Follicle-Stimulating Hormone-Responsive Cytoskeletal Genes in Rat Granulosa Cells: Class I {beta}-Tubulin, Tropomyosin-4, and Kinesin Heavy Chain

doi:10.1210/en.2002-220477

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Follicle-Stimulating Hormone-Responsive Cytoskeletal Genes in Rat Granulosa Cells: Class I ß-Tubulin, Tropomyosin-4, and Kinesin Heavy Chain

Nicole A. Grieshaber, CheMyong Ko, Scott S. Grieshaber, Inhae Ji and Tae H. Ji

Department of Chemistry, University of Kentucky, Lexington, Kentucky 40506-0055

Address all correspondence and requests for reprints to: Dr. Tae H. Ji, Department of Chemistry, University of Kentucky, Lexington, Kentucky 40506-0055. E-mail: tji{at}uky.edu.

FSH regulates gene expression for granulosa cell differentiationand follicular development. Therefore, FSH-responsive genesare crucial, but only a few genes have been identified for theearly stage of follicular development. In particular, littleis known about cytoskeletal genes, which likely play essentialroles in the morphological changes such as the antrum formation,a major landmark. FSH is also known to induce the differentiationof an immature, undifferentiated rat ovary granulosa (ROG) cellline. Our data show that FSH induced massive yet distinct reorganizationof microtubules and the actin cytoskeletons as well as morphologicalchanges. To identify those genes responding to FSH during thedifferentiation, differential display was performed on ROG cells.Of the 80 FSH-responsive genes identified, there were threecytoskeleton-related genes (class I ß-tubulin, tropomyosin4, and kinesin heavy chain), which are crucial for intracellularmorphogenesis, transport, and differentiation. Northern blotsshow that the level of these gene transcripts reached a peakat 6 h after FSH treatment and subsided at 24 h. FSH inducedthe similar temporal expression not only in granulosa cellsisolated from immature rats, but also in vivo. For instance,in situ hybridization showed that ß-tubulin mRNA wastransiently expressed in the granulosa cells of large preantraland early antral follicles. Despite the same temporal expression,the regulatory mechanisms of the three genes were strikinglydifferent. As an example, cycloheximide blocked the ß-tubulinmRNA expression, whereas it increased tropomyosin-4 (TM4) mRNA.Yet, it did not impact kinesin heavy chain (Khc) mRNA. In conclusion,FSH induces the massive reorganization of the cytoskeletonsand morphological changes by the selective regulation of thegene expression, protein synthesis, and rearrangement of thecytoskeletal proteins in the ROG cells and probably, specificfollicles and granulosa cells.

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