Search

Your search keyword '"Wiegand, Roger"' showing total 19 results
Start Over Author "Wiegand, Roger" Database OAIster
19 results on '"Wiegand, Roger"'

1. Seeking diagnostic and prognostic biomarkers for childhood bacterial pneumonia in sub-Saharan Africa: study protocol for an observational study

Author

CTI Research, MS Dermatologie/Allergologie, Infection & Immunity, CTI, Valim, Clarissa, Olatunji, Yekin Ajauoi, Isa, Yasir Shitu, Salaudeen, Rasheed, Golam, Sarwar, Knol, Edward F, Kanyi, Sheriffo, Jammeh, Abdoulie, Bassat, Quique, de Jager, Wilco, Diaz, Alejandro A, Wiegand, Roger C, Ramirez, Julio, Moses, Marsha A, D'Alessandro, Umberto, Hibberd, Patricia L, Mackenzie, Grant A, CTI Research, MS Dermatologie/Allergologie, Infection & Immunity, CTI, Valim, Clarissa, Olatunji, Yekin Ajauoi, Isa, Yasir Shitu, Salaudeen, Rasheed, Golam, Sarwar, Knol, Edward F, Kanyi, Sheriffo, Jammeh, Abdoulie, Bassat, Quique, de Jager, Wilco, Diaz, Alejandro A, Wiegand, Roger C, Ramirez, Julio, Moses, Marsha A, D'Alessandro, Umberto, Hibberd, Patricia L, and Mackenzie, Grant A

Published
2021

2. SNP Genotyping Defines Complex Gene-Flow Boundaries Among African Malaria Vector Mosquitoes

Author

Massachusetts Institute of Technology. Department of Biology, Neafsey, Daniel, Johnson, Charles, Wiegand, Roger, Lander, Eric Steven, Wirth, Dyann, Muskavitch, Marc, Lawniczak, M. K. N., Park, D. J., Redmond, S. N., Coulibaly, M. B., Traore, S. F., Sagnon, N., Costantini, C., Collins, F. H., Kafatos, F. C., Besansky, N. J., Christophides, G. K., Neafsey, Daniel E., Johnson, Charles A., Wiegand, Roger C., Wirth, Dyann F., Massachusetts Institute of Technology. Department of Biology, Neafsey, Daniel, Johnson, Charles, Wiegand, Roger, Lander, Eric Steven, Wirth, Dyann, Muskavitch, Marc, Lawniczak, M. K. N., Park, D. J., Redmond, S. N., Coulibaly, M. B., Traore, S. F., Sagnon, N., Costantini, C., Collins, F. H., Kafatos, F. C., Besansky, N. J., Christophides, G. K., Neafsey, Daniel E., Johnson, Charles A., Wiegand, Roger C., and Wirth, Dyann F.

Abstract

Mosquitoes in the Anopheles gambiae complex show rapid ecological and behavioral diversification, traits that promote malaria transmission and complicate vector control efforts. A high-density, genome-wide mosquito SNP-genotyping array allowed mapping of genomic differentiation between populations and species that exhibit varying levels of reproductive isolation. Regions near centromeres or within polymorphic inversions exhibited the greatest genetic divergence, but divergence was also observed elsewhere in the genomes. Signals of natural selection within populations were overrepresented among genomic regions that are differentiated between populations, implying that differentiation is often driven by population-specific selective events. Complex genomic differentiation among speciating vector mosquito populations implies that tools for genome-wide monitoring of population structure will prove useful for the advancement of malaria eradication.

Published
2018

3. Responses to Bacteria, Virus, and Malaria Distinguish the Etiology of Pediatric Clinical Pneumonia.

Author

Valim, Clarissa, Valim, Clarissa, Ahmad, Rushdy, Lanaspa, Miguel, Tan, Yan, Acácio, Sozinho, Gillette, Michael A, Almendinger, Katherine D, Milner, Danny A, Madrid, Lola, Pellé, Karell, Harezlak, Jaroslaw, Silterra, Jacob, Alonso, Pedro L, Carr, Steven A, Mesirov, Jill P, Wirth, Dyann F, Wiegand, Roger C, Bassat, Quique, Valim, Clarissa, Valim, Clarissa, Ahmad, Rushdy, Lanaspa, Miguel, Tan, Yan, Acácio, Sozinho, Gillette, Michael A, Almendinger, Katherine D, Milner, Danny A, Madrid, Lola, Pellé, Karell, Harezlak, Jaroslaw, Silterra, Jacob, Alonso, Pedro L, Carr, Steven A, Mesirov, Jill P, Wirth, Dyann F, Wiegand, Roger C, and Bassat, Quique

Abstract

RationalePlasma-detectable biomarkers that rapidly and accurately diagnose bacterial infections in children with suspected pneumonia could reduce the morbidity of respiratory disease and decrease the unnecessary use of antibiotic therapy.ObjectivesUsing 56 markers measured in a multiplexed immunoassay, we sought to identify proteins and protein combinations that could discriminate bacterial from viral or malarial diagnoses.MethodsWe selected 80 patients with clinically diagnosed pneumonia (as defined by the World Health Organization) who also met criteria for bacterial, viral, or malarial infection based on clinical, radiographic, and laboratory results. Ten healthy community control subjects were enrolled to assess marker reliability. Patients were subdivided into two sets: one for identifying potential markers and another for validating them.Measurements and main resultsThree proteins (haptoglobin, tumor necrosis factor receptor 2 or IL-10, and tissue inhibitor of metalloproteinases 1) were identified that, when combined through a classification tree signature, accurately classified patients into bacterial, malarial, and viral etiologies and misclassified only one patient with bacterial pneumonia from the validation set. The overall sensitivity and specificity of this signature for the bacterial diagnosis were 96 and 86%, respectively. Alternative combinations of markers with comparable accuracy were selected by support vector machine and regression models and included haptoglobin, IL-10, and creatine kinase-MB.ConclusionsCombinations of plasma proteins accurately identified children with a respiratory syndrome who were likely to have bacterial infections and who would benefit from antibiotic therapy. When used in conjunction with malaria diagnostic tests, they may improve diagnostic specificity and simplify treatment decisions for clinicians.

Published
2016

4. Identification and Functional Validation of the Novel Antimalarial Resistance Locus PF10_0355 in Plasmodium falciparum

Author

Whitaker College of Health Sciences and Technology, Broad Institute of MIT and Harvard, Massachusetts Institute of Technology. Department of Biology, Lander, Eric S., Park, Daniel J., Schaffner, Stephen F., Neafsey, Daniel E., Cortese, Joseph F., Daniels, Rachel F., Johnson, Charles A., Shlyakhter, Ilya, Grossman, Sharon Rachel, Karlsson, Elinor K., Birren, Bruce W., Wiegand, Roger C., Wirth, Dyann F., Volkman, Sarah K., Sabeti, Pardis C., Tyne, Daria Van, Angelino, Elaine, Barnes, Kayla G., Rosen, David M., Lukens, Amanda K., Milner, Danny A., Becker, Justin S., Yamins, Daniel, Ndiaye, Daouda, Sarr, Ousmane, Mboup, Soulyemane, Happi, Christian, Furlotte, Nicholas A., Eskin, Eleazar, Kang, Hyun Min, Hartl, Daniel L., Whitaker College of Health Sciences and Technology, Broad Institute of MIT and Harvard, Massachusetts Institute of Technology. Department of Biology, Lander, Eric S., Park, Daniel J., Schaffner, Stephen F., Neafsey, Daniel E., Cortese, Joseph F., Daniels, Rachel F., Johnson, Charles A., Shlyakhter, Ilya, Grossman, Sharon Rachel, Karlsson, Elinor K., Birren, Bruce W., Wiegand, Roger C., Wirth, Dyann F., Volkman, Sarah K., Sabeti, Pardis C., Tyne, Daria Van, Angelino, Elaine, Barnes, Kayla G., Rosen, David M., Lukens, Amanda K., Milner, Danny A., Becker, Justin S., Yamins, Daniel, Ndiaye, Daouda, Sarr, Ousmane, Mboup, Soulyemane, Happi, Christian, Furlotte, Nicholas A., Eskin, Eleazar, Kang, Hyun Min, and Hartl, Daniel L.

Abstract

The Plasmodium falciparum parasite's ability to adapt to environmental pressures, such as the human immune system and antimalarial drugs, makes malaria an enduring burden to public health. Understanding the genetic basis of these adaptations is critical to intervening successfully against malaria. To that end, we created a high-density genotyping array that assays over 17,000 single nucleotide polymorphisms (~1 SNP/kb), and applied it to 57 culture-adapted parasites from three continents. We characterized genome-wide genetic diversity within and between populations and identified numerous loci with signals of natural selection, suggesting their role in recent adaptation. In addition, we performed a genome-wide association study (GWAS), searching for loci correlated with resistance to thirteen antimalarials; we detected both known and novel resistance loci, including a new halofantrine resistance locus, PF10_0355. Through functional testing we demonstrated that PF10_0355 overexpression decreases sensitivity to halofantrine, mefloquine, and lumefantrine, but not to structurally unrelated antimalarials, and that increased gene copy number mediates resistance. Our GWAS and follow-on functional validation demonstrate the potential of genome-wide studies to elucidate functionally important loci in the malaria parasite genome., Bill & Melinda Gates Foundation, Ellison Medical Foundation, Exxon Mobil Foundation, Fogarty International Center, National Institute of Allergy and Infectious Diseases (U.S.), Burroughs Wellcome Fund, David & Lucile Packard Foundation, National Science Foundation (U.S.). Graduate Research Fellowship Program

Published
2012

5. Identification and Functional Validation of the Novel Antimalarial Resistance Locus PF10_0355 in Plasmodium falciparum

Author

Whitaker College of Health Sciences and Technology, Broad Institute of MIT and Harvard, Massachusetts Institute of Technology. Department of Biology, Lander, Eric S., Park, Daniel J., Schaffner, Stephen F., Neafsey, Daniel E., Cortese, Joseph F., Daniels, Rachel F., Johnson, Charles A., Shlyakhter, Ilya, Grossman, Sharon Rachel, Karlsson, Elinor K., Birren, Bruce W., Wiegand, Roger C., Wirth, Dyann F., Volkman, Sarah K., Sabeti, Pardis C., Tyne, Daria Van, Angelino, Elaine, Barnes, Kayla G., Rosen, David M., Lukens, Amanda K., Milner, Danny A., Becker, Justin S., Yamins, Daniel, Ndiaye, Daouda, Sarr, Ousmane, Mboup, Soulyemane, Happi, Christian, Furlotte, Nicholas A., Eskin, Eleazar, Kang, Hyun Min, Hartl, Daniel L., Park, Daniel, Schaffner, Stephen F, Karlsson, Elinor, Lander, Eric Steven, Sabeti, Pardis, Whitaker College of Health Sciences and Technology, Broad Institute of MIT and Harvard, Massachusetts Institute of Technology. Department of Biology, Lander, Eric S., Park, Daniel J., Schaffner, Stephen F., Neafsey, Daniel E., Cortese, Joseph F., Daniels, Rachel F., Johnson, Charles A., Shlyakhter, Ilya, Grossman, Sharon Rachel, Karlsson, Elinor K., Birren, Bruce W., Wiegand, Roger C., Wirth, Dyann F., Volkman, Sarah K., Sabeti, Pardis C., Tyne, Daria Van, Angelino, Elaine, Barnes, Kayla G., Rosen, David M., Lukens, Amanda K., Milner, Danny A., Becker, Justin S., Yamins, Daniel, Ndiaye, Daouda, Sarr, Ousmane, Mboup, Soulyemane, Happi, Christian, Furlotte, Nicholas A., Eskin, Eleazar, Kang, Hyun Min, Hartl, Daniel L., Park, Daniel, Schaffner, Stephen F, Karlsson, Elinor, Lander, Eric Steven, and Sabeti, Pardis

Abstract

The Plasmodium falciparum parasite's ability to adapt to environmental pressures, such as the human immune system and antimalarial drugs, makes malaria an enduring burden to public health. Understanding the genetic basis of these adaptations is critical to intervening successfully against malaria. To that end, we created a high-density genotyping array that assays over 17,000 single nucleotide polymorphisms (~1 SNP/kb), and applied it to 57 culture-adapted parasites from three continents. We characterized genome-wide genetic diversity within and between populations and identified numerous loci with signals of natural selection, suggesting their role in recent adaptation. In addition, we performed a genome-wide association study (GWAS), searching for loci correlated with resistance to thirteen antimalarials; we detected both known and novel resistance loci, including a new halofantrine resistance locus, PF10_0355. Through functional testing we demonstrated that PF10_0355 overexpression decreases sensitivity to halofantrine, mefloquine, and lumefantrine, but not to structurally unrelated antimalarials, and that increased gene copy number mediates resistance. Our GWAS and follow-on functional validation demonstrate the potential of genome-wide studies to elucidate functionally important loci in the malaria parasite genome., Bill & Melinda Gates Foundation, Ellison Medical Foundation, Exxon Mobil Foundation, Fogarty International Center, National Institute of Allergy and Infectious Diseases (U.S.), Burroughs Wellcome Fund, David & Lucile Packard Foundation, National Science Foundation (U.S.). Graduate Research Fellowship Program

Published
2012

6. Identification and functional validation of the novel antimalarial resistance locus PF10_0355 in Plasmodium falciparum.

Author

Van Tyne, Daria, Van Tyne, Daria, Park, Daniel J, Schaffner, Stephen F, Neafsey, Daniel E, Angelino, Elaine, Cortese, Joseph F, Barnes, Kayla G, Rosen, David M, Lukens, Amanda K, Daniels, Rachel F, Milner, Danny A, Johnson, Charles A, Shlyakhter, Ilya, Grossman, Sharon R, Becker, Justin S, Yamins, Daniel, Karlsson, Elinor K, Ndiaye, Daouda, Sarr, Ousmane, Mboup, Souleymane, Happi, Christian, Furlotte, Nicholas A, Eskin, Eleazar, Kang, Hyun Min, Hartl, Daniel L, Birren, Bruce W, Wiegand, Roger C, Lander, Eric S, Wirth, Dyann F, Volkman, Sarah K, Sabeti, Pardis C, Van Tyne, Daria, Van Tyne, Daria, Park, Daniel J, Schaffner, Stephen F, Neafsey, Daniel E, Angelino, Elaine, Cortese, Joseph F, Barnes, Kayla G, Rosen, David M, Lukens, Amanda K, Daniels, Rachel F, Milner, Danny A, Johnson, Charles A, Shlyakhter, Ilya, Grossman, Sharon R, Becker, Justin S, Yamins, Daniel, Karlsson, Elinor K, Ndiaye, Daouda, Sarr, Ousmane, Mboup, Souleymane, Happi, Christian, Furlotte, Nicholas A, Eskin, Eleazar, Kang, Hyun Min, Hartl, Daniel L, Birren, Bruce W, Wiegand, Roger C, Lander, Eric S, Wirth, Dyann F, Volkman, Sarah K, and Sabeti, Pardis C

Abstract

The Plasmodium falciparum parasite's ability to adapt to environmental pressures, such as the human immune system and antimalarial drugs, makes malaria an enduring burden to public health. Understanding the genetic basis of these adaptations is critical to intervening successfully against malaria. To that end, we created a high-density genotyping array that assays over 17,000 single nucleotide polymorphisms (∼ 1 SNP/kb), and applied it to 57 culture-adapted parasites from three continents. We characterized genome-wide genetic diversity within and between populations and identified numerous loci with signals of natural selection, suggesting their role in recent adaptation. In addition, we performed a genome-wide association study (GWAS), searching for loci correlated with resistance to thirteen antimalarials; we detected both known and novel resistance loci, including a new halofantrine resistance locus, PF10_0355. Through functional testing we demonstrated that PF10_0355 overexpression decreases sensitivity to halofantrine, mefloquine, and lumefantrine, but not to structurally unrelated antimalarials, and that increased gene copy number mediates resistance. Our GWAS and follow-on functional validation demonstrate the potential of genome-wide studies to elucidate functionally important loci in the malaria parasite genome.

Published
2011

7. Identification and functional validation of the novel antimalarial resistance locus PF10_0355 in Plasmodium falciparum.

Author

Van Tyne, Daria, Moran, Nancy A1, Van Tyne, Daria, Park, Daniel J, Schaffner, Stephen F, Neafsey, Daniel E, Angelino, Elaine, Cortese, Joseph F, Barnes, Kayla G, Rosen, David M, Lukens, Amanda K, Daniels, Rachel F, Milner, Danny A, Johnson, Charles A, Shlyakhter, Ilya, Grossman, Sharon R, Becker, Justin S, Yamins, Daniel, Karlsson, Elinor K, Ndiaye, Daouda, Sarr, Ousmane, Mboup, Souleymane, Happi, Christian, Furlotte, Nicholas A, Eskin, Eleazar, Kang, Hyun Min, Hartl, Daniel L, Birren, Bruce W, Wiegand, Roger C, Lander, Eric S, Wirth, Dyann F, Volkman, Sarah K, Sabeti, Pardis C, Van Tyne, Daria, Moran, Nancy A1, Van Tyne, Daria, Park, Daniel J, Schaffner, Stephen F, Neafsey, Daniel E, Angelino, Elaine, Cortese, Joseph F, Barnes, Kayla G, Rosen, David M, Lukens, Amanda K, Daniels, Rachel F, Milner, Danny A, Johnson, Charles A, Shlyakhter, Ilya, Grossman, Sharon R, Becker, Justin S, Yamins, Daniel, Karlsson, Elinor K, Ndiaye, Daouda, Sarr, Ousmane, Mboup, Souleymane, Happi, Christian, Furlotte, Nicholas A, Eskin, Eleazar, Kang, Hyun Min, Hartl, Daniel L, Birren, Bruce W, Wiegand, Roger C, Lander, Eric S, Wirth, Dyann F, Volkman, Sarah K, and Sabeti, Pardis C

Abstract

The Plasmodium falciparum parasite's ability to adapt to environmental pressures, such as the human immune system and antimalarial drugs, makes malaria an enduring burden to public health. Understanding the genetic basis of these adaptations is critical to intervening successfully against malaria. To that end, we created a high-density genotyping array that assays over 17,000 single nucleotide polymorphisms (∼ 1 SNP/kb), and applied it to 57 culture-adapted parasites from three continents. We characterized genome-wide genetic diversity within and between populations and identified numerous loci with signals of natural selection, suggesting their role in recent adaptation. In addition, we performed a genome-wide association study (GWAS), searching for loci correlated with resistance to thirteen antimalarials; we detected both known and novel resistance loci, including a new halofantrine resistance locus, PF10_0355. Through functional testing we demonstrated that PF10_0355 overexpression decreases sensitivity to halofantrine, mefloquine, and lumefantrine, but not to structurally unrelated antimalarials, and that increased gene copy number mediates resistance. Our GWAS and follow-on functional validation demonstrate the potential of genome-wide studies to elucidate functionally important loci in the malaria parasite genome.

Published
2011

8. A general SNP-based molecular barcode for Plasmodium falciparum identification and tracking

Author

Lincoln Laboratory, Daniels, Rachel F., Neafsey, Daniel E., Park, Daniel J., Sabeti, Pardis C., Wiegand, Roger C., Mahesh, Nira, Rosen, David, Angelino, Elaine, Volkman, Sarah K., Milner, Danny A., Wirth, Dyann F., Lincoln Laboratory, Daniels, Rachel F., Neafsey, Daniel E., Park, Daniel J., Sabeti, Pardis C., Wiegand, Roger C., Mahesh, Nira, Rosen, David, Angelino, Elaine, Volkman, Sarah K., Milner, Danny A., and Wirth, Dyann F.

Abstract

Background Single nucleotide polymorphism (SNP) genotyping provides the means to develop a practical, rapid, inexpensive assay that will uniquely identify any Plasmodium falciparum parasite using a small amount of DNA. Such an assay could be used to distinguish recrudescence from re-infection in drug trials, to monitor the frequency and distribution of specific parasites in a patient population undergoing drug treatment or vaccine challenge, or for tracking samples and determining purity of isolates in the laboratory during culture adaptation and sub-cloning, as well as routine passage. Methods A panel of twenty-four SNP markers has been identified that exhibit a high minor allele frequency (average MAF > 35%), for which robust TaqMan genotyping assays were constructed. All SNPs were identified through whole genome sequencing and MAF was estimated through Affymetrix array-based genotyping of a worldwide collection of parasites. These assays create a "molecular barcode" to uniquely identify a parasite genome. Results Using 24 such markers no two parasites known to be of independent origin have yet been found to have the same allele signature. The TaqMan genotyping assays can be performed on a variety of samples including cultured parasites, frozen whole blood, or whole blood spotted onto filter paper with a success rate > 99%. Less than 5 ng of parasite DNA is needed to complete a panel of 24 markers. The ability of this SNP panel to detect and identify parasites was compared to the standard molecular methods, MSP-1 and MSP-2 typing. Conclusion This work provides a facile field-deployable genotyping tool that can be used without special skills with standard lab equipment, and at reasonable cost that will unambiguously identify and track P. falciparum parasites both from patient samples and in the laboratory., National Institutes of Health (U.S), Broad Institute of MIT and Harvard (SPARC funding), Ellison Medical Foundation, Burroughs Wellcome Fund, Bill & Melinda Gates Foundation, National Institute of Allergy and Infectious Diseases (U.S.) (NIAID). Microbial Sequencing Center, Fogarty International Center, Exxon Mobil Foundation, National Institutes of Health (U.S) (K23 grant K23AIO72033-01)

Published
2010

9. Genome-wide SNP genotyping highlights the role of natural selection in Plasmodium falciparum population divergence

Author

Broad Institute of MIT and Harvard, Massachusetts Institute of Technology. Department of Biology, Neafsey, Daniel E., Schaffner, Stephen F., Park, Daniel, Montgomery, Philip, Daniels, Rachel F., Houde, Nathan, Cortese, Joseph F., Tyndall, Erin, Gates, Casey, Stange-Thomann, Nicole, Wiegand, Roger C., Lander, Eric S., Birren, Bruce W., Sabeti, Pardis C., Volkman, Sarak K., Milner, Danny A., Lukens, Amanda K., Rosen, David, Sarr, Ousmane, Ndiaye, Daouda, Ndir, Omar, Mboup, Soulyemane, Ferreira, Marcelo U., do Lago Moraes, Sandra, Dash, Aditya P., Chitnis, Chetan E., Hartl, Daniel L., Wirth, Dyann F., Schaffner, Stephen F, Lander, Eric Steven, Sabeti, Pardis, Broad Institute of MIT and Harvard, Massachusetts Institute of Technology. Department of Biology, Neafsey, Daniel E., Schaffner, Stephen F., Park, Daniel, Montgomery, Philip, Daniels, Rachel F., Houde, Nathan, Cortese, Joseph F., Tyndall, Erin, Gates, Casey, Stange-Thomann, Nicole, Wiegand, Roger C., Lander, Eric S., Birren, Bruce W., Sabeti, Pardis C., Volkman, Sarak K., Milner, Danny A., Lukens, Amanda K., Rosen, David, Sarr, Ousmane, Ndiaye, Daouda, Ndir, Omar, Mboup, Soulyemane, Ferreira, Marcelo U., do Lago Moraes, Sandra, Dash, Aditya P., Chitnis, Chetan E., Hartl, Daniel L., Wirth, Dyann F., Schaffner, Stephen F, Lander, Eric Steven, and Sabeti, Pardis

Abstract

Background: The malaria parasite Plasmodium falciparum exhibits abundant genetic diversity, and this diversity is key to its success as a pathogen. Previous efforts to study genetic diversity in P. falciparum have begun to elucidate the demographic history of the species, as well as patterns of population structure and patterns of linkage disequilibrium within its genome. Such studies will be greatly enhanced by new genomic tools and recent large-scale efforts to map genomic variation. To that end, we have developed a high throughput single nucleotide polymorphism (SNP) genotyping platform for P. falciparum. Results: Using an Affymetrix 3,000 SNP assay array, we found roughly half the assays (1,638) yielded high quality, 100% accurate genotyping calls for both major and minor SNP alleles. Genotype data from 76 global isolates confirm significant genetic differentiation among continental populations and varying levels of SNP diversity and linkage disequilibrium according to geographic location and local epidemiological factors. We further discovered that nonsynonymous and silent (synonymous or noncoding) SNPs differ with respect to within-population diversity, inter-population differentiation, and the degree to which allele frequencies are correlated between populations. Conclusions: The distinct population profile of nonsynonymous variants indicates that natural selection has a significant influence on genomic diversity in P. falciparum, and that many of these changes may reflect functional variants deserving of follow-up study. Our analysis demonstrates the potential for new high-throughput genotyping technologies to enhance studies of population structure, natural selection, and ultimately enable genome-wide association studies in P. falciparum to find genes underlying key phenotypic traits., National Institutes of Health (U.S.), Broad Institute of Harvard and MIT, Burroughs Wellcome Fund, Bill & Melinda Gates Foundation, National Institute of Allergy and Infectious Diseases (U.S.). Microbial Sequencing Center, Ellison Medical Foundation, Fogarty International Center, Exxon Mobil Foundation, National Center for Research Resources (U.S.) (Grant U54 RR020278)

Published
2010

10. A general SNP-based molecular barcode for Plasmodium falciparum identification and tracking

Author

Broad Institute of MIT and Harvard, Daniels, Rachel F., Neafsey, Daniel E., Park, Daniel J., Sabeti, Pardis C., Wiegand, Roger C., Volkman, Sarah K., Milner, Danny A., Mahesh, Nira, Rosen, David, Angelino, Elaine, Wirth, Dyann F., Broad Institute of MIT and Harvard, Daniels, Rachel F., Neafsey, Daniel E., Park, Daniel J., Sabeti, Pardis C., Wiegand, Roger C., Volkman, Sarah K., Milner, Danny A., Mahesh, Nira, Rosen, David, Angelino, Elaine, and Wirth, Dyann F.

Abstract

Background: Single nucleotide polymorphism (SNP) genotyping provides the means to develop a practical, rapid, inexpensive assay that will uniquely identify any Plasmodium falciparum parasite using a small amount of DNA. Such an assay could be used to distinguish recrudescence from re-infection in drug trials, to monitor the frequency and distribution of specific parasites in a patient population undergoing drug treatment or vaccine challenge, or for tracking samples and determining purity of isolates in the laboratory during culture adaptation and sub-cloning, as well as routine passage. Methods: A panel of twenty-four SNP markers has been identified that exhibit a high minor allele frequency (average MAF > 35%), for which robust TaqMan genotyping assays were constructed. All SNPs were identified through whole genome sequencing and MAF was estimated through Affymetrix array-based genotyping of a worldwide collection of parasites. These assays create a "molecular barcode" to uniquely identify a parasite genome. Results: Using 24 such markers no two parasites known to be of independent origin have yet been found to have the same allele signature. The TaqMan genotyping assays can be performed on a variety of samples including cultured parasites, frozen whole blood, or whole blood spotted onto filter paper with a success rate > 99%. Less than 5 ng of parasite DNA is needed to complete a panel of 24 markers. The ability of this SNP panel to detect and identify parasites was compared to the standard molecular methods, MSP-1 and MSP-2 typing. Conclusion: This work provides a facile field-deployable genotyping tool that can be used without special skills with standard lab equipment, and at reasonable cost that will unambiguously identify and track P. falciparum parasites both from patient samples and in the laboratory.

Published
2009

Catalog

Books, media, physical & digital resources
See catalog results