Holger Bastians scite author profile

Chromosomal instability (CIN) is defined as the perpetual missegregation of whole chromosomes during mitosis and represents a hallmark of human cancer. However, the mechanisms causing CIN and its consequences on tumor growth are largely unknown. We identify an increase in microtubule plus end assembly rates as a fundamental trigger for CIN in CRC cells. This trigger is mediated by overexpression of the oncogene AURKA or by loss of the tumor suppressor gene CHK2, a genetic constitution found in 73% of human colorectal cancers. Increased microtubule assembly rates are associated with transient abnormalities in mitotic spindle geometry promoting the generation of lagging chromosomes and resulting in CIN. Reconstitution of proper microtubule assembly rates by chemical or genetic means suppresses CIN and thereby, unexpectedly, accelerates tumor growth in vitro and in vivo. Thus, we identify a fundamental mechanism triggering CIN in cancer cells and reveal its adverse consequence on tumor growth.

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The CHK2–BRCA1 tumour suppressor pathway ensures chromosomal stability in human somatic cells

Stolz

et al. 2010

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Chromosomal instability (CIN) is a major hallmark of human cancer and might contribute to tumorigenesis. Genes required for the normal progression of mitosis represent potential CIN genes and, as such, are important tumour suppressors. The Chk2 kinase and its downstream targets p53 and Brca1 are tumour suppressors that have been functionally linked to the DNA damage response pathway. Here, we report a function of Chk2, independent of p53 and DNA damage, that is required for proper progression of mitosis, and for the maintenance of chromosomal stability in human somatic cells. Depletion of Chk2 or abrogation of its kinase activity causes abnormal mitotic spindle assembly associated with a delay in mitosis, which promotes the generation of lagging chromosomes, chromosome missegregation and CIN, while still allowing survival and growth. Furthermore, we have identified Brca1 as a mitotic target of the Chk2 kinase in the absence of DNA damage. Accordingly, loss of BRCA1 or its Chk2-mediated phosphorylation leads to spindle formation defects and CIN. Thus, the CHK2-BRCA1 tumour suppressor pathway is required for chromosomal stability, which might contribute to their tumour suppressor function.

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Mitotic drug targets and the development of novel anti-mitotic anticancer drugs

Schmidt

Bastians

2007

Drug Resistance Updates

176

158

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Crosstalk of the mitotic spindle assembly checkpoint with p53 to prevent polyploidy

et al. 2004

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Treatment of cells with microtubule inhibitors results in activation of the mitotic spindle assembly checkpoint, leading to mitotic arrest before anaphase. Upon prolonged treatment, however, cells can adapt and exit mitosis aberrantly, resulting in the occurrence of tetraploid cells in G1. Those cells subsequently arrest in postmitotic G1 due to the activation of a p53-dependent G1 checkpoint. Failure of the G1 checkpoint leads to endoreduplication and further polyploidization. Using HCT116 and isogenic p53-deficient or spindle checkpoint compromised derivatives, we show here that not only p53 but also a functional spindle assembly checkpoint is required for postmitotic G1 checkpoint function. During transient mitotic arrest, p53 stabilization and activation is triggered by a pathway independent of ATM/ATR, Chk1 and Chk2. We further show that a prolonged spindle checkpoint-mediated mitotic arrest is required for proper postmitotic G1 checkpoint function. In addition, we demonstrate that polyploid cells are inhibited to re-enter mitosis by an additional checkpoint acting in G2. Thus, during a normal cell cycle, polyploidization and subsequent aneuploidization is prevented by the function of the mitotic spindle checkpoint, a p53-dependent G1 checkpoint and an additional G2 checkpoint.

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Yeast Shuttling SR Proteins Npl3p, Gbp2p, and Hrb1p Are Part of the Translating mRNPs, and Npl3p Can Function as a Translational Repressor

Windgassen

Sturm

Cajigas

et al. 2004

Molecular and Cellular Biology

102

124

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A major challenge in current molecular biology is to understand how sequential steps in gene expression are coupled. Recently, much attention has been focused on the linkage of transcription, processing, and mRNA export. Here we describe the cytoplasmic rearrangement for shuttling mRNA binding proteins in Saccharomyces cerevisiae during translation. While the bulk of Hrp1p, Nab2p, or Mex67p is not associated with polysome containing mRNAs, significant amounts of the serine/arginine (SR)-type shuttling mRNA binding proteins Npl3p, Gbp2p, and Hrb1p remain associated with the mRNA-protein complex during translation. Interestingly, a prolonged association of Npl3p with polysome containing mRNAs results in translational defects, indicating that Npl3p can function as a negative translational regulator. Consistent with this idea, a mutation in NPL3 that slows down translation suppresses growth defects caused by the presence of translation inhibitors or a mutation in eIF5A. Moreover, using sucrose density gradient analysis, we provide evidence that the import receptor Mtr10p, but not the SR protein kinase Sky1p, is involved in the timely regulated release of Npl3p from polysomeassociated mRNAs. Together, these data shed light onto the transformation of an exporting to a translating mRNP.

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Holger Bastians

Increased microtubule assembly rates influence chromosomal instability in colorectal cancer cells

The CHK2–BRCA1 tumour suppressor pathway ensures chromosomal stability in human somatic cells

Mitotic drug targets and the development of novel anti-mitotic anticancer drugs

Crosstalk of the mitotic spindle assembly checkpoint with p53 to prevent polyploidy

Yeast Shuttling SR Proteins Npl3p, Gbp2p, and Hrb1p Are Part of the Translating mRNPs, and Npl3p Can Function as a Translational Repressor

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