The cyanomethyl benzonitrile compounds used for this study contain two cyano groups: a -CH2CN side chain, plus a cyano group attached to the benzene ring. The ortho, meta and para -CH2CN substituted compounds were biotransformed using whale cell suspensions of the bacterium Rhodococcus rhodochrous LL100-21. The bacterium had previously been grown on the mono-nitrile compounds propionitrile, benzonitrile or acetonitrile, inducing the formation of nitrile hydrolyzing enzymes. Suspensions of R. rhodochrous LL100-21 that had been grown on propionitrile or benzonitrile converted the aliphatic group of 2-(cyanomethyl) benzonitrile (a) to the corresponding carboxylic acid, 2-(cyanophenyl) acetic acid (d) with excellent recovery of the product and no evidence for any other products. Conversely, when grown on acetonitrile the bacterium converted 2-(cyanomethyl) benzonitrile (a) to the amide derivatives 2-(cyanophenyl) acetamide (k) and 2-(cyanomethyl) benzamide (l) but only in low yields. Biotransformations of 3-(cyanomethyl) benzonitrile (b) and 4-(cyanomethyl) benzonitrile (c), by suspensions of bacteria that had been grown on benzonitrile or propionitrile, resulted in hydrolysis of the aromatic nitrile to produce 3- and 4-(cyanomethyl) benzoic acid (j) and (m), respectively, both with a high yield. Low concentrations of other products were also detected, for example the diacids 3-and 4-(carboxyphenyl) acetic acid (h) and (i). When the bacterium was grown on acetonitrile it could biotransform 3-and 4-(cyanomethyl) benzonitrile (b) and (c) to different products indicating less regiospecificity by the nitrile hydratase enzyme. Comparison of the initial rates of conversion of the aliphatic cyano side chain of 2-(cyanomethyl) benzonitrile (a) and other substituted benzonitriles indicated that electronic effects did not affect the initial rate of the reaction as they would require transmission through an SP3 methylene carbon atom.