An Overview of Candidate Therapeutic Target Genes in Ovarian Cancer.

Ovarian cancer (OC) shows the highest mortality rate among gynecological malignancies and, because of the absence of specific symptoms, it is frequently diagnosed at an advanced stage, mainly due to the lack of specific and early biomarkers, such as those based on cancer molecular signature identification. Indeed, although significant progress has been made toward improving the clinical outcome of other cancers, rates of mortality for OC are essentially unchanged since 1980, suggesting the need of new approaches to identify and characterize the molecular mechanisms underlying pathogenesis and progression of these malignancies. In addition, due to the low response rate and the high frequency of resistance to current treatments, emerging therapeutic strategies against OC focus on targeting single factors and pathways specifically involved in tumor growth and metastasis. To date, loss-of-function screenings are extensively applied to identify key drug targets in cancer, seeking for more effective, disease-tailored treatments to overcome lack of response or resistance to current therapies. We review here the information relative to essential genes and functional pathways recently discovered in OC, often strictly interconnected with each other and representing promising biomarkers and molecular targets to treat these malignancies.

Identification of a novel truncating mutation in PALB2 gene by a multigene sequencing panel for mutational screening of breast cancer risk-associated and related genes.

BACKGROUND: Breast cancer (BC) is the most common neoplasm in women, with 5%-10% patients showing a familial predisposition, where germline mutations in BRCA1/BRCA2 genes are found in -20% of cases. Next-generation sequencing (NGS) is among the best available options for genetic screening, providing several benefits that include enhanced sensitivity and unbiased mutation detection. PALB2 (partner and localizer of BRCA2) is a cancer predisposing gene recently described that encodes a protein partner of BRCA2 involved in DNA double-strand break repair and cell cycle control. The DNA damage response represents a key cellular event, targeted by innovative anticancer therapies, including those based on poly (ADP-ribose) polymerase (PARP) inhibitors targeting PARP1 and PARP2 enzymes, activated by DNA damage and involved in single-strand break and base excision repair. METHODS: Genomic DNA was isolated from 34 patient samples and four BC cell lines, as controls, and 27 breast cancer predisposing genes belonging to the BRCA1/BRCA2 and PARP pathways were sequenced by NGS. RESULTS: The panel described here allowed identification of several sequence variations in most investigated genes, among which we found a novel truncating mutation in PALB2. CONCLUSIONS: The NGS-based strategy designed here for molecular analysis of a customized panel of BC predisposing and related genes was found to perform effectively, providing a comprehensive exploration of all genomic sequences of the investigated genes. It is thus useful for BC molecular diagnosis, in particular for familiar cases where alterations in routinely investigated genes, such as BRCAs, result to be absent.

The nuclear receptor ERß engages AGO2 in regulation of gene transcription, RNA splicing and RISC loading.

BACKGROUND: The RNA-binding protein Argonaute 2 (AGO2) is a key effector of RNA-silencing pathways It exerts a pivotal role in microRNA maturation and activity and can modulate chromatin remodeling, transcriptional gene regulation and RNA splicing. Estrogen receptor beta (ERß) is endowed with oncosuppressive activities, antagonizing hormone-induced carcinogenesis and inhibiting growth and oncogenic functions in luminal-like breast cancers (BCs), where its expression correlates with a better prognosis of the disease. RESULTS: Applying interaction proteomics coupled to mass spectrometry to characterize nuclear factors cooperating with ERß in gene regulation, we identify AGO2 as a novel partner of ERß in human BC cells. ERß-AGO2 association was confirmed in vitro and in vivo in both the nucleus and cytoplasm and is shown to be RNA-mediated. ChIP-Seq demonstrates AGO2 association with a large number of ERß binding sites, and total and nascent RNA-Seq in ERß + vs ERß - cells, and before and after AGO2 knock-down in ERß + cells, reveals a widespread involvement of this factor in ERß-mediated regulation of gene transcription rate and RNA splicing. Moreover, isolation and sequencing by RIP-Seq of ERß-associated long and small RNAs in the cytoplasm suggests involvement of the nuclear receptor in RISC loading, indicating that it may also be able to directly control mRNA translation efficiency and stability. CONCLUSIONS: These results demonstrate that AGO2 can act as a pleiotropic functional partner of ERß, indicating that both factors are endowed with multiple roles in the control of key cellular functions.

Characterization of two de novoKCNT1 mutations in children with malignant migrating partial seizures in infancy.

The KCNT1 gene encodes for subunits contributing to the Na(+)-activated K(+) current (KNa), expressed in many cell types. Mutations in KCNT1 have been found in patients affected with a wide spectrum of early-onset epilepsies, including Malignant Migrating Partial Seizures in Infancy (MMPSI), a severe early-onset epileptic encephalopathy characterized by pharmacoresistant focal seizures migrating from one brain region or hemisphere to another and neurodevelopment arrest or regression, resulting in profound disability. In the present study we report identification by whole exome sequencing (WES) of two de novo, heterozygous KCNT1 mutations (G288S and, not previously reported, M516V) in two unrelated MMPSI probands. Functional studies in a heterologous expression system revealed that channels formed by mutant KCNT1 subunits carried larger currents when compared to wild-type KCNT1 channels, both as homo- and heteromers with these last. Both mutations induced a marked leftward shift in homomeric channel activation gating. Interestingly, the KCNT1 blockers quinidine (3-1000µM) and bepridil (0.03-10µM) inhibited both wild-type and mutant KCNT1 currents in a concentration-dependent manner, with mutant channels showing higher sensitivity to blockade. This latter result suggests two genotype-tailored pharmacological strategies to specifically counteract the dysfunction of KCNT1 activating mutations in MMPSI patients.

Thymidine kinase-mediated shut down of bone morphogenetic protein-4 expression allows regulated bone production.

Bone morphogenetic Proteins (BMPs) are growth factors also involved in ossification and chondrogenesis that have generated interest for their efficiency in inducing bone neo-synthesis. BMPs expression in engineered cells has been successful in stimulating osteoblastic differentiation and ectopic and orthotopic bone formation in vivo. We have previously shown that an adenoviral vector expressing bone morphogenetic protein type-4 (BMP-4) is able to efficiently drive bone formation in a rabbit model of discontinuous bone lesions. However, unregulated secretion of BMPs has also been implicated in bone overproduction and exostosis. We have constructed a replication-defective first generation adenoviral (FG-Ad) vector containing a cassette for the expression of BMP-4 associated with the Herpes Simplex virus thymidine kinase (TK) gene (FG-B4TK) in order to shut down BMP-4 expression and, therefore, regulate bone production. TK expression does not interfere with BMP-4 ability to induce ectopic bone formation in athymic nude mice. Administration of ganciclovir blocks ectopic bone production in quadriceps muscle transduced with the FG-B4TK with no effect on the contralateral muscle transduced with a vector expressing only BMP-4. Histological findings confirmed the pro-apoptotic activity of TK and the reduction of mineralized areas in the quadriceps transduced with FG-B4TK in mice treated with ganciclovir. We have generated a system to block BMP-4 secretion by inducing apoptosis in transduced cells therefore blocking unwanted bone formation. This system is an additional tool to generate regulated amount of bone in discontinuous bone lesions and can be easily coupled with biomaterials capable of recruiting cells and generating a local bioreactor.