Project description:Canine adipose-derived mesenchymal stem cells (cAD-MSCs) show therapeutic promise for their regenerative potential, particularly in their secretome. However, concerns arise regarding the impact of in vitro cultivation need for storing therapeutic doses, prompting this study to comprehensively explore the impact of in vitro aging on gene expression and secretome composition. The study involved collecting abdominal adipose tissue samples from nine healthy female dogs, from which cAD-MSCs were extracted and cultured. Stem cells were validated through trilineage differentiation assays and flow cytometry immunophenotyping. Gene expression profiling, using RT-qPCR array and cAD-MSCs secretome LC-MS/MS analysis, were conducted at passages 3 and 6 to reveal gene expression and protein composition alterations during in vitro culture. Gene expression profiling of in vitro aged cAD-MSCs revealed expression alterations, while significant downregulation was observed in two MSC-associated genes. Proteomic analysis revealed 10% distinctively expressed proteins, and several up- and downregulations. Grouping these proteins with biologically significant ones, Gene Ontology Panther Pathway analysis revealed that P3 proteins were significantly associated with cytoskeletal regulation, nicotinic acetylcholine receptor signaling, inflammation mediated by chemokine and cytokine signaling, Wnt signaling, and CCKR signaling map. In contrast, P6 proteins were linked to the xanthine and guanine salvage pathway, adenine and hypoxanthine salvage pathway, and blood coagulation pathway. To the best of our knowledge, this study presents the first original perspective on the changes in secretome composition that occur when cAD-MSCs age in vitro. Our findings highlight significant changes that, in conclusion, indicate the regenerative potential of cAD-MSCs and that their secretome may be compromised due to in vitro aging. Consequently, our study suggests a preference for earlier passages when considering these cells for therapeutic applications.

Project description:Canine adipose-derived mesenchymal stem cells (cAD-MSCs) show therapeutic promise for their regenerative potential, particularly in their secretome. However, concerns arise regarding the impact of in vitro cultivation need for storing therapeutic doses, prompting this study to comprehensively explore the impact of in vitro aging on gene expression and secretome composition. The study involved collecting abdominal adipose tissue samples from nine healthy female dogs, from which cAD-MSCs were extracted and cultured. Stem cells were validated through trilineage differentiation assays and flow cytometry immunophenotyping. Gene expression profiling, using RT-qPCR array and cAD-MSCs secretome LC-MS/MS analysis, were conducted at passages 3 and 6 to reveal gene expression and protein composition alterations during in vitro culture. Gene expression profiling of in vitro aged cAD-MSCs revealed expression alterations, while significant downregulation was observed in two MSC-associated genes. Proteomic analysis revealed 10% distinctively expressed proteins, and several up- and downregulations. Grouping these proteins with biologically significant ones, Gene Ontology Panther Pathway analysis revealed that P3 proteins were significantly associated with cytoskeletal regulation, nicotinic acetylcholine receptor signaling, inflammation mediated by chemokine and cytokine signaling, Wnt signaling, and CCKR signaling map. In contrast, P6 proteins were linked to the xanthine and guanine salvage pathway, adenine and hypoxanthine salvage pathway, and blood coagulation pathway. To the best of our knowledge, this study presents the first original perspective on the changes in secretome composition that occur when cAD-MSCs age in vitro. Our findings highlight significant changes that, in conclusion, indicate the regenerative potential of cAD-MSCs and that their secretome may be compromised due to in vitro aging. Consequently, our study suggests a preference for earlier passages when considering these cells for therapeutic applications.

Project description:Cyclic regeneration of the endometrium, and its repair after parturition or injury, are crucial for successful reproduction. Mesenchymal stem cells (MSCs) derived from bone marrow (BM-MSC) facilitate tissue repair via their secretome, which contains growth factors and cytokines that promote wound healing. Despite the implication of MSCs in endometrial regeneration and repair, the mechanisms remain unclear. This study tested the hypothesis that the secretome of MSCs from human BM upregulates human endometrial stromal cell (HESC) proliferation, migration and invasion, and activates pathways to increase HESC motility. MSCs were purchased from ATCC (BM-MSC-1) and cultured from the BM aspirate of a healthy female donor (BM-MSC-2). Indirect co-culture of MSCs and hTERT-immortalized HESCs via a transwell system studied the effect of the BM-MSC secretome on HESC proliferation, migration, and invasion. To study the effect of the MSC secretome on HESC gene expression, HESCs were exposed to the BM-MSC secretome via indirect co-culture for 24 h. Total RNA was extracted from HESCs for RNA sequencing (RNA-Seq). Differentially expressed genes (DEG) and significantly altered pathways were identified. Indirect co-culture of HESCs with BM- MSCs resulted in significant increase in HESC migration and invasion regardless of the source of MSCs. Effects on cellular proliferation varied among the BM-MSC source. Exposure of HESCs to the secretome of BM-MSCs changed the expression of 10,141 genes with FDR < 0.05. There was overlap among 4351 genes between HESCs exposed to BM-MSC-1 and BM-MSC-2, including upregulated expression of cell motility genes common to both BM-MSC exposures. Increased HESC motility by the secretome of BM-MSC appears to be mediated by paracrine and autocrine mechanisms, in part by modifying HESC gene expression. These data support the potential for leveraging the MSC secretome as a novel cell-free therapy in the treatment of disorders of endometrial regeneration.

Project description:Studying the safety and efficacy of two treatment protocols for Multiple sclerosis (MS) patients using Mesenchymal Stromal/Stem Cells MSCs subtype derived from the umbilical cord; UC-MSCs and their secretome

Project description:Background: Advanced Renal cell carcinoma (RCC) is therapeutically challenging. RCC progression is facilitated by mesenchymal stem/stromal cells (MSCs) that exert remarkable tumor tropism. The specific mechanisms mediating MSCs’ migration to RCC remain unknown. Here, we comprehensively analyzed RCC secretome to identify MSCs attractants. Methods: Conditioned media (CM) were collected from five RCC-derived cell lines (Caki-1, 786-O, A498, KIJ265T, KIJ308T) and non-tumorous control cell line (RPTEC/TERT1) and analyzed using cytokine arrays targeting 274 cytokines in addition to global CM proteomics. MSCs were isolated from bone marrow of patients undergoing standard orthopedic surgeries. RCC CM and the selected recombinant cytokines were used to analyze their influence on MSCs migration and microarray-targeted gene expression. The expression of genes encoding cytokines was evaluated in 100 matched-paired control-RCC tumor samples. Results: When compared with normal cells, CM from advanced RCC cell lines (Caki-1, KIJ265T) were the strongest stimulators of MSCs migration. Targeted analysis of 274 cytokines and global proteomics of RCC CM revealed decreased DPP4 and EGF, as well as increased AREG, FN1, and MMP1, with consistently altered gene expression in RCC cell lines and tumors. AREG and FN1 stimulated, while DPP4 attenuated MSCs migration. RCC CM induced MSCs’ transcriptional reprogramming, stimulating the expression of CD44, PTX3, and RAB27B. RCC cells secreted hyaluronic acid (HA), a CD44 ligand mediating MSCs’ homing to the kidney. AREG emerged as an upregulator of MSCs’ transcription. Conclusions: advanced RCC cells secrete AREG, FN1 and HA to induce MSCs migration, while DPP4 loss prevents its inhibitory effect on MSCs homing. RCC secretome induces MSCs’ transcriptional reprograming to facilitate their migration. The identified components of RCC secretome represent potential therapeutic targets. We used microarrays to determine the effect of the conditioned media (CM) collected from two RCC-derived cell lines (Caki-1, KIJ265T) and non-tumorous control cell line (RPTEC/TERT1) on the transcriptome change in mesenchymal stem/stromal cells (MSCs).

Project description:We established a useful protocol for generating insulin -producing cells (IPCs) from canine adipose mesenchymal stem cells (cAD-MSCs). IPCs were induced from cAD-MSCs with the three-stepwise protocol. For the first stage , cAD-MSCs was induced to definitive endoderm (DE) with the cooperation of Chir99021 and Activin A for 3 days. For the second stage, pancreatic endocrine (PE) progenitor was induced from DE after treatment with taurine, retinoic acid, FGF2 EGF, TGFβ inhibitor, dorsomorphin, nicotinamide, and DAPT for the next 5 days. In the last stage, the combination of taurine, nicotinamide, Glp-1, forskolin, PI3K inhibitor, and TGFβ inhibitor was used to yield efficiently functional IPCs from PE precursors for 5 days. To indentify differences in the expression pattern of genes related to pancreatic beta cell development, we performed real time quantitative polymerase chain reaction (RT-qPCR).

Project description:Human induced pluripotent stem cells (iPSCs) - derived mesenchymal stromal cells (iMSCs) are a potentially useful cell type for circumventing ageing-related shortfalls associated with primary mesenchymal or skeletal stromal cells (MSCs/SSCs). To date, the extent of the reflection of ageing-hallmarks in iMSCs differentiated from iPSCs derived from elderly donors remains unclear. In this study, we show that fetal (55 days post conception) femur-derived MSCs and MSCs isolated from aged (60 – 74 years) donors differ in their transcriptome and secretome profile. Yet, iMSCs irrespective of donor age and cell type acquired a rejuvenation gene signature, specifically, INHBE, DNMT3B, POU5F1P1, CDKN1C, GCNT2; also present in pluripotent stem cells but not observed in the parental MSCs. Furthermore, dendrograms generated from the transcriptomes of iMSCs derived from the human embryonic stem cell line H1, fetal and aged MSCs always clustered together with the parental fetal femur-derived MSCs. In addition, these were distinct from MSCs isolated from aged donors when comparing gene ontologies (GOs) related to ageing processes. Critically, in terms of regenerative medicine applications, iMSCs re-acquired a similar secretome (e.g. SERPINE1, SDF-1a, HGF, IL6, IL10, THBS1) to that of the parental fetal MSCs, thus re-enforcing their capabilities of imparting context dependent paracrine signaling.

Project description:<p><strong>BACKGROUND:</strong> Ischemia/reperfusion injury (IRI) is the leading cause of acute kidney injury (AKI). The current standard of care focuses on supporting kidney function, stating the need for more efficient and targeted therapies to enhance repair. Mesenchymal Stromal Cells (MSCs) and their secretome, either as conditioned medium (CM) or extracellular vesicles (EVs), have emerged as promising options for regenerative therapy, however, their full potential in treating AKI remains unknown.</p><p><strong>METHODS:</strong> In this study, we employed an in vitro model of chemically-induced ischemia using antimycin A combined with 2-deoxy-D-glucose to induce ischemic injury in proximal tubule epithelial cells. Afterwards, we evaluated the effects of MSC secretome, CM or EVs obtained from adipose tissue, bone marrow and umbilical cord, on ameliorating the detrimental effects of ischemia. To assess the damage and treatment outcomes, we analyzed cell morphology, mitochondrial health parameters (mitochondrial activity, ATP production, mass and membrane potential) and overall cell metabolism by metabolomics.</p><p><strong>RESULTS:</strong> Our findings show that ischemic injury caused cytoskeletal changes confirmed by disruption of the F-actin network, energetic imbalance as revealed by a 50% decrease in the oxygen consumption rate, increased oxidative stress, mitochondrial dysfunction and reduced cell metabolism. Upon treatment with MSC secretome, the morphological derangements were partly restored and ATP production increased by 40-50%, with umbilical cord-derived EVs being most effective. Furthermore, MSC treatment led to phenotype restoration as indicated by an increase in cell bioenergetics, including increased levels of glycolysis intermediates, as well as an accumulation of antioxidant metabolites.</p><p><strong>CONCLUSION:</strong> Our in vitro model effectively replicated the in vivo-like morphological and molecular changes observed during ischemic injury. Additionally, treatment with MSC secretome ameliorated proximal tubule damage, highlighting its potential as a viable therapeutic option for targeting AKI.</p>

Project description:We found the bone marrow stromal-derived neural progenitor cells secretome have the neural protection effect. Proteomic analysis was performed nn order to analyze the protection factor in the secretome. Keywords: Neural protection, secretome

Project description:Mesenchymal stromal cells (MSCs) have been introduced as promising cell source for regenerative medicine. Besides their multilineage differentiation capacity, MSCs release a wide spectrum of bioactive factors. This secretome holds immunomodulatory and regenerative capacities. In intervertebral disc (IVD) cells, application of MSC secretome has been shown to decrease the apoptosis rate, induce proliferation and promote production of extracellular matrix (ECM). For clinical translation of secretome-based treatment, characterization of the secretome composition is needed to better understand the induced biological processes and identify potentially effective secretomes. Methods: This study aimed to investigate the proteome released by bone marrow derived MSCs following exposure to a healthy, traumatic, or degenerative human IVD environment by mass spectroscopy and quantitative immunoassay analyses. Exposure of MSCs to the proinflammatory stimulus interleukin 1β (IL-1b) was used as control.