Project description:Spider silk proteins are synthesized in the silk-producing glands, where the spidroins are produced, stored and processed into a solid fiber from a crystalline liquid solution. Despite great interest in the spider silk properties, that make this material suitable for biomedical and biotechnological applications, the mechanism of formation and spinning of the silk fibers has not been fully elucidated; and no combination of proteomic and transcriptomic study has been carried out so far in the spider silk-producing glands. Nephila clavipes is an attractive orb-web spider to investigate the spinning process of silk production, given the properties of strength, elasticity and biocompatibility of their silk fibers. Thus, considering that the combination of proteomic and transcriptomic analysis may reveal an extensive repertoire of novel proteins involved in the silk spinning process, and in order to facilitate and enable proteomics in this non-model organism, the current study aims to construct a high quality reference mRNA-derived protein database that could be used to identify tissue specific expression patterns in spider silk glands. Next-generation sequencing has offered a powerful and cost-efficient technique for the generation of transcriptomic datasets in non-model species using diverse platforms such as the Illumina HiSeq, Roche 454, Pacific Biosystems, and Applied Biosystems SOLiD; In the current study, the Illumina HiSeq 2000 platform will be used to generate a N. clavipes spider silk glands transcriptome-based protein database. The transcriptome data generated in this study will provide a comprehensive and valuable genomic resource for future research of the group of spider silk-producing glands, in order to improve our understanding of the overall mechanism of action involved in production, secretion, storage, transport, protection and conformational changes of spidroins during the spinning process, and prey capture; and the results may be relevant for scientists in material Science, biology, biochemistry, and environmental scientists.

Project description:Spinneret, which locates at the end of the silk gland, is an important tissue for silk spinning. Although it has been discovered for hundreds of years, its particular roles in silk spinning and fiber formation are still unclear. Here we report the first proteome profile of silkworm spinnerets by LC-MS/MS. Totally, 1572 non-redundant proteins and 232 differential expressed proteins were identified in the spinneret from the spinning larvae and the third day of fifth instar larvae. Silk fiber formation related proteins, such as cuticle proteins, ion-transporting proteins, muscular proteins, and energy metabolic proteins, were abundant in the spinneret. By analyzing the signal pathways, we discovered that the processes associated with energy metabolism were active in spinneret. GO enrichment analysis revealed that the differential expressed proteins were involved in energy metabolism, chitin binding, and cuticle construction. The active energy metabolism might provide abundant energy for the muscle contraction, ion and water transporting. The chitin binding and cuticle construction process might provide sufficient shear forces for silk formation. This dataset suggests that the spinneret provided a suitable physiological and biochemical environment for silk formation, and will be helpful for elucidating the functions of spinneret.

Project description:Proteotranscriptomic view on the role of spider silk glands during the silk spinning process

Project description:DNA barcoding of plants in Hiroshima Prefecture, Japan

Project description:Background: The growth and development of the posterior silk gland and the biosynthesis of the silk core protein at the fifth larval instar stage of Bombyx mori are of paramount importance for silk production. Results: Here, aided by next-generation sequencing and microarry assay, we profile 1,229 microRNAs (miRNAs), including 728 novel miRNAs and 110 miRNA/miRNA* duplexes, from the posterior silk gland at the fifth larval instar. Target gene prediction yields 14,222 unique target genes from 1,195 miRNAs. Functional categorization classifies the genes into complex pathways that include both cellular and metabolic processes, especially protein synthesis and processing. Conclusion: The enrichment of target genes in the ribosome-related pathway indicates that miRNAs may directly regulate translation. Our findings pave a way for further functional elucidation of these miRNAs in silk production. Sequencing 10 total RNA samples from the posterior silk gland of different strains and developmental stage using Illumina Solexa technology. Four strains of silkworm (Q, B, QB and BQ) with different two development stages (stage 1: fourth instar molting to day 2 of fifth instar; stage 2: fifth instar day 3 to day 8 before spinning, according to our previous genes expression cluster analysis), and two strains (R1 and J1) from entire period (stage 1 + stage 2).

Project description:The anterior silk gland in the silkworm plays an important role in the process of liquid fibroin to solid silk fiber .In view of this,the proteomics analysis was applied to to study the relationship between the function of proteins in the anterior silk gland and the mechanism of spinning. The anterior silk glands on the 3rd day of fifth instar were dissected.Aftter 1D SDS-PAGE ,one gel lane was cut into 10 bands and each band further sliced into small pieces was subjected to in-gel tryptic digestion for 20 hours.The digested peptides were separated by RP nanoscale capillary liquid chromatography and analyzed using a surveyor LC system (Thermo Figgigan, San Jose, CA).The eluate from the RP column was analyzed by Finnigan LTQ(Thermo Electron Corporation）linear ion trap Mass equipped with a nanospray souce in the positive ion mode. The MS analysis was performed with one full MS scan followed by three MS/MS scans on the most intense ions from the MS spectrum with the dynamic exclusion settings: repeat count 2, repeat duration 30s, exclusion duration 90s. Data were acquired in data-dependent mode using Xcalibur software.Ten raw datasets from LC-MS/MS were searched against the predicted silkworm database by Xia.et al which consists of 21312 silkworm proteins.The searching was carried out with the Turbo SEQUEST(Bioworks version 3.2, Thermo Electron).

Project description:Amongst the various different insect groups, there is remarkable diversity in the number and size of wings. However the development of the basic body plan in insects is similar to a large extent. The genes of the hox complex regulate various pathways to bring about the development or modification of different organs. Ubx, a gene of the bithorax hox complex is expressed in the third thoracic segment of insects and is known to specify the fate of wing appendage in that segment.To understand the role of Ubx and how its regulatory mechanism has evolved through the course of evolution we have compared its genome wide targets in different insect orders. The identification of regulatory pathways and the key players Ubx regulates is crucial to understand how it has controlled wing development across insect orders. Our lab has previously identified direct targets of Ubx in Drosophila using ChIP-chip (Agrawal et al, 2011). To further our knowledge on the role of regulation in development and modification of hind wing appendage we have studied the targets in the hind wings of other insects (silk moth; Lepidoptera and honeybee; Hymenoptera) and performed a comparative analysis. We have employed ChIP followed by illumina sequencing to identify the targets of Ubx in developing hind and fore wing buds of Bombyx larvae. This is a first next generation sequencing study in Lepidoptera in an attempt to understand wing development.

Project description:Phytoplasma DNA barcoding

Project description:Background: The growth and development of the posterior silk gland and the biosynthesis of the silk core protein at the fifth larval instar stage of Bombyx mori are of paramount importance for silk production. Results: Here, aided by next-generation sequencing and microarry assay, we profile 1,229 microRNAs (miRNAs), including 728 novel miRNAs and 110 miRNA/miRNA* duplexes, from the posterior silk gland at the fifth larval instar. Target gene prediction yields 14,222 unique target genes from 1,195 miRNAs. Functional categorization classifies the genes into complex pathways that include both cellular and metabolic processes, especially protein synthesis and processing. Conclusion: The enrichment of target genes in the ribosome-related pathway indicates that miRNAs may directly regulate translation. Our findings pave a way for further functional elucidation of these miRNAs in silk production.

Project description:cocoon-spinning insect