A few years ago, we accidentally sequenced an interesting mite when making the Rhodamnia argentea reference genome. We don’t really know what it is, but thanks to nanopore sequencing and a low repeat content, we produced a gapless telomere-to-telomere assembly! As an unfunded passion project, it’s been ticking along in the background since then, but is now published in Genome Biology and Evolution.
One of the most interesting aspects of the paper is the genome reduction - despite being a complete nuclear genome, the assembly is under 35 megabases! This is a couple of orders of magnitude smaller than many other arachnid genomes.
We are yet to do a comprehensive analysis, but just looking at the core set of expected arachnid genes, as defined by BUSCO (e.g. single-copy genes that are expected to be present in most arachnid genomes) revealed that about a third of them were missing. (This low completeness was partly responsible for the time taken to fully recognised and deal with the contamination.) Tellingly, the closest sequenced relatives of this mite also have reduced genomes and are missing many of the same BUSCO genes, revealing a long history of gene loss.
The proportion of “Duplicated” BUSCO genes is also surprisingly high at 4.5%. These are genuine duplications, with consistent diploid read depths and many of the pairs present on both chromosomes. It will be interesting to see if these duplications are replacing some of the lost functions from the other genes, or are novel genes behind such a specialised lifestyle. As an unfunded passion project, it was beyond scope to investigate the full annotation as part of this paper, but get in touch if you would be interested to do this!
Edwards RJ, Chen SH, Halliday B & Bragg JG (2025): Small but mitey: a gapless telomere-to-telomere assembly of an unidentified mite with a streamlined genome. Genome Biology and Evolution Feb 13. [Gen Biol Evol] [PubMed]
Abstract
A draft assembly of the rainforest tree Rhodamnia argentea Benth. (malletwood, Myrtaceae) revealed contaminating DNA sequences that most closely matched those from mites in the family Eriophyidae. Eriophyoid mites are plant parasites that often induce galls or other deformities on their host plants. They are notable for their small size (averaging 200 μm), distinctive four-legged body structure, and heavily streamlined genomes, which are among the smallest known of all arthropods. Contaminating mite sequences were assembled into a high-quality gapless telomere-to-telomere nuclear genome. The entire genome was assembled on two fully contiguous chromosomes, capped with a novel TTTGG or TTTGGTGTTGG telomere sequence, and exhibited clear signs of genome reduction (34.5 Mbp total length, 68.6% arachnid Benchmarking Universal Single-Copy Ortholog completeness). Phylogenomic analysis confirmed that this genome is that of a previously unsequenced eriophyoid mite. Despite its unknown identity, this complete nuclear genome provides a valuable resource to investigate invertebrate genome reduction.
