Abstract

A series of quassinoid compounds was investigated to determine the structure‐activity relationships for the binding and inactivation steps associated with the inhibition of protein synthesis by these compounds in a rabbit reticulocyte system. The binding of these compounds to rabbit reticulocyte run‐off ribosomes was measured in a competition‐binding assay using [14C]trichodermin as the competing ligand. Previous studies have shown that trichodermin and quassionoids compete for a single binding site on yeast ribosomes. Our experiments confirmed this behavior with rabbit reticulocyte ribosomes and ind9icated that binding equlibrium could be reached in 2.5 min at 30°C. The comparative binding data indicated the following: (a) The nature of the side‐chain at position 15 has very little effect on the association of these compounds with rabbit reticulocyte ribosomes. There is one exception to this general rule, however. saturation of the double bond in brusaatol (compound II) to give dihydrobrusatol (compound IV) increases the d form 1.6μM to 8.7 μM. (b) Easy access to the A ring is required for optimal binding. The addition of any bulky hydrophobic group to the A ring increased the Kd significantly. However, the double bond in the A ring does not appear to be required for binding since the Kd values for dihydrobrusatol (compound IV) and tetrahydrobrusatol (compound VI) to the corresponding lactol (compound X) has only a minor effect on Kd. In order to determine whether inactivation of rabbit reticulocyte ribosomes had any structural requirements which differed from those required for simple binding, we also compared the concentrations of these compounds required to give 50% inhibition of protein synthesis (ID50) in rabbit reticulocye lysates. Previous studies had indicated that binding of quassinoids to the peptidyl transferase center and inhibition of peptide bond formation was probably the only mode of action of these compounds. Our experiments indicated that the ID50 values for several of thse compounds were the same in whole reticulocytes and reticulocyte lysates, suggesting that transport and/or metabolism of these compounds was probably not limiting for their inhibitory effects. The inhibition studies indicated that (a) The nature of the side‐chain at position 15 had no detectable effect on the inhibition: (b) the double bonds in the A ring and lactone ring are probably involved in the inactivation of rabbit reticulocyte ribosomes.

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