家蚕丝素蛋白轻链基因（fib-L）启动子序列的克隆及其活性分析

家蚕Bombyx mori丝素蛋白轻链（fibroin light-chain, fib-L）基因fib-L具有在后部丝腺组织专一性、高效性表达的特点。为了利用其启动子构建能够表达外源基因的丝腺生物工厂,本实验对fib-L启动子活性进行了研究。通过PCR法克隆了fib-L启动子元件,序列分析显示fib-L启动子由位于-33 ～ -25处的TATA盒元件和位于－128～－121处的特征性序列GTCAATTT共同组成。用fib-L启动子控制报告基因DsRed进行家蚕BmN细胞和蚕体内的瞬时表达研究,结果表明fib-L启动子可以驱动DsRed报告基因在BmN细胞和家蚕后部丝腺组织中瞬时表达。     

Expression of hIGF-I in the silk glands of transgenic silkworms and in transformed silkworm cells

To express human insulin-like growth factor-I (hIGF-I) in transformed Bombyx mori cultured cells and silk glands, the transgenic vector pigA3GFP-hIGF-ie-neo was constructed with a neomycin resistance gene driven by the baculovirus ie-1 promoter, and with the hIGF-I gene under the control of the silkworm sericin promoter Ser-1. The stably transformed BmN cells expressing hIGF-I were selected by using the antibiotic G418 at a final concentration of 700—800 μg/mL after the BmN cells were transfected with the piggyBac vector and the helper plasmid. The specific band of hIGF-I was detected in the transformed cells by Western blot. The expression level of hIGF-I, determined by ELISA, was about 7800 pg in 5×10⁵ cells. Analysis of the chromosomal insertion sites by inverse PCR showed that exogenous DNA could be inserted into the cell genome randomly or at TTAA target sequence specifically for piggyBac element transposition. The transgenic vector pigA3GFP-hIGF-ie-neo was transferred into the eggs using sperm-mediated gene transfer. Finally, two transgenic silkworms were obtained after screening for the neo and gfp genes and verified by PCR and dot hybridization. The expression level of hIGF-I determined by ELISA was about 2440 pg/g of silk gland of the transgenic silkworms of the G1 generation.     

Expression of the hIGF-I gene driven by the Fhx/P25 promoter in the silk glands of germline silkworm and transformed BmN cells

The expression of the human insulin-like growth factor (hIGF-I) gene driven by the Fhx/P25 promoter in the silk glands of transgenic silkworms (Bombyx mori) and in transformed silkworm cells, was achieved using BmN cells transfected with a piggyBac vector, pigA3GFP-Fhx/P25-hIGF-ie-neo containing a neomycin-resistance gene (neo), a green fluorescent protein gene (gfp), an hIGF-I gene, and a helper plasmid containing the piggyBac transposase sequence under the control of the B. mori actin 3 (A3) promoter. We selected stably transformed BmN cells expressing hIGF-I using the antibiotic G418. The expression level of hIGF-I was about 450 pg in 3 × 10(6) cells, determined by ELISA. The piggyBac vector was transferred into the silkworm eggs using sperm-mediated gene transfer. The expression level of hIGF-I per gram fresh posterior silk glands of G4 transgenic silkworms was approx. 150 ng.     

Transgenic silkworms that weave recombinant proteins into silk cocoons

As a result of breeding for more than 4,000 years, the silkworm, Bombyx mori, has acquired the ability to synthesize bulk amounts of silk proteins in its silk glands. To utilize this capacity for mass production of useful proteins, transgenic silkworms were generated that synthesized recombinant proteins in the silk gland and secreted them into the silk cocoon. The silk gland is classified into two main regions: the posterior (PSG) and the middle silk gland (MSG). By controlling the expressed regions of the recombinant protein gene in the silk gland, we were able to control the localization of the synthesized protein in the silk thread. Expression in the PSG or MSG led to localization in the insoluble fibroin core or hydrophilic outer sericin layer, respectively. This review focuses on the expression of recombinant protein in the MSG of transgenic silkworms. The recombinant protein secreted in the sericin layer is extractable from the cocoon with only a small amount of endogenous silk protein contamination by soaking the cocoon in mild aqueous solutions. The possibility of utilizing transgenic silkworms as a valuable tool for the mass production of therapeutic and industrially relevant recombinant proteins is discussed.     

Identification and purification of a Bombyx mori homologue of FTZ-F1.

Extracts from embryos and from posterior and middle silk glands of the silkworm, Bombyx mori contain a sequence specific DNA binding factor termed BmFTZ-F1. The factor binds to the recognition site of FTZ-F1, a positive regulator of the fushi tarazu gene in Drosophila melanogaster. BmFTZ-F1 and FTZ-F1 share the same methylation interference patterns, the same chromatographic behaviors and similar protease digestion profiles. Anti-FTZ-F1 cross reacts with BmFTZ-F1. These results indicate that BmFTZ-F1 is a B. mori homologue of FTZ-F1. The mobility of the factor-DNA complex formed in the silk gland extract changes depending on the developmental stages. Purification of BmFTZF1 to an almost homogeneous state reveals that the factor is a 73 kd protein.     

Novel enhancer and promoter elements indispensable for the tissue-specific expression of the sericin-1 gene of the silkworm Bombyx mori

Sericins are glue proteins produced specifically in the middle silk gland (MSG) of the silkworm Bombyx mori, while the silk fiber protein, fibroin, is produced in the posterior silk gland (PSG). These silk proteins are expected to be useful biomaterials in medical technology as well as biotechnology. In this study, we analyzed promoter elements of the sericin-1 gene (ser1) in vivo by introducing reporter constructs into silk glands via gene gun technology. The region from −1602 to +47 was sufficient to induce MSG-specific expression. The 5′ deletion mutants showed a three-step decrease in promoter activity with the key sequences located between −1362 and −1250, −201 and −116, and −115 and −37. We detected a tissue- and stage-specific factor complex (MSG-intermolt-specific complex: MIC) bound to the sequence elements around the −1350, −320, −180, and −70 regions. A mutation in the −70 region, which inhibits MIC-binding, diminished almost all promoter activity, while another mutation that did not inhibit MIC-binding showed no effect on promoter activity. The results suggest that the binding of MIC to the above elements is intrinsic for the spatiotemporal specificity of ser1 in vivo.     

Quantitative analysis of cytoplasmic actin gene promoter and nuclear polyhedrosis virus immediate-early promoter activities in various tissues of silkworm Bombyx mori using recombinant Autographa californica nuclear polyhedrosis virus as vector

Cassettes harboring luciferase reporter driven by Bombyx mori cytoplasmic actin gene promoter (A3) (671 bp) and B. mori nuclear polyhedrosis virus immediate-early promoter (IE-1) (580 bp) were transferred to the bacmid AcΔEGT to generate the recombinant Autographa californica nuclear polyhedrosis viruses, AcNPVA3Luc and AcNPVIELuc, respectively. Recombinant baculoviruses were injected into the hemocoele of newly ecdysed 5th instar larvae. The activities of the A3 and IE-1 promoters in various tissues were measured by luciferase activity assay and normalized by the copy number of recombinant virus. Results showed that the activity of the A3 promoter was approximately 10-fold higher than the IE-1 promoter. The promoter activities of A3 and IE-1 were highest in the silk gland, followed by fat body, middle gut, Malpighian tubule, and hemocyte. In silk gland, activity of the two promoters was highest in posterior silk gland, followed by middle and anterior silk glands. The difference in promoter activities reflects the growth speed of tissue in silkworm larvae. The activity of the A3 promoter remained unchanged and was not inhibited significantly by viral factors at least 3–4 d post injection of rAcNPV.     

Conservation of a pair of serpin 2 genes and their expression in Amphiesmenoptera

Silk secreted by the larvae of Hydropsyche angustipennis (Trichoptera) contains serpins HaSerp2A and HaSerp2B that are homologous to serpin 2 known from several lepidopterans and some other insects. The gene HaSerp2A is 2684 bp downstream from the HaSerp2B gene. The genes possess identical exon/intron segmentation (9 exons) and their sequences are nearly identical: only 8 out of 1203 nt differ in the coding region, 4 out of 567 nt in the introns and 2 out of 52 nt in 3' UTR. Both genes are highly expressed in the silk glands whereas expression in larval carcass devoid of the silk glands is hard to detect. Translation products of the genes consist of 401 amino acids, are 98.8% identical, and are secreted as 45 kDa proteins into silk. Homologous genes in similar tandem arrangement occur on chromosome 15 of Bombyx mori (Lepidoptera). The upstream gene BmSerp2B is modified in several exons and does not seem to produce functional mRNA. The gene BmSerp2A contains two copies of exon 9, of which only the second one is used. One kind of mRNA does and the other does not include exon 1, which encodes a signal peptide. The mRNA yielding secreted BmSerp2A is expressed in the posterior, and that encoding the cytoplasmic BmSerp2A in the middle silk gland region; both kinds are strongly expressed in the anterior region. The data indicate that (1) A duplication of serpin 2 gene occurred either before Trichoptera and Lepidoptera diverged as separate orders or independently in early phylogeny of either order; (2) In the caddisfly H. angustipennis, both genes are expressed specifically in the silk glands and generate proteins deposited in the silk; (3) Only one gene seems to be functional in B. mori and is expressed in a cytoplasmic and in a secreted forms in diverse organs, including the silk glands.