Leishmania major drives host phagocyte death and cell-to-cell transfer depending on intracellular pathogen proliferation rate
Iris Baars, Moritz Jaedtka, Leon-Alexander Dewitz, Yan Fu, Tobias Franz, Juliane Mohr, Patricia Gintschel, Hannes Berlin, Angelina Degen, Sandra Freier, Stefan Rygol, Burkhart Schraven, Sascha Kahlfuß, Ger van Zandbergen, Andreas J. Müller
Iris Baars, Moritz Jaedtka, Leon-Alexander Dewitz, Yan Fu, Tobias Franz, Juliane Mohr, Patricia Gintschel, Hannes Berlin, Angelina Degen, Sandra Freier, Stefan Rygol, Burkhart Schraven, Sascha Kahlfuß, Ger van Zandbergen, Andreas J. Müller
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Research Article Infectious disease Microbiology

Leishmania major drives host phagocyte death and cell-to-cell transfer depending on intracellular pathogen proliferation rate

Abstract

The virulence of intracellular pathogens relies largely on the ability to survive and replicate within phagocytes but also on release and transfer into new host cells. Such cell-to-cell transfer could represent a target for counteracting microbial pathogenesis. However, our understanding of the underlying cellular and molecular processes remains woefully insufficient. Using intravital 2-photon microscopy of caspase-3 activation in the Leishmania major–infected (L. major–infected) live skin, we showed increased apoptosis in cells infected by the parasite. Also, transfer of the parasite to new host cells occurred directly without a detectable extracellular state and was associated with concomitant uptake of cellular material from the original host cell. These in vivo findings were fully recapitulated in infections of isolated human phagocytes. Furthermore, we observed that high pathogen proliferation increased cell death in infected cells, and long-term residency within an infected host cell was only possible for slowly proliferating parasites. Our results therefore suggest that L. major drives its own dissemination to new phagocytes by inducing host cell death in a proliferation-dependent manner.

Authors

Iris Baars, Moritz Jaedtka, Leon-Alexander Dewitz, Yan Fu, Tobias Franz, Juliane Mohr, Patricia Gintschel, Hannes Berlin, Angelina Degen, Sandra Freier, Stefan Rygol, Burkhart Schraven, Sascha Kahlfuß, Ger van Zandbergen, Andreas J. Müller

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Figure 5

Proliferation-competent L. major parasites induce cell death in infected macrophages.

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Proliferation-competent L. major parasites induce cell death in infected...
(A) Experimental setup for in vitro analysis of host cell death using LmmKikumeGreen proliferation-competent and LmDsRed KBMA parasites and wide-field imaging. (B) Growth curve of proliferation-competent (green) and KBMA proliferation-incompetent (red) parasites. (C) Promastigote (SHERP) and amastigote (ABC) gene expression (normalized to NMT as a housekeeping gene) in extracellular promastigotes and proliferation-competent and KBMA proliferation-incompetent parasites as measured by qPCR. Each symbol represents 1 sample. Data represent 3 independent samples for each condition. Horizontal bars denote the median. (D) Selected frames from live cell imaging and TUNEL staining after fixation of the same site are shown, revealing TUNEL+ (cyan) murine IP macrophages colocalizing with proliferation-competent (green) but not KBMA proliferation-incompetent (red) parasite. Scale bar: 20 μm. (E) Selection of LmmKikumeGreen proliferation-competent and LmDsRed KBMA parasites in TUNEL (left) and TUNEL+ (right) cells according to green and red parasite fluorescence. All measured infected cells are shown individually. (F) Quantification of percentage of proliferation-competent parasites in all TUNEL+ and TUNEL murine IP macrophages. Each symbol shows 1 field of view imaged over time and relocalized afterward for TUNEL staining, with at least 3 TUNEL+ and at least 6 TUNEL cells per imaged field analyzed according to the criteria shown in E. Horizontal bars denote the mean. **P < 0.01, ***P < 0.001, ****P < 0.0001 by paired t test.