稳定转染MiR-499对P19CL6细胞向心肌细胞分化的影响

小鼠miR-499基因包含在心肌重链肌球蛋白Myh7b基因的第19内含子中,并且在心肌细胞中特异表达,然而其在心肌细胞中表达的生物学功能和意义尚不清楚.利用可体外分化为心肌细胞的P19CL6细胞建立稳定表达miR-499的细胞株对研究miR-499的生物学功能具有重要意义.根据小鼠miR-499基因序列,设计PCR引物...     

Upregulations of Gata4 and oxytocin receptor are important in cardiomyocyte differentiation processes of P19CL6 cells

Oxytocin induces P19 cells to differentiate into cardiomyocytes possibly through the oxytocin/oxytocin receptor system. We added oxytocin to the growth medium of P19CL6, a subline of P19, but they did not differentiate into cardiomyocytes as indicated by RT-PCR and Western blotting results. During the cardiac commitment time of P19CL6 cells, the mRNA expression levels of the oxytocin receptor were upregulated by the addition of oxytocin as well as DMSO, but an upregulation of Gata4 expression levels was only observed for the cells induced by DMSO. The in silico analysis of the upstream sequence of the oxytocin receptor predicted putative binding sites for Gata4 and Nkx2.5. These results suggest that upregulations of the oxytocin receptor and Gata4 are important for cardiomyocyte differentiation processes.     

抑制NHE1活性对干细胞向心肌分化的影响

Na /H 交换蛋白1(NHE1)在心肌细胞发育过程中发挥重要的调节功能.为深入探索NHEl活性对干细胞向心肌分化过程中产生的影响,采用二甲基亚砜(DMSO)诱导P19干细胞向心肌细胞分化,同时在培养液中添加NHE1抑制荆EMD87580,对诱导后形成的类胚体进行检测.通过细胞形态观察、免疫组织化学染色及检测心肌特异表达基因等方法证明,经诱导形成的类胚体贴壁生长后,会向心肌细胞分化并出现跳动细胞团.而经过抑制剂处理的P19干细胞尽管能够形成类胚体且贴壁培养后细胞仍具有增殖活力,细胞团周边也较整齐,但未出现向心肌细胞分化的现象.这一结果表明,抑制NHE1的活性,能够影响P19干细胞向心肌细胞的分化作用.     

Insulin induces proliferation and cardiac differentiation of P19CL6 cells in a dose‐dependent manner

Insulin is a peptide hormone produced by beta cells of the pancreas. The roles of insulin in energy metabolism have been well studied, with most of the attention focused on glucose utilization, but the roles of insulin in cell proliferation and differentiation remain unclear. In this study, we observed for the first time that 10 nmol/L insulin treatment induces cell proliferation and cardiac differentiation of P19CL6 cells, whereas 50 and 100 nmol/L insulin treatment induces P19CL6 cell apoptosis and blocks cardiac differentiation of P19CL6 cells. By using real‐time polymerase chain reaction (PCR) and Western blotting analysis, we found that the mRNA levels of cyclin D1 and α myosin heavy chain (α‐MHC) are induced upon 10 nmol/L insulin stimulation and inhibited upon 50/100 nmol/L insulin treatment, whereas the mRNA levels of BCL‐2‐antagonist of cell death (BAD) exists a reverse trend. The similar results were observed in P19CL6 cells expressing GATA‐6 or peroxisome proliferator‐activated receptor α (PPARα). Our results identified the downstream targets of insulin, cyclin D1, BAD, α‐MHC, and GATA‐4, elucidate a novel molecular mechanism of insulin in promoting cell proliferation and differentiation.     

Involvement of Yes‐associated protein 1 (YAP1) in doxorubicin‐induced cytotoxicity in H9c2 cardiac cells

Cardiac cell death is one of the major events implicated in doxorubicin‐induced cardiotoxicity, which leads to heart failure. We recently reported that Yes‐associated protein 1 (YAP1) regulates cell survival and apoptosis. However, it is unclear whether YAP1 regulates doxorubicin‐induced cell death in cardiomyocytes. We investigated whether YAP1 is involved in doxorubicin‐induced cell death using H9c2 cardiac cells and mouse heart. In an in vivo study, YAP1 protein expression was significantly decreased in hearts of doxorubicin‐treated mice with increased caspase‐3 activation. Doxorubicin also caused cell death by increasing caspase‐3 activation in H9c2 cells. Doxorubicin reduced YAP1 protein expression and messenger RNA expression accompanied by increased phosphorylation of YAP1 at Ser127. Doxorubicin further increased cell death with increased caspase‐3/7 activation in the absence of YAP1 when compared with doxorubicin or siYAP1 treatment alone. Overexpression of constitutively active YAP1 (YAP1–5SA) using an adenovirus gene transfer technique significantly reversed doxorubicin‐induced cell death by decreasing caspase‐3/7 activation in H9c2 cells. Akt, a potential prosurvival factor, decreased in doxorubicin‐ and YAP1 short interfering RNA (siRNA)‐treated cells. Doxorubicin further significantly decreased Akt protein expression when YAP1 was silenced. Overexpression of YAP1 canceled decreased Akt protein expression induced by doxorubicin treatment in H9c2 cells. In conclusion, these results suggest that doxorubicin‐induced cardiac cell death is mediated in part by down‐regulation of YAP1 and YAP1‐targeted gene, Akt. Modulating YAP1 and its related Hippo pathway on local cardiomyocytes may be a promising therapeutic approach for doxorubicin‐induced cardiotoxicity.     

Knockdown of Mtfp1 can minimize doxorubicin cardiotoxicity by inhibiting Dnm1l‐mediated mitochondrial fission

The long‐term usage of doxorubicin (DOX) is largely limited due to the development of severe cardiomyopathy. Many studies indicate that DOX‐induced cardiac injury is related to reactive oxygen species generation and ultimate activation of apoptosis. The role of novel mitochondrial fission protein 1 (Mtfp1) in DOX‐induced cardiotoxicity remains elusive. Here, we report the pro‐mitochondrial fission and pro‐apoptotic roles of Mtfp1 in DOX‐induced cardiotoxicity. DOX up‐regulates the Mtfp1 expression in HL‐1 cardiac myocytes. Knockdown of Mtfp1 prevents cardiac myocyte from undergoing mitochondrial fission, and subsequently reduces the DOX‐induced apoptosis by preventing dynamin 1‐like (Dnm1l) accumulation in mitochondria. In contrast, when Mtfp1 is overexpressed, a suboptimal dose of DOX can induce a significant percentage of cells to undergo mitochondrial fission and apoptosis. These data suggest that knocking down of Mtfp1 can minimize the cardiomyocytes loss in DOX‐induced cardiotoxicity. Thus, the regulation of Mtfp1 expression could be a novel therapeutic approach in chemotherapy‐induced cardiotoxicity.     

Nulp1基因抑制P19CL6细胞向心肌细胞分化

Nulp1基因是已克隆的一个新的bHLH转录因子亚家族成员.前期的研究表明：Nulp1蛋白作为一个转录抑制子对SRF信号途径有极强的抑制作用.为了进一步研究Nulp1基因在心肌分化中的作用,在能够高效分化为心肌细胞的P19CL6细胞系中过表达Nulp1基因,发现心肌分化标志基因的表达被抑制;用RNA干扰技术,使Nulp1基因在P19CL6细胞系中的内源表达降低,发现心肌分化标志基因的表达提高,说明Nulp1基因能够抑制P19CL6细胞系向心肌细胞的分化.     

hhlim促进DMSO诱导的P19细胞向心肌分化

为了确定hhlim是否参与胚胎期的心肌分化和发育过程,用可表达hhlim蛋白和hhlim反义RNA的真核表达质粒转染P19胚胎干细胞,经G418筛选得到稳定表达hhlim和hhlim反义RNA的P19细胞克隆后,观察hhlim对P19细胞向心肌分化和发育的影响.结果显示,Nkx2.5和GATA-4在未被外源性hhlim基因转染的P19细胞中不表达.DMSO刺激细胞2天后,GATA-4开始表达,3天后Nkx2.5的表达活性显著升高.hhlim的过表达不但有利于P19细胞的存活和生长,而且还可以使Nkx2.5和GATA-4的表达比对照细胞提前1天.反义hhlim细胞株被DMSO诱导5天后,细胞仍呈集落化生长.同时,Nkx2.5和GATA-4开始表达的时间明显延滞.结果表明,hhlim能促进P19细胞向心肌细胞分化,其作用是通过促进转录因子GATA-4和Nkx2.5的表达而实现的.     

Long‐term repopulation of aged bone marrow stem cells using young Sca‐1 cells promotes aged heart rejuvenation

Reduced quantity and quality of stem cells in aged individuals hinders cardiac repair and regeneration after injury. We used young bone marrow (BM) stem cell antigen 1 (Sca‐1) cells to reconstitute aged BM and rejuvenate the aged heart, and examined the underlying molecular mechanisms. BM Sca‐1⁺ or Sca‐1^? cells from young (2–3 months) or aged (18–19 months) GFP transgenic mice were transplanted into lethally irradiated aged mice to generate 4 groups of chimeras: young Sca‐1⁺, young Sca‐1^?, old Sca‐1⁺, and old Sca‐1^?. Four months later, expression of rejuvenation‐related genes (Bmi1, Cbx8, PNUTS, Sirt1, Sirt2, Sirt6) and proteins (CDK2, CDK4) was increased along with telomerase activity and telomerase‐related protein (DNA‐PKcs, TRF‐2) expression, whereas expression of senescence‐related genes (p16^INK4a, P19^ARF, p27^Kip1) and proteins (p16^INK4a, p27^Kip1) was decreased in Sca‐1⁺ chimeric hearts, especially in the young group. Host cardiac endothelial cells (GFP^?CD31⁺) but not cardiomyocytes were the primary cell type rejuvenated by young Sca‐1⁺ cells as shown by improved proliferation, migration, and tubular formation abilities. C‐X‐C chemokine CXCL12 was the factor most highly expressed in homed donor BM (GFP⁺) cells isolated from young Sca‐1⁺ chimeric hearts. Protein expression of Cxcr4, phospho‐Akt, and phospho‐FoxO3a in endothelial cells derived from the aged chimeric heart was increased, especially in the young Sca‐1⁺ group. Reconstitution of aged BM with young Sca‐1⁺ cells resulted in effective homing of functional stem cells in the aged heart. These young, regenerative stem cells promoted aged heart rejuvenation through activation of the Cxcl12/Cxcr4 pathway of cardiac endothelial cells.     

Differentiation of human adipose‐derived stem cells into beating cardiomyocytes

Human adipose‐derived stem cells (ASCs) may differentiate into cardiomyocytes and this provides a source of donor cells for tissue engineering. In this study, we evaluated cardiomyogenic differentiation protocols using a DNA demethylating agent 5‐azacytidine (5‐aza), a modified cardiomyogenic medium (MCM), a histone deacetylase inhibitor trichostatin A (TSA) and co‐culture with neonatal rat cardiomyocytes. 5‐aza treatment reduced both cardiac actin and TropT mRNA expression. Incubation in MCM only slightly increased gene expression (1.5‐ to 1.9‐fold) and the number of cells co‐expressing nkx2.5/sarcomeric α‐actin (27.2%versus 0.2% in control). TSA treatment increased cardiac actin mRNA expression 11‐fold after 1 week, which could be sustained for 2 weeks by culturing cells in cardiomyocyte culture medium. TSA‐treated cells also stained positively for cardiac myosin heavy chain, α‐actin, TropI and connexin43; however, none of these treatments produced beating cells. ASCs in non‐contact co‐culture showed no cardiac differentiation; however, ASCs co‐cultured in direct contact co‐culture exhibited a time‐dependent increase in cardiac actin mRNA expression (up to 33‐fold) between days 3 and 14. Immunocytochemistry revealed co‐expression of GATA4 and Nkx2.5, α‐actin, TropI and cardiac myosin heavy chain in CM‐DiI labelled ASCs. Most importantly, many of these cells showed spontaneous contractions accompanied by calcium transients in culture. Human ASC (hASC) showed synchronous Ca²⁺ transient and contraction synchronous with surrounding rat cardiomyocytes (106 beats/min.). Gap junctions also formed between them as observed by dye transfer. In conclusion, cell‐to‐cell interaction was identified as a key inducer for cardiomyogenic differentiation of hASCs. This method was optimized by co‐culture with contracting cardiomyocytes and provides a potential cardiac differentiation system to progress applications for cardiac cell therapy or tissue engineering.