Structural analysis of the inhibition of Cdk4 and Cdk6 by p16(INK4a) through molecular dynamics simulations

Cyclin-dependent kinases 4, 6 and 2 (Cdk4/6/2), are proteins that lead progression through the G1-S transition, a step strictly regulated in the process of cell proliferation. The p16(INK4a) tumor suppressor, whose expression is inhibited in a high number of cancers, binds to Cdk4/6 and inhibits phosphorylation of the retinoblastoma protein, forcing cells to remain in the G1 phase and therefore, arresting cell division. Accordingly, the design of small compounds mimicking the inhibition of p16(INK4a) appears to be a promising way to treat cancer. In order to get some insight into the key interactions governing recognition between different cyclin-dependent kinases and the p16(INK4a) tumor suppressor, the present work reports the results of molecular dynamics simulations of both, the Cdk6-p16(INK4a) complex and the Cdk4-p16(INK4a) complex, respectively at 300 K. Most of the key interactions observed, were already anticipated in the analysis of the crystal structure of Cdk6-p16(INK4a). However, a few different features found out from the analysis of these calculations provide a better understanding of the role of the T-loop conformation, a fragment of Cdks, and the way the ATP binding-site is distorted upon binding of p16(INK4a).     

Phosphorylation of p16INK4A correlates with Cdk4 association

Progression through the eukaryotic cell cycle is driven by the activity of cyclin-dependent kinases. The cyclin D-dependent kinase Cdk4 promotes progression through the G(1) phase of the cell cycle and is deregulated in many human tumors. The tumor suppressor protein p16(INK4A) (p16) forms a complex with Cdk4 and inhibits kinase activity. Here we report that p16 is phosphorylated, and the phosphorylated form of p16 is preferentially associated with Cdk4 in normal human fibroblasts. We mapped phosphorylation sites on exogenously overexpressed p16 to serines 7, 8, 140, and 152 and found that endogenous p16 associated with Cdk4 is phosphorylated at serine 152. All mapped phosphorylation sites lie outside of the conserved kinase-binding domain of p16 but in regions of the protein affected by mutations in familial and sporadic cancer. Our results suggest a novel regulation of p16 activity.     

Structural Analysis of the Inhibition of Cdk4 and Cdk6 by p16INK4a through Molecular Dynamics Simulations

Abstract

Cyclin-dependent kinases 4, 6 and 2 (Cdk4/6/2), are proteins that lead progression through the G1-S transition, a step strictly regulated in the process of cell proliferation. The p16^INK4a tumor suppressor, whose expression is inhibited in a high number of cancers, binds to Cdk4/6 and inhibits phosphorylation of the retinoblastoma protein, forcing cells to remain in the G1 phase and therefore, arresting cell division. Accordingly, the design of small compounds mimicking the inhibition of p16^INK4a appears to be a promising way to treat cancer. In order to get some insight into the key interactions governing recognition between different cyclin-dependent kinases and the p16^INK4a tumor suppressor, the present work reports the results of molecular dynamics simulations of both, the Cdk6-p16^INK4a complex and the Cdk4-p16^INK4a complex, respectively at 300 K. Most of the key interactions observed, were already anticipated in the analysis of the crystal structure of Cdk6-p16^INK4a. However, a few different features found out from the analysis of these calculations provide a better understanding of the role of the T-loop conformation, a fragment of Cdks, and the way the ATP binding-site is distorted upon binding of p16^INK4a.     

Lack of cyclin D-Cdk complexes in Rb-negative cells correlates with high levels of p16INK4/MTS1 tumour suppressor gene product.

D-type cyclins, in association with the cyclin-dependent kinases Cdk4 or Cdk6, regulate events in the G1 phase of the cell cycle and may contribute to the phosphorylation of the retinoblastoma gene product (Rb). However, in cells in which the function of Rb has been compromised, either by naturally arising mutations or through binding to proteins encoded by DNA tumour viruses, Cdk4 and Cdk6 are not associated with D cyclins. Instead, both kinases form binary complexes with a stable 16 kDa protein (p16) encoded by the putative tumour suppressor gene INK4/MTS1 on human chromosome 9p21. Here we show an inverse correlation between Rb status and the expression of p16. Since Rb-negative cells express high levels of p16, we suggest that in these cells p16 competes with D cyclins for binding to Cdk4 and Cdk6 and prevents formation of active complexes. In line with these predictions, DNA tumour virus oncoproteins do not disrupt cyclin D1-Cdk4 complexes in cells lacking p16.     

p16INK4a Peptide mimetics identified via virtual screening

The transition from G1 to S phase in the cell cycle is highly regulated by Cdk4 and Cdk6, which in turn is inhibited by the tumor suppressor p16^INK4a. Replacement of lost p16^INK4a activity in cancer cells via gene therapy has worked in vivo to decrease tumor progression; however, practical issues limit gene therapy applications at this time. Here, we report the discovery of compounds that inhibit Cdk4 and Cdk6 activity. The NMR structure of a peptide that exhibits p16^INK4a activity was solved and combined with known functional data to generate a pharmacophore that was used to mine the NCI chemical database. The hits were filtered utilizing the program Qikprop. Four compounds were subsequently shown to inhibit Cdk4 and/or Cdk6 with IC₅₀ in the μM range. These compounds form lead compounds upon which further cell cycle inhibitors can be developed.     

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).     

INK4 proteins, a family of mammalian CDK inhibitors with novel biological functions

The cyclin D-Cdk4-6/INK4/Rb/E2F pathway plays a key role in controlling cell growth by integrating multiple mitogenic and antimitogenic stimuli. The members of INK4 family, comprising p16(INK4a), p15(INK4b), p18(INK4c), and p19(INK4d), block the progression of the cell cycle by binding to either Cdk4 or Cdk6 and inhibiting the action of cyclin D. These INK4 proteins share a similar structure dominated by several ankyrin repeats. Although they appear to be structurally redundant and equally potent as inhibitors, the INK4 family members are differentially expressed during mouse development. The striking diversity in the pattern of expression of INK4 genes suggested that this family of cell cycle inhibitors might have cell lineage-specific or tissue-specific functions. The INK4 proteins are commonly lost or inactivated by mutations in diverse types of cancer, and they represent established or candidate tumor suppressors. Apart from their capacity to arrest cells in the G1-phase of the cell cycle they have been shown to participate in an increasing number of cellular processes. Given their emerging roles in fundamental physiological as well as pathological processes, it is interesting to explore the diverse roles for the individual INK4 family members in different functions other than cell cycle regulation. Extensive studies, over the past few years, uncover the involvement of INK4 proteins in senescence, apoptosis, DNA repair, and multistep oncogenesis. We will focus the discussion here on these unexpected issues.     

p16INK4a-induced senescence is disabled by melanoma-associated mutations

The p16(INK4a)-Rb tumour suppressor pathway is required for the initiation and maintenance of cellular senescence, a state of permanent growth arrest that acts as a natural barrier against cancer progression. Senescence can be overcome if the pathway is not fully engaged, and this may occur when p16(INK4a) is inactivated. p16(INK4a) is frequently altered in human cancer and germline mutations affecting p16(INK4a) have been linked to melanoma susceptibility. To characterize the functions of melanoma-associated p16(INK4a) mutations, in terms of promoting proliferative arrest and initiating senescence, we utilized an inducible expression system in a melanoma cell model. We show that wild-type p16(INK4a) promotes rapid cell cycle arrest that leads to a senescence programme characterized by the appearance of chromatin foci, activation of acidic beta-galactosidase activity, p53 independence and Rb dependence. Accumulation of wild-type p16(INK4a) also promoted cell enlargement and extensive vacuolization independent of Rb status. In contrast, the highly penetrant p16(INK4a) variants, R24P and A36P failed to arrest cell proliferation and did not initiate senescence. We also show that overexpression of CDK4, or its homologue CDK6, but not the downstream kinase, CDK2, inhibited the ability of wild-type p16(INK4a) to promote cell cycle arrest and senescence. Our data provide the first evidence that p16(INK4a) can initiate a CDK4/6-dependent autonomous senescence programme that is disabled by inherited melanoma-associated mutations.     

Reducing CDK4/6-p16(INK4a) interface. Computational alanine scanning of a peptide bound to CDK6 protein

The tumor suppressor gene p16INK4a is commonly found altered in numerous and different types of cancer. The encoded protein arrests cell cycle in G1 phase by binding to CDK4 and CDK6, inhibiting their kinase function. In 1995, a 20-residue peptide, extracted from p16INK4a protein sequence, was discovered that retains the cell cycle inhibition properties of the endogenous tumor suppressor. However, its structure has not been determined yet. In this article, the features of a theoretical structure of the peptide bound to CDK6 are reported. The complex was modeled from CDK6-p16INK4a X-ray crystal structure and through molecular dynamics. Final structure was assessed by comparing computed binding free energy changes, when single-alanine substitutions were brought about on the peptide, to experimental data. Better concordance was obtained when including a high level of solvation effects. Solute-solvent vdW energy and electrostatic energy between solute and first shells of water, computed through a force field and considering explicit waters, were also to be included to achieve reasonably good concordance between theoretical and experimental data.     

Phenotype‐rescue of cyclin‐dependent kinase inhibitor p16/INK4A defects in a spontaneous canine cell model of breast cancer

Mammary cancer is among the most frequently observed canine tumors in unspayed female dogs resulting in death due to metastatic disease. These tumors are excellent models of human breast cancer but until recently there was only anecdotal evidence regarding underlying genetic defects. We recently reported expression defects in the cyclin‐dependent kinase p21/Cip1 and p53 among three independent canine mammary tumor (CMT) cell lines derived from spontaneous canine mammary cancers. We investigated further defects in the same three cell lines focusing on additional tumor suppressor gene defects in cyclin‐dependent kinase inhibitors. p27/KIP1 appeared normally expressed and did not appear to encode inactivating mutations. In contrast, expression of p16/INK4A was defective/absent in two cell lines and normal/slightly induced in the third cell line. To determine if defects were causative in maintaining the transformed phenotype, a p16/INK4A transgene was permanently transfected followed by selection and single cell cloning. CMT/p16 clones were characterized for transgene expression, p16 protein content and phenotype including proliferation rate, cell cycle phase distribution, contact inhibition, substrate dependent cell growth and cell morphology. All cell lines appeared unique yet clear indications of phenotype rescue due to p16/INK4A transgene complementation were observed suggesting that defects in p16 expression were present in all three. In some cases cellular senescence also appeared to be induced. These data provide evidence supporting p16/INK4A mutations as causative defects promoting transformation in canine mammary cancer and further characterizes tumor suppressor gene defects with functional consequences in these cells supporting their application as spontaneous animal models of human disease. J. Cell. Biochem. 106: 491–505, 2009. © 2009 Wiley‐Liss, Inc.     

Multifaceted regulation of cell cycle progression by estrogen: regulation of Cdk inhibitors and Cdc25A independent of cyclin D1-Cdk4 function

Estrogens induce proliferation of estrogen receptor (ER)-positive MCF-7 breast cancer cells by stimulating G(1)/S transition associated with increased cyclin D1 expression, activation of cyclin-dependent kinases (Cdks), and phosphorylation of the retinoblastoma protein (pRb). We have utilized blockade of cyclin D1-Cdk4 complex formation through adenovirus-mediated expression of p16(INK4a) to demonstrate that estrogen regulates Cdk inhibitor expression and expression of the Cdk-activating phosphatase Cdc25A independent of cyclin D1-Cdk4 function and cell cycle progression. Expression of p16(INK4a) inhibited G(1)/S transition induced in MCF-7 cells by 17-beta-estradiol (E(2)) with associated inhibition of both Cdk4- and Cdk2-associated kinase activities. Inhibition of Cdk2 activity was associated with delayed removal of Cdk-inhibitory activity in early G(1) and decreased cyclin A expression. Cdk-inhibitory activity and expression of both p21(Cip1) and p27(Kip1) was decreased, however, in both control and p16(INK4a)-expressing cells 20 h after estrogen treatment. Expression of Cdc25A mRNA and protein was induced by E(2) in control and p16(INK4a)-expressing MCF-7 cells; however, functional activity of Cdc25A was inhibited in cells expressing p16(INK4a). Inhibition of Cdc25A activity in p16(INK4a)-expressing cells was associated with depressed Cdk2 activity and was reversed in vivo and in vitro by active Cdk2. Transfection of MCF-7 cells with a dominant-negative Cdk2 construct inhibited the E(2)-dependent activation of ectopic Cdc25A. Supporting a role for Cdc25A in estrogen action, antisense CDC25A oligonucleotides inhibited estrogen-induced Cdk2 activation and DNA synthesis. In addition, inactive cyclin E-Cdk2 complexes from p16(INK4a)-expressing, estrogen-treated cells were activated in vitro by treatment with recombinant Cdc25A and in vivo in cells overexpressing Cdc25A. The results demonstrate that functional association of cyclin D1-Cdk4 complexes is required for Cdk2 activation in MCF-7 cells and that Cdk2 activity is, in turn, required for the in vivo activation of Cdc25A. These studies establish Cdc25A as a growth-promoting target of estrogen action and further indicate that estrogens independently regulate multiple components of the cell cycle machinery, including expression of p21(Cip1) and p27(Kip1).     

The atr protein kinase controls UV-dependent upregulation of p16INK4A through inhibition of Skp2-related polyubiquitination/degradation

The tumor suppressor p16(INK4A), a phosphoprotein that exists in human cells under both phosphorylated and nonphosphorylated forms, plays crucial roles during the cellular response to UV light. However, it is still unclear how this protein is activated in response to this carcinogenic agent. We have shown here that UVC upregulates p16(INK4A) and the phosphorylated form of the protein at the 4 serine sites; Ser-7, Ser-8, Ser-140, and Ser-152. This accumulation of p16(INK4A) occurred through increasing the stability of both forms of the protein. Importantly, phospho-p16(INK4A) showed much higher stability, and UV treatment strongly increased its level in absence of de novo protein synthesis. Furthermore, we have shown that the UV-dependent upregulation of both forms of p16(INK4A) is under the control of the protein kinase Atr, which suppresses their UVC-dependent proteasomal degradation. Interestingly, although this degradation is ubiquitin-related for p16(INK4A) through the Skp2 ubiquitin ligase protein, it is ubiquitin-independent for the phosphorylated form. In addition, we present clear evidence that Skp2 is upregulated in ATR-deficient cells, leading to the downregulation of the p27(Kip1) protein in response to UVC light. Moreover, we have shown a preferential association of endogeneous phospho-p16(INK4A) with Cdk4. This association increased following UV-treatment mainly for p16(INK4A) phosphorylated at Ser-140 and Ser-152. Besides, we have shown that Atr regulates UV-related p16/Cdk4-dependent and -independent phosphorylation of pRB and G1 cell cycle delay. Together, these results indicate that p16(INK4A) and p27(Kip1) are key targets in the Atr-dependent signaling pathway in response to UV damage.     

The N-terminal peptide of the Kaposi's sarcoma-associated herpesvirus (KSHV)-cyclin determines substrate specificity

Cyclin-dependent kinases (Cdks) are activated by cyclin binding and phosphorylation by the Cdk-activating kinase (CAK). Activation of Cdk6 by the D-type cyclins requires phosphorylation of Cdk6 by CAK on threonine 177. In contrast, Cdk6 is activated by the Kaposi's sarcoma-associated herpesvirus (KSHV)-cyclin in the absence and presence of CAK phosphorylation. The activity of Cdk6.KSHV-cyclin complexes was investigated here by analyzing mutants of the KSHV-cyclin and Cdk6 in vitro as well as in U2OS cells. Deletion of the N terminus of the KSHV-cyclin affects the substrate specificity indicating that the N terminus is required for phosphorylation of histone H1 but not for other substrates. Mutation of residues in the region 180-200 of the KSHV-cyclin decreases the binding affinity to Cdk6 in U2OS cells but increases the activity of Cdk6.KSHV-cyclin complexes in vitro indicating that low affinity binding of cyclins to the Cdk subunit might favor increased on- or off-rates of Cdk substrates. Expression of high levels of p16(INK4a) in cells leads to the formation of a heterotrimeric complex composed of Cdk6, KSHV-cyclin, and p16(INK4a). Some of the Cdk6 .KSHV-cyclin.p16 complexes were found to be active indicating that there might be different modes of p16 binding to Cdk6.cyclin complexes.     

An NF-kappaB-specific inhibitor, IkappaBalpha, binds to and inhibits cyclin-dependent kinase 4

IkappaBalpha, a protein composed of six ankyrin repeats, is a specific inhibitor of nuclear factor kappaB (NF-kappaB) and functions in signal transductions in many different cell types. Using both in vivo yeast two-hybrid assays and in vitro activity and binding assays, we showed that IkappaBalpha binds to cyclin-dependent kinase 4 (CDK4) specifically and inhibits its kinase activity. The potencies of binding and inhibition of IkappaBalpha are comparable to those of INK4 proteins, the specific CDK4 inhibitors that also contain ankyrin repeats. Furthermore, we showed that INK4 proteins and IkappaBalpha compete with each other for binding to CDK4. These results led us to propose a hypothesis that there is cross talk between the NF-kappaB/IkappaBalpha pathway and the p16/CDK4/Rb pathway in cells, and that IkappaBalpha could substitute for the CDK4-inhibiting function of p16, a tumor suppressor frequently inactivated in human tumors. To further understand the structural basis of IkappaBalpha-CDK binding, we used different mutants of CDK4 to show that there are notable differences between IkappaBalpha and INK4 proteins in CDK4 binding since the binding is affected differently by different CDK4 mutations. We also demonstrated that the interaction of IkappaBalpha with CDK4 is different from that with its NF-kappaB. While most of the contacts contributing to NF-kappaB binding are located within the last two C-terminal ankyrin repeats and the loop region bridging them, the first four ankyrin repeats at the N-terminus are responsible for CDK4 binding and inhibition.     

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.     

INK4a/ARF: a multifunctional tumor suppressor locus

The INK4a/ARF locus encodes two physically linked tumor suppressor proteins, p16(INK4a) and ARF, which regulate the RB and p53 pathways, respectively. The unusual genomic relationship of the open reading frames of these proteins initially fueled speculation that only one of the two was the true tumor suppressor, and loss of the other merely coincidental in cancer. Recent human and mouse genetic data, however, have firmly established that both proteins possess significant in vivo tumor suppressor activity, although there appear to be species- and cell-type specific differences between the two. For example, ARF plays a clear role in preventing Myc-induced lymphomagenesis in mice, whereas the role for p16(INK4a) is human carcinomas is more firmly established. In this review, I discuss the evolutionary history of the locus, the relative importance of these tumor suppressor genes in human cancer, and recent information suggesting novel biochemical and physiologic functions of these proteins in vivo.     

Mutations in the INK4a/ARF melanoma susceptibility locus functionally impair p14ARF

The INK4a/ARF locus encodes two cell cycle regulatory proteins, the cyclin-dependent kinase inhibitor, p16(INK4a), and the p53 activator, p14(ARF). Germline mutations in this locus are associated with melanoma susceptibility in 20-40% of multiple case melanoma families. Many of these mutations specifically impair p16(INK4a), whereas mutations uniquely targeting p14(ARF) are rare. Nevertheless, the importance of p14(ARF) has not been excluded because more than 40% of INK4a/ARF alterations affect p16(INK4a) and p14(ARF). We now report that p14(ARF) is functionally impaired in melanoma kindreds carrying INK4a/ARF mutations. Of the seven INK4a/ARF mutations tested, three altered the subcellular distribution of p14(ARF) and diminished the ability of p14(ARF) to activate the p53 pathway. This work establishes the importance of p14(ARF) in melanoma predisposition.