PURPOSE: To deduce the function of the lens-specific cytoskeletal structure, the beaded filament, by blocking expression of the fiber cell-specific beaded filament protein CP49. METHODS: The first exon of the mouse CP49 gene was deleted by using targeted genomic deletion techniques. Gene deletion was assessed through Southern blot analysis and PCR. Translation and protein expression were characterized by Northern and Western blot analysis of both CP49 and its assembly partner filensin. The architecture of knockout lenses was compared with that of wild-type lenses at the histologic level by light microscopy. Lens clarity was assessed in situ by direct ophthalmic examination and slit lamp microscopy. RESULTS: Transcription and translation of CP49 were successfully negated in knockout animals. Lenses homozygous for the CP49 deletion showed no obvious changes in lens architecture at the light microscope level. Filensin levels were sharply reduced, although filensin mRNA levels appeared unchanged. Direct examination of lenses showed no obvious loss of lens clarity, but slit lamp examination revealed the emergence of opacification in even the youngest animals. The opacification worsened with age. CONCLUSIONS: The absence of CP49 causes a subtle loss of optical clarity in the ocular lens, a loss that worsens with age. However, CP49 is not essential for the assumption or maintenance of overall fiber cell shape or long-range order of fiber cells. CP49 appears to regulate the protein levels of its assembly partner filensin, suggesting a mechanism for the regulation of beaded filament protein stoichiometry.
PURPOSE: To deduce the function of the lens-specific cytoskeletal structure, the beaded filament, by blocking expression of the fiber cell-specific beaded filament protein CP49. METHODS: The first exon of the mouseCP49 gene was deleted by using targeted genomic deletion techniques. Gene deletion was assessed through Southern blot analysis and PCR. Translation and protein expression were characterized by Northern and Western blot analysis of both CP49 and its assembly partner filensin. The architecture of knockout lenses was compared with that of wild-type lenses at the histologic level by light microscopy. Lens clarity was assessed in situ by direct ophthalmic examination and slit lamp microscopy. RESULTS: Transcription and translation of CP49 were successfully negated in knockout animals. Lenses homozygous for the CP49 deletion showed no obvious changes in lens architecture at the light microscope level. Filensin levels were sharply reduced, although filensin mRNA levels appeared unchanged. Direct examination of lenses showed no obvious loss of lens clarity, but slit lamp examination revealed the emergence of opacification in even the youngest animals. The opacification worsened with age. CONCLUSIONS: The absence of CP49 causes a subtle loss of optical clarity in the ocular lens, a loss that worsens with age. However, CP49 is not essential for the assumption or maintenance of overall fiber cell shape or long-range order of fiber cells. CP49 appears to regulate the protein levels of its assembly partner filensin, suggesting a mechanism for the regulation of beaded filament protein stoichiometry.
Authors: Roberta B Nowak; Robert S Fischer; Rebecca K Zoltoski; Jerome R Kuszak; Velia M Fowler Journal: J Cell Biol Date: 2009-09-14 Impact factor: 10.539
Authors: Angus C Grey; Kerry L Walker; Rosica S Petrova; Jun Han; Phillip A Wilmarth; Larry L David; Paul J Donaldson; Kevin L Schey Journal: Exp Eye Res Date: 2013-01-08 Impact factor: 3.467