Project description:Background: Bone marrow-derived multipotent progenitor cell (MPC) transplantation leads to short term functional and bioenergetic improvement in a porcine model of postinfarction Left Ventricular (LV) remodeling despite a low engraftment rate. However, the long term outcome after MPC transplantation is unknown. Methods and Results: The objectives of this study were to determine the long term functional outcome after MPC transplantation in a porcine model of postinfarction LV remodeling and to elucidate its mechanisms. Myocardial infarction (MI) was created by ligating the first and second diagonal branches of the Left anterior descending artery after open thoracotomy. Intramyocardial injection of 50 million lacZ labeled MPC was performed in the periscar region (Cell, n=7) with 5 equal injections immediately after MI, while in control animals (CONT, n=7; only 6 were profiled by microarray) saline was injected. Outcome was assessed temporally for 4 months with MRI and P-31 MRS. Engraftment was studied on histology and gene chip (Affymetrix) array analysis was used to study differential expression of genes in the two groups at 4 months. MPC treatment resulted in improvement of ejection fraction as early as 10 days after MI (32.2±5.5 vs. 43.4±5.1 in CONT and Cell respectively, p <0.05). This improvement was seen each month and persisted up to 4 months (35.7±5.0 vs. 51.2±4.8 in CONT and Cell respectively, p<0.005). PCr/ATP ratio improved with MPC transplantation (1.88±0.11 vs. 2.13±0.13 in CONT and Cell respectively, p<0.05). Under increased workload with inotropic stimulation, the bioenergetic differences were even more pronounced. There was no significant difference in scar size (scar/LV area*100) at 10 days post infarction (9.7±2.3 vs. 8.3±1.5 in CONT and Cell respectively). However, at 4 months there was a significant decrease in scar size in the MPC treated animals (8.6±2.4 vs. 4.6±1.0 in CONT and Cell respectively, p <0.05). No significant engraftment of MPC was observed on histology at 4 months. Gene chip array analysis identified several genes which were differentially expressed in the two groups. MPC transplantation was associated with a downregulation of mitochondrial oxidative enzymes, increased levels of MEF2a (Myocyte Enhancer Factor 2a) and ZFP91 (Zinc finger protein 91). Conclusion: MPC transplantation results in long term improvement in ventricular function and myocardial energetics that is associated with a decreased scar size and differential expression of genes. 13 swine were randomized after myocardial infarction to receive either 50 million stem cells (n=7) or saline only (n=6). The pigs were followed for a total of 4 months after transplantation with MRI occurring at baseline, 10 days, 1 month and then subsequently each month for 4 months. At the end of the study open-chest NMR spectroscopy was performed and then after sacrifice histology and microarray analysis was done on the tissue samples.

Project description:Human pluripotent stem cell-derived cardiomyocytes (CMs) are a promising tool for cardiac cell therapy. To optimize graft cells for cardiac reconstruction, we compared the engraftment efficiency of intramyocardially-injected undifferentiated-induced pluripotent stem cells (iPSCs), day4 mesodermal cells, and day8, day20, and day30 purified iPSC-CMs after initial differentiation by tracing the engraftment ratio (ER) using in vivo bioluminescence imaging. This analysis revealed the ER of day20 CMs was significantly higher compared to other cells. Transplantation of day20 CMs into the infarcted hearts of immunodeficient mice showed significant functional improvement. Moreover, the imaging signal and ratio of Ki67-positive CMs at 3 months post injection indicated engrafted CMs proliferated in the host heart. Although this graft growth reached a plateau at 3 months, histological analysis confirmed progressive maturation from 3 to 6 months. These results suggested that day20 CMs had very high engraftment, proliferation, and therapeutic potential in host mouse hearts. Differentiated cells, N=10 Undifferentiated pluripotent stem cells, N=1 Heart samples, N=6

Project description:Human pluripotent stem cell-derived cardiomyocytes (CMs) are a promising tool for cardiac cell therapy. To optimize graft cells for cardiac reconstruction, we compared the engraftment efficiency of intramyocardially-injected undifferentiated-induced pluripotent stem cells (iPSCs), day4 mesodermal cells, and day8, day20, and day30 purified iPSC-CMs after initial differentiation by tracing the engraftment ratio (ER) using in vivo bioluminescence imaging. This analysis revealed the ER of day20 CMs was significantly higher compared to other cells. Transplantation of day20 CMs into the infarcted hearts of immunodeficient mice showed significant functional improvement. Moreover, the imaging signal and ratio of Ki67-positive CMs at 3 months post injection indicated engrafted CMs proliferated in the host heart. Although this graft growth reached a plateau at 3 months, histological analysis confirmed progressive maturation from 3 to 6 months. These results suggested that day20 CMs had very high engraftment, proliferation, and therapeutic potential in host mouse hearts.

Project description:Human hair follicles undergo repetitive cycles of growth throughout their lifetime. During the hair follicle cycle, functional and structural changes occur within the surrounding skin environment. However, skin that experienced a deep injury lacks cycling hair follicles and turns into a mass of unremodelled scar tissue. We hypothesise that re-introducing cycling hair follicles into human scars will stimulate skin remodelling improving fibrotic tissue. To determine the transcriptional events underlying remodelling of scar dermis after hair follicle transplantation, we used Affymetrix microarrays to perform profiling of scar dermis before (0 mo), and at three time points after hair transplantation transplantation: 2, 4, and 6 months.

Project description:Background: Right ventricular (RV) and left ventricular (LV) myocardium differ in their response to pressure-overload hypertrophy (POH). In this report we use microarray and proteomic analyses to identify pathways modulated by LV-, and RV-POH in the immature heart. Methods: Newborn New Zealand White rabbits underwent banding of the descending thoracic aorta (LV-POH; n=6). RV-POH was achieved by banding the pulmonary artery (n=6). Sham–control animals (SC; n=6 each) were sham-manipulated. Following 4 (LV-POH) and 6 weeks (RV-POH) recovery, the hearts were removed and matched sample RNA and proteins were isolated for microarray and proteomic analysis. Results: There was no difference in body weight in RV-, LV-POH vs. SC but there was a significant increase vs. SC in RV (3.2±0.8g vs. 1.2±0.3g; P<0.01) and LV weight (7.08±0.6g vs. 4.02±0.2g; P<0.01). Fractional area change (RV-POH) and shortening fraction (LV-POH) decreased significantly (23±6 vs. 47±6 and 21±4 vs.44±2, respectively, P<0.01). Microarray analysis demonstrated that LV-POH enriched pathways for oxidative phosphorylation, mitochondria energy pathways, actin, ILK, hypoxia, calcium and protein kinase-A signalling. RV-POH enriched pathways for cardiac oxidative phosphorylation. Proteomic analysis revealed 19 proteins were uniquely expressed in LV-POH vs. SC. Functional annotation clustering analysis indicated significant enrichment for the mitochondrion, cellular macromolecular complex assembly and oxidative phosphorylation. RV-POH had 15 uniquely expressed proteins vs. SC. Functional annotation clustering analysis indicated significant enrichment in structural constituents of muscle, cardiac muscle tissue development and calcium handling. Conclusion: Our results identify unique transcript and protein expression profiles in LV, RV-POH and provide new insight into the biological basis of ventricular specific hypertrophy.

Project description:Background: Right ventricular (RV) and left ventricular (LV) myocardium differ in their response to pressure-overload hypertrophy (POH). In this report we use microarray and proteomic analyses to identify pathways modulated by LV-, and RV-POH in the immature heart. Methods: Newborn New Zealand White rabbits underwent banding of the descending thoracic aorta (LV-POH; n=6). RV-POH was achieved by banding the pulmonary artery (n=6). Sham–control animals (SC; n=6 each) were sham-manipulated. Following 4 (LV-POH) and 6 weeks (RV-POH) recovery, the hearts were removed and matched sample RNA and proteins were isolated for microarray and proteomic analysis. Results: There was no difference in body weight in RV-, LV-POH vs. SC but there was a significant increase vs. SC in RV (3.2±0.8g vs. 1.2±0.3g; P<0.01) and LV weight (7.08±0.6g vs. 4.02±0.2g; P<0.01). Fractional area change (RV-POH) and shortening fraction (LV-POH) decreased significantly (23±6 vs. 47±6 and 21±4 vs.44±2, respectively, P<0.01). Microarray analysis demonstrated that LV-POH enriched pathways for oxidative phosphorylation, mitochondria energy pathways, actin, ILK, hypoxia, calcium and protein kinase-A signalling. RV-POH enriched pathways for cardiac oxidative phosphorylation. Proteomic analysis revealed 19 proteins were uniquely expressed in LV-POH vs. SC. Functional annotation clustering analysis indicated significant enrichment for the mitochondrion, cellular macromolecular complex assembly and oxidative phosphorylation. RV-POH had 15 uniquely expressed proteins vs. SC. Functional annotation clustering analysis indicated significant enrichment in structural constituents of muscle, cardiac muscle tissue development and calcium handling. Conclusion: Our results identify unique transcript and protein expression profiles in LV, RV-POH and provide new insight into the biological basis of ventricular specific hypertrophy. 3 different conditions: PAB-RV vs. Sham-control RV, PAB-RV [test] vs. PAB-LV [control], AOB-LV vs. Sham-control LV.

Project description:Cell transplantation therapy is considered a novel and promising strategy in regenerative medicine. Recent studies point out that paracrine effects and inflammation induced by transplanted cells are key factors for the improvement of myocardial function. The present study aims at differentiating paracrine effects from inflammatory reactions after cell transplantation. Therefore, in vitro induced apoptotic bodies were transplanted after myocardial infarction in a rat model. Eight weeks after transplantation, the functional results showed no improvement in left ventricular function. Histological analysis revealed no significant differences in the amount of infiltrated cells and collagen content did not differ among the four groups, which sustains the functional data. Surprisingly, angiogenesis increased in groups with apoptotic bodies derived from HUVEC and endothelial progenitor cells, but not from fibroblasts. A complex genetic analysis of apoptotic bodies indicated that miRNAs could be responsible for these changes. In conclusion, our study demonstrates both that neoangiogenesis alone is not sufficient to improve function and that inflammation is critical for scar remodeling and improvement of the heart function after cell therapy. Given what we have learned about microRNAs, we hypthesized that the molecular mechanisms of angiogenesis induction could involve apoptotic bodies exerting paracrine angiogenic effects. Using GeneChip miRNA 3.0 Array, microRNAs were analysed in apoptotic bodies from endothelial progenitor cells (EPCs), human umbilical veno-endothelial cells (HUVECs), and fibroblasts. From human EPCs, human dermal fibroblasts, and HUVECs, apoptotic bodies were isolated after treatment with cycloheximide in hypoxia for 24 hours.

Project description:In the context of lentiviral vector (LV)-mediated gene correction of hematopoietic stem and progenitor cells (HSPC), the viral origin of LV could trigger cellular responses with potential functional consequences that have not been investigated to date. Here, a time-course genome-wide transcriptional profiling of transduced human HSPC reveals a remarkably limited impact of LV on cellular gene expression, supporting some stealth features of the vector. In particular, LV efficiently escaped innate immune sensing that instead led to robust type I IFN signaling upon transduction with a gamma-retroviral vector. However, recognition of LV DNA prior to integration did trigger DNA damage responses that were activated also by non-integrating Adeno-associated vector DNA. As a consequence of this transient p53 activation, transduced HSPC showed increased apoptosis in vitro and reduced engraftment in vivo at limiting cell doses, but no long-term impact or competitive disadvantage were detected. Pharmacological inhibition of the LV signaling partially rescued both apoptosis and engraftment, potentially providing a novel strategy to further dampen the impact of ex vivo gene therapy on HSPC. Overall, our results shed light on the molecular mechanisms of viral vector sensing in HSPC and provide critical insight for the development of more stealth gene therapy strategies.

Project description:Cell transplantation therapy is considered a novel and promising strategy in regenerative medicine. Recent studies point out that paracrine effects and inflammation induced by transplanted cells are key factors for the improvement of myocardial function. The present study aims at differentiating paracrine effects from inflammatory reactions after cell transplantation. Therefore, in vitro induced apoptotic bodies were transplanted after myocardial infarction in a rat model. Eight weeks after transplantation, the functional results showed no improvement in left ventricular function. Histological analysis revealed no significant differences in the amount of infiltrated cells and collagen content did not differ among the four groups, which sustains the functional data. Surprisingly, angiogenesis increased in groups with apoptotic bodies derived from HUVEC and endothelial progenitor cells, but not from fibroblasts. A complex genetic analysis of apoptotic bodies indicated that miRNAs could be responsible for these changes. In conclusion, our study demonstrates both that neoangiogenesis alone is not sufficient to improve function and that inflammation is critical for scar remodeling and improvement of the heart function after cell therapy. Given what we have learned about microRNAs, we hypthesized that the molecular mechanisms of angiogenesis induction could involve apoptotic bodies exerting paracrine angiogenic effects. Using GeneChip miRNA 3.0 Array, microRNAs were analysed in apoptotic bodies from endothelial progenitor cells (EPCs), human umbilical veno-endothelial cells (HUVECs), and fibroblasts.

Project description:We used microarrays to characterize transcriptome profiles of rat vocal fold tissue following surgical injury (vs. naive tissue); rat vocal fold fibroblasts harvested from scar tissue at the 60 d time point (vs. naive fibroblasts); rat vocal fold scar fibroblasts treated with siRNA against the collagen chaperone protein rat gp46 (vs. scramble siRNA).