Modular cis‐regulatory logic of yellow gene expression in silkmoth larvae

Colour patterns in butterflies and moths are crucial traits for adaptation. Previous investigations have highlighted genes responsible for pigmentation (ie yellow and ebony). However, the mechanisms by which these genes are regulated in lepidopteran insects remain poorly understood. To elucidate this, molecular studies involving dipterans have largely analysed the cis‐regulatory regions of pigmentation genes and have revealed cis‐regulatory modularity. Here, we used well‐developed transgenic techniques in Bombyx mori and demonstrated that cis‐regulatory modularity controls tissue‐specific expression of the yellow gene. We first identified which body parts are regulated by the yellow gene via black pigmentation. We then isolated three discrete regulatory elements driving tissue‐specific gene expression in three regions of B. mori larvae. Finally, we found that there is no apparent sequence conservation of cis‐regulatory regions between B. mori and Drosophila melanogaster, and no expression driven by the regulatory regions of one species when introduced into the other species. Therefore, the trans‐regulatory landscapes of the yellow gene differ significantly between the two taxa. The results of this study confirm that lepidopteran species use cis‐regulatory modules to control gene expression related to pigmentation, and represent a powerful cadre of transgenic tools for studying evolutionary developmental mechanisms.     

Transgenic characterization of two testis‐specific promoters in the silkworm,Bombyx mori

Sex‐specific regulatory elements are key components for developing insect genetic sexing systems. The current insect genetic sexing system mainly uses a female‐specific modification system whereas little success was reported on male‐specific genetic modification. In the silkworm Bombyx mori, a lepidopteran model insect with economic importance, a transgene‐based, female‐specific lethality system has been established based on sex‐specific alternative splicing factors and a female‐specific promoter BmVgp (vitellogenin promoter) has been identified. However, no male‐specific regulatory elements have yet been identified. Here we report the transgenic identification of two promoters that drive reporter gene expression in a testis‐specific manner in B. mori. Putative promoter sequences from the B. mori Radial spoke head 1 gene (BmR1) and beta‐tubulin 4 gene (Bmβ4) were introduced using piggybac‐based germline transformation. In transgenic silkworms, expression of the reporter gene enhanced green fluorescent protein (EGFP) directed by either BmR1 promoter (BmR1p) or Bmβ4p showed precisely testis‐specific manners from the larval to adult stage. Furthermore, EGFP expression of these two transgenic lines showed different localization in the testis, indicating that BmR1p or Bmβ4p might be used as distinct regulatory elements in directing testis‐specific gene expression. Identification of these testis‐specific promoters not only contributes to a better understanding of testis‐specific gene function in insects, but also has potential applications in sterile insect techniques for pest management.     

Two Tor genes in the silkworm Bombyx mori

Target of rapamycin (TOR), a member of the phosphatidylinositol kinase‐related kinase family, plays a critical role in the regulation of growth, metabolism, development and survival, at both the cellular and the organismal levels. Two paralogous Tor genes, BmTor1 and BmTor2, were identified as a pair of inverted repeats in the genome of the silkworm Bombyx mori. The synteny of BmTor1 and CG8360 indicates that BmTor1 is the orthologue while BmTor2 is a duplicate. Analyses of the two BmTor genes at both the nucleotide and amino acid levels reveal that they are evolutionally and structurally conserved. The two BmTor genes had similar expression patterns of tissue distribution with highest levels in the nervous system, and nearly identical developmental change profiles with maximal levels during the 4^th‐larval‐moulting and the larval–pupal transition stages. Furthermore, both BmTor genes were up‐regulated by either starvation or the moulting hormone 20‐hydroxyecdysone (20E), while BmTor2 was more sensitive to both treatments than BmTor1. For the first time, we have identified two copies of the Tor gene in a higher eukaryote, which are induced by starvation and 20E during the larval moulting and the larval–pupal transition stage.     

Transgenic analysis of the BmBLOS2 gene that governs the translucency of the larval integument of the silkworm,Bombyx mori

The larval integument of the silkworm, Bombyx mori, is opaque because urate granules accumulate in the epidermis. Although the biosynthetic pathway of uric acid is well studied, little is known about how uric acid accumulates as urate granules in epidermal cells. In the distinct oily (od) mutant silkworm, the larval integument is translucent because of the inability to construct urate granules. Recently, we have found that the od mutant has a genomic deletion in the B. mori homologue of the human biogenesis of lysosome‐related organelles complex1, subunit 2 (BLOS2) gene (BmBLOS2). Here, we performed a molecular and functional characterization of BmBLOS2. Northern blot analysis showed that BmBLOS2 was ubiquitously expressed in various tissues. We analysed the structure of a newly isolated mutant (od^B) allelic to od and found a premature stop codon in the coding sequence of BmBLOS2 in this new mutation. Moreover, the translucent phenotype was rescued by the germ‐line transformation of the wild‐type BmBLOS2 allele into the od mutant. Our results suggest that BmBLOS2 is responsible for the od mutant phenotype and plays a crucial role in biogenesis of urate granules in the larval epidermis of the silkworm. The relationships amongst Hermansky–Pudlak syndrome (HPS) genes in mammals, granule group genes in Drosophila and translucent mutant genes in B. mori are discussed.     

Systemic disruption of the homeostasis of transfer RNA isopentenyltransferase causes growth and development abnormalities in Bombyx mori

Isopentenylation at A37 (i⁶A37) of some transfer RNAs (tRNAs) plays a vital role in regulating the efficiency and fidelity of protein synthesis. However, whether insects, which are well known for their highly efficient protein synthesis machinery, employ this regulatory mechanism remains uninvestigated. In the current study, a candidate tRNA isopentenyltransferase (IPT) gene with three alternative splicing isoforms (BmIPT1–BmIPT3) was identified in Bombyx mori (silkworm). Only BmIPT1 could complement a yeast mutant lacking tRNA IPT. Phylogenetic analysis showed that silkworm tRNA IPT is conserved in the Lepidoptera. BmIPT was expressed in all B. mori tissues and organs that were investigated, but was expressed at a significantly higher level in silk glands of the fourth instar compared to the first day of the fifth instar. Interestingly, BmIPT was expressed at a significantly higher level in the domesticated silkworm, B. mori, than in wild Bombyx mandarina in multiple tissues and organs. Knock‐down of BmIPT by RNA interference caused severe abnormalities in silk spinning and metamorphosis. Constitutive overexpression of BmIPT1 using a cytoplasmic actin 4 promoter in B. mori raised its messenger RNA level more than sixfold compared with nontransgenic insects and led to significant decreases in the body weight and cocoon shell ratio. Together, these results confirm the first functional tRNA IPT in insects and show that a suitable expression level of tRNA IPT is vital for silk spinning, normal growth, and metamorphosis. Thus, i⁶A modification at position A37 in tRNA probably plays an important role in B. mori protein synthesis.