Project description:The somatic microenvironment supports spermatogonial stem cell differentiation into sperm. Extracellular matrix (ECM) plays multiple roles in the stem cell niche, including self-renewal, proliferation, differentiation and survival of spermatogonial cells. The pathophysiology of male infertility might be representative of a progressive degenerative process of the testicular tissue, including ECM, rather than a defective genetic background, thus outlining the existence of chronic etiological agents/pathways. In this context, we sought to identify potential causative factors responsible for a number of modifications of the testicular somatic microenvironment associated with idiopathic germ cell aplasia in human beings. Proteomic analysis of the decellularized ECM was performed to study testis parenchyma from 10 idiopathic non-obstructive azoospermic (iNOA) men, dichotomized according to positive sperm retrieval versus germ cell aplasia. Germ cell aplasia was characterized by an increased nuclear distribution of the retinoic acid receptor in Sertoli cells which was associated with decreased expression of the ECM markers, Nidogen-2 and Heparan sulfate proteoglycan-2. Decreased levels of the interstitial matrisome associated Factor IX and its regulator VKORC1 were instead coupled with decreased signaling of vitamin K in Leydig cells. This study identified pathogenetic signature of the somatic testicular microenvironment and provide mechanistic insights into the molecular determinants of human idiopathic germ cell aplasia.

Project description:The goal of this project is to characterize the ECM composition of actively proliferative and dormant head and neck squamous cell carcinoma xenografts and identify components of the ECM niche instructing tumor cell dormancy.

Project description:The goal of this project is to characterize the ECM composition of actively proliferative and dormant head and neck squamous cell carcinoma xenografts and identify components of the ECM niche instructing tumor cell dormancy.

Project description:FoxL1+telocytes (TCFoxL1+) are novel gastrointestinal subepithelial cells that form communication axis between the mesenchyme and epithelium. TCFoxL1+ are strategically positioned to be key contributors to the microenvironment through production and secretion of growth factors and extracellular matrix (ECM) proteins. In recent years, the alteration of the bone morphogenetic protein (BMP) signaling in TCFoxL1+ was demonstrated to trigger a toxic microenvironment with ECM remodeling that leads to the development of pre-neoplastic gastric lesions. However, a comprehensive analysis of variations in the ECM composition and its associated proteins in gas-tric neoplasia linked to TCFoxL1+ dysregulation has never been performed. This study provides a better understanding of how TCFoxL1+ defective BMP signaling participates in gastric pre-neoplastic microenvironment. Using a proteomic approach, we determined the changes in the complete matrisome of BmpR1a△FoxL1+ and control mice, both in total antrum as well as in isolated mesenchyme-enriched antrum fractions. Comparative proteomic analysis revealed that the deconstruction of the gastric antrum led to a more comprehensive analysis of the ECM frac-tion of gastric tissues microenvironment. These results show that TCFoxL1+ are key members of the mesenchymal cell population and actively participate in the establishment of the matrisomic fraction of the microenvironment; thus, influencing epithelial cell behavior

Project description:This study focuses on the impact of ECM (extra-cellular matrix) over cell processes such as proliferation, differentiation or mineralization which is more specifically related to our dental pulp cells. We cultured these dental pulp stem cells (DPSC) in mineralization growth or normal growth conditions. After 21 days, cells were incubated in decellularized solution until no intact cells are seen. After ECM was washed, we studied the mineralization associated to these two different ECM. Matrisome proteins were identified through proteomics. DPSC matrisome is composed of 225 individual different proteins. We classified them according to different categories, the 3 core matrisome categories: glycoproteins, collagens, proteoglycans and the 3 matrisome associated proteins categories: the regulators, affiliated and secreted. When comparing the proteins in the N-ECM and OM-ECM, most of the core matrisome proteins are downregulated in OM conditions, except 3 glycoproteins, as well as regulators and secreted factors. However, annexins were found to be upregulated in OM condition. Cell adhesion, tensile strength and growth factor binding are over-represented in NM ECM. The collagen group and glycoproteins were higher in N-ECM than OM-ECM Thereafter, gingival stem cells (GSC), the less inherit osteogenic potency cells, were seeded on these N-ECM and OM-ECM. When GSCs were seeded on DPSC-derived ECM, the OM-ECM dramatically promoted mineral deposition compared with N-ECM. We hypothesize that annexins could participate in the osteogenic inductive properties. ECM plays a pivotal role in many physiological processes, it regulates cells behavior and can orient cell differentiation. Dental pulp and oral mucosa share embryological origins but differ in their reactions to insults. Dental pulp can mineralize while oral mucosa heals ad integrum. We hypothesize that ECM participate in these characteristics.

Project description:Lymph nodes are secondary lymphoid tissues that play a critical role in filtering the lymph and supporting adaptive immune responses. Surgical resection of LNs, radiation therapy or infections may damage lymphatic vasculature and compromised immune functions. Here, we describe the generation of functional synthetic lympho-organoids (LOs) using LN stromal progenitors and decellularized extra cellular matrix-based scaffolds. We show that upon transplantation at the site of resected LNs, LOs become integrated into the endogenous lymphatic vasculature and efficiently restore lymphatic drainage and perfusion. Upon immunization, LOs support the activation of antigen-specific immune responses, thus acquiring properties of native lymphoid tissues. These findings provide the first proof-of-concept for the development of synthetic lympho-organoids suitable to restore lymphatic and immune cell functions.

Project description:The extracellular matrix (ECM), a key interface between the cerebrovasculature and other cells within the neuro-glial-vascular unit , provides structural stability and modulates cell behaviour and signalling. These functions are dependent on ECM protein composition. Since ECM defects may contribute to a broad range of disorders including cerebrovascular disease, it is crucially important to characterize ECM composition to better understand the mechanisms by which the ECM modulates brain health and disease. To date, molecular studies of the cerebrovascular ECM have been limited. We therefore generated ECM extracts from vascular enriched tissues of both mouse and human post-mortem brain. We used mass spectrometry with off-line high-pH reversed-phase fractionation to increase proteome depth and characterized the identified proteins. This identified a large number of proteins (>1000 mouse, >2000 human) in the ECM-enriched fractions, with > 66% of the identified proteins covered in both human and mouse samples. We now report 147 ECM proteins, including collagens (as major ECM components), laminins, fibronectin and nidogens, that can be considered as the core constituents of the human brain vascular matrisome. We also identified 12 novel proteins in the ECM-enriched fraction, that may have regulate or interact with the matrisome, including several key regulators of neurovascular interactions, such as BCAM, CDH5 and PARVB. Many of the identified brain vascular matrisome proteins are encoded by genes identified in stroke and cerebral small vessel disease genome-wide association studies, underscoring the importance of the vascular ECM in health and disease. This brain vascular matrisome represents a powerful resource for investigating the impact of aging and disease on the cerebrovasculature.

Project description:Recent approaches of regenerative reproductive medicine investigate the decellularized extracellular matrix to develop a transplantable engineered ovary (TEO). However, a full proteomic analysis is not usually performed after the decellularization process to evaluate the preservation of the extracellular matrix (ECM). In this study, the ECM of the bovine ovarian cortex was analyzed before and after decellularization using mass spectrometry and bioinformatics. A total of 155 matrisome proteins were identified in the native ECM of the bovine ovarian cortex, with 145 matrisome proteins detected in the decellularized ECM. After decellularization, only 10 matrisome proteins were lost, and notably, none belonged to the category of reproductive biological processes. Histology and histochemistry analyses were employed to assess the general morphology of both native and decellularized ECM, allowing for the identification of the most abundant ECM proteins. Moreover, our study highlighted collagen type VI alpha 3 and heparan sulfate proteoglycan 2 as the most abundant components in the bovine ovarian ECM, mirroring the composition observed in the human ovary. These findings enhance our understanding of the composition of both native and decellularized ECM, with the potential implications for the development of a TEO.

Project description:Comparative proteome of extracted Hydra vulgaris AEP extracellular matrix form Wnt9/10 knock out and Azakenpaullone treated animals. Used to analyse the changes in molecular composition of the mesoglea (ECM) of normal and Wnt depleted animals

Project description:Tumor initiation and progression are critically dependent on interaction of cancer cells with their cellular and extracellular microenvironment. Alterations in the composition, integrity, and mechanical properties of the extracellular matrix (ECM) dictate tumor processes including proliferation, migration, and invasion. Also in primary liver cancers, consisting of hepatocellular carcinoma (HCC) and cholangiocarcinoma (CCA), the dysregulation of the extracellular environment by liver fibrosis and tumor desmoplasia is pertinent. Yet, in-depth characterization of liver cancer ECM and underlying tumor-promoting mechanisms remain largely unknown. Herein, we used an integrative molecular and mechanical approach to extensively characterize the ECM of HCC and CCA tumors by utilizing decellularization techniques. We identified a myriad of ECM-related proteins in both tumor and adjacent liver tissue, highlighting the complexity of the primary liver cancer matrisome. The differences in ECM protein abundance result in divergent mechanical properties on a macro- and micro-scale that is tumor-type specific. Furthermore, we employed the decellularized tumor ECM to create a tumor-specific hydrogel that support patient-derived tumor organoids. This provides a new avenue for personalized medicine by combining patient-derived tumor ECM and cancer cells. Taken together, this study provides better understanding of alterations to key aspects of the ECM that occur during primary liver cancer development.