A single-parasite transcriptional atlas of Toxoplasma Gondii reveals novel control of antigen expression.

ABSTRACT

Toxoplasma gondii, a protozoan parasite, undergoes a complex and poorly understood developmental process that is critical for establishing a chronic infection in its intermediate hosts. Here, we applied single-cell RNA-sequencing (scRNA-seq) on >5,400 Toxoplasma in both tachyzoite and bradyzoite stages using three widely studied strains to construct a comprehensive atlas of cell-cycle and asexual development, revealing hidden states and transcriptional factors associated with each developmental stage. Analysis of SAG1-related sequence (SRS) antigenic repertoire reveals a highly heterogeneous, sporadic expression pattern unexplained by measurement noise, cell cycle, or asexual development. Furthermore, we identified AP2IX-1 as a transcription factor that controls the switching from the ubiquitous SAG1 to rare surface antigens not previously observed in tachyzoites. In addition, comparative analysis between Toxoplasma and Plasmodium scRNA-seq results reveals concerted expression of gene sets, despite fundamental differences in cell division. Lastly, we built an interactive data-browser for visualization of our atlas resource.

Toxoplasma gondii is a single-celled parasite that can infect most warm-blooded animals, but only reproduces sexually in domestic and wild cats. Distantly related to the malaria agent, it currently infects over a quarter of the world's human population. Although it is benign in most cases, the condition can still be dangerous for foetuses and people whose immune system is compromised. In the human body, Toxoplasma cells infiltrate muscle and nerve cells; there it undergoes a complex transformation that helps the parasites to stop dividing quickly and instead hide from the immune system in a dormant state. It is still unclear how this transition unfolds, and in particular which genes are switched on and off at any given time. To understand this transformation, scientists often measure which genes are active across a group of parasites. However, this approach gives only an 'average' picture and does not allow each parasite to be profiled, missing out on the diversity that may exist between individuals. One area of particular interest, for example, is a set of genes called SAG1-related sequences. They code for the 'molecular overcoat' of the parasite, an array of proteins that sit on the surface of Toxoplasma cells. More than 120 SAG1-related genes exist in the genome of each Toxoplasma parasite, creating a whole wardrobe of proteins that potentially hide the parasites from the immune system. Here, Xue et al. harnessed a technique called single-cell RNA sequencing, which allowed them to screen which genes were active in 5,400 individual Toxoplasma parasites from different strains. The analysis included both the rapidly dividing form of the parasite (present in the initial stage of an infection), and the slowly dividing form found in people who carry Toxoplasma without any symptoms. The resulting 'atlas' contains previously hidden information about the genes used at each stage of parasite development this included unexpected similarities between Toxoplasma and the malaria agent, as well as subtle differences between two of the Toxoplasma strains. The atlas also sheds light on how individual parasites turns on SAG1-related sequences. It reveals a surprising diversity in the composition of the protein coats sported by Toxoplasma cells at the same developmental stage, a strategy that may help to thwart the immune system. One individual parasite in particular had an unusual combination of coat and other proteins found in both the fast and slow-dividing human forms. This parasite had been grown in human cells, yet a closer analysis revealed that it had activated several genes (including ones encoding the protein coat) that are normally only 'on' in the parasites going through sexual reproduction in domestic and wild cats. This new data atlas helps to understand how Toxoplasma are transmitted to and grow within humans, which could aid the development of treatments. Ultimately, a better knowledge of these parasites could also bring new information about the agent that causes malaria.