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1501661 
Journal Article 
Normal targeting of a tagged Kv1.5 channel acutely transfected into fresh adult cardiac myocytes by a biolistic method 
Dou, Y; Balse, E; Dehghani Zadeh, A; Wang, T; Goonasekara, CL; Noble, GP; Eldstrom, J; Steele, DF; Hatem, SN; Fedida, D 
2010 
Yes 
American Journal of Physiology: Cell Physiology
ISSN: 0363-6143
EISSN: 1522-1563 
298 
C1343-C1352 
English 
20357183 
WOS:000277949300011 
The transfection of cardiac myocytes is difficult, and so most of the data regarding the regulation of trafficking and targeting of cardiac ion channels have been obtained using heterologous expression systems. Here we apply the fast biolistic transfection procedure to adult cardiomyocytes to show that biolistically introduced exogenous voltage-gated potassium channel, Kv1.5, is functional and, like endogenous Kv1.5, localizes to the intercalated disc, where it is expressed at the surface of that structure. Transfection efficiency averages 28.2 +/- 5.7% of surviving myocytes at 24 h postbombardment. Ventricular myocytes transfected with a tagged Kv1.5 exhibit an increased sustained current component that is approximately 40% sensitive to 100 microM 4-aminopyridine and which is absent in myocytes transfected with a fluorescent protein-encoding construct alone. Kv1.5 deletion mutations known to reduce the surface expression of the channel in heterologous cells similarly reduce the surface expression in transfected ventricular myocytes, although targeting to the intercalated disc per se is generally unaffected by both NH(2)- and COOH-terminal deletion mutants. Expressed current levels in wild-type Kv1.5, Kv1.5DeltaSH3(1), Kv1.5DeltaN209, and Kv1.5DeltaN135 mutants were well correlated with apparent surface expression of the channel at the intercalated disc. Our results conclusively demonstrate functionality of channels present at the intercalated disc in native myocytes and identify determinants of trafficking and surface targeting in intact cells. Clearly, biolistic transfection of adult cardiac myocytes will be a valuable method to study the regulation of surface expression of channels in their native environment. 
cardiomyocyte; transfection; potassium channel