The eukaryotic cell cycle is regulated by a complex network of many proteins. Effective reprogramming of this complex regulatory apparatus to achieve bioprocess goals, such as cessation of proliferation at high cell density to allow an extended period of high production, can require coordinated manipulation of multiple genes. Previous efforts to establish inducible cell-cycle arrest of Chinese hamster ovary (CHO) cells by regulated expression of the cyclin-dependent kinase inhibitor (CDI) p21 failed. By tetracycline-regulated coexpression of p21 and the differentiation factor CCAAT/enhancer-binding protein alpha (which both stabilizes and induces p21), we have achieved effective cell-cycle arrest. Production of a model heterologous protein (secreted alkaline phosphatase; SEAP) has been increased 10-15 times, on a per cell basis, relative to an isogenic control cell line. Because activation of apoptosis response is a possible complication in a proliferation-arrested culture, the survival gene bcl-xL was coexpressed with another CDI, p27, found to enable CHO cell-cycle arrest predominantly in G1 phase. CHO cells stably transfected with a tricistronic construct containing the genes for these proteins and for SEAP showed 30-fold higher SEAP expression than controls.
Somatic gene therapy as a potential strategy for the treatment of myocardial diseases relies on an efficient gene transfer into cardiac muscle cells. The difficulty of delivering genes into adult cardiomyocytes exists not only in vivo but also in primary culture systems. Therefore, possibilities for ex vivo gene transfer and the in vitro study of physiological processes by reverse genetics are limited. We investigated the potential of an alphavirus-based vector system to transduce adult rat cardiomyocytes (ARC) in culture using a replication-deficient Sindbis virus (SIN) encoding beta-galactosidase (SIN-LacZ). Transduction efficiency depended on the virus concentration used, with expression of the reporter gene being detectable in up to 80% of cultured ARC as early as 24 h after infection. We observed a remarkably lower cytotoxicity of this viral vector in ARC than in other cells such as fibroblasts and neonatal cardiomyocytes. Additionally, no perceptible changes in the morphology of the nuclei or cytoskeleton were found in ARC 48 h after infection with SIN-LacZ. We conclude that SIN vectors are useful for gene delivery into adult cardiomyocytes and believe that improved versions of this viral system may be useful for cardiovascular gene therapy in the future.
Expression of epitope-tagged sarcomeric proteins in cardiomyocytes is a powerful approach for the characterization of interacting domains. Here, we report a new strategy for the study of the targeting of contractile proteins in cardiomyocytes by Sindbis virus (SIN)-mediated gene transfer. Two recombinant SIN were generated, one encoding the myosin-light chain MLC3f-eGFP fusion protein (SINrep5/MLC3f-eGFP), and the other encoding the alpha-actinin-DsRed fusion protein (SINrep5/alpha-actinin-DsRed). After infection of long-term cultured neonatal and adult rat cardiomyocytes with SINrep5/MLC3f-eGFP, the exogenous MLC3f-eGFP fusion protein localized to the sarcomeres. Freshly isolated rod-shaped ventricular cardiomyocytes infected with SINrep5/alpha-actinin-DsRed exhibited a correct incorporation of the newly synthesized alpha-actinin-DsRed fusion protein at the Z-band of the sarcomere. This allows the assumption that the exogenous protein is assembled into myofibrils in living cardiomyocy-tes using the same molecular interactions equally to the endogenous counterpart. It has been thus demonstrated that the SIN expression system makes possible the straightforward analysis of the localization of sarcomeric proteins in cultured cardiomyocytes and may offer new possibilities for the characterization of mutant proteins involved in hypertrophic cardiomyopathies.
Cardiomyocytes cease to divide shortly after birth and an irreversible cell cycle arrest is evident accompanied by the downregulation of cyclin-dependent kinase activities. To get a better understanding of the cardiac cell cycle and its regulation, the effect of functional recovery of the mitosis-promoting factor (MPF) consisting of cyclin B1 and the cyclin-dependent kinase Cdc2 was assessed in primary cultures of postmitotic ventricular adult rat cardiomyocytes (ARC). Gene transfer into ARC was achieved using the adenovirus-enhanced transferrinfection system that was characterized by the absence of cytotoxic events. Simultaneous ectopic expression of wild-type versions of cyclin B1 and Cdc2 was sufficient to induce MPF activity. Reestablished MPF resulted in a mitotic phenotype, marked by an abnormal condensation of the nuclei, histone H3 phosphorylation and variable degree of decay of the contractile apparatus. Although a complete cell division was not observed, the results provided conclusive evidence that cell cycle-related events in postmitotic cardiomyocytes could be triggered by genetic intervention downstream of the G1/S checkpoint. This will be of importance to design novel strategies to overcome the proliferation arrest in adult cardiomyocytes.
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