- Open Access
Simple, sensitive and quantitative bioluminescence assay for determination of malaria pre-patent period
© Zuzarte-Luis et al.; licensee BioMed Central Ltd. 2014
- Received: 17 November 2013
- Accepted: 31 December 2013
- Published: 8 January 2014
The first phase of malaria infection occurs in the liver and is clinically silent. Inside hepatocytes each Plasmodium sporozoite replicate into thousands of erythrocyte-infectious merozoites that when released into the blood stream result in clinical symptoms of the disease. The time between sporozoite inoculation and the appearance of parasites in the blood is defined as the pre-patent period, which is classically analysed by time-consuming and labor-intensive techniques, such as microscopy and PCR.
Luciferase-expressing Plasmodium berghei parasites were used to measure pre-patent period of malaria infection in rodents using a bioluminescence assay that requires only one microliter of blood collected from the tail-vein. The accuracy and sensitivity of this new method was compared with conventional microscopy and PCR based techniques, and its capacity to measure the impact of anti-malarial interventions against the liver evaluated.
The described method is very sensitive allowing the detection of parasites during the first cycles of blood stage replication. It accurately translates differences in liver load due to inoculation of different sporozoite doses as well as a result of treatment with different primaquine regimens.
A novel, simple, fast, and sensitive method to measure pre-patent period of malaria infection in rodents is described here. The sensitivity and accuracy of this new method is comparable to standard PCR and microscopy-based techniques, respectively.
- Malaria Infection
- Bioluminescence Assay
- Sporozoite Infection
- Transgenic Parasite
Malaria infection is initiated when Plasmodium parasites enter the host through the bite of an infected Anopheles mosquito. The clinical manifestations of the disease occur during the intra-erythrocytic stage of replication, but prior to infecting red blood cells Plasmodium parasites go through an obligatory and asymptomatic phase of intrahepatic development.
Upon reaching the liver, sporozoites invade host hepatocytes inside which they develop into thousands of red blood cell-infectious merozoites . Targeting this asymptomatic stage of infection is crucial for the success of anti-malarial interventions since clearance of the parasite at this stage completely abrogates the clinical manifestation and transmission of the disease. As such, the development of anti-malarial vaccine candidates and chemoprophylaxis approaches focused on the liver stage of infection is critical [2, 3]. It is, however, challenging to evaluate the efficacy of anti-malarial strategies that target the development of Plasmodium parasites in the liver.
Rodent models are frequently used to study the impact of the different strategies in vivo and several methods have been developed to accurately measure Plasmodium liver infection (for a comprehensive review see ). Nevertheless, standard methods are invasive and terminal, as they require the collection of liver tissue to determine parasite burden. Among the usual methods are the microscopy-based techniques to analyse fixed livers upon immunofluorescence assay (IFA), using Plasmodium-specific antibodies, or live samples using transgenic parasites engineered to express fluorescent proteins  and quantitative reverse transcriptase PCR (qRT-PCR) to detect Plasmodium-specific targets, typically 18S ribosomal RNA, or trans-genes expressed by engineered parasites . These assays are usually performed in the end phase of Plasmodium development in the liver (between 40 and 48 hr after infection with Plasmodium berghei or Plasmodium yoelii sporozoites), and prior to the egress of parasites into the blood. As such, they are inappropriate to evaluate the impact of the anti-malarial strategies on the final stage of the parasite maturation, egress from the liver and onset of the symptomatic blood infection .
The length of the pre-patent period, i.e. the time between sporozoite inoculation and the appearance of parasites in the blood, directly reflects the duration of the liver stage and the number of infective merozoites produced. However, determining the onset of blood parasitaemia through the analysis of blood smears by microscopy is time-consuming and not accurate, as it may take a few cycles of blood stage replication to achieve a detectable level of parasites in the blood. The molecular methods (PCR-based techniques) are more sensitive allowing not only to accurately measure parasite load but also to determine speciation. They are, however, expensive and labor intensive methods [8, 9].
The recently developed chemiluminescent parasites have become valuable tools in experimental malaria research. The luciferase-expressing parasites can be used to assess parasite hepatic development through non-invasive methods and still allowing infection to proceed to the blood stage in the same animals where liver burden was previously assessed . As such, it is possible, using these parasites to evaluate the effect of specific anti-malarial strategies that target the liver stage.
Here, a further use for these transgenic luciferase-expressing lines is proposed to accurately evaluate the pre-patent period of malaria infection. This new assay constitutes a simple, fast, non-invasive, and highly sensitive bioluminescent assay allowing a precise evaluation of the malaria pre-patent period as it allows the detection of blood parasites as early as 60 hr after sporozoite inoculation. This means that this method is able to detect the first generation of merozoites released from the liver, since that merozoite egress from hepatocytes starts 48 hr after infection with sporozoites .
Mice, parasites and reagents
Male C57BL/6 mice, aged six to eight weeks were purchased from Charles River and housed in the pathogen-free facilities of the Instituto de Medicina Molecular, Lisbon (IMM). The luciferase expressing P. berghei ANKA transgenic parasite lines (676m1cl1 line) was used in all the experiments. Sporozoites were obtained by disruption of the salivary glands of freshly dissected infected female Anopheles stephensi mosquitoes and collected in DMEM (Dulbecco’s Modified Eagle Medium from GIBCO). Mosquitoes were bred at the insectary facility of the Instituto de Medicina Molecular. Firely luciferase assay kit was purchased from Biotium, Hayward, USA and DNA extraction kit was purchased from QIAGEN.
All experimental procedures were performed according to EU recommendations for good practices and animal welfare and approved by the IMM Animal Care and Ethical Committee (AEC_2010_024_MM_RDT_General_IMM). Animals were monitored daily and every effort was made to minimize suffering. Upon completion of experiments, mice were euthanized via administration of CO2 followed by cervical dislocation.
Infection and bioluminescence assay
Plasmodium liver stage infection was established by mosquito bite, through a 20 minutes bite of one infected Anopheles mosquito, or intravenously (IV) through retro-orbital injection of the designated quantity of sporozoites. At the selected time-points 1 μL of blood was collected from the tail vein into 50 μL of lysis buffer. Luminescence was determined by adding 50 μL of D-luciferin dissolved in firely luciferase assay buffer (according to the manufacturer’s instructions) to 30 μL of lysate and immediately measured using a multiplate reader (Tecan, Switzerland). Values of luciferase activity are expressed as relative luminescence units (RLU).
DNA extraction and real-time PCR analysis
At the selected time-points, and concomitant with the sampling for bioluminescence assay, 1 μL of blood was collected from the tail vein into 200 μL of 1× PBS. DNA extraction was performed using the DNeasy Blood & Tissue Kit, according to the manufacturer’s instructions. Real-time PCR analysis to was performed using 2 μL of DNA and the iTaq Universal SYBR Green Supermix from Bio-Rad according to the manufacturer’s instructions. Expression levels of 18 s rRNA were normalized against the housekeeping gene seryl-tRNA synthetase (PbANKA_061540). Gene expression values were calculated based on the ΔΔCt method. Primer pairs used were: PbA 18S rRNA: 5′GGAGATTGGTTTTGACGTTTATGTG3′ and 5′GGAGATTGGTTTTGACGTTTATGTG3′; PBANKA_061540: 5′ATTGCTCAACCTTATCAAACTG3′ and 5′AGCCACATCTGAACAACCG3′.
Blood parasitaemia was monitored daily by light microscopy, starting 60 hr after infection. Air-dried thin blood smears were fixed in absolute methanol and stained with Giemsa. Percentage of infected red blood cells (iRBC) was assessed by microscopic examination of 15 fields of Giemsa-stained blood smears.
Statistically significant differences between two different groups were analysed using the Mann–Whitney test. P < 0.05 were considered statistically significant. Significances are represented in the figures as follows *P < 0.05; **P < 0.01. All statistic tests were performed using Graph Prism 5.0 software.
Bioluminescence assessment of blood parasite load correlates with parasitaemia measurements
Bioluminescence measurements detect circulating parasites 60 hr upon infection with 50,000 sporozoites
Having shown that bioluminescence measurements have a direct correlation with the number of circulating parasites, the next step was to establish the earliest time point after sporozoite infection, as well as the lowest level of parasites that this assay could detect. Infections were initiated by IV injection of 500 and 50,000 sporozoites and bioluminescence measurements from 1 μL of tail-vein blood were performed 60 and 72 hr after infection. The results show that circulating parasites can be quantified by this method as early as 60 hr when the infection is initiated with 50,000 sporozoites (Figure 1C). Importantly, the luminescence levels are proportionally lower upon administration of primaquine (PRQ) on the day of infection (estimated to reduce liver infection by 90%) or 24 hr after infection (estimated to reduced approximately 50% of liver parasite load). In addition, an infection initiated by the bite of one single infected mosquito could be detected 72 hr after the infectious bite (Figure 1D) in levels similarly to the inoculation IV of 500 sporozoites (Figure 1C).
Sensitivity of the bioluminescence assay is similar to the PCR detection of blood parasite load
To further test the sensitivity of the assay, bioluminescence measurements were compared with real-time PCR analysis, both in samples of 1 μL of tail-vein blood of animals infected by IV injection of 50,000 sporozoites at 48, 60 and 72 hr after sporozoite infection. The results show that the sensitivity of both methods is similar, as in both cases the differences to non-infected (Ni) blood samples are only significant at 60 and 72 hr, but not at 48 hr after infection. The results of the analysis of technical triplicates are further indicators of assay robustness.
The bioluminescent assay described here allows the fast and efficient quantitative monitoring of pre-patent period in a minimally invasive manner. This technique has clear benefits over the traditional, time-consuming, examination of blood smears to detect the presence of circulating parasites. It takes a few cycles of blood stage replication to produce a level of parasitaemia detectable by blood smear analysis; as such, the measurement of the pre-patent period by this method may be inaccurate and may include the impact of the anti-malarial strategy in the blood stage without providing a direct quantification of production and release of infective first-generation merozoites. Additionally, this assay presents similar sensitivity to the widely used PCR-based methods.
The requirement to use the chemiluminescent parasites further allows the combination with bioluminescence assays during liver stage infection to better discriminate the effects of distinct intervention strategies. The recent reports of luciferase-expressing parasites of different species, including P. yoelii as well as Plasmodium falciparum, will allow the expansion of this protocol to these species. Most importantly, the description of liver and blood-humanized mice (until now still in separate hosts) [14, 15] may soon allow the establishment of this assay to test different strategies against P. falciparum infection. As such, the use of different luciferase-expressing parasites may greatly accelerate and streamline the process of identifying and analysing future vaccine candidates as well as drug candidates against the pre-erythrocytic stages of malaria parasites, including those that may target the parasite at very late states or transition period between stages.
We would like to thank Ana Parreira for mosquito production and infection and Liliana Mancio-Silva for help with PCR experiments. This work was supported by Fundação para a Ciência e Tecnologia (FCT, Portugal) grants PTDC/SAU-MIC/113697/2009 (VZL) and EXCL/IMI-MIC/0056/2012 (MMM).
- Prudencio M, Rodriguez A, Mota MM: The silent path to thousands of merozoites: the plasmodium liver stage. Nat Rev Microbiol. 2006, 4: 849-856. 10.1038/nrmicro1529.View ArticlePubMedGoogle Scholar
- Derbyshire ER, Mota MM, Clardy J: The next opportunity in anti-malaria drug discovery: the liver stage. PLoS Pathog. 2011, 7: e1002178-10.1371/journal.ppat.1002178.PubMed CentralView ArticlePubMedGoogle Scholar
- Rodrigues T, Prudencio M, Moreira R, Mota MM, Lopes F: Targeting the liver stage of malaria parasites: a yet unmet goal. J Med Chem. 2012, 55: 995-1012. 10.1021/jm201095h.View ArticlePubMedGoogle Scholar
- Prudencio M, Mota MM, Mendes AM: A toolbox to study liver stage malaria. Trends Parasitol. 2011, 27: 565-574. 10.1016/j.pt.2011.09.004.View ArticlePubMedGoogle Scholar
- Amino R, Thiberge S, Blazquez S, Baldacci P, Renaud O, Shorte S, Menard R: Imaging malaria sporozoites in the dermis of the mammalian host. Nat Protoc. 2007, 2: 1705-1712. 10.1038/nprot.2007.120.View ArticlePubMedGoogle Scholar
- Portugal S, Carret C, Recker M, Armitage AE, Goncalves LA, Epiphanio S, Sullivan D, Roy C, Newbold CI, Drakesmith H, Mota MM: Host-mediated regulation of superinfection in malaria. Nat Med. 2011, 17: 732-737. 10.1038/nm.2368.PubMed CentralView ArticlePubMedGoogle Scholar
- Yu M, Kumar TR, Nkrumah LJ, Coppi A, Retzlaff S, Li CD, Kelly BJ, Moura PA, Lakshmanan V, Freundlich JS, Valderramos JC, Vilcheze C, Siedner M, Tsai JH, Falkard B, Sidhu AB, Purcell LA, Gratraud P, Kremer L, Waters AP, Schiehser G, Jacobus DP, Janse CJ, Ager A, Jacobs WR, Sacchettini JC, Heussler V, Sinnis P, Fidock DA: The fatty acid biosynthesis enzyme FabI plays a key role in the development of liver-stage malarial parasites. Cell Host Microbe. 2008, 4: 567-578. 10.1016/j.chom.2008.11.001.PubMed CentralView ArticlePubMedGoogle Scholar
- Valkiunas G, Iezhova TA, Krizanauskiene A, Palinauskas V, Sehgal RN, Bensch S: A comparative analysis of microscopy and PCR-based detection methods for blood parasites. J Parasitol. 2008, 94: 1395-1401. 10.1645/GE-1570.1.View ArticlePubMedGoogle Scholar
- Taylor SM, Juliano JJ, Trottman PA, Griffin JB, Landis SH, Kitsa P, Tshefu AK, Meshnick SR: High-throughput pooling and real-time PCR-based strategy for malaria detection. J Clin Microbiol. 2010, 48: 512-519. 10.1128/JCM.01800-09.PubMed CentralView ArticlePubMedGoogle Scholar
- Ploemen IH, Prudencio M, Douradinha BG, Ramesar J, Fonager J, Van Gemert GJ, Luty AJ, Hermsen CC, Sauerwein RW, Baptista FG, Mota MM, Waters AP, Que I, Lowik CW, Khan SM, Janse CJ, Franke-Fayard BM: Visualisation and quantitative analysis of the rodent malaria liver stage by real time imaging. PLoS One. 2009, 4: e7881-10.1371/journal.pone.0007881.PubMed CentralView ArticlePubMedGoogle Scholar
- Liehl P, Zuzarte-Luis V, Chan J, Zillinger T, Baptista F, Carapau D, Konert M, Hanson KK, Carret C, Lassnig C, Muller M, Kalinke U, Saeed M, Chora AF, Golenbock DT, Strobl B, Prudencio M, Coelho LP, Kappe SH, Superti-Furga G, Pichlmair A, Vigario AM, Rice CM, Fitzgerald KA, Barchet W, Mota MM: Host-cell sensors for plasmodium activate innate immunity against liver-stage infection. Nat Med. 2013, doi:10.1038/nm.3424. [Epub ahead of print]Google Scholar
- Miller JL, Murray S, Vaughan AM, Harupa A, Sack B, Baldwin M, Crispe IN, Kappe SH: Quantitative bioluminescent imaging of pre-erythrocytic malaria parasite infection using luciferase-expressing plasmodium yoelii. PLoS One. 2013, 8: e60820-10.1371/journal.pone.0060820.PubMed CentralView ArticlePubMedGoogle Scholar
- Vaughan AM, Kappe SH: Vaccination using radiation- or genetically attenuated live sporozoites. Methods Mol Biol. 2013, 923: 549-566.View ArticlePubMedGoogle Scholar
- Vaughan AM, Mikolajczak SA, Wilson EM, Grompe M, Kaushansky A, Camargo N, Bial J, Ploss A, Kappe SH: Complete plasmodium falciparum liver-stage development in liver-chimeric mice. J Clin Invest. 2012, 122: 3618-3628. 10.1172/JCI62684.PubMed CentralView ArticlePubMedGoogle Scholar
- Angulo-Barturen I, Jimenez-Diaz MB, Mulet T, Rullas J, Herreros E, Ferrer S, Jimenez E, Mendoza A, Regadera J, Rosenthal PJ, Bathurst I, Pompliano DL, Gomez De Las Heras F, Gargallo-Viola D: A murine model of falciparum-malaria by in vivo selection of competent strains in non-myelodepleted mice engrafted with human erythrocytes. PLoS One. 2008, 3: e2252-10.1371/journal.pone.0002252.PubMed CentralView ArticlePubMedGoogle Scholar
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