Neutralization of Acidic Residues in Helix II Stabilizes the Folded Conformation of Acyl Carrier Protein and Variably Alters Its Function with Different Enzymes

Gong, Huansheng; Murphy, Anne; McMaster, Christopher R.; Byers, David M.

doi:10.1074/jbc.m608234200

Cited by 32 publications

(55 citation statements)

References 48 publications

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“…Strategic placement of basic residues in ACP can influence its solution conformation; e.g., mutation of Ala-75 to His results in a more compact helical ACP at neutral°pH°due°to°charge°neutralization° [24].°Recently, we have shown that site-directed mutagenic neutralization of seven acidic divalent cation-binding residues at both ends of Helix II also increases helical content and decreases°the°hydrodynamic°radius°of°ACP° [26].°This ACP mutant (SA/SB) is expressed predominantly in the apo-form and cannot be further stabilized by divalent cation°binding.°As°shown°in°Figure°1c,°apo-SA/SB exhibited significantly greater helical content than aporACP at neutral pH and was only slightly unfolded even at pH 9.5. However, the CSD of this mutant exhibited only a modest change over this pH range, with average net charge decreasing from 8.0 at pH 9.5 to 7.6°at°pH°4.4°(Figure°2b).°Moreover,°this°profile°was very similar to that of rACP, consistent with earlier observations that the CSD of a protein does not necessarily°reflect°its°net°charge°in°solution° [15],°which°in°this case would be considerably lower for SA/SB (total of 15 acidic residues) relative to rACP (22 acidic residues) at neutral and higher pH values.…”

Section: Resultsmentioning

confidence: 94%

“…Myristoyl-ACP was prepared enzymatically from holo-ACP by incubation with myristic acid (14:0), ATP, and V. harveyi acyl-ACP synthetase as detailed elsewhere [25]. Site-directed mutagenesis of rACP and preparation of mutant SA/SB, in which seven central conserved acidic amino acid residues are replaced with their corresponding neutral amide residues, is described in reference [26].°Similar methods were used to replace Leu at position 46 with Trp to introduce an intrinsic fluorescence probe sensitive to ACP folding (Gong and Byers, manuscript in preparation). Residue numbering corresponds to that of native V. harveyi ACP (SwissProt accession no.…”

Section: Methodsmentioning

confidence: 99%

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Electrospray ionization mass spectra of acyl carrier protein are insensitive to its solution phase conformation

Murphy

Rowland

Byers

2007

J. Am. Soc. Mass Spectrom.

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Electrospray ionization mass spectrometry (ESI-MS) can be used to monitor conformational changes of proteins in solution based on the charge state distribution (CSD) of the corresponding gas-phase ions, although relatively few studies of acidic proteins have been reported. Here, we have compared the CSD and solution structure of recombinant Vibrio harveyi acyl carrier protein (rACP), a small acidic protein whose secondary and tertiary structure can be manipulated by pH, fatty acylation, and site-directed mutagenesis. Circular dichroism and intrinsic fluorescence demonstrated that apo-rACP adopts a folded helical conformation in aqueous solution below pH 6 or in 50% acetonitrile/0.1% formic acid, but is unfolded at neutral and basic pH values. A rACP mutant, in which seven conserved acidic residues were replaced with their corresponding neutral amides, was folded over the entire pH range of 5 to 9. However, under the same solvent conditions, both wild type and mutant ACPs exhibited similar CSDs (6 ϩ -9 ϩ species) at all pH values. Covalent attachment of myristic acid to the phosphopantetheine prosthetic group of rACP, which is known to stabilize a folded conformation in solution, also had little influence on its CSD in either positive or negative ion modes. Overall, our results are consistent with ACP as a "natively unfolded" protein in a dynamic conformational equilibrium, which allows access to (de)protonation events during the electrospray process. (J Am Soc Mass Spectrom 2007, 18, 1525-1532

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Section: Resultsmentioning

confidence: 94%

Section: Methodsmentioning

confidence: 99%

Electrospray ionization mass spectra of acyl carrier protein are insensitive to its solution phase conformation

Murphy

Rowland

Byers

2007

J. Am. Soc. Mass Spectrom.

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“…This region is already known to be recognized by a number of enzymes, e.g. ␤-ketoacyl-(ACP) reductase (37,38), acyl carrier protein synthase (39), protein acyltransferase HlyC (40), acyl-ACP synthetase, UDP-N-acetyl glucosamine acyltransferase (41), and ␤-ketoacyl-ACP synthase III (42). Outward movement of helix III in combination with acyl chain insertion generates strain on the ACP molecule, as revealed from slight changes in C ␣ and C ␤ of residues present at the bottom opening of the hydrophobic core in tetradecanoyl-ACP.…”

Section: Phosphopantetheine Moiety Is Relatively Structured In the Acmentioning

confidence: 99%

Structural Insights into the Acyl Intermediates of the Plasmodium falciparum Fatty Acid Synthesis Pathway

Upadhyay

Misra

Srivastava

et al. 2009

Journal of Biological Chemistry

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Acyl carrier protein (ACP) plays a central role in fatty acid biosynthesis. However, the molecular machinery that mediates its function is not yet fully understood. Therefore, structural studies were carried out on the acyl-ACP intermediates of Plasmodium falciparum using NMR as a spectroscopic probe. Chemical shift perturbation studies put forth a new picture of the interaction of ACP molecule with the acyl chain, namely, the hydrophobic core can protect up to 12 carbon units, and additional carbons protrude out from the top of the hydrophobic cavity. The latter hypothesis stems from chemical shift changes observed in C ␣ and C ␤ of Ser-37 in tetradecanoyl-ACP. 13 C, 15 N-Double-filtered nuclear Overhauser effect (NOE) spectroscopy experiments further substantiate the concept; in octanoyl (C 8 )-and dodecanoyl (C 12 )-ACP, a long range NOE is observed within the phosphopantetheine arm, suggesting an arch-like conformation. This NOE is nearly invisible in tetradecanoyl (C 14 )-ACP, indicating a change in conformation of the prosthetic group. Furthermore, the present study provides insights into the molecular mechanism of ACP expansion, as revealed from a unique side chain-to-backbone hydrogen bond between two fairly conserved residues, Ile-55 HN and Glu-48 O. The backbone amide of Ile-55 HN reports a pK a value for the carboxylate, ϳ1.9 pH units higher than model compound value, suggesting strong electrostatic repulsion between helix II and helix III. Charge-charge repulsion between the helices in combination with thrust from inside due to acyl chain would energetically favor the separation of the two helices. Helix III has fewer structural restraints and, hence, undergoes major conformational change without altering the overall-fold of P. falciparum ACP.In the malarial parasite Plasmodium falciparum, fatty acid biosynthesis occurs by a pathway distinct from the host. A number of enzymes involved in the process viz. ␤-ketoacyl acyl carrier protein (ACP) 5 synthase III, ␤-hydroxy acyl-ACP hydratase, and enoyl-ACP reductase are targets for drug design (1, 2). An indispensable component, crucial for each step of the pathway, is a small acidic protein, the ACP. ACP plays a pivotal role in a range of biochemical processes, like fatty acid biosynthesis (3), polyketide synthesis (4, 5), oligosaccharides (6), biotin, and nonribosomal peptide synthesis (7,8). Thus, the knowledge of structural features, which dictate ACP function, could offer new avenues for inhibitor design to disable several pathways of the parasite in parallel.Acyl carrier protein differs structurally in the host and the parasite. It exists as an independent protein in type II fatty acid synthesis pathway, observed in P. falciparum, Escherichia coli, spinach, and most prokaryotes. In the type II pathway, fatty acids are synthesized by multiple enzymes catalyzing different reactions. Conversely, mammalian ACP (malarial host) is an integral domain of one single multidomain, multifunctional fatty acid synthase (FAS) (type I pathway), each domain catalyzin...

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“…To further examine the effect of cyclization on ACP structure in solution, we used a variety of biophysical methods to analyze the conformation of both cycL46W and linL46W in response to Mg 2ϩ ions, which are known to induce a folded helical conformation upon binding to V. harveyi ACP at physiological pH (10). The apo forms of linear ACPs were used in these studies, as cyclic ACP is predominantly expressed in this form (see below).…”

Section: Resultsmentioning

confidence: 99%

“…For example, Vibrio harveyi ACP is largely unfolded at neutral pH, but its helical conformation can be stabilized by charge neutralization (i.e. at low pH or by residue replacements) (13), by binding of divalent cations to helix II (10), or by interaction with partner enzymes (15). Molecular dynamic simulations (16) and NMR experiments (17,18) have indicated greatest mobility in the long loop I connecting helices I and II, in the helix II-helix III region, and at the N and C termini, which are in close proximity.…”

Section: Bacterial Acyl Carrier Protein (Acp)mentioning

confidence: 99%

Intein-mediated Cyclization of Bacterial Acyl Carrier Protein Stabilizes Its Folded Conformation but Does Not Abolish Function

Volkmann

Murphy

Rowland

et al. 2010

Journal of Biological Chemistry

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Bacterial acyl carrier protein (ACP) is essential for the synthesis of fatty acids and serves as the major acyl donor for the formation of phospholipids and other lipid products. Acyl-ACP encloses attached fatty acyl groups in a hydrophobic pocket within a four-helix bundle, but must at least partially unfold to present the acyl chain to the active sites of its multiple enzyme partners. To further examine the constraints of ACP structure and function, we have constructed a cyclic version of Vibrio harveyi ACP, using split-intein technology to covalently join its closely apposed N and C termini. Cyclization stabilized ACP in a folded helical conformation as indicated by gel electrophoresis, circular dichroism, fluorescence, and mass spectrometry. Molecular dynamics simulations also indicated overall decreased polypeptide chain mobility in cyclic ACP, although no major conformational rearrangements over a 10-ns period were noted. In vivo complementation assays revealed that cyclic ACP can functionally replace the linear wild-type protein and support growth of an Escherichia coli ACP-null mutant strain. Cyclization of a folding-deficient ACP mutant (F50A) both restored its ability to adopt a folded conformation and enhanced complementation of growth. Our results thus suggest that ACP must be able to adopt a folded conformation for biological activity, and that its function does not require complete unfolding of the protein. Bacterial acyl carrier protein (ACP)2 is a small (typically 70 -80 residue) protein required for the synthesis and transfer of fatty acyl chains in the production of phospholipids and other specialized products, including lipid A, lipoic acid, acylhomoserine lactones, and hemolysin (reviewed in Ref. 1). Over two dozen nuclear magnetic resonance (NMR) and x-ray crystal structures have revealed a conserved "ACP fold" consisting of a four-helix bundle (1). Fatty acids covalently attached to the phosphopantetheine prosthetic group at the N-terminal end of helix II are enclosed within the hydrophobic interior of this bundle, interacting predominantly with residues on helices II-IV (2-5). Further computational (6, 7), crystallographic (8, 9), and mutagenic (10 -13) analyses have implicated the acidic central helix II as a "recognition helix" for interaction with most of the ACP enzyme partners. Subtle conformational alterations in this region likely also contribute to discrimination by ACPdependent enzymes among the various acyl-ACP derivatives (4,14).The acidic nature of ACP (pI ϳ 4) contributes to a highly dynamic and flexible structure in solution, and some ACPs exhibit features characteristic of natively unfolded proteins (1). For example, Vibrio harveyi ACP is largely unfolded at neutral pH, but its helical conformation can be stabilized by charge neutralization (i.e. at low pH or by residue replacements) (13), by binding of divalent cations to helix II (10), or by interaction with partner enzymes (15). Molecular dynamic simulations (16) and NMR experiments (17, 18) have indicated greatest mobili...

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Neutralization of Acidic Residues in Helix II Stabilizes the Folded Conformation of Acyl Carrier Protein and Variably Alters Its Function with Different Enzymes

Cited by 32 publications

References 48 publications

Electrospray ionization mass spectra of acyl carrier protein are insensitive to its solution phase conformation

Electrospray ionization mass spectra of acyl carrier protein are insensitive to its solution phase conformation

Structural Insights into the Acyl Intermediates of the Plasmodium falciparum Fatty Acid Synthesis Pathway

Intein-mediated Cyclization of Bacterial Acyl Carrier Protein Stabilizes Its Folded Conformation but Does Not Abolish Function

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