Nanoscale imaging and quantification of local proteolytic activity

Proteolytic cleavage of extracellular matrix (ECM) is a critical feature of tumor cell invasion, and affects cancer cell growth, differentiation, apoptosis, and migration. Malignant cells secrete most proteases as inactive proenzymes that undergo proteolytic cleavage for activation, and proteolytic activity is elevated in close proximity to these cells. Therefore, local activity rather than protease concentration determines ECM proteolysis. Precise quantification of local proteolytic activity, functional investigation, and high resolution imaging of morphological ECM alterations have proven difficult. In this study, we present a novel approach for measuring proteolytic activity in the microenvironment of cells by using atomic force microscopy (AFM). Amelanotic melanoma cells (A7-clone) were seeded on fluorescent gelatin or collagen-IV coatings. Proteolysis reduced fluorescence of these coatings. Fluorescence microscopy (FM) in combination with AFM was used to maneuver the AFM-tip to tumor cell induced proteolytic spots. AFM enabled nanoscale volume measurement, three-dimensional reconstruction of single proteins and demonstrated that ECM cleavage is restricted to the proteolytic microenvironment of cancer cells. This method detected significant decreases in molecular weight of protein clusters (-76.6%), matrix volume (-46.6%), and height (-38.1%) between intact and proteolyzed gelatin. Similar parameter changes were demonstrated without FM, by AFM-scanning gelatin in close proximity to invasive cells. Furthermore, AFM depicted significantly stronger local degradation of gelatin than collagen-IV by A7-cells. Taken together, AFM allows specific quantification and imaging of local proteolytic processes at a nanometer level, thus providing a unique method for the functional evaluation of invasiveness and metastatic potential of tumor cells in small scale samples.     

Autophagy,citrullination and cancer

A cell needs to maintain a balance between biosynthesis and degradation of cellular components to maintain homeostasis. There are 2 pathways, the proteasome, which degrades short-lived proteins, and the autophagy/lysosomal pathway, which degrades long-lived proteins and organelles. Both of these pathways are also involved in antigen presentation or the effective delivery of peptides to MHC molecules for presentation to T cells. Autophagy (macroautophagy) is a key player in providing substantial sources of citrullinated peptides for loading onto MHC-II molecules to stimulate CD4⁺ T cell responses. Stressful conditions in the tumor microenvironment induce autophagy in cancer cells as a mechanism to promote their survival. We therefore investigated if citrullinated peptides could stimulate CD4⁺ T cell responses that would recognize these modifications produced during autophagy within tumor cells. Focusing on the intermediate filament protein VIM (vimentin), we generated citrullinated VIM peptides for immunization experiments in mice. Immunization with these peptides induced CD4⁺ T cells in response to autophagic tumor targets. Remarkably, a single immunization with modified peptide, up to 14 d after tumor implant, resulted in long-term survival in 60% to 90% of animals with no associated toxicity. These results show how CD4⁺ cells can mediate potent antitumor responses against modified self-epitopes presented on tumor cells, and they illustrate for the first time how the citrullinated peptides produced during autophagy may offer especially attractive vaccine targets for cancer therapy.     

Phagocytized Beads Reduce the α5β1 Integrin Facilitated Invasiveness of Cancer Cells by Regulating Cellular Stiffness

Cell invasion through the extracellular matrix (ECM) of connective tissue is an important biomechanical process, which plays a prominent role in tumor progression. The malignancy of tumors depends mainly on the capacity of cancer cells to migrate and metastasize. A prerequisite for metastasis is the invasion of cancer cells through connective tissue to targeted organs. Cellular stiffness and cytoskeletal remodeling dynamics have been proposed to affect the invasiveness of cancer cells. Here, this study investigated whether highly invasive cancer cells are capable of invading into dense 3D-ECMs with an average pore-size of 1.3 or 3.0 μm when phagocytized beads (2.7 and 4.5 μm diameter) increased their cellular stiffness and reduced their cytoskeletal remodeling dynamics compared to weakly invasive cancer cells. The phagocytized beads decreased the invasiveness of the α5β1^high cancer cells into 3D-ECMs, whereas the invasiveness of the α5β1^low cancer cells was not affected. The effect of phagocytized beads on the highly invasive α5β1^high cells was abolished by specific knock-down of the α5 integrin subunit or addition of an anti-α5 integrin blocking antibody. Furthermore, the reduction of contractile forces using MLCK and ROCK inhibitors abolished the effect of phagocytized beads on the invasiveness of α5β1^high cells. In addition, the cellular stiffness of α5β1^high cells was increased after bead phagocytosis, whereas the bead phagocytosis did not alter the stiffness of α5β1^low cells. Taken together, the α5β1 integrin dependent invasiveness was reduced after bead phagocytosis by altered biomechanical properties, suggesting that the α5β1^high cells need an appropriate intermediate cellular stiffness to overcome the steric hindrance of 3D-ECMs, whereas the α5β1^low cells were not affected by phagocytized beads.     

Immunocytochemical visualization of P185HER2 receptor using antibodies fused with dibarnase and conjugate of barstar with colloidal gold

The localization of the P185^HER2 transmembrane receptor in SKOV-3 and BT-474 cancer cells was studied by fluorescence, confocal, and electron immunomicroscopy. The P185^HER2 receptor is a marker of breast and ovarian tumors; it is also considered to be a target for anticancer therapy. It is extremely important to choose a universal immunicytotoxic agent applicable, firstly, to study the distribution of P185^HER2 in cancer cells, secondarily, to remove P185^HER2 from the cell surface and, thirdly, to eliminate target cells. In this study, for visualization P185^HER2 we propose an immunocytotoxic system, which consists of monoclonal miniantibody 4D5 scFv to the extracellular P185^HER2 domain fused with two molecules of barnase (cytotoxic RNAase from Bacillus amyloliquefaciens) and its specific inhibitor, barstar. Fluorescent microscopy showed that the module 4D5 scFc-dibarnase:barstar is efficient for identifying P185^HER2 on the surfaces of cancer cells. It was found by confocal microscopy that interaction with 4D5 scFc-dibarnase results in the internalization of P185^HER2. The localization of P185^HER2 in human ovarian carcinoma cells (SKOV-3) and breast carcinoma cells (BT-474) was compared by electron microscopy using 4D5 scFv-dibarnase:barstar-Au and 4D5 scFv-dibarnase-Au complexes. P185^HER2 is distributed unequally on the cell surface with preferential localization on protrusions or close to their bases and at contacts between protrusions and the cell membrane. At 37°C, P185^HER2 is internalized through coated pits and vesicles and concentrates in endosomes and multivesicular bodies in the cells of both cell lines, as well as in lysosomes in BT-474 cells.     

In situ solid-state NMR study of antimicrobial peptide interactions with erythrocyte membranes

Antimicrobial peptides are promising therapeutic agents to mitigate the global rise of antibiotic resistance. They generally act by perturbing the bacterial cell membrane and are thus less likely to induce resistance. Because they are membrane-active molecules, it is critical to verify and understand their potential action toward eukaryotic cells to help design effective and safe drugs. In this work, we studied the interaction of two antimicrobial peptides, aurein 1.2 and caerin 1.1, with red blood cell (RBC) membranes using in situ ³¹P and ²H solid-state NMR (SS-NMR). We established a protocol to integrate up to 25% of deuterated fatty acids in the membranes of ghosts, which are obtained when hemoglobin is removed from RBCs. Fatty acid incorporation and the integrity of the lipid bilayer were confirmed by SS-NMR and fluorescence confocal microscopy. Leakage assays were performed to assess the lytic power of the antimicrobial peptides. The in situ perturbation of the ghost membranes by aurein 1.2 and caerin 1.1 revealed by ³¹P and ²H SS-NMR is consistent with membrane perturbation through a carpet mechanism for aurein 1.2, whereas caerin 1.1 acts on RBCs via pore formation. These results are compatible with fluorescence microscopy images of the ghosts. The peptides interact with eukaryotic membranes following similar mechanisms that take place in bacteria, highlighting the importance of hydrophobicity when determining such interactions. Our work bridges model membranes and in vitro studies and provides an analytical toolbox to assess drug toxicity toward eukaryotic cells.     

Identification of a novel HLA-A2-restricted cytotoxic T lymphocyte epitope from cancer-testis antigen PLAC1 in breast cancer

Identification of cytotoxic T lymphocyte (CTL) epitopes from tumor antigens is essential for the development of peptide vaccines against tumor immunotherapy. Among all the tumor antigens, the caner-testis (CT) antigens are the most widely studied and promising targets. PLAC1 (placenta-specific 1, CT92) was considered as a novel member of caner-testis antigen, which expressed in a wide range of human malignancies, most frequently in breast cancer. In this study, three native peptides and their analogues derived from PLAC1 were predicted by T cell epitope prediction programs including SYFPEITHI, BIMAS and NetCTL 1.2. Binding affinity and stability assays in T2 cells showed that two native peptides, p28 and p31, and their analogues (p28-1Y9?V, p31-1Y2L) had more potent binding activity towards HLA-A*0201 molecule. In ELISPOT assay, the CTLs induced by these four peptides could release IFN-γ. The CTLs induced by these four peptides from the peripheral blood mononuclear cells (PBMCs) of HLA-A*02⁺ healthy donor could lyse MCF-7 breast cancer cells (HLA-A*0201⁺, PLAC1⁺) in vitro. When immunized in HLA-A2.1/K^b transgenic mice, the peptide p28 could induce the most potent peptide-specific CTLs among these peptides. Therefore, our results indicated that the peptide p28 (VLCSIDWFM) could serve as a novel candidate epitope for the development of peptide vaccines against PLAC1-positive breast cancer.     

Imaging proteolysis by living human glioma cells

Degradation of basement membrane is an essential step for tumor invasion. In order to study degradation in real time as well as localize the site of proteolysis, we have established an assay with living human cancer cells in which we image cleavage of quenched-fluorescent basement membrane type IV collagen (DQ-collagen IV). Accumulation of fluorescent products is imaged with a confocal microscope and localized by optically sectioning both the cells and the matrix on which they are growing. For the studies described here, we seeded U87 human glioma cells as either monolayers or spheroids on a 3-dimensional gelatin matrix in which DQ-collagen IV had been embedded. As early as 24 hours after plating as monolayers, U87 cells were present throughout the 3-dimensional matrix. Cells at all levels had accumulated fluorescent degradation products of DQ-collagen IV intracellularly within vesicles. Similar observations were made for U87 spheroids and the individual cells migrating from the spheroids into the gelatin matrix. Both the migrating cells and those within the spheroid contained fluorescent degradation products of DQ-collagen IV intracellularly within vesicles. Thus, glioma cells like breast cancer cells are able to degrade type IV collagen intracellularly, suggesting that this is an important pathway for matrix degradation.     

Quantitative Measurement of Invadopodia-mediated Extracellular Matrix Proteolysis in Single and Multicellular Contexts

Cellular invasion into local tissues is a process important in development and homeostasis. Malregulated invasion and subsequent cell movement is characteristic of multiple pathological processes, including inflammation, cardiovascular disease and tumor cell metastasis¹. Focalized proteolytic degradation of extracellular matrix (ECM) components in the epithelial or endothelial basement membrane is a critical step in initiating cellular invasion. In tumor cells, extensive in vitro analysis has determined that ECM degradation is accomplished by ventral actin-rich membrane protrusive structures termed invadopodia^2,3. Invadopodia form in close apposition to the ECM, where they moderate ECM breakdown through the action of matrix metalloproteinases (MMPs). The ability of tumor cells to form invadopodia directly correlates with the ability to invade into local stroma and associated vascular components³. Visualization of invadopodia-mediated ECM degradation of cells by fluorescent microscopy using dye-labeled matrix proteins coated onto glass coverslips has emerged as the most prevalent technique for evaluating the degree of matrix proteolysis and cellular invasive potential^4,5. Here we describe a version of the standard method for generating fluorescently-labeled glass coverslips utilizing a commercially available Oregon Green-488 gelatin conjugate. This method is easily scaled to rapidly produce large numbers of coated coverslips. We show some of the common microscopic artifacts that are often encountered during this procedure and how these can be avoided. Finally, we describe standardized methods using readily available computer software to allow quantification of labeled gelatin matrix degradation mediated by individual cells and by entire cellular populations. The described procedures provide the ability to accurately and reproducibly monitor invadopodia activity, and can also serve as a platform for evaluating the efficacy of modulating protein expression or testing of anti-invasive compounds on extracellular matrix degradation in single and multicellular settings.     

Three-dimensional imaging of tumor angiogenesis

OBJECTIVE: To three-dimensionally visualize the microvessel environment of tumor angiogenesis by confocal laser scanning microscopy (CLSM). STUDY DESIGN: To reveal underlying mechanisms of tumor angiogenesis, a 7, 12-dimethylbenz(a) anthracene-induced rat cancer model was used. For demonstrating tumor vasculature, fluorescence injection method (FITC-conjugated gelatin solution) was employed. FITC gelatin was injected into the left ventricle of the rat heart. After complete perfusion, the mammary glands were resected, fixed under ice cold conditions and subjected to immunohistochemistry (IHC) for tumor cells. The LSM-410 (Carl Zeiss, Jena, Germany) was employed on thick sections (300-2,000 microns) to elucidate detailed microvessel networks (MVN) and tumor cells. RESULTS: Tumor vasculature on thick sections was clearly detected by CLSM at the maximum focus depth of 2,000 microns. Three-dimensional (3-D), reconstructed images of normal mammary glands showed regular and linear MVN. In DMBA-induced mammary cancer, vascular density of MVN was markedly increased and showed an anastomosing, irregular MVN pattern. Furthermore, focal segmentation and tortuous, branching patterns of microvessels were also seen. CONCLUSION: Application of the fluorescence injection method and IHC using CLSM was very useful for studying the 3-D relationship between tumor angiogenesis and neoplastic epithelial changes. These results suggest that application of this technique is ideal for studying 3-D imaging of tumor angiogenesis.     

DEspR Roles in Tumor Vasculo-Angiogenesis,Invasiveness, CSC-Survival and Anoikis Resistance: A ‘Common Receptor Coordinator’ Paradigm

A priori, a common receptor induced in tumor microvessels, cancer cells and cancer stem-like cells (CSCs) that is involved in tumor angiogenesis, invasiveness, and CSC anoikis resistance and survival, could underlie contemporaneous coordination of these events rather than assume stochasticity. Here we show that functional analysis of the dual endothelin1/VEGFsignal peptide receptor, DEspR, (formerly named Dear, Chr.4q31.2) supports the putative common receptor paradigm in pancreatic ductal adenocarcinoma (PDAC) and glioblastoma (GBM) selected for their invasiveness, CD133+CSCs, and polar angiogenic features. Unlike normal tissue, DEspR is detected in PDAC and GBM microvessels, tumor cells, and CSCs isolated from PDAC-Panc1 and GBM-U87 cells. DEspR-inhibition decreased angiogenesis, invasiveness, CSC-survival and anoikis resistance in vitro, and decreased Panc1-CSC and U87-CSC xenograft tumor growth, vasculo-angiogenesis and invasiveness in nude^nu/nu rats, suggesting that DEspR activation would coordinate these tumor progression events. As an accessible, cell-surface ‘common receptor coordinator’, DEspR-inhibition defines a novel targeted-therapy paradigm for pancreatic cancer and glioblastoma.     

Major Histocompatibility Complex Class II+ Invariant Chain Negative Breast Cancer Cells Present Unique Peptides that Activate Tumor-specific T Cells from Breast Cancer Patients

The major histocompatibility complex (MHC) class II-associated Invariant chain (Ii) is present in professional antigen presenting cells where it regulates peptide loading onto MHC class II molecules and the peptidome presented to CD4⁺ T lymphocytes. Because Ii prevents peptide loading in neutral subcellular compartments, we reasoned that Ii⁻ cells may present peptides not presented by Ii⁺ cells. Based on the hypothesis that patients are tolerant to MHC II-restricted tumor peptides presented by Ii⁺ cells, but will not be tolerant to novel peptides presented by Ii⁻ cells, we generated MHC II vaccines to activate cancer patients'' T cells. The vaccines are Ii⁻ tumor cells expressing syngeneic HLA-DR and the costimulatory molecule CD80. We used liquid chromatography coupled with mass spectrometry to sequence MHC II-restricted peptides from Ii⁺ and Ii⁻ MCF10 human breast cancer cells transfected with HLA-DR7 or the MHC Class II transactivator CIITA to determine if Ii⁻ cells present novel peptides. Ii expression was induced in the HLA-DR7 transfectants by transfection of Ii, and inhibited in the CIITA transfectants by RNA interference. Peptides were analyzed and binding affinity predicted by artificial neural net analysis. HLA-DR7-restricted peptides from Ii⁻ and Ii⁺ cells do not differ in size or in subcellular location of their source proteins; however, a subset of HLA-DR7-restricted peptides of Ii⁻ cells are not presented by Ii⁺ cells, and are derived from source proteins not used by Ii⁺ cells. Peptides from Ii⁻ cells with the highest predicted HLA-DR7 binding affinity were synthesized, and activated tumor-specific HLA-DR7⁺ human T cells from healthy donors and breast cancer patients, demonstrating that the MS-identified peptides are bonafide tumor antigens. These results demonstrate that Ii regulates the repertoire of tumor peptides presented by MHC class II⁺ breast cancer cells and identify novel immunogenic MHC II-restricted peptides that are potential therapeutic reagents for cancer patients.Cancer vaccines are a promising tool for cancer treatment and prevention because of their potential for inducing tumor-specific responses in conjunction with minimal toxicity for healthy cells. Cancer vaccines are based on the concept that tumor cells synthesize multiple peptides that are potential immunogens, and that with the appropriate vaccine protocol, these peptides will activate an efficacious antitumor response in the patient. Much effort has been invested in identifying and testing tumor-encoded peptides, particularly peptides presented by major histocompatibility complex (MHC)¹ class I, molecules capable of activating CD8⁺ T-cells that directly kill tumor cells (1, 2). Fewer studies have been devoted to identifying MHC class II-restricted peptides for the activation of tumor-reactive CD4⁺ T-cells despite compelling evidence that Type 1 CD4⁺ T helper cells facilitate the optimal activation of CD8⁺ T-cells and the generation of immune memory, which is likely to be essential for protection from metastatic disease.Activation of CD4⁺ T cells requires delivery of a costimulatory signal plus an antigen-specific signal consisting of peptide bound to an MHC II molecule. Most cells do not express MHC II or costimulatory molecules, so CD4⁺ T cells are typically activated by professional antigen presenting cells (APC), which endocytose exogenously synthesized antigen and process and present it in the context of their own MHC II molecules. This processing and presentation process requires Invariant chain (Ii), a molecule that is coordinately synthesized with MHC II molecules and prevents the binding and presentation of APC-encoded endogenous peptides (3, 4). As a result, tumor-reactive CD4⁺ T cells are activated to tumor peptides generated by the antigen processing machinery of professional APC, rather than peptides generated by the tumor cells. Because of the potential discrepancy in peptide generation between professional APC and tumor cells, and the critical role of Ii in preventing the presentation of endogenous peptides, we have generated “MHC II cancer vaccines” that consist of Ii⁻ tumor cells transfected with syngeneic MHC class II and CD80 genes. We reasoned that MHC II⁺Ii⁻CD80⁺ tumor cells may present a novel repertoire of MHC II-restricted tumor peptides that are not presented by professional APC, and therefore may be highly immunogenic. Once activated, CD4⁺ T cells produce IFNγ and provide help to CD8⁺ T cells and do not need to react with native tumor cells. Therefore, the MHC II vaccines have the potential to activate CD4⁺ Th1 cells that facilitate antitumor immunity. In vitro (5) and in vivo (5–7) studies with mice support this conclusion. In vitro studies with human MHC II vaccines further demonstrate that the absence of Ii facilitates the activation of MHC II-restricted tumor-specific CD4⁺ type 1 T cells of HLA-DR-syngeneic healthy donors and cancer patients, and that the vaccines activate CD4⁺ T cells with a distinct repertoire of T cell receptors (8–12). A critical negative role for Ii is also supported by studies of human acute myelogenous leukemia (AML). High levels of class II-associated invariant chain peptide (CLIP), a degradation product of Ii, by leukemic blasts is associated with poor patient prognosis (13, 14), whereas down-modulation of CLIP on AML cells increases the activation of tumor-reactive human CD4⁺ T cells (14, 15).We have now used mass spectrometry to identify MHC II-restricted peptides from MHC II⁺Ii⁻ and MHC II⁺Ii⁺ human breast cancer cells to test the concept that the absence of Ii facilitates the presentation of unique immunogenic MHC II-restricted peptides. We report here that a subset of MHC II-restricted peptides from HLA-DR7⁺ breast cancer cells are unique to Ii⁻ cells and are derived from source proteins not used by Ii⁺ cells. Ii⁻ peptides have high binding affinity for HLA-DR7 and activate tumor-specific T-cells from the peripheral blood of healthy donors and breast cancer patients. This is the first study to compare the human tumor cell MHC II peptidome in the absence or presence of Ii and to demonstrate that MHC II⁺Ii⁻ tumor cells present novel immunogenic MHC II-restricted peptides that are potential therapeutic reagents for cancer patients.     

Insights and perspectives on calcium channel functions in the cockpit of cancerous space invaders

Development of metastasis causes the most serious clinical consequences of cancer and is responsible for over 90 % of cancer-related deaths. Hence, a better understanding of the mechanisms that drive metastasis formation appears critical for drug development designed to prevent the spread of cancer and related mortality. Metastasis dissemination is a multistep process supported by the increased motility and invasiveness capacities of tumor cells. To succeed in overcoming the mechanical constraints imposed by the basement membrane and surrounding tissues, cancer cells reorganize their focal adhesions or extend acto-adhesive cellular protrusions, called invadosomes, that can both contact the extracellular matrix and tune its degradation through metalloprotease activity. Over the last decade, accumulating evidence has demonstrated that altered Ca²⁺ channel activities and/or expression promote tumor cell-specific phenotypic changes, such as exacerbated migration and invasion capacities, leading to metastasis formation. While several studies have addressed the molecular basis of Ca²⁺ channel-dependent cancer cell migration, we are still far from having a comprehensive vision of the Ca²⁺ channel-regulated mechanisms of migration/invasion. This is especially true regarding the specific context of invadosome-driven invasion. This review aims to provide an overview of the current evidence supporting a central role for Ca²⁺ channel-dependent signaling in the regulation of these dynamic degradative structures. It will present available data on the few Ca²⁺ channels that have been studied in that specific context and discuss some potential interesting actors that have not been fully explored yet.     

Visualization of Ovarian Cancer Cells with Peptide VEGEGEEGEEY

The binding of peptide VEGEGEEGEEY to the surface of ovarian cancer cells was studied by confocal microscopy. It has been demonstrated that the peptide competes with hyaluronan for the binding to RHAMM (receptor for hyaluronan-mediated motility). It was found that peptide VEGEGEEGEEY specifically bound to RHAMM on ovarian cancer cell surface, and this interaction was blocked by anti-RHAMM antibodies. The peptide did not bind to RHAMM-knockout fibroblasts RHAMM^(–/–) but interacted with transfected fibroblasts RHAMM^(+/+), which further confirms the binding of the peptide to RHAMM. Evaluation of the peptide binding selectivity showed that the peptide reacts with cancer cells and does not bind to the surface of fibroblasts and normal cells. Thus, the specificity of binding of peptide FITC-VEGEGEEGEEY to RHAMM suggests a possibility of its application as a molecular probe for imaging and diagnosis of ovarian cancer at early stages.     

New lytic peptides based on the D,L-amphipathic helix motif preferentially kill tumor cells compared to normal cells

Despite significant advances in cancer therapy, there is an urgent need for drugs with a new mode of action that will preferentially kill cancer cells. Several cationic antimicrobial peptides, which bind strongly to negatively charged membranes, were shown to kill cancer cells slightly better than normal cells. This was explained by a slight increase (3-9%) in the level of the negatively charged membrane phosphatidylserine (PS) in many cancer cells compared to their normal counterparts. Unfortunately, however, these peptides are inactivated by serum components. Here we synthesized and investigated the anticancer activity and the role of peptide charge, peptide structure, and phospholipid headgroup charge on the activity of a new group of diastereomeric lytic peptides (containing D- and L-forms of leucine and lysine; 15-17 amino acids long). The peptides are highly toxic to cancer cells, to a degree similar to or larger than that of mitomycin C. However, compared with mitomycin C and many native antimicrobial peptides, they are more selective for cancer cells. The peptides were investigated for (i) their binding to mono- and bilayer membranes by using the surface plasmon resonance (SPR) technique, (ii) their ability to permeate membranes by using fluorescence spectroscopy, (iii) their structure and their effect on the lipid order by using ATR-FTIR spectroscopy, and (iv) their ability to bind to cancer versus normal cells by using confocal microscopy. The data suggest that the peptides disintegrate the cell membrane in a detergent-like manner. However, in contrast to native antimicrobial peptides, the diastereomers bind and permeate similarly zwitterionic and PS-containing model membranes. Therefore, cell selectivity is probably determined mainly by improved electrostatic attraction of the peptides to acidic components on the surface of cancer cells (e.g., O-glycosylation of mucines). The simple composition of the diastereomeric peptides and their stability regarding enzymatic degradation by serum components make them excellent candidates for new chemotherapeutic drugs.     

Preparation,characterization, bioactive and cell attachment studies of α-chitin/gelatin composite membranes

The chitin/gelatin composite membranes were prepared by mixing of chitin hydrogel with gelatin. The prepared composite membranes were characterized by scanning electron microscopy (SEM), X-ray diffraction (XRD), mechanical, swelling, enzymatic degradation and thermal studies. The XRD pattern of the chitin/gelatin composite membranes showed almost the same pattern as α-chitin. The bioactivity studies of these chitin/gelatin membranes were carried out with the simulated body fluid solution (SBF) for 7, 14 and 21 days followed by the characterization with the scanning electron microscopy (SEM) and Energy Dispersive Spectrum (EDS) studies. The SEM and EDS studies confirmed the formation of calcium phosphate layer on the surface of chitin/gelatin membranes. Biocompatibility of the chitin/gelatin membrane was assessed using human MG-63 osteoblast-like cells. After 48 h of incubation, it was found that the cells had attached and completely covered the membrane surface. Thus, the prepared chitin/gelatin membranes are bioactive and are suitable for cell adhesion suggesting that these membranes can be used for tissue-engineering applications.     

CXCL12 induces lung cancer cell migration by polarized mtDNA redistribution

Instability of mitochondrial DNA (mtDNA) has been associated with the initiation and development of cancer, but the specific role of mtDNA in the invasiveness and migration of cancer cells remains unclear. In this study, we investigated whether the chemokine CXCL12 causes intact mitochondria to redistribute in cancer cells and, in this way, to increase cell invasiveness and migration. A549 lung cancer cells with intact mtDNA (mtDNA+) and ρ⁰A549 cells depleted of mtDNA (mtDNA?) by long-term ethidium bromide incubation were examined for their responses to CXCL12 in a transwell migration assay and for mitochondrial distribution by fluorescence microscopy. Intact A549 cells showed significantly increased migration and increased polar distribution of mitochondria (asymmetry) in response to CXCL12. However, ρ⁰A549 cells showed no changes in mitochondrial distribution in response to CXCL12, and only a few ρ⁰A549 cells migrated across the transwell membrane after CXCL12 treatment. These results demonstrate that, in A549 lung cancer cells, intact mitochondrial DNA is necessary for mitochondrial redistribution and a chemotactic response to CXCL12.     

The Function of Vacuolar ATPase (V-ATPase) a Subunit Isoforms in Invasiveness of MCF10a and MCF10CA1a Human Breast Cancer Cells

The vacuolar H⁺ ATPases (V-ATPases) are ATP-driven proton pumps that transport protons across both intracellular and plasma membranes. Previous studies have implicated V-ATPases in the invasiveness of various cancer cell lines. In this study, we evaluated the role of V-ATPases in the invasiveness of two closely matched human breast cancer lines. MCF10a cells are a non-invasive, immortalized breast epithelial cell line, and MCF10CA1a cells are a highly invasive, H-Ras-transformed derivative of MCF10a cells selected for their metastatic potential. Using an in vitro Matrigel assay, MCF10CA1a cells showed a much higher invasion than the parental MCF10a cells. Moreover, this increased invasion was completely sensitive to the specific V-ATPase inhibitor concanamycin. MCF10CA1a cells expressed much higher levels of both a1 and a3 subunit isoforms relative to the parental line. Isoforms of subunit a are responsible for subcellular localization of V-ATPases, with a3 and a4 targeting V-ATPases to the plasma membrane of specialized cells. Knockdown of either a3 alone or a3 and a4 together using isoform-specific siRNAs inhibited invasion by MCF10CA1a cells. Importantly, overexpression of a3 but not the other a subunit isoforms greatly increased the invasiveness of the parental MCF10a cells. Similarly, overexpression of a3 significantly increased expression of V-ATPases at the plasma membrane. These studies suggest that breast tumor cells employ particular a subunit isoforms to target V-ATPases to the plasma membrane, where they function in tumor cell invasion.     

Quantitative analysis of the effect of cancer invasiveness and collagen concentration on 3D matrix remodeling

Extracellular matrix (ECM) remodeling is a key component of cell migration and tumor metastasis, and has been associated with cancer progression. Despite the importance of matrix remodeling, systematic and quantitative studies on the process have largely been lacking. Furthermore, it remains unclear if the disrupted tensional homeostasis characteristic of malignancy is due to initially altered ECM and tissue properties, or to the alteration of the tissue by tumor cells. To explore these questions, we studied matrix remodeling by two different prostate cancer cell lines in a three-dimensional collagen system. Over one week, we monitored structural changes in gels of varying collagen content using confocal reflection microscopy and quantitative image analysis, tracking metrics of fibril fraction, pore size, and fiber length and diameter. Gels that were seeded with no cells (control), LNCaP cells, and DU-145 cells were quantitatively compared. Gels with higher collagen content initially had smaller pore sizes and higher fibril fractions, as expected. However, over time, LNCaP- and DU-145-populated matrices showed different structural properties compared both to each other and to the control gels, with LNCaP cells appearing to favor microenvironments with lower collagen fiber fractions and larger pores than DU-145 cells. We posit that the DU-145 cells' preference for denser matrices is due to their higher invasiveness and proteolytic capabilities. Inhibition of matrix proteases resulted in reduced fibril fractions for high concentration gels seeded with either cell type, supporting our hypothesis. Our novel quantitative results probe the dynamics of gel remodeling in three dimensions and suggest that prostate cancer cells remodel their ECM in a synergistic manner that is dependent on both initial matrix properties as well as their invasiveness.     

Identification of Prostate-Specific G-Protein Coupled Receptor as a Tumor Antigen Recognized by CD8+ T Cells for Cancer Immunotherapy

Background

Prostate cancer is the most common cancer among elderly men in the US, and immunotherapy has been shown to be a promising strategy to treat patients with metastatic castration-resistant prostate cancer. Efforts to identify novel prostate specific tumor antigens will facilitate the development of effective cancer vaccines against prostate cancer. Prostate-specific G-protein coupled receptor (PSGR) is a novel antigen that has been shown to be specifically over-expressed in human prostate cancer tissues. In this study, we describe the identification of PSGR-derived peptide epitopes recognized by CD8⁺ T cells in an HLA-A2 dependent manner.

Methodology/Principal Findings

Twenty-one PSGR-derived peptides were predicted by an immuno-informatics approach based on the HLA-A2 binding motif. These peptides were examined for their ability to induce peptide-specific T cell responses in peripheral blood mononuclear cells (PBMCs) obtained from either HLA-A2⁺ healthy donors or HLA-A2⁺ prostate cancer patients. The recognition of HLA-A2 positive and PSGR expressing LNCaP cells was also tested. Among the 21 PSGR-derived peptides, three peptides, PSGR3, PSGR4 and PSGR14 frequently induced peptide-specific T cell responses in PBMCs from both healthy donors and prostate cancer patients. Importantly, these peptide-specific T cells recognized and killed LNCaP prostate cancer cells in an HLA class I-restricted manner.

Conclusions/Significance

We have identified three novel HLA-A2-restricted PSGR-derived peptides recognized by CD8⁺ T cells, which, in turn, recognize HLA-A2⁺ and PSGR⁺ tumor cells. The PSGR-derived peptides identified may be used as diagnostic markers as well as immune targets for development of anticancer vaccines.     

激光共聚焦显微镜研究大白鼠肝癌FSK7902细胞系的实体瘤中角蛋白和嗜铬颗粒素A的关系

应用免疫组织化学ＡＢＣ法和免疫荧光组织化学方法结合激光共聚焦显微镜观察了嗜铬颗粒素Ａ和角蛋白在大白鼠肝癌ＦＳＫ７９０２细胞系形成的实体瘤癌细胞中的表达,结果表明在ＦＳＫ７９０２实体瘤内,大多数癌细胞呈角蛋白和ＣｇＡ免疫反应阳性,反应产物位于核周胞质或核旁的某些区域。