Different telomere damage signaling pathways in human and mouse cells

Programmed telomere shortening in human somatic cells is thought to act as a tumor suppressor pathway, limiting the replicative potential of developing tumor cells. Critically short human telomeres induce senescence either by activating p53 or by inducing the p16/RB pathway, and suppression of both pathways is required to suppress senescence of aged human cells. Here we report that removal of TRF2 from human telomeres and the ensuing de-protection of chromosome ends induced immediate premature senescence. Although the telomeric tracts remained intact, the TRF2(DeltaBDeltaM)-induced premature senescence was indistinguishable from replicative senescence and could be mediated by either the p53 or the p16/RB pathway. Telomere de-protection also induced a growth arrest and senescent morphology in mouse cells. However, in this setting the loss of p53 function was sufficient to completely abrogate the arrest, indicating that the p16/RB response to telomere dysfunction is not active in mouse cells. These findings reveal a fundamental difference in telomere damage signaling in human and mouse cells that bears on the use of mouse models for the telomere tumor suppressor pathway.     

Adult mesenchymal stem cell ageing interplays with depressed mitochondrial Ndufs6

Mesenchymal stem cell (MSC)-based therapy has emerged as a novel strategy to treat many degenerative diseases. Accumulating evidence shows that the function of MSCs declines with age, thus limiting their regenerative capacity. Nonetheless, the underlying mechanisms that control MSC ageing are not well understood. We show that compared with bone marrow-MSCs (BM-MSCs) isolated from young and aged samples, NADH dehydrogenase (ubiquinone) iron-sulfur protein 6 (Ndufs6) is depressed in aged MSCs. Similar to that of Ndufs6 knockout (Ndufs6^−/−) mice, MSCs exhibited a reduced self-renewal and differentiation capacity with a tendency to senescence in the presence of an increased p53/p21 level. Downregulation of Ndufs6 by siRNA also accelerated progression of wild-type BM-MSCs to an aged state. In contrast, replenishment of Ndufs6 in Ndufs6^−/−-BM-MSCs significantly rejuvenated senescent cells and restored their proliferative ability. Compared with BM-MSCs, Ndufs6^−/−-BM-MSCs displayed increased intracellular and mitochondrial reactive oxygen species (ROS), and decreased mitochondrial membrane potential. Treatment of Ndufs6^−/−-BM-MSCs with mitochondrial ROS inhibitor Mito-TEMPO notably reversed the cellular senescence and reduced the increased p53/p21 level. We provide direct evidence that impairment of mitochondrial Ndufs6 is a putative accelerator of adult stem cell ageing that is associated with excessive ROS accumulation and upregulation of p53/p21. It also indicates that manipulation of mitochondrial function is critical and can effectively protect adult stem cells against senescence.Subject terms: Ageing, Stem-cell research     

Involvement of p53 and p21 in Cellular Defects and Tumorigenesis in Atm−/− Mice

Disruption of the mouse Atm gene, whose human counterpart is consistently mutated in ataxia-telangiectasia (A-T) patients, creates an A-T mouse model exhibiting most of the A-T-related systematic and cellular defects. While ATM plays a major role in signaling the p53 response to DNA strand break damage, Atm^−/− p53^−/− mice develop lymphomas earlier than Atm^−/− or p53^−/− mice, indicating that mutations in these two genes lead to synergy in tumorigenesis. The cell cycle G₁/S checkpoint is abolished in Atm^−/− p53^−/− mouse embryonic fibroblasts (MEFs) following γ-irradiation, suggesting that the partial G₁ cell cycle arrest in Atm^−/− cells following γ-irradiation is due to the residual p53 response in these cells. In addition, the Atm^−/− p21^−/− MEFs are more severely defective in their cell cycle G₁ arrest following γ-irradiation than Atm^−/− and p21^−/− MEFs. The Atm^−/− MEFs exhibit multiple cellular proliferative defects in culture, and an increased constitutive level of p21 in these cells might account for these cellular proliferation defects. Consistent with this notion, Atm^−/− p21^−/− MEFs proliferate similarly to wild-type MEFs and exhibit no premature senescence. These cellular proliferative defects are also rescued in Atm^−/− p53^−/− MEFs and little p21 can be detected in these cells, indicating that the abnormal p21 protein level in Atm^−/− cells is also p53 dependent and leads to the cellular proliferative defects in these cells. However, the p21 mRNA level in Atm^−/− MEFs is lower than that in Atm^+/+ MEFs, suggesting that the higher level of constitutive p21 protein in Atm^−/− MEFs is likely due to increased stability of the p21 protein.     

Cellular senescence and organismal ageing in the absence of p21CIP1/WAF1 in ku80−/− mice

Ku80 is important in the repair of DNA double-strand breaks by its essential function in non-homologous end-joining. The absence of Ku80 causes the accumulation of DNA damage and leads to premature ageing in mice. We showed that mouse embryonic fibroblasts (MEFs) from ku80^−/− mice senesced rapidly with elevated levels of p53 and p21. Deletion of p21 delayed the early senescence phenotype in ku80^−/− MEFs, despite an otherwise intact response of p53. In contrast to ku80^−/−p53^−/− mice, which die rapidly primarily from lymphomas, there was no significant increase in tumorigenesis in ku80^−/−p21^−/− mice. However, ku80^−/−p21^−/− mice showed no improvement with respect to rough fur coat or osteopaenia, and even showed a shortened lifespan compared with ku80^−/− mice. These results show that the increased lifespan of ku80^−/− MEFs owing to the loss of p21 is not associated with an improvement of the premature ageing phenotypes of ku80^−/− mice observed at the organismal level.     

Synergistic Interaction of Rnf8 and p53 in the Protection against Genomic Instability and Tumorigenesis

Rnf8 is an E3 ubiquitin ligase that plays a key role in the DNA damage response as well as in the maintenance of telomeres and chromatin remodeling. Rnf8^−/− mice exhibit developmental defects and increased susceptibility to tumorigenesis. We observed that levels of p53, a central regulator of the cellular response to DNA damage, increased in Rnf8^−/− mice in a tissue- and cell type–specific manner. To investigate the role of the p53-pathway inactivation on the phenotype observed in Rnf8^−/− mice, we have generated Rnf8^−/−p53^−/− mice. Double-knockout mice showed similar growth retardation defects and impaired class switch recombination compared to Rnf8^−/− mice. In contrast, loss of p53 fully rescued the increased apoptosis and reduced number of thymocytes and splenocytes in Rnf8^−/− mice. Similarly, the senescence phenotype of Rnf8^−/− mouse embryonic fibroblasts was rescued in p53 null background. Rnf8^−/−p53^−/− cells displayed defective cell cycle checkpoints and DNA double-strand break repair. In addition, Rnf8^−/−p53^−/− mice had increased levels of genomic instability and a remarkably elevated tumor incidence compared to either Rnf8^−/− or p53^−/− mice. Altogether, the data in this study highlight the importance of p53-pathway activation upon loss of Rnf8, suggesting that Rnf8 and p53 functionally interact to protect against genomic instability and tumorigenesis.     

BTG2 antagonizes Pin1 in response to mitogens and telomere disruption during replicative senescence

Cellular senescence limits the replicative capacity of normal cells and acts as an intrinsic barrier that protects against the development of cancer. Telomere shortening–induced replicative senescence is dependent on the ATM‐p53‐p21 pathway but additional genes likely contribute to senescence. Here, we show that the p53‐responsive gene BTG2 plays an essential role in replicative senescence. Similar to p53 and p21 depletion, BTG2 depletion in human fibroblasts leads to an extension of cellular lifespan, and ectopic BTG2 induces senescence independently of p53. The anti‐proliferative function of BTG2 during senescence involves its stabilization in response to telomere dysfunction followed by serum‐dependent binding and relocalization of the cell cycle regulator prolyl isomerase Pin1. Pin1 inhibition leads to senescence in late‐passage cells, and ectopic Pin1 expression rescues cells from BTG2‐induced senescence. The neutralization of Pin1 by BTG2 provides a critical mechanism to maintain senescent arrest in the presence of mitogenic signals in normal primary fibroblasts.     

Single‐cell analysis of p16INK4a and p21WAF1 expression suggests distinct mechanisms of senescence in normal human and Li‐Fraumeni Syndrome fibroblasts

Herein we used single‐cell observation methods to gain insight into the roles of p16^INK4A and p21^WAF1 (hereafter p16 and p21) in replicative senescence and ionizing radiation‐induced accelerated senescence in human [normal, ataxia telangiectasia (AT) and Li‐Fraumeni syndrome (LFS)] fibroblast strains. Cultures of all strains entered a state of replicative senescence at late passages, as evident from inhibition of growth, acquisition of flattened and enlarged cell morphology, and positive staining for senescence‐associated β‐galactosidase. In addition, proliferating early‐passage cultures of these strains exhibited accelerated senescence in response to ionizing radiation. Immunofluorescence microscopy revealed the heterogeneous expression of p16 in normal and AT fibroblast strains, with the majority of the cells exhibiting undetectable levels of p16 irrespective of in vitro culture age. Importantly, replicative senescence as well as accelerated senescence triggered by ionizing radiation were accompanied by sustained nuclear accumulation of p21, but did not correlate with p16 expression in p53‐proficient (normal and AT) fibroblasts. In p53‐deficient (LFS) fibroblasts, on the other hand, replicative senescence and ionizing radiation‐triggered accelerated senescence strongly correlated with expression of p16 but not of p21. Furthermore, senescence in LFS fibroblasts was associated with genomic instability encompassing polyploidy. Our findings are compatible with a model in which p16 serves as a backup regulator of senescence, triggering this response preferentially in the absence of wild‐type p53 activity. The possibility that one of the tumor‐suppressor functions of p16 may be associated with genomic instability, preventing the emergence of malignant progeny from polyploid giant cells, is also supported by these results. J. Cell. Physiol. 223: 57–67, 2010. © 2009 Wiley‐Liss, Inc.     

Epimorphic regeneration in mice is p53-independent

The process of regeneration is most readily studied in species of sponge, hydra, planarian and salamander (i.e., newt and axolotl). The closure of MRL mouse ear pinna through-and-through holes provides a mammalian model of unusual wound healing/regeneration in which a blastema-like structure closes the ear hole and cartilage and hair follicles are replaced. Recent studies, based on a broad level of DNA damage and a cell cycle pattern of G₂/M “arrest,” showed that p21^Cip1/Waf1 was missing from the MRL mouse ear and that a p21-null mouse could close its ear holes. Given the p53/p21 axis of control of DNA damage, cell cycle arrest, apoptosis and senescence, we tested the role of p53 in the ear hole regenerative response. Using backcross mice, we found that loss of p53 in MRL mice did not show reduced healing. Furthermore, cross sections of MRL. p53^−/− mouse ears at 6 weeks post-injury showed an increased level of adipocytes and chondrocytes in the region of healing whereas MRL or p21^−/− mice showed chondrogenesis alone in this same region, though at later time points. In addition, we also investigated other cell cyclerelated mutant mice to determine how p21 was being regulated. We demonstrate that p16 and Gadd45 null mice show little healing capacity. Interestingly, a partial healing phenotype in mice with a dual Tgfβ/Rag2 knockout mutation was seen. These data demonstrate an independence of p53 signaling for mouse appendage regeneration and suggest that the role of p21 in this process is possibly through the abrogation of the Tgfβ/Smad pathway.Key words: mouse, regeneration, p53, p21, MRL, ear-hole, Tgfβ     

Upregulation of miR-760 and miR-186 Is Associated with Replicative Senescence in Human Lung Fibroblast Cells

We have previously shown that microRNAs (miRNAs) miR-760, miR-186, miR-337-3p, and miR-216b stimulate premature senescence through protein kinase CK2 (CK2) down-regulation in human colon cancer cells. Here, we examined whether these four miRNAs are involved in the replicative senescence of human lung fibroblast IMR-90 cells. miR-760 and miR-186 were significantly upregulated in replicatively senescent IMR-90 cells, and their joint action with both miR-337-3p and miR-216b was necessary for efficient downregulation of the α subunit of CK2 (CK2α) in IMR-90 cells. A mutation in any of the four miRNA-binding sequences within the CK2α 3′-untranslated region (UTR) indicated that all four miRNAs should simultaneously bind to the target sites for CK2α downregulation. The four miRNAs increased senescence-associated β-galactosidase (SA-β-gal) staining, p53 and p21^Cip1/WAF1 expression, and reactive oxygen species (ROS) production in proliferating IMR-90 cells. CK2α over-expression almost abolished this event. Taken together, the present results suggest that the upregulation of miR-760 and miR-186 is associated with replicative senescence in human lung fibroblast cells, and their cooperative action with miR-337-3p and miR-216b may induce replicative senescence through CK2α downregulation-dependent ROS generation.     

Nuclear Accumulation of p21Cip1 at the Onset of Mitosis: a Role at the G2/M-Phase Transition

Cell cycle arrest in G₁ in response to ionizing radiation or senescence is believed to be provoked by inactivation of G₁ cyclin-cyclin-dependent kinases (Cdks) by the Cdk inhibitor p21^{Cip1/Waf1/Sdi1}. We provide evidence that in addition to exerting negative control of the G₁/S phase transition, p21 may play a role at the onset of mitosis. In nontransformed fibroblasts, p21 transiently reaccumulates in the nucleus near the G₂/M-phase boundary, concomitant with cyclin B1 nuclear translocation, and associates with a fraction of cyclin A-Cdk and cyclin B1-Cdk complexes. Premitotic nuclear accumulation of cyclin B1 is not detectable in cells with low p21 levels, such as fibroblasts expressing the viral human papillomavirus type 16 E6 oncoprotein, which functionally inactivates p53, or in tumor-derived cells. Moreover, synchronized E6-expressing fibroblasts show accelerated entry into mitosis compared to wild-type cells and exhibit higher cyclin A- and cyclin B1-associated kinase activities. Finally, primary embryonic fibroblasts derived from p21^−/− mice have significantly reduced numbers of premitotic cells with nuclear cyclin B1. These data suggest that p21 promotes a transient pause late in G₂ that may contribute to the implementation of late cell cycle checkpoint controls.     

Sustained Endocannabinoid Signaling Compromises Decidual Function and Promotes Inflammation-induced Preterm Birth

Recent studies provide evidence that premature maternal decidual senescence resulting from heightened mTORC1 signaling is a cause of preterm birth (PTB). We show here that mice devoid of fatty acid amide hydrolase (FAAH) with elevated levels of N-arachidonyl ethanolamide (anandamide), a major endocannabinoid lipid mediator, were more susceptible to PTB upon lipopolysaccharide (LPS) challenge. Anandamide is degraded by FAAH and primarily works by activating two G-protein-coupled receptors CB1 and CB2, encoded by Cnr1 and Cnr2, respectively. We found that Faah^−/− decidual cells progressively underwent premature senescence as marked by increased senescence-associated β-galactosidase (SA-β-Gal) staining and γH2AX-positive decidual cells. Interestingly, increased endocannabinoid signaling activated MAPK p38, but not p42/44 or mTORC1 signaling, in Faah^−/− deciduae, and inhibition of p38 halted premature decidual senescence. We further showed that treatment of a long-acting anandamide in wild-type mice at midgestation triggered premature decidual senescence utilizing CB1, since administration of a CB1 antagonist greatly reduced the rate of PTB in Faah^−/− females exposed to LPS. These results provide evidence that endocannabinoid signaling is critical in regulating decidual senescence and parturition timing. This study identifies a previously unidentified pathway in decidual senescence, which is independent of mTORC1 signaling.     

p21Waf1/Cip1 Inhibition of Cyclin E/Cdk2 Activity Prevents Endoreduplication after Mitotic Spindle Disruption

During a normal cell cycle, entry into S phase is dependent on completion of mitosis and subsequent activation of cyclin-dependent kinases (Cdks) in G₁. These events are monitored by checkpoint pathways. Recent studies and data presented herein show that after treatment with microtubule inhibitors (MTIs), cells deficient in the Cdk inhibitor p21^Waf1/Cip1 enter S phase with a ≥4N DNA content, a process known as endoreduplication, which results in polyploidy. To determine how p21 prevents MTI-induced endoreduplication, the G₁/S and G₂/M checkpoint pathways were examined in two isogenic cell systems: HCT116 p21^+/+ and p21^−/− cells and H1299 cells containing an inducible p21 expression vector (HIp21). Both HCT116 p21^−/− cells and noninduced HIp21 cells endoreduplicated after MTI treatment. Analysis of G₁-phase Cdk activities demonstrated that the induction of p21 inhibited endoreduplication through direct cyclin E/Cdk2 regulation. The kinetics of p21 inhibition of cyclin E/Cdk2 activity and binding to proliferating-cell nuclear antigen in HCT116 p21^+/+ cells paralleled the onset of endoreduplication in HCT116 p21^−/− cells. In contrast, loss of p21 did not lead to deregulated cyclin D1-dependent kinase activities, nor did p21 directly regulate cyclin B1/Cdc2 activity. Furthermore, we show that MTI-induced endoreduplication in p53-deficient HIp21 cells was due to levels of p21 protein below a threshold required for negative regulation of cyclin E/Cdk2, since ectopic expression of p21 restored cyclin E/Cdk2 regulation and prevented endoreduplication. Based on these findings, we propose that p21 plays an integral role in the checkpoint pathways that restrain normal cells from entering S phase after aberrant mitotic exit due to defects in microtubule dynamics.     

c-Jun NH2-Terminal Kinase Is Required for Lineage-Specific Differentiation but Not Stem Cell Self-Renewal

The c-Jun NH₂-terminal kinase (JNK) is implicated in proliferation. Mice with a deficiency of either the Jnk1 or the Jnk2 genes are viable, but a compound deficiency of both Jnk1 and Jnk2 causes early embryonic lethality. Studies using conditional gene ablation and chemical genetic approaches demonstrate that the combined loss of JNK1 and JNK2 protein kinase function results in rapid senescence. To test whether this role of JNK was required for stem cell proliferation, we isolated embryonic stem (ES) cells from wild-type and JNK-deficient mice. We found that Jnk1^−/− Jnk2^−/− ES cells underwent self-renewal, but these cells proliferated more rapidly than wild-type ES cells and exhibited major defects in lineage-specific differentiation. Together, these data demonstrate that JNK is not required for proliferation or self-renewal of ES cells, but JNK plays a key role in the differentiation of ES cells.The c-Jun NH₂-terminal kinase (JNK) is a member of the mitogen-activated protein (MAP) kinase group of signaling proteins. JNK is encoded by two ubiquitously expressed genes (Jnk1 and Jnk2) and by a third gene (Jnk3) that is selectively expressed in neurons (14). Gene disruption studies demonstrate that mice without Jnk1 or Jnk2 are viable, but compound deficiency of both Jnk1 and Jnk2 causes early embryonic lethality (14). Murine embryonic fibroblasts (MEFs) isolated from Jnk1^−/− Jnk2^−/− mice exhibit a severe growth retardation phenotype (54). The markedly reduced growth of Jnk1^−/− Jnk2^−/− MEFs is consistent with the finding that JNK is critically required for the regulation of AP1-dependent gene expression (56) that is implicated in cellular proliferation (26). Thus, Jnk1^−/− Jnk2^−/− MEFs express low levels of AP1 proteins (e.g., c-Jun and JunD) and exhibit marked defects in AP1 target gene expression (34, 56). This loss of AP1 function is mediated, in part, by reduced phosphorylation of the activation domain of Jun family proteins and ATF2 (56).More recent studies using a conditional gene ablation strategy have demonstrated that compound JNK deficiency causes rapid senescence (12). This conclusion was confirmed by using chemical genetic analysis with MEFs isolated from mice with a germ line mutation that sensitizes JNK to inhibition by a predesigned small-molecule drug (12, 25). This form of senescence was found to be p53 dependent (12) and resembles the p53-dependent senescence of c-Jun^−/− MEFs (49). These data indicate that JNK plays a critical role in cellular proliferation. Indeed, it is possible that the p53-dependent senescence observed in JNK-deficient cells may contribute to aging. This is because altered p53 function is established to be an important determinant of early aging (36, 55). Importantly, this role of p53 in aging appears to be distinct from p53-mediated tumor suppression and DNA damage responses (21, 39, 43).One aspect of the aging process is a reduction in the regenerative capacity of stem cells (50). Indeed, it has been established that altered p53 activity associated with aging causes decreased stem cell function (8, 18, 42) and that disruption of the p53 pathway can increase stem cell function (1). Since JNK can influence p53-dependent senescence (12), these data indicate that JNK may be important for stem cell proliferation and self-renewal potential.Embryonic stem (ES) cells proliferate and are capable of both self-renewal and differentiation to multiple cell types. Indeed, murine ES cells can differentiate to create all tissues within a mouse. The profound growth retardation and rapid p53-dependent senescence of Jnk1^−/− Jnk2^−/− MEFs (12) suggests that JNK may play a critical role in the normal function of ES cells, including self-renewal and differentiation potential. The purpose of the present study was to test this hypothesis. Our approach was to isolate ES cells from wild-type and JNK-deficient mice. We demonstrate that JNK is not required for self-renewal or the proliferation of ES cells. However, JNK is required for ES cell differentiation.     

The specific role of pRb in p16INK4A-mediated arrest of normal and malignant human breast cells

RB family proteins pRb, p107 and p130 have similar structures and overlapping functions, enabling cell cycle arrest and cellular senescence. pRb, but not p107 or p130, is frequently mutated in human malignancies. In human fibroblasts acutely exposed to oncogenic ras, pRb has a specific role in suppressing DNA replication, and p107 or p130 cannot compensate for the loss of this function; however, a second p53/p21-dependent checkpoint prevents escape from growth arrest. This model of oncogene-induced senescence requires the additional loss of p53/p21 to explain selection for preferential loss of pRb function in human malignancies. We asked whether similar rules apply to the role of pRb in growth arrest of human epithelial cells, the source of most cancers. In two malignant human breast cancer cell lines, we found that individual RB family proteins were sufficient for the establishment of p16-initiated senescence, and that growth arrest in G₁ was not dependent on the presence of functional pRb or p53. However, senescence induction by endogenous p16 was delayed in primary normal human mammary epithelial cells with reduced pRb but not with reduced p107 or p130. Thus, under these circumstances, despite the presence of functional p53, p107 and p130 were unable to completely compensate for pRb in mediating senescence induction. We propose that early inactivation of pRb in pre-malignant breast cells can, by itself, extend proliferative lifespan, allowing acquisition of additional changes necessary for malignant transformation.Key words: breast cancer, senescence, retinoblastoma, p130, p107     

参与细胞衰老的蛋白质结构域

  大多数正常体细胞有有限的复制周期,并最终进入生长停滞状态被称为复制性衰老.迄今比较公认的3条细胞衰老信号转导途径是：p16INK4a/Rb、p19ARF/p53/p21Waf1以及PTEN/p27.目前发现,在基因转录水平上,有些转录因子的结构域对调节p16INK4a、p53/p21Waf1以及p27等与细胞衰老相关基因的表达有重要作用,如E2DBD、环指域(RING finger)等;其次,各条通路要发挥作用,必然要借助其上下游蛋白质的相互作用,其中结构域发挥了纽带作用.本文对其中某些蛋白质相互作用的结构域进行了描述.最后,还总结了其他一些参与细胞衰老的结构域.