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Functional Analysis of the Putative BUB2 Homologues of C. elegans in the Spindle Position Checkpoint  

Lee, Kyung-Hee (Department of Biochemistry, and Institute of Life Science and Biotechnology, College of Sciences, Yonsei University)
Song, Ki-Won (Department of Biochemistry, and Institute of Life Science and Biotechnology, College of Sciences, Yonsei University)
Publication Information
Animal cells and systems / v.9, no.2, 2005 , pp. 87-94 More about this Journal
Abstract
Spindle position checkpoint monitors the orientation of mitotic spindle for proper segregation of replicated chromosomes into mother cell and the daughter, and prohibits mitotic exit when mitotic spindle is misaligned. BUB2 forms one of the key upstream element of spindle position checkpoint in budding yeast, but its functional homologues have not been identified in higher eukaryotes. Here, we analyzed the functions of two putative BUB2 homologues of C. elegans in the spindle orientation checkpoint. From the C. elegans genome database, we found that two open reading frames (ORFs), F35H12_2 and C33F10_2, showed high sequence homology with BUB2. We obtained the expressed sequence tag (EST) clones for F35H12_2 (yk221d4) and C33F10_2 (yk14e10) and verified the full cDNA for each ORF by sequencing and 5' RACE with SL1 primer. The functional complementation assays of yk221d4 and yk14e10 in ${\Delta}bub2$ of S. cerevisiae revealed that these putative BUB2 homologues of C. elegans could not replace the function of BUB2 in spindle position checkpoint and mitotic exit. Our attempt to document the component of spindle position checkpoint in metazoans using sequence homology was not successful. This suggests that structural information about its components might be required to identify functional homologues of the spindle position checkpoint in higher eukaryotes.
Keywords
BUB2; S. cerevisiae; C. elegans; F35H12_2; C33F10_2; spindle position checkpoint; mitotic exit network; human GAPCenA;
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