Katsura Kojima

Use of RNAi technology to confer enhanced resistance to BmNPV on transgenic silkworms

Summary.dsRNA is a powerful tool for gene-specific silencing in plants and animals. In this study, we examined the use of gene silencing in generating transgenic silkworms resistant to the Bombyx mori nucleopolyhedrovirus (BmNPV). Using a transposon piggyBac system, we first generated BmN cells (rBmN-lef1), which carried artificial genes designed for expressing dsRNAs with sequences of the essential viral gene lef-1. NPV DNA microarray analysis revealed that the accumulation of lef-1 mRNA was successfully inhibited in rBmN-lef1 infected with BmNPV. The virus titer in the culture medium of rBmN-lef1 at 48 hr post-infection (h.p.i.) was 50% of that of the control cells. Moderate BmNPV-resistance caused by transgenesis of the artificial dsRNA-expressing gene was confirmed in the transgenic silkworms. Virus production was reduced in transgenic silkworms relative to controls up to 96 hrs after viral inoculation. Although complete protection was not achieved and the transgenic larvae ultimately died, this is the first report to show the use of RNAi in confering enhanced viral resistance on transgenic animals.

A New Method for the Modification of Fibroin Heavy Chain Protein in the Transgenic Silkworm

We constructed a new plasmid vector for the production of a modified silk fibroin heavy chain protein (H-chain) in the transgenic silkworm. The plasmid (pHC-null) contained the promoter and the 3′ region of a gene encoding the H-chain and the coding regions for the N-terminal domain and the C-terminal domain of the H-chain. For the model protein, we cloned a foreign gene that encoded EGFP between the N-terminal domain and the C-terminal domain in pHC-null and generated transgenic silkworms that produced a modified H-chain, HC-EGFP. Transgenic silkworms produced HC-EGFP in the posterior part of silk gland cells, secreted it into the lumen of the gland, and produced a cocoon with HC-EGFP as part of the fibroin proteins. N-terminal sequencing of HC-EGFP localized the signal sequence cleavage site to between positions A(21) and N(22). These results indicate that our new plasmid successfully produced the modified H-chain in a transgenic silkworm.

Effects of RGDS sequence genetically interfused in the silk fibroin light chain protein on chondrocyte adhesion and cartilage synthesis.

Initial chondrocyte-silk fibroin interactions are implicated in chondrogenesis when using fibroin as a scaffold for chondrocytes. Here, we focused on integrin-mediated cell-scaffold adhesion and prepared cell adhesive fibroin in which a tandem repeat of the Arg-Gly-Asp-Ser (RGDS) sequence was genetically interfused in the fibroin light chain (L-chain) (L-RGDSx2 fibroin). We investigated the effects of the sequence on chondrocyte adhesion and cartilage synthesis, in comparison to the effects of fibronectin. As the physicochemical surface properties (e.g., wettability and zeta potential) of the fibroin substrate were not affected by the modification, specific cell adhesion to the RGDS predominately changed the chondrocyte adhesive state. This suggestion was also supported by the competitive inhibition of chondrocyte attachment to the L-RGDSx2 fibroin substrate with soluble RGD peptides in the medium. Unlike fibronectin, the expression of RGDS in the fibroin L-chain had no effect on chondrocyte spreading area but enhanced mRNA expression levels of integrins alpha5 and beta1, and aggrecan at 12 h after seeding. Although both the sequence and fibronectin increased cell adhesive force, chondrocytes grown on the fibroin substrate exhibited a peak in the force with time in culture. These results suggested that moderate chondrocyte adhesion to fibroin induced by the RGDS sequence was able to maintain the chondrogenic phenotype and, from the histology findings, the sequence could facilitate chondrogenesis.

Identification of Four Major Hornet Silk Genes with a Complex of Alanine-Rich and Serine-Rich Sequences in Vespa simillima xanthoptera Cameron

Hornet silk, a fibrous protein in the cocoon produced by the larva of the vespa, is composed of four major proteins. In this study, we constructed silk-gland cDNA libraries from larvae of the hornet Vespa simillima xanthoptera Cameron and deduced the full amino acid sequences of the four hornet silk proteins, which were named Vssilk 1–4 in increasing order of molecular size. Portions of the amino acid sequences of the four proteins were confirmed by Matrix-assisted laser desorption/ionization-time of flight/mass spectrometry (MALDI-TOF/MS) and N-terminal protein sequencing. The primary sequences of the four Vssilk proteins (1–4) were highly divergent, but the four proteins had some common properties: (i) the amino acid compositions of all four proteins were similar to each other in that the well-defined and characteristic repetitive patterns present in most of the known silk proteins were absent; and (ii) the characteristics of the amino acid sequences of the four proteins were also similar in that Ser-rich structures such as sericin were localized at both ends of the chains and Ala-rich structures such as fibroin were found in the center. These characteristic primary structures might be responsible for the coexisting α-helix and β-sheet conformations that make up the unique secondary structure of hornet silk proteins in the native state. Because heptad repeat sequences of hydrophobic residue are present in the Ala-rich region, we believe that the Ala-rich region of hornet silk predominantly forms a coiled coil with an α-helix conformation.

High-Toughness Silk Produced by a Transgenic Silkworm Expressing Spider (Araneus ventricosus) Dragline Silk Protein

Spider dragline silk is a natural fiber that has excellent tensile properties; however, it is difficult to produce artificially as a long, strong fiber. Here, the spider (Araneus ventricosus) dragline protein gene was cloned and a transgenic silkworm was generated, that expressed the fusion protein of the fibroin heavy chain and spider dragline protein in cocoon silk. The spider silk protein content ranged from 0.37 to 0.61% w/w (1.4–2.4 mol%) native silkworm fibroin. Using a good silk-producing strain, C515, as the transgenic silkworm can make the raw silk from its cocoons for the first time. The tensile characteristics (toughness) of the raw silk improved by 53% after the introduction of spider dragline silk protein; the improvement depended on the quantity of the expressed spider dragline protein. To demonstrate the commercial feasibility for machine reeling, weaving, and sewing, we used the transgenic spider silk to weave a vest and scarf; this was the first application of spider silk fibers from transgenic silkworms.

Mechanical Properties of Regenerated Bombyx mori Silk Fibers and Recombinant Silk Fibers Produced by Transgenic Silkworms

Regenerated silk fibroin fibers from the cocoons of silkworm, Bombyx mori, were prepared with hexafluoro solvents, 1,1,1,3,3,3-hexafluoro-2-propanol (HFIP) or hexafluoroacetone-trihydrate (HFA), as dope solvents and methanol as coagulation solvent. The regenerated fiber prepared from the HFIP solution showed slightly larger tensile strength when the draw ratio is 1:3 than that of native silk fiber, but the strength of the regenerated fiber with draw ratio 1:3 from the HFA solution is much lower than that of native silk fiber. This difference in the tensile strength of the regenerated silk fibers between two dope solvents comes from the difference in the long-range orientation of the crystalline region rather than that of short-range structural environment such as the fraction of β-sheet structure. The increase in the biodegradation was observed for the regenerated silk fiber compared with native silk fiber. Preparations of regenerated silk fibroin fibers containing spider silk sequences were obtained by mixing silk fibroins and silk-like proteins with characteristic sequences from a spider, Naphila clavipes, to produce drag-line silk in E. coli in the fluoro solvents. A small increase in the tensile strength was obtained by adding 5% (w/w) of the silk-like protein to the silk fibroin. The production of silk fibroin fibers with these spider silk sequences was also performed with transgenic silkworms. Small increase in the tensile strength of the fibers was obtained without significant change in the elongation-at-break.

Assembly of the silk fibroin elementary unit in endoplasmic reticulum and a role of L‐chain for protection of α1,2‐mannose residues in N‐linked oligosaccharide chains of fibrohexamerin/P25

Silk fibroin of Bombyx mori is secreted from the posterior silk gland (PSG) as a 2.3‐MDa elementary unit, consisting of six sets of a disulfide‐linked heavy chain (H‐chain)–light chain (L‐chain) heterodimer and one molecule of fibrohexamerin (fhx)/P25. Fhx/P25, a glycoprotein, associates noncovalently with the H–L heterodimers. The elementary unit was found and purified from the endoplasmic reticulum (ER) extract of PSG cells. A substantial amount of fhx/P25 unassembled into the elementary unit was also present in ER. In normal‐level fibroin‐producing breeds (J‐139 and C108), the elementary unit contained fhx/P25 of either 30 kDa (major) or 27 kDa (minor). The 27‐kDa fhx/P25 was produced from the 30‐kDa form by digestion with the bacterial α1,2‐mannosidase in vitro. The elementary unit in the ER extract contained only the 30‐kDa fhx/P25, whereas both 30‐ and 27‐kDa forms of fhx/P25 were present in the ER plus Golgi mixed extracts. In naked‐pupa mutants [Nd(2), Nd‐s and Nd‐s D], extremely small amounts of fibroin were produced and they consisted of one molecule of 27‐kDa fhx/P25 and six molecules of H‐chain but no L‐chain. When the Nd‐s D mutant was subjected to transgenesis with the normal L‐chain gene, the (H‐L)6fhx1‐type elementary unit containing the 30‐kDa fhx/P25, was produced. These results suggest that fhx/P25 in the elementary unit is largely protected from digestion with Golgi α1,2‐mannosidases when L‐chains are present in the unit. Models suggesting a role of L‐chain for the protection of α1,2‐mannose residues of fhx/P25 are presented.

Cross-linking in the silks of bees, ants and hornets

Silk production is integral to the construction of nests or cocoons for many Aculeata, stinging Hymenopterans such as ants, bees and wasps. Here we report the sequences of new aculeate silk proteins and compare cross-linking among nine native silks from three bee species (Apis mellifera, Bombus terrestris and Megachile rotundata), three ant species (Myrmecia forficata, Oecophylla smaragdina and Harpegnathos saltator) and three hornets (Vespa analis, Vespa simillima and Vespa mandarinia). The well studied silks of spiders and silkworms are comprised of large proteins that are cross-linked and stabilized predominantly by intra and intermolecular beta sheet structure. In contrast, the aculeate silks are comprised of relatively small proteins that contain central coiled coil domains and comparatively reduced amounts of beta sheet structure. The hornet silks, which have the most beta sheet structure and the greatest amount of amino acid sequence outside the coiled-coil domains, dissolve in concentrated LiBr solution and appear to be stabilized predominantly by beta sheet structure like the classic silks. In contrast, the ant and bee silks, which have less beta sheet and less sequence outside the coiled-coil domains, could not be dissolved in LiBr and appear to be predominantly stabilized by covalent cross-linking. The iso-peptide cross-linker, ε-(γ-glutamyl)-lysine that is produced by transglutaminase enzymes, was demonstrated to be present in all silks by mass spectrometry, but at greater levels in silks of ants and bees. The bee silks and ant cocoons, but not the Oecophylla nest silks, appeared to be further stabilized by tanning reactions.

An efficient binary system for gene expression in the silkworm, Bombyx mori, using GAL4 variants

A binary gene expression system using the yeast GAL4 DNA-binding protein and the upstream activating sequence (UAS) of galactose-driven yeast genes is an established and powerful tool for the analysis of gene function. However, in the domesticated silkworm, Bombyx mori, this system has been limited in its utility by the relatively low transcriptional activation activity of GAL4 and by its toxicity. In this study, we investigated the potential of several established GAL4 variants (GAL4Δ, GAL4VP16, GAL4VPmad2, GAL4VPmad3, and GAL4NFκB) and of two new GAL4 variants, GAL4Rel and GAL4Relish, which contain the transcription-activating regions of the BmRel and BmRelish genes, respectively, to improve the utility of the GAL4/UAS system in B. mori. We generated constructs containing these GAL4 variants under the control of constitutive or inducible promoters and investigated their transcription-activating activity in cultured B. mori cells and embryos and in transgenic silkworms. GAL4VP16 and GAL4NFκB exhibited high transactivation activity but appeared to be toxic when used as transgenes under the control of a constitutive promoter. Similarly, GAL4VPmad2 and GAL4VPmad3 exhibited higher transactivation activity than GAL4, combined with strong toxicity. The transcription-activating activity of GAL4Δ was about twice that of GAL4. The two new GAL4 variants, GAL4Rel and GAL4Relish, were less active than GAL4. Using GAL4VP16 and GAL4NFκB constructs, we have developed a very efficient GAL4/UAS binary gene expression system for use in cultured B. mori cells and embryos and in transgenic silkworms.

Drawing-Induced Changes in Morphology and Mechanical Properties of Hornet Silk Gel Films

Complete amino acid sequences of the four major proteins (Vssilk 1-4) of silk (hornet silk) obtained from yellow hornet ( Vespa simillima , Vespinae, Vespidae) cocoons have been determined. The native structure of the hornet silk (HS), in which Vssilk 1-4 have an alpha-helix domain with coiled-coil alpha-helices and a beta-sheet domain, is restored when hornet silk gel films (HSGFs) are formed by pressing and drying HS hydrogel. Necking occurs when dry HSGFs are drawn; however, wet HSGFs can be uniaxially drawn with a draw ratio (DR) of 2. Drawing helps obtain high-performance films with a maximum tensile strength and tensile modulus of 170 MPa and 5.5 GPa, respectively. Drawing-induced changes in the orientation and conformation of the coiled-coil structure are investigated.