Adaptive T cells regulate disease tolerance in human malaria

Abstract Immunity to severe malaria is acquired quickly, operates independently of pathogen load and represents a highly effective form of disease tolerance. The mechanism that underpins tolerance in human malaria remains unknown. We developed a re-challenge model of falciparum malaria in which healthy naive adult volunteers were infected three times over a 12-month period to track the development of disease tolerance in real-time. We found that parasitaemia triggered a hardwired emergency myeloid response that led to systemic inflammation, pyrexia and hallmark symptoms of clinical malaria across the first three infections of life. In contrast, CD4+ T cell activation was quickly modified to reduce the number and diversity of effector cells upon re-challenge. Crucially, this did not silence critical helper T cell functions but instead prevented the generation of cytotoxic effectors associated with autoinflammatory disease. Tolerised hosts were thus able to prevent collateral tissue damage and injury. Host control of T cell activation can therefore be established after a single infection and in the absence of anti-parasite immunity. And furthermore, this rapid host adaptation can protect vital organs to minimise the harm caused by systemic inflammation and sequestration.