Direct evidence from siRNA-directed "knock down" that p16(INK4a) is required for human fibroblast senescence and for limiting ras-induced epithelial cell proliferation

The selective pressure for disruption of the cyclin-dependent kinase inhibitor p16(INK4a) in human cancer has been postulated to reflect its role in mediating growth arrest, both in response to telomere erosion (replicative senescence) and to oncogene-induced and other "stress" signals. Given the known species-specific differences in regulation of senescence, we have tested this hypothesis in human, as opposed to rodent, cells by designing a small interfering RNA (siRNA) to knock down p16(INK4a) expression. Transfection of this siRNA into late-passage normal human diploid fibroblasts allowed at least temporary escape from entry into replicative senescence. Furthermore, in our in vitro model of early-stage, RAS-induced thyroid tumorigenesis, sequential transfections with this siRNA allowed outgrowth of small clusters of proliferating epithelial cells, consistent with escape from the spontaneous "senescence", which normally curtails their proliferative response to mutant RAS. These data provide the first direct evidence that p16(INK4a) is necessary for the initiation of both telomere-dependent and telomere-independent senescence in human cells.     

Expression and characterization of Syrian golden hamster p16, a homologue of human tumor suppressor p16 INK4A

The p16(INK4A)/CDKN2A tumor suppressor gene is known to be inactivated in up to 98% of human pancreatic cancer specimens and represents a potential target for novel therapeutic intervention. Chemically induced pancreatic tumors in Syrian golden hamsters have been demonstrated to share many morphologic and biological similarities with human pancreatic tumors and this model may be appropriate for studying therapies targeting p16(INK4A)/CDKN2A. The purpose of this study was to investigate the fundamental biochemistry of hamster P16 protein. Using both in vivo and in vitro approaches, the CDK4 binding affinity, kinase inhibitory activity, and thermodynamic stability of hamster and human P16 proteins were evaluated. Furthermore, a structural model of hamster P16 protein was generated. These studies demonstrate that hamster P16 protein is biochemically indistinguishable from human P16 protein. From a biochemical perspective, these data strongly support the study of p16-related pancreatic oncogenesis and cancer therapies in the hamster model.     

p16 loss rescues functional decline of Brca1-deficient mammary stem cells

Recent evidence indicates that the accumulation of endogenous DNA damage can induce senescence and limit the function of adult stem cells. It remains elusive whether deficiency in DNA damage repair is associated with the functional alteration of mammary stem cells. In this article, we reported that senescence was induced in mammary epithelial cells during aging along with increased expression of p16Ink4a (p16), an inhibitor of CDK4 and CKD6. Loss of p16 abrogated the age-induced senescence in mammary epithelial cells and significantly increased mammary stem cell function. We showed that loss of Brca1, a tumor suppressor that functions in DNA damage repair, in the mammary epithelium induced senescence with induction of p16 and a decline of stem cell function, which was rescued by p16 loss. These data not only answer the question as to whether deficiency in DNA damage repair is associated with the functional decline of mammary stem cells, but also identify the role of p16 in suppressing Brca1-deficient mammary stem cell function.     

Design and characterization of a hyperstable p16INK4a that restores Cdk4 binding activity when combined with oncogenic mutations

Cyclin-dependent kinase inhibitor p16(INK4a) is the founding member of the INK4 family of tumor suppressors capable of arresting mammalian cell division. Missense mutations in the p16(INK4a) gene (INK4a/CDKN2A/MTS1) are strongly linked to several types of human cancer. These mutations are evenly distributed throughout this small, ankyrin repeat protein and the majority of them disrupt the native secondary and/or tertiary structure, leading to protein unfolding, aggregation and loss of function. We report here the use of multiple stabilizing substitutions to increase the stability of p16(INK4a) and furthermore, to restore Cdk4 binding activity of several defective, cancer-related mutant proteins. Stabilizing substitutions were predicted using four different techniques. The three most effective substitutions were combined to create a hyperstable p16(INK4a) variant that is 1.4 kcal/mol more stable than wild-type. This engineered construct is monomeric in solution with wild-type-like secondary and tertiary structure and cyclin-dependent kinase 4 binding activity. Interestingly, these hyperstable substitutions, when combined with oncogenic mutations R24P, P81L or V126D, can significantly restore Cdk4 binding activity, despite the divergent features of each destabilizing mutation. Extensive biophysical studies indicate that the hyperstable substitutions enhance the binding activity of mutant p16 through several different mechanisms, including an increased amount of secondary structure and thermostability, reduction in exposed hydrophobic surface(s) and/or a reduced tendency to aggregate. This apparent global suppressor effect suggests that increasing the thermodynamic stability of p16 can be used as a general strategy to restore the biological activity to defective mutants of this important tumor suppressor protein.     

Identification and characterization of a novel protein ISOC2 that interacts with p16INK4a

p16(INK4a) is a multiple tumor suppressor, playing an important role in proliferation and tumorigenesis. To screen the p16(INK4a)-associated proteins, we performed a yeast two-hybrid assay and identified a novel protein isochorismatase domain containing 2 (ISOC2). ISOC2 conserves in different species, and encodes 205 and 210 amino acids in human and mouse, respectively. The expression of ISOC2 in mouse is universal but predominantly in uterus, stomach, and urinary tract system. Interaction between ISOC2 and p16(INK4a) was verified using in vitro pull-down assays and in vivo co-immunoprecipitation. Confocal microscopy studies using green and cyan fluorescent fusion proteins determined that ISOC2 co-localizes with p16(INK4a). Over-expressed ISOC2 is able to inhibit p16(INK4a) in dose-dependent manner. Our data indicated that ISOC2 is a novel functional protein, which is able to bind and co-localize with a tumor suppressor gene p16(INK4a). Over-expressed ISOC2 inhibits the expression of p16(INK4a), suggesting that this novel gene may play a role during the tumor development by interacting with p16(INK4a).     

p16INK4a and p14ARF methylation as a potential biomarker for human bladder cancer

Promoter hypermethylation is one of the putative mechanisms underlying the inactivation of negative cell-cycle regulators. We examined whether the methylation status of p16(INK4a) and p14(ARF), genes located upstream of the RB and p53 pathway, is a useful biomarker for the staging, clinical outcome, and prognosis of human bladder cancer. Using methylation-specific PCR (MSP), we examined the methylation status of p16(INK4a) and p14(ARF) in 64 samples from 45 bladder cancer patients (34 males, 11 females). In 19 patients with recurrent bladder cancer, we examined paired tissue samples from their primary and recurrent tumors. The methylation status of representative samples was confirmed by bisulfite DNA sequencing analysis. The median follow-up duration was 34.3 months (range 27.0-100.1 months). The methylation rate for p16(INK4a) and p14(ARF) was 17.8% and 31.1%, respectively, in the 45 patients. The incidence of p16(INKa) and p14(ARF) methylation was significantly higher in patients with invasive (>or=pT2) than superficial bladder cancer (pT1) (p=0.006 and p=0.001, respectively). No MSP bands for p16(INK4a) and p14(ARF) were detected in the 8 patients with superficial, non-recurrent tumors. In 19 patients with tumor recurrence, the p16(INK4a) and p14(ARF) methylation status of the primary and recurrent tumors was similar. Of the 22 patients who had undergone cystectomy, 8 (36.4%) manifested p16(INKa) methylation; p16(INK4a) was not methylated in 23 patients without cystectomy (p=0.002). Kaplan-Meier analysis revealed that patients with p14(ARF) methylation had a significantly poorer prognosis than those without (p=0.029). This is the first study indicating that MSP analysis of p16(INK4a) and p14(ARF) genes is a useful biomarker for the pathological stage, clinical outcome, and prognosis of patients with bladder cancer.     

The number of p16INK4a positive cells in human skin reflects biological age

Cellular senescence is a defense mechanism in response to molecular damage which accumulates with aging. Correspondingly, the number of senescent cells has been reported to be greater in older than in younger subjects and furthermore associates with age-related pathologies. Inter-individual differences exist in the rate at which a person ages (biological age). Here, we studied whether younger biological age is related to fewer senescent cells in middle-aged individuals with the propensity for longevity, using p16INK4a as a marker for cellular senescence. We observed that a younger biological age associates with lower levels of p16INK4a positive cells in human skin.     

Inactivation of p16INK4a in Primary Tumors and Cell Lines of Head and Neck Squamous Cell Carcinoma

Inactivation of the p16^INK4a gene by mutation and deletion is common in head and neck squamous cell carcinoma (HNSCC). The present study demonstrates that hypermethylation of the 5 CpG islands can serve as an alternative mechanism for the inactivation of the p16^INK4a gene in this tumor. We studied 11 HNSCC cell lines and 17 oral squamous cell carcinoma (OSCC) primary tumors for p16^INK4a gene status by protein/mRNA and DNA genetic/epigenetic analyses to determine the incidence of its inactivation. Our study indicates that: (1) inactivation of p16 protein is frequent in HNSCC cell lines (6/11, 54.5%) and OSCC primary tumors (15/17, 88.2%), (2) inactivation of p16^INK4a protein is commonly associated with the presence of gene alteration such as mutation, homozygous deletion and especially aberrant methylation, and (3) genomic sequencing of bisulfite-modified DNA shows that the carcinoma develops a heterogeneous pattern of hypermethylation.     

小鼠p16~(INK4a)基因位点的结构和功能研究

p1 6INK4a基因的失活与多种肿瘤的发生和发展有联系。通过筛选小鼠基因组文库 ,获得长度为 1 4.5kb的p1 6INK4a基因组DNA片段。对上述 1 4.5kbDNA测序后进行生物信息学分析表明 :该片段包含 3个外显子 ,编码 1个由 1 68个氨基酸残基组成的多肽 ,其相对分子质量的理论计算值为 1 7941 ,有 7个可能的磷酸化位点 ,说明p1 6INK4a蛋白的功能可能受到磷酸化的调控。该DNA片段的非编码区分布着大量短散布元件、长散布元件和简单重复序列 ,这样的结构为转座和同源重组提供了结构基础 ,提示了部分肿瘤细胞中p1 6INK4a基因缺失的可能原因。对第一外显子序列与已发表的相应序列比较发现其DNA序列和所编码的多肽存在多态性     

Prevalence of aberrant methylation of p14ARF over p16INK4a in some human primary tumors

The INK4a/ARF locus encodes two unrelated tumor suppressor proteins, p16INK4a and p14ARF, which participate in the two main cell-cycle control pathways, p16–Rb and p14–p53. Methylation of CpG promoter islands has been described as a mechanism of gene silencing. Exon 1 of the p16INK4a gene and the p14ARF promoter gene reside within CpG islands. Therefore, both can become methylated de novo and silenced. It has recently been proposed that the methylation changes in certain genes could be used as molecular markers for the detection of almost all forms of human cancer. Here, we analyzed concomitantly in each tumor sample and normal tissue the methylation status of p16INK4a and p14ARF by methylation-specific PCR (MSP) in 100 breast, 95 colon and 27 bladder carcinomas. A series of clinicopathological parameter were obtained from the medical records of the patients, p14ARF showed a higher rate of hypermethylation than p16INK4a in all three tumor types. p16INK4a and p14ARF aberrant methylation was significantly correlated with poor prognosis clinicopathological parameters of the three tumor types. We conclude that both p16INKa and p14ARF hypermethylation may be involved in breast, colon and bladder carcinogenesis, with special emphasis on the role of the lesser studied p14ARF gene, and that tumors with aberrant methylation in the two genes were associated with worse prognosis.     

细胞衰老的重要通路:p16INK4a/Rb和p19ARF/p53/p21Cip1信号途径

细胞周期蛋白依赖激酶（cyclin-dependent kinase,CDK)抑制因子p16^INK4a,p21^Cipl等是细胞衰老的关键效应物。本文对涉及这些抑制物的两条衰老诱导途径作一综述,它们是p16^INK4a/Rb和p19^ARF/p53/p21^Cipl信号途径。其中,几个抑癌基因的产物R ,16^INFK4a,p53及p19^ARF处于两条途径的核心位置。     

The impact of autophagy on the development of senescence in primary tubular epithelial cells

Autophagy and senescence are 2 distinct pathways that are importantly involved in acute kidney injury and renal repair. Recent data indicate that the 2 processes might be interrelated. To investigate the potential link between autophagy and senescence in the kidney we isolated primary tubular epithelial cells (PTEC) from wild-type mice and monitored the occurrence of cellular senescence during autophagy activation and inhibition. We found that the process of cell isolation and transfer into culture was associated with a strong basal autophagic activation in PTEC. Specific inhibition of autophagy by silencing autophagy-related 5 (Atg5) counteracted the occurrence of senescence hallmarks under baseline conditions. Reduced senescent features were also observed in Atg5 silenced PTEC after γ-irradiation and during H-Ras induced oncogenic senescence, but the response was less uniform in these stress models. Senescence inhibition was paralleled by better preservation of a mature epithelial phenotype in PTEC. Interestingly, treatment with rapamycin, which acts as an activator of autophagy, also counteracted the occurrence of senescence features in PTEC. While we interpret the anti-senescent effect of rapamycin as an autophagy-independent effect of mTOR-inhibition, the more specific approach of Atg5 silencing indicates that overactivated autophagy can have pro-senescent effects in PTEC. These results highlight the complex interaction between cell culture dependent stress mechanisms, autophagy and senescence.     

Suppression of thioredoxin-1 induces premature senescence in normal human fibroblasts

Thioredoxin (TRX) is a ubiquitous multifunctional thiol protein that is critically involved in maintaining cellular redox homeostasis. Levels of thioredoxin-1 (TRX1), the major isoform of TRX, have been shown to correlate with organismal lifespan and age-associated tissue deterioration. Accordingly, we investigated the direct functional effects of suppressing TRX1 levels on cellular senescence, a phenomenon intimately linked with tissue degeneration and aging. Here we find that suppression of TRX1 expression via shRNA rapidly induces premature senescence in young human skin fibroblasts through upregulation of the p53/p21^Cip1/Waf1 and p16^INK4a tumor suppressor pathways. Moreover, inhibition of these pathways by introduction of SV40 Large T Antigen prevents TRX1 suppression-induced premature senescence but not susceptibility to oxidative stressors. Thus our results suggest that TRX1 has a role in suppressing senescence in normal cells in addition to its function as a redox-protective protein.     

Downregulation of 14-3-3sigma prevents clonal evolution and leads to immortalization of primary human keratinocytes

In human epidermal keratinocytes, replicative senescence, is determined by a progressive decline of clonogenic and dividing cells. Its timing is controlled by clonal evolution, that is, by the continuous transition from stem cells to transient amplifying cells. We now report that downregulation of 14-3-3sigma, which is specifically expressed in human stratified epithelia, prevents keratinocyte clonal evolution, thereby forcing keratinocytes into the stem cell compartment. This allows primary human keratinocytes to readily escape replicative senescence. 14-3-3sigma-dependent bypass of senescence is accompanied by maintenance of telomerase activity and by downregulation of the p16(INK4a) tumor suppressor gene, hallmarks of keratinocyte immortalization. Taken together, these data therefore suggest that inhibition of a single endogenous gene product fosters immortalization of primary human epithelial cells without the need of exogenous oncogenes and/or oncoviruses.     

p18INK4c and p27KIP1 are required for cell cycle arrest of differentiated myotubes

Myogenic differentiation is characterized by permanent and irreversible cell cycle withdrawal and increased resistance to apoptosis. These functions correlate with changes in expression and activity of several cyclin-dependent kinase inhibitors, including p18, p21, and p27. In this study, we examined the requirements for p18, p21, and p27 in initiating growth arrest in multinucleated myotubes under differentiation conditions and in maintaining terminal arrest upon restimulation of differentiated myotubes with mitogenic signals. Under differentiation conditions, only p27(-/-) or p18(-/-)p27(-/-) myotubes are capable of reentering the cell cycle and synthesizing DNA at a very low frequency. Escape from cell cycle arrest was significantly greater in p18(-/-)p27(-/-) myotubes than in p27(-/-) myotubes. Stimulation of differentiated cultures with a mitogen-rich growth medium enhances p18(-/-)p27(-/-) myotube proliferation to encompass approximately half of the nuclei. p18(-/-)p21(-/-) and p21(-/-)p27(-/-) myotubes remain terminally arrested. Nuclei within individual restimulated p18(-/-)p27(-/-) myotubes can be found in all phases of the cell cycle, and a myotube can be multiphasic without any obvious deleterious effects. Increasing the time of differentiation or serum stimulation of p18(-/-)p27(-/-) myotubes neither increases the proliferation index of the myotube nuclei, nor does it alter the percentage of nuclei in each of the cell cycle phases. During the first 24 h of serum stimulation, the p18(-/-)p27(-/-) myotube nuclei that escape G0 arrest will rearrest in either S or G2 phase, without either mitosis or endoreplication. Apoptosis is increased in restimulated p18(-/-)p27(-/-) myotube nuclei, but is not specific for any cell cycle phase. These results suggest a collaborative role for p18 and p27 in initiating and maintaining G0 arrest during myogenic differentiation. While p18 and p27 appear to be essential in initiating G0 arrest in a proportion of postmitotic myotube nuclei, there must be another cell cycle inhibitor protein that functions with p18 and p27 in maintaining terminal arrest. We propose that the combined rate-limiting expressions of p18, p27, and this other inhibitor determine whether the myotube nuclei will remain postmitotic, or reenter the cell cycle, and if the nuclei escape G0 arrest, in which phase of the cell cycle the nuclei will ultimately rearrest.