Novel gene rearrangements in the mitochondrial genome of a webspinner, Aposthonia japonica (Insecta: Embioptera).

Webspinners (order Embioptera) are polyneopteran insects characterized by enlarged foretarsi with silk glands, whose silk is used to produce galleries in which the insects live gregariously. The phylogenetic position of webspinners has been debated. In the present study, an almost complete mitochondrial DNA (mtDNA) sequence of Embioptera is reported for the first time. The mtDNA of a webspinner, Aposthonia japonica , has the 13 protein-coding genes (PCGs) generally found in metazoan mtDNA sequences. There is a translocation of a large region including atp6, atp8, cox3, nad3, and nad5 as well as a duplication of the 12S rRNA gene. The rearrangement does not seem to affect nucleotide composition, although amino acid composition in some parts of the mtDNA is biased compared with other Polyneoptera species. Based on phylogenetic analyses using nucleotide sequences of all PCGs concatenated with two rRNA genes and the amino acid sequences of all PCGs, A. japonica is sister to Verophasmatodea, a suborder of typical stick and leaf insects.

Exploring the molecular phylogeny of phasmids with whole mitochondrial genome sequences.

Phasmids are remarkable mimics of twigs, sticks, and leaves. This extreme adaptation for crypsis can easily lead to the convergent evolution of morphology, making it difficult to establish a taxonomic system of phasmids. Accordingly, there are multiple phylogenetic hypotheses that conflict with each other. Phylogenetic arrangements suggested by molecular data disagree with the morphology-based taxonomy in some instances. We collected 13 phasmatodean species, sequenced their mitochondrial genomes, and recovered their molecular phylogeny. Our analyses did not support the monophyly of Areolatae or Anareolatae, two major infraorders of Phasmatodea. The position of Neohirasea was also quite different from the conventional taxonomic systems, thus challenging the previously assumed monophyly of the subfamily Lonchodinae. The enigmatic taxon, Timema, was shown to be distantly related to other phasmatodeans.

A deleted portion of one of the two xanthine dehydrogenase genes causes translucent larval skin in the oq mutant of the silkworm (Bombyx mori).

A silkworm mutant, oq, has translucent larval skin because it is deficient in xanthine dehydrogenase (XDH) activity and is unable to synthesize uric acid, which is normally accumulated in the larval epidermis and makes the skin white and opaque. Two XDH bands were found in zymograms of the silkworm fat body: an intense band (XDHalpha) and a faint one (XDHbeta). The oq mutant lacks only XDHalpha, which seemed to be the major source of XDH activity in the fat body. An 8-bp deletion found in BmXDH1, a silkworm XDH gene, generates a premature stop codon. The resulting truncated BmXDH1 protein lacks three molybdenum cofactor-binding domains necessary for enzyme activity. BmXDH2, the other XDH gene, does not show any apparent deficiencies. BmXDH1 expressed in yeast cells yielded an activity band with the same mobility as that of XDHalpha in zymograms. BmXDH1 of the oq mutant did not yield active XDH in yeast, while the activity was restored by filling in the deleted sequence. These results showed that BmXDH1 deletion in the oq mutant is responsible for the absence of significant XDH activity, resulting in the translucent larval skin of the mutant phenotype.

SID-1 protein of Caenorhabditis elegans mediates uptake of dsRNA into Bombyx cells.

RNA interference is one of the most revolutionary tools in the study of gene function, particularly in non-model systems. However, in Bombyx mori, as with many lepidopteran species, attempts at systemic RNAi have had mixed success. Gene identification and phylogenetic analyses suggest that Bombyx has the core RNAi machinery, which is necessary to undergo RNAi as a cellular response. We introduced sid genes from Caenorhabditis elegans into Bombyx BmN4 cells to enhance the uptake of dsRNA and revealed that the SID-1 protein, but not SID-2, has the ability to endow the RNAi effect with the addition of dsRNA to the medium. Observed RNAi effect was dependent on both the levels of sid-1 expression and the concentration of the dsRNA. These results suggest that SID-1 promotes the uptake of dsRNA from the medium into Bombyx cells. We generated transgenic animals that express sid-1 but have not detected significant enhancements of in vivo phenotype in response to the injection of the dsRNA into hemocoel.

A single-base deletion in an ABC transporter gene causes white eyes, white eggs, and translucent larval skin in the silkworm w-3(oe) mutant.

The w-3(oe) silkworm mutant has white eyes and eggs due to the absence of ommochrome pigments in the eye pigment cells and serosa cells. The mutant is also characterized by translucent larval skin resulting from a deficiency in the transportation of uric acid, which acts as a white pigment in larval epidermal cells. A silkworm homolog of the fruitfly white gene, Bmwh3, a member of ATP-binding cassette transporter superfamily, was mapped on the w-3 locus. The w-3(oe) mutant has a single-base deletion in exon 2 and a premature stop codon at the 5' end of exon 3. These results show that w-3 is equivalent to Bmwh3 and is responsible for the transportation of ommochrome precursors and uric acid into pigment granules and urate granules, respectively.