Differential responses and recovery dynamics of HSPC populations following Plasmodium chabaudi infection

Severe infections such as malaria are on the rise worldwide, driven by both climate change and increasing drug-resistance. It is therefore paramount that we better understand how the host’s organism responds to severe infection. Hematopoiesis is particularly of interest in this context because hematopoietic stem and progenitor cells (HSPCs) maintain the turnover of all blood cells, including all immune cells. Severe infections have been widely acknowledged to affecting HSPCs, however this disruption has been mainly studied during the acute phase, and the process and level of HSPC recovery remains understudied. Using a self-resolving model of natural rodent malaria, infection by Plasmodium chabaudi , here we systematically assess HSPCs’ acute response and recovery upon pathogen clearance. We demonstrate that during the acute phase of infection the most quiescent and functional stem cells are depleted, multipotent progenitor compartments are drastically enlarged, and oligopotent progenitors virtually disappear, underpinned by dramatic, population-specific and sometimes unexpected changes in proliferation rates. HSPC populations return to homeostatic size and proliferation rate again through specific patterns of recovery. Overall, our data demonstrate that HSPC populations adopt different responses to cope with severe infection and suggest that the ability to adjust proliferative capacity becomes more restricted as differentiation progresses.