Abstract
Background
Toxoplasma gondii is an apicomplexan intracellular obligate parasite and the etiological agent of toxoplasmosis in humans, domestic animals and wildlife, causing miscarriages and negatively impacting offspring. During its intracellular development, it relies on nutrients from the host cell, controlling several pathways and the cytoskeleton. T. gondii has been proven to control the host cell cycle, mitosis and cytokinesis, depending on the time of infection and the origin of the host cell. However, no data from parallel infection studies have been collected. Given that T. gondii can infect virtually any nucleated cell, including those of humans and animals, understanding the mechanism by which it infects or develops inside the host cell is essential for disease prevention. Therefore, we aimed here to reveal whether this modulation is dependent on a specific cell type or host cell species.
Methods
We used only primary cells from humans and bovines at a maximum of four passages to ensure that all cells were counted with appropriate cell cycle checkpoint control. The cell cycle progression was analysed using fluorescence-activated cell sorting (FACS)-based DNA quantification, and its regulation was followed by the quantification of cyclin B1 (mitosis checkpoint protein). The results demonstrated that all studied host cells except bovine colonic epithelial cells (BCEC) were arrested in the S-phase, and none of them were affected in cyclin B1 expression. Additionally, we used an immunofluorescence assay to track mitosis and cytokinesis in uninfected and T. gondii-infected cells.
Results
The results demonstrated that all studied host cell except bovine colonic epithelial cells (BCEC) were arrested in the S-phase, and none of them were affected in cyclin B1 expression. Our findings showed that the analysed cells developed chromosome segregation problems and failed to complete cytokinesis. Also, the number of centrosomes per mitotic pole was increased after infection in all cell types. Therefore, our data suggest that T. gondii modulates the host cell cycle, chromosome segregation and cytokinesis during infection or development regardless of the host cell origin or type.
Graphical Abstract
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Background
The obligate intracellular parasite Toxoplasma gondii is a globally spread zoonotic protozoan that causes severe health problems in both humans and animals. Prenatal infections can cause abortion or harm the progeny's welfare. Acute infections can be life-threatening in immunocompromised individuals, and several studies have postulated a correlation between latent T. gondii infections and neurological/psychiatric disorders in humans [1, 2].
Intracellular protozoa are well known for modulating their host cells to ensure efficient intracellular development and proliferation. As such, they have been shown to modulate a variety of host cellular functional categories, such as apoptosis, autophagy, cytoskeleton, metabolism, immunological responses and cell cycle [3,4,5,6,7,8]. Some parasite-triggered cell cycle disruption is both parasite species- and host cell type-specific. Toxoplasma gondii, Leishmania spp., Trypanosoma cruzi and Encephalitozoon spp. induce cell cycle arrest and dampen host cell proliferation, whilst Theileria stimulates host cell division and proliferation [9,10,11,12,13,14]. Leishmania amazonensis interferes early in the cell cycle with the G0/G1 phase, and T. cruzi triggers host cell progression to the S-phase, besides blocking host cell mitosis and impairing cytokinesis after nuclear replication [10, 12]. The host cell type seems to be important in Plasmodium species; for example, P. falciparum infections in HepG2 cells were found to affect mitosis and lead to binucleated phenotype formation without cell division [15]. However, cell cycle-dependent reactions played no role in P. berghei- or P. yoelii-infected mouse models either in vivo or in vitro. Plasmodium falciparum-infected primary hepatocytes provide evidence that primary cell types differ considerably from permanent cell lines in their reactions. To date, there is no information whether the control that T. gondii exerts on the host cell cycle is restricted to specific cell types or to only some host cell species. However, it has been shown that T. gondii infections shift G0/G1 cells through the S-phase in human foreskin fibroblasts (HFF) [4], but arrest cells in the G2-phase in a human trophoblast cell line and human dermal fibroblasts [3], or even both in the L6 rat myoblast cell line [16]. The G2-phase arrest in human dermal fibroblasts or a human trophoblast cell line was linked to decreased cyclin B1 abundance without alterations in other G2/M checkpoint-related proteins [3]. T. gondii arrest of HFF during the S-phase or G2/M was accompanied by a delayed or absent increase in cyclin A and cyclin B1, thereby indicating a missing exit from the S-phase and failure to progress [4]. T. gondii infections increased the proportion of polyploid cells (8n) in the murine RAW264.7 cell line, most likely reflecting DNA replication without subsequent cytokinesis [17]. All of the above suggests that T. gondii altered the host cell cycle based on the origin of the host or the cell type infected. However, no experiment has been carried out in parallel using different cell types and species in order to establish comparative analyses. Therefore, the current study sought to determine whether T. gondii regulates the host cell cycle progression based on the host cell species or type. We used commercially available primary human cells and two primary bovine cell lines in-house-isolated, controlling the passage number to maintain the original phenotype. Our findings showed that cell cycle arrest occurred in almost all primary cells excluding bovine colonic epithelial cells (BCEC). Nonetheless, T. gondii-induced chromosome mis-segregation and cytokinesis failure were detected in all cell types studied, suggesting that T. gondii modulates these two mechanisms independently of host cell origin.
Methods
Primary human and bovine host cells and parasite maintenance
Primary human umbilical vein endothelial cells (HUVEC, six donors in total, PromoCell), HFF (n = 3, PromoCell) and human small intestine epithelial cells (FHs74, American Type Culture Collection [ATCC]) were cultured at 37 °C and 5% CO2 following the supplier’s protocols [(media: HUVEC: Endothelial Cell Growth Medium, PromoCell; HFF: Dulbecco's modified Eagle medium [DMEM]-GlutaMAX, Gibco; FHs74: HybriCare, ATCC; BCEC: RPMI1640, Sigma; bovine small intestinal epithelial cells [BSIEC]: DMSM/F12, Gibco); see primary cell information in Table 1]. Each experiment was performed at a maximum of four passages after isolation to enable the best comparison. All cell lines were seeded at the same time and infected with the same batch of tachyzoites. T. gondii RH tachyzoites were maintained by serial passages in primary HFF cells (maximum passage: 10). Therefore, free-released T. gondii tachyzoites were harvested from HFF supernatants, pelleted (400×g, 12 min), counted and suspended in the corresponding medium for each host cell type. Infections were performed in sub-confluent cell layers. All experiments were performed at a multiplicity of infection (MOI) of 1:1 (cells: parasites).
Flow cytometry-based analysis of cell cycle phases
Cellular DNA content was measured using FxCycle PI (propidium iodide)/RNAse staining solution (Invitrogen, F10797) according to the manufacturer’s instructions. Cyclin B1 quantification was performed in cells fixed with BD fixation/permeabilization solution (BD, 554714, Becton, Dickinson and Company, Heidelberg, Germany) and stained with cyclin B1-AF647 (Cell Signaling Technology, 4118). The samples were analysed using a BD Accuri C6 Plus flow cytometer (Becton–Dickinson) applying 535/5 nm excitation and emission collected in a 617/20 band-pass. Cells were gated according to their size and granularity; only morphologically intact host cells were included in the analysis. All analyses were performed in FlowJo v.10 software.
Immunofluorescence assays
The method was performed as described by Velásquez et al. [18]. Briefly, uninfected and infected cells were fixed with paraformaldehyde (PFA, 4%, 15 min, room temperature [RT]), washed with phosphate-buffered saline (PBS) and incubated in blocking/permeabilization solution (PBS with 3% bovine serum albumin [BSA], 0.1% Triton X-100; 1 h, RT). Thereafter, samples were incubated in primary antibodies (Table 2) and diluted in blocking/permeabilization solution (overnight at 4 °C in a humidified chamber). After three washes in PBS, the samples were incubated in secondary antibody solutions (Table 2; 30 min at RT and complete darkness). Cell nuclei were labelled using a DAPI-supplemented mounting medium (Fluoromount-G, Thermo Fisher).
Image acquisition and reconstruction
Image acquisition and reconstruction were carried out according to the description published by Velásquez et al. [18]. A ReScan confocal microscope (RCM 1.1 Visible, Confocal.nl) equipped with a fixed 50 µm pinhole size and combined with a Nikon Ti2-A inverted microscope was used to acquire fluorescence and confocal images. The RCM unit was connected to a Toptica CLE laser with the following excitations: 405/488/561/640 nm. Images were acquired using a scientific CMOS [complementary metal–oxide–semiconductor] (sCMOS) camera (pco.edge, PCO) with a CFI Plan Apochromat 60× lambda-immersion oil objective (NA 1.4/0.13; Nikon). The system was operated using NIS-Elements software (version 5.11). Images were acquired via z-stack optical series with a step size of 0.1 micron depth to cover all structures of interest within the analysed host cells. Z-series were displayed as maximum z-projections. Identical brightness and contrast conditions were applied for each data set within one experiment using Fiji software [19].
Statistical analysis
All data are expressed as mean ± standard deviation (SD) from three independent experiments. When two groups were compared, a Mann–Whitney test was performed. When three or more experimental groups were compared, a Kruskal–Wallis one-way analysis of variance was applied. Significance was defined as P ≤ 0.05. All graphs and statistical analyses were performed using GraphPad Prism 9 software.
Results
Toxoplasma gondii has been described to modulate the host cell cycle between the G1 and G2/M phase depending on the experimental model used [3, 4, 14, 20]. Given that these experiments were performed under different experimental conditions and cell types, we wanted to know whether T. gondii uses this mechanism as an infection strategy or whether it is dependent on the host type or species. As host cells, we tested three human primary cells, HUVEC, FHs74 and HFF, and two primary bovine cells, BSIEC and BCEC. To avoid artefacts due to the immortalization of the cell or tumour phenotype, we worked only with primary cells, at a limit of four passages after isolation. The host cells were infected at sub-confluence, and at 24 h post-infection (p.i.) they were analysed for DNA content using fluorescence-activated cell sorting (FACS) flow cytometry. The gating process started by selecting the cell population according to their shape and granularity (Fig. 1). Cells were then plotted as the number of cells versus PI signal. The first peak represents the cells in the G1-phase, the second peak represents those cells in the G2/M-phase, and the S-phase corresponds to the cells located between the two peaks. Cells in each cell cycle phase are shown as a proportion of the total number of cells counted. DNA quantification results showed that HUVEC, HFF and FHs74 from humans and BSIEC were arrested in the S-phase after infection (Fig. 1), whereas T. gondii infection did not affect cell cycle progression in BCEC (Fig. 1). It should be noted that HUVEC and HFF cells showed a reduction in the number of cells in the G1-phase, and HFF also showed a reduced percentage of cells in the G2-phase (Fig. 1).
Cell cycle arrest in the S-phase could be explained by a blockage entry into the G2/M-phase. Therefore, we analysed the expression of one of the main regulators of the G2-to-M-phase transition, cyclin B1. Cyclin B1 accumulates throughout the S-phase, with a peak at the onset of the M-phase [21]. After that, cyclin B1 needs to be degraded to allow cells to enter mitosis. Thus, we quantified the cyclin B1 protein 24 h p.i., using FACS-based quantification. The cells were gated according to their shape and granularity and then plotted as the total number of counted cells and the cyclin B1 intensity (Fig. 2). The results showed that none of the cells modulated cyclin B1 expression after T. gondii infection (Fig. 2), suggesting that T. gondii does not arrest the host cell cycle in the S-phase due to modulation of the mitosis checkpoint protein cyclin B1.
It has been previously demonstrated that T. gondii infection affects mitosis progression itself, and thus we performed an immunofluorescence assay in cells infected for 24 h with T. gondii tachyzoites. Firstly, we quantified the percentages of cells in mitosis in the non-infected and infected monolayers (total number of cells: FHs74:1169; BSIEC:1248; BCEC:1531; HFF:6280; HUVEC:4287), with no significant differences in the mitotic index between the bovine cell lines BCEC and BSIEC and the human cell line HUVEC (Fig. 3A, B). Mitosis was evaluated from prophase (chromosome condensation) to telophase (chromosomes sets were pulled to opposite poles of the cell). On the contrary, human cell lines FHs74 and HFF increased the percentage of mitotic cells in the T. gondii-infected monolayer (Fig. 3B). Secondly, we quantified the aberrant mitotic cells in all human and bovine cell lines. Fixed cells were stained for chromosomes (DAPI, blue), centrosome (γ-tubulin, red) and T. gondii tachyzoites (green; Fig. 3C). Aberrant mitoses were detected in all phases of mitosis, as shown in Fig. 3C. We observed prometaphases or metaphases with more than two centrosome poles (Fig. 3C, white arrows). Similar results were observed in telophase, suggesting that T. gondii affects the centrosome number and therefore the chromosome segregation throughout mitosis, independently of the cell origin or type. In order to determine whether this effect was significant after infection, we quantified the percentage of aberrant mitosis in non-infected and infected monolayers. We defined aberrant mitosis as those mitotic spindle problems in chromosome segregation, mislocated centrioles or an increased number of centrosomes. The results showed that only the bovine cell line BCEC exhibited a significant increase in the number of aberrant mitoses after infection (Fig. 3C). Human endothelial cells and fibroblasts displayed an increased percentage of aberrant mitosis, while epithelial cell mitosis was not affected by infection (Fig. 3C).
Finally, we wanted to know whether the cytokinesis failure observed after T. gondii infection was cell-type or cell-origin-specific. Cytokinesis failure means a failure in cytosol division at the end of mitosis; therefore, we quantified the total number of cells displaying more than one nucleus per cell (binucleated cells; Fig. 4). Human and bovine cells were fixed 24 h p.i. and stained against T. gondii and DAPI, and the total number of binucleated cells was counted (Fig. 4). The results showed that all cells tested had increased percentages of binucleated cells, independently of the origin or cell type (Fig. 4). We consistently observed parasite-driven cytokinesis inhibition resulting in 18–34% of the host cells with more than two nuclei in all cell types (Fig. 4). Taken together, the current data suggest that T. gondii-induced chromosome segregation errors and cytokinesis failure are neither host species- nor host cell type-dependent. However, host cell cycle arrest was only observed in four of the five cell types tested in the current study, suggesting a parasite mechanism that might relate to the cell type.
Conclusions
Toxoplasma gondii is an obligate intracellular parasite that is globally spread and causes severe health problems in humans and animals, such as abortion, severely affecting the progeny welfare [2]. Given that this parasite can infect almost any warm-blooded animal, the mechanism that T. gondii uses to develop inside the host cell is of interest to scientists worldwide. In the last year, increasing evidence has shown that T. gondii modulates the host cell cycle, but all studies involved only one or two types of cells, using different experimental approaches, MOIs or infection time. Also, some studies worked with immortalized or tumour cells, which are well known to lose the cell cycle checkpoint control that a primary cell has. Therefore, we wanted to determine whether T. gondii uses the control of the host cell cycle as a mechanism to ensure its intracellular development, independently of the species or cell type used as a host. In order to study the responses closest to a real infection scenario, we worked only with primary cells at a maximum of four passages after isolation. The results showed that the cell cycle of only one cell type (BCEC) was not influenced after infection. However, it is important to highlight that this cell line was isolated and monitored in our laboratory, with normal growth like the others, and normal intracellular development of T. gondii tachyzoites during infection as well. Therefore, the results might be analysed according to specific proteins that the parasite modulates in order to arrest the host cell cycle but that are not expressed in this cell type. Nevertheless, further experiments are needed to identify why T. gondii infection cannot control cell cycle progression in BCEC cells, but this is beyond the scope of the current work.
Regarding the mitosis and binucleated cell percentages, the results showed no differences between human and bovine cell lines. Therefore, we consider that both pathways controlled by T. gondii infection probably involved molecules or proteins that are not specific to a cell type or a determinate species. Similarly, it occurred with chromosome segregation errors, which were observed equally in all studied cell lines and species tested in the current study. Mitosis and cytokinesis need the cytoskeleton to function, specifically from the tubulin fibres which form the mitotic spindle or the midbody formation, respectively [22, 23]. Interestingly, T. gondii is well known to modulate the host cell tubulin cytoskeleton by relocating it around the parasitophorous vacuole (PV) [5]. After 1 h, infected cells showed a relocation of aster microtubules around the PV, and longer times of infection showed cells with multiple γ-tubulin foci suggesting critical microtubule dynamics in infected cells [5]. Therefore, our results can be explained by the control that T. gondii infection does on the host cell cytoskeleton and highlight that the failure cytokinesis process and the problems in the chromosome segregation are mechanisms that T. gondii uses in all infections, not depending on the host cell origin or cell type.
Our research indicates that T. gondii modulates host cell cycle progression, chromosome segregation and cytokinesis in primary cells independently of the host and cell type. Therefore, we suggest that these mechanisms represent a basal control of the parasite over the host cell. For future studies, it would be interesting to identify whether these T. gondii-induced phenotypes are all interconnected or if they represent a specific control that T. gondii separately exerts in pathways.
Availability of data and materials
The original contributions presented in the study are included in the article/Supplementary material.
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Acknowledgements
We would like to thank all members of Anja Taubert’s lab for the helpful discussion of the current work as well as all the technical staff of the Institute of Parasitology. The authors thank A. Wehrend (Clinic for Obstetrics, Gynecology and Andrology of Large and Small Animals, Justus Liebig University, Giessen, Germany) for the continuous supply of bovine umbilical cords.
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Open Access funding enabled and organized by Projekt DEAL. The authors declare that no financial support was received for the research, authorship, and/or publication of this article.
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Conceptualization: ZDV. Main experimentation: LRB and ZDV. Formal analysis: LRB and ZDV. Statistical analyses: LRB and ZDV. Resources and funding: AT and CH. Data curation: ZDV. Writing—original draft: ZDV. Writing—review and editing: LRB, CH, AT and ZDV.
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Rojas-Baron, L., Senk, K., Hermosilla, C. et al. Toxoplasma gondii modulates the host cell cycle, chromosome segregation, and cytokinesis irrespective of cell type or species origin. Parasites Vectors 17, 180 (2024). https://doi.org/10.1186/s13071-024-06244-2
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DOI: https://doi.org/10.1186/s13071-024-06244-2