Giulio Ghersi

The protease complex consisting of dipeptidyl peptidase IV and seprase plays a role in the migration and invasion of human endothelial cells in collagenous matrices.

Dipeptidyl peptidase IV (DPP4/CD26) and seprase/fibroblast activation protein alpha are homologous type II transmembrane, homodimeric glycoproteins that exhibit unique prolyl peptidase activities. Human DPP4 is ubiquitously expressed in epithelial and endothelial cells and serves multiple functions in cleaving the penultimate positioned prolyl bonds at the NH(2) terminus of a variety of physiologically important peptides in the circulation. Recent studies showed a linkage between DPP4 and down-regulation of certain chemokines and mitogenic growth factors, and degradation of denatured collagens (gelatin), suggesting a role of DPP4 in the cell invasive phenotype. Here, we found the existence of a novel protease complex consisting of DPP4 and seprase in human endothelial cells that were activated to migrate and invade in the extracellular matrix in vitro. DPP4 and seprase were coexpressed with the three major protease systems (matrix metalloproteinase, plasminogen activator, and type II transmembrane serine protease) at the cell surface and organize as a complex at invadopodia-like protrusions. Both proteases were colocalized at the endothelial cells of capillaries, but not large blood vessels, in invasive breast ductal carcinoma in vivo. Importantly, monoclonal antibodies against the gelatin-binding domain of DPP4 blocked the local gelatin degradation by endothelial cells in the presence of the major metallo- and serine protease systems that modified pericellular collagenous matrices and subsequent cell migration and invasion. Thus, we have identified a novel mechanism involving the DPP4 gelatin-binding domain of the DPP4-seprase complex that facilitates the local degradation of the extracellular matrix and the invasion of the endothelial cells into collagenous matrices.

DPPIV, seprase, and related serine peptidases in multiple cellular functions

Publisher Summary Serine integral membrane peptidases (SIMP), including DPPIV, seprase, and related prolyl peptidases, which are both Pro-Xaa cleaving enzymes and adhesion molecules, are likely to emerge as an important protease family. The main functions of SIMPs reside in their proteolytic and adhesive capacities, thus influencing cellular activities, migration, and invasion. These membrane proteases may form a physically and functionally linked complex at invadopodia during cellular invasion. The cysteine-rich domain of some peptidases exhibits the capability of binding to multiple molecules. This could allow not only activation of the peptidases themselves but also association with other membrane proteases to participate in cooperative extracellular matrix (ECM) protein degradation at invadopodia during cancer invasion. This chapter focuses on a small group of membrane serine peptidases, the SIMP, that are inducible, specific for proline-containing peptides and macromolecules, and active on the cell surface. Prototypes of SIMP members are DPPIV and seprase. Other SIMP-related peptidases, including quiescent cell proline aminodipeptidase (QPP), prolyl carboxy-peptidase (PCP), prolyl endopeptidase (PEP), dipeptidyl peptidase 6 (DPP6), dipeptidyl peptidase 8 (DPP8), dipeptidyl peptidase 9 (DDP9), attractin, dipeptidyl peptidase II (DPPII), and dipeptidyl peptidase IV-β (DPPIV-β), have subtle structural and functional differences from DPPIV and seprase, and they are also discussed in the chapter.

Preparation of three-layered porous PLA/PEG scaffold: relationship between morphology, mechanical behavior and cell permeability

Interface tissue engineering (ITE) is used to repair or regenerate interface living tissue such as for instance bone and cartilage. This kind of tissues present natural different properties from a biological and mechanical point of view. With the aim to imitating the natural gradient occurring in the bone-cartilage tissue, several technologies and methods have been proposed over recent years in order to develop polymeric functionally graded scaffolds (FGS). In this study three-layered scaffolds with a pore size gradient were developed by melt mixing polylactic acid (PLA) and two water-soluble porogen agents: sodium chloride (NaCl) and polyethylene glycol (PEG). Pore dimensions were controlled by NaCl granulometry while PEG solvation created a micropores network within the devices. Scaffolds were characterized from a morphological and mechanical point of view in order to find a correlation between the preparation method, the pore architecture and compressive mechanical behavior. Biological tests were also performed in order to study the effect of pore size gradient on the permeation of different cell lines in co-culture. To imitate the physiological work condition, compressive tests were also performed in phosphate buffered saline (PBS) solution at 37°C. The presented preparation method permitted to prepare three-layered scaffolds with high control of porosity and pore size distribution. Furthermore mechanical behaviors were found to be strongly affected by pore architecture of tested devices as well as the permeation of osteoblast and fibroblast in-vitro.

Muscle degeneration in neuraminidase 1-deficient mice results from infiltration of the muscle fibers by expanded connective tissue

Neuraminidase 1 (NEU1) regulates the catabolism of sialoglycoconjugates in lysosomes. Congenital NEU1 deficiency in children is the basis of sialidosis, a severe neurosomatic disorder in which patients experience a broad spectrum of clinical manifestations varying in the age of onset and severity. Osteoskeletal deformities and muscle hypotonia have been described in patients with sialidosis. Here we present the first comprehensive analysis of the skeletal muscle pathology associated with loss of Neu1 function in mice. In this animal model, skeletal muscles showed an expansion of the epimysial and perimysial spaces, associated with proliferation of fibroblast-like cells and abnormal deposition of collagens. Muscle fibers located adjacent to the expanded connective tissue underwent extensive invagination of their sarcolemma, which resulted in the infiltration of the fibers by fibroblast-like cells and extracellular matrix, and in their progressive cytosolic fragmentation. Both the expanded connective tissue and the juxtaposed infiltrated muscle fibers were strongly positive for lysosomal markers and displayed increased proteolytic activity of lysosomal cathepsins and metalloproteinases. These combined features could lead to abnormal remodeling of the extracellular matrix that could be responsible for sarcolemmal invagination and progressive muscle fiber degeneration, ultimately resulting in an overt atrophic phenotype. This unique pattern of muscle damage, which has never been described in any myopathy, might explain the neuromuscular manifestations reported in patients with the type II severe form of sialidosis. More broadly, these findings point to a potential role of NEU1 in cell proliferation and extracellular matrix remodeling.

Minimalism in Radiation Synthesis of Biomedical Functional Nanogels

A scalable, single-step, synthetic approach for the manufacture of biocompatible, functionalized micro- and nanogels is presented. In particular, poly(N-vinyl pyrrolidone)-grafted-(aminopropyl)methacrylamide microgels and nanogels were generated through e-beam irradiation of PVP aqueous solutions in the presence of a primary amino-group-carrying monomer. Particles with different hydrodynamic diameters and surface charge densities were obtained at the variance of the irradiation conditions. Chemical structure was investigated by different spectroscopic techniques. Fluorescent variants were generated through fluorescein isothiocyanate attachment to the primary amino groups grafted to PVP, to both quantify the available functional groups for bioconjugation and follow nanogels localization in cell cultures. Finally, a model protein, bovine serum albumin, was conjugated to the nanogels to demonstrate the attachment of biologically relevant molecules for targeting purposes in drug delivery. The described approach provides a novel strategy to fabricate biohybrid nanogels with a very promising potential in nanomedicine.

Integration of PCL and PLA in a monolithic porous scaffold for interface tissue engineering

A novel bi-layered multiphasic scaffold (BLS) have been fabricated for the first time by combining melt mixing, compression molding and particulate leaching. One layer has been composed by polylactic acid (PLA) presenting pore size in the range of 90-110µm while the other layer has been made of polycaprolactone (PCL) with pores ranging from 5 to 40µm. The different chemo-physical properties of the two biopolymers combined with the tunable pore architecture permitted to realize monolithic functionally graded scaffolds engineered to be potentially used for interface tissues regenerations. BLS have been characterized from a morphological and a mechanical point of view. In particular, mechanical tests have been carried out both in air and immersing the specimens in phosphate buffered saline (PBS) solution at 37°C, in order to evaluate the elastic modulus and the interlayer adhesion strength. Fibroblasts and osteoblasts have been cultured and co-cultured in order to investigate the cells permeation trough the different layers. The results indicate that the presented method is appropriate for the preparation of multiphasic porous scaffolds with tunable morphological and mechanical characteristics. Furthermore, the cells seeded were found to grow with a different trend trough the different layers thus demonstrating that the presented device has good potential to be used in interface tissue regeneration applications.

Shed Membrane Vesicles and Selective Localization of Gelatinases and MMP‐9/TIMP‐1 Complexes

Shedding of membrane vesicles is a vital phenomenon frequently observed in tumor cells and suggested to be involved in several aspects of tumor progression. 1 As we have recently shown, in 8701-BC breast carcinoma cells, vesicle shedding is modulated by extracellular signal; and several molecules, probably involved in tumor progression, are specifically densified on shed vesicles. 2 One of the clustered molecules is gelatinase B (MMP-9), which is present in both active and proenzyme forms. Western blot analyses of vesicles shed by 8701-BC breast carcinoma cells demonstrate that most MMP-9 molecules bound to vesicle membranes are in association with TIMP-1, as components of high M r complexes. 2 ProMMP-9/TIMP-1 complexes have been detected in vesicles shed by all other analyzed cell lines. Other proteolytic enzymes, on the contrary, were detected in vesicles shed by some cell lines and not in others. The urokinase type of plasminogen activator (uPA), while not detected in vesicles shed by 8701-BC and MCF-7 cells, is present in MDA MB-231. In vesicles shed by HT-1080 fibrosarcoma, we find not only MMP-9 and uPA, but also gelatinase A (MMP-2). 3 We observe a positive correlation between the quantity of shed vesicles, the amount of lytic enzymes they carry, and the in vitro invasive capability of the different cell lines. These findings indicate that vesicle production might represent an important mechanism by which tumor cells induce the localized degradation of the extracellular matrix and acquire metastatic capabilities. We have no evidence of which membrane vesicle components are involved in binding of proMMP-9/TIMP-1 complexes. Since Olson et al. recently reported that, in breast epithelial cells, proMMP-9 binds to α 2 (IV) chain of collagen IV, 4 we tested 8701-BC shed vesicles for the presence of this molecule. As shown by F IGURE 1, when Western blot analyses were performed in nonboiled, nonreducing conditions, antibodies against the α 2 (IV) chain of human collagen IV, recognized two components. One of them, having an electrophoretic mobility of 190 kDa, corresponds to the α 2 (IV) chain of collagen IV, the molecule identified as the proMMP-9 receptor

Chemical hydrogels based on a hyaluronic acid-graft-α-elastin derivative as potential scaffolds for tissue engineering

In this work hyaluronic acid (HA) functionalized with ethylenediamine (EDA) has been employed to graft α-elastin. In particular a HA-EDA derivative bearing 50 mol% of pendant amino groups has been successfully employed to produce the copolymer HA-EDA-g-α-elastin containing 32% w/w of protein. After grafting with α-elastin, remaining free amino groups reacted with ethylene glycol diglycidyl ether (EGDGE) for producing chemical hydrogels, proposed as scaffolds for tissue engineering. Swelling degree, resistance to chemical and enzymatic hydrolysis, as well as preliminary biological properties of HA-EDA-g-α-elastin/EGDGE scaffold have been evaluated and compared with a HA-EDA/EGDGE scaffold. The presence of α-elastin grafted to HA-EDA improves attachment, viability and proliferation of primary rat dermal fibroblasts and human umbilical artery smooth muscle cells. Biological performance of HA-EDA-g-α-elastin/EGDGE scaffold resulted comparable to that of a commercial collagen type I sponge (Antema®), chosen as a positive control.

Differential expression and function of cadherin-like proteins in the sea urchin embryo

Cadherins are Ca(+2)-dependent cell surface proteins involved in the specification of the adhesive properties of cells. They are supposed to play a critical role in morphogenesis and pattern formation. In this paper we show that in the sea urchin embryo there are at least two different cadherins of relative molecular masses 140 and 125 kDa. The 140 kDa cadherin is already present in the fertilized egg and is the sea urchin equivalent of E-cadherin. The 125 kDa cadherin, which can be detected using a broad-spectrum anti-cadherin antibody, appears only at later stages of development. In later embryos these two molecules are distributed differently: E-cadherin is present predominantly in the invaginating endoderm of the gastrula while the 125 kDa protein is present on the cell surface of most epithelia. Consistently with the observed differences in expression and in distribution, antibodies directed against these two cadherins differently perturb sea urchin development. For example, when these antibodies are added to early gastrulas only the antibodies against the 125 kDa component can induce a complete disaggregation of the ectoderm, while anti E-cadherin antibodies induce an abnormal development of the endoderm while the embryo maintains its basic integrity. These results are discussed in view of the need for multiple adhesion receptors during pattern formation and embryogenesis.

Heparin functionalized polyaspartamide/polyester scaffold for potential blood vessel regeneration

An interesting issue in tissue engineering is the development of a biodegradable vascular graft able to substitute a blood vessel and to allow its complete regeneration. Here, we report a new scaffold potentially useful as a synthetic vascular graft, produced through the electrospinning of α,β-poly(N-2-hydroxyethyl) (2-aminoethylcarbamate)-D,L-aspartamide-graft-polylactic acid (PHEA-EDA-g-PLA) in the presence of polycaprolactone (PCL). The scaffold degradation profile has been evaluated as well as the possibility to bind heparin to electrospun fibers, being it a known anticoagulant molecule able to bind growth factors. In vitro cell compatibility has been investigated using human vascular endothelial cells (ECV 304) and the ability of heparinized PHEA-EDA-g-PLA/PCL scaffold to retain basic fibroblast growth factor has been evaluated in comparison with not heparinized sample.