Mapping the lipoylation site of Arabidopsis thaliana plastidial dihydrolipoamide S-acetyltransferase using mass spectrometry and site-directed mutagenesis.

Catalytic enhancement achieved by the pyruvate dehydrogenase complex (PDC) results from a combination of substrate channeling plus active-site coupling. The mechanism for active-site coupling involves lipoic acid prosthetic groups covalently attached to Lys in the primary sequence of the dihydrolipoyl S-acetyltransferase (E2) component. Arabidopsis thaliana plastidial E2 (AtplE2-1A-His(6)) was expressed in Escherichia coli. Analysis of recombinant protein by SDS-PAGE revealed a Mr 59,000 band. Supplementation of bacterial culture medium with l-lipoic acid (LA) shifted the band to Mr 57,000. Intact mass determinations using matrix-assisted laser desorption ionization-time of flight (MALDI-TOF) mass spectrometry (MS) revealed the faster migrating E2 species was 189 Da larger than the slower migrating form, exactly the difference that would result from addition of a single lipoamide group. Results from systematic MALDI-TOF analysis of Lys-containing tryptic peptides derived from purified recombinant AtplE2-1A indicate that Lys96 is the site of lipoyl-addition. Analysis of Lys96 site-directed mutant proteins showed that they migrated as single species during SDS-PAGE when expressed in either the absence or presence of supplemental LA. Results from both intact and tryptic peptide mass determinations by MALDI-TOF MS confirmed that the mutant proteins were not lipoylated. The A. thaliana plastidial E2 subunit includes a single lipoyl-prosthetic group covalently attached to Lys96. Despite low primary sequence identity with bacterial E2, the plant E2 protein was recognized and modified by E. coli E2 lipoyl-addition system. Results from meta-genomic analysis suggest a ß-turn is more important in defining the site for LA addition than a conserved sequence motif.

Proteomic analysis of near-isogenic sunflower varieties differing in seed oil traits.

Near-isogenic sunflower lines containing 25% (inbred RHA280) and 48% (RHA801) oil by seed dry mass were comparatively analyzed in biological triplicate at 18 days after flowering using two-dimensional (both pI 3-10 and 4-7) Difference Gel Electrophoresis. Additionally, two inbred lines varying in oleic acid content, HA89 (18% oleic) and HA341 (89% oleic), were also analyzed in the same manner. Statistical analyses of these sunflower lines was performed beginning with fitting a mixed effects linear model to the log-transformed optical volume of each spot to account for gel variation, followed by testing the significance between varieties for mean transformed optical spot volumes. The p-values from the spot analysis procedures were then used to find the cutoff point for differential expression using a 10% false-discovery rate (FDR). Comparison of the oil content and oleic acid composition lines revealed 77 and 42 protein spots below the 10% FDR cutoff, respectively, and were therefore declared differentially expressed. Liquid chromatography-tandem mass spectrometry analysis of each of these protein spots resulted in assignments for 44 and 17 spots, respectively. Fructokinase, plastid phosphoglycerate kinase, and enolase proteins were determined to be up-regulated in the high oil line, while phosphofructokinase, cytosolic phosphoglucomutase, and cytsolic phosphoglycerate kinase were up-regulated in the low oil variety. Additionally, four activities involved in amino acid synthesis were up-regulated in the low oil variety in addition to 12S storage proteins and a protein similar to legumin storage protein. Interestingly, two 2-DE spots identified as 14-3-3 proteins were found to be up-regulated in high oleic acid variety. Alteration of glycolytic and amino acid biosynthetic enzymes, as well as storage protein levels, suggests seed oil content is tightly linked to carbohydrate metabolism and protein synthesis in a complex manner.