Heparanase-mediated cleavage of macromolecular heparin accelerates release of granular components of mast cells from extracellular matrices.

Heparanase cleaves macromolecular heparin in the secretory granules of connective tissue-type mast cells. We investigated roles of the cleavage under a microenvironment mimicking where the mast cells physiologically reside. A connective tissue-type mast cell line MST and mouse peritoneal cell-derived mast cells stored macromolecular heparin in the secretory granules. The cells expressing heparanase stored fragmented heparin (~10 kDa) due to heparanase-dependent cleavage of the heparin. We produced an artificial collagen-based extracellular matrix and placed the live cells or glycosaminoglycans purified from the cells in the matrix to measure the release of sulfated macromolecules into the medium. The sulfate-radiolabelled molecules from the degranulating heparanase-expressing cells and the purified glycosaminoglycans showed significantly greater release into the medium than those derived from mock cells, which was not the case in suspension culture. The mast cell granular enzyme chymase, but not ß-hexosaminidase, showed significantly greater release from the degranulating heparanase-expressing cells than from mock cells. Purified chymase mixed with fragmented heparin derived from heparanase-expressing cells showed greater release from collagen gels than the enzyme alone or mixed with macromolecular heparin derived from mock cells. We propose that the cleavage of macromolecular heparin by heparanase accelerates the release of heparin and chymase from extracellular matrices.

Evaluation of therapeutic effects of FAK inhibition in murine models of atherosclerosis.

OBJECTIVE: Therapeutic effects of focal adhesion kinase (FAK) inhibition using a small molecule inhibitor was evaluated in apolipoprotein E (apoE) knockout (KO) and low-density lipoprotein receptor (LDLr) KO mouse atherosclerosis models. RESULTS: The prevention trial consisted of an 8-week treatment with an FAK inhibitor concurrent treatment with a high fat (HF)/high cholesterol (HC) diet. The intervention trial consisted of 6- and 8-week treatment after 6- and 8-week pre-loading, respectively, of a HF/HC diet in apoE KO and LDLr KO mice, respectively. The inhibitor was admixed with a HF/HC diet and mice were given free access to the admixture. The FAK inhibitor exhibited marked inhibition against the development of the atherosclerosis in both of prevention and intervention trials at a dose of 0.03% without showing any remarkable toxic properties in biochemical examinations. These results indicated that FAK inhibition might be a possible candidate for novel therapeutic targets against atherosclerosis.

Matrix metalloproteinase inhibitor, MMI270 (CGS27023A) inhibited hematogenic metastasis of B16 melanoma cells in both experimental and spontaneous metastasis models.

Matrix metalloproteinases (MMP) have been implicated in several steps of tumor metastasis, such as invasion in the extracellular matrix, intravasation, extravasation, and growth in a distant organ site. Various synthetic MMP inhibitors have been reported to suppress tumor metastasis in animal models. However, there are few reports describing which steps in the metastasis process are most critical for inhibition by MMP inhibitors. In the experimental lung colonization model by i.v. injection of mouse B16-F10 melanoma cells, we found that the daily administration of MMI270 for 2 weeks significantly decreased the number of colonies in the lung compared with the control without affecting the size of colony. Micrometastasis was monitored day 7 post-inoculation by measuring the melanin content in the lung as well as by microscopic examination of the lung tissue sections. Even only twice administrations of MMI270 on the first day after tumor injection significantly inhibited micrometastasis in the lung. In the spontaneous metastasis model using B16-BL6 melanoma cells, lung metastasis was not affected by a continuous administration of MMI270 using a mini osmotic-pump. On the contrary, when mice were subjected to popliteal lymphadenectomy on day 7 after the cell inoculation in the footpad subdermis, the continuous administration of MMI270 significantly suppressed the lung metastasis. These results suggest that the tumor cell extravasation in the target organ is the most critical step where MMPs can play their significant role in the experimental metastasis, and that the lymphatic metastasis process is less susceptible to MMI270 than the hematogenic metastasis process in the spontaneous metastasis model.

Human breast adenocarcinoma (MDA-231) and human lung squamous cell carcinoma (Hara) do not have the ability to cause bone resorption by themselves during the establishment of bone metastasis.

Osteolysis is an important process in the establishment of bone metastasis. The role which cancer cells play in this process is not fully understood. In this study, we first established a reproducible in vivo bone metastasis model using two types of tumor cells, human breast adenocarcinoma (MDA-231) and human lung squamous cell carcinoma (Hara cells), and examined in vitro characteristics of the tumor cells. Tumor cells injected into the left heart ventricle of nude mice preferentially metastasized to bone, 6 weeks after the inoculation. Histological observation of the bone metastatic lesion showed that tumor cells invaded the bone marrow, and osteoclasts adjacent to fibroblasts were actively resorbing the bone matrix. In vitro analysis of the tumor cells showed that MDA-231 cells express cathepsin K, matrix metalloproteinase 9 (MMP-9), and membrane type-1 matrix metalloproteinase (MT1-MMP), all of which are believed to play an important role in osteoclastic bone resorption. In contrast, Hara cells do not express cathepsin K and MT1-MMP. MMP-9 was expressed at a low level. To assess the osteolytic activity of the tumor cells, an in vitro pit assay was performed. The rabbit osteoclasts formed numerous pits on a dentin slice after 18 h of incubation, whereas tumor cells by themselves did not. Taken together, we conclude that MDA-231 and Hara cells, which metastasize to the bone in vivo, do not have enough ability to achieve bone resorption by themselves, but rather achieve it through activation of fibroblast like cells and osteoclasts.

Heparanase expression in B16 melanoma cells and peripheral blood neutrophils before and after extravasation detected by novel anti-mouse heparanase monoclonal antibodies.

Degradation of extracellular matrix is associated with extravasation of metastatic tumor cells and inflammatory cells. Heparanase, the heparan sulfate-specific endo-beta-glucuronidase, is a key enzyme for the matrix degradation, yet its involvement in extravasation and invasion during pathological processes was not fully clarified in vivo. In the present study, we examined heparanase expression in mouse experimental models, lung metastasis of melanoma and skin infiltration of neutrophils. Sixteen novel monoclonal antibodies specific for mouse heparanase were established by enzyme-linked immunosorbent assay with a recombinant mouse proheparanase, immunocytochemical staining of B16F10 melanoma cells cultured in vitro, and immunoprecipitation of the lysate of heparanase transfectant cells. Heparanase expression in metastatic nodules of B16F10 melanoma cells and in neutrophils localized in the inflamed skin was immunohistochemically detected using a monoclonal antibody RIO-1 that recognized the C-terminus of mouse heparanase. Homogeneous and strong heparanase staining was observed in 46% of the lung micrometastases of B16F10 melanoma cells. The staining was intensely positive on the invasive front of larger established metastasis nodules, but it was weak or heterogeneous inside the nodules. Heparanase expression in skin-infiltrating neutrophils was examined after inducing local inflammation with croton oil. The monoclonal antibody stained a significant portion of neutrophils inside and along the blood vessels, whereas it did not stain dermal neutrophils located distant from the vasculatures. The present study strongly suggests that both melanoma cells and neutrophils transiently express heparanase before and during the invasive process in vivo.

Tumor growth inhibition by synthetic and expressed siRNA targeting focal adhesion kinase.

Focal adhesion kinase (FAK) was first identified as a viral Src substrate, and substantial experimental data have significantly correlated the elevated FAK expression in human tumor cells with an increased cell adhesion and invasion potential. However, studies investigating the role of FAK in cell proliferation have been limited. Recently, a technique known as RNA interference (RNAi) was successfully adapted to mammalian cells to decrease specifically the expression of targeted cellular genes. In this study, we investigated the role of FAK in cell proliferation, adhesion, and migration by using small interfering RNA (siRNA) technique. Firstly, we constructed a plasmid library expressing short hairpin RNAs (shRNAs) targeting FAK and selected clones substantially suppressing FAK expression in HeLa and HT1080 cells. We then studied the function of FAK in the highly invasive human prostate cancer cell line, PC3M, and mouse breast cancer cell line 4T1, by using selected shRNA clones (#40 and #42) and siRNAs chemically synthesized following the target sequences of #40 and #42. We demonstrated that the decrease of FAK protein expression by treatment with shRNA/siRNA targeting FAK inhibited cell adhesion on a fibronectin/laminin-coated plate, cell migration in a haptotactic migration assay, and cell proliferation in vitro. Furthermore, it suppressed tumor growth in vivo in heterotopic/orthotopic mice models. These results support our hypothesis that FAK plays a crucial role in tumor formation and growth in vivo by regulation of cell adhesion and proliferation by FAK-dependent signals.

Identification of genes responsible for cell migration by a library of randomized ribozymes.

Several genes appear to be associated with metastasis, but the underlying mechanisms of metastasis still remain unclear. In this study, we used a library of randomized ribozymes to identify, by inactivation of transcripts, genes involved in cell migration that is an essential aspect of metastasis. Using a chemotaxis assay, the ribozymes that inhibited cell migration were selected from the library. Among such ribozymes, we found two ribozymes that targeted and cleaved ROCK1 mRNA at independent sites. ROCK1 and ROCK2 are Rho kinases, and it has been demonstrated that they regulate the organization of the actin cytoskeleton and are responsible for cell motility and cytokinesis. The two ribozymes that specifically cleaved ROCK1 mRNA inhibited both the migration and invasion of invasive HT1080 fibrosarcoma, but neither had any effect on cell proliferation. Our analysis indicates that the ribozymes toward ROCK1 can block invasive activity but not the proliferation of HT1080 cells without having any effect on expression of ROCK2. Ribozymes identified in this study, including the ribozymes against ROCK1, might be useful in understanding the mechanisms of cell migration and metastasis.

The receptor for advanced glycation end-products (RAGE) directly binds to ERK by a D-domain-like docking site.

The receptor for advanced glycation end-products (RAGE)-mediated cellular activation through the mitogen-activated protein kinase (MAPK) cascade, activation of NF-kappaB and Rho family small G-proteins, cdc42/Rac, is implicated in the pathogenesis of inflammatory disorders and tumor growth/metastasis. However, the precise molecular mechanisms for the initiation of cell signaling by RAGE remain to be elucidated. In this study, proteins which directly bind to the cytoplasmic C-terminus of RAGE were purified from rat lung extracts using an affinity chromatography technique and identified to be extracellular signal-regulated protein kinase-1 and -2 (ERK-1/2). Their interactions were confirmed by immunoprecipitation of ERK-1/2 from RAGE-expressing HT1080 cell extracts with anti-RAGE antibody. Furthermore, the augmentation of kinase activity of RAGE-bound ERK upon the stimulation of cells with amphoterin was demonstrated by determining the phosphorylation level of myelin basic protein, an ERK substrate. In vitro binding studies using a series of C-terminal deletion mutants of human RAGE revealed the importance of the membrane-proximal cytoplasmic region of RAGE for the direct ERK-RAGE interaction. This region contained a sequence similar to the D-domain, a ERK docking site which is conserved in some ERK substrates including MAPK-interacting kinase-1/2, mitogen- and stress-activated protein kinase-1, and ribosomal S6 kinase. These data suggest that ERK may play a role in RAGE signaling through direct interaction with RAGE.

Silencing of focal adhesion kinase by tumor direct injection of small interfering RNA decreases in vivo tumor growth.

Focal adhesion kinase (FAK) is shown to be frequently correlated with malignancy of the tumor and poor prognosis of the diseases.Because FAK resides immediately downstream of the interaction of cell surface adhesion molecules and extracellular matricies, it is considered to be critical to regulate several cellular processes including growth, differentiation, adhesion, motility and apoptosis. However, the studies on the role of FAK related to cell proliferation have been limited even in vitro. Here, in order to validate the role of FAK in in vivo tumor formation and proliferation, we employed direct intratumoral injection of short hairpin RNA (shRNA) targeting FAK with cationic liposome. Using shRNAs targeting FAK selected from the constructed shRNA library for FAK and by optimization of in vivo delivery conditions, we demonstrated different patterns of the association of FAK inhibition with in vivo tumor formation/proliferation inhibition in two models, PC3M heterotopic xenograft and 4T1 orthotopic syngraft models. These observations indicated that the roles of FAK in tumorigenesis are different among the tumor species. In addition, we showed that ERK is the critical MAP kinase in the signaling pathway down stream of FAK in in vivo proliferation of 4T1 tumor cells.