Riccardo Ferracini

The tyrosine kinase encoded by the MET proto-oncogene is activated by autophosphorylation.

Protein tyrosine kinases are crucially involved in the control of cell proliferation. Therefore, the regulation of their activity in both normal and neoplastic cells has been under intense scrutiny. The product of the MET oncogene is a transmembrane receptorlike tyrosine kinase with a unique disulfide-linked heterodimeric structure. Here we show that the tyrosine kinase activity of the MET-encoded protein is powerfully activated by tyrosine autophosphorylation. The enhancement of activity was quantitated with a phosphorylation assay of exogenous substrates. It involved an increase in the Vmax of the enzyme-catalyzed phosphotransfer reaction. No change was observed in the Km (substrate). A causal relationship between tyrosine autophosphorylation and activation of the kinase activity was proved by (i) the kinetic agreement between autophosphorylation and kinase activation, (ii) the overlapping dose-response relationship for ATP, (iii) the specificity for ATP of the activation process, (iv) the phosphorylation of tyrosine residues only, in the Met protein, in the activation step, (v) the linear dependence of the activation from the input of enzyme assayed, and (vi) the reversal of the active state by phosphatase treatment. Autophosphorylation occurred predominantly on a single tryptic peptide, most likely via an intermolecular reaction. The structural features responsible for this positive modulation of kinase activity were all contained in the 45-kDa intracellular moiety of the Met protein.

IL-7 Up-Regulates TNF-α-Dependent Osteoclastogenesis in Patients Affected by Solid Tumor

Background Interleukin-7 (IL-7) is a potent regulator of lymphocyte development, which has also significant effects on bone; in fact it is a potent osteoclastogenic factor. Some human solid tumors produce high IL-7 levels, suggesting a potential IL-7 role on tumor development and progression. Methodology We studied 50 male patients affected by solid tumors, and their blood samples were collected at tumor diagnosis. PBMCs were isolated and cultured with/without IL-7 to study its influence on osteoclastogenesis. Serum and cell culture supernatant IL-7 levels were measured by ELISA. The quantitative analysis of IL-7 expression on T and B cells was performed by Real-Time PCR. Principal Findings Serum IL-7 levels were highest in osteolytic cancer patients, followed by cancer patients without bone lesions, and then healthy controls. We showed the IL-7 production in PBMC cultures and particularly in monocyte and B cell co-cultures. A quantitative analysis of IL-7 expression in T and B cells confirmed that B cells had a high IL-7 expression. In all cell culture conditions, IL-7 significantly increased osteoclastogenesis and an anti-IL-7 antibody inhibited it. We demonstrated that IL-7 supports OC formation by inducing the TNF-α production and low RANKL levels, which synergize in promoting osteoclastogenesis. Conclusions We demonstrated the presence of high serum IL-7 levels in patients with bone metastasis, suggesting the use of serum IL-7 level as a clinical marker of disease progression and of bone involvement. Moreover, we showed the capability of IL-7 to stimulate spontaneous osteoclastogenesis of bone metastatic patients and to induce osteoclastogenesis in cancer patients without bone involvement. These findings add further details to the disclosure of the mechanisms controlling bone metastasis in solid tumors.

Mechanisms of spontaneous osteoclastogenesis in cancer with bone involvement

Bone metastases represents a common cause of morbidity in patients suffering many types of cancer: breast, lung, kidney, prostate, and multiple myeloma. Osteolytic metastases often cause severe pain, pathologic fractures, hypercalcemia, spinal cord compression, and other nervecompression syndromes. Osteoclasts (OCs), cells deriving from granulocitic‐macrophagic lineage, are responsible for osteolysis, which may be reduced by inhibiting both OCs formation and activity. By studying bone osteolytic metastases mechanism in solid tumors, we report here our findings that cancer patients with bone involvement display an increase in osteoclasts precursors, compared with both healthy controls and cancer patients without bone metastases. Peripheral blood mononuclear cells (PBMCs) from patients with osteolytic lesions show osteoclastogenesis without adding M‐CSF, RANKL, or TNF‐α. However, these factors are necessary to generate OCs from healthy donors, non‐osteolytic patient PBMCs and T‐cell depleted PBMCs. OCs derived from cancer patients show more resorption pits than OCs from healthy donors and express genes involved in osteoclastogenesis. Our data show that a spontaneous osteoclastogenesis occurs in patients affected by osteolytic lesions and may be supported by factors released by T lymphocytes. These factors could give a priming to osteoclast precursors and promote osteoclastogenesis. In fact, T‐cell depleted PBMCs do not differentiate into OCs without adding M‐CSF and RANKL. Moreover, we do not obtain a higher number of OCs by increasing RANKL doses in cultures, and OCs and T lymphocytes mRNA level are detected for TNF‐α but not for RANKL. The addition of OPG to PBMCs cultures do not modify spontaneous osteoclastogenesis. A neutralizing anti‐TNF‐α antibody in unstimulated PBMC cultures of osteolytic cancer patients induces an inhibition of osteoclastogenesis. These data suggest that TNF‐α may be responsible for osteoclastogenesis in these tumors.

MET Overexpression Turns Human Primary Osteoblasts into Osteosarcomas

The MET oncogene was causally involved in the pathogenesis of a rare tumor, i.e., the papillary renal cell carcinoma, in which activating mutations, either germline or somatic, were identified. MET activating mutations are rarely found in other human tumors, whereas at higher frequencies, MET is amplified and/or overexpressed in sporadic tumors of specific histotypes, including osteosarcoma. In this work, we provide experimental evidence that overexpression of the MET oncogene causes and sustains the full-blown transformation of osteoblasts. Overexpression of MET, obtained by lentiviral vector-mediated gene transfer, resulted in the conversion of primary human osteoblasts into osteosarcoma cells, displaying the transformed phenotype in vitro and the distinguishing features of human osteosarcomas in vivo. These included atypical nuclei, aberrant mitoses, production of alkaline phosphatase, secretion of osteoid extracellular matrix, and striking neovascularization. Although with a lower tumorigenicity, this phenotype was superimposable to that observed after transfer of the MET gene activated by mutation. Both transformation and tumorigenesis were fully abrogated when MET expression was quenched by short-hairpin RNA or when signaling was impaired by a dominant-negative MET receptor. These data show that MET overexpression is oncogenic and that it is essential for the maintenance of the cancer phenotype.

A Mouse Model of Pulmonary Metastasis from Spontaneous Osteosarcoma Monitored In Vivo by Luciferase Imaging

Background Osteosarcoma (OSA) is lethal when metastatic after chemotherapy and/or surgical treatment. Thus animal models are necessary to study the OSA metastatic spread and to validate novel therapies able to control the systemic disease. We report the development of a syngeneic (Balb/c) murine OSA model, using a cell line derived from a spontaneous murine tumor. Methodology The tumorigenic and metastatic ability of OSA cell lines were assayed after orthotopic injection in mice distal femur. Expression profiling was carried out to characterize the parental and metastatic cell lines. Cells from metastases were propagated and engineered to express Luciferase, in order to follow metastases in vivo. Principal Findings Luciferase bioluminescence allowed to monitor the primary tumor growth and revealed the appearance of spontaneous pulmonary metastases. In vivo assays showed that metastasis is a stable property of metastatic OSA cell lines after both propagation in culture and luciferase trasduction. When compared to parental cell line, both unmodified and genetically marked metastatic cells, showed comparable and stable differential expression of the enpp4, pfn2 and prkcd genes, already associated to the metastatic phenotype in human cancer. Conclusions This OSA animal model faithfully recapitulates some of the most important features of the human malignancy, such as lung metastatization. Moreover, the non-invasive imaging allows monitoring the tumor progression in living mice. A great asset of this model is the metastatic phenotype, which is a stable property, not modifiable after genetic manipulation.

Bone and bone marrow pro-osteoclastogenic cytokines are up-regulated in osteoporosis fragility fractures

SummaryThis study evaluates cytokines production in bone and bone marrow of patients with an osteoporotic fracture or with osteoarthritis by real time PCR, Western blot and immunohistochemistry. We demonstrate that the cytokine pattern is shifted towards osteoclast activation and osteoblast inhibition in patients with osteoporotic fractures.IntroductionFragility fractures are the resultant of low bone mass and poor bone architecture typical of osteoporosis. Cytokines involved in the control of bone cell maturation and function are produced by both bone itself and bone marrow cells, but the roles of these two sources in its control and the amounts they produce are not clear. This study compares their production in patients with an osteoporotic fracture and those with osteoarthritis.MethodsWe evaluated 52 femoral heads from women subjected to hip-joint replacement surgery for femoral neck fractures due to low-energy trauma (37), or for osteoarthritis (15). Total RNA was extracted from both bone and bone marrow, and quantitative PCR was used to identify the receptor activator of nuclear factor kB Ligand (RANKL), osteoprotegerin (OPG), macrophage colony stimulating factor (M-CSF), transforming growth factor β (TGFβ), Dickoppf-1 (DKK-1) and sclerostin (SOST) expression. Immunohistochemistry and Western blot were performed in order to quantify and localize in bone and bone marrow the cytokines.ResultsWe found an increase of RANKL/OPG ratio, M-CSF, SOST and DKK-1 in fractured patients, whereas TGFβ was increased in osteoarthritic bone. Bone marrow produced greater amounts of RANKL, M-CSF and TGFβ compared to bone, whereas the production of DKK-1 and SOST was higher in bone.ConclusionsWe show that bone marrow cells produced the greater amount of pro-osteoclastogenic cytokines, whereas bone cells produced higher amount of osteoblast inhibitors in patients with fragility fracture, thus the cytokine pattern is shifted towards osteoclast activation and osteoblast inhibition in these patients.

Bone invading NSCLC cells produce IL-7: mice model and human histologic data

BackgroundBone metastases are a common and dismal consequence of lung cancer that is a leading cause of death. The role of IL-7 in promoting bone metastases has been previously investigated in NSCLC, but many aspects remain to be disclosed. To further study IL-7 function in bone metastasis, we developed a human-in-mice model of bone aggression by NSCLC and analyzed human bone metastasis biopsies.MethodsWe used NOD/SCID mice implanted with human bone. After bone engraftment, two groups of mice were injected subcutaneously with A549, a human NSCLC cell line, either close or at the contralateral flank to the human bone implant, while a third control group did not receive cancer cells. Tumor and bone vitality and IL-7 expression were assessed in implanted bone, affected or not by A549. Serum IL-7 levels were evaluated by ELISA. IL-7 immunohistochemistry was performed on 10 human bone NSCLC metastasis biopsies for comparison.ResultsAt 12 weeks after bone implant, we observed osteogenic activity and neovascularization, confirming bone vitality. Tumor aggressive cells implanted close to human bone invaded the bone tissue. The bone-aggressive cancer cells were positive for IL-7 staining both in the mice model and in human biopsies. Higher IL-7 serum levels were found in mice injected with A549 cells close to the bone implant compared to mice injected with A549 cells in the flank opposite to the bone implant.ConclusionsWe demonstrated that bone-invading cells express and produce IL-7, which is known to promote osteoclast activation and osteolytic lesions. Tumor-bone interaction increases IL-7 production, with an increase in IL-7 serum levels. The presented mice model of bone invasion by contiguous tumor is suitable to study bone-tumor cell interaction. IL-7 plays a role in the first steps of metastatic process.

Primary breast cancer stem-like cells metastasise to bone, switch phenotype and acquire a bone tropism signature

Background:Bone metastases represent a common and severe complication in breast cancer, and the involvement of cancer stem cells (CSCs) in the promotion of bone metastasis is currently under discussion. Here, we used a human-in-mice model to study bone metastasis formation due to primary breast CSCs-like colonisation.Methods:Primary CD44+CD24− breast CSCs-like were transduced by a luciferase-lentiviral vector and injected through subcutaneous and intracardiac (IC) routes in non-obese/severe-combined immunodeficient (NOD/SCID) mice carrying subcutaneous human bone implants. The CSCs-like localisation was monitored by in vivo luciferase imaging. Bone metastatic CSCs-like were analysed through immunohistochemistry and flow cytometry, and gene expression analyses were performed by microarray techniques.Results:Breast CSCs-like colonised the human-implanted bone, resulting in bone remodelling. Bone metastatic lesions were histologically apparent by tumour cell expression of epithelial markers and vimentin. The bone-isolated CSCs-like were CD44−CD24+ and showed tumorigenic abilities after injection in secondary mice. CD44−CD24+ CSCs-like displayed a distinct bone tropism signature that was enriched in genes that discriminate bone metastases of breast cancer from metastases at other organs.Conclusion:Breast CSCs-like promote bone metastasis and display a CSCs-like bone tropism signature. This signature has clinical prognostic relevance, because it efficiently discriminates osteotropic breast cancers from tumour metastases at other sites.

The MET oncogene transforms human primary bone‐derived cells into osteosarcomas by targeting committed osteo‐progenitors

The MET oncogene is aberrantly overexpressed in human osteosarcomas. We have previously converted primary cultures of human bone‐derived cells into osteosarcoma cells by overexpressing MET. To determine whether MET transforms mesenchymal stem cells or committed progenitor cells, here we characterize distinct MET overexpressing osteosarcoma (MET‐OS) clones using genome‐wide expression profiling, cytometric analysis, and functional assays. All the MET‐OS clones consistently display mesenchymal and stemness markers, but not most of the mesenchymal–stem cell‐specific markers. Conversely, the MET‐OS clones express genes characteristic of early osteoblastic differentiation phases, but not those of late phases. Profiling of mesenchymal stem cells induced to differentiate along osteoblast, adipocyte, and chondrocyte lineages confirms that MET‐OS cells are similar to cells at an initial phase of osteoblastic differentiation. Accordingly, MET‐OS cells cannot differentiate into adipocytes or chondrocytes, but can partially differentiate into osteogenic‐matrix‐producing cells. Moreover, in vitro MET‐OS cells form self‐renewing spheres enriched in cells that can initiate tumors in vivo. MET kinase inhibition abrogates the self‐renewal capacity of MET‐OS cells and allows them to progress toward osteoblastic differentiation. These data show that MET initiates the transformation of a cell population that has features of osteo‐progenitors and suggest that MET regulates self‐renewal and lineage differentiation of osteosarcoma cells.

Increased spontaneous osteoclastogenesis from peripheral blood mononuclear cells in phenylketonuria

SummaryPhenylketonuria (PKU) is commonly complicated by a progressive bone impairment of uncertain aetiology. The therapeutic phenylalanine (Phe)-restricted diet and the possible noxious effects of high plasma Phe concentrations on bone have previously been suggested as possible determinant factors. Since osteoclasts are involved in bone reabsorption, they could play a role in determining bone damage in PKU. The reported increased excretion of bone resorption markers in PKU patients is consistent with this hypothesis. Although different diseases characterized by bone loss have been related to increased spontaneous osteoclastogenesis from peripheral blood mononuclear cells (PBMCs), to date there is no evidence of increased osteoclast formation in PKU. In this study, we compared the spontaneous osteoclastogenesis from PBMCs in 20 patients affected by PKU with that observed in age- and sex-matched healthy subjects. Phenylketonuric patients showed the number of osteoclasts to be almost double that observed in controls (159.9 ± 79.5 and 87.8 ± 44.7, respectively; p = 0.001). Moreover, a strict direct correlation between the spontaneous osteoclastogenesis in PKU patients and the mean blood Phe concentrations in the preceding year was observed (r = 0.576; p = 0.010). An imbalance between bone formation and bone resorption might explain, at least in part, the pathogenesis of bone loss in this disease. These findings could provide new insights into the biological mechanisms underlying bone damage in PKU.