Coordination of signalling networks and tumorigenic properties by ABL in glioblastoma cells.

The cytoplasmic tyrosine kinase ABL exerts positive or negative effects in solid tumours according to the cellular context, thus functioning as a "switch modulator". The therapeutic effects of drugs targeting a set of signals encompassing ABL have been explored in several solid tumours. However, the net contribution of ABL inhibition by these agents remains elusive as these drugs also act on other signalling components. Here, using glioblastoma (GBM) as a cellular paradigm, we report that ABL inhibition exacerbates mesenchymal features as highlighted by down-regulation of epithelial markers and up-regulation of mesenchymal markers. Cells with permanent ABL inhibition exhibit enhanced motility and invasive capabilities, while proliferation and tumorigenic properties are reduced. Intriguingly, permanent ABL inhibition also interferes with GBM neurosphere formation and with expression of stemness markers in sphere-cultured GBM cells. Furthermore, we show that the molecular and biological characteristics of GBM cells with impaired ABL are reversible by restoring ABL levels, thus uncovering a remarkable plasticity of GBM cells to ABL threshold. A phospho-signalling screen revealed that loss of tumorigenic and self-renewal properties in GBM cells under permanent ABL inhibition coincide with drastic changes in the expression and/or phosphorylation levels of multiple signalling components. Our findings identify ABL as a crucial player for migration, invasion, proliferation, tumorigenic, and stem-cell like properties of GBM cells. Taken together, this work supports the notion that the oncogenic role of ABL in GBM cells is associated with its capability to coordinate a signalling setting that determines tumorigenic and stem-cell like properties.

Adrenomedullin blockade suppresses growth of human hormone-independent prostate tumor xenograft in mice.

PURPOSE: To study the role of the adrenomedullin system [adrenomedullin and its receptors (AMR), CLR, RAMP2, and RAMP3] in prostate cancer androgen-independent growth. EXPERIMENTAL DESIGN: Androgen-dependent and -independent prostate cancer models were used to investigate the role and mechanisms of adrenomedullin in prostate cancer hormone-independent growth and tumor-associated angiogenesis and lymphangiogenesis. RESULTS: Adrenomedullin and AMR were immunohistochemically localized in the carcinomatous epithelial compartment of prostate cancer specimens of high grade (Gleason score >7), suggesting a role of the adrenomedullin system in prostate cancer growth. We used the androgen-independent Du145 cells, for which we demonstrate that adrenomedullin stimulated cell proliferation in vitro through the cAMP/CRAF/MEK/ERK pathway. The proliferation of Du145 and PC3 cells is decreased by anti-adrenomedullin antibody (αAM), supporting the fact that adrenomedullin may function as a potent autocrine/paracrine growth factor for prostate cancer androgen-independent cells. In vivo, αAM therapy inhibits the growth of Du145 androgen-independent xenografts and interestingly of LNCaP androgen-dependent xenografts only in castrated animals, suggesting strongly that adrenomedullin might play an important role in tumor regrowth following androgen ablation. Histologic examination of αAM-treated tumors showed evidence of disruption of tumor vascularity, with depletion of vascular as well as lymphatic endothelial cells and pericytes, and increased lymphatic endothelial cell apoptosis. Importantly, αAM potently blocks tumor-associated lymphangiogenesis, but does not affect established vasculature and lymphatic vessels in normal adult mice. CONCLUSIONS: We conclude that expression of adrenomedullin upon androgen ablation in prostate cancer plays an important role in hormone-independent tumor growth and in neovascularization by supplying/amplifying signals essential for pathologic neoangiogenesis and lymphangiogenesis. Clin Cancer Res; 19(22); 6138-50. ©2013 AACR.

Spatiotemporal distribution of tenascin-R in the developing human cerebral cortex parallels neuronal migration.

Tenascin-R is an extracellular matrix glycoprotein that is restricted to the central nervous system, where it acts as a multifunctional and versatile molecule. We report spatial and temporal distribution of tenascin-R in the developing human cerebral cortex for the first time. At 7.5 gestational weeks (GW), tenascin-R was expressed in a restricted area of the basal telencephalon. At 9.5 and 11 GW, it showed a unique double band expression pattern that delineated the boundaries of the future cortical plate. From 14 to 30 GW, tenascin-R labeling extended to the whole cortex from the deep layers toward the marginal zone with an inside-to-outside progression pattern reminiscent of neuronal migration. Moreover, tenascin-R labeling initially appeared in the form of thin, straight, or slightly tortuous intercellular processes directed toward the surface in parallel with the axis of neuronal migration. At the end of pregnancy and at adulthood, diffuse and homogeneous immunolabeling of the whole cortex thickness was observed. The striatum and thalamus were faintly positive for TNR as early as 14 GW, and this positivity intensified with brain maturation. At all developmental stages, the germinative zone, the corpus callosum, the anterior commissure, and the internal capsule appeared clearly negative for tenascin-R immunostaining whereas the adjacent parenchyma was immunopositive. Our results show that tenascin-R expression is tightly regulated in a spatiotemporal manner during brain development, especially cortical plate formation. Its pattern of expression suggests a role for tenascin-R in corticogenesis.

A2B5 cells from human glioblastoma have cancer stem cell properties.

Glioblastomas, like other cancers, harbor small cell populations with the capability of sustaining tumor formation. These cells are referred to as cancer stem cells. We isolated cells expressing the surface marker A2B5 from three human glioblastomas (GBM) and showed that after grafting into nude mice, they generated dense and highly infiltrative tumors. Then, we extensively studied A2B5(+) cells isolated from 11 human GBM. These cells display neurosphere-like, self-renewal, asymmetrical cell division properties and have multipotency capability. Stereotactic xenografts of dissociated A2B5(+)-derived secondary spheres revealed that as few as 1000 cells produced a tumor. Moreover, flow cytometry characterization of A2B5(+)-derived spheres revealed three distinct populations of cells: A2B5(+)/CD133(+), A2B5(+)/CD133(-) and A2B5(-)/CD133(-), with striking proportion differences among GBM. Both A2B5(+)/CD133(+) and A2B5(+)/CD133(-) cell fractions displayed a high proliferative index, the potential to generate spheres and produced tumors in nude mice. Finally, we generated two green fluorescent protein-cell lines that display--after serum induction--distinct proliferative and migratory properties, and differ in their CD133 level of expression. Taken together, our results suggest that transformed A2B5(+) cells are crucial for the initiation and maintenance of GBM, although CD133 expression is more involved in determining the tumor's behavior.

High expression of cathepsin B and plasminogen activator inhibitor type-1 are strong predictors of survival in glioblastomas.

In contrast to pilocytic astrocytomas (WHO grade I gliomas) that are circumscribed and cured by surgical resection, invasion is a hallmark of grades II-IV gliomas. Proteases play a major role in the invasion process and correlations between glioma grading, survival and protease expression have been demonstrated. In this study, we have chosen to study using different technical approaches (Q-RT-PCR, in situ hybridization and immunohistochemistry) the expression of five molecules involved in extracellular matrix degradation (cathepsin B, MMP2, MMP9, uPA and PAI-1) in glioblastomas in order to determine their prognostic impact among grade IV gliomas. Pilocytic astrocytomas were used as controls. Q-RT-PCR showed that transcripts of uPA, PAI-1, cathepsin B and MMP9 were significantly more expressed in glioblastomas (n = 52), in comparison to pilocytic astrocytomas (n = 17) (P = 0.049, P < 0.0001, P = 0.03 and P < 0.0001, respectively). On both univariate and multivariate analyses, cathepsin B and PAI-1 were strong predictors of overall survival among the group of glioblastomas (P < 0.0001 and P = 0.01, respectively). Immunohistochemical expression of cathepsin B further confirmed its prognostic value in an independent cohort of patients with glioblastoma. In situ hybridization showed that uPA is detected at the invasive edge of glioblastomas, whereas PAI-1 is more abundant in microvascular proliferation and pseudo-palisading cells than at the infiltrative edges. These results suggest that cathepsin B and PAI-1 are important biomarkers for the stratification of glioblastoma patients with respect to survival.

BMP4-BMPR1A signaling in beta cells is required for and augments glucose-stimulated insulin secretion.

Impaired glucose-stimulated insulin secretion (GSIS) and perturbed proinsulin processing are hallmarks of beta cell dysfunction in type 2 diabetes. Signals that can preserve and/or enhance beta cell function are therefore of great therapeutic interest. Here we show that bone morphogenetic protein 4 (Bmp4) and its high-affinity receptor, Bmpr1a, are expressed in beta cells. Mice with attenuated BMPR1A signaling in beta cells show decreased expression of key genes involved in insulin gene expression, proinsulin processing, glucose sensing, secretion stimulus coupling, incretin signaling, and insulin exocytosis and develop diabetes due to impaired insulin secretion. We also show that transgenic expression of Bmp4 in beta cells enhances GSIS and glucose clearance and that systemic administration of BMP4 protein to adult mice significantly stimulates GSIS and ameliorates glucose tolerance in a mouse model of glucose intolerance. Thus, BMP4-BMPR1A signaling in beta cells plays a key role in GSIS.

[AP-HM tumour tissue bank: molecular signature of gliomas]. / Tumorothèque de l'AP-HM: cartographie moléculaire des gliomes.

The AP-HM tissue bank is the largest one in France regarding some collections, including brain tumors. This collection was used to better characterize some gliomas. In particular because some benign gliomas such as pilocytic astrocytomas (WHO grade I) can be misclassified as malignant ones such as glioblastomas (grade IV) the first aim of our study was to find accurate diagnostic markers. This was done mainly by suppressive substractive hybridization (SSH). This study also provides a restrictive list of genes selectively involved in angiogenesis and invasion, which were highly expressed in GBM. Results were confirmed by real time quantitative RT-PCR in a large cohort of patients. In addition in order to find accurate markers which can predict GBM overall survival (OS) we selected three cohorts of GBM patients with distinctive OS (short survival < 6 months, long survival > 18 months and intermediate). Quantification of a series of markers involved in angiogenesis and invasion was done as well as cDNA array analysis.

Genetic pathways to glioblastoma: a population-based study.

We conducted a population-based study on glioblastomas in the Canton of Zurich, Switzerland (population, 1.16 million) to determine the frequency of major genetic alterations and their effect on patient survival. Between 1980 and 1994, 715 glioblastomas were diagnosed. The incidence rate per 100,000 population/year, adjusted to the World Standard Population, was 3.32 in males and 2.24 in females. Observed survival rates were 42.4% at 6 months, 17.7% at 1 year, and 3.3% at 2 years. For all of the age groups, younger patients survived significantly longer, ranging from a median of 8.8 months (<50 years) to 1.6 months (>80 years). Loss of heterozygosity (LOH) 10q was the most frequent genetic alteration (69%), followed by EGFR amplification (34%), TP53 mutations (31%), p16(INK4a) deletion (31%), and PTEN mutations (24%). LOH 10q occurred in association with any of the other genetic alterations and was predictive of shorter survival. Primary (de novo) glioblastomas prevailed (95%), whereas secondary glioblastomas that progressed from low-grade or anaplastic gliomas were rare (5%). Secondary glioblastomas were characterized by frequent LOH 10q (63%) and TP53 mutations (65%). Of the TP53 mutations in secondary glioblastomas, 57% were in hotspot codons 248 and 273, whereas in primary glioblastomas, mutations were more equally distributed. G:C-->A:T mutations at CpG sites were more frequent in secondary than primary glioblastomas (56% versus 30%; P = 0.0208). This suggests that the acquisition of TP53 mutations in these glioblastoma subtypes occurs through different mechanisms.

PTEN methylation and expression in glioblastomas.

The tumor suppressor gene PTEN on chromosome 10q23.3 regulates the Akt signaling pathway and modulates cell growth and apoptosis. The PTEN gene is mutated in 20-40% of glioblastomas. In this study, we assessed whether loss of PTEN expression is also caused epigenetically. Methylation-specific PCR revealed that CpG islands of the PTEN promoter were methylated in 27 of 77 (35%) glioblastomas and in 4 of 11 (36%) glioblastoma cell lines. Only two glioblastomas showed loss of PTEN immunoreactivity in the entire biopsy; both had a missense PTEN mutation and LOH at the PTEN locus, but lacked PTEN methylation. In biopsy specimens with focal loss of PTEN expression, DNA samples extracted from microdissected foci showed PTEN methylation only in areas with loss of PTEN expression. These results suggest that PTEN methylation occurs frequently in glioblastomas and may be associated with focal loss of PTEN expression. However, the correlation between PTEN methylation, PTEN mutations, LOH at the PTEN locus, and loss of PTEN protein expression was inconsistent. Possible reasons for discrepancies between gene status and protein expression include differences in the biological effect of specific PTEN mutations and the possibility that the processed PTEN pseudogene on 9p21 is expressed in glioblastomas and co-reacts with the PTEN antibody.

AXIN1 mutations but not deletions in cerebellar medulloblastomas.

Medulloblastoma is a malignant, invasive embryonal tumour of the cerebellum which manifests preferentially in children. A subset of cases is associated with colon cancer and APC germline mutations (Turcot syndrome), and APC and beta-catenin point mutations occur in up to 10% of sporadic cases, indicating the involvement of the Wnt pathway in the development of medulloblastoma. In 39 sporadic cerebellar medulloblastomas screeened for alterations in the AXIN1 gene, another component of the Wnt pathway, we found missense AXIN1 mutations in two tumours, CCC-->TCC at codon 255 (exon 1, Pro-->Ser) and TCT-->TGT at codon 263 (exon 1, Ser-->Cys). Furthermore, the A allele at the G/A polymorphism at nucleotide 16 in intron 4 was significantly over-represented in medulloblastomas (39 cases; G 0.76 vs-A 0.24) compared to healthy individuals (86 cases; G 0.91 vs A 0.09; P=0.0027). RT-PCR revealed large deletions in the AXIN1 gene in 5/12 (42%) medulloblastomas, consistent with a previous report. However, we observed such deletions at a similar frequency also in normal brain tissue (6/12, 50%). Since there are multiple complementary, inverted sequences present in the AXIN1 gene, these large deletions may represent RT-PCR errors due to stem-loop secondary structures.