Matricellular protein SPARC is translocated to the nuclei of immortalized murine lens epithelial cells

Q Yan, M Weaver, N Perdue… - Journal of cellular …, 2005 - Wiley Online Library
Q Yan, M Weaver, N Perdue, EH Sage
Journal of cellular physiology, 2005Wiley Online Library
The matricellular glycoprotein, secreted protein acidic and rich in cysteine (SPARC), has
complex biological activities and is important for lens epithelial cell function and regulation
of cataract formation. To understand how SPARC influences lens epithelial cell activity and
homeostasis, we have studied the subcellular distribution of SPARC in murine lens
epithelial cells in vitro. We demonstrate that endogenous SPARC is located in the cytoplasm
of either quiescent or dividing lens epithelial cells in culture. However, cytoplasmic SPARC …
Abstract
The matricellular glycoprotein, secreted protein acidic and rich in cysteine (SPARC), has complex biological activities and is important for lens epithelial cell function and regulation of cataract formation. To understand how SPARC influences lens epithelial cell activity and homeostasis, we have studied the subcellular distribution of SPARC in murine lens epithelial cells in vitro. We demonstrate that endogenous SPARC is located in the cytoplasm of either quiescent or dividing lens epithelial cells in culture. However, cytoplasmic SPARC was translocated into the nuclei of immortalized lens epithelial cells upon a significant reduction of intracellular SPARC in these cells. Recombinant human (rh) SPARC added to the culture media was quickly and efficiently internalized into the cytosol of SPARC‐null lens epithelial cells. Moreover, cytoplasmic rhSPARC was also translocated into the nucleus after exogenous rhSPARC was removed from the culture media. The translocation of SPARC into the nucleus was therefore triggered by the reduction of SPARC protein normally available to the cells. A mouse SPARC–EGFP chimeric fusion protein (70 kDa) was expressed in lens epithelial cells and 293‐EBNA cells, and was observed both in the cytoplasm and culture medium, but not in the nucleus. SPARC does not appear to have a strong nuclear localization sequence. Alternatively, SPARC might pass through the nuclear pore complex by passive diffusion. SPARC therefore functions not only as an extracellular protein but also potentially as an intracellular protein to influence cellular activities and homeostasis. © 2004 Wiley‐Liss, Inc.
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