Inhibition of poly(ADP-ribosyl)ation in cancer: Old and new paradigms revisited

Inhibitors of poly(ADP-ribose) polymerases actualized the biological concept of synthetic lethality in the clinical practice, yielding a paradigmatic example of translational medicine. The profound sensitivity of tumors with germline BRCA mutations to PARP1/2 blockade owes to inherent defects of the BRCA-dependent homologous recombination machinery, which are unleashed by interruption of PARP DNA repair activity and lead to DNA damage overload and cell death. Conversely, aspirant BRCA-like tumors harboring somatic DNA repair dysfunctions (a vast entity of genetic and epigenetic defects known as “BRCAness”) not always align with the familial counterpart and appear not to be equally sensitive to PARP inhibition. The acquisition of secondary resistance in initially responsive patients and the lack of standardized biomarkers to identify “BRCAness” pose serious threats to the clinical advance of PARP inhibitors; a feeling is also emerging that a BRCA-centered perspective might have missed the influence of additional, not negligible and DNA repair-independent PARP contributions onto therapy outcome. While regulatory approval for PARP1/2 inhibitors is still pending, novel therapeutic opportunities are sprouting from different branches of the PARP family, although they remain immature for clinical extrapolation. This review is an endeavor to provide a comprehensive appraisal of the multifaceted biology of PARPs and their evolving impact on cancer therapeutics.     

Immunohistochemical detection of tankyrase 2 in human breast tumors and normal renal tissue

Tankyrase, which functions at telomeres and other cellular compartments, is thought to be a positive regulator of telomerase; its isoenzyme tankyrase 2 has been cloned as a putative cancer antigen. This pilot immunohistochemical study was designed to examine whether tumors overexpress tankyrase 2. An antibody was generated by using synthetic peptide specific for tankyrase 2 and was tested by Western blot and immunocytochemically; no cross-reaction with isoenzyme 1 was revealed. Among tissue sections, two tumors of 18 specimens were positive for tankyrase 2. Others were negative or contained barely detectable protein. The surrounding normal tissues were negative. Tankyrase 2 was also revealed in epithelial cells of a limited number of normal renal tubules, whereas other renal tissues were negative. These data suggest that tankyrase 2 is not expressed ubiquitously in human tissues. To determine whether the up-regulation of tankyrase 2 is associated with tissue regeneration and cell proliferation, we compared the activity and concentration of the enzyme in a model human embryonic kidney cell line 293 arrested by serum deprivation and restimulated with serum. The serum-starved quiescent cell culture exhibited detectable protein as did the proliferating cells; enzyme activity dramatically increased in the latter. We conclude that pathologic overexpression of tankyrase 2 in some tumors may be a result of the cancer-related adaptation of the malignant cells dependent on tankyrase activity. Under normal conditions, the protein might be up-regulated during cell differentiation and also posttranslationally in proliferating cells. This study was supported by the Russian Foundation for Basic Research (grant no. 03-04-48835, principal investigator A.N. Kuimov)     

A novel yeast cell-based screen identifies flavone as a tankyrase inhibitor

The telomere-associated protein tankyrase 1 is a poly(ADP-ribose) polymerase and is considered to be a promising target for cancer therapy, especially for BRCA-associated cancers. However, an efficient assay system for inhibitor screening has not been established, mainly due to the difficulty of efficient preparation of the enzyme and its substrate. Here, we report a cell-based assay system for detecting inhibitory activity against tankyrase 1. We found that overexpression of the human tankyrase 1 gene causes a growth defect in the fission yeast Schizosaccharomyces pombe. Chemicals that restore the growth defect phenotype can be identified as potential tankyrase 1 inhibitors. We performed a high-throughput screen using this system, and identified flavone as a compound that restores the growth of yeast cells overexpressing tankyrase 1. Indeed, flavone inhibited poly(ADP-ribosyl)ation of proteins caused by overexpression of tankyrase 1 in yeast cells. This system allows rapid identification of inhibitory activity against tankyrase 1 and is amenable to high-throughput screening using robotics.     

Tankyrase function at telomeres, spindle poles, and beyond

Telomeres have special needs; they require distinct mechanisms for their protection, replication, and separation at mitosis. A dedicated six-subunit protein complex termed shelterin attends to these needs. But shelterin cannot do it alone and often relies on recruits from other cellular locales. One such recruit is tankyrase 1, a poly(ADP-ribose) polymerase that is brought to telomeres by the shelterin DNA binding subunit TRF1, where it functions in telomere length regulation and sister chromatid separation. An understanding of how tankyrase 1 functions at telomeres has been confounded by its complexity; it localizes to multiple subcellular sites, it has many diverse binding partners, and it has a closely related homolog (tankyrase 2) with which it may functionally overlap. This review summarizes our current knowledge of tankyrases focusing on their localization, binding partners, and function.     

ATM controls proper mitotic spindle structure

The recessive ataxia-telangiectasia (A-T) syndrome is characterized by cerebellar degeneration, immunodeficiency, cancer susceptibility, premature aging, and insulin-resistant diabetes and is caused by loss of function of the ATM kinase, a member of the phosphoinositide 3-kinase–like protein kinases (PIKKs) family. ATM plays a crucial role in the DNA damage response (DDR); however, the complexity of A-T features suggests that ATM may regulate other cellular functions. Here we show that ATM affects proper bipolar mitotic spindle structure independently of DNA damage. In addition, we find that in mitosis ATM forms a complex with the poly(ADP)ribose (PAR) polymerase Tankyrase (TNKS) 1, the spindle pole protein NuMA1, and breast cancer susceptibility protein BRCA1, another crucial DDR player. Our evidence indicates that the complex is required for efficient poly(ADP)ribosylation of NuMA1. We find further that a mutant NuMA1 version, non-phosphorylatable at potential ATM-dependent phosphorylation sites, is poorly PARylated and induces loss of spindle bipolarity. Our findings may help to explain crucial A-T features and provide further mechanistic rationale for TNKS inhibition in cancer therapy.     

Modulating the wnt signaling pathway with small molecules

Wnt signaling is a critical component during embryonic development and also plays an important role in regulating adult tissue homeostasis. Abnormal activation of Wnt signaling has been implicated in many cancers, while reduced activity of Wnt signaling leads to poor wound healing and structural formations. Thus, extensive efforts have been focused on developing small molecules that have potential to either inhibit or activate the pathway, hoping these molecules can offer leads for novel approaches in treating different human diseases. Many small‐molecule inhibitors specifically target various elements, such as Frizzled, Disheveled, Porcupine, or Tankyrase, within the Wnt signaling pathways. These small molecules not only have the potential to be further developed as therapeutic reagents, but they may also be used as chemical probes to dissect the underlying mechanism of the Wnt signaling pathways. Therefore, their respective mechanisms and effective dosages are highly pertinent. Aiming to provide an overview of those molecules in a concise, easy‐to‐use manner, we summarize and organize the current research on them so that it may be helpful for utilization in different studies.     

Mitotic phosphorylation of tankyrase, a PARP that promotes spindle assembly, by GSK3

The assembly and function of mitotic spindles require poly(ADP-ribosyl)ation of spindle components by tankyrase, a poly(ADP-ribose) polymerase that aggregates to spindle poles during mitosis. Tankyrase itself is phosphorylated during mitosis, but the kinases involved remain undefined. Herein we report that mitotic phosphorylation of tankyrase is abrogated in cells treated with the GSK3 inhibitors LiCl and indirubin. Moreover, the electrophoretic mobility-shift of tankyrase arising from mitotic phosphorylation can be reproduced in vitro by GSK3-mediated phosphorylation. Lastly, mutagenesis study suggested that GSK3 in vitro phosphorylates tankyrase on S978, T982, S987, and S991, residues that comprise two adjacent copies of the canonical GSK3 phospho-acceptor motif [S/T]-X-X-X-[S/T]. Collectively, our data suggest that GSK3 contributes to mitotic tankyrase phosphorylation, raising the possibility that this phosphorylation might mediate some of the established roles of GSK3 in spindle assembly and mitotic progression.