Draft Genome Assembly of the False Spider Mite Brevipalpus yothersi.

The false spider mite Brevipalpus yothersi infests a broad host plant range and has become one of the most economically important species within the genus Brevipalpus. This phytophagous mite inflicts damage by both feeding on plants and transmitting plant viruses.

B revipalpus yothersi Baker (Tenuipalpidae), previously misidentified as Brevipalpus phoenicis (Geijskes), was recently resurrected, redescribed, and placed in the B. phoenicis sensu stricto group (1). The false spider mite B. yothersi is a vector of several plant viruses, some of which cause diseases in economically important crops, such as citrus and passion fruit (2). More than 40 plant species have been reported as natural hosts of Brevipalpus-transmitted viruses (BTVs) (3). Despite the intense use of pesticides and acaricides (4), even low population densities of the false spider mites are sufficient to infest citrus orchards and spread diseases such as citrus leprosis (CL) in Brazil (5) and potentially in the United States and the European Union (6). Most tropical and subtropical regions in the world have resident Brevipalpus mites (1), and these pose a major threat to crops affected by the transmitted viruses.
Although information on the economic impact of false spider mites in agriculture is limited, it was estimated that almost 10% of the total world acaricide market value is spent on the control of Brevipalpus spp. (7). Brevipalpus phoenicis sensu lato species, which include B. yothersi (1), reproduce by thelytoky parthenogenesis, controlled by a symbiotic relationship with Cardinium bacteria. As a result of the reproductive manipulation, B. yothersi populations almost exclusively consist of haploid females (n ϭ 2 chromosomes) (8).
For sequencing, a B. yothersi population was identified by molecular and morphological traits, as described in Navia et al. (9) and Beard et al. (1), respectively. An isofemale line was reared on sweet orange [Citrus sinensis (L.) Osbeck] fruits. For DNA extraction, 8,000 male mites, lacking Cardinium, were collected, flash frozen, and ground with tungsten beads in batches of 2,000 mites. Batches were homogenized, and total DNA was extracted with a DNeasy blood and tissue kit (Qiagen). The DNA samples were pooled and sequenced on a Roche 454 GS FLXϩ system with one kit for unidirectional sequencing and one for the mate-pair library preparation protocol (spacing, 3 to 8 kb; reads, 700 to 1,000 bp). Additional sequencing of paired-end libraries was prepared with the Gel-Free protocol (Nextera) and performed with an Illumina MiSeq next-generation sequencer (MiSeq run, Nextera kit, 2 ϫ 250 bp reads, 10 to 15 Gb data; see Table 1).
Raw sequencing reads were quality trimmed, and all ends were removed with a quality Phred score below 20. The MiSeq read pairs were joined into pseudoreads and assembled with the 454 reads with an overlap-layout approach (Newbler 2.9.1). The resulting contigs were further scaffolded with the mate-pair reads (SSpace 2.0) (10), and resulting gaps were locally filled through an iterative process (GapFiller 1.10) (11). The obtained genome sequence was assembled into 3,467 contigs scaffolded into 849 larger genomic segments (N 50 , 632 kb; 71.18 Mb; GC, 36.8%) and was annotated with both EuGene (12) and AUGUSTUS (13). We predicted 15,929 protein-coding genes, with an average coding DNA sequence (CDS) length of 1,266 bp. The core eukaryotic protein-coding gene presence was assessed with BUSCO (14) (v3.0, 303 reference genes), with 86.5% complete orthologs present (83.2% single copy, 3.3% duplicates, 2.3% fragments, and 34 genes missing). BLASTP hits against the reference genome of the spider mite Tetranychus urticae identified 11,721 homologous genes. A search with the InterProScan tool could assign known motifs and gene ontology (GO) terms, for, respectively, 10,171 and 7,831 genes.
Data availability. This whole-genome shotgun project has been deposited at DDBJ/ ENA/GenBank as BioProject number PRJNA490612 under the accession number QZCP00000000. The version described in this paper is the first version.

ACKNOWLEDGMENTS
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