Comparisons of the conformational stability of cyclin-dependent kinase (CDK) 4-interacting ankyrin repeat (AR) proteins

Distinct ankyrin repeat subdomains control VAPYRIN locations and intracellular accommodation functions during arbuscular mycorrhizal symbiosis

Over 70% of vascular flowering plants engage in endosymbiotic associations with arbuscular mycorrhizal (AM) fungi. VAPYRIN (VPY) is a plant protein that is required for intracellular accommodation of AM fungi but how it functions is still unclear. VPY has a large ankyrin repeat domain with potential for interactions with multiple proteins. Here we show that overexpression of the ankyrin repeat domain results in a vpy-like phenotype, consistent with the sequestration of interacting proteins. We identify distinct ankyrin repeats that are essential for intracellular accommodation of arbuscules and reveal that VPY functions in both the cytoplasm and nucleus. VPY interacts with two kinases, including DOES NOT MAKE INFECTIONS3 (DMI3), a nuclear-localized symbiosis signaling kinase. Overexpression of VPY in a symbiosis-attenuated genetic background results in a dmi3 -like phenotype suggesting that VPY negatively influences DMI3 function. Overall, the data indicate a requirement for VPY in the nucleus and cytoplasm where it may coordinate signaling and cellular accommodation processes.

The other side of the coin: the tumor-suppressive aspect of oncogenes and the oncogenic aspect of tumor-suppressive genes, such as those along the CCND-CDK4/6-RB axis

Although cancer-regulatory genes are dichotomized to oncogenes and tumor-suppressor gene s, in reality they can be oncogenic in one situation but tumor-suppressive in another. This dual-function nature, which sometimes hampers our understanding of tumor biology, has several manifestations: (1) Most canonically defined genes have multiple mRNAs, regulatory RNAs, protein isoforms, and posttranslational modifications; (2) Genes may interact at different levels, such as by forming chimeric RNAs or by forming different protein complexes; (3) Increased levels of tumor-suppressive genes in normal cells drive proliferation of cancer progenitor cells in the same organ or tissue by imposing compensatory proliferation pressure, which presents the dual-function nature as a cell-cell interaction. All these manifestations of dual functions can find examples in the genes along the CCND-CDK4/6-RB axis. The dual-function nature also underlies the heterogeneity of cancer cells. Gene-targeting chemotherapies, including that targets CDK4, are effective to some cancer cells but in the meantime may promote growth or progression of some others in the same patient. Redefining "gene" by considering each mRNA, regulatory RNA, protein isoform, and posttranslational modification from the same genomic locus as a "gene" may help in better understanding tumor biology and better selecting targets for different sub-populations of cancer cells in individual patients for personalized therapy.

The study of pH-dependent stability shows that the TPLH-mediated hydrogen-bonding network is important for the conformation and stability of human gankyrin

Ankyrin repeat (AR) proteins possess a distinctive modular and repetitive architecture, and their global folds are maintained by short-range interactions in terms of the primary sequence. In this work, we extended our previous study on the highly conserved TPLH tetrapeptide and investigated the impact of a solvent-exposed histidine residue on the pH-dependent stability of gankyrin, providing further insight into the contribution of the TPLH motif to the tertiary fold of AR proteins. Consisting of seven ARs, gankyrin has five histidine residues in TPLH motifs or its variants, all of which adopt a H(ε2)-tautermeric form and are shielded from solvent. By truncating the C-terminal ankyrin repeat (AR7), we exposed H177 in the (174)TPLH(177) of AR6 (the second C-terminal AR) to an aqueous environment. We showed that this truncated gankyrin mutant, namely, Gank(1-201), was well-folded at a neutral pH with a slightly lower stability with respect to gankyrin wild type (WT). However, unlike gankyrin WT, the stability of Gank(1-201) was markedly decreased together with a loss of conformation at a pH slightly below 6.0. It was rationalized that the protonation of the H177 imidazole ring triggered the disruption of the TPLH-mediated hydrogen-bonding network, which in turn led to the loss of conformation and stability. These results together with the work on Q210H mutant nicely explain that the C-terminal AR7 has a (207)TPLQ(210) variant and are in support of the notion that a string of TPLH/variant, which may arguably act like a zip lock to the elongated AR proteins via intra-/inter-repeat hydrogen-bonding, is important in maintaining the tertiary fold. Additionally, we made rational mutagenesis to introduce extra surface charge on AR7 of gankyrin and demonstrated that G214E and I219D mutations increased the stability of gankyrin while the function remained intact. Taken together, our results indicate that the TPLH-mediated hydrogen-bonding network is important for the conformation and stability of human gankyrin, and the C-terminal AR contributes to the conformational stability of gankyrin (AR proteins in general) through shielding this TPLH network from solvent as well as making the surface area more accessible to solvent.

Regulatory mechanisms of tumor suppressor P16(INK4A) and their relevance to cancer

P16(INK4A) (also known as P16 and MTS1), a protein consisting exclusively of four ankyrin repeats, is recognized as a tumor suppressor mainly because of the prevalence of genetic inactivation of the p16(INK4A) (or CDKN2A) gene in virtually all types of human cancers. However, it has also been shown that an elevated level of expression (upregulation) of P16 is involved in cellular senescence, aging, and cancer progression, indicating that the regulation of P16 is critical for its function. Here, we discuss the regulatory mechanisms of P16 function at the DNA level, the transcription level, and the posttranscriptional level, as well as their implications for the structure-function relationship of P16 and for human cancers.

Contributions of conserved TPLH tetrapeptides to the conformational stability of ankyrin repeat proteins

Ankyrin repeat (AR) proteins are one of the most abundant classes of repeat proteins and are involved in numerous physiological processes. These proteins are composed of various numbers of AR motifs stacked in a nearly linear fashion to adopt an elongated and nonglobular architecture. One salient feature prevalent in such a structural unit is the TPLH tetrapeptide or a close variant, T/SxxH, which initiates the helix-turn-helix conformation and presumably contributes to conformational stability through a hydrogen-bonding network. In the present study, we investigated the roles of T/SxxH motif in the stability, structure, and function of AR proteins by a systematic and rationalized mutagenic study on, followed by biochemical and biophysical characterization of, gankyrin, an oncogenic protein composed of seven ARs and six T/SxxH tetrapeptides, and P16, a tumor suppressor with four ARs but no TPLH tetrapeptide. Our results showed that this tetrapeptide is ineffectual on global structure and function, but contributes significantly to conformational stability when its stabilizing potentials are fully realized in the local conformation, including (1) the intra-AR hydrogen bonding involving the hydroxyl group; (2) the intra-AR and inter-AR hydrogen bonds involving the imidazole ring; and (3) the hydrophobic interaction associated with the Thr-methyl group. Considering that the capping and close-to-capping units tend to have more sequence diversity and more conformational variation, it could be also generally true that a T/SxxH motif close to the terminal repeats contributes little or even negatively to stability with respect to Ala substitution, but substantially stabilizes the global conformation when located in the middle of a long stretch of ARs.

IKKbeta specifically binds to P16 and phosphorylates Ser8 of P16

In spite of its central roles in cell cycle progression, senescence, and aging, knowledge about the posttranslational regulation of P16 (also known as INK4A and MTS1) remains limited. While it has been reported that P16 could be phosphorylated at Ser7, Ser8, Ser140, and Ser152, the corresponding kinases have not been identified yet. Here we report that IKKbeta, a primary kinase for IkappaBalpha phosphorylation, is involved in P16 phosphorylation. Immunoprecipitation and kinase assays showed that IKKbeta specifically binds to P16 and phosphorylates P16 at Ser8 in WI38 cells. Biochemical characterization of phosphomimetic Ser-->Glu P16 mutants demonstrated that phosphorylation at Ser8 of P16 brings about a significant loss of its cyclin-dependent kinase (CDK) 4-inhibitory activity while P16 retains structurally and functionally intact upon phosphorylation at Ser7, Ser140, and Ser152. Our results reveal the novel role of IKKbeta in P16 phosphorylation and broaden our understanding of the regulation of P16.

Gankyrin Oncoprotein: Structure, Function, and Involvement in Cancer

Gankyrin, a newly defined oncoprotein also known as PSMD10 and P28, functions as a dual-negative regulator of the two most prominent tumor suppressor pathways, the CDK/pRb and HDM2/P53 pathways. Its aberrant expression has been prevalently found in human hepatocellular carcinomas (HCC) and esophagus squamous cell carcinomas (ESCC), indicative of the potential of gankyrin as a rational diagnostic and therapeutic target in cancers. Here, we review the unique structural features and functional diversity of gankyrin, and discuss its implication in cancer diagnostics and therapeutics from the perspective of chemical biology.