Solution Structure of B. subtilis Acyl Carrier Protein

Enterococcus faecalis is a Gram-positive, commensal bacterium that lives in the gastrointestinal tracts of humans and other mammals. It causes severe infections because of high antibiotic resistance. E. faecalis can endure extremes of temperature and pH. Acyl carrier protein (ACP) is a key element in the biosynthesis of fatty acids responsible for acyl group shuttling and delivery. In this study, to understand the origin of high thermal stabilities of E. faecalis ACP (Ef-ACP), its solution structure was investigated for the first time. CD experiments showed that the melting temperature of Ef-ACP is 78.8°C, which is much higher than that of Escherichia coli ACP (67.2°C). The overall structure of Ef-ACP shows the common ACP folding pattern consisting of four ␣-helices (helix I (residues 3-17), helix II (residues 39 -53), helix III (residues 60 -64), and helix IV (residues 68 -78)) connected by three loops. Unique Ef-ACP structural features include a hydrophobic interaction between Phe 45 in helix II and Phe 18 in the ␣ 1 ␣ 2 loop and a hydrogen bonding between Ser 15 in helix I and Ile 20 in the ␣ 1 ␣ 2 loop, resulting in its high thermal stability. Phe 45 -mediated hydrophobic packing may block acyl chain binding subpocket II entry. Furthermore, Ser 58 in the ␣ 2 ␣ 3 loop in Ef-ACP, which usually constitutes a proline in other ACPs, exhibited slow conformational exchanges, resulting in the movement of the helix III outside the structure to accommodate a longer acyl chain in the acyl binding cavity. These results might provide insights into the development of antibiotics against pathogenic drug-resistant E. faecalis strains.

Section: Chemical Shift Perturbations Of Apo-and Holo-ef-acp-tosupporting

confidence: 82%

Section: Discussionmentioning

confidence: 99%

See 1 more Smart Citation

Novel Structural Components Contribute to the High Thermal Stability of Acyl Carrier Protein from Enterococcus faecalis

Park

Jung

Song

et al. 2016

“…ACP functions to sequester the growing acyl chain attached to the prosthetic group from solvent as it shuttles the intermediates between enzymes. Our work, and the protein NMR analysis of other ACPs (32,(35)(36)(37), shows that the prosthetic group exists in two states, one is exposed to solvent and the other is bound to the protein. Our protein NMR experiments indicate the prosthetic group interacts with ACP along the interior face of helix ␣2 2 pointing the active site sulfhydryl toward residues in loop-2 between helices ␣2 and ␣3.…”

Section: Discussionmentioning

confidence: 74%

Key Residues Responsible for Acyl Carrier Protein and β-Ketoacyl-Acyl Carrier Protein Reductase (FabG) Interaction

Zhang¹,

Zheng

et al. 2003

133

148

We tested this hypothesis by mutating two surface residues, Arg-129 and Arg-172, located in a hydrophobic patch adjacent to the active site entrance on ␤-ketoacyl-ACP reductase (FabG). Enzymatic analysis showed that the mutant enzymes were compromised in their ability to utilize ACP thioester substrates but were fully active in assays with a substrate analog. Direct binding assays and competitive inhibition experiments showed that the FabG mutant proteins had reduced affinities for ACP. Chemical shift perturbation protein NMR experiments showed that FabG-ACP interactions occurred along the length of ACP helix ␣2 and extended into the adjacent loop-2 region to involve Ile-54. These data confirm a role for the highly conserved electronegative/hydrophobic residues along ACP helix ␣2 in recognizing a constellation of Arg residues embedded in a hydrophobic patch on the surface of its partner enzymes, and reveal a role for the loop-2 region in the conformational change associated with ACP binding. The specific FabG-ACP interactions involve the most conserved ACP residues, which accounts for the ability of ACPs and the type II proteins from different species to function interchangeably.Fatty acid biosynthesis in bacteria and plants is carried out by a series of enzymes that are collectively known as the type II fatty-acid synthase and is most extensively studied in the Escherichia coli system (1, 2). ACP 1 is a small, acidic protein that functions as the central acyl group carrier in type II fatty-acid synthase systems. The ACPs are rod-shaped proteins with a preponderance of acidic residues organized into four ␣-helices (3-7). The acyl intermediates are attached to the terminal sulfhydryl of the 4Ј-phosphopantetheine prosthetic group (8), which is attached via a phosphodiester linkage to Ser-36 located at the beginning of the second helical segment. The primary gene product is an apoprotein that is converted to ACP by the transfer of the 4Ј-phosphopantetheine moiety of CoA to Ser-36 by [ACP]synthase (AcpS) (9, 10). ACP performs two functions. First, it sequesters the growing acyl chain from the aqueous environment, and second, upon binding to one of the type II proteins, it releases its grip on the fatty acid, which is inserted into the active site cavity of the enzyme. ACPs are widely distributed in nature and are easily recognized by their significant primary sequence identity, particularly at the prosthetic group attachment site and extending along helix ␣2 (11). These similarities are thought to underlie the observation that ACPs from virtually any source are substrates for AcpS and function with the fatty acid biosynthetic enzymes of E. coli (11). However, the individual enzymes of type II fatty acid synthesis do not share a primary structure motif that would define the presence of a common ACP-binding motif.The molecular details that govern the specific interactions between ACP and the type II enzymes are poorly known. The analysis of the binding of ACP to FabH points to ionic interactions playing a determinant ...

“…5, B-E. Although the rat FAS ACP forms the conserved ␣-helical bundle structure common to all ACPs, there is a slightly lower degree of ␣-helical content (46% over residues 2114 -2192) than other ACPs (E. coli FAS ACP 50% (39,40), S. cerevisiae ACP (50%) (41), B. subtilis FAS ACP 60% (42), and the actinorhodin PKS ACP 50% (12)). The shorter helices are replaced instead by the longer loop regions in the rat FAS ACP.…”

Section: Discussionmentioning

confidence: 99%

A Mammalian Type I Fatty Acid Synthase Acyl Carrier Protein Domain Does Not Sequester Acyl Chains

Płoskoń¹,

Arthur

Evans

et al. 2008

The synthases that produce fatty acids in mammals (FASs) are arranged as large multidomain polypeptides. The growing fatty acid chain is bound covalently during chain elongation and reduction to the acyl carrier protein (ACP) domain that is then able to access each catalytic site. In this work we report the highresolution nuclear magnetic resonance (NMR) solution structure of the isolated rat fatty acid synthase apoACP domain. Fatty acid biosynthesis in mammals is important not only for energy homeostasis and development but also as a potential target for the treatment of obesity (1) and cancer (2). Type I fatty acid synthases (FASs) 3 that catalyze the biosynthesis of fatty acids in mammals, utilize simple acyl units, bound to the phosphopantetheine arm of a holo acyl carrier protein (ACP) domain, for chain initiation and elongation. The recent elucidation of the low resolution structure of the mammalian FAS by x-ray crystallography (3) has provided key structural and mechanistic insights into this important enzyme. Although the resolution of the crystal is insufficient to discern the backbone and side chains, the electron density has permitted the authors to propose a model based on the structures of individual domains and homologous enzymes. The authors have proposed a "head to head" dimeric model that comprises a central core consisting of the enol-reductase, dehydratase (DH), and ketosynthase with the malonyl transferase and ketoreductase domains being located peripherally. Dimerization occurs through association of the KS domains. Notable absences in the crystal structure are the locations of the peripheral ACP and thioesterase domains, suggesting that the positions of the ACP and thioesterase domains are relatively mobile compared with the core of the FAS. In comparison, bacterial Type II FASs consist of discrete monofunctional proteins (4). Structural studies of the Type II FAS ACP components are particularly well developed and have revealed the structural basis of acyl chain binding and the phenomenon of conformational switching. The crystal structures of Escherichia coli FAS butyryl (5), hexanoyl-, heptanoyl-, and decanoyl-ACPs (6) and nuclear magnetic resonance (NMR) structures of spinach FAS decanoyl-and stearoyl-ACPs have been reported (7). These structures reveal that during fatty acid biosynthesis, fully saturated acyl chains are sequestered within a central cavity in the ACP formed through conformational changes in the protein. The fatty acid chain is sequestered within the hydrophobic core of the ACP perhaps to protect the thioester moiety from hydrolysis. Binding of the acyl chain also influences the dynamics of the ACPs. Spinach FAS holo-ACP exists in equilibrium between a folded and largely disordered form, however, upon acylation this equilibrium is shifted toward the folded form. At present the physiological role of switching of this, and other ACPs, is unknown (8, 9). It has been suggested that switching confers allosteric regulation of the ACP, whereby its interaction with other enzymes...