p16INK4A Participates in a G1 Arrest Checkpoint in Response to DNA Damage

Members of the INK4 protein family specifically inhibit cyclin-dependent kinase 4 (cdk4) and cdk6-mediated phosphorylation of the retinoblastoma susceptibility gene product (Rb). p16^INK4A, a prototypic INK4 protein, has been identified as a tumor suppressor in many human cancers. Inactivation of p16^INK4A in tumors expressing wild-type Rb is thought to be required in order for many malignant cell types to enter S phase efficiently or to escape senescence. Here, we demonstrate another mechanism of tumor suppression by implicating p16^INK4A in a G₁ arrest checkpoint in response to DNA damage. Calu-1 non-small cell lung cancer cells, which retain Rb and lack p53, do not arrest in G₁ following DNA damage. However, engineered expression of p16^INK4A at levels compatible with cell proliferation restores a G₁ arrest checkpoint in response to treatment with γ-irradiation, topoisomerase I and II inhibitors, and cisplatin. A similar checkpoint can be demonstrated in p53^−/− fibroblasts that express p16^INK4A. DNA damage-induced G₁ arrest, which requires the expression of pocket proteins such as Rb, can be abrogated by overexpression of cdk4, kinase-inactive cdk4 variants capable of sequestering p16^INK4A, or a cdk4 variant incapable of binding p16^INK4A. After exposure to DNA-damaging agents, there was no change either in overall levels of p16^INK4A or in amounts of p16^INK4A found in complex with cdks 4 and 6. Nonetheless, p16^INK4A expression is required for the reduction in cdk4- and cdk6-mediated Rb kinase activity observed in response to DNA damage. During tumor progression, loss of p16^INK4A expression may be necessary for cells with wild-type Rb to bypass this G₁ arrest checkpoint and attain a fully transformed phenotype.     

The physiology of p16INK4A-mediated G1 proliferative arrest

Phosphorylation of the product of the retinoblastoma susceptibility gene (Rb) physiologically inactivates its growth-suppressive properties. Rb phosphorylation is mediated by cyclin-dependent kinases (CDKs), whose activity is enhanced by cyclins and inhibited by CDK inhibitors. p16^INK4A is a member of a family of inhibitors specific for CDK4 and CDK6. p16^INK4A is deleted and inactivated in a wide variety of human malignancies, including familial melanomas and pancreatic carcinoma syndromes, indicating that it is an authentic human tumor suppressor. Although one mechanism for its tumor suppression may be prevention of Rb phosphorylation, thereby causing G1 arrest, many normal cell types express p16^INK4A, and are still able to traverse the cell cycle. In a search for other mechanisms, we have found that p16^INK4A is required for p53-independent G1 arrest in response to DNA-damaging agents, including topoisomerase I and II inhibitors. Thus, like other tumor suppressors, p16^INK4A plays an essential role in a DNA-damage checkpoint that leads to cell cycle arrest.     

Regulation of proliferation in developing human tooth germs by MSX homeodomain proteins and cyclin-dependent kinase inhibitor p19INK4d

Before the secretion of hard dental tissues, tooth germs undergo several distinctive stages of development (dental lamina, bud, cap and bell). Every stage is characterized by specific proliferation patterns, which is regulated by various morphogens, growth factors and homeodomain proteins. The role of MSX homeodomain proteins in odontogenesis is rather complex. Expression domains of genes encoding for murine Msx1/2 during development are observed in tissues containing highly proliferative progenitor cells. Arrest of tooth development in Msx knockout mice can be attributed to impaired proliferation of progenitor cells. In Msx1 knockout mice, these progenitor cells start to differentiate prematurely as they strongly express cyclin-dependent kinase inhibitor p19^INK4d. p19^INK4d induces terminal differentiation of cells by blocking the cell cycle in mitogen-responsive G1 phase. Direct suppression of p19^INK4d by Msx1 protein is, therefore, important for maintaining proliferation of progenitor cells at levels required for the normal progression of tooth development. In this study, we examined the expression patterns of MSX1, MSX2 and p19^INK4d in human incisor tooth germs during the bud, cap and early bell stages of development. The distribution of expression domains of p19^INK4d throughout the investigated period indicates that p19^INK4d plays active role during human tooth development. Furthermore, comparison of expression domains of p19^INK4d with those of MSX1, MSX2 and proliferation markers Ki67, Cyclin A2 and pRb, indicates that MSX-mediated regulation of proliferation in human tooth germs might not be executed by the mechanism similar to one described in developing tooth germs of wild-type mouse.     

CDK4 inhibition restores G₁-S arrest in MYCN-amplified neuroblastoma cells in the context of doxorubicin-induced DNA damage

Relapse with drug-resistant disease is the main cause of death in MYCN-amplified neuroblastoma patients. MYCN-amplified neuroblastoma cells in vitro are characterized by a failure to arrest at the G?-S checkpoint after irradiation- or drug-induced DNA damage. We show that several MYCN-amplified cell lines harbor additional chromosomal aberrations targeting p53 and/or pRB pathway components, including CDK4/CCND1/MDM2 amplifications, p16INK4A/p14ARF deletions or TP53 mutations. Cells with these additional aberrations undergo significantly lower levels of cell death after doxorubicin treatment compared with MYCN-amplified cells, with no additional mutations in these pathways. In MYCN-amplified cells CDK4 expression is elevated, increasing the competition between CDK4 and CDK2 for binding p21. This results in insufficient p21 to inhibit CDK2, leading to high CDK4 and CDK2 kinase activity upon doxorubicin treatment. CDK4 inhibition by siRNAs, selective small compounds or p19^INK4D overexpression partly restored G?-S arrest, delayed S-phase progression and reduced cell viability upon doxorubicin treatment. Our results suggest a specific function of p19^INK4D, but not p16^INK4A, in sensitizing MYCN-amplified cells with a functional p53 pathway to doxorubicin-induced cell death. In summary, the CDK4/cyclin D-pRB axis is altered in MYCN-amplified cells to evade a G?-S arrest after doxorubicin-induced DNA damage. Additional chromosomal aberrations affecting the p53-p21 and CDK4-pRB axes compound the effects of MYCN on the G? checkpoint and reduce sensitivity to cell death after doxorubicin treatment. CDK4 inhibition partly restores G?-S arrest and sensitizes cells to doxorubicin-mediated cell death in MYCN-amplified cells with an intact p53 pathway.     

Identification of the DNA damage-responsive elements of therhp51+ gene, arecA andRAD51 homolog from the fission yeastSchizosaccharomyces pombe

TheSchizosaccharomyces pombe rhp51 ⁺ gene encodes a recombinational repair protein that shares significant sequence identities with the bacterial RecA and theSaccharomyces cerevisiae RAD51 protein. Levels ofrhp51 ⁺ mRNA increase following several types of DNA damage or inhibition of DNA synthesis. Anrhp51::ura4 fusion gene was used to identify the cis-acting promoter elements involved in regulatingrhp51 ⁺ expression in response to DNA damage. Two elements, designated DRE1 and DRE2 (fordamage-responsiveelement), match a decamer consensus URS (upstream repressing sequence) found in the promoters of many other DNA repair and metabolism genes fromS. cerevisiae. However, our results show that DRE1 and DRE2 each function as a UAS (upstream activating sequence) rather than a URS and are also required for DNA-damage inducibility of the gene. A 20-bp fragment located downstream of both DRE1 and DRE2 is responsible for URS function. The DRE1 and DRE2 elements cross-competed for binding to two proteins of 45 and 59 kDa. DNase I footprint analysis suggests that DRE1 and DRE2 bind to the same DNA-binding proteins. These results suggest that the DRE-binding proteins may play an important role in the DNA-damage inducibility ofrhp51 ⁺ expression.     

Altered expression of G1/S phase cell cycle regulators in placental mesenchymal stromal cells derived from preeclamptic pregnancies with fetal-placental compromise

Herein, we evaluated whether Placental Mesenchymal Stromal Cells (PDMSCs) derived from normal and Preeclamptic (PE) placentae presented differences in the expression of G1/S-phase regulators p16^INK4A, p18^INK4C, CDK4 and CDK6. Finally, we investigated normal and PE-PDMSCs paracrine effects on JunB, Cyclin D1, p16^INK4A, p18^INK4C, CDK4 and CDK6 expressions in physiological term villous explants.

PDMSCs were isolated from physiological (n = 20) and PE (n = 24) placentae. Passage three normal and PE-PDMSC and conditioned media (CM) were collected after 48h. Physiological villous explants (n = 60) were treated for 72h with normal or PE-PDMSCs CM. Explants viability was assessed by Lactate Dehydrogenase Cytotoxicity assay. Cyclin D1 localization was evaluated by Immuofluorescence (IF) while JunB, Cyclin-D1 p16^INK4A, p18^INK4C, CDK4 and CDK6 levels were assessed by Real Time PCR and Western Blot assay.

We reported significantly increased p16^INK4A and p18^INK4C expression in PE- relative to normal PDMSCs while no differences in CDK4 and CDK6 levels were detected. Explants viability was not affected by normal or PE-PDMSCs CM. Normal PDMSCs CM increased JunB, p16^INK4 and p18^INK4C and decreased Cyclin-D1 in placental tissues. In contrast, PE-PDMSCs CM induced JunB downregulation and Cyclin D1 increase in placental explants. Cyclin D1 IF staining showed that CM treatment targeted mainly the syncytiotrophoblast.

We showed Cyclin D1-p16INK4A/p18INK4C altered pathway in PE-PDMSCs demonstrating an aberrant G1/S phase transition in these pathological cells. The abnormal Cyclin D1-p16INK4A/p18INK4C expression in explants conditioned by PE-PDMSCs media suggest a key contribution of mesenchymal cells to the altered trophoblast cell cycle regulation typical of PE pregnancies with fetal-placental compromise.     

The 5′-flanking region of the E1 α form of the murine p16 (MTS1) gene

We have PCR-amplified and sequenced the immediate (841 bp) 5′-flanking region of murine p16^INK4a (MTS1, CDKN2) tumor suppressor gene. Comparing to recently published 5'-flanking region of the human α form of p16^INK4a, homologies were found in several regions of murine p16^INK4a-α putative promoter sequence.     

An AC-repeat adjacent to mouse Cdkn2B allows the detection of specific allelic losses in the p15 INK4b and p16 INK4a tumor suppressor genes

The cyclin-dependent kinase inhibitors p15 ^INK4b and p16 ^INK4a are involved in the development of a wide range of human and murine tumors. These tumor suppressor genes are inactivated by deletions frequently associated to point mutations in the coding regions or hypermethylation of their promoters. In this work, we describe a simple-sequence length polymorphism located in mouse Chromosome (Chr) 4, between the Cdkn2B (p15 ^INK4b ) and Cdkn2A (p16 ^INK4a ) genes, only 700 bp downstream of the Cdkn2B locus. This DNA region was analyzed in different inbred strains showing a variable AC-repetitive DNA sequence. We used this microsatellite to detect loss of heterozygosity of the Cdkn2A and Cdkn2B loci in γ-irradiation-induced thymic lymphomas of C57BL/6J × RF/J F₁ hybrids. Using this specific marker, we were able to locate additional allelic losses not detected by other microsatellites. Since the allelic losses can be detected by a simple PCR amplification, this AC-repetitive sequence is specially useful as a genetic marker for these Cdkn2 genes and specifically for the p15 ^INK4b cell cycle inhibitor. Received: 27 August 1997 / Accepted: 13 November 1997     

Overexpression of cdk4/cyclin D1 induces apoptosis in PC12 cells in the presence of trophic support.

The induction of apoptosis by cell cycle regulator molecules under conditions optimal for exponential growth was examined in rat pheochromocytoma PC12 cells by overexpression of cyclins and cyclin-dependent kinases (cdks). By flow cytometry and by immunofluorescence, only cells overexpressing cdk4 or cyclin D1 underwent apoptosis, which was not associated with G1-arrest. Cdk4 kinase activity was significantly higher in cdk4-, or cyclin D1-expressing cells. Furthermore, induction of apoptosis by cdk4 was abrogated by co-transfection of p16(INK4), or dominant negative cdk4. These results suggest that upregulation of cdk4 kinase activity is a primary and critical mediator of apoptosis in PC12 cells under physiological conditions.     

Acquired TET2 mutation in one patient with familial platelet disorder with predisposition to AML led to the development of pre‐leukaemic clone resulting in T2‐ALL and AML‐M0

Familial platelet disorder with predisposition to acute myeloid leukaemia (FPD/AML) is characterized by germline RUNX1 mutations, thrombocytopaenia, platelet dysfunction and a risk of developing acute myeloid and in rare cases lymphoid T leukaemia. Here, we focus on a case of a man with a familial history of RUNX1^R174Q mutation who developed at the age of 42 years a T2‐ALL and, 2 years after remission, an AML‐M0. Both AML‐M0 and T2‐ALL blast populations demonstrated a loss of 1p36.32‐23 and 17q11.2 regions as well as other small deletions, clonal rearrangements of both TCRγ and TCRδ and a presence of 18 variants at a frequency of more than 40%. Additional variants were identified only in T2‐ALL or in AML‐M0 evoking the existence of a common original clone, which gave rise to subclonal populations. Next generation sequencing (NGS) performed on peripheral blood‐derived CD34⁺ cells 5 years prior to T2‐ALL development revealed only the missense TET2^P1962T mutation at a frequency of 1%, which increases to more than 40% in fully transformed leukaemic T2‐ALL and AML‐M0 clones. This result suggests that TET2^P1962T mutation in association with germline RUNX1^R174Q mutation leads to amplification of a haematopoietic clone susceptible to acquire other transforming alterations.     

cdk6 can shorten G(1) phase dependent upon the N-terminal INK4 interaction domain.

Deregulated activity of cdk4 or cdk6 can lead to inappropriate cellular proliferation and tumorigenesis accompanied by unchecked inactivation of the retinoblastoma tumor suppressor protein. Certain tumor types preferentially activate either cdk4 or cdk6, suggesting that these kinases may not be equivalently oncogenic in all cell types. Although it is clear that cdk4 can act as an oncogene at least in part by evading inhibition by p16(INK4a), the role of cdk6 in tumorigenesis is less well understood. To investigate the consequences of aberrant expression of cdk6, the requirements for proliferation caused by cdk6 overexpression were studied. cdk6-transfected U2OS cells displayed an accelerated progression through G(1) phase that was dependent on kinase activity and that did not correlate with p27 binding. Furthermore, a mutation that prevents cdk6 interaction with INK4 proteins (cdk6R31C) was found to inactivate the proliferative effect of cdk6 and increase cytoplasmic localization, despite the fact that this mutant could phosphorylate the retinoblastoma protein in vitro. Together, these data suggest a role for the cdk6 INK4 interaction domain in the generation of functional, nuclear cdk6 complexes and demonstrate the importance of elevated cdk6 kinase activity in G(1) acceleration.