Intracorporal injection of hSlocDNA in rats produces physiologically relevant alterations in penile function

The Ca -sensitive K channel (maxi-K ) is an important modulator of corporal smooth muscle tone. The goal of these studies was twofold: 1) to determine the feasibility of transfecting corporal smooth muscle cells in vivo with the hSlo cDNA, which encodes for the human smooth muscle maxi-K channel, an...

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Bibliographic Details
Published in:American journal of physiology. Heart and circulatory physiology 1998-08, Vol.275 (2), p.H600
Main Authors: Christ, G J, Rehman, J, Day, N, Salkoff, L, Valcic, M, Melman, A, Geliebter, J
Format: Article
Language:English
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Summary:The Ca -sensitive K channel (maxi-K ) is an important modulator of corporal smooth muscle tone. The goal of these studies was twofold: 1) to determine the feasibility of transfecting corporal smooth muscle cells in vivo with the hSlo cDNA, which encodes for the human smooth muscle maxi-K channel, and 2) to determine whether transfection of the maxi-K channel would affect the physiological response to cavernous nerve stimulation in a rat model in vivo. Intracorporal microinjection of pCMVβ/Lac Z DNA in 10-wk-old rats resulted in significant incorporation and expression of β-galactosidase activity in 10 of 12 injected animals for up to 75 days postinjection. Moreover, electrical stimulation of the cavernous nerve revealed that, relative to the responses obtained in age-matched control animals ( N = 12), intracavernous injection of naked pcDNA/ hSlo DNA was associated with a statistically significant elevation in the mean amplitude of the intracavernous pressure response at all levels of current stimulation (range 0.5-10 mA) at both 1 mo ( N= 5) and 2 mo ( N = 8) postinjection. Furthermore, qualitatively similar observations were made at 3 mo ( N = 2) and 4 mo ( N = 2) postinjection. These data indicate that naked hSlo DNA is quite easily incorporated into corporal smooth muscle and, furthermore, that expression is sustained for at least 2 mo in corporal smooth muscle cells in vivo. Finally, after expression, hSlo is capable of measurably altering nerve-stimulated penile erection. Taken together, these data provide compelling evidence for the potential utility of gene therapy in the treatment of erectile dysfunction.
ISSN:1522-1539