1. Characterization of kinesin-like proteins in silkworm posterior silkgland cells
- Author
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Albert Cheung Hoi Yu, Yige Guo, Junlin Teng, Chuan-Xi Zhang, Jianguo Chen, Qiao Wang, Wei Zhang, Xiaolei Su, and Birong Shen
- Subjects
Cellular differentiation ,Silk ,Biological Transport, Active ,Kinesins ,Colocalization ,Cell Biology ,Biology ,Bombyx ,Cell biology ,Blot ,Exocrine Glands ,Microtubule ,Multigene Family ,Animals ,Humans ,Insect Proteins ,Kinesin ,Endomembrane system ,Transport Vesicles ,Molecular Biology ,Phylogeny ,Intracellular ,Ribonucleoprotein - Abstract
Kinesins are microtubule-based motors involved in various intracellular transports. Neurons, flagellated cells, and pigment cells have been traditionally used as model systems to study the cellular functions of kinesins. Here, we report silkworm posterior silkgland (PSG), specialized cells with an extensive endomembrane system for intracellular transport and efficient secretion of fibroin, as a novel model for kinesin study. To investigate kinesin-driven intracellular transport in PSG cells, we cloned five silkworm kinesin-like proteins (KLPs), BmKinesin-1, BmKinesin-6, BmKinesin-7, BmKinesin-13, and BmKinesin-14A. We determined their expression patterns by relative real-time PCR and western blotting. Immunofluorescence microscopy verified their colocalization with microtubules. By combining pull-down assays, LC-MS/MS, and western blotting analysis, we identified many potential cargoes of BmKinesin-1 in PSG, including fibroin-containing granules and exuperantia-associated ribonucleoprotein (RNP) complexes. Moreover, BmKinesin-13 overexpression disrupted the microtubule network in BmN cells, which is consistent with a role of Kinesin-13 in regulating microtubule dynamics in other organisms. On the basis of these results, we concluded that PSG might have advantages in elucidating mechanisms of intracellular transport in secretory tissues and could serve as a potential model for kinesin studies.
- Published
- 2010