The Photoactivated Relaxation of Smooth Muscle of Rabbit Aorta

doi:10.1085/jgp.44.3.499

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The Photoactivated Relaxation of Smooth Muscle of Rabbit Aorta

R. F. Furchgott ¹, S. J. Ehrreich ¹, and E. Greenblatt ¹

¹ From the Department of Pharmacology, College of Medicine, State University of New York Downstate Medical Center, Brooklyn, New York

Smooth muscle of strips of rabbit aorta, placed in a stateof active tonic contraction by addition of a stimulating drug,relaxes during exposure to light. The relaxation is reversible.The extent of relaxation produced by a standard exposure dependson the preexposure level of active contraction but not on thenature of the stimulating drug used to produce contraction.With strips brought to an intermediate level of contraction,the degree of relaxation (steady state levels) is a rectangularhyperbolic function of radiation intensity. The kinetics ofthe relaxation process during irradiation and the recovery processfollowing irradiation are consistent with the hypothesis thatthe primary photoactivated material initiates a reaction orreactions leading to a product which inhibits some process involvedin the production of active contraction. The photorelaxationdoes not require the presence of oxygen. It is potentiated byreducing the temperature of the aortic strip. The action spectrumof the photorelaxation shows relatively low effectiveness atwavelengths above 450 mµ. The effectiveness increases markedlyand progressively as the wavelength is lowered below 450 mµ,reaching a peak at 310 mµ. A deep trough occurs at 280mµ. However, both peak and trough probably result frominternal filtering due to absorption by proteins in the aorticstrip. It is surmised that if a correction could be made forthis internal filtering, the action spectrum would rise continuouslydown to wavelengths at least as low as 250 mµ.

Submitted on January 21, 1961

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