We show the method for performing intravital microscopy of the spleen using GFP transgenic malaria parasites and the quantification of parasite mobility and blood flow within this organ.
The advent of intravital microscopy in experimental rodent malaria models has allowed major advances to the knowledge of parasite-host interactions 1,2. Thus, in vivo imaging of malaria parasites during pre-erythrocytic stages have revealed the active entrance of parasites into skin lymph nodes 3, the complete development of the parasite in the skin 4, and the formation of a hepatocyte-derived merosome to assure migration and release of merozoites into the blood stream 5. Moreover, the development of individual parasites in erythrocytes has been recently documented using 4D imaging and challenged our current view on protein export in malaria 6. Thus, intravital imaging has radically changed our view on key events in Plasmodium development. Unfortunately, studies of the dynamic passage of malaria parasites through the spleen, a major lymphoid organ exquisitely adapted to clear infected red blood cells are lacking due to technical constraints.
Using the murine model of malaria Plasmodium yoelii in Balb/c mice, we have implemented intravital imaging of the spleen and reported a differential remodeling of it and adherence of parasitized red blood cells (pRBCs) to barrier cells of fibroblastic origin in the red pulp during infection with the non-lethal parasite line P.yoelii 17X as opposed to infections with the P.yoelii 17XL lethal parasite line 7. To reach these conclusions, a specific methodology using ImageJ free software was developed to enable characterization of the fast three-dimensional movement of single-pRBCs. Results obtained with this protocol allow determining velocity, directionality and residence time of parasites in the spleen, all parameters addressing adherence in vivo. In addition, we report the methodology for blood flow quantification using intravital microscopy and the use of different colouring agents to gain insight into the complex microcirculatory structure of the spleen.
Ethics statement
All the animal studies were performed at the animal facilities of University of Barcelona in accordance with guidelines and protocols approved by the Ethics Committee for Animal Experimentation of the University of Barcelona CEEA-UB (Protocol No DMAH: 5429). Female Balb/c mice of 6-8 weeks of age were obtained from Charles River Laboratories.
This method was used in the research reported in 7.
1. Animal infection with green fluorescent protein (GFP) transgenic parasites
2. Labeling of red blood cells with FITC and injection to control animals
3. Surgical procedures
4. Imaging of living parasites in the spleen
5. Intravital microscopy of the microvasculature of the spleen and image acquisition for blood flow measurement
6. Image processing and quantitative analysis of parasite mobility using ImageJ software
7. Calculation of volumetric blood flow
8. Statistical analysis
9. Representative Results
Intravital imaging of GFP parasites in the spleen revealed differences in mobility between the two strains of parasites. Quantitative analysis of mobility parameters of single parasites indicated reduced velocity, lack of directionality and augmented residence time of parasites of mice infected with 17X strain. Moreover, volumetric blood flow in vessels was not altered between strains 7. The technical procedure is presented in Figure 1A. Figure 1B shows a general view of a normal spleen of a mouse injected with FITC-labeled RBCs, with a zoom in into the red pulp and another to a vessel (Figure 1B, zoom in 1 and 2, respectively). Vasculature was evidenced by injecting 70 kDa Dextran-Texas Red together with erythrocyte reflection contrast. Other fluorescent dyes summarized in Table 1 can be used to gain information on the organ being imaged, such as Hoechst (Figure 1C, 1D).
Real-time imaging of parasites of the 17XL and 17X strain is presented in Movies 1 and 2, with some 17X-pRBC (Movie 2) showing a rolling-circle behavior. Quantitative analysis of mobility parameters was achieved through tracking of individual parasites with the help of Z-coded color images. Figure 2A shows a Z-projection of a Z-coded color stack, where the encircled particle appears moving in different planes. Figure 2B and 2C represent the tracks for different parasites in 17X and 17XL infection, respectively. Results from directionality and residence time of all the particles quantified are presented as a density distribution map of parasite population in Figure 2D and 2E, respectively. To monitor blood flow in the spleen using intravital microscopy, the streaks obtained in xt images of the central lumen of vessels resulting from the erythrocyte movement were measured to calculate velocity 11. The images show a xy scan of a vessel (Figure 2F) with the corresponding xt line scan (Figure 2G).
Fluorescent Probe | Localization | 1 photon Excitation (nm) | 2 photon Excitation (nm) | Detected emission (nm) | Quantity/ mouse weight |
Hoechst 33342 | Membrane-permeant DNA-binding probe. It labels nuclei of all cells (live and dead) after Intravenous injection. | 405 | 800 | 410-480 | 12.5 g/Kg |
Propidium iodide | Membrane-impermeant DNA-binding probe. It labels nuclei of cells with compromised membrane (apoptotic and necrotic cells). | 561 | 800 | 570-650 | 250 mg/Kg |
70,000 mol wt Dextran- Fluorescent (FITC, Texas Red) | Fluid-phase marker that enhances contrast of plasma. | FITC 488 Texas Red 594 | 800 | 500-540 600-650 |
50 mg/Kg |
Sodium Fluorescein | Bulk fluid-phase albumin marker that enhances contrast of plasma. | 488 | 800 | 500-540 | 2 mmol/Kg |
Evans Blue | Bulk fluid-phase albumin marker that enhances contrast of plasma. | 633 | nd | 645-700 | 20 mg/Kg |
Rhodamine R6 | Vital probe that accumulates in active mitochondria. It labels endothelia and circulating white cells after intravenous injection. | 561 | 800 | 570-650 | 25 mg/Kg |
Fluospheres- 1micron diameter | Beads that are uptaken by cells with phagocytic activity. | 488 | 800 | 500-540 | nd |
Alexa488-labeled fibrin IIβ chain-specific antibody | Probe that labels fibrin IIβ chain | 488 | 800 | 500-540 | 0.3 mg/Kg |
Table 1. Fluorescent probes for intravital microscopy. Vital fluorescent dyes with different localizations that may be used to label the spleen in vivo. Excitation/emission (Exc/em) ranges to be used with one-photon (or two-photon microscopy) are provided. The dose indicated is dissolved in 0.1-0.2 ml of saline buffer and injected to the tail vein of the mouse. [nd: not determined in this study.
Figure 1. Intravital microscopy of the spleen. A. Leica TCS-SP5 confocal microscope with one mouse placed on the stage of the microscope. The mouse has the inferior part of the spleen exposed and sealed with a cover-slip. B. Image of a representative area of the spleen of a non-infected animal injected with FITC-labeled RBCs and 70 kDa Dextran- Texas Red to visualize the vasculature. Reflection (yellow), Dextran (blue) and FITC-RBCs (green) are shown. Blow-ups in white boxes represent open-circulation (1) and close-circulation (2) areas. Open-circulation (C) and close-circulation(D) stained with 70 kDa dextran (red) and Hoechst 33342 (blue).
Figure 2. Quantification of parasite mobility and blood flow. A-C. Quantitative analysis of particle movement in the four dimensions (4D) is facilitated by using color-coded image processing. A. Tracking was performed with the depth information from Z-coded color images, represented using maximum intensity projection of five different depths. White rectangle represents the same particle at different Z in one time point. Different positions are due to time lapses between the acquisition of different Z images. Depth code: yellow (0 μm), orange (2 μm), pink (4 μm), blue (6 μm), green (8 μm). B, C. Time projections of particle movement with each time interval coloured as: gray (0-2.4 sec), cyan (2.4-4.8 sec), magenta (4.8-7.0 sec), red (7.0-9.4 sec) and yellow (9.4-11.8 sec). White line represents 4D manual tracking of particles of 17X (11.8 s) (B) and 17XL (4.8 sec) (C) GFP parasites using MTrackJ. D,E. Distribution of the density of GFP particles by values of directionality (D) and residence time (E). Data correspond to 120 particles of each line of parasites and 100 FITC-labeled RBCs from three independent experiments analysed with the equality-of-medians test. The 17X/17XL/FITC-RBCs medians are 0.53/0.75/0.85 (D) and 4.61/0.67/0.9 sec (E). Differences between the two lines in (D) and (E) are statistically significant (P < 0.001). Differences between FITC-labeled RBCs and 17XL parasites are not statistically significant (P > 0.05). F,G. Spleen blood flow measurements. Representation of xy image (F) and xt image (G) from a line-scan of the central lumen of the same vessel (white line). Spleen vessel showing plasma with 70 kDa dextran (red), pRBC (green) and erythrocyte reflection (blue).
Movies 1 and 2. Time-lapse intravital microscopy images of the murine spleen infected with 17XL (1) or 17X (2) GFP-transgenic parasites at 10% parasitemia (Z-maximum projection). Parasite and tissue autofluorescence are shown in green and red respectively. Scale bars represent 10 μm and the time interval is in sec.
Click here to watch Movie 1.
Click here to watch Movie 2.
The implementation of intravital microscopy of the spleen in this rodent malaria model opened the possibility of investigating the dynamic passage of parasites through this organ which until now has been considered a “black-box” due to technical considerations. In here, a major effort was put to adapt a quantitative method that allows comparative analysis of different parasite lines at the single and population levels. In contrast to other tissues and cells that had been imaged before in malaria 3,5, imaging the passage of pRBCs through the spleen needs to take into consideration the three-dimensionality and compartmentalization of the organ, the presence of different circulations with fast and slow flux 13, as well as the rapid erythrocyte velocities. With this aim, a specific methodology using online available ImageJ software was developed to enable single parasite tracking, mobility analysis and comparison between lines at the population level. However, the application of automatic software that solves identification and tracking of single parasites in this context is still needed. Of note, the parameters used to describe parasite mobility have been previously described in other studies to report lymphocyte recruitment and adhesion in vivo 12,14,15. Thus, this methodology and parameters should be considered a new tool to the in vivo studies of adherence in malaria. In the future, we will use this technology to gain insight into the immunobiology and parasite-spleen cell interactions by imaging infection in transgenic mice expressing fluorescent reporter genes in different cells. Moreover, the generation of transgenic parasites expressing fluorescent markers other than GFP may be used in combination to image dual infections in this model.
In vivo imaging is a powerful tool to study the dynamic interplay of parasites within their hosts. However, there exist several factors affecting cell mobility that must be taken into consideration. Changes in the tissue architecture in response to infection with different Plasmodium strains can modify cell passage and interaction with the tissue 7,16 and the rheological properties of red blood cells, as well as changes in the hematocrit or other hematologic parameters, can affect blood flow and hence the interaction of cells with the tissue. For this reason, we recommend to analyze vessel blood flow with the procedure provided. To avoid any confounding effects, we imaged the spleen of infected mice at a time point when hematocrit, reticulocytemia and parasite tropism is comparable in both infections 7.
The resolution of this technique allows for the observation of single fluorescent cells passing through the spleen at earlier time points (<1% parasitemia). However, quantitative analysis of the dynamic behavior of parasites was performed at 1% parasitemia, when sufficient numbers of pRBCs were observed passing through the spleen at time lapses that allow tracking of single cell movement. In movies 1 and 2, which correspond to animals at 10% parasitemia, we showed the general pattern of parasite passage through the spleen in each infection; however, quantitative analysis of moving cells was performed in movies from animals at 1% parasitemia, where single cells are easily followed. Due to the rapid three-dimensional movement of infected red blood cells, we couldn’t differentiate between developmental stages of the parasite, as different fluorescence intensities could be attributed to different depths or penetrability of the laser.
With this procedure, fluorescent cells can be visualized in the subcapsular zone of the spleen, composed mainly of red pulp 17. By using plasma dyes, we could discern between the fast/closed and slow/open circulations of the red pulp. Other studies have reported imaging of fluorescent T-cells in the white pulp using confocal 18 or two-photon microscopy 19, with the last offering greater tissue penetration. In those, off-line analysis and ex vivo characterization of the zone being imaged is an important factor to accurately interpret the data. Thus, efforts to enlighten the microcirculatory structure of the spleen, as well as the development of probes that label specific cells and structures, are of importance to facilitate the study of parasite-host interactions.
The authors have nothing to disclose.
We are particularly grateful to S. Graewe and V. Heussler for the initial training and continuous input in intravital microscopy of malaria parasites, to J. Burns for donating GFP transgenic parasites, to A. Bosch (Confocal Unit, CCiT-UB, IDIBAPS) for assistance in image analysis and quantification and to P. Astola for technical assistance. We thank R. Tous and I. Caralt for video production. MF is a recipient of a graduate fellowship from the Generality of Catalonia. HAP is an ICREA research professor. Work in the laboratory of HAP is funded by the European Community’s Seventh Framework Programme (FP7/2007-2013) under grant agreement N° 242095, by the Private Foundation CELLEX (Catalonia, Spain), and by the Spanish Ministry of Science and Innovation (SAF2009-07760).
Name of the reagent | Company | Catalogue number | Comments |
Leica TCS-SP5 confocal microscope | Leica Microsystems, Heidelberg, Germany | TCS-SP5 Serial no. 5100000419 | |
Ketamine (Ketolar 50 mg/ml) | Pfizer | 631028 | |
Midazolam 15 mg/3 ml | Normon | 838193 | |
70,000 MW Dextran, conjugated to Texas Red | Molecular Probes | D1830 | |
Fluorescein Isothiocyanate, isomer I (FITC) | Sigma | F7250 | |
Hoechst 33342 | Sigma | H1399 | |
Giemsa stain | Sigma | GS1 | Working solution is at 10% in distilled water |
Super Glue-3 Loctite | Loctite | 9975-0880 |