METABOLIC EVIDENCE FOR THE INVOLVEMENT OF A DELTA(4)-PALMITOYL-ACYL CARRIER PROTEIN DESATURASE IN PETROSELINIC ACID SYNTHESIS IN CORIANDER ENDOSPERM AND TRANSGENIC TOBACCO CELLS

We have previously demonstrated that the double bond of petroselinic a cid (18:1 Delta(6cis)) in coriander (Coriandrum safivum L.) seed resul ts from the activity of a 36-kD desaturase that is structurally relate d to the Delta(9)-stearoyl-acyl carrier protein (ACP) desaturase (E.B. Cahoon, J. Shanklin, J.B. Ohlrogge [1992] Proc Natl Acad Sci USA 89: 11184-11188). To further characterize the biosynthetic pathway of this unusual fatty acid, C-14-labeling experiments were conducted using de veloping endosperm of coriander. Studies were also performed using sus pension cultures of transgenic tobacco (Nicotiana tabacum L.) that exp ress the coriander 36-kD desaturase, and as a result produce petroseli nic acid and Delta(4)-hexadecenoic acid. When supplied exogenously to coriander endosperm slices, [1-C-14]palmitic acid and stearic acid wer e incorporated into glycerolipids but were not converted to petroselin ic acid. This suggested that petroselinic acid is not formed by the de saturation of a fatty acid bound to a glycerolipid or by reactions inv olving acyl-coenzyme As (CoA). Instead, evidence was most consistent w ith an acyl-ACP route of petroselinic acid synthesis. For example, the exogenous feeding of [1-C-14]lauric acid and myristic acid to coriand er endosperm slices resulted in the incorporation of the radiolabels i nto long-chain fatty acids, including primarily petroselinic acid, pre sumably through acyl-ACP-associated reactions. In addition, using an i n vitro fatty acid biosynthetic system, homogenates of coriander endos perm incorporated [2-C-14]malonyl-CoA into petroselinic acid, of which a portion was detected in a putative acyl-ACP fraction. Furthermore, analysis of transgenic tobacco suspension cultures expressing the cori ander 36-kD desaturase revealed significant amounts of petroselinic ac id and Delta(4)-hexadecenoic acid in the acyl-ACP pool of these cells. Also presented is evidence derived from [U-C-14]nonanoic acid labelin g of coriander endosperm, which demonstrates that the coriander 36-kD desaturase positions double bonds relative to the carboxyl end of acyl -ACP substrates. The data obtained in these studies are rationalized i n terms of a biosynthetic pathway of petroselinic acid involving the D elta(4) desaturation of palmitoyl-ACP by the 36-kD desaturase followed by two-carbon elongation of the resulting Delta(4)-hexadecenoyl-ACP.