Cellular barcoding of Toxoplasma reveals permissive host brain colonization

Pathogenic infections and the diseases they cause are defined by invasion and colonization of distinct host cell types and tissue niches. In the case of viruses and bacteria, molecular and cellular barcoding has shaped our understanding of within-host pathogen population dynamics, and informed therapeutic intervention strategies. Host brain colonization is a clinically untreatable feature of persistent infection by the eukaryotic pathogen Toxoplasma gondii, and the process remains poorly understood. The host blood-brain barrier is expected to physically restrict parasite colonization of this tissue niche and force the infection through a selection bottleneck, however tools and technologies to test this hypothesis have not been available. Here, we have developed a simple CRISPR-based method to barcode Toxoplasma parasites, and then used complex libraries of barcoded parasites to define how the different phases of an infection shape the pathogen population structure. Unexpectedly, we have discovered that the murine host brain does not restrict parasite colonization, with the population structure predominantly shaped by a bottleneck experienced during the acute phase of infection. These data support an evolutionary strategy to maximize genetic diversity of parasite persister cells within the intermediate host brain for subsequent transmission into the definitive feline host.