Comparison of real-time PCR and microscopy for malaria parasite detection in Malawian pregnant women

Abstract Background New diagnostic tools for malaria are required owing to the changing epidemiology of malaria, particularly among pregnant women in sub-Saharan Africa. Real-time PCR assays targeting Plasmodium falciparum lactate dehydrogenase (pfldh) gene may facilitate the identification of a high proportion of pregnant women with a P. falciparum parasitaemia below the threshold of microscopy. These molecular methods will enable further studies on the effects of these submicroscopic infections on maternal health and birth outcomes. Methods The pfldh real-time PCR assay and conventional microscopy were compared for the detection of P. falciparum from dried blood spots and blood smears collected from the peripheral blood of 475 Malawian women at delivery. A cycle threshold (Ct) of the real-time PCR was determined optimizing the sensitivity and specificity of the pfldh PCR assay compared to microscopy. A real-time PCR species-specific assay was applied to identify the contribution to malaria infections of three Plasmodium species (P. falciparum P. ovale and P. malariae) in 44 discordant smear and pfldh PCR assay results. Results Of the 475 women, P. falciparum was detected in 11 (2.3%) by microscopy and in 51 (10.7%) by real-time PCR; compared to microscopy, the sensitivity of real-time PCR was 90.9% and the specificity 91.2%. If a Ct value of 38 was used as a cut-off, specificity improved to 94.6% with no change in sensitivity. The real-time PCR species-specific assay detected P. falciparum alone in all but four samples: two samples were mixed infections with P. falciparum and P. malariae, one was a pure P. malariae infection and one was a pfldh PCR assay-positive/species-specific assay-negative sample. Of three P. malariae infections detected by microscopy, only one was confirmed by the species-specific assay. Conclusions Although microscopy remains the most appropriate method for clinical malaria diagnosis in field settings, molecular diagnostics such as real-time PCR offer a more reliable means to detect malaria parasites, particularly at low levels. Determination of the possible contribution of these submicroscopic infections to poor birth outcomes and maternal health is critical. For future studies to investigate these effects, this pfldh real-time PCR assay offers a reliable detection method

High-Throughput Pooling and Real-Time PCR-Based Strategy for Malaria Detection

Molecular assays can provide critical information for malaria diagnosis, speciation, and drug resistance, but their cost and resource requirements limit their application to clinical malaria studies. This study describes the application of a resource-conserving testing algorithm employing sample pooling for real-time PCR assays for malaria in a cohort of 182 pregnant women in Kinshasa. A total of 1,268 peripheral blood samples were collected during the study. Using a real-time PCR assay that detects all Plasmodium species, microscopy-positive samples were amplified individually; the microscopy-negative samples were amplified after pooling the genomic DNA (gDNA) of four samples prior to testing. Of 176 microscopy-positive samples, 74 were positive by the real-time PCR assay; the 1,092 microscopy-negative samples were initially amplified in 293 pools, and subsequently, 35 samples were real-time PCR positive (3%). With the real-time PCR result as the referent standard, microscopy was 67.9% sensitive (95% confidence interval [CI], 58.3% to 76.5%) and 91.2% specific (95% CI, 89.4% to 92.8%) for malaria. In total, we detected 109 parasitemias by real-time PCR and, by pooling samples, obviated over 50% of reactions and halved the cost of testing. Our study highlights both substantial discordance between malaria diagnostics and the utility and parsimony of employing a sample pooling strategy for molecular diagnostics in clinical and epidemiologic malaria studies

Comparison of real-time PCR and microscopy for malaria parasite detection in Malawian pregnant women

Abstract Background New diagnostic tools for malaria are required owing to the changing epidemiology of malaria, particularly among pregnant women in sub-Saharan Africa. Real-time PCR assays targeting Plasmodium falciparum lactate dehydrogenase (pfldh) gene may facilitate the identification of a high proportion of pregnant women with a P. falciparum parasitaemia below the threshold of microscopy. These molecular methods will enable further studies on the effects of these submicroscopic infections on maternal health and birth outcomes. Methods The pfldh real-time PCR assay and conventional microscopy were compared for the detection of P. falciparum from dried blood spots and blood smears collected from the peripheral blood of 475 Malawian women at delivery. A cycle threshold (Ct) of the real-time PCR was determined optimizing the sensitivity and specificity of the pfldh PCR assay compared to microscopy. A real-time PCR species-specific assay was applied to identify the contribution to malaria infections of three Plasmodium species (P. falciparum P. ovale and P. malariae) in 44 discordant smear and pfldh PCR assay results. Results Of the 475 women, P. falciparum was detected in 11 (2.3%) by microscopy and in 51 (10.7%) by real-time PCR; compared to microscopy, the sensitivity of real-time PCR was 90.9% and the specificity 91.2%. If a Ct value of 38 was used as a cut-off, specificity improved to 94.6% with no change in sensitivity. The real-time PCR species-specific assay detected P. falciparum alone in all but four samples: two samples were mixed infections with P. falciparum and P. malariae, one was a pure P. malariae infection and one was a pfldh PCR assay-positive/species-specific assay-negative sample. Of three P. malariae infections detected by microscopy, only one was confirmed by the species-specific assay. Conclusions Although microscopy remains the most appropriate method for clinical malaria diagnosis in field settings, molecular diagnostics such as real-time PCR offer a more reliable means to detect malaria parasites, particularly at low levels. Determination of the possible contribution of these submicroscopic infections to poor birth outcomes and maternal health is critical. For future studies to investigate these effects, this pfldh real-time PCR assay offers a reliable detection method.</p

High-Throughput Pooling and Real-Time PCR-Based Strategy for Malaria Detection▿

Molecular assays can provide critical information for malaria diagnosis, speciation, and drug resistance, but their cost and resource requirements limit their application to clinical malaria studies. This study describes the application of a resource-conserving testing algorithm employing sample pooling for real-time PCR assays for malaria in a cohort of 182 pregnant women in Kinshasa. A total of 1,268 peripheral blood samples were collected during the study. Using a real-time PCR assay that detects all Plasmodium species, microscopy-positive samples were amplified individually; the microscopy-negative samples were amplified after pooling the genomic DNA (gDNA) of four samples prior to testing. Of 176 microscopy-positive samples, 74 were positive by the real-time PCR assay; the 1,092 microscopy-negative samples were initially amplified in 293 pools, and subsequently, 35 samples were real-time PCR positive (3%). With the real-time PCR result as the referent standard, microscopy was 67.9% sensitive (95% confidence interval [CI], 58.3% to 76.5%) and 91.2% specific (95% CI, 89.4% to 92.8%) for malaria. In total, we detected 109 parasitemias by real-time PCR and, by pooling samples, obviated over 50% of reactions and halved the cost of testing. Our study highlights both substantial discordance between malaria diagnostics and the utility and parsimony of employing a sample pooling strategy for molecular diagnostics in clinical and epidemiologic malaria studies

Combined inhibition of tumor suppressors PTEN and PP2A drives anoikis resistance and is associated with therapy relapse in prostate cancer

Reactivation of tumor suppressor phosphatases may provide entirely novel opportunities for cancer therapy. Here, we discover clinically relevant functional co-operation between loss of activities of two human tumor suppressor phosphatases, PTEN, and PP2A. Analysis of prostate cancer tissue microarray material consisting of 358 patients treated primarily with radical prostatectomy revealed that overexpression of PP2A inhibitor protein PME-1 associates with significantly shorter time to therapy relapse in patients with PTEN-deficient PrCa. Further, PP2A inhibition by PME-1 overexpression in PTEN-deficient cell models inhibits apoptosis induction in anchorage-independent conditions (anoikis). PP2A reactivation by small molecules (SMAPs) was also found to inhibit viability of PTEN-deficient PrCa cells. Importantly, rather than regulating the well-known PP2A target pathways, PME-1 was found to physically associate with, and to regulate deformability of the nuclear lamina in PrCa cells. Mass spectrometry phosphoproteomics analysis identified several PME-1-regulated nuclear lamina constituents, and PME-1 deficient cells with compromised nuclear lamina were particularly vulnerable to apoptosis induction by mechanical stress. As a direct molecular target, Lamin A/C phosphorylation was found to be protected by PME-1-mediated PP2A inhibition under anoikis-inducing conditions. PME-1 inhibition in PrCa cells resulted in increased apoptosis in an in ovo tumor model, and PME-1-depleted cells had compromised long-term survival in zebrafish circulation. In summary we discover that PP2A reactivation by PME-1 targeting sensitizes PTEN-deficient PrCa cells to anoikis. Clinically, the results identify PME-1 as a novel candidate biomarker for increased relapse risk in PTEN-deficient PrCa, and indicate pharmacological PP2A activation as a novel potential therapeutic approach against circulating prostate cancer cells. At the general level, the results clearly emphasize the need for better understanding of phosphatases as key modulators of cancer progression. Citation Format: Christian Rupp, Aleksi Isomursu, Anna Aakula, Andrew Erickson, Song-Ping Li, Amanpreet Kaur, Pragya Shah, Yuba R. Pokharel, Lloyd Trottman, Jan Lammerding, Antti Rannikko, Pekka Taimen, Tuomas Mirtti, Ilkka Paatero, Johanna Ivaska, Jukka K. Westermarck. Combined inhibition of tumor suppressors PTEN and PP2A drives anoikis resistance and is associated with therapy relapse in prostate cancer [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2019; 2019 Mar 29-Apr 3; Atlanta, GA. Philadelphia (PA): AACR; Cancer Res 2019;79(13 Suppl):Abstract nr 348