Yoko Takasu

Preparation of undegraded native molecular fibroin solution from silkworm cocoons

Abstract The molecular mass of solubilized fibroin prepared from silk was analyzed by SDS-PAGE. It was found that the fibroin molecule was degraded during reeling, degumming (removal of sericin), and dissolution of silk threads. A protocol for the preparation of solubilized fibroin conserving its native molecular size is offered, that is, (1) to use only fresh cocoons (not dry cocoons or reeled silk threads), (2) to degum by heating in 8 M aqueous urea, and (3) to dissolve by saturated (∼9 M) aqueous lithium thiocyanate at room temperature.

Isolation of Three Main Sericin Components from the Cocoon of the Silkworm, Bombyx mori

To characterize the sericin components of the cocoon of silkworm Bombyx mori, fresh cocoon shells were dissolved in saturated aqueous lithium thiocyanate containing 2-mercaptoethanol, and fractionated by ethanol precipitation. Cocoon sericin was found to mainly consist of three polypeptides having molecular masses of the 400, 250, and 150 kDa estimated by SDS-PAGE, which corresponds to the sericin present in the middle, anterior, and posterior part of the middle silk gland. The amino acid compositions of the 400 and 150 kDa components were similar to each other, but that of the 250 kDa component was different. This suggests differences in the coding gene and properties of the 250 kDa sericin from the other two.

Sericin Enhances Attachment of Cultured Human Skin Fibroblasts

Human skin fibroblasts were cultured on sericin prepared from cocoon shells. The living cell number after 72 h was enhanced to 250% of the no-sericin control. The increase was due to the acceleration of the initial attachment of the cells. It was found that sericin M, the main component of about 400 kDa, and its serine-rich repetitive domain were the active principles.

Targeted mutagenesis in the silkworm Bombyx mori using zinc finger nuclease mRNA injection

Targeted mutagenesis is one of the key methods for functional gene analysis. A simplified variant of gene targeting uses direct microinjection of custom-designed Zinc Finger Nuclease (ZFN) mRNAs into Drosophila embryos. To evaluate the applicability of this method to gene targeting in another insect, we mutagenized the Bombyx mori epidermal color marker gene BmBLOS2, which controls the formation of uric acid granules in the larval epidermis. Our results revealed that ZFN mRNA injection is effective to induce somatic, as well as germline, mutations in a targeted gene by non-homologous end joining (NHEJ). The ZFN-induced NHEJ mutations lack end-filling and blunt ligation products, and include mainly 7 bp or longer deletions, as well as single nucleotide insertions. These observations suggest that the B. mori double-strand break repair system relies on microhomologies rather than on a canonical ligase IV-dependent mechanism. The frequency of germline mutants in G(1) was sufficient to be used for gene targeting relying on a screen based solely on molecular methods.

Identification of fibroin-derived peptides enhancing the proliferation of cultured human skin fibroblasts

We previously reported that the fibroin of the silkworm Bombyx mori enhanced the proliferation of cultured human skin fibroblasts. In this work, the fibroin was digested by chymotrypsin, and the resulting peptide fragments were fractionated and assayed for their biological activity. Two peptides that promoted fibroblast growth were isolated and identified to be VITTDSDGNE and NINDFDED. Both sequences are found in the N-terminal region of the fibroin polypeptide and are thought to be the active principle of fibroblast growth-promoting activity.

Recent progress in genome engineering techniques in the silkworm, Bombyx mori.

Rapid advances in genome engineering tools, such as zinc finger nucleases (ZFNs), transcription activator‐like effector nucleases (TALENs), and the clustered regularly interspaced palindromic repeats/CRISPR‐associated (CRISPR/Cas) system, have enabled efficient gene knockout experiments in a wide variety of organisms. Here, we review the recent progress in targeted gene disruption techniques in the silkworm, Bombyx mori. Although efficiency of targeted mutagenesis was very low in an early experiment using ZFNs, recent studies have shown that TALENs can induce highly efficient mutagenesis of desired target genes in Bombyx. Notably, mutation frequencies induced by TALENs can reach more than 50% of G0 gametes. Thus, TALENs can now be used as a standard tool for gene targeting studies, even when mutant phenotypes are unknown. We also propose guidelines for experimental design and strategy for knockout experiments in Bombyx. Genome editing technologies will greatly increase the usefulness of Bombyx as a model for lepidopteran insects, the major agricultural pests, and lead to sophisticated breeding of Bombyx for use in sericulture and biotechnology.

Efficient disruption of endogenous Bombyx gene by TAL effector nucleases

Engineered nucleases are proteins that are able to cleave DNA at specified sites in the genome. These proteins have recently been used for gene targeting in a number of organisms. We showed earlier that zinc finger nucleases (ZFNs) can be used for generating gene-specific mutations in Bombyx mori by an error-prone DNA repair process of non-homologous end joining (NHEJ). Here we test the utility of another type of chimeric nuclease based on bacterial TAL effector proteins in order to induce targeted mutations in silkworm DNA. We designed three TAL effector nucleases (TALENs) against the genomic locus BmBLOS2, previously targeted by ZFNs. All three TALENs were able to induce mutations in silkworm germline cells suggesting a higher success rate of this type of chimeric enzyme. The efficiency of two of the tested TALENs was slightly higher than of the successful ZFN used previously. Simple design, high frequency of candidate targeting sites and comparable efficiency of induction of NHEJ mutations make TALENs an important alternative to ZFNs.

Efficient TALEN construction for Bombyx mori gene targeting.

Engineered nucleases are artificial enzymes able to introduce double stranded breaks at desired genomic locations. The double stranded breaks start the error-prone repair process of non-homologous end-joining (NHEJ), which eventually leads to the induction of mutations at target sites. We showed earlier that ZFNs and TALENs are able to induce NHEJ mutations in the B. mori genome. In order to optimize our mutagenesis protocol, we modified one of the reported truncated TALEN scaffolds and optimized it for use in the B. mori embryo. We also established a novel B. mori somatic cell assay suitable for the preselection of highly efficient TALENs directly in the B. mori model system. We compared the efficiency of several TALEN pairs based on three different frameworks using the BmBLOS2 gene. The new active TALENs show one order of magnitude higher efficiency than those we used previously. We confirmed the utility of our improved protocol by mutagenesis of the autosomal gene, red egg (Bm-re) and showed that it allows obtaining homozygous mutants in G1. Our procedure minimizes the chance of failure in B. mori gene targeting experiments.

Identification of Ser2 proteins as major sericin components in the non-cocoon silk of Bombyx mori.

Sericins are glue proteins of Bombyx mori silk fibers. They are produced in the middle silk gland (MSG) cells, stored in the lumen, and pushed out from the spinneret surrounding the fibroin fibers. The Ser2 gene was partly cloned from the anterior region of the MSG more than 20 years ago and is regarded as a sericin-encoding gene; however, Ser2 proteins do not appear to be major components of cocoon proteins. We used northern blotting to analyze the expression of three sericin genes--Ser1, Ser2, and Ser3--in the MSG of third to fifth instar larvae, and measured the corresponding cDNA levels by competitive PCR. The results revealed that Ser2 gene expression dominated until the middle period of the fifth instar, while the expression of the other genes was mainly observed after the middle fifth instar. Protein analysis demonstrated that the two Ser2 proteins produced by alternative splicing were major coating proteins of larval silk threads spun during the growing stages. The molecular components of larval silk sericin were completely different from those of cocoon sericin, and the difference may be related to the functions of the two kinds of silk fibers.

Structure and expression of the silk adhesive protein Ser2 in Bombyx mori.

Sericins are soluble silk components encoded in Bombyx mori by three genes, of which Ser1 and Ser3 have been characterized. The Ser1 and Ser3 proteins were shown to appear later in the last larval instar as the major sericins of cocoon silk. These proteins are, however, virtually absent in the highly adhesive silk spun prior to cocoon spinning, when the larvae construct a loose scaffold for cocoon attachment. We show here that the silk-gland lumen of the feeding last instar larvae contains two abundant adhesive proteins of 230 kDa and 120 kDa that were identified as products of the Ser2 gene. We also describe the sequence, exon-intron structure, alternative splicing and deduced translation products of this gene in the Daizo p50 strain of B. mori. Two mRNAs of 5.7 and 3.1 kb are generated by alternative splicing of the largest exon. The predicted mature proteins contain 1740 and 882 amino acid residues. The repetitive amino acid sequence encoded by exons 9a and 9b is apparently responsible for the adhesiveness of Ser2 products. It has a similar periodic arrangement of motifs containing lysine and proline as a highly adhesive protein of the mussel Mytilus edulis.