A computational approach to the mechanism of self-cleavage of hammerhead RNA.

AUTOR(ES)

Mei, H Y

RESUMO

Extensive minimization and dynamics computational studies of the hammerhead structural domain of the virusoid of lucerne transient streak virus have been carried out. The following observations at the self-cleavage position are derived from the resulting three-dimensional structure: (i) the cytosine base is at the surface and does not interact with another base (it is free to move), and (ii) the ribose-phosphate backbone is forced to take an abrupt turn since it bridges stems I and III, and this turn points the pro-S and pro-R oxygens of the phosphate to the inward side of the hammerhead. These structural features are independent of the hammerhead being open or closed and allow an unencumbered 3'- to 2'-endo conformational change of the ribose with the resultant creation of an unusual stereochemistry that allows a direct in-line self-cleavage reaction. In the closed hammerhead structure, interactions of stems I and II create a vacancy into which the catalytic hydrated Mg(II) may be docked on labile phosphate. This opening is not present if stems I and II are shortened.

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