Acyl carrier protein interacts with melittin

Acyl carrier protein (ACP) from Escherichia coli has been shown to form complexes with melittin, a cationic peptide from bee venom. ACP is a small (Mr 8847), acidic, Ca2(+)-binding protein, which possesses some characteristics resembling those of regulatory Ca2(+)-binding proteins including interaction with melittin. Complexing between melittin and ACP which occurred both in the presence and absence of Ca2+ was evident by chemical cross-linking the two peptides, fluorescence changes (including anisotropy measurements), and inhibition by melittin of the activity of a nonaggregated fatty acid synthetase from Euglena. Also, anti-Apis mellifera antibodies which contained antibodies against melittin specifically inhibited the same enzyme system activity relative to non-immune IgG.     

Acyl carrier protein: structure-function relationships in a conserved multifunctional protein family.

Acyl carrier protein (ACP) is a universal and highly conserved carrier of acyl intermediates during fatty acid synthesis. In yeast and mammals, ACP exists as a separate domain within a large multifunctional fatty acid synthase polyprotein (type I FAS), whereas it is a small monomeric protein in bacteria and plastids (type II FAS). Bacterial ACPs are also acyl donors for synthesis of a variety of products, including endotoxin and acylated homoserine lactones involved in quorum sensing; the distinct and essential nature of these processes in growth and pathogenesis make ACP-dependent enzymes attractive antimicrobial drug targets. Additionally, ACP homologues are key components in the production of secondary metabolites such as polyketides and nonribosomal peptides. Many ACPs exhibit characteristic structural features of natively unfolded proteins in vitro, with a dynamic and flexible conformation dominated by 3 parallel alpha helices that enclose the thioester-linked acyl group attached to a phosphopantetheine prosthetic group. ACP conformation may also be influenced by divalent cations and interaction with partner enzymes through its "recognition" helix II, properties that are key to its ability to alternately sequester acyl groups and deliver them to the active sites of ACP-dependent enzymes. This review highlights recent progress in defining how the structural features of ACP are related to its multiple carrier roles in fatty acid metabolism.     

Acyl carrier protein structural classification and normal mode analysis

All acyl carrier protein primary and tertiary structures were gathered into the ThYme database. They are classified into 16 families by amino acid sequence similarity, with members of the different families having sequences with statistically highly significant differences. These classifications are supported by tertiary structure superposition analysis. Tertiary structures from a number of families are very similar, suggesting that these families may come from a single distant ancestor. Normal vibrational mode analysis was conducted on experimentally determined freestanding structures, showing greater fluctuations at chain termini and loops than in most helices. Their modes overlap more so within families than between different families. The tertiary structures of three acyl carrier protein families that lacked any known structures were predicted as well.     

Acyl carrier protein from Escherichia coli. Structural characterization of short-chain acylated acyl carrier proteins by NMR

Acylated acyl carrier proteins (ACPs) with acyl chain lengths of 2, 4, 6, 8, and 10 carbons were investigated by NMR and nuclear Overhauser methods at 500 MHz. Chemical shift changes of downfield aromatic and upfield, ring-current-shifted, isoleucine proton resonances monotonically vary as a function of acyl chain length with the most prominent shifts occurring with chain lengths between four and six carbons. Chemical shifts are largest for one of the two phenylalanines; however, substantial shifts do exist for Tyr-71, His-75, and two isoleucines. Since these residues are distributed throughout the molecule, their associated resonance chemical shifts are most probably explained by an induced conformational change. Comparative NOE measurements on reduced ACP (ACP-SH) and ACP-S-C8 suggest, however, that these induced conformational changes are small except for around one of the phenylalanines. A tertiary structural model for acyl-ACP consistent with our previous model for ACP-SH [Mayo, K. H., Tyrell, P. M., & Prestegard, J. H. (1983) Biochemistry 22, 4485-4493] is presented.     

Acyl carrier protein is conjugated to glutathione in spinach seed

Acyl carrier protein (ACP) contains an essential sulfhydryl group in its phosphopantetheine prosthetic group. We have investigated the state of this sulfhydryl in developing and mature spinach seed (Spinacia oleracea). Seed extracts were separated on sodium dodecyl sulfate or native polyacrylamide gels, blotted to nitrocellulose, and probed with antibodies raised against spinach ACP-I. In extracts of mature seeds prepared with reducing agents, ACP-II migrated as a single major band, whereas extracts prepared without reducing agents gave two major bands. The additional band was identified as a conjugate of ACP-II to glutathione (ACP-S-S-G) on the basis of its sensitivity to reducing agents and its comigration with standards in both native and sodium dodecyl sulfate gel electrophoresis. In developing spinach seeds ACP-II exists primarily in its free sulfhydryl form or as acyl derivatives, with essentially no ACP-S-S-G present. During later stages of seed development, as seed water content declines, ACP-S-S-G accumulates to approximately 50% of the total ACP. Seed imbibition results in a rapid decline in ACP-S-S-G levels. The ACP-S-S-G:ACP-SH ratio of seeds during storage was found to be a function of seed water content and this could be manipulated by controlling the relative humidity under which the seeds were stored. We speculate that conjugation of ACP to glutathione protects the ACP from sulfhydryl oxidative damage in dry seeds.     

Acyl carrier protein is present in the mitochondria of plants and eucaryotic micro-organisms

Proteins antigenically similar to the acyl carrier protein (ACP) found in the mitochondria of Neurospora crassa were detected by immunoblotting and radioimmunoassay techniques in mitochondria isolated from yeast, potatoes, and pea leaves. These mitochondrial proteins were similar to Neurospora ACP both in their electrophoretic mobility and in their unusual decrease in mobility upon reduction. Authentic ACP(s) show this type of change upon conversion of the acylated to the unacylated form. Purified ACP from both spinach chloroplasts and Escherichia coli cells cross-reacted with antibodies raised against Neurospora ACP. Purified ACP from Neurospora cross-reacted with antibodies raised against spinach chloroplast ACP and E. coli ACP. Mitochondria isolated from beef heart and rat brain were tested extensively and exhibited no cross-reaction with any of the three anti-ACP preparations. The discovery of ACP in the mitochondria of other organisms raises questions concerning the possible relationship between ACP and beta-oxidation in mitochondria, the involvement of ACP in de novo biosynthesis of some of the acyl chains in mitochondria and the subcellular locations of fatty acid biosynthesis in plants and eucaryotic micro-organisms.     

Acyl carrier protein import into chloroplasts. Both the precursor and mature forms are substrates for phosphopantetheine attachment by a soluble chloroplast holo-acyl carrier protein synthase

Recently a chloroplast holo-acyl carrier protein (holoACP) synthase activity was identified which attached the phosphopantetheine prosthetic group to acyl carrier protein, producing holoACP (Fernandez and Lamppa (1990) Plant Cell 2, 195-206). Here we show that the mature form of ACP (apoACP), after entry into the chloroplast and removal of the transit peptide, is a substrate for modification by the holoACP synthase. Modification occurs optimally at 37 degrees C and is inhibited by 5 mM 3',5'-ADP and 2 mM EDTA. An ACP construct (matACP) lacking the transit peptide was also converted to the holoACP form in an organelle-free assay, independent of precursor cleavage. The matACP construct was used to monitor the chromatographic separation of the holoACP synthase from the transit peptidase. Superose 12 gel filtration analysis indicates that the holoACP synthase has an apparent Mr of approximately 50,000. Using fractions enriched for the holoACP synthase it was demonstrated that the precursor of ACP is also modified in the presence of CoA and subsequently can be proteolytically processed directly to holoACP. Kinetic analysis, however, indicates that removal of the transit peptide is a much faster reaction than phosphopantetheine addition, suggesting that apoACP is the primary substrate for the chloroplast holoACP synthase in vivo.