scholarly journals Transcriptome profiling ofPlasmodium vivaxinSaimirimonkeys identifies potential ligands for invasion

2019 ◽  
Vol 116 (14) ◽  
pp. 7053-7061 ◽  
Author(s):  
Karthigayan Gunalan ◽  
Juliana M. Sá ◽  
Roberto R. Moraes Barros ◽  
Sarah L. Anzick ◽  
Ramoncito L. Caleon ◽  
...  
Keyword(s):  
Surface Protein ◽  
Transcriptome Profiling ◽  
Merozoite Surface Protein ◽  
Blood Group Antigen ◽  
Sub Saharan Africa ◽  
Duffy Binding Protein ◽  
Duffy Antigen ◽  
Rnaseq Data ◽  
Sub Saharan ◽  
Duffy Negative

Unlike the case in Asia and Latin America,Plasmodium vivaxinfections are rare in sub-Saharan Africa due to the absence of the Duffy blood group antigen (Duffy antigen), the only known erythrocyte receptor for theP. vivaxmerozoite invasion ligand, Duffy binding protein 1 (DBP1). However,P. vivaxinfections have been documented in Duffy-negative individuals throughout Africa, suggesting thatP. vivaxmay use ligands other than DBP1 to invade Duffy-negative erythrocytes through other receptors. To identify potentialP. vivaxligands, we compared parasite gene expression inSaimiriandAotusmonkey erythrocytes infected withP. vivaxSalvador I (Sal I). DBP1 bindsAotusbut does not bind toSaimirierythrocytes; thus,P. vivaxSal I must invadeSaimirierythrocytes independent of DBP1. Comparing RNA sequencing (RNAseq) data for late-stage infections inSaimiriandAotuserythrocytes when invasion ligands are expressed, we identified genes that belong to tryptophan-rich antigen and merozoite surface protein 3 (MSP3) families that were more abundantly expressed inSaimiriinfections compared withAotusinfections. These genes may encode potential ligands responsible forP. vivaxinfections of Duffy-negative Africans.

scholarly journals Plasmodium vivax from Duffy-Negative and Duffy-Positive Individuals Shares Similar Gene Pool in East Africa

2021 ◽  
Author(s):  
Daniel Kepple ◽  
Alfred Hubbard ◽  
Musab M Ali ◽  
Beka R Abargero ◽  
Karen Lopez ◽  
...  
Keyword(s):  
Plasmodium Vivax ◽  
East Africa ◽  
Sub Saharan Africa ◽  
Road Density ◽  
Genetic Characteristics ◽  
Plasmodium Vivax Malaria ◽  
Genetic Clusters ◽  
Sub Saharan ◽  
The Impact ◽  
Duffy Negative

Abstract Plasmodium vivax malaria was thought to be rare in Africa, but an increasing number of P. vivax cases reported across Africa and in Duffy-negative individuals challenges this conventional dogma. The genetic characteristics of P. vivax in Duffy-negative infections, the transmission of P. vivax in East Africa, and the impact of environments on transmission remain largely unknown. This study examined genetic and transmission features of P. vivax from 107 Duffy-negative and 305 Duffy-positive individuals in Ethiopia and Sudan. No clear genetic differentiation was found in P. vivax between the two Duffy groups, indicating between-host transmission. P. vivax from Ethiopia and Sudan showed similar genetic clusters, except samples from Khartoum, possibly due to distance and road density that inhibited parasite gene flow. This study is the first to show that P. vivax can transmit to and from Duffy-negative individuals and provides critical insights into the spread of P. vivax in sub-Saharan Africa.

scholarly journals Presence of additional P. vivax malaria in Duffy negative individuals from Southwestern Nigeria: Short Report

2020 ◽  
Author(s):  
MARY Aigbiremo OBOH ◽  
Upasana Shyamsunder Singh ◽  
Daouda Ndiaye ◽  
Aida Sadikh Badiane ◽  
Nazia Anwar Ali ◽  
...  
Keyword(s):  
Vivax Malaria ◽  
National Level ◽  
Sub Saharan Africa ◽  
Diagnostic Tools ◽  
Short Report ◽  
Southwestern Nigeria ◽  
Malaria Epidemiology ◽  
High Prevalence ◽  
Sub Saharan ◽  
Duffy Negative

Abstract Background Malaria in sub-Saharan Africa (sSA) is thought to be hugely caused by Plasmodium falciparum . Recently, growing reports of cases due to P. ovale , P. malariae , and P. vivax have been significantly reported to play a role in malaria epidemiology in sSA. This in fact is due to the usage of very sensitive diagnostic tools (e.g. PCR) which have highlighted the underestimation of non-falciparum malaria in this sub-region. P. vivax was historically thought to be absent in sSA due to the high prevalence of the Duffy null antigen in individuals residing in this sub-continent. For example, recent studies reporting the detection of vivax malaria in Duffy-negative individuals from Mali, Mauritania, Cameroon to mention a few challenges this notion.Methods Following our earlier report of P. vivax in Duffy-negative individuals, we have collected and assessed RDT and/or microscope malaria positive samples following the conventional PCR method and DNA sequencing to confirm both single/mixed infections as well as the Duffy status of the individuals.Results Amplification of Plasmodium gDNA was possible in 59.9% (145/242) of the evaluated isolates and as expected P. falciparum was the most predominant (91.7%) species identified. Interestingly, four P. vivax isolates were identified either as single (3) or mixed (1 – P. falciparum / P. vivax ) infection. Sequencing results confirmed, all vivax isolates as truly vivax malaria and their Duffy status to be that of the Duffy-negative genotype.Conclusion Identification of more vivax isolates among these Duffy-negative individuals from Nigeria, substantiate the expanding body of evidence on the ability of P. vivax to infect RBCs that do not express the DARC gene. Hence, such genetic-epidemiological study should be conducted at the national level in order to evaluate the actual burden of P. vivax in the country.

scholarly journals The Epidemiology of Plasmodium vivax Among Adults in the Democratic Republic of the Congo: A Nationally-Representative, Cross-Sectional Survey

2020 ◽  
Author(s):  
Nicholas F. Brazeau ◽  
Cedar L. Mitchell ◽  
Andrew P. Morgan ◽  
Molly Deutsch-Feldman ◽  
Oliver John Watson ◽  
...  
Keyword(s):  
Risk Factors ◽  
Democratic Republic ◽  
Sub Saharan Africa ◽  
Mitochondrial Genomes ◽  
Republic Of The Congo ◽  
Nationally Representative ◽  
Sub Saharan ◽  
Duffy Negative ◽  
Malaria Risk Factors ◽  
Population Genetic Analyses

ABSTRACTBackgroundReports of P. vivax infections among Duffy-negative hosts have begun to accumulate throughout sub-Saharan Africa. Despite this growing body of evidence, no nationally representative epidemiological surveys of P. vivax in sub-Saharan Africa nor population genetic analyses to determine the source of these infections have been performed.MethodsTo overcome this critical gap in knowledge, we screened nearly 18,000 adults in the Democratic Republic of the Congo (DRC) for P. vivax using samples from the 2013-2014 Demographic Health Survey. Infections were identified by quantitative PCR and confirmed with nested-PCR. P. vivax mitochondrial genomes were constructed after short-read sequencing. Risk factors, spatial distributions and population genetic analyses were explored.FindingsOverall, we found a 2.96% (95% CI: 2.28%, 3.65%) prevalence of P. vivax infections across the DRC. Nearly all infections were among Duffy-negative adults (486/489). Infections were not associated with typical malaria risk-factors and demonstrated small-scale heterogeneity in prevalence across space. Mitochondrial genomes suggested that DRC P. vivax is an older clade that shares its most recent common ancestor with South American isolates.InterpretationP. vivax is more prevalent across the DRC than previously believed despite widespread Duffy-negativity. Comparison to global and historical P. vivax sequences suggests that historic DRC P. vivax may have been transported to the New World on the wave of European expansion. Our findings suggest congolese P. vivax is an innocuous threat given its relatively flat distribution across space, lack of malaria risk factors, and potentially ancestral lineage.FundingNational Institutes of Health and the Wellcome Trust.

Functional Role of the Chemokine Binding Duffy Antigen Receptor Complex (DARC) in Human Inflammation In Vivo.

Blood ◽  
2006 ◽  
Vol 108 (11) ◽  
pp. 20-20
Author(s):  
Florian B. Mayr ◽  
Petra Jilma-Stohlawetz ◽  
Christa Firbas ◽  
Anthony F. Suffredini ◽  
Hartmut Derendorf ◽  
...  
Keyword(s):  
Inflammatory Response ◽  
Functional Role ◽  
Blood Group Antigen ◽  
Receptor Complex ◽  
Human Endotoxemia ◽  
Time Points ◽  
Duffy Antigen ◽  
Duffy Negative

Abstract Background: The Duffy receptor is a promiscuous receptor for chemokines that binds selected members of both the C-X-C and C-C families with high affinity. Duffy antigen may influence plasma levels of proinflammatory cytokines by acting as a “chemokine sink”. Additionally, Duffy knockout mice experienced an exaggerated response to endotoxin in comparison to wild-type mice. The current trial was designed to elucidate the functional role of the Duffy blood group antigen in human inflammation. We hypothesized that “Duffy negative“ volunteers might show an increased inflammatory response to endotoxin (LPS) infusion in terms of cytokine response. The human endotoxemia model is a well established model of systemic inflammation, where a well defined, self-limited inflammatory stimulus permits the elucidation of key players involved in the inflammatory response. We therefore used this model to investigate the functional role of the Duffy Antigen Receptor Complex (DARC) in the inflammatory response after endotoxin challenge. Methods: Thirty-two healthy male volunteers received an intravenous infusion of 2ng/kg endotoxin, 16 Caucasians (Duffy antigen positive on erythrocytes) and 16 subjects of African descent (“Duffy negatives”). Cytokines, chemokines, as well as their receptors were quantified by ELISA, RT-PCR and FACS. Results: Plasma levels of TNF, IL-6, IL-8 and IL-8 mRNA in whole blood increased to a similar extent in both groups after LPS infusion. In contrast, peak MCP-1 levels at 3 hours were roughly 2-fold higher in Duffy positive subjects 16ng/mL as compared to Duffy negative subjects (7ng/mL p<0.001). Similarly, GRO-alpha levels were 2.5-fold higher in Duffy positive subjects at 2 hours after LPS infusion (210pg/mL vs 85pg/mL; p= 0.0001), whereas baseline values showed no difference between both groups. There was no difference in the LPS induced release of MIP-1 beta (which was used as a negative control). Baseline levels of MCP-1 and GRO-alpha in erythrocyte lysates were significantly higher in Duffy positive individuals, whereas IL-8 and MIP-1beta levels were comparable between both groups. Values of MCP-1 and GRO-α, both known to bind to the Duffy antigen, increased extensively in erythrocyte lysates of Duffy positive subjects over time (P=<0.001 vs. time). In contrast, MCP-1 only moderately changed over time in Duffy negative subjects (P<0.03 vs. time), whereas GRO-alpha remained comparable to baseline at all time points (P=0.2 vs. time). As a consequence, MCP-1 and GRO-alpha were several hundred-fold higher in Duffy positive subjects at all time points and reached peak levels at 2–4 hours. Additionally, IL-8, which also binds to erythrocytes via the Duffy antigen, was roughly 7-fold higher in erythrocyte lysates of Duffy positive subjects 2 hours after LPS infusion. As expected, MIP-1beta remained similar at all time points and was comparable between both groups. The expected increase in CD11b, and decrease in CCR-2 and CXCR-1, CXCR-2 occurred without differences between groups. Conclusion: This study characterized for the first time the in vivo function of the Duffy Antigen in humans. The blood group antigen has a profound effect on erythrocyte-bound chemokines and free chemokines in a model of human endotoxemia.

scholarly journals Role ofPlasmodium vivaxDuffy-binding protein 1 in invasion of Duffy-null Africans

2016 ◽  
Vol 113 (22) ◽  
pp. 6271-6276 ◽  
Author(s):  
Karthigayan Gunalan ◽  
Eugenia Lo ◽  
Jessica B. Hostetler ◽  
Delenasaw Yewhalaw ◽  
Jianbing Mu ◽  
...  
Keyword(s):  
Blood Group ◽  
Malaria Parasite ◽  
Binding Protein ◽  
Squirrel Monkeys ◽  
Blood Group Antigen ◽  
Affinity Binding ◽  
Duffy Binding Protein ◽  
Duffy Blood Group ◽  
Duffy Antigen ◽  
The World

The ability of the malaria parasitePlasmodium vivaxto invade erythrocytes is dependent on the expression of the Duffy blood group antigen on erythrocytes. Consequently, Africans who are null for the Duffy antigen are not susceptible toP. vivaxinfections. Recently,P. vivaxinfections in Duffy-null Africans have been documented, raising the possibility thatP. vivax, a virulent pathogen in other parts of the world, may expand malarial disease in Africa.P. vivaxbinds the Duffy blood group antigen through its Duffy-binding protein 1 (DBP1). To determine if mutations in DBP1 resulted in the ability ofP. vivaxto bind Duffy-null erythrocytes, we analyzedP. vivaxparasites obtained from two Duffy-null individuals living in Ethiopia where Duffy-null and -positive Africans live side-by-side. We determined that, although the DBP1s from these parasites contained unique sequences, they failed to bind Duffy-null erythrocytes, indicating that mutations in DBP1 did not account for the ability ofP. vivaxto infect Duffy-null Africans. However, an unusual DNA expansion of DBP1 (three and eight copies) in the two Duffy-nullP. vivaxinfections suggests that an expansion of DBP1 may have been selected to allow low-affinity binding to another receptor on Duffy-null erythrocytes. Indeed, we show that Salvador (Sal) IP. vivaxinfects Squirrel monkeys independently of DBP1 binding to Squirrel monkey erythrocytes. We conclude thatP. vivaxSal I and perhapsP. vivaxin Duffy-null patients may have adapted to use new ligand–receptor pairs for invasion.

scholarly journals Genomic Analysis of Plasmodium vivax in Southern Ethiopia Reveals Selective Pressures in Multiple Parasite Mechanisms

2019 ◽  
Vol 220 (11) ◽  
pp. 1738-1749 ◽  
Author(s):  
Sarah Auburn ◽  
Sisay Getachew ◽  
Richard D Pearson ◽  
Roberto Amato ◽  
Olivo Miotto ◽  
...  
Keyword(s):  
Plasmodium Vivax ◽  
Regulation Of Gene Expression ◽  
Genomic Analysis ◽  
Sub Saharan Africa ◽  
Chloroquine Resistance ◽  
Southern Ethiopia ◽  
Chloroquine Resistance Transporter ◽  
Negative Trait ◽  
Sub Saharan ◽  
Duffy Negative

Abstract The Horn of Africa harbors the largest reservoir of Plasmodium vivax in the continent. Most of sub-Saharan Africa has remained relatively vivax-free due to a high prevalence of the human Duffy-negative trait, but the emergence of strains able to invade Duffy-negative reticulocytes poses a major public health threat. We undertook the first population genomic investigation of P. vivax from the region, comparing the genomes of 24 Ethiopian isolates against data from Southeast Asia to identify important local adaptions. The prevalence of the Duffy binding protein amplification in Ethiopia was 79%, potentially reflecting adaptation to Duffy negativity. There was also evidence of selection in a region upstream of the chloroquine resistance transporter, a putative chloroquine-resistance determinant. Strong signals of selection were observed in genes involved in immune evasion and regulation of gene expression, highlighting the need for a multifaceted intervention approach to combat P. vivax in the region.

scholarly journals Presence of additional P. vivax malaria in Duffy negative individuals from Southwestern Nigeria

2019 ◽  
Author(s):  
Mary Aigbiremo Oboh ◽  
Upasana Shyamsunder Singh ◽  
Daouda Nidaye ◽  
Aida S. Badiane ◽  
Anwar Ali ◽  
...  
Keyword(s):  
Plasmodium Falciparum ◽  
Vivax Malaria ◽  
National Level ◽  
Sub Saharan Africa ◽  
Mixed Infections ◽  
Southwestern Nigeria ◽  
High Prevalence ◽  
Pcr Method ◽  
Sub Saharan ◽  
Duffy Negative

AbstractMalaria in sub-Saharan Africa (sSA) is thought to be hugely caused by Plasmodium falciparum and very infrequently by P. ovale, P. malariae, with P. vivax not even being considered to be of any significant role. However, with the availability of very sensitive diagnostic tool, it has become more clear that, the percentage of non-falciparum malaria in this sub-region has been underestimated. P. vivax was historically thought to be absent in sSA due to the high prevalence of the Duffy null antigen in individuals residing here. Nevertheless, recent studies reporting the detection of vivax malaria in Duffy-negative individuals challenges this notion. Following our earlier report of P. vivax in Duffy-negative individuals, we have re-assessed all previous samples following the classical PCR method and sequencing to confirm both single/mixed infections as well as the Duffy status of the individuals.Interestingly, fifteen additional Plasmodium infections were detected, representing 5.9% in prevalence from our earlier work. In addition, P. vivax represents 26.7% (4/15) of the new isolates collected in Nigeria. Sequencing results confirmed, all vivax isolates as truly vivax malaria and their Duffy status to be that of the Duffy-negative genotype. The identification of more vivax isolates among these Duffy-negative individuals from Nigeria, substantiate the expanding body of evidence of the ability of P. vivax to infect RBCs that do not express the DARC gene. Hence, such geno-epidemiological study should be conducted at the national level in order to evaluate the actual burden of P. vivax in the country.

scholarly journals Genetic polymorphism of the N-terminal region in circumsporozoite surface protein of Plasmodium falciparum field isolates from Sudan

2019 ◽  
Vol 18 (1) ◽  
Author(s):  
Nouh S. Mohamed ◽  
Musab M. Ali Albsheer ◽  
Hanadi Abdelbagi ◽  
Emanuel E. Siddig ◽  
Mona A. Mohamed ◽  
...  
Keyword(s):  
Genetic Diversity ◽  
Plasmodium Falciparum ◽  
Balancing Selection ◽  
Pcr Amplification ◽  
Surface Protein ◽  
Merozoite Surface Protein ◽  
Molecular Study ◽  
Terminal Region ◽  
Sub Saharan Africa ◽  
Cross Sectional

Abstract Background Malaria caused by Plasmodium falciparum parasite is still known to be one of the most significant public health problems in sub-Saharan Africa. Genetic diversity of the Sudanese P. falciparum based on the diversity in the circumsporozoite surface protein (PfCSP) has not been previously studied. Therefore, this study aimed to investigate the genetic diversity of the N-terminal region of the pfcsp gene. Methods A cross-sectional molecular study was conducted; 50 blood samples have been analysed from different regions in Sudan. Patients were recruited from the health facilities of Khartoum, New Halfa, Red Sea, White Nile, Al Qadarif, Gezira, River Nile, and Ad Damazin during malaria transmission seasons between June to October and December to February 2017–2018. Microscopic and nested PCR was performed for detection of P. falciparum. Merozoite surface protein-1 was performed to differentiate single and multiple clonal infections. The N-terminal of the pfcsp gene has been sequenced using PCR-Sanger dideoxy method and analysed to sequences polymorphism including the numbers of haplotypes (H), segregating sites (S), haplotypes diversity (Hd) and the average number of nucleotide differences between two sequences (Pi) were obtained using the software DnaSP v5.10. As well as neutrality testing, Tajima’s D test, Fu and Li’s D and F statistics. Results PCR amplification resulted in 1200 bp of the pfcsp gene. Only 21 PCR products were successfully sequenced while 29 were presenting multiple clonal P. falciparum parasite were not sequenced. The analysis of the N-terminal region of the PfCSP amino acids sequence compared to the reference strains showed five different haplotypes. H1 consisted of 3D7, NF54, HB3 and 13 isolates of the Sudanese pfcsp. H2 comprised of 7G8, Dd2, MAD20, RO33, Wellcome strain, and 5 isolates of the Sudanese pfcsp. H3, H4, and H5 were found in 3 distinct isolates. Hd was 0.594 ± 0.065, and S was 12. The most common polymorphic site was A98G; other sites were D82Y, N83H, N83M, K85L, L86F, R87L, R87F, and A98S. Fu and Li’s D* test value was − 2.70818, Fu and Li’s F* test value was − 2.83907, indicating a role of negative balancing selection in the pfcsp N-terminal region. Analysis with the global pfcsp N-terminal regions showed the presence of 13 haplotypes. Haplotypes frequencies were 79.4%, 17.0%, 1.6% and 1.0% for H1, H2, H3 and H4, respectively. Remaining haplotypes frequency was 0.1% for each. Hd was 0.340 ± 0.017 with a Pi of 0.00485, S was 18 sites, and Pi was 0.00030. Amino acid polymorphisms identified in the N-terminal region of global pfcsp were present at eight positions (D82Y, N83H/M, K85L/T/N, L86F, R87L/F, A98G/V/S, D99G, and G100D). Conclusions Sudanese pfcsp N-terminal region was well-conserved with only a few polymorphic sites. Geographical distribution of genetic diversity showed high similarity to the African isolates, and this will help and contribute in the deployment of RTS,S, a PfCSP-based vaccine, in Sudan.

scholarly journals Whole Genome Sequencing of Plasmodium vivax Isolates Reveals Frequent Sequence and Structural Polymorphisms in Erythrocyte Binding Genes

2020 ◽  
Author(s):  
Anthony Ford ◽  
Daniel Kepple ◽  
Beka Raya Abagero ◽  
Jordan Connors ◽  
Richard Pearson ◽  
...  
Keyword(s):  
Plasmodium Vivax ◽  
Copy Number ◽  
Binding Protein ◽  
Surface Protein ◽  
Merozoite Surface Protein ◽  
Whole Genome ◽  
Single Nucleotide ◽  
Geographical Scale ◽  
Erythrocyte Binding ◽  
Duffy Negative

AbstractPlasmodium vivax malaria is much less common in Africa than the rest of the world because the parasite relies primarily on the Duffy antigen/chemokine receptor (DARC) to invade human erythrocytes, and the majority of Africans are Duffy negative. Recently, there has been a dramatic increase in the reporting of P. vivax cases in Africa, with a high number of them being in Duffy negative individuals, potentially indicating P. vivax has evolved an alternative invasion mechanism that can overcome Duffy negativity. Here, we analyzed single nucleotide polymorphism (SNP) and copy number variation (CNV) in Whole Genome Sequence (WGS) data from 44 P. vivax samples isolated from symptomatic malaria patients in southwestern Ethiopia, where both Duffy positive and Duffy negative individuals are found. A total of 236,351 SNPs were detected, of which 21.9% was nonsynonymous and 78.1% was synonymous mutations. The largest number of SNPs were detected on chromosomes 9 (33,478 SNPs; 14% of total) and 10 (28,133 SNPs; 11.9%). There were particularly high levels of polymorphism in erythrocyte binding gene candidates including reticulocyte binding protein 2c (RBP2c), merozoite surface protein 1 (MSP1), and merozoite surface protein 3 (MSP3.5, MSP3.85 and MSP3.9). Thirteen genes related to immunogenicity and erythrocyte binding function were detected with significant signals of positive selection. Variation in gene copy number was also concentrated in genes involved in host-parasite interactions, including the expansion of the Duffy binding protein gene (PvDBP) on chromosome 6 and several PIR genes. Based on the phylogeny constructed from the whole genome sequences, the expansion of these genes was an independent process among the P. vivax lineages in Ethiopia. We further inferred transmission patterns of P. vivax infections among study sites and showed various levels of gene flow at a small geographical scale. The genomic features of P. vivax provided baseline data for future comparison with those in Duffy-negative individuals, and allowed us to develop a panel of informative Single Nucleotide Polymorphic markers diagnostic at a micro-geographical scale.

scholarly journals Plasmodium vivax and Plasmodium ovale in the Malaria Elimination Agenda in Africa

2021 ◽  
Author(s):  
Isaac K. Quaye ◽  
Larysa Aleksenko
Keyword(s):  
Plasmodium Falciparum ◽  
Plasmodium Vivax ◽  
Malaria Elimination ◽  
Sub Saharan Africa ◽  
Roll Back Malaria ◽  
Plasmodium Ovale ◽  
Sub Saharan ◽  
Roll Back ◽  
Duffy Negative ◽  
A Current

In recent times, several countries in sub-Saharan Africa have reported cases of Plasmodium vivax (Pv) with a considerable number being Duffy negative. Current efforts at malaria elimination are focused solely on Plasmodium falciparum (Pf) excluding non-falciparum malaria. Pv and Plasmodium ovale (Po) have hypnozoite forms that can serve as reservoirs of infection and sustain transmission. The burden of these parasites in Africa seems to be more than acknowledged, playing roles in migrant and autochthonous infections. Considering that elimination and eradication is a current aim for WHO and Roll Back Malaria (RBM), the inclusion of Pv and Po in the elimination agenda cannot be over-emphasized. The biology of Pv and Po are such that the same elimination strategies as are used for Pf cannot be applied so, going forward, new approaches will be required to attain elimination and eradication targets.

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