Hung Chi Cheng

Lung Endothelial Dipeptidyl Peptidase IV Promotes Adhesion and Metastasis of Rat Breast Cancer Cells via Tumor Cell Surface-associated Fibronectin

Endothelial cell adhesion molecules are partly responsible for the distinct organ distribution of cancer metastases. Dipeptidyl peptidase IV (DPP IV) expressed on rat lung capillary endothelia is shown here to be an adhesion receptor for rat breast cancer cells and to mediate lung colonization by these tumor cells. Fibronectin (FN) assembled on breast cancer cell surfaces into multiple, randomly dispersed globules from cellular and plasma FN is identified as the principal ligand for DPP IV. Ligand expression correlates quantitatively with the tumor cells’ capabilities to bind to DPP IV and to metastasize to the lungs. DPP IV/FN-mediated adhesion and metastasis are blocked when tumor cells are incubated with soluble DPP IV prior to conducting adhesion and lung colony assays. Adhesion is also blocked by anti-DPP IV monoclonal antibody 6A3 and anti-FN antiserum. However, adhesion to immobilized FN is unaffected by soluble plasma FN and, thus, can happen during hematogenous spread of cancer cells at high plasma FN concentrations. The ability of many cancer cells to capture FN molecules on their surface and to augment such deposits by FN self-association during passage in the blood suggests that DPP IV/FN binding may be a relatively common mechanism for lung metastasis.

The Breast Cancer β4 Integrin and Endothelial Human CLCA2 Mediate Lung Metastasis

Adhesion of blood-borne cancer cells to the endothelium is a critical determinant of organ-specific metastasis. Here we show that colonization of the lungs by human breast cancer cells is correlated with cell surface expression of the α6β4 integrin and adhesion to human CLCA2 (hCLCA2), a Ca2+-sensitive chloride channel protein that is expressed on the endothelial cell luminal surface of pulmonary arteries, arterioles, and venules. Tumor cell adhesion to endothelial hCLCA2 is mediated by the β4 integrin, establishing for the first time a cell-cell adhesion property for this integrin that involves an entirely new adhesion partner. This adhesion is augmented by an increased surface expression of the α6β4 integrin in breast cancer cells selected in vivo for enhanced lung colonization but abolished by the specific cleavage of the β4 integrin with matrilysin. β4 integrin/hCLCA2 adhesion-blocking antibodies directed against either of the two interacting adhesion molecules inhibit lung colonization, while overexpression of the β4 integrin in a model murine tumor cell line of modest lung colonization potential significantly increases the lung metastatic performance. Our data clearly show that the β4/hCLCA2 adhesion is critical for lung metastasis, yet expression of the β4 integrin in many benign breast tumors shows that this integrin is insufficient to bestow metastatic competence on cells that lack invasiveness and other established properties of metastatic cells.

Cloning and characterization of lung-endothelial cell adhesion molecule- 1 suggest it is an endothelial chloride channel

Lung-endothelial cell adhesion molecule-1 (Lu-ECAM-1) is an endothelial cell surface molecule that mediates adhesion of metastatic melanoma cells to lung endothelium. Here we analyze the organization of the Lu-ECAM-1 protein complex, report the sequence of Lu-ECAM-1 cDNAs, and reveal a novel function of the protein. Lu-ECAM-1 immunopurified from bovine aortic endothelial cells (BAEC) consists of tightly associated glycoproteins of 90, 38, and 32 kDa, with minor components of 130 and 120 kDa. We present evidence that all of these protein species are encoded by a single open reading frame whose initial translation product is proteolytically processed to yield the other products. Correct processing in vitro was demonstrated by transfection of the longest cDNA into human embryonic kidney 293 cells; immunoblot analysis showed that the ∼120-kDa precursor gave rise to 90- and 38-kDa products. RNA blots of BAEC mRNA detected messages in agreement with the sizes of the cDNA clones in addition to several of high molecular weight. DNA blot analysis showed that Lu-ECAM-1 is conserved throughout its length in all mammals tested, usually as a single or low copy gene. In the bovine, Lu-ECAM-1 protein is 88% identical to a calcium-dependent chloride channel described recently in tracheal epithelium, Ca-CC. Probes for Lu-ECAM-1 mRNA and protein confirmed the presence of a homolog in this tissue. We show that messages for both proteins are present in lung while only Ca-CC is present in trachea and only Lu-ECAM-1 is present in BAEC. These results suggest that endothelial cells express a chloride channel that is related to, but distinct from, that expressed in tracheal epithelium. They further suggest that an adhesion molecule can also be a chloride channel.

Molecular characteristics and functional diversity of CLCA family members.

1. In the present brief review, we describe some of the molecular and functional characteristics of a novel mammalian family of putative Ca2+‐activated chloride channels (CLCA).

A Novel Sialyltransferase Inhibitor Suppresses FAK/Paxillin Signaling and Cancer Angiogenesis and Metastasis Pathways

Increased sialyltransferase (ST) activity promotes cancer cell metastasis, and overexpression of cell surface sialic acid correlates with poor prognosis in cancer patients. To seek therapies targeting metastasis for cancer treatment, we developed a novel ST inhibitor, Lith-O-Asp, and investigated its antimetastatic and antiangiogenic effects and mechanisms. We found that cells treated with Lith-O-Asp showed a reduction of activity on various ST enzymes by in vitro and cell-based activity analyses. Lith-O-Asp inhibited migration and invasion abilities in various cancer cell lines and showed inhibitory effect on the angiogenic activity of human umbilical vein endothelial cells. Indeed, Lith-O-Asp treatment consequently delayed cancer cell metastasis in experimental and spontaneous metastasis assays in animal models. Importantly, Lith-O-Asp decreased the sialic acid modification of integrin-β1 and inhibited the expression of phospho-FAK, phospho-paxillin, and the matrix metalloprotease (MMP) 2 and MMP9. Lith-O-Asp attenuated the Rho GTPase activity leading to actin dynamic impairment. In addition, 2DE-MS/MS and immunoblotting analyses showed that Lith-O-Asp altered the protein expression level and phosphorylation status of various proteins involved in crucial metastasis and angiogenesis pathways such as vimentin and ribonuclease/angiogenin inhibitor RNH1. Furthermore, Lith-O-Asp treatment significantly inhibited the invasive ability exerted by ectopic overexpression of various ST enzymes catalyzing α-2,6- or α-2,3-sialylation. Our results provide compelling evidence that the potential pan-ST inhibitor, Lith-O-Asp, suppressed cancer cell metastasis likely by inhibiting FAK/paxillin signaling and expressing antiangiogenesis factors. Lith-O-Asp is worthy for further testing as a novel antimetastasis drug for cancer treatment.

Secretomic Analysis Identifies Alpha-1 Antitrypsin (A1AT) as a Required Protein in Cancer Cell Migration, Invasion, and Pericellular Fibronectin Assembly for Facilitating Lung Colonization of Lung Adenocarcinoma Cells

Metastasis is a major obstacle that must be overcome for the successful treatment of lung cancer. Proteins secreted by cancer cells may facilitate the progression of metastasis, particularly within the phases of migration and invasion. To discover metastasis-promoting secretory proteins within cancer cells, we used the label-free quantitative proteomics approach and compared the secretomes from the lung adenocarcinoma cell lines CL1-0 and CL1-5, which exhibit low and high metastatic properties, respectively. By employing quantitative analyses, we identified 660 proteins, 68 of which were considered to be expressed at different levels between the two cell lines. High levels of A1AT were secreted by CL1-5, and the roles of A1AT in the influence of lung adenocarcinoma metastasis were investigated. Molecular and pathological confirmation demonstrated that altered expression of A1AT correlates with the metastatic potential of lung adenocarcinoma. The migration and invasion properties of CL1-5 cells were significantly diminished by reducing the expression and secretion of their A1AT proteins. Conversely, the migration and invasion properties of CL1-0 cells were significantly increased through the overexpression and secretion of A1AT proteins. Furthermore, the assembly levels of the metastasis-promoting pericellular fibronectin (FN1), which facilitates colonization of lung capillary endothelia by adhering to the cell surface receptor dipeptidyl peptidase IV (DPP IV), were higher on the surfaces of suspended CL1-5 cells than on those of the CL1-0 cells. This discovery reflects previous findings in breast cancer. In line with this finding, FN1 assembly and the lung colonization of suspended CL1-5 cells were inhibited when endogenous A1AT protein was knocked down using siRNA. The major thrust of this study is to demonstrate the effects of coupling the label-free proteomics strategy with the secretomes of cancer cells that differentially exhibit invasive and metastatic properties. This provides a new opportunity for the effective identification of metastasis-associated proteins that are secreted by cancer cells and promote experimental metastasis.

RUNX3-mediated transcriptional inhibition of Akt suppresses tumorigenesis of human gastric cancer cells

Activation of Akt signaling pathway has been suggested involving in chemoresistance, metastasis and tumorigenesis of gastric cancer. However, the mechanism of Akt regulation in gastric cancer is not fully understood. RUNX3, which was first identified as a transcription factor, suppresses gastric tumorigenesis through regulating expression of target genes. Here, we found that restoration of RUNX3 significantly downregulates the protein and mRNA expression of Akt1 in gastric cancer cell lines, AGS and SNU-1. Knockdown of RUNX3 upregulates protein and mRNA expression of Akt1 in normal gastric epithelial cell line, GES-1. The negative correlation of RUNX3 and Akt expression and downstream β-catenin/cyclin D1 effectors was further confirmed in AGS and GES-1 cell lines, as well as clinical specimens of gastric cancer. We identified two RUNX3-binding sites in Akt1 promoter and the binding of RUNX3 on Akt1 promoter significantly inhibits Akt1 expression. The RUNX3-mediated inhibition of Akt1 caused β-catenin protein degradation and then cyclin D1 downregulation. Restoration of cyclin D1 reverses cell growth inhibition and G1 phase arrest induced by RUNX3 in gastric cancer cells. Our results show that loss of RUNX3 expression can enhance the Akt1-mediated signaling pathway and promote the tumorigenesis process in human gastric cancer.

Protein Kinase Cϵ Mediates Polymeric Fibronectin Assembly on the Surface of Blood-borne Rat Breast Cancer Cells to Promote Pulmonary Metastasis

Malignant breast cancer cells that have entered the blood circulation from primary mammary fat pad tumors or are grown in end-over-end suspension culture assemble a characteristic, multi-globular polymeric fibronectin (polyFn) coat on their surfaces. Surface polyFn is critical for pulmonary metastasis, presumably by facilitating lung vascular arrest via endothelial dipeptidylpeptidase IV (CD26). Here, we show that cell-surface polyFn assembly is initiated by the state of suspension, is dependent upon the synthesis and secretion of cellular Fn, and is augmented in a dose- and time-dependent manner by plasma Fn. PolyFn assembly is regulated by protein kinase Cϵ (PKCϵ), which translocates rapidly and in increasing amounts from the cytosol to the plasma membrane and is phosphorylated. PolyFn assembly is impeded by select inhibitors of this kinase, i.e. bisindolylmaleimide I, Ro-32-0432, Gö6983, and Rottlerin, by the phorbol 12-myristate 13-acetate-mediated and time-dependent loss of PKCϵ protein and decreased plasma membrane translocation, and more specifically, by stable transfection of lung-metastatic MTF7L breast cancer cells with small interfering RNA-PKCϵ and dominant-negative PKCϵ constructs (e.g. RD-PKCϵ). The inability to assemble a cell surface-associated polyFn coat by knockdown of endogenous Fn or PKCϵ impedes cancer cells from metastasis to the lungs. The present studies identify a novel regulatory mechanism for polyFn assembly on blood-borne breast cancer cells and depict its effect on pulmonary metastasis.

The putative chloride channel hCLCA2 has a single C-terminal transmembrane segment

Calcium-activated chloride channel (CLCA) proteins were first described as a family of plasma membrane Cl– channels that could be activated by calcium. Genetic and electrophysiological studies have supported this view. The human CLCA2 protein is expressed as a 943-amino-acid precursor whose N-terminal signal sequence is removed followed by internal cleavage near amino acid position 680. Earlier investigations of transmembrane geometry suggested five membrane passes. However, analysis by the more recently derived simple modular architecture research tool algorithm predicts that a C-terminal 22-amino-acid hydrophobic segment comprises the only transmembrane pass. To resolve this question, we raised an antibody against hCLCA2 and investigated the synthesis, localization, maturation, and topology of the protein. Cell surface biotinylation and endoglycosidase H analysis revealed a 128-kDa precursor confined to the endoplasmic reticulum and a maturely glycosylated 141-kDa precursor at the cell surface by 48 h post-transfection. By 72 h, 109-kDa N-terminal and 35-kDa C-terminal cleavage products were detected at the cell surface but not in the endoplasmic reticulum. Surprisingly, however, the 109-kDa product was spontaneously shed into the medium or removed by acid washes, whereas the precursor and 35-kDa product were retained by the membrane. Two other CLCA family members, bCLCA2 and hCLCA1, also demonstrated preferential release of the N-terminal product. Transfer of the hCLCA2 C-terminal hydrophobic segment to a secreted form of green fluorescent protein was sufficient to target that protein to the plasma membrane. Together, these data indicate that hCLCA2 is mostly extracellular with only a single transmembrane segment followed by a short cytoplasmic tail and is itself unlikely to form a channel.

Truncated Dipeptidyl Peptidase IV Is a Potent Anti-Adhesion and Anti-Metastasis Peptide for Rat Breast Cancer Cells

A novel adhesion receptor/ligand pair was shown recently to mediate lung vascular arrest and metastasis of rat breast cancer cells. The interacting adhesion molecules are endothelial dipeptidyl peptidase IV (DPP IV) and tumor cell surface-associated, polymeric fibronectin (FN). A truncated DPP IV (DPP IV(31–767): amino acids 31–767) in which the FN-binding site is preserved is shown here to mask the breast cancer cell surface-associated FN complexes, causing a dose-dependent inhibition of adhesion to endothelial DPP IV and impeding lung colony formation by approximately 80%. Since surface accumulation of FN is chiefly occurring during dissemination in the blood and since many cancer cell types have surface receptors by which they may initiate FN accumulation on their surfaces, the present anti-metastatic treatment modality may extend its efficacy farther than appreciated by this study.