Simple and sensitive antimalarial drug screening in vitro and in vivo using transgenic luciferase expressing Plasmodium berghei parasites.

We report two improved assays for in vitro and in vivo screening of chemicals with potential anti-malarial activity against the blood stages of the rodent malaria parasite Plasmodiumberghei. These assays are based on the determination of luciferase activity (luminescence) in small blood samples containing transgenic blood stage parasites that express luciferase under the control of a promoter that is either schizont-specific (ama-1) or constitutive (eef1alphaa). Assay 1, the in vitro drug luminescence (ITDL) assay, measured the success of schizont maturation in the presence of candidate drugs quantifying luciferase activity in mature schizonts only (ama-1 promoter). The ITDL assay generated drug-inhibition curves and EC(50) values comparable to those obtained with standard in vitro drug-susceptibility assays. The second assay, the in vivo drug-luminescence (IVDL) assay, measured parasite growth in vivo in a standard 4-day suppressive drug test, monitored by measuring the constitutive luciferase activity of circulating parasites (eef1alphaa promoter). The IVDL assay generates growth-curves that are identical to those obtained by manual counting of parasites in Giemsa-stained smears. The reading of luminescence assays is rapid, requires a minimal number of handling steps and no experience with parasite morphology or handling fluorescence-activated cell sorters, produces no radioactive waste and test-plates can be stored for prolonged periods before processing. Both tests are suitable for use in larger-scale in vitro and in vivo screening of drugs. The standard methodology of anti-malarial drug screening and validation, which includes testing in rodent models of malaria, can be improved by the incorporation of such assays.

Single rapid real-time monitored isothermal RNA amplification assay for quantification of human immunodeficiency virus type 1 isolates from groups M, N, and O.

Because human immunodeficiency virus type 1 (HIV-1) subtypes and circulating recombinant forms (CRFs) are spreading rapidly worldwide and are becoming less confined to a geographical area, RNA assays that can detect and quantify all HIV-1 isolates reliably are in demand. We have developed a fast, real-time monitored RNA assay based on an isothermal nucleic acid sequence-based amplification technology that amplifies a part of the long terminal repeat region of the HIV-1 genome. Real-time detection was possible due to the addition of molecular beacons to the amplification reaction that was monitored in a fluorimeter with a thermostat. The lower level of detection of the assay was 10 HIV-1 RNA molecules per reaction, and the lower level of quantification was 100 copies of HIV-1 RNA with a dynamic range of linear quantification between 10(2) and 10(7) RNA molecules. All HIV-1 groups, subtypes, and CRFs could be detected and quantified with equal efficiency, including the group N isolate YBF30 and the group O isolate ANT70. To test the clinical utility of the assay, a series of 62 serum samples containing viruses that encompassed subtypes A through G and CRFs AE and AG of HIV-1 group M were analyzed, and these results were compared to the results of a commercially available assay. This comparison showed that the quantification results correlated highly (R(2) = 0.735) for those subtypes that could be well quantified by both assays (subtypes B, C, D, and F), whereas improved quantification was obtained for subtypes A and G and CRFs AE and AG. A retrospective study with six individuals infected with either a subtype A, B, C, or D or an AG isolate of HIV-1 group M, who were treated with highly active antiretroviral therapy, revealed that the assay was well suited to the monitoring of therapy effects. In conclusion, the newly developed real-time monitored HIV-1 assay is a fast and sensitive assay with a large dynamic range of quantification and is suitable for quantification of most if not all subtypes and groups of HIV-1.