Isoaspartate formation in extracellular matrix proteins, by aspartate isomerization or asparagine deamidation, is generally viewed as a degradation reaction occurring in vivo during tissue aging. For instance, non-enzymatic isoaspartate formation at RGD-integrin binding sites causes loss of cell adhesion sites, which in turn can be enzymatically "repaired" to RGD by protein-L-isoAsp-O-methyltransferase. We show here that isoaspartate formation is also a mechanism for extracellular matrix activation. In particular, we show that deamidation of Asn 263 at the Asn-Gly-Arg (NGR) site in fibronectin N-terminal region generates an ␣ v  3 -integrin binding site containing the L-isoDGR sequence, which is enzymatically "deactivated" to DGR by protein-L-isoAsp-O-methyltransferase. Furthermore, rapid NGRto-isoDGR sequence transition in fibronectin fragments generates ␣ v  3 antagonists (named "isonectins") that competitively bind RGD binding sites and inhibit endothelial cell adhesion, proliferation, and tumor growth. Time-dependent generation of isoDGR may represent a sort of molecular clock for activating latent integrin binding sites in proteins.Fibronectins are adhesive proteins that mediate a variety of cellular interactions with extracellular matrix and play important roles in hemostasis, thrombosis, inflammation, wound repair, angiogenesis, and embryogenesis (1, 2). About 20 isoforms of human fibronectin can be generated as a result of alternative splicing of the primary transcript (1, 3). Fibronectins are large glycoproteins (ϳ450 kDa) composed of two nearly identical disulfide-bonded subunits present in most body fluids and extracellular matrix of many tissues. Each subunit consists of three types of repeating homologous modules termed FN-I, FN-II, and FN-III repeats. Alternatively spliced modules, called EDA, EDB, and IIICS, can also be present (1, 3). Single modules or groups of modules may contain binding sites for different molecules, including sulfated glycosaminoglycans, DNA, gelatin, heparin, and fibrin (1, 3, 4). Furthermore, fibronectins contain binding sites for about half of the known cell surface integrin receptors (5, 6). In particular, the FN-III 10 repeat contains an RGD site that can bind, and ␣II b  3 integrins, while the FN-III 9 repeat contains the so-called "synergy site" PHSRN that cooperates with RGD in the binding of ␣ 5  1 and ␣II b  3 (1, 7).Primary and tertiary structure analysis of human fibronectin showed that this protein contains two GNGRG loops, located in FN-I 5 and FN-I 7 modules, that are conserved in bovine, murine, rat, amphibian, and fish (8). Two additional NGR sites, less conserved, are also present in human FN-II 1 and FN-III 9 (see Fig. 1). Recent experimental work showed that peptides containing the NGR motif can inhibit ␣ 5  1 -and ␣ v  1 -mediated cell adhesion to fibronectin (9).These notions prompted us to investigate the functional role of NGR in fibronectin. We observed that the NGR sequence of FN-I 5 (residues 263-265) promotes endothelial cell adhesion via an...
Examination of the foreign body response to biomaterials by nonlinear intravital microscopy
Implanted biomaterials often fail because they elicit a foreign body response (FBR) and concomitant fibrotic encapsulation. To design clinically relevant interference approaches, it is crucial to first examine the FBR mechanisms. Here, we report the development and validation of infrared-excited nonlinear microscopy to resolve the three-dimensional (3D) organization and fate of 3D-electrospun scaffolds implanted deep into the skin of mice, and the following step-wise FBR process. We observed that immigrating myeloid cells (predominantly macrophages of the M1 type) engaged and became immobilized along the scaffold/tissue interface, before forming multinucleated giant cells. Both macrophages and giant cells locally produced vascular endothelial growth factor (VEGF), which initiated and maintained an immature neovessel network, followed by formation of a dense collagen capsule 2–4 weeks post-implantation. Elimination of the macrophage/giant-cell compartment by clodronate and/or neutralization of VEGF by VEGF Trap significantly diminished giant-cell accumulation, neovascularization and fibrosis. Our findings identify macrophages and giant cells as incendiaries of the fibrotic encapsulation of engrafted biomaterials via VEGF release and neovascularization, and therefore as targets for therapy.
Cooperative effects of aminopeptidase N (CD13) expressed by nonmalignant and cancer cells within the tumor microenvironment
Processes that promote cancer progression such as angiogenesis require a functional interplay between malignant and nonmalignant cells in the tumor microenvironment. The metalloprotease aminopeptidase N (APN; CD13) is often overexpressed in tumor cells and has been implicated in angiogenesis and cancer progression. Our previous studies of APN-null mice revealed impaired neoangiogenesis in model systems without cancer cells and suggested the hypothesis that APN expressed by nonmalignant cells might promote tumor growth. We tested this hypothesis by comparing the effects of APN deficiency in allografted malignant (tumor) and nonmalignant (host) cells on tumor growth and metastasis in APNnull mice. In two independent tumor graft models, APN activity in both the tumors and the host cells cooperate to promote tumor vascularization and growth. Loss of APN expression by the host and/ or the malignant cells also impaired lung metastasis in experimental mouse models. Thus, cooperation in APN expression by both cancer cells and nonmalignant stromal cells within the tumor microenvironment promotes angiogenesis, tumor growth, and metastasis.lung cancer | melanoma | proteolytic activity | shRNA | tumorigenesis A minopeptidase N (APN, CD13; EC 3.4.11.2) is a widely expressed type II membrane-bound metalloprotease (1, 2). It functions in the enzymatic cleavage of peptides, in endocytosis, and as a signaling molecule and has been implicated in the regulation of complex and diverse processes, including cell migration, cell survival, viral uptake, and angiogenesis (3). APN has also been linked specifically to cancer, having been identified as a cellsurface marker for malignant myeloid cells (4-7) and reaching high levels of expression in association with the progression of tumors, including breast, ovarian, and prostate cancer (8-14). Indeed, vascular endothelial growth factor (VEGF), a key angiogenesis regulator, induces the expression of APN at an early stage of tumor growth (15), again highlighting the role of this enzyme in angiogenesis, a process crucial for sustained growth of most solid tumors (16). Studies of bestatin, a CD13 inhibitor and antiangiogenic agent, also suggest that APN enzymatic activity is relevant for tumorigenesis (17,18). Nevertheless, the substrates of APN in the context of angiogenesis are still unknown. The only well-defined substrate is angiotensin III in the renin-angiotensin pathway, in which APN cleaves the NH 2 -terminal arginine residue of angiotensin III to form angiotensin IV. Consistent with several lines of evidence, we have previously identified APN as a target for inhibition of tumor vascularization and growth (18)(19)(20).Tumor growth relies on a complex microenvironment in which malignant cells cooperate with various other cell types: endothelial cells of the blood and lymphatic circulation, mesenchymal stromal cells/cancer-associated fibroblasts, and a variety of bone marrow-derived cells such as myeloid-derived suppressor cells and lymphocytes (21, 22). Some of these cell populations c...
Discovery and horizontal follow-up of an autoantibody signature in human prostate cancer
In response to an urgent need for improved diagnostic and predictive serum biomarkers for management of metastatic prostate cancer, we used phage display fingerprinting to analyze sequentially acquired serum samples from a patient with advancing prostate cancer. We identified a peptide ligand, CTFAGSSC, demonstrating an increased recovery frequency over time. Serum antibody reactivity to this peptide epitope increased in the index patient, in parallel with development of deteriorating symptoms. The antigen mimicking the peptide epitope was identified as alpha-2-HeremansSchmid glycoprotein, also known as fetuin-A. Metastatic prostate cancer cell lines and bone metastasis samples displayed robust fetuin-A expression, and we demonstrated serum immune reactivity to fetuin-A with concomitant development of metastatic castrateresistant disease in a large cohort of prostate cancer patients. Whereas fetuin-A is an established tumor antigen in several types of cancer, including breast cancer, glioblastoma, and pancreas cancer, this report is to our knowledge the first study implicating fetuin-A in prostate cancer and indicating that autoantibodies specific for fetuin-A show utility as a prognostic indicator for prostate cancer patients prone to progress to metastatic disease.cancer biomarker | peptide library | prostate cancer | phage display
Self-targeting of TNF-releasing cancer cells in preclinical models of primary and metastatic tumors
Circulating cancer cells can putatively colonize distant organs to form metastases or to reinfiltrate primary tumors themselves through a process termed "tumor self-seeding." Here we exploit this biological attribute to deliver tumor necrosis factor alpha (TNF), a potent antitumor cytokine, directly to primary and metastatic tumors in a mechanism that we have defined as "tumor self-targeting." For this purpose, we genetically engineered mouse mammary adenocarcinoma (TSA), melanoma (B16-F10), and Lewis lung carcinoma cells to produce and release murine TNF. In a series of intervention trials, systemic administration of TNF-expressing tumor cells was associated with reduced growth of both primary tumors and metastatic colonies in immunocompetent mice. We show that these malignant cells home to tumors, locally release TNF, damage neovascular endothelium, and induce massive cancer cell apoptosis. We also demonstrate that such tumor-cell-mediated delivery avoids or minimizes common side effects often associated with TNF-based therapy, such as acute inflammation and weight loss. Our study provides proof of concept that genetically modified circulating tumor cells may serve as targeted vectors to deliver anticancer agents. In a clinical context, this unique paradigm represents a personalized approach to be translated into applications potentially using patient-derived circulating tumor cells as self-targeted vectors for drug delivery.
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