Characterization of MAD2B and other mitotic spindle checkpoint genes
DP Cahill, LT Da Costa, EB Carson-Walter, KW Kinzler… - Genomics, 1999 - Elsevier
Genomics, 1999•Elsevier
Aneuploidy is a characteristic of the majority of human cancers, and recent work has
suggested that mitotic checkpoint defects play a role in its development. To further explore
this issue, we isolated a novel human gene, MAD2B (MAD2L2), which is homologous to the
spindle checkpoint gene MAD2 (MAD2L1). We determined the chromosomal localization of
it and other spindle checkpoint genes, including MAD1L1, MAD2, BUB3, TTK (MPS1L1),
and CDC20. In addition, we resolved the genomic intron–exon structure of the human BUB1 …
suggested that mitotic checkpoint defects play a role in its development. To further explore
this issue, we isolated a novel human gene, MAD2B (MAD2L2), which is homologous to the
spindle checkpoint gene MAD2 (MAD2L1). We determined the chromosomal localization of
it and other spindle checkpoint genes, including MAD1L1, MAD2, BUB3, TTK (MPS1L1),
and CDC20. In addition, we resolved the genomic intron–exon structure of the human BUB1 …
Aneuploidy is a characteristic of the majority of human cancers, and recent work has suggested that mitotic checkpoint defects play a role in its development. To further explore this issue, we isolated a novel human gene, MAD2B (MAD2L2), which is homologous to the spindle checkpoint gene MAD2 (MAD2L1). We determined the chromosomal localization of it and other spindle checkpoint genes, including MAD1L1, MAD2, BUB3, TTK (MPS1L1), and CDC20. In addition, we resolved the genomic intron–exon structure of the human BUB1 gene. We then searched for mutations in these genes in a panel of 19 aneuploid colorectal tumors. No new mutations were identified, suggesting that genes yet to be discovered are responsible for most of the checkpoint defects observed in aneuploid cancers.
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