Telomere dysfunction is typically studied under conditions in which a component of the six-subunit shelterin complex that protects chromosome ends is disrupted. The nature of spontaneous telomere dysfunction is less well understood. Here we report that immortalized human cell lines lacking wild-type p53 function spontaneously show many telomeres with a DNA damage response (DDR), commonly affecting only one sister chromatid and not associated with increased chromosome end-joining. DDR(+) telomeres represent an intermediate configuration between the fully capped and uncapped (fusogenic) states. In telomerase activity-positive (TA(+)) cells, DDR is associated with low TA and short telomeres. In cells using the alternative lengthening of telomeres mechanism (ALT(+)), DDR is partly independent of telomere length, mostly affects leading strand-replicated telomeres, and can be partly suppressed by TRF2 overexpression. In ALT(+) (but not TA(+)) cells, DDR(+) telomeres preferentially associate with large foci of extrachromosomal telomeric DNA and recombination proteins. DDR(+) telomeres therefore arise through different mechanisms in TA(+) and ALT(+) cells and have different consequences.
Five dysfunctional telomeres predict onset of senescence in human cellsReplicative senescence is triggered by DNA damage response foci associated with telomeres. Reddel and colleagues now establish that a threshold of five damaged telomeres exists to induce senescence in normal cells and that end-to-end chromosome fusion is not required for senescence induction.
Mortalin/mthsp70 (HSPA9) is a stress chaperone enriched in many cancers that has been implicated in carcinogenesis by promoting cell proliferation and survival. In this study, we examined the clinical relevance of mortalin upregulation in carcinogenesis. Consistent with high mortalin expression in various human tumors and cell lines, we found that mortalin overexpression increased the migration and invasiveness of breast cancer cells. Expression analyses revealed that proteins involved in focal adhesion, PI3K-Akt, and JAK-STAT signaling, all known to play key roles in cell migration and epithelial-tomesenchymal transition (EMT), were upregulated in mortalinexpressing cancer cells. We further determined that expression levels of the mesenchymal markers vimentin (VIM), fibronectin (FN1), b-catenin (CTNNB1), CK14 (KRT14), and hnRNP-K were also increased upon mortalin overexpression, whereas the epithelial markers E-cadherin (CDH1), CK8 (KRT8), and CK18 (KRT18) were downregulated. Furthermore, shRNAmediated and pharmacologic inhibition of mortalin suppressed the migration and invasive capacity of cancer cells and was associated with a diminished EMT gene signature. Taken together, these findings support a role for mortalin in the induction of EMT, prompting further investigation of its therapeutic value in metastatic disease models. Cancer Res; 76(9);
Background: Mortalin/mtHsp70 is an essential stress chaperone frequently enriched in cancers. Results: Mortalin is present in the nucleus of cancer cells where it causes strong inactivation of tumor suppressor protein p53 and activation of telomerase and heterogeneous ribonucleoprotein K (hnRNP-K) proteins. Conclusion: Nuclear mortalin promotes carcinogenesis. Significance: This study is important for the development of mortalin-based anticancer treatments.
Mortalin/mtHsp70 (mitochondrial Hsp70) and HSP60 (heat-shock protein 60) are heat-shock proteins that reside in multiple subcellular compartments, with mitochondria being the predominant one. In the present study, we demonstrate that the two proteins interact both in vivo and in vitro, and that the N-terminal region of mortalin is involved in these interactions. Suppression of HSP60 expression by shRNA (short hairpin RNA) plasmids caused the growth arrest of cancer cells similar to that obtained by suppression of mortalin expression by ribozymes. An overexpression of mortalin, but not of HSP60, extended the in vitro lifespan of normal fibroblasts (TIG-1). Taken together, this study for the first time delineates: (i) molecular interactions of HSP60 with mortalin; (ii) their co- and exclusive localizations in vivo; (iii) their involvement in tumorigenesis; and (iv) their functional distinction in pathways involved in senescence.
Quantum dots are the nanoparticles that are recently emerging as an alternative to organic fluorescence probes in cell biology and biomedicine, and have several predictive advantages. These include their i) broad absorption spectra allowing visualization with single light source, ii) exceptional photo-stability allowing long term studies and iii) narrow and symmetrical emission spectrum that is controlled by their size and material composition. These unique properties allow simultaneous excitation of different size of quantum dots with a single excitation light source, their simultaneous resolution and visualization as different colors. At present there are only a few studies that have tested quantum dots in cellular imaging. We describe here the use of quantum dots in mortalin imaging of normal and cancer cells. Mortalin staining pattern with quantum dots in both normal and cancer cells mimicked those obtained with organic florescence probes and were considerably stable.
The tumor suppressor protein, p53, is central to the pathways that monitor the stress, DNA damage repair, cell cycle, aging, and cancer. Highly complex p53 networks involving its upstream sensors and regulators, downstream effectors and regulatory feedback loops have been identified. CARF (Collaborator of ARF) was shown to enhance ARF-dependent and -independent wild-type p53 function. Here we report that (i) CARF overexpression causes premature senescence of human fibroblasts, (ii) it is vital for replicative and stress-induced senescence, and (iii) the lack of CARF function causes aneuploidy and apoptosis. We provide evidence that CARF plays a dual role in regulating p53-mediated senescence and apoptosis, the two major tumor suppressor mechanisms.The tumor suppressor protein, p53, is the most frequently inactivated protein in human cancers that symbolizes deregulation of genomic stability, cell cycle, senescence, and stress damage-repair response of cells (1-5). p53 signaling has been established as a complex network comprised of (i) upstream components consisting of stress signals and sensor proteins including kinases, transferases, methyalses, ligases, and others that regulate its activity either by post-translational modifications or by subcellular localization, (ii) core regulators including an upstream positive regulator (alternative reading frame, ARF) 4 protein that blocks its downstream effector and antagonist human double minute-2 (HDM2) protein, and (iii) the downstream effectors that determine the fate of cells by instigation of growth arrest, senescence, or apoptosis, the three potent tumor suppressor mechanisms. In addition to the fact that the initiation of DNA damage-induced senescence and establishment of growth arrest require p53 activation (4), a large number of studies have shown that the persistent inactivation of p53 is required for tumor maintenance. Cancer cells undergo either growth arrest or apoptosis with restoration of wild-type p53 function in vitro and in vivo (6 -8). These studies have prioritized further understanding of p53 signaling and regulation that would have major impact in cancer drug development.It is yet to be resolved how functional restoration of p53 culminates to growth arrest/senescence in some cells and apoptosis in others. Is it driven by the level of p53 expression, modulating partner proteins or its upstream regulators? Among the large number of p53-binding proteins that influence its activities, ARF and HDM2 have been demonstrated as its major regulators. HDM2 (an E3 ubiquitin ligase) is transcriptionally activated by p53 and acts to degrade p53 in turn; thus, executing a negative feedback loop on p53 activity. ARF has been shown to bind and inhibit HDM2 activity resulting in the activation of p53 pathway (9). CARF (Collaborator of ARF) protein was initially cloned as an ARF-binding protein by yeast two-hybrid screening and was shown to activate ARF-dependent and -independent p53 functions (10 -13). CARF interacts not only with ARF but also with p53 and HDM2, an...
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