21Background: Chromosome-level assemblies are indispensable for accurate gene prediction, 22 synteny assessment and understanding higher-order genome architecture. Reference and draft 23 genomes of key helminth species have been published but little is yet known about the biology 24 of their chromosomes. Here we present the complete genome of the tapeworm Hymenolepis 25 microstoma, providing a reference-quality, end-to-end assembly that represents the first fully 26 assembled genome of a spiralian/lophotrochozoan, revealing new insights into chromosome 27 evolution. 28Results: Long-read sequencing and optical mapping data were added to previous short-read 29 data enabling complete re-assembly into six chromosomes, consistent with karyology. Small 30 genome size (169 Mb) and lack of haploid variation (1 SNP/3.2 Mb) contributed to exceptionally 31 high contiguity with only 85 gaps remaining in regions of low complexity sequence. Resolution of 32 repeat regions reveals novel gene expansions, micro-exon genes, and spliced leader trans-33 splicing, and illuminates the landscape of transposable elements, explaining observed length 34 differences in sister chromatids. Syntenic comparison with other parasitic flatworms shows 35 conserved ancestral linkage groups indicating that the H. microstoma karyotype evolved through 36 fusion events. Strikingly, the assembly reveals that the chromosomes terminate in centromeric 37 arrays, indicating that these motifs play a role not only in segregation, but also in protecting the 38 linear integrity and full lengths of chromosomes. 39
Conclusions:Despite strong conservation of canonical telomeres, our results show that they 40 can be substituted by more complex, species-specific sequences, as represented by 41 centromeres. The assembly provides a robust platform for investigations that require complete 42 genome representation. 43 44 3