT + samples, respectively (t-test p < 0.001, Fig. 2). We observed higher false-negative RDT prevalence in Kinshasa and Sud-Kivu than Bas-Uele, a pattern similar to RDT-/PCR + results we observed in our original pfhrp2 survey in asymptomatic children as part of the 2013–14 DRC DHS10. When tested by pfldh PCR, 368 (86%) of the 426 RDT-negative/microscopy-positive samples were PCR-negative, a finding consistent with false-positive microscopy calls in this cohort.

Figure 2
figure 2

Parasite densities by microscopy among HRP2-based RDT-negative (red) and RDT-positive (blue) isolates. False-negative RDT results were more likely to occur at low microscopy parasite densities, with geometric means of 959 (geometric standard deviation [SD] 4.2) and 4675 (geom. SD 6.9) parasites/µL for RDT-negative versus RDT-positive samples, respectively (t-test p < 0.001). RDT rapid diagnostic test.

Pfhrp2/3 deletion genotyping by PCR

We performed pfhrp2/3 genotyping using PCR on a subset of samples, including those collected from all 426 subjects with RDT-/microscopy + results and from 429 RDT + /microscopy + controls selected at random from the same province (Fig. 3). Among the RDT- samples, only 23 had parasite densities sufficient for pfhrp2/3 deletion genotyping by pfldh qPCR (≥ 40 parasites/µL)13. We further characterized these samples and 74 RDT-positive controls selected from the same facilities (n = 97 total) using a series of PCR assays for pfhrp2 and pfhrp3, and a final confirmatory PCR assay for PfBtubulin. Eight parasites were PCR-negative for pfhrp2 or pfhrp3 in duplicate despite having parasite densities well above the PCR assays’ limits of detection and successful amplification of a second single-copy gene, consistent with pfhrp2/3 gene deletions using conventional PCR genotyping criteria4,5,41. PCR genotyping suggested five deletions among symptomatic RDT-/microscopy + subjects (four pfhrp2−/3− and one pfhrp2−/3 +) and three among RDT + /microscopy + subjects (one pfhrp2−/3 + , one pfhrp2 + /3−, and one pfhrp2−/3−) (Supplementary Table 2). Parasite densities for these eight putative pfhrp2/3-deleted samples ranged from 84 to 102,700 parasites/µL by qPCR (median 2929, interquartile range 1314 to 4572).

Figure 3
figure 3

Sample selection for assessment of pfhrp2/3 deletions and diagnostic performance. Pf P. falciparum, Pm P. malariae, Po P. ovale, Pv P. vivax, Pk P. knowlesi.

Whole-genome sequencing of candidate pfhrp2/3 deletions

However, whole-genome sequencing (WGS) confirmed that all eight putative pfhrp2/3-deleted samples had parasites with intact pfhrp2 and pfhrp3 genes (Fig. 4). All eight samples had at least 5 aligned reads across > 80% of the genome, with median aligned reads ranging from 66–254 reads/position (Supplementary Fig. 2). Regions of reduced sequencing depth corresponded to differences in the number of histidine repeats compared to the 3D7 reference sequence and did not introduce frame-shift mutations. Mutations in PCR primer binding sites were not observed. Fws values suggested monoclonal infection in only 3 (37.5%) of the 8 samples subjected to whole-genome sequencing (Supplementary Table 3).

Figure 4
figure 4

No pfhrp2 or pfhrp3 deletions were identified by whole-genome sequencing. WGS of five pfhrp2−/3−, two pfhrp2−/3 + , and one pfhrp2 + /3− parasites originally identified by PCR confirmed intact genes. Each row represents a distinct sample: from SANHRP_01 (top) to SANHRP_08 (bottom). Depth of coverage statistics and sample characteristics are provided in Supplementary Fig. 2 and Supplementary Tables 2–3.

Antigenemia assessment using a bead-based immunoassay

Luminex-based serological assessment further confirmed that all eight pfhrp2/3-PCR-negative samples had detectable HRP2 antigenemia, providing confidence that the intact genes observed during whole-genome sequencing encoded functional HRP2 and/or P. falciparum histidine-rich protein 3 (HRP3) proteins. Background-subtracted mean fluorescence intensity (MFI) thresholds for positivity were 29, 62, and 72 for HRP2, pLDH, and pAldolase, respectively (Supplementary Figs. 1 and 3). We assessed HRP2 antigenemia in all 97 samples that had undergone pfhrp2/3 genotyping by PCR. Comparing RDT-negative versus RDT-positive samples, positivity and background-subtracted mean fluorescence intensity (MFI) was similar between groups for all three antigens tested: HRP2, Plasmodium parasite lactate dehydrogenase (pLDH), and Plasmodium parasite aldolase (pAldolase) (Table 2). Surprisingly, the majority of all RDT- samples tested had high levels of circulating HRP2 detected by Luminex, suggesting that the negative RDT results were likely due to operator error or RDT failure (Fig. 5, Supplementary Fig. 3).

Table 2 Plasmodium antigen immunoassay results.
Figure 5
figure 5

False-negative RDT results occurred in the setting of high HRP2 antigenemia. A Luminex bead-based immunoassay for three parasite antigens confirmed circulating HRP2 antigen in the majority of RDT-negative but PCR-positive/microscopy-positive isolates tested (RDT-negative). RDT-positive controls selected from the same facility are included for comparison. One pLDH value with background-subtracted MFI < 0 is not depicted. Log-transformed plots are provided in Supplementary Fig. 3. HRP2 P. falciparum histidine-rich protein 2, pAldolase Plasmodium aldolase, pLDH Plasmodium lactate dehydrogenase.

Non-falciparum malaria

Non-falciparum malaria is expected to cause HRP2-RDT-negative/microscopy-positive results and was common in our study cohort. Among 1000 randomly selected samples that underwent species identification using a series of real-time PCR assays (Fig. 3), malaria was confirmed by PCR in 56.8% of samples, and non-falciparum co-infection with P. falciparum was common (13.2%, n = 75) (Table 3). However, only 1.9% (n = 11) of symptomatic cases were due to non-falciparum infections alone. P. ovale was observed in 11.2% (n = 64) of Plasmodium-PCR-positive symptomatic cases. Among the four (0.8%) symptomatic cases involving P. vivax, half involved P. falciparum and all were low density (< 5 parasites/µL by semi-quantitative 18S rRNA PCR). The majority of symptomatic P. malariae infections (86.9%, n = 20/23) occurred as part of mixed infections with P. falciparum (Supplementary Fig. 4). We were unable to determine the species in 19 samples that were positive by the pan-species 18S PCR assay in duplicate; all had negative P. knowlesi PCR results.

Table 3 Species identification by PCR among subjects with symptomatic malaria.

RDT performance

Assessment of RDT performance versus PCR suggested that false-negative RDT results in our cohort were commonly caused by RDT failure or operator error rather than parasite factors. Among the random subset of 1000 samples that underwent 18S rRNA testing for all species, 134 (24.9%) of 538 P. falciparum 18S rRNA real-time PCR-positive samples were RDT-negative. RDT performance varied by province, with a larger proportion of RDT-/PCR + results in provinces with higher P. falciparum prevalence by 18S rRNA PCR: Bas-Uele (19%), followed by Sud-Kivu (17%), and finally Kinshasa (5%) (Supplementary Table 4). Only a small proportion of samples (3.6%, n = 36) were RDT + /PCR−, a finding not unexpected and suggestive of persistent PfHRP2 antigenemia after recent clearance of parasitemia42. When compared to PCR, RDTs were 75% sensitive and 92% specific, with good agreement (Cohen’s kappa = 0.66). Microscopy was 53% sensitive and 81% specific, with fair agreement with PCR (Cohen’s kappa = 0.33). Parasite densities as determined by microscopy and pfldh qPCR had moderate correlation (Spearman correlation coefficient = 0.63, p < 0.001, Supplementary Fig. 5).

Discussion

We did not observe symptomatic malaria due to pfhrp2- or pfhrp3-deleted P. falciparum in this large, cross-sectional survey across three geographically disparate DRC provinces. The majority of RDT-negative/microscopy-positive results occurred in the setting of low or absent parasitemia. This finding implicates parasite densities below the RDT’s limit of detection and false-positive microscopy results as the primary causes of RDT-microscopy discordance in the present study. Further assessment of RDT performance using microscopy, genus- and species-specific real-time PCR assays, and Luminex-based antigenemia assessment confirmed that RDT failure and/or user error also caused false-negative RDTs in the present study. However, the overall performance of HRP2-based RDTs was superior to microscopy and in good agreement with PCR.

These findings support continued use of HRP2-based RDTs in the DRC. They also contrast with the results of our prior study of asymptomatic children enrolled in the 2013–2014 DHS. There are several possible explanations for these differences. The present study enrolled symptomatic subjects in order to directly inform policy decisions about malaria case management. This study design could have inhibited our ability to identify pfhrp2/3-deleted parasites. We and others have proposed the hypothesis that parasites with deletions of the pfhrp2 and/or pfhrp3 genes and their flanking regions may be less fit6,10,43, and less likely to cause symptomatic disease. Direct assessment of this hypothesis has not yet been performed in vivo or in vitro, to our knowledge, and is limited by the challenges of confirming deletions in low parasite density infections. However, genetic cross experiments of the 3D7 (wild-type), DD2 (pfhrp2-deleted), and HB3 (pfhrp3-deleted) lab strains did not provide definitive evidence of a fitness cost associated with deletion of either gene44,45. In addition, reports from Eritrea confirm that pfhrp2/3-deleted parasites can cause symptomatic and sometimes severe disease8.

Exhaustive analysis of putative pfhrp2/3-deleted parasites was needed to discern the status of both genes. The use of rigorous parasite density thresholds well above the downstream pfhrp2/3 PCR assays’ limit of detection13, confirmation of successful amplification of multiple single-copy genes, and adherence to commonly accepted criteria5 reduced the risk of inappropriate pfhrp2/3 deletion calls. Only five of 426 (1.2%) RDT-negative/microscopy-positive samples were identified as putative pfhrp2/3 deletions during initial testing. However, we subsequently confirmed HRP2 antigenemia and intact pfhrp2 and pfhrp3 genes in all eight pfhrp2/3-PCR-negative samples using highly sensitive antigen detection methods and WGS, respectively. Pfhrp2/3 sequence variation and resulting changes in the structure of the HRP2 and HRP3 proteins could yield a negative RDT but positive Luminex result, or vice versa, due to differences in the anti-HRP2 monoclonal antibodies employed by both assays. However, previous evaluation of diverse P. falciparum strains failed to identify an association between pfhrp2/3 sequence variation and RDT sensitivity46. Taken together, Luminex and WGS results confirmed that the putative pfhrp2/3-deleted parasites were misclassified during initial PCR testing.

These findings emphasize the challenges of confirming pfhrp2/3 gene deletions and support the argument that a portion of pfhrp2/3 deletion calls in our original study of asymptomatic children in the DRC resulted from experimental artifact10,11. Even complex laboratory workflows conducted in accordance with commonly used deletion classification criteria are not always sufficient to eliminate the risk of misclassification of pfhrp2/3 deletions. The use of advanced serological and next-generation sequencing methods improved the quality of our pfhrp2/3 deletion assessment, allowed for a more robust evaluation of RDT performance, and enabled visualization of the genetic structure of the pfhrp2 and pfhrp3 genes and their flanking regions. While these methodologies are not widely available in resource-limited settings, they are now accessible through a network of laboratories that collaborate with the World Health Organization to support pfhrp2/3 deletion surveillance47 and in select locales in sub-Saharan Africa with advanced laboratory capacity.

Symptomatic malaria due to non-falciparum species was common but usually occurred as part of mixed infections with P. falciparum. Although non-falciparum species are not detected by widely deployed HRP2-based RDTs, co-infection with P. falciparum is expected to trigger a positive RDT result and prompt treatment with artemisinin-combination therapy according to current DRC guidelines. Therefore, complications due to untreated symptomatic, non-falciparum malaria are likely uncommon, although the risk of relapse by P. vivax or P. ovale without proper diagnosis and terminal prophylaxis remains. Our findings are generally in-line with prior reports of non-falciparum infection among asymptomatic subjects in the DRC48,49,50.

Strengths of this study include its geographically diverse sampling locations, robust pipeline of conventional and advanced laboratory methodologies, and relevance to malaria case management. Indeed, these findings directly informed the DRC national malaria control program’s decision to continue the use of HRP2-based RDTs, despite evidence of pfhrp2-negative parasites from our initial study of asymptomatic subjects. Our experience in the DRC confirms the importance of basing policy decisions on careful studies of the target population—individuals presenting to health facilities with symptomatic malaria—rather than convenience sampling determined by sample availability or access to study sites.

Limitations include our inability to discriminate pfhrp2/3-deleted from pfhrp2/3-intact strains in individuals infected by multiple P. falciparum strains. Neither the conventional methods nor the advanced Luminex-based HRP2 antigenemia assessment and WGS methods employed here are well-suited to identify gene deletions in mixed infections. Indeed, assessment of whole-genome sequencing data confirmed mono-infection in only three of eight samples tested. We therefore cannot exclude the possibility that the five remaining samples included mixed infection that involved pfhrp2/3-deleted strains. Recently developed multiplexed qPCR methods51 and amplicon-based deep sequencing approaches52 have potential to elucidate pfhrp2/3-deleted minor variants in future large-scale surveys. Second, we restricted our pfhrp2/3 deletion analysis to samples with ≥ 40 parasites/µL. This requirement was necessary to reduce the risk of misclassification due to DNA concentrations below the pfhrp2/3 PCR assays’ limits of detection13, but it prevents us from commenting on the prevalence of deletions in lower density infections. Third, enrollment occurred primarily in the rainy season, with only limited dry season enrollment near the end of the study in Bas-Uele. A modeling study predicts that pfhrp2/3-deleted parasite prevalence may be underestimated during the rainy season, when individuals are more likely to be infected by multiple parasite strains53. Fourth, we could not evaluate associations between specific symptoms or temperature and RDT performance, as this data was only available for a subset of subjects. Finally, this study was restricted to three provinces. These provinces spanned a range of malaria prevalences, but they do not capture the full diversity of the DRC, which is Africa’s second largest country by land mass and neighbors nine other countries.

In conclusion, ongoing HRP2-based RDT use is appropriate in the DRC. False-negative RDT results due to pfhrp2/3 deletions were not observed among symptomatic subjects. Most false-negative results in the DRC are likely due to low parasite densities, RDT failure, or operator error. Only a minority of non-falciparum malaria cases would be missed by an HRP2-based RDT testing strategy; co-infection with P. falciparum and non-falciparum species was common. Careful laboratory workflows are required during pfhrp2/3 gene deletion analyses. Advanced serological and next-generation sequencing approaches can be used to improve the rigor and reproducibility of pfhrp2/3 deletion surveillance efforts and to inform malaria diagnostic testing policy.