Third generation sequencing revises the molecular karyotype for Toxoplasma gondii and identifies emerging copy number variants in sexual recombinants

Toxoplasma gondii is an obligate intracellular parasite that has a significant impact on human health, especially in the immunocompromised. This parasite is also a useful genetic model for intracellular parasitism given its ease of culture in the laboratory and relevant animal models. However, as for many other eukaryotes, the T. gondii genome is incomplete, containing hundreds of sequence gaps due to the presence of repetitive and/or uncloneable sequences that prevent complete telomere-to-telomere de novo chromosome assembly. Here, we report the first use of single molecule DNA sequencing to generate near complete de novo genome assemblies for T. gondii and its near relative, N. caninum. Using the Oxford Nanopore Minion platform, we dramatically improved the contiguity of the T. gondii genome (N50 of ~6.6Mb) and increased overall assembled sequence compared to current reference sequences by ~2 Mb. Multiple complete chromosomes were fully assembled as evidenced by clear telomeric repeats on the end of each contig. Interestingly, for all of the Toxoplasma gondii strains that we sequenced (RH, CTG, II x III F1 progeny clones CL13, S27, S21, and S26), the largest contig ranged in size between 11.9 and 12.1 Mb in size, which is larger than any previously reported T. gondii chromosome. This was due to a repeatable and consistent fusion of chromosomes VIIb and VIII. These data were further validated by mapping existing T. gondii ME49 Hi-C data to our assembly, providing parallel lines of evidence that the T. gondii karyotype consists of 13, rather than 14, chromosomes. In addition revising the molecular karyotype we were also able to resolve hundreds of repeats, including short tandem repeats and larger tandem gene expansions. For well-known host-targeting effector loci like rhoptry protein 5 (ROP5) and mitochondrial association factor 1 (MAF1), we were also able to accurately determine the precise gene count, order, sequence and orientation. Finally, when we compared the T. gondii and N. caninum assemblies we found that while the 13 chromosome karyotype was conserved, we determined that previously unidentified large scale translocation events occurred in T. gondii and N. caninum since their most recent common ancestry.