Direct differentiation of rat skin fibroblasts into cardiomyocytes

Myocardial infarction (MI) is one of the major cardiovascular diseases caused by diminished supply of nutrients and oxygen to the heart due to obstruction of the coronary artery. Different treatment options are available for cardiac diseases, however, they do not completely repair the damage. Therefore, reprogramming terminally differentiated fibroblasts using transcription factors is a promising strategy to differentiate them into cardiac like cells in vitro and to increase functional cardiomyocytes and reduce fibrotic scar in vivo. In this study, skin fibroblasts were selected for reprogramming because they serve as a convenient source for the autologous cell therapy. Fibroblasts were isolated from skin of rat pups, propagated, and directly reprogrammed towards cardiac lineage. For reprogramming, two different approaches were adopted, i.e., cells were transfected with: (1) combination of cardiac transcription factors; GATA4, MEF2c, Nkx2.5 (GMN), and (2) combination of cardiac transcription factors; GATA4, MEF2c, Nkx2.5, and iPSC factors; Oct4, Klf4, Sox2 and cMyc (GMNO). After 72 h of transfection, cells were analyzed for the expression of cardiac markers at the mRNA and protein levels. For in vivo study, rat MI models were developed by ligating the left anterior descending coronary artery and the reprogrammed cells were transplanted in the infarcted heart. qPCR results showed that the reprogrammed cells exhibited significant upregulation of cardiac genes. Immunocytochemistry analysis further confirmed cardiomyogenic differentiation of the reprogrammed cells. For the assessment of cardiac function, animals were analyzed via echocardiography after 2 and 4 weeks of cell transplantation. Echocardiographic results showed that the hearts transplanted with the reprogrammed cells improved ejection fraction, fractional shortening, left ventricular internal systolic and diastolic dimensions, and end systolic and diastolic volumes. After 4 weeks of cell transplantation, heart tissues were harvested and processed for histology. The histological analysis showed that the reprogrammed cells improved wall thickness of left ventricle and reduced fibrosis significantly as compared to the control. It is concluded from the study that novel combination of cardiac transcription factors directly reprogrammed skin fibroblasts and differentiated them into cardiomyocytes. These differentiated cells showed cardiomyogenic characters in vitro, and reduced fibrosis and improved cardiac function in vivo. Furthermore, direct reprogramming of fibroblasts transfected with cardiac transcription factors showed better regeneration of the injured myocardium and improved cardiac function as compared to the indirect approach in which combination of cardiac and iPSC factors were used. The study after further optimization could be used as a better strategy for cell-based therapeutic approaches for cardiovascular diseases.

Wnt signaling pathway inhibitor promotes mesenchymal stem cells differentiation into cardiac progenitor cells in vitro and improves cardiomyopathy in vivo

BACKGROUND

Cardiovascular diseases particularly myocardial infarction (MI) are the leading cause of mortality and morbidity around the globe. As cardiac tissue possesses very limited regeneration potential, therefore use of a potent small molecule, inhibitor Wnt production-4 (IWP-4) for stem cell differentiation into cardiomyocytes could be a promising approach for cardiac regeneration. Wnt pathway inhibitors may help stem cells in their fate determination towards cardiomyogenic lineage and provide better homing and survival of cells in vivo. Mesenchymal stem cells (MSCs) derived from the human umbilical cord have the potential to regenerate cardiac tissue, as they are easy to isolate and possess multilineage differentiation capability. IWP-4 may promote the differentiation of MSCs into the cardiac lineage.

AIM

To evaluate the cardiac differentiation ability of IWP-4 and its subsequent in vivo effects.

METHODS

Umbilical cord tissue of human origin was utilized to isolate the MSCs which were characterized by their morphology, immunophenotyping of surface markers specific to MSCs, as well as by tri-lineage differentiation capability. Cytotoxicity analysis was performed to identify the optimal concentration of IWP-4. MSCs were treated with 5 μM IWP-4 at two different time intervals. Differentiation of MSCs into cardiomyocytes was evaluated at DNA and protein levels. The MI rat model was developed. IWP-4 treated as well as untreated MSCs were implanted in the MI model, then the cardiac function was analyzed via echocardiography. MSCs were labeled with 1,1'-dioctadecyl-3,3,3',3'-tetramethylindocarbocyanine perchlorate (DiI) dye for tracking, while the regeneration of infarcted myocardium was examined by histology and immunohistochemistry.

RESULTS

MSCs were isolated and characterized. Cytotoxicity analysis showed that IWP-4 was non-cytotoxic at 5 μM concentration. Cardiac specific gene and protein expression analyses exhibited more remarkable results in fourteen days treated group that was eventually selected for in vivo transplantation. Cardiac function was restored in the IWP-4 treated group in comparison to the MI group. Immunohistochemical analysis confirmed the homing of pre-differentiated MSCs that were labeled with DiI cell labeling dye. Histological analysis confirmed the significant reduction in fibrotic area, and improved left ventricular wall thickness in IWP-4 treated MSC group.

CONCLUSION

Treatment of MSCs with IWP-4 inhibits Wnt pathway and promotes cardiac differentiation. These pre-conditioned MSCs transplanted in vivo improved cardiac function by cell homing, survival, and differentiation at the infarcted region, increased left ventricular wall thickness, and reduced infarct size.

Abstract P1138: Combination Of Pluripotency And Cardiac Transcription Factors Reprogram Skin Fibroblasts Into Cardiomyocytes

Direct reprogramming of autologous somatic cells into cardiomyocytes is a novel approach which is being employed for cardiac regeneration. Multiple studies have combined different cardiac-specific factors that could directly reprogram cardiac fibroblasts into induced cardiomyocyte-like cells. However, this approach needs heart biopsy for the isolation of autologous fibroblasts which involves extensive surgical procedures that require precision. In this study, we aimed to develop an approach which can directly reprogram somatic cells into cardiomyocyte-like cells using a combination of pluripotency and cardiac transcription factors. Skin fibroblasts were isolated from rat neonatal pups and were induced into cardiomyocyte-like cells using non-viral integration of cardiac transcription factors (GATA4, Mef2c and Nkx2.5) and OKSIM plasmid carrying the iPSC factors, Sox2, Oct4, Klf4 and cMyc. After 72 h, cells were analyzed for the expression of cardiac markers by qPCR and immunocytochemistry. Gene expression analysis showed significantly higher expression of cardiac markers GATA4, cMHC, Mef2c, cTnT, cTnI, and Nkx2.5 Immunostaining confirmed the expression of cardiac proteins GATA4, cMHC, cTnT, cTnI, and Nkx2.5. These results imply that the transfected cells started differentiating towards cardiac lineage. Transfected cells were also transplanted in rat myocardial infarction (MI) model immediately after ligation of left ventricle descending (LAD) artery. After 2 and 4 weeks of cell transplantation, the animals were assessed for cardiac function via echocardiography. They showed significant improvement in the cardiac function as compared to MI and non-transfected groups. After 4 weeks, the hearts were harvested, and histological analysis was performed for the assessment of fibrosis and left ventricular wall thickness. Rats transplanted with transfected cells showed significantly reduced fibrosis and increased wall thickness as compared to MI and non-transfected groups. In conclusion, transient and combined expression of cardiac transcription and iPSC factors in neonatal somatic cells leads to the transdifferentiation of skin cells into myogenic lineage. This approach can be useful for future therapeutic application for cardiovascular diseases.

Association of specific single nucleotide variants (SNVs) in the promoter and 3'-Untranslated region of Vascular Endothelial growth factor (VEGF) gene with risk and higher tumour grade of head and neck cancers

BACKGROUND

Head and Neck Cancers (HNCs)comprise one of the most frequent cancers in South-Asian region. Vascular Endothelial Growth Factor (VEGF) has a potent role in tumorigenesis and metastasis. Certain common single nucleotide variants (SNVs) in the highly polymorphic VEGF gene are correlated with variations in VEGF functions. The data for these SNVs in HNCs is scarce for South Asian populations. The present study addresses this shortfall. It investigates the association of two VEGF SNVs, -2578C/A (rs699947) in the promoter region and + 936C/T (rs3025039) in 3'-UTR, with the risk of HNCs and tumour characteristics.

METHODS

The study comprised 323 participants with 121 HNC patients and 202 controls. Germline DNA was isolated from peripheral blood samples. PCR-RFLP methods were optimized and validated by Sanger sequencing. After Hardy-Weinberg evaluation, the independent associations were analyzed under the assumptions of different genetic models. The χ² test of independence or Fisher's Exact test (significant p-values at < 0.05) were performed and ORs (odds ratios) with 95% confidence interval were tabulated.

RESULTS

VEGF -2578 A-allele, CA + AA, and AA genotypes had significant protective association against HNCs. The respective ORs were: 0.651 (0.469-0.904), 0.613 (0.381 - 0.985), and 0.393 (0.193-0.804). VEGF + 936 T-allele, CT, and CT + TT genotypes had significantly increased susceptibility for HNCs. The respective ORs were 1.882 (1.001 - 3.536), 2.060 (1.035 - 4.102), and 2.023 (1.032 - 3.966). Additionally, VEGF + 936 CT and CT + TT genotypes showed significant associations with higher tumour grade (p-values < 0.029, and < 0.037, respectively).

CONCLUSION

The present study is the foremost report of independent and unique associations of the investigated VEGF SNVs with HNCs.

Clinical variability of tetrasomy 12p

We describe five patients with tetrasomy 12p (one previously reported). These patients exhibit a very wide range of phenotypic features from that of classic Pallister-Killian syndrome to only mild learning disabilities with pigmentary skin changes. As such, these cases highlight the fact that tetrasomy 12p [i(12p)] and Pallister-Killian syndrome are not synonymous, although this combination of genotype and phenotype is often seen. This information is especially important in prenatally ascertained i(12p). The full spectrum of phenotypic possibilities associated with this chromosome aneuploidy should be discussed in prenatal counseling.

Evaluation of three oil-adjuvant vaccines against Pasteurella multocida in buffalo calves

Three oil-adjuvant vaccines of Pasteurella multocida 6:B were evaluated with respect to the level and duration of the humoral immune response produced in buffalo calves. Preparation 1 was a water-in-oil emulsion containing Marcol 52, Montanide 888 and antigen at a ratio of 6:1:3. Preparation 2 was a double emulsion containing Marcol 52, Arlacel A and Tween 80 in addition to antigen. Preparation 3 contained alpha-d-tocopheryl acetate (vitamin E), Montanide 888 and antigen. All three preparations induced a similar sustained immune response in buffalo calves beyond 270 days post-vaccination.

Serological evaluation of Pasteurella multocida antigens associated with protection in buffalo calves

Different antigens of Pasteurella multocida Carter's type 6:B including whole bacterium, antigen heated at 56 degrees C, antigen heated at 100 degrees C, sonicated antigen, capsular antigen, potassium thiocyanate extract, lipopolysaccharide and sodium salicylate extract were evaluated to assess protection in buffalo calves against haemorrhagic septicaemia. Sera from calves with known protection status in experimental challenge were titrated by enzyme-linked immunosorbent assay (ELISA) against all antigens. Capsular antigen extracted with 2.5% sodium chloride was superior to other antigens for assessing protection status of buffalo calves against P. multocida by ELISA. This capsular antigen was able to differentiate clearly between well-protected, protected and unprotected animals.

Studies on the aetiology of hydropericardium syndrome (Angara disease) in broilers

The study was carried out to determine the aetiological agent(s) associated with hydropericardium syndrome (Angara disease) in broilers in Pakistan. The results indicate that in addition to adenovirus some other agent is involved in causing the disease but that this agent requires co-infection by an adenovirus for the reproduction of the typical signs of the syndrome. The nature of this agent remains unknown because no discrete virus or virus-like particle could be seen by electron microscopy.