A Network of 17 Microtubule-Related Genes Highlights Functional Deregulations in Breast Cancer.

A wide panel of microtubule-associated proteins and kinases is involved in coordinated regulation of the microtubule cytoskeleton and may thus represent valuable molecular markers contributing to major cellular pathways deregulated in cancer. We previously identified a panel of 17 microtubule-related (MT-Rel) genes that are differentially expressed in breast tumors showing resistance to taxane-based chemotherapy. In the present study, we evaluated the expression, prognostic value and functional impact of these genes in breast cancer. We show that 14 MT-Rel genes (KIF4A, ASPM, KIF20A, KIF14, TPX2, KIF18B, KIFC1, AURKB, KIF2C, GTSE1, KIF15, KIF11, RACGAP1, STMN1) are up-regulated in breast tumors compared with adjacent normal tissue. Six of them (KIF4A, ASPM, KIF20A, KIF14, TPX2, KIF18B) are overexpressed by more than 10-fold in tumor samples and four of them (KIF11, AURKB, TPX2 and KIFC1) are essential for cell survival. Overexpression of all 14 genes, and underexpression of 3 other MT-Rel genes (MAST4, MAPT and MTUS1) are associated with poor breast cancer patient survival. A Systems Biology approach highlighted three major functional networks connecting the 17 MT-Rel genes and their partners, which are centered on spindle assembly, chromosome segregation and cytokinesis. Our studies identified mitotic Aurora kinases and their substrates as major targets for therapeutic approaches against breast cancer.

[Mitochondrial transport: How does it impact cancer?] / Le transport mitochondrial - Quel impact dans le cancer ?

Cancer cells are characterized by a deregulation of their metabolic activity, which allows them to meet a high energy demand. Mitochondria are key organelles that control several metabolic processes and represent the main source of energy in the form of ATP. Intracellular transport of mitochondria is essential for addressing these organelles to the right place at the right time according to energy requirement. Mitochondrial transport in cancer cells involves mitochondria-associated Miro/TRAK complexes that bind to motor proteins (kinesins, dyneins and myosins) to promote mitochondrial displacement along microtubules or actin filaments. This review focuses on the molecular players of intracellular mitochondrial transport along microtubules during cell migration and mitosis, and their deregulation in tissues from cancer patients. Intercellular mitochondrial transport upon cancer cell exposure to hypoxia or chemotherapy is also presented. This field of investigation opens new interesting perspectives in oncology, as targeting mitochondrial transport may represent an innovative strategy for treating cancer.

Title: Le transport mitochondrial - Quel impact dans le cancer ? Abstract: La reprogrammation métabolique est l'un des marqueurs de la carcinogenèse. Au cœur de cette reprogrammation se trouvent les mitochondries qui produisent l'énergie sous forme de molécules d'ATP. La régulation spatio-temporelle de la production d'ATP, indispensable pour fournir l'énergie au bon endroit et au bon moment, est assurée par le transport intracellulaire des mitochondries. Les complexes Miro/TRAK présents à la surface des mitochondries se lient aux protéines motrices de la cellule (dynéine, kinésine, myosine) pour transporter les mitochondries le long du cytosquelette. Ces acteurs du transport mitochondrial sont souvent dérégulés dans le cancer. Nous présentons dans cette revue les mécanismes par lesquels le transport mitochondrial contribue à la migration, à la division cellulaire et à la réponse au stress des cellules cancéreuses. Décrypter ces mécanismes pourrait ouvrir la voie à de nouvelles approches thérapeutiques en oncologie.