Figures
Abstract
Background
Here we report the monitoring of the digestive tract colonization of Rhodnius prolixus by Trypanosoma cruzi using an accurate determination of the parasite load by qPCR coupled with fluorescence and bioluminescence imaging (BLI). These complementary methods revealed critical steps necessary for the parasite population to colonize the insect gut and establish vector infection.
Methodology/Principal Findings
qPCR analysis of the parasite load in the insect gut showed several limitations due mainly to the presence of digestive-derived products that are thought to degrade DNA and inhibit further the PCR reaction. We developed a real-time PCR strategy targeting the T. cruzi repetitive satellite DNA sequence using as internal standard for normalization, an exogenous heterologous DNA spiked into insect samples extract, to precisely quantify the parasite load in each segment of the insect gut (anterior midgut, AM, posterior midgut, PM, and hindgut, H). Using combined fluorescence microscopy and BLI imaging as well as qPCR analysis, we showed that during their journey through the insect digestive tract, most of the parasites are lysed in the AM during the first 24 hours independently of the gut microbiota. During this short period, live parasites move through the PM to establish the onset of infection. At days 3–4 post-infection (p.i.), the parasite population begins to colonize the H to reach a climax at day 7 p.i., which is maintained during the next two weeks. Remarkably, the fluctuation of the parasite number in H remains relatively stable over the two weeks after refeeding, while the populations residing in the AM and PM increases slightly and probably constitutes the reservoirs of dividing epimastigotes.
Author Summary
Although the key aspects of the T. cruzi life cycle were described more than one century ago, the development and interactions of T. cruzi with its vector are poorly characterized. By dissection of different compartments of the triatomine gut (prototype Rhodnius prolixus) (i.e., AM, PM and H) at regular time intervals, we evaluated trypanosome development within the insect using an accurate qPCR assay. qPCR analysis of trypanosomal colonization and clearance dynamics in real-time were confirmed in vivo using both fluorescence and bioluminescence imaging, which revealed massive parasite lysis during the first 24 hours post-feeding (p.f.). After one week, the parasite succeeded in establishing a resident population in each compartment of the gut, albeit at varying levels. From one week after the onset of infection in the AM and PM, some resident forms agglomerated into rosettes, clustering in close association with the vector tissue and constituting potential parasite reservoirs of the bug. For the first time, we have described a methodology to accurately quantify parasites in the insect gut that would be a useful tool for evaluating the impact of RNAi silencing of insect genes during the course of infection by T. cruzi.
Citation: Dias FdA, Guerra B, Vieira LR, Perdomo HD, Gandara ACP, Amaral RJVd, et al. (2015) Monitoring of the Parasite Load in the Digestive Tract of Rhodnius prolixus by Combined qPCR Analysis and Imaging Techniques Provides New Insights into the Trypanosome Life Cycle. PLoS Negl Trop Dis 9(10): e0004186. https://doi.org/10.1371/journal.pntd.0004186
Editor: Alvaro Acosta-Serrano, Liverpool School of Tropical Medicine, UNITED KINGDOM
Received: March 18, 2015; Accepted: October 1, 2015; Published: October 23, 2015
Copyright: © 2015 Dias et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited
Data Availability: All relevant data are within the paper and its Supporting Information files.
Funding: This work was supported by grants from the Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq) (www.cnpq.br), Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES) (www.capes.gov.br), the Wallonie-Bruxelles International (WBI) (www.wbi.be)/Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES) bilateral cooperation agreement, Fundação de Amparo a Pesquisa do Estado do Rio de Janeiro (FAPERJ) (www.faperj.br), Instituto Nacional de Ciência e Tecnologia em Entomologia Molecular (INCTEM) (www.inctem.bioqmed.ufrj.br), Rio de Janeiro, Brazil, and Instituto Nacional de Ciência e Tecnologia de Biologia Estrutural e Bioimagem (INBEB) (www.imbebb.org.br), Rio de Janeiro, Brazil. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Competing interests: The authors have declared that no competing interests exist.
Introduction
Chagas disease is considered to be a neglected major parasitic tropical illness in Latin America that affects 7–8 million people distributed in 21 endemic countries and is responsible for 12,000 deaths each year (http://www.who.int/mediacentre/factsheets/fs340/en/). This disease is now an increasing worldwide public health problem due to the migration of infected subjects to non-endemic, more developed regions, mainly North America and Europe, where they could potentially transmit the disease by either hemotransfusion, organ donation, or pregnancy. Many of the chronically infected people develop severe and irreversible cardiovascular, gastrointestinal, and/or neurological problems that lead to a loss of productivity and high costs of medical care [1–3].
The etiological agent of Chagas disease is the protozoan Trypanosoma cruzi, which is transmitted in endemic areas principally via hematophagous triatomine insects [4]. Among the 140 triatomine species, Rhodnius prolixus is one of the most important vectors of Chagas disease in Central and South America and was chosen by researchers several decades ago as a prototype for the study of Chagas transmission, principally due to its use as a model for studies of insect physiology and biochemistry since the 1930s [5]. While some of the major features of the T. cruzi life cycle were described more than one century ago, the full development of the parasite within its vector remains poorly characterized. During its complex life cycle, the parasite encounters drastic environmental changes (e.g., temperature and pH) that are accompanied by major morphological and biochemical changes and cycling switches between multiplicative and non-proliferative stages. When the triatomine feeds on an infected vertebrate host, the bloodstream trypomastigotes are ingested and differentiate in the anterior midgut (AM) predominantly into epimastigote forms [4]. These latter forms replicate principally in the posterior midgut (PM) and can attach to the perimicrovillar membranes that cover the intestinal cells [6]. Some of these epimastigotes attach to the hindgut (H) wall and differentiate into infective metacyclic trypomastigotes that are released in the excreta [7,8]. During insect feeding on the blood of the mammalian host, contaminated feces and urine are released on the vertebrate host skin and subsequently enter the bloodstream by scratching the bite wound or via the mucosa.
The analysis of the development and distribution as well as the quantification of T. cruzi in different segments of the insect gut have been mostly based on optical microscopy approaches. To date, no standardized assay has been available to quantify parasites that are present at low levels in the gut. The classical technique for counting, using a Neubauer hemocytometer, has been employed to quantify T. cruzi in whole homogenates or gut contents, as well as in excreta samples [9–12]. Although useful for rapid quantification and to make comparisons between samples containing high parasite loads, this method is neither accurate nor statistical for samples containing a low parasite load, which is a common occurrence in the field [9]. Indeed, samples containing less than one parasite per microliter are not scored using the Neubauer counting chamber. In addition, the quantification of parasites in gut samples by microscopic counting is frequently hampered by the presence of a high concentration of erythrocytes in the AM, heme aggregates in the PM and H, and urate crystals in the H. Moreover, it may be complicated to discriminate immobile parasites from tissue debris and to count the exact number of parasites that form rosettes. Recently, the use of bioluminescent T. cruzi has revealed the feasibility of following the parasite distribution in vivo within the insect gut, thus providing the possibility of observing biologically relevant features of the parasite life cycle involved in vector-parasite interactions [13]. Similarly, the use of GFP-tagged T. cruzi as a microscopic tool for biological studies in infected hosts has been previously reported [14].
In contrast to the classical techniques, molecular-based assays such as quantitative real-time PCR (qPCR) allow a more sensitive quantitative analysis because these techniques are able to specifically amplify the parasite DNA sequence target [15,16]. However, the amplification of DNA samples extracted from the intact triatomine gut by PCR may be inhibited by the co-purification of several potential PCR inhibitors [17] such as heparin (added to blood to avoid clotting during artificial infection), polysaccharides (e.g., [18] polysaccharides produced by the microbiota), hemoglobin (released by hemolysis in the AM), hemozoin (heme aggregate, similar to hematin, which is produced in the PM [19]) and possibly uric acid (an end-product of purine metabolism that is highly abundant in the H).
The first aim of the present study was to describe an extraction protocol that allows the isolation of PCR inhibitor-free DNA from gut homogenates of triatomine bugs and to develop and evaluate the efficiency of a highly sensitive and accurate qPCR assay for the quantification of T. cruzi loads in these samples. Here, by combining this highly sensitive and accurate qPCR strategy with qualitative imaging analyses (fluorescence microscopy and BLI detection), we provide new insight into the dynamics of insect gut colonization that reveals several key features of the life cycle of T. cruzi.
Methods
Ethics statement
All of the animal care and experimental protocols were conducted in accordance with the guidelines of the institutional animal care and use committee (Comissão de Avaliação do Uso de Animais em Pesquisa da Universidade Federal do Rio de Janeiro, CAUAP-UFRJ) and the NIH Guide for the Care and Use of Laboratory Animals (ISBN 0-309-05377-3). The protocols were approved by CEUA-UFRJ (Comissão de Ética no Uso de Animais da Universidade Federal do Rio de Janeiro) under registry #115/13. Technicians at the animal facility of the Institute of Medical Biochemistry Leopoldo de Meis (UFRJ) performed all of the rabbit husbandry under strict guidelines to ensure careful and consistent handling of the animals.
Insects
The insects used herein were adult mated females obtained from a Rhodnius prolixus colony, maintained at 28°C and 75% relative humidity, and fed on New Zealand white rabbit blood.
Parasites
T. cruzi epimastigotes (Dm28c clone and CL Brener) were grown in liver infusion tryptose (LIT) culture medium containing 10% heat-inactivated fetal bovine serum at 28°C. Luciferase- and GFP-expressing parasites were grown in LIT in the presence of 200 and 300 μg/ml geneticin, respectively. Epimastigote forms were obtained during the log growth phase. Trypomastigote (Dm28c clone) forms from cell culture were obtained using metacyclic trypomastigote parasites to infect LLCMK2 host cells.
Generation of T. cruzi lineages expressing GFP and luciferase
pTEX-GFP–A fragment of 718 bp corresponding to the GFP coding region from plasmid pEGFP-C3 (Clontech Laboratories Inc., Mountain View, CA, USA) was amplified by PCR using the following oligonucleotides (For: 5´-GGGGGATCCATGGTGAGCAAGGGCGAGGAGCTGTT-3’ and Rev: 5´-GGGGGATCCTCACTTGTACAGCTCGTCCATGCCAGAGTGATC-3´) and cloned into the BamHI sites of the pTEX episomal expression vector [20]. The PCR reaction was performed using a PCR thermal cycler (model 9700, Applied Biosystems) for 30 cycles under the following conditions (94°C, 1 min; 55°C, 30 sec and 72°C, 1 min). The resulting supercoiled plasmid (100 μg) was transfected into mid-log phase T. cruzi epimastigotes (Dm28c) by electroporation using a gene pulser II electroporation system (Bio-Rad) as previously described [21]. Transgenic parasites were selected and maintained in complete LIT medium containing geneticin (150 μg/ml).
pBS:THT-Luc-T–pBS:THT–Luc–T integrative vector encoding firefly luciferase (a generous gift of David Engman, Northwestern University, Chicago) was used to achieve the stable integration of the luciferase gene into the trypanosomal tubulin locus. Ten micrograms of SalI-linearized plasmid was transfected into mid-log phase T. cruzi epimastigotes (Dm28c) using the Human T cell nucleofector kit in an Amaxa transfection device (set to program TX-011). Parasites were selected for resistance to hygromycin (50 μg/ml after 24 hours, increased to 200 μg/ml during drug selection), and luciferase activity was assessed by serial dilutions of the parasites in vitro.
pTREX-luc Dm28c strain (epimastigote and trypomastigote forms) (a generous gift from Cristina Henriques and Wanderley de Souza, UFRJ) were grown in the presence of 200 μg/ml geneticin. pTREX-luc is an integrative vector that targets the ribosomal locus. Trypomastigote forms from cell culture were obtained using metacyclic trypomastigote parasites to infect LLCMK2 host cells.
Gut microbiota cultivation
Rhodococcus rhodnii, the only cultivable bacterium that colonizes the gut of insects from our Rhodnius prolixus colony, was isolated from the AM of starved insects and grown in Luria-Bertani (LB) broth at 28°C with shaking (120 rpm). Estimation of bacterial concentration was performed by OD measurement at 600 nm using the Bioscreen C turbidimetric analyzer (Labsystems Oy, Helsinki, Finland). Bacteria were grown to log phase and harvested by centrifugation for posterior use in insect feeding. To establish axenic first instar nymphs, eggs were collected and washed with sodium hypochlorite (1%) for 40 seconds, and three times with sterile PBS. The eggs were laid to hatch in sterile vials and maintained at 28°C.
Infection
The experimental insects were allowed to feed through a latex artificial membrane feeding apparatus on heparinized (2.5 units/ml) and heat-inactivated rabbit blood (heated at 56°C during 45 min) containing 107 x ml-1 or 105 x ml-1 parasites (epimastigotes or trypomastigotes) expressing either GFP or luciferase. For infection, the adults were starved for 28 days and the first instar nymphs were used 5–7 days after hatching. Where indicated, adult and nymph insects were infected with T. cruzi plus, respectively, 108–109/ml R. rhodnii, or 105/ml R. rhodnii. In a specific set of experiments, the adult insects were fed with blood containing 1 x 107 heat-killed (65°C, 2 h) parasites per ml. Only fully engorged insects were used in the experiments. After infection, the insects were maintained as described above.
Epifluorescence microscopy
The insects fed with blood containing 107 GFP-expressing epimastigotes/ml were dissected in phosphate-buffered saline (PBS, pH 7.2), mounted between slides and coverslips and observed without fixation. Alternatively, the AM was opened with tweezers and mounted between slides and coverslips to allow a better analysis of the digestive cells in the apical region. Differential interference contrast (DIC) and fluorescence microscopy were performed using a Zeiss Axiobserver Z1 microscope with a 100 W mercury lamp filtered by a Zeiss-10 filter set for GFP (excitation–BP 450–490; beam splitter–FT 510; emission–BP 515–565). Images were acquired using a monochromatic Axiocam MRC5. Where indicated, color fluorescence image acquisition was performed using a Zeiss Axioplan 2 fluorescence microscope with a 100 W mercury lamp filtered by a Zeiss-09 filter set (excitation BP 450–490; beam splitter FT 510; emission LP 515) and acquired by a 10–24 mm Fujicolor Superia X-Tra film 400 ASA exposition. All of the obtained images were processed equivalently using Adobe PhotoShop.
Bioluminescent imaging
Insects infected with parasites expressing luciferase, or their dissected guts, were monitored, and images were acquired throughout the experimental period using the bioluminescent imaging system (IVIS-Lumina; Caliper, Hopkinton, MA). Images were analyzed using the Living Image 3.2 software. The imaging time was 5 minutes. Adult insects were injected in the hemocoel with 3 μl of luciferin substrate (VivoGlo luciferin in vivo grade (Promega), 15 mg/ml) using a Hamilton syringe prior to imaging. First instar nymphs were injected with 138 nl of the same solution using a nano-injector (Nanoject, Drummond) with glass capillary needles. In vivo experiments: fifteen minutes after injection, the insects were imaged in the dorsal position. Ex vivo experiments: fifteen minutes after injection, the insects were dissected, and the guts were imaged.
DNA extraction from digestive tract samples of infected insects
Several DNA extraction methods were tested to purify DNA from digestive tract samples of infected insects (phenol-choroform extraction, QIAamp DNA mini kit (Qiagen) and Cetyl trimethyl ammonium bromide (CTAB)). The classical phenol-chloroform method used to purify DNA from blood samples and animal tissues is not suitable for DNA purification from the insect gut because of its high content of hemozoin, which is invariably found in the PM and H samples harvested from days 3 to day 21 p.f.. As previously reported, even during blood sample processing, the presence of PCR inhibitors that are co-purified with DNA can affect the efficiency of the qPCR reaction and result in an underestimation of the parasite loads [22]. Another approach was attempted using a kit based on silica-DNA binding technology (QIAamp DNA mini kit, QIAGEN). The results showed that the efficiency of the DNA recovery was severely reduced by the presence of hemozoin, producing brownish DNA pellets, as confirmed by the false-negative PCR results. Only the latter technique, using CTAB, provided reproducible results, potentially due to the selective precipitation of DNA and elimination of hemin/hemozoin and polysaccharides. After infection with parasites constitutively expressing GFP, the AM, PM and H were extracted from cold-anesthetized insects at the indicated time points p.i.. Each gut section was homogenized separately in 1 ml of Solution A (1.5% CTAB; 2 M NaCl; 10 mM EDTA; 100 mM sodium acetate, pH 4.6). After homogenization, a 100-μl aliquot was transferred to a 2-ml microfuge tube containing 900 μl of Solution B (Solution A containing 10 μg salmon sperm DNA as DNA carrier, 10 ng of plasmid pLew82 (ble) [23] and 125 μg RNAse A per each 900-μl aliquot) and vortexed for 2 min. The samples were then heated for 30 min at 65°C for RNAse A activity. After the addition of 500 μl of chloroform, the samples were heated for 2 h at 65°C. Following this step, the samples were incubated for 10 min at RT and centrifuged at 9,000 × g at 25°C. After transferring a 600-μl aliquot of the aqueous phase to a new tube, 300 μl of chloroform was added to the samples followed by vortexing for 2 min. The samples were then incubated at RT for 10 min and centrifuged at 20,000 × g for 10 min at 25°C. A 400-μl aliquot of the aqueous phase of each sample was precipitated at -20°C for 1 hour after the addition of 1 μl of 20 mg/ml glycogen solution (Sigma-Aldrich) (or salmon sperm DNA (ssDNA), which provided comparable results), 40 μl of 3 M sodium acetate (pH 5.2) and 1 ml of ice-cold ethanol. The samples were then centrifuged at 20,000 × g at 4°C for 10 min. The DNA pellet was washed twice with cold 70% ethanol, dried at RT and resuspended in 50 μl of nuclease-free water.
Parasite standard calibration curve
T. cruzi DNA standards were obtained from either parasite-free whole gut homogenates from insects on day 7 p.f. or rabbit blood that was serially spiked with 107 parasites diluted 10-fold with nuclease-free water and containing 10 μg/ml salmon sperm DNA (ssDNA) to cover a range between either 105 and 0.001 or 2.5 x 106 and 2.5 parasite equivalents for the Dm28c and CL Brener lineages, respectively, per 5 μl of sample added to the reaction mixture.
Plasmid standard calibration curve
The standard calibration curve for the internal loading control (pLew82) [23] containing the ble resistance gene was performed using the same reconstituted samples as used for the parasite calibration curves; insect gut homogenates or rabbit blood samples were spiked with 10 ng of plasmid and serially diluted 10-fold with nuclease-free water containing 10 μg/ml salmon sperm DNA (ssDNA) to cover a range between 10 and 0.01 ng of plasmid.
Heterologous internal loading control
All of the samples were extracted in the presence of 10 ng of pLew82 plasmid used as a heterologous internal standard. The standard calibration curve for the internal loading control was used to determine the percentage of DNA recovery after extraction.
Real-time PCR and parasite quantification
qPCR was performed using a StepOnePlus real-time PCR system (Applied Biosystems) with Power SYBR Green PCR master mix (Applied Biosystems) in a final volume of 15 μl. The PCR reactions consisted of 5 μl of DNA sample and 500 nM of T. cruzi repeat DNA-specific primers [15], which amplify a 182-bp amplicon from tandemly repeated satellite DNA. Specific T. cruzi DNA-oligonucleotides were TcFw (5'-GCTCTTGCCCACAMGGGTGC-3'), where M = A or C, and TcRv (5'-CCAAGCAGCGGATAGTTCAGG-3'). In parallel, reactions containing 5 μl of DNA sample and 500 nM of oligonucleotides designed to PCR amplify a 148-bp fragment of the Sh ble gene from plasmid pLew82 were performed using the following set of primers: BleFw (5'-CAAGTTGACCAGTGCCGTTC-3') and BleRv (5'-GCTGATGAACAGGGTCACG-3') as loading control. The qPCR conditions used for both primers pairs were as follows: 10 min at 95°C followed by 40 cycles of 15 s at 95°C and 15 s at 60°C (data collection). The amplification step was followed by a melting curve analysis to ensure that a single product was amplified. The data were analyzed with StepOne software v2.3. Negative controls for both primer pairs consisted of a reaction with no DNA. For each primer set, the efficiency of the amplification was determined using the following formula: Efficiency (E) = -1 + 10 (−1/slope). The protocols used for the qPCR experiments followed the Minimum Information Required for Publication of Quantitative Real-Time PCR Experiments (MIQE) guidelines [24].
Normalization and quantification of parasite loads per gut section
Quantification of the parasite equivalents from DNA samples was calculated considering both the amplification curve of standard T. cruzi DNA and the percentage of DNA applied to the well. The results were normalized according to the heterologous internal standard amplification curve.
Results
Analytical sensibility of qPCR with CTAB-purified DNA for distinct phylogenetic T. cruzi lineages
Among the several extraction methods tested to purify the DNA from the insect gut (phenol-chloroform, QIAamp DNA mini kit (Qiagen) and CTAB), only the latter provided reproducible results and no inhibition of the PCR reaction. Therefore, this method was chosen to purify the DNA. Similarly, particular attention was paid to the concentration of heparin added to the blood as an anticoagulant for the extraction of plasma DNA due to its well-known inhibitory effect on the PCR reaction [17]. The use of citrate or EDTA as anticoagulants was discarded because of their toxicity to the insect, which becomes especially evident over long periods of time p.f..
As expected, the DNA recovery from the different gut samples was highly variable even in the presence of ssDNA as the DNA carrier, requiring a heterologous internal loading control to normalize the DNA recovery for each sample extraction. We first assessed the efficiency of the PCR amplification of the internal standard using serial dilutions of plasmid containing the ble resistance gene spiked into heparinized rabbit blood for comparison to that of the purified T. cruzi DNA targeting repetitive satellite sequences [15]. Highly similar amplification efficiency percentages were obtained for both amplicons (E = 0.95 for satellite DNA vs. E = 0.96 for ble), thus validating the use of the internal standard for qPCR (S1 Fig). Therefore, the sensitivity of the T. cruzi satellite DNA-based qPCR was determined by serial dilution of purified DNA from Dm28c (TcI) and CL Brener (TcVI) reference stocks after normalization by plasmid DNA spiked into the blood lysate (Fig 1). The qPCR provided a detection limit of 1 and 0.01 parasite equivalents (for a cycle threshold (Ct) number of approximately 25) for the CL Brener and Dm28c lineages, respectively. The parasite concentrations lower than 0.01 were still detectable but at a higher Ct value (approximately 30), which was close to the detection limit background. Dynamic ranges, amplification efficiencies and R2 values (coefficient of determination) were, respectively, 0.01−104 and 1−105 parasite eq., 89 and 95% and 0.998 and 1.000, for the CL Brener and Dm28c lineages. To determine whether some trace of PCR inhibitor isolated from the total gut homogenates was able to affect both the PCR efficiency and sensitivity, we performed qPCR amplifications for Dm28c by replacing blood DNA with tissue-specific insect homogenates of the entire digestive tract (AM, PM and H) dissected one week after the blood-meal spiked with various parasite quantities (S2 Fig). The dynamic range, amplification efficiency and R2 value were, respectively, 0.001−104 parasite eq., 92% and 1, which were similar to those provided by the blood DNA extract. Thus, standard curves with a similar high sensibility were generated independently of the DNA origin, validating the robustness of the qPCR assay.
The results are expressed as parasite equivalents/50 ng DNA. The slope and regression coefficient of the curves as well as the amplification efficiency for each parasite lineage are indicated.
These data revealed that the use of the Moser-modified primers [15,25] designed to amplify satellite DNA from different T. cruzi lineages purified from blood or insect gut homogenates, combined with an internal standard (ble), successfully produced an accurate standard parasite calibration curve in both reference stocks. Thus, this methodology provides an optimized reliable qPCR assay that is adapted to quantify parasite DNA in the insect gut.
Quantitative monitoring of T. cruzi load in the R. prolixus digestive tract
We assessed the parasite load of bugs that were artificially fed on decomplemented infected blood containing 107 epimastigotes (Dm28c)/ml and dissected after different periods of time over three weeks (Fig 2A). During the first 24 hours p.i., ~ 92% of the parasites were lysed, and most of the live trypanosomes (1.9 x 105 cells corresponding to 98.69% of the live parasites) were present in the AM while a resident population started to colonize the PM (1.29%). At day 4 p.i., the parasite population started to colonize the H, reaching a higher density at day 7 p.i. (~ 104 parasite equivalents), while approximately 6.8% ± 2.78 (SE) (n = 5) of the total cells counted were metacyclic parasites (Fig 2B). At day 14 p.i., the proportion of metacyclic parasites increased and represented 25.2% ± 4.22 (SE) (n = 10) of the total population. It is noteworthy that two weeks after refeeding, the proportion of metacyclic parasites remained stable at 19.1% ± 2.05 (SE) (n = 10) (Fig 2B). Concomitantly, to the increase in the number of parasites from the rectum, the population from the AM dropped to its lower level after three weeks p.i. (a few dozen parasites). In contrast, the trypanosome populations in both the PM and H remained constant over two weeks with 103 to 104 parasite equivalents, respectively (Fig 2A). In an attempt to characterize the clearance dynamics, infected bugs were fed on decomplemented blood at three weeks after infection, and the parasite number was assessed by qPCR over two weeks in each segment of the gut (Fig 2A, arrow). Surprisingly, the three populations maintained a similar level of parasites despite the diuresis and urine flux mobilized during this process. This relative constant level of parasite populations possibly reflects the tight interactions between the vector and parasite [6] and results of the equilibrium between the number of parasites generated by cell replication and the number of parasites released in the excreta. In both the AM and PM, a slight increase in parasite numbers was observed, suggesting the presence of parasite nests that served as reservoirs (see results below).
(A) Follow-up of parasite development in the anterior midgut (AM), posterior midgut (PM) and hindgut (H) post-infection (p.i.) and post-feeding (p.f.). Adult insects were fed with 107 cells/ml of blood. The arrowhead and arrow indicates, respectively, the time of the initial infection and refeeding with a blood meal without parasites (21 days p.i.). Each time point represents three independent experiments (n≥8). The percentage of metacyclic trypomastigote forms (mean ± SE; n = 10) determined in the hindgut contents at 7 and 14 days p.i. and 14 days p.f. are indicated. (B) Monitoring of the DNA clearance of heat-killed parasites. Infections were performed with live parasites or parasites killed by incubation at 65°C during 2 hours before injection. n≥4 for each time point. (C) Comparison between the gut colonization of R. prolixus by T. cruzi Dm28c (left panel) and CL Brener (right panel). Each time point represents three independent experiments (n≥8). At several time points, the insects were dissected, and total DNA was extracted individually from the different gut segments and used to assess the parasite number by qPCR.
The massive lysis event observed 24 hours after infection raised the possibility that the DNA provided by the dead parasites could contribute to an overestimation of the parasite load in the gut. To assess the amount of DNA template released from dead parasites remaining in the digestive tract that could eventually be amplified by qPCR, we performed a controlled experiment using insects fed with blood containing 107 heat-killed parasites/ml (Fig 2C). In the AM and PM, 24 hours p.f. was sufficient to decrease the number of parasites to three logs below that obtained with live parasites, whereas at four days p.f., the contribution of the remnant DNA fell to only 4 logs below that of insects fed with live parasites. Thus, the initial contribution of DNA from lysed parasites represents only ~ 0.1% of the total number of parasites. Finally, the kinetics of parasite DNA degradation by insect gut nucleases showed that 7 days were necessary to completely remove all of the remnant DNA. These data suggest that the quantitative monitoring of the parasite load by qPCR is a reliable measurement for live parasites despite the large number of parasites that were lysed at the beginning of infection.
Next, we compared the colonization of the bug by the Dm28c strain (left panel), which belongs to TcI, a group related to the sylvatic cycle, with that of CL Brener (right panel), another T. cruzi lineage, which belongs to TcVI, a group related to human/domestic cycle (Fig 2D). Similar profiles of parasite CL Brener loads were generated in the different compartments of the gut, although a significant increase in resistance to lysis was observed, especially in the PM where the relative number of parasites reached 106 on day 4 p.i., i.e., a difference of two and half logs compared to that observed for the Dm28c lineage (5 x 103 parasites). After two weeks, the parasite load became stable in all of the gut compartments and reached a maximal value in the H (approximately 105 cells). Altogether, these results show that the qPCR methodology can be used in a straightforward manner to study the colonization dynamics in insects infected by different parasite lineages.
Monitoring of trypanosome infection using fluorescence and bioluminescence imaging
We qualitatively investigated the presence of live parasites in the digestive tract by BLI and fluorescence microscopy to compare these data with those obtained by qPCR. Using a Dm28c lineage constitutively expressing luciferase (pBS:THT-Luc-T integrative construct), AMs filled with parasites expressing saturating amounts of photons were observed immediately after the blood meal (red signal corresponding to radiance ~ 1.9 x 106 p/sec/cm2/sr) (Fig 3A and 3B and S3 Fig) with some variability in photon emission reflecting the variable amount of blood ingested by the bugs (average of 242.9 ± 27.9 μl, n = 10 ± SD). After 6 hours, the light emission was significantly reduced in the AM, and most of the high intensity signal moved towards the posterior part of the insect abdomen. After 24 hours, the signal disappeared completely from the AM correlating with a large decrease in maximal radiance photon emission, and some red spots were distributed across the posterior end of the insect abdomen (Fig 3A and 3B). From days 3 to 7 p.i., we observed a decrease in the luminescent signal and, in some cases, a recolonization of the AM that could be explained by either dividing resident epimastigotes and/or parasites that had moved back from the PM (Fig 3C). Although the decrease in luminescence was proportional to the decrease in parasite number, as attested by the maximal radiance photon emission that correlated positively with the number of cells in vitro (Fig 3D) as previously reported [13], the use of BLI for the in vivo quantification of parasites in intact insects is clearly limited by the high detection threshold limit inherent to the technique. After 2 weeks, the signal was reduced to some punctuated parts of the PM. One to two weeks after refeeding, the luminescent signal disappeared completely from the insect midguts (Fig 4A and 4B) and was limited to the rectum (Fig 4C). Altogether, the BLI data corroborated the qPCR results showing a massive lysis that occurred during the first 24 hours p.i. and demonstrated that this process started very early, approximately 6 hours after the blood meal (Fig 5A and 5B). Ex vivo dissection confirmed the migration of the parasites to the PM and the complete absence of signal in the AM (Fig 5C and 5D). To analyze whether the cell lysis event was due to the bacterial endosymbionts of the triatomine bug, such as the actinomycete Rhodococcus rhodnii, which is the only cultivable gut bacterium found in our insect colony, we infected insects with blood containing either T. cruzi expressing luciferase or T. cruzi expressing luciferase plus different R. rhodnii concentrations (2 to 10 times higher than that in the starved AM of R. prolixus [26]). Although the bacterial load was considerably increased, no significant difference in the luminescent signal intensity was detected 24 hours p.i. between the two insect groups (Fig 5E). We also checked that heparin (2.5 U/ml), added to the blood as anticoagulant, had not effect on the in vitro growth of R. rhodnii (S4 Fig). These data suggested that under our experimental conditions, the gut microbiota did not appear to be involved in the drastic reduction of the epimastigote parasite number. We investigated whether such a decrease could be observed using trypomastigote parasites, which are supposed to be a more robust and resistant form that is adapted to the bloodstream of the vertebrate host [27] and corresponds to the stage that infects the insect vector under natural conditions. Using a Dm28c lineage constitutively expressing luciferase (pTREX-Luc integrative construct) in both epimastigotes and trypomastigotes in culture, we observed a large decrease in the luminescent signal after 24 h in both parasite life stages (Fig 6A). Whereas the trypomastigote parasites expressed approximately 10 times less luminescence than the epimastigote forms (Fig 6B), which is compatible with the 10-fold decrease of the transcription rate for RNA pol I in infective forms [28], from 6 h to 24 h, they displayed a luminescent signal reduction higher than that observed in epimastigotes, representing 0.77% and 16.2% of the ingested parasites, respectively. The observation that both the insect and bloodstream trypomastigote forms displayed a similar large decrease in photon emission indicated that the cold-shock was not responsible for the lysis of epimastigote parasites. We next investigated whether trypomastigote decrease was also unaffected by the gut microbiota, using first instar nymphs presenting the advantage to be naturally gut microbiota-free. Germ-free first instar nymphs were fed on decomplemented blood containing either T. cruzi trypomastigotes or epimastigotes (~ 105 cells/nymph) expressing luciferase in the presence or absence of R. rhodnii (103 bacteria/nymph) (Fig 6C and S5 Fig). Similar amplitude of decrease in the luminescent signal after 24 h was observed in both parasite life stages of nymphs infected or not by R. rhodnii arguing that gut microbiota is not involved in the parasite lysis of both stages during the first 24 h after blood meal.
(A) Insects were infected with T. cruzi Dm28c epimastigotes constitutively expressing luciferase, and time-course monitoring of infection was assessed for two weeks by BLI. (B) Quantification of the luminescence signal emitted by the infected insects at the times indicated in A. (C) In vivo luminescence evaluation of insects at day 3 and 7 p.i. and ex vivo at day 7. (D) Correlation between the bioluminescence emission measured in each well and parasite number. The images are representative of at least 24 insects analyzed at each time point in three independent experiments. The images of all of the insects analyzed at each time point were used to quantify the mean of the emitted luminescence signal.
In vivo (A, B) and ex vivo (C) BLI showing that at one to two weeks after refeeding, most of the parasites remains densely packed in the rectum, as evidenced by the punctuated luminescent signal located at the end of the digestive tract.
(A) The images show the drastic reduction of the luminescence signal in the AM. (B) Quantification of the BLI signal emitted by the whole intestine obtained at different times as indicated in A. (C) Ex vivo BLI confirming that the signal was located exclusively in PM 24 hours p.i.. (D) Quantification of the BLI signal emitted by AM (a) and PM (b) at 0 and 24 hours after infection. (E) Effect of the microbiota on parasite lysis and BLI reduction. The insects were infected with parasites alone (Tc) or with parasites plus 2.5 x 107 or 2.5 x 108 Rhodococcus rhodnii per ml of blood. Two independent experiments (n = 16) were conducted, and the results were analyzed by one-way ANOVA.
(A) Representative values of the luminescence emission for epimastigotes and trypomastigotes at 6 h and 24 h. Epi 6 h vs. Epi 24 h, P<0.01; Trypo 6 h vs. Trypo 24 h, P<0.0001. ANOVA followed by Tukey's multiple comparisons test. (B) Quantification of the BLI signal emitted by adult insects infected with various amounts of epimastigotes (Epi) or trypomastigotes (Trypo). (C) Quantification of the BLI signal emitted by gut microbiota-free first instar nymphs fed with epimastigote (Epi) or trypomastigote (Trypo) forms (107 cells/ml), in the presence or absence of R. rhodnii. In each stage ± bacteria, 6 h vs. 24 h, P<0.001. ANOVA followed by Tukey's multiple comparisons test.
Because of the high detection limit inherent to the BLI method, we used GFP-tagged parasites to check the relative parasite abundance and distribution, its morphology and the host tissue associations by fluorescence microscopy. At 24 hours p.i., the AM displayed a relative parasite density that was smaller than expected and was mainly represented by parasites near the epithelium. This phenomenon was due to both the presence of a large amount of intact erythrocytes that scattered the parasites and the globular form of the AM, which prevented the visualization of GFP-tagged parasites located in deeper sites (Fig 7A). S1 Video illustrates this feature showing parasites with a high fluorescence emission signal at the border of the epithelium and others deeper in the lumen of the midgut with a low emission signal [4,29]. From days 4 to 7 p.i., when the total parasite population decreased in the AM (Fig 7B and 7C), we observed free-swimming parasites and aggregates of trypanosomes forming rosettes (Fig 7D and 7E), some of these aggregates were associated with the gut wall (Fig 7F and 7G and 7H). In the PM, while the total parasite number remained unaltered during this period (Figs 2A and 7I and 7J), we detected a massive presence of parasites concentrated in some regions of the PM, frequently as trypanosome aggregates (Fig 7K and 7L). S2 Video shows that among the parasites scored in the PM, some were free-swimming while others appeared to be attached to the epithelium, possibly via the perimicrovillar membrane [6]. In the H, we observed a relative increase in the number of parasites from days 4 to 21 p.i. (Fig 7M and 7N and 7O), among which an important proportion was attached by the flagellum to the wall of the rectum (S3 Video) as previously reported by Schaub et al [30].
The images show the presence of green fluorescent parasites colonizing the AM (A-H), PM (I-L) and H (M-R). (A-C) Fluorescence images of the AM showing free-swimming parasites at days 1, 2 and 7 p.i., respectively. (D-H) Fluorescence and DIC images showing parasite aggregates, at day 1 p.i. (D, E), and day 4 p.i. (F-H). The asterisks indicate aggregate of parasites associated to gut wall. (I-K) Fluorescence images of the PM at days 1, 2 and 7 p.i.. (L) Fluorescence image at day 4 p.i.. The asterisk indicates a cluster of parasites in the lumen of the PM. Fluorescence and DIC images of the H at days 4 (M, P), 7 (N, Q) and 21 (O, R) p.i., respectively. Scale bars: (A-H) 50 μm; (I-K) 50 μm; (L) 10 μm; (M-R) 50 μm. A-E, I-K, M-Q and F-H and L images were performed, respectively, using a Zeiss Axioplan 2 fluorescence microscope and a Zeiss Axioplan 2 fluorescence microscope.
Evaluation of dynamics of gut colonization by T. cruzi under natural conditions
The high optimization of qPCR leading to a high sensitivity of detection (detection limit of 1 and 0.01 parasite equivalents, respectively, for the CL Brener and Dm28c lineages), constitutes a proof of principle to assess the dynamics of natural infections of insects, which are frequently infected by low densities of bloodstream trypomastigotes (≤104 parasites/insect). Therefore, we assessed the parasite load of insect adults artificially fed on decomplemented infected blood containing either 105 trypomastigotes/ml or 105 epimastigotes/ml (Dm28c) that were dissected after different periods of time over three weeks (Fig 8A and 8B). Similar profiles of parasite loads were observed throughout the different gut compartments of insects fed with epimastigotes or trypomastigotes. The insects were initially infected by approximately 2.5 x 104 parasites and similarly to that previously observed, during the first 24 hours p.i., around 90% of these parasites were lysed (87.32% and 87.35% of trypomastigotes and epimastigotes, respectively) with a preferential colonization in the AM (corresponding to 97.18% and 98.9% of live epimastigotes and trypomastigotes, respectively). The resident population of epimastigotes that was initially present in the PM multiplied 12.9-fold in 24 h to colonize the PM while in the case the of insect fed by trypomastigotes we observed a lower increase of 3.1-fold, which is due to the differentiation of quiescent trypomastigotes to dividing epimastigotes. In the H, the parasite population of trypomastigotes reached its climax at day 7 p.i. (~ 102 parasite equivalents) and stabilized over two weeks as it did in the PM with around 101 to 102 parasite equivalents of epimastigotes and trypomastigotes, respectively. After three weeks p.i., the AM populations had almost disappeared (approximately 1 parasite equivalent). Similarly to that observed previously, two weeks after refeeding insects infected by epimastigotes or trypomastigotes, a constant level of parasites was maintained within a similar range in each gut compartment, although a little bit higher in insects infected by trypomastigotes (Fig 8A and 8B arrow). Thus, the rate of insect infection by trypomastigotes is almost identical to that of epimastigotes displaying similar kinetics of colonization of the gut by low level of trypomastigotes leading to fully competent vector two weeks after refeeding. We can also conclude that the amplitude of the peaks of population fluctuating in the gut is function of the number of parasites that was initially ingested by the insect at the beginning of the infection.
Follow-up of parasite development in the anterior midgut (AM), posterior midgut (PM) and hindgut (H) post-infection (p.i.) and post-feeding (p.f.) in epimastigotes (A) and metacyclics trypomastigotes (B). Adult insects were fed with 107 cells/ml. The arrowhead and arrow indicates, respectively, the time of the initial infection a trypomastigotes and refeeding (21 days p.i.). At several time points, the insects were dissected, and total DNA was extracted individually from the different gut segments and used to assess the parasite number by qPCR. Each time point represents an experiment (n = 8).
Discussion
In the present study, we report a highly sensitive and accurate qPCR strategy combined with qualitative and semi-quantitative imaging analyses for the quantification of the parasite load in each segment of the digestive tract and provide insight into the dynamics of insect gut colonization. While it is clear that blood digestion constitutes the principal function of the insect gut, very little is known about the proteins that are involved in the vector response after a blood meal and how they affect both trypanosome infection and gut colonization. During its journey through the insect gut, the parasite must adapt to several harsh environments that it will encounter, first in the AM where blood is stored and erythrocytes are lysed, followed by the PM were blood proteins are digested and heme is detoxified to generate large amounts of crystalline hemoglobin, and finally in the rectum where urate crystals accumulate and blood remnants are excreted. All of these by-products derived from blood digestion are susceptible to co-precipitate during DNA purification and inhibit further PCR reactions. In this respect, the use of CTAB for DNA extraction possesses several advantages over other purification methods (e.g., phenol-chloroform, silica-DNA binding technology): (i) it removes polysaccharides, such as chitin, a constituent of the hindgut procuticle, and bacterial polysaccharides supposed to be highly abundant in the digestive tract of Rhodnius (e.g., capsular polysaccharides produced by Rhodococcus sp.) [31–33]; (ii) the CTAB acidic buffer (pH 4.6) leads to the formation of hemin and hemozoin precipitates and thus do not interfere with both DNA recovery [34] and efficiency of PCR reaction.
Regarding the qPCR strategy developed in the present study, the primers designed by Moser and colleagues [25] and subsequently modified by Cummings and Tarleton [15] were found to be efficient for the accurate quantification of parasite loads in tissue independently of both the parasite lineages used (such as Dm28c (TcI), and CL Brener (TcVI)) and the parasite stage. In addition, the use of exogenous DNA plasmid rather than an internal marker (insect DNA marker) spiked into the insect gut samples was crucial to ensure the appropriate normalization for accurate quantification of parasite loads due to the occurrence of individual differences in the number of gut epithelial cells.
Our results showed that the qPCR methodology developed herein allowed the determination of parasite numbers in ranges far below that obtained using the Neubauer chamber for cell counting (threshold limit ~ 10 cells/μl of gut macerate). Using a similar artificial infection protocol and counting the parasites in a Neubauer chamber, we observed that, in most of cases, we were unable to detect any parasites in the different segments of the digestive tract and only scored those insects with high parasite loads (S6 Fig). This sampling bias does not produce reliable results to follow insects infected with low parasite densities (<104 parasites/insect), which is frequently observed in natural infections [35]. In addition, in contrast to our results, this method does not allow the detection of parasites in the AM at p.i. times beyond ten days [36] and misses parasites that adhere to insect tissue. This contrasts with our qPCR methodology, which allows the detection of up to 1 parasite/AM, two weeks after the refeeding of infected vectors with low level of parasites (~ 104 parasites) but also cell aggregates. In this respect, it is noteworthy that the presence of parasite nests observed in both AM and PM from day 7 p.i. might function as reservoirs to maintain a basic rate of metacyclogenesis in the vector that is necessary to assure an optimized vectorial competence throughout the life of the infected insect, which can live up to one year under regular feeding conditions [4]. We hypothesized that the presence of small reservoirs of epimastigote parasites in the midgut could be boosted upon blood refeeding, causing the maintenance of the parasite number to a constant level in the different gut compartments with a slight increase in parasite load in the AM and PM at three weeks after infection. The observation that the percentage of metacyclogenesis scored at day 14 p.i. (25.2%) was in a similar range to that scored at day 14 after the second blood feeding (19.1%) supports a control system that balances the relative proportions of dividing epimastigote cells and metacyclic quiescent cells. We postulate that this mechanism that leads to the fine-tuning of the parasite load in each segment of the digestive tract should provide a basic rate of metacyclogenesis that is required to increase the period of vectorial competence.
Previous reports have shown that the kinetics of digestive tract colonization is dependent on several parameters such as the rate of insect infection by metacyclics (or epimastigotes), the efficiency of differentiation from metacyclics to epimastigotes, the multiplication of epimastigotes inside the gut and finally their transformation to metacyclic trypomastigotes. These parameters rely on the species of insect vector, the nature of the gut microbiota [37,38] and the strain or lineage of the infecting parasites [9]. In this respect, our data confirmed the variability in infection level between two different T. cruzi lineages, although the parasite load curves displayed a similar pattern. Indeed, CL Brener compared to Dm28c exhibited a higher resistance phenotype to lysis, as evidenced by the high percentage of epimastigote forms in the gut (especially in the PM); however, the onset of infection through different segments of the gut followed a similar time course [9]. Our data also showed that independently of the parasite stage used for infecting the insect (epimastigote or trypomastigote forms), the gut colonization followed a similar profile, with a dramatic decrease in parasite number during the first 24 h after infection, which was already noted by Henriques et al. (2012) [13] but at latter times, on the seventh day p.i., and representing 4.5% of ingested trypomastigotes. We show that this decrease is observed in the AM, which represents the first point of contact between the ingested parasites and the vector surface, which is composed of epithelial cells that are devoid of a perimicrovillar membrane [4]. These results suggest that the lysis event may be due to some lytic factor that is able to kill both forms of the protozoan, in particular the trypomastigote, which is the natural form ingested by the insect and is also, despite greater resistance than the epimastigote form to several stress treatments such as complement [39], is also susceptible to lysis in the insect gut. As previously suggested, several factors related to vector immunity could be responsible for this severe reduction in parasite load (e.g., lectins, antimicrobial peptides (AMPs), and nitric oxide) [40], but other contributing factors could include digestive enzymes and other biochemical factors. In addition, some studies have shown that the microbiota of the triatomine might be involved in the control of the population density of epimastigotes in the gut but this effect is observed at latter times (3 days p.i.) and is not observed for most of the T. cruzi lineages such as Dm28c [41]. In contrast, our data show that the initial lysis of the Dm28c parasites observed during the first 24 h in the AM is independently of the presence of gut symbionts and may be due to some factors of the innate immune system of the vector that are released during hemoglobin digestion or that are already present in the AM. Several immunity-related components present in the AM might play a central role in the control of the parasite density. Among these factors, AMPs could play a critical role in limiting the infection of the vector, as reported for trypanosomal vectors [42–44]. Other putative trypanolytic factors such as lectins could play a role in determining the outcome of the infection. Lectins were found overexpressed in the AM and PM after a blood meal and have been reported to be involved in the agglutination of parasites [45]. A hypothetical hemolytic factor isolated from AM extracts and supposed to be involved in erythrocyte lysis was reported to lyse the T. cruzi Y strain more efficiently than the Dm28c strain in vitro [41,46]. In this regard, not only the parasite strain but also the source of the blood used to feed insects would be important to take into account to study the lysis event [47]. ROS and nitrogen intermediates could also play a role in the control of T. cruzi infection in the triatomine gut [48,49]. Regarding the digestive enzymes, although no proteolytic activity was detected in the AM [50, 51], the transcriptome study of the digestive tract of Rhodnius revealed an abundance of transcripts encoding aspartyl protease (in particular, cathepsin D-like enzyme) and cysteinyl proteases [52]. In addition, we cannot discard the possibility that some proteolytic enzymes became fully active in the AM through the clipping off of the proprotease precursors by some trypanosomal proteases such as the cruzipain, which is the major cysteine protease in the parasite.
Taken together, our data reveal some unexpected biological features of the colonization of the R. prolixus midgut by T. cruzi that may be critical for the investigation of parameters involved in vectorial competence. In laboratories performing xenodiagnosis in chagasic patients or infecting triatomines experimentally, the rate of infection is highly variable and often includes a significant number of insect vectors with no parasite score. Similarly the vector infection rate in endemic regions for Chagas disease is markedly variable, ranging from 5% (Brazil) [53] (Data from Pan American Health Organization) to 79% (Bolivia) [54]. It has been proposed that this low infection rate might be due to the lysis of ingested parasites with the blood meal, which, in some cases, could lead to complete parasite lysis with no survival [55]. Our observations confirmed a massive lysis of both epimastigote and trypomastigote parasites during early stages of infection, which could explain the refractivity of the natural vectors to parasite infection or transmission. In addition, we showed that a low rate of infection can be maintained in the vector that would be necessary to increase the vectorial competence for disease transmission.
Finally, the methodology developed in this work for accurately quantifying low levels of parasites in the gut of the triatomine vector constitutes a useful tool to get insight into the dialog between the parasite and its vector. The use of dsRNA for targeting candidate genes involved in the innate immune response of the vector would help in mapping the key factors responsible for parasite killing in the midgut of the vector. At this respect, the use of first instar nymphs that ingest around 20 times less blood than adults would allow us to develop a high-throughput RNAi library screening strategy delivered via bacterial feeding, using BLI as readout, to identify key insect factors that could be involved in the infection output, in particular in the context of the massive lysis event. To conclude, the techniques developed in this study to monitor insect infection constitute a toolbox helpful to screen insect or parasite genes involved in the infection outcome.
Supporting Information
S1 Fig. Representative standard qPCR calibration curves generated from 10-fold serial dilutions of blood spiked with internal loading control (plasmid pLew82) and T. cruzi Dm28c.
The plot shows representative Ct values of the amplification curves generated with primers targeting the ble resistance gene or the T. cruzi repetitive satellite DNA. DNA samples were sequentially diluted 10-fold to obtain from 0.01 to 10 ng of pLew82/50 ng DNA and from 0.02 to 20 ng of T. cruzi DNA/50 ng DNA considering that approximately 2 x 10−4 ng of parasite DNA corresponds to one parasite equivalent. The amplification efficiency of both PCR reactions are indicated.
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S2 Fig. Standard amplification curves generated from DNA extracted from digestive tract homogenates spiked with epimastigotes of T. cruzi Dm28c.
The plots show representative Ct values of the amplification curves generated with primers targeting T. cruzi repetitive satellite DNA. DNA samples were sequentially diluted 10-fold to obtain from 0.001 to 10000 parasite equivalents. The results are expressed as parasite equivalents/50 ng DNA. The slope and regression coefficient of the curve and the amplification efficiency are indicated.
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S3 Fig. In vivo time-course evaluation of infection dynamics during the 24 hours after infection of insects with luciferase-expressing parasites.
The images show bioluminescence imaging of infected insects at the indicated times.
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S4 Fig. Evaluation of heparin on in vitro growth of R. rhodnii.
(A) In vitro bacteria growth was monitored in the presence (+) or absence (-) of heparin (2.5 units/ml) during 72 hours by OD measurement at 600 nm. OD values (mean values, n = 6) were plotted versus time (hours). (B) Bacteria cultivated in the presence or absence of heparin during 72 hours were serially diluted and plated on LB agar plates for colony forming units (CFU) counting. Representative plates are shown.
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S5 Fig. Comparison of time-course development of epimastigotes and trypomastigotes expressing luciferase in the digestive tract of nymphs during the first 24 h p.i., in the presence or absence of R. rhodnii.
The nymhs were fed on rabbit blood containing 1 x 107 epimastigotes (Epi) or trypomastigotes (Trypo) of T. cruzi (Dm28c) per ml containing or not 5 x 105 Rhodococcus rhodnii per ml of blood. The time-course monitoring of infection was assessed at 6 h (0 d) and 24 h after the infection (1 d) by bioluminescence imaging of parasites constitutively expressing luciferase. The pictures were taken from three representative nymphs among the eight infected in each condition.
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S6 Fig. Evaluation of infection dynamics by counting the parasites in a Neubauer chamber.
The insects were fed on blood containing 107 epimastigotes/ml and dissected after feeding at the indicated times. The anterior midgut (AM), posterior midgut (PM) and hindgut (H) were individually homogenized in 50 μl of PBS. The parasites in a 10-μl homogenate aliquot were counted.
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S1 Video. In vivo imaging of GFP-tagged parasites in AM of R. prolixus at 7 days p.i.
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S2 Video. In vivo imaging of GFP-tagged parasites in PM of R. prolixus at 7 days p.i.
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S3 Video. In vivo imaging of GFP-tagged parasites in H of R. prolixus at 7 days p.i.
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Acknowledgments
We thank David Engman (Northwestern University, Chicago) for the pBS:THT-Luc-T luciferase construct, Cristina Henriques and Wanderley de Souza (UFRJ) for the T. cruzi luciferase strain (pTREX-luc), Leila da Conceição F.D. Oliveira, Daniela O. Faustino and Julio Scharfstein (UFRJ) for technical support with the production of trypomastigote Dm28c expressing luciferase and helpful suggestions. We also thank José de S. Lima Jr. and Gustavo Alifor for insect care, and S. R. Cássia for general assistance.
Author Contributions
Conceived and designed the experiments: DS. Performed the experiments: FdAD BG ACPG HDP LRV RJVdA SAOG FAL DS. Analyzed the data: FdAD MHFS EM REV PLdO DS. Contributed reagents/materials/analysis tools: EM DS PLdO. Wrote the paper: FdAD DS.
References
- 1. Maguire JH (2006) Chagas' disease—can we stop the deaths? N Engl J Med 355: 760–761. pmid:16928993
- 2. Teixeira AR, Nascimento RJ, Sturm NR (2006) Evolution and pathology in chagas disease—a review. Mem Inst Oswaldo Cruz 101: 463–491. pmid:17072450
- 3. Hotez PJ, Dumonteil E, Betancourt Cravioto M, Bottazzi ME, Tapia-Conyer R, et al. (2013) An unfolding tragedy of Chagas disease in North America. PLoS Negl Trop Dis 7: e2300. pmid:24205411
- 4. Kollien AH, Schaub GA (2000) The development of Trypanosoma cruzi in triatominae. Parasitol Today 16: 381–387. pmid:10951597
- 5.
Wigglesworth VB (1972) The principies of insect physiology. 7th ed. London: Chapman & Hall. 827 p.
- 6. Alves CR, Albuquerque-Cunha JM, Mello CB, Garcia ES, Nogueira NF, et al. (2007) Trypanosoma cruzi: attachment to perimicrovillar membrane glycoproteins of Rhodnius prolixus. Exp Parasitol 116: 44–52. pmid:17250827
- 7. Schmidt J, Kleffmann T, Schaub GA (1998) Hydrophobic attachment of Trypanosoma cruzi to a superficial layer of the rectal cuticle in the bug Triatoma infestans. Parasitol Res 84: 527–536. pmid:9694367
- 8. Zeledon R, Bolanos R, Espejo Navarro MR, Rojas M (1988) Morphological evidence by scanning electron microscopy of excretion of metacyclic forms of Trypanosoma cruzi in vector's urine. Mem Inst Oswaldo Cruz 83: 361–365. pmid:3152276
- 9. Mello CB, Azambuja P, Garcia ES, Ratcliffe NA (1996) Differential in vitro and in vivo behavior of three strains of Trypanosoma cruzi in the gut and hemolymph of Rhodnius prolixus. Exp Parasitol 82: 112–121. pmid:8617337
- 10. Kollien AH, Schaub GA (1998) Trypanosoma cruzi in the rectum of the bug Triatoma infestans: effects of blood ingestion by the starved vector. Am J Trop Med Hyg 59: 166–170. pmid:9684647
- 11. Araujo CA, Waniek PJ, Jansen AM (2008) Development of a Trypanosoma cruzi (TcI) isolate in the digestive tract of an unfamiliar vector, Triatoma brasiliensis (Hemiptera, Reduviidae). Acta Trop 107: 195–199. pmid:18579102
- 12. Araujo CA, Waniek PJ, Jansen AM (2014) TcI/TcII co-infection can enhance Trypanosoma cruzi growth in Rhodnius prolixus. Parasit Vectors 7: 94. pmid:24593987
- 13. Henriques C, Castro DP, Gomes LH, Garcia ES, de Souza W (2012) Bioluminescent imaging of Trypanosoma cruzi infection in Rhodnius prolixus. Parasit Vectors 5: 214. pmid:23013827
- 14. Guevara P, Dias M, Rojas A, Crisante G, Abreu-Blanco MT, et al. (2005) Expression of fluorescent genes in Trypanosoma cruzi and Trypanosoma rangeli (Kinetoplastida: Trypanosomatidae): its application to parasite-vector biology. J Med Entomol 42: 48–56. pmid:15691008
- 15. Cummings KL, Tarleton RL (2003) Rapid quantitation of Trypanosoma cruzi in host tissue by real-time PCR. Mol Biochem Parasitol 129: 53–59. pmid:12798506
- 16. Piron M, Fisa R, Casamitjana N, Lopez-Chejade P, Puig L, et al. (2007) Development of a real-time PCR assay for Trypanosoma cruzi detection in blood samples. Acta Trop 103: 195–200. pmid:17662227
- 17. Schrader C, Schielke A, Ellerbroek L, Johne R (2012) PCR inhibitors—occurrence, properties and removal. J Appl Microbiol 113: 1014–1026. pmid:22747964
- 18. Maddrell SH (1964) Excretion in the Blood-Sucking Bug, Rhodnius Prolixus Stal. Ii. The Normal Course of Diuresis and the Effect of Temperature. J Exp Biol 41: 163–176. pmid:14161607
- 19. Oliveira MF, Silva JR, Dansa-Petretski M, de Souza W, Lins U, et al. (1999) Haem detoxification by an insect. Nature 400: 517–518. pmid:10448851
- 20. Kelly JM, Ward HM, Miles MA, Kendall G (1992) A shuttle vector which facilitates the expression of transfected genes in Trypanosoma cruzi and Leishmania. Nucleic Acids Res 20: 3963–3969. pmid:1324472
- 21. Lu HY, Buck GA (1991) Expression of an exogenous gene in Trypanosoma cruzi epimastigotes. Mol Biochem Parasitol 44: 109–114. pmid:2011146
- 22. Duffy T, Bisio M, Altcheh J, Burgos JM, Diez M, et al. (2009) Accurate real-time PCR strategy for monitoring bloodstream parasitic loads in chagas disease patients. PLoS Negl Trop Dis 3: e419. pmid:19381287
- 23. Wirtz E, Hoek M, Cross GA (1998) Regulated processive transcription of chromatin by T7 RNA polymerase in Trypanosoma brucei. Nucleic Acids Res 26: 4626–4634. pmid:9753730
- 24. Bustin SA, Benes V, Garson JA, Hellemans J, Huggett J, et al. (2009) The MIQE guidelines: minimum information for publication of quantitative real-time PCR experiments. Clin Chem 55: 611–622. pmid:19246619
- 25. Moser DR, Kirchhoff LV, Donelson JE (1989) Detection of Trypanosoma cruzi by DNA amplification using the polymerase chain reaction. J Clin Microbiol 27: 1477–1482. pmid:2504769
- 26. Eichler S, Schaub GA (2002) Development of symbionts in triatomine bugs and the effects of infections with trypanosomatids. Exp Parasitol 100: 17–27. pmid:11971650
- 27. Anziano DF, Dalmasso AP, Lelchuk R, Vasquez C (1972) Role of complement in immune lysis of Trypanosoma cruzi. Infect Immun 6: 860–864. pmid:4564786
- 28. Elias MC, Marques-Porto R, Freymuller E, Schenkman S (2001) Transcription rate modulation through the Trypanosoma cruzi life cycle occurs in parallel with changes in nuclear organisation. Mol Biochem Parasitol 112: 79–90. pmid:11166389
- 29. Garcia ES, Azambuja P (1991) Development and interactions of Trypanosoma cruzi within the insect vector. Parasitol Today 7: 240–244. pmid:15463507
- 30. Schaub GA, Kleffmann T, Kollien AH, Schmidt J (1998) Hydrophobic attachment of Trypanosoma cruzi to the rectal cuticle of Triatoma infestans and its influence on metacyclogenesis—a review. Tokai J Exp Clin Med 23: 321–327. pmid:10622629
- 31. Woolcock JB, Mutimer MD (1978) The capsules of Corynebacterium equi and Streptococcus equi. J Gen Microbiol 109: 127–130. pmid:366078
- 32. Neu TR, Dengler T, Jann B, Poralla K (1992) Structural studies of an emulsion-stabilizing exopolysaccharide produced by an adhesive, hydrophobic Rhodococcus strain. J Gen Microbiol 138: 2531–2537. pmid:1487724
- 33. Iwabuchi N, Sunairi M, Urai M, Itoh C, Anzai H, et al. (2002) Extracellular polysaccharides of Rhodococcus rhodochrous S-2 stimulate the degradation of aromatic components in crude oil by indigenous marine bacteria. Appl Environ Microbiol 68: 2337–2343. pmid:11976106
- 34. Parroche P, Lauw FN, Goutagny N, Latz E, Monks BG, et al. (2007) Malaria hemozoin is immunologically inert but radically enhances innate responses by presenting malaria DNA to Toll-like receptor 9. Proc Natl Acad Sci U S A 104: 1919–1924. pmid:17261807
- 35.
Schaub GA (2009) Chapter 4: Interactions of Trypanosomatids and Triatomines. In: Stephen JS CJ, editor. Advances in Insect Physiology: Elsevier Ltd, Academic Press. pp. 177–242.
- 36. Cortez MG, Gonzalez MS, Cabral MM, Garcia ES, Azambuja P (2002) Dynamic development of Trypanosoma cruzi in Rhodnius prolixus: role of decapitation and ecdysone therapy. Parasitol Res 88: 697–703. pmid:12107464
- 37. Garcia ES, Ratcliffe NA, Whitten MM, Gonzalez MS, Azambuja P (2007) Exploring the role of insect host factors in the dynamics of Trypanosoma cruzi-Rhodnius prolixus interactions. J Insect Physiol 53: 11–21. pmid:17141801
- 38. Azambuja P, Garcia ES, Ratcliffe NA (2005) Gut microbiota and parasite transmission by insect vectors. Trends Parasitol 21: 568–572. pmid:16226491
- 39. Joiner K, Sher A, Gaither T, Hammer C (1986) Evasion of alternative complement pathway by Trypanosoma cruzi results from inefficient binding of factor B. Proc Natl Acad Sci U S A 83: 6593–6597. pmid:2944112
- 40.
Ratcliffe NA, Whitten M.M.A. (2004) Vector immunity in microbe–vector interactions. In: Gillespie SH, Smith G. L., Osbourn A., editor. Vector-borne Diseases. Cambridge: Cambridge University Press. pp. 199–262.
- 41. Azambuja P, Feder D, Garcia ES (2004) Isolation of Serratia marcescens in the midgut of Rhodnius prolixus: impact on the establishment of the parasite Trypanosoma cruzi in the vector. Exp Parasitol 107: 89–96. pmid:15208042
- 42. Boulanger N, Bulet P, Lowenberger C (2006) Antimicrobial peptides in the interactions between insects and flagellate parasites. Trends Parasitol 22: 262–268. pmid:16635587
- 43. Vieira CS, Waniek PJ, Mattos DP, Castro DP, Mello CB, et al. (2014) Humoral responses in Rhodnius prolixus: bacterial feeding induces differential patterns of antibacterial activity and enhances mRNA levels of antimicrobial peptides in the midgut. Parasit Vectors 7: 232. pmid:24885969
- 44. Madison MN, Kleshchenko YY, Nde PN, Simmons KJ, Lima MF, et al. (2007) Human defensin alpha-1 causes Trypanosoma cruzi membrane pore formation and induces DNA fragmentation, which leads to trypanosome destruction. Infect Immun 75: 4780–4791. pmid:17635867
- 45. Pereira ME, Andrade AF, Ribeiro JM (1981) Lectins of distinct specificity in Rhodnius prolixus interact selectively with Trypanosoma cruzi. Science 211: 597–600. pmid:7006082
- 46. Castro DP, Seabra SH, Garcia ES, de Souza W, Azambuja P (2007) Trypanosoma cruzi: ultrastructural studies of adhesion, lysis and biofilm formation by Serratia marcescens. Exp Parasitol 117: 201–207. pmid:17570364
- 47. Ratcliffe NA, Nigam Y, Mello CB, Garcia ES, Azambuja P (1996) Trypanosoma cruzi and erythrocyte agglutinins: a comparative study of occurrence and properties in the gut and hemolymph of Rhodnius prolixus. Exp Parasitol 83: 83–93. pmid:8654555
- 48. Graca-Souza AV, Maya-Monteiro C, Paiva-Silva GO, Braz GR, Paes MC, et al. (2006) Adaptations against heme toxicity in blood-feeding arthropods. Insect Biochem Mol Biol 36: 322–335. pmid:16551546
- 49. Nogueira NP, Saraiva FM, Sultano PE, Cunha PR, Laranja GA, et al. (2015) Proliferation and Differentiation of Trypanosoma cruzi inside Its Vector Have a New Trigger: Redox Status. PLoS One 10: e0116712. pmid:25671543
- 50. Billingsley PF (1988) Morphometric analysis of Rhodnius prolixus Stal (Hemiptera:Reduviidae) midgut cells during blood digestion. Tissue Cell 20: 291–301. pmid:3043761
- 51.
Terra WR FC (2005) Biochemistry of digestion. In: Gilbert LI IK, Gill SS, editors, editor. Comprehensive Insect Molecular Science. Oxford: Elsevier. pp. 171–224.
- 52. Ribeiro JM, Genta FA, Sorgine MH, Logullo R, Mesquita RD, et al. (2014) An insight into the transcriptome of the digestive tract of the bloodsucking bug, Rhodnius prolixus. PLoS Negl Trop Dis 8: e2594. pmid:24416461
- 53.
Dias JCP (2002) Controle da Doenca de Chagas no Brasil. In: Silbeira AC, editor. Controle da Doenca de Chagas nos Paıses do Cone Sul da América: Pan American Health Organization. pp. 145–239.
- 54. Medrano-Mercado N, Ugarte-Fernandez R, Butron V, Uber-Busek S, Guerra HL, et al. (2008) Urban transmission of Chagas disease in Cochabamba, Bolivia. Mem Inst Oswaldo Cruz 103: 423–430.
- 55. Garcia ES, Genta FA, de Azambuja P, Schaub GA (2010) Interactions between intestinal compounds of triatomines and Trypanosoma cruzi. Trends Parasitol 26: 499–505. pmid:20801082