Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts:   Target Concepts:
Query: EC:2.7.10.2 (focal adhesion kinase)
 44,029 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Abnormal numbers, structures and functions of centrosomes in chronic myeloid leukaemia (CML) may influence cell proliferation and genomic instability, which are features of the disease. Centrosomes are regulators of mitotic spindle orientation and can act as scaffolds for centrosome-associated regulators of the cell cycle. This study showed, for the first time, that p210(BCR-ABL1) and p145(ABL1) are both centrosome-associated proteins, as demonstrated by co-immunoprecipitation with the pericentriolar protein, pericentrin. Furthermore, when CML cells were treated with imatinib there was a 55% and 20% reduction of p210(BCR-ABL1) and p145(ABL1) binding to pericentrin, respectively. Cell lines expressing p210(BCR-ABL1) and primary CD34(+) cells from CML patients exhibited more numerical and structural centrosomal abnormalities than p210(BCR-ABL1) negative cells. Primary cells from CML blast crisis (BC) patients exhibited a distinctive amorphous staining pattern of pericentrin compared to normal and CML chronic phase (CP) patients, suggesting a possible defect in pericentrin localisation at the centrosomes. Proteins, such as aurora kinases, pericentrin, survivin and separase, regulate centrosome structure and function, cell cycle and mitotic spindle formation. Levels of the protease, separase are abnormally high in CML CP and BC cells in comparison to normal CD34(+) cells. The data imply that expression of p210(BCR-ABL1) is associated with abnormalities in the centrosome-centriole cycle and increased separase expression.
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PMID:Abnormal centrosome-centriole cycle in chronic myeloid leukaemia? 1956 13

Separase, an endopeptidase required for the separation of sister-chromatides in mitotic anaphase, triggers centriole disengagement during centrosome duplication. In cancer, separase is frequently overexpressed, pointing to a functional role as an aneuploidy promoter associated with centrosomal amplification and genomic instability. Recently, we have shown that centrosomal amplification and subsequent chromosomal aberrations are a hallmark of chronic myeloid leukemia (CML), increasing from chronic phase (CP) toward blast crisis (BC). Moreover, a functional linkage of p210BCR-ABL tyrosine kinase activity with centrosomal amplification and clonal evolution has been established in long-term cell culture experiments. Unexpectedly, therapeutic doses of imatinib (IM) did not counteract; instead induced similar centrosomal alterations in vitro. We investigated the influence of IM and p210BCR-ABL on Separase as a potential driver of centrosomal amplification in CML. Short-term cell cultures of p210BCR-ABL-negative (NHDF, UROtsa, HL-60, U937), positive (K562, LAMA-84) and inducible (U937p210BCR-ABL/c6 (Tet-ON)) human cell lines were treated with therapeutic doses of IM and analyzed by qRT-PCR, Western blot analysis and quantitative Separase activity assays. Decreased Separase protein levels were observed in all cells treated with IM in a dose dependent manner. Accordingly, in all p210BCR-ABL-negative cell lines, decreased proteolytic activity of Separase was found. In contrast, p210BCR-ABL-positive cells showed increased Separase proteolytic activity. This activation of Separase was consistent with changes in the expression levels of Separase regulators (Separase phosphorylation at serine residue 1126, Securin, CyclinB1 and PP2A). Our data suggest that regulation of Separase in IM-treated BCR-ABL-positive cells occurs on both the protein expression and the proteolytic activity levels. Activation of Separase proteolytic activity exclusively in p210BCR-ABL-positive cells during IM treatment may act as a driving force for centrosomal amplification, contributing to genomic instability, clonal evolution and resistance in CML.
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PMID:The proteolytic activity of separase in BCR-ABL-positive cells is increased by imatinib. 2287 Mar 41

Human securin, also known as human pituitary tumor-transforming gene 1 (pttg1), plays a key role in cell-cycle regulation. Two homologous genes, pttg2 and pttg3, have been identified although very little is known about their physiological function. In this study, we aimed at the characterization of these two pttg1 homologs. Real-time PCR analysis using specific probes demonstrated that Pttg2 is expressed at very low levels in various cell lines and tissues whereas Pttg3 was largely undetectable. We focused on the study of Pttg2 and found that, unlike PTTG1, PTTG2 lacks transactivation activity and does not bind to separase, making improbable a role in the control of sister chromatids separation. To further investigate the biological role of pttg2, we used short hairpin RNA inhibition of Pttg2 and found that cells with reduced Pttg2 levels assumed a rounded morphology compatible with a defect in cell adhesion and died by apoptosis in a p53- and p21-dependent manner. Using microarray technology, we generated a gene expression profile of Pttg2-depleted cells versus wild-type cells and found that knockdown of PTTG2 results in concomitant downregulation of E-cadherin and elevated vimentin levels, consistent with EMT induction. The observation of aberrant cellular behaviors in Pttg2-silenced cells reveals functions for pttg2 in cell adhesion and provides insights into a potential role in cell invasion.
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PMID:PTTG2 silencing results in induction of epithelial-to-mesenchymal transition and apoptosis. 2347 May 37