Project description:Titanium is widely used in bone prostheses due to its excellent biocompatibility and osseointegration capacity. To understand the effect of sandblasted acid-etched (SAE) Ti implants on the biological responses of human osteoblast (HOb), their proteomic profiles were analysed using nLC-MS/MS. The cells were cultured with the implant materials, and 2544 distinct proteins were detected in samples taken after 1, 3 and 7 days. Comparative analyses of proteomic data were performed using Perseus software. The expression of proteins related to EIF2, mTOR, insulin-secretion and IGF pathways showed marked differences in cells grown with SAE-Ti in comparison with cells cultured without Ti. Moreover, the proteomic profiles obtained with SAE-Ti were compared over time. The affected proteins were related to adhesion, immunity, oxidative stress, coagulation, angiogenesis, osteogenesis and extracellular matrix formation functions. The proliferation, mineralisation and osteogenic gene expression in HObs cultured with SAE-Ti were characterised in vitro. The results showed that the osteoblasts exposed to this material increase their mineralisation rate and expression of COLI, RUNX2, SP7, CTNNB1, CAD13, IGF2, MAPK2 and mTOR. Overall, the observed proteomic profiles can explain the SAE-Ti osteogenic properties, widening our knowledge of key signalling pathways taking part in the early stages of the osseointegration process in this type of implantations.

Project description:The present study aimed to develop and optimize cell derived membrane-coated nanostructures by applying a design of experiments (DoE) to improve the therapeutic index by homotypic targeting in cancer cells. The protein composition of the extracted cell membrane from tumoral cells were assessed by mass spectrometry-based proteomics. PLGA-based nanoparticles encapsulating temozolomide (TMZ NPs) were successfully developed. The coating technology applying the isolated U251 cell membrane (MB) was optimized using a fractional two-level three-factor factorial design. All the formulation runs were systematically characterized regarding their diameter, polydispersity index (PDI), and zeta potential (ZP). Experimental conditions generated by DoE were also subjected to morphological studies using negative-staining transmission electron microscopy (TEM). MicroRaman, Fourier-Transform Infrared (FTIR) spectroscopies and Confocal microscopy were used as characterization techniques for evaluating the NP-MB nanostructures. Internalization studies were carried out to evaluate the homotypic targeting ability. The results have shown that nearly 80% of plasma membrane proteins were retained in the cell membrane vesicles after the isolation process, including key proteins to the homotypic binding. DoE analysis considering acquired TEM images reveals that condition run five should be the best-optimized procedure to produce the biomimetic cell-derived membrane-coated nanostructure (NP-MB). Raman, FTIR, and confocal characterization results have shown the successful encapsulation of TMZ drug and provided evidence of the effective coating applying the MB. Cell internalization studies corroborate the proteomic data indicating that the optimized NP-MB achieved specific targeting of homotypic tumor cells. The structure should retain the complex biological functions of U251 natural cell membranes while exhibiting physicochemical properties suitable for effective homotypic recognition. Together, these findings provide coverage and a deeper understanding regarding the dynamics around extracted cell membrane and polymeric nanostructures interactions and an in-depth insight into the cell membrane coating technology and the development of optimized biomimetic and bioinspired nanostructured systems.

Project description:Given the clinical need for osteoregenerative materials incorporating controlled biomimetic and biophysical cues, a novel norbornene-modified gelatin was developed with a degree of substitution of 169% compared to the number of amines present in pristine gelatin type B. It is, to the best of our knowledge, the highest substitution degree reported to date for norbornene-functionalised gelatin. Thiol-ene crosslinking exploiting thiolated gelatin as cell-interactive crosslinker resulted in networks with high (>95%) norbornene conversion. Comparing the number of physical crosslinks present, the degree of hydrolytic degradation upon modification, the network density as well as the chemical crosslinking type, the novel thiol-ene network was benchmarked against conventional gelatin-based systems in terms of the effect of biophysical cues, more specifically visco-elastic and topographical properties, affecting osteogenesis both in 2D and in 3D via a biofabrication strategy. The novel thiol-ene network outperformed conventional gelatin-based networks in terms of osteogenesis, as evidenced in 2D dental pulp stem cell seeding assays, resulting from the presentation of both a local (substrate elasticity, 25-40 kPa) and a bulk (compressive modulus, 25-45 kPa) osteogenic substrate modulus in combination with adequate fibrillar cell adhesion spacing to optimally transfer traction forces from the fibrillar ECM (as evidenced by mesh size determination with the rubber-elasticity theory) and resulting in a 1.5- and 1.7-fold increase in alkaline phosphatase activity and calcium production respectively as osteogenic markers (compared to the gold standard gelatin methacryloyl (GelMA)). Dental pulp stem cell encapsulation in extrusion-based biofabricated 3D constructs also showed a favorable response towards the novel thiol-ene network thanks to the combination of its RGD mobility (as observed from proteomic analysis), stress relaxation and substrate rigidity (bulk compressive modulus of 11-30 kPa) to enable a 1.5- and 7-fold increase in alkaline phosphatase activity and calcium production respectively as osteogenic markers (compared to the gold standard GelMA).

Project description:We report the application of RNA sequencing to evaluate the effect of titanium (Ti) with nanotopography, compared to Ti control, on the whole transcriptome of osteoblastic cells in isolated cultures grown on these surfaces and to evaluate the effect of Ti with nanotopography, compared to Ti control, on the whole transcriptome of osteoblastic cells, grown on these surfaces, in co-culture with osteoclastic cells. MC3T3-E1 osteoblastic cells were plated at the density of 1x10^4 cells/well on the Ti discs with nanotopography and Ti control, in 24-well plates in osteogenic medium and kept isolated for 5 days to allow cell adhesion. Osteoclast cells from the RAW 264.7 lineage were cultured on osteoclastogenic medium on ThinCert™ cell culture inserts (Greiner Bio-One), with 0.4 μm pore, at the density of 1x104 cells/membrane, and was also be kept isolated for 5 days to allow cell adhesion. At the end of this period theThinCert™ cell culture inserts (Greiner Bio-One), containing the osteoclast cells were positioned on the osteoblastic cell cultures, thereby establishing indirect co-culture. The controls were osteoblastic cells of the MC3T3-E1 lineage grown on the Ti discs in the absence of osteoclast cells of the RAW 264.7 lineage, i.e., not maintained in co-culture.

Project description:The cellular microenvironment in classical Hodgkin lymphoma (cHL) is dominated by a mixed infiltrate of inflammatory cells with typically only about 1% Hodgkin and Reed/Sternberg (HRS) tumor cells. T cells are usually the largest population of cells in the cHL microenvironment, encompassing T helper (Th) cells, regulatory T (Treg) cells and cytotoxic T cells. Th and Treg cells presumably provide essential survival signals for HRS cells. Treg cells are also involved in rescuing HRS cells from anti-tumor immune responses. An understanding of the immune evasion strategies of HRS cells is not only highly relevant for a characterization of the pathophysiology of cHL, but also clinically, given the current treatment approaches targeting checkpoint inhibitors. Here, we characterized the cHL-specific CD4+ T cell infiltrate regarding its role in immune evasion. Global gene expression analysis of CD4+ Th and Treg cells isolated from cHL lymph nodes and reactive tonsils revealed that Treg cell signatures were enriched in CD4+ Th cells of cHL. Hence, HRS cells may induce a Treg differentiation in Th cells, which was supported by in vitro studies with Th cells and cHL cell lines. Furthermore, we found indication for immune-suppressive purinergic signaling and a role of the inhibitory receptor-ligand pairs BTLA-HVEM and CD200R-CD200 in promoting immune evasion. Taken together, this study reveals that the immune evasion strategies in cHL are even more complex and multifaceted than previously recognized.

Project description:Cranial bone defect is a major clinical challenge that increases the life burden of patients. Tricarboxylic acid (TCA) cycle metabolites have recently drawn considerable attention in the field of bone tissue regeneration due to their bio-safety, low cost, structural stability, and effectiveness. However, the development of TCA cycle metabolite-modified biomimetic grafts for skull bone regeneration via a facile and general approach remains lacking. Moreover, the mechanism underlying the release of TCA cycle metabolites from biomaterials in immune responses and mesenchymal stem cells (MSCs) fate (migration and differentiation) remain unknown. Herein, inspired by the Hofmeister effects, we developed a series of TCA metabolite (in the form of sodium salt)-coordinated biomimetic hydrogels (CGG) with strong mechanical and anti-swelling performances. Importantly, the sodium citrate (Na3Cit)-treated CGG hydrogels (CGG-Cit) with the highest mechanical modulus and strength significantly promoted skull bone regeneration in rats and mice. Mechanistically, using a transgenic mouse model, bulk RNA sequencing, and single-cell RNA sequencing, we demonstrated that CGG-Cit promotes Gli1+ MSCs migration via neutrophil-secreted OSM. Our results also indicate that CGG-Cit improved osteogenesis via enhanced H3K9ac modification on osteogenic master genes. Taken together, the immune microenvironments and MSCs fate-regulated biomimetic hydrogels developed herein represent a highly efficient and facile approach toward skull bone tissue regeneration with great potential for bench-to-bedside translation.

Project description:Cranial bone defect is a major clinical challenge that increases the life burden of patients. Tricarboxylic acid (TCA) cycle metabolites have recently drawn considerable attention in the field of bone tissue regeneration due to their bio-safety, low cost, structural stability, and effectiveness. However, the development of TCA cycle metabolite-modified biomimetic grafts for skull bone regeneration via a facile and general approach remains lacking. Moreover, the mechanism underlying the release of TCA cycle metabolites from biomaterials in immune responses and mesenchymal stem cells (MSCs) fate (migration and differentiation) remain unknown. Herein, inspired by the Hofmeister effects, we developed a series of TCA metabolite (in the form of sodium salt)-coordinated biomimetic hydrogels (CGG) with strong mechanical and anti-swelling performances. Importantly, the sodium citrate (Na3Cit)-treated CGG hydrogels (CGG-Cit) with the highest mechanical modulus and strength significantly promoted skull bone regeneration in rats and mice. Mechanistically, using a transgenic mouse model, bulk RNA sequencing, and single-cell RNA sequencing, we demonstrated that CGG-Cit promotes Gli1+ MSCs migration via neutrophil-secreted OSM. Our results also indicate that CGG-Cit improved osteogenesis via enhanced H3K9ac modification on osteogenic master genes. Taken together, the immune microenvironments and MSCs fate-regulated biomimetic hydrogels developed herein represent a highly efficient and facile approach toward skull bone tissue regeneration with great potential for bench-to-bedside translation.

Project description:To understand the tumor microenvironment changes in terms of transcriptome upon PIKfyve inhibition by small molecule ESK981 and the immune checkpoint inhibitor anti-PD-1 in Myc-CaP syngeneic mouse model.

Project description:Biomaterial-based bone tissue engineering offers a promising prospect for the treatment of bone defects. In particular, the ability of biomaterials to regulate the immune microenvironment of the defect site is essential for effective bone regeneration. Electro-biomaterials have been confirmed to induce macrophage M2 polarization through metabolic pathways, thereby enhancing bone regeneration. Considering the central role of mitochondria in cellular metabolism and their ability to influence the function of neighboring cells through intercellular transfer, and inspired by the fact that tumor cells can uptake mitochondria from immune cells to generate energy, we hypothesize that the metabolic activation of immune cells by electro-materials can be transmitted to preosteoblasts through mitochondria to promote bone repair. Therefore, this study proposed a conductive micro-hydrogel (CMH) system composed of conductive hydrogel microspheres made from GelMA and poly(3,4-ethylenedioxythiophene):poly(styrenesulfonate) (PEDOT:PSS), which served as scaffolds for defect filling, and a biomimetic periosteum made from poly-l-lactic acid (PLLA) and polydopamine (PDA) for microsphere immobilization and isolation of soft tissue. The microspheres exhibited excellent tissue support and degradation properties, their high specific surface area enhanced tissue remodeling, and their good conductivity eliminated free radicals and induced macrophage M2 polarization, which were confirmed by tests of mechanical property, swelling and degradation, conductivity and assays of cellular biocompatibility, ROS generation, and macrophage phenotype. In vivo experiments using a rat mandibular defect model confirmed the excellent bone repair capabilities of the CMH system, and transcriptomics, metabolomics, and metabolic testing revealed that the CMH system upregulated the oxidative phosphorylation pathway of macrophage, enhancing mitochondrial respiration and ATP production. Mitochondrial tracing experiments demonstrated the transfer of macrophage mitochondria to preosteoblasts, resulting in enhanced metabolic activity and osteogenic differentiation of preosteoblasts. This study may be the first suggest that conductive biomaterials facilitate osteogenic immunomodulation through mitochondrial transfer, which provides a promising method for regulating the immune microenvironment and reveals a novel pathway by which M2 macrophages enhance osteogenesis.

Project description:CD4+ helper T (Th) cells are critical regulators of immune responses but their role in breast cancer is currently unknown. This work aims to characterize Th cells infiltrating invasive primary human breast tumors, analyze the influence by the tumor microenvironment and identify Th cell specific prognostic gene signatures. CD4+ T cells isolated from the tumor (TIL), axillary lymph node (LN) and blood (PB) of 10 patients were analyzed on Affymetrix U133 Plus 2.0 arrays. A confirmation set of 60 patients were studied by flow cytometry, qRT-PCR or immunohistochemistry and analyzed according to the extent of the tumor immune infiltrate. Gene expression profiles of freshly isolated TIL were also compared with TIL that had been rested overnight or with CD4+ T cells [non-stimulated (NS) or stimulated (S)] from healthy donor PB treated with tumor supernatant (SN). Comparing gene expression profiles of donor blood derived total CD4+ T cells [non-stimulated (NS)] with and without tumor supernatant (SN) treatment Total CD4+ T cells from a healthy donor blood (NS) were treated (and as control: untreated samples in biological triplicate) with SN from fresh breast tumor homogenates of 3 patients and analyzed on Affymetrix U133 Plus 2.0 arrays