Abstract
Trematode parthenitae have long been believed to form clonal populations, but clonal diversity has been discovered in this asexual stage of the lifecycle. Clonal polymorphism in the model species Himasthla elongata has been previously described, but the source of this phenomenon remains unknown. In this work, we traced cercarial clonal diversity using a simplified amplified fragment length polymorphism (SAFLP) method and characterised the nature of fragments in diverse electrophoretic bands. The repetitive elements were identified in both the primary sequence of the H. elongata genome and in the transcriptome data. Long-interspersed nuclear elements (LINEs) and long terminal repeat retrotransposons (LTRs) were found to represent an overwhelming majority of the genome and the transposon transcripts. Most sequenced fragments from SAFLP pattern contained the reverse transcriptase (RT, ORF2) domains of LINEs, and only a few sequences belonged to ORFs of LTRs and ORF1 of LINEs. A fragment corresponding to a CR1-like (LINE) spacer region was discovered and named CR1-renegade (CR1-rng). In addition to RT-containing CR1 transcripts, we found short CR1-rng transcripts in the redia transcriptome and short contigs in the mobilome. Probes against CR1-RT and CR1-rng presented strikingly different pictures in FISH mapping, despite both being fragments of CR1. In silico data and Southern blotting indicated that CR1-rng is not tandemly organised. CR1 involvement in clonal diversity is discussed.
Highlights
Transposable elements (TEs) are considered one of the main factors involved in genome reorganisation and are abundant in the genomes of many eukaryotes [1]
Partial genome sequencing resulted in 13,548,912 paired-end Illumina reads (Bioproject PRJNA698775), and 12,646,374 passed quality filtering
Long-interspersed nuclear elements (LINEs) are prevalent in mobilome contigs, the set of cloned fragments, and TEs in the redia transcriptome
Summary
Transposable elements (TEs) are considered one of the main factors involved in genome reorganisation and are abundant in the genomes of many eukaryotes [1]. TEs may comprise less than ~10% of invertebrate genomes, such as in C. elegans, and more than ~40% of the genomes of vertebrates, such as in humans and mice [2,3,4,5]. Despite the development of genome sequencing and data processing technologies, TEs have been studied in only a limited number of species, predominantly higher eukaryotes. The changes that TEs introduce to the genome can lead to population isolation and, subsequently, to the formation of new species [11,12,13]
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