A Continuum Method for Determining Membrane Protein Insertion Energies and the Problem of Charged Residues

Choe, Seungho; Hecht, Karen A.; Grabe, Michael

doi:10.1085/jgp.200809959

Cited by 75 publications

(134 citation statements)

References 46 publications

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“…Finally, the resulting individual insertion free energies for arginine and leucine are determined to be 6.5 kcal∕mol and −1.0 kcal∕mol, respectively. These free energies present a range that is narrower than that found in previous simulations (28,29,31,35) and is closer to the experimental one.…”

Section: Resultssupporting

confidence: 78%

“…After accounting for the distinct hydrophobic moments of the two TM helices, i.e., ΔG 24). Both values are, however, significantly closer than those based on simulations of direct transfer of isolated amino acids from water to the membrane, which are approximately −4 kcal∕mol for leucine and þ10-14 kcal∕mol for arginine (28,29,31).…”

Section: Resultsmentioning

confidence: 68%

“…Translocation of an arginine amino acid borne by an effectively infinite polyleucine α-helix from water to the hydrophobic membrane core requires 17 kcal∕mol (27). Other studies of the translocation of side-chain analogs have corroborated the large discrepancy between computational and experimental measurements, with values ranging from 10 to 14 kcal∕mol for arginine (28)(29)(30)(31). Furthermore, the free-energy gain from the insertion of hydrophobic amino acids was also found to be consistently larger in theoretical investigations compared to experiments.…”

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confidence: 94%

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Free-energy cost for translocon-assisted insertion of membrane proteins

Gumbart

Chipot

Schulten

2011

Proc. Natl. Acad. Sci. U.S.A.

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Nascent membrane proteins typically insert in a sequential fashion into the membrane via a protein-conducting channel, the Sec translocon. How this process occurs is still unclear, although a thermodynamic partitioning between the channel and the membrane environment has been proposed. Experiment-and simulationbased scales for the insertion free energy of various amino acids are, however, at variance, the former appearing to lie in a narrower range than the latter. Membrane insertion of arginine, for instance, requires 14-17 kcal∕mol according to molecular dynamics simulations, but only 2-3 kcal∕mol according to experiment. We suggest that this disagreement is resolved by assuming a two-stage insertion process wherein the first step, the insertion into the translocon, is energized by protein synthesis and, therefore, has an effectively zero free-energy cost; the second step, the insertion into the membrane, invokes the translocon as an intermediary between the fully hydrated and the fully inserted locations. Using free-energy perturbation calculations, the effective transfer free energies from the translocon to the membrane have been determined for both arginine and leucine amino acids carried by a background polyleucine helix. Indeed, the insertion penalty for arginine as well as the insertion gain for leucine from the translocon to the membrane is found to be significantly reduced compared to direct insertion from water, resulting in the same compression as observed in the experiment-based scale.membrane-protein insertion | SecY | ribosome | hydrophobicity scale N early all membrane proteins found in the inner membranes of bacterial cells and the membranes of eukaryotic cells are inserted concomitant with their synthesis by the ribosome, i.e., cotranslationally (1). Insertion into the bilayer does not happen directly, but rather occurs via a highly conserved protein-conducting channel in the membrane, the Sec translocon (2-4). At an early stage of synthesis, the ribosome docks to the channel, forming a tightly bound complex (5, 6). The polypeptide is then inserted into the translocon prior to entering the membrane, the former step requiring a driving force, such as nucleotide hydrolysis, a membrane potential gradient, or the pressure exerted by the growing nascent chain (2).In addition to aiding the insertion of membrane proteins, the translocon also allows certain nascent proteins to cross the membrane (2). Structures of the Sec translocon (7-9) reveal two apparent gates, one transverse for the passage of soluble proteins across the membrane and one lateral for the exit of membrane proteins (7,10,11). The lateral gate is formed at the interface of two halves of SecY (7, 12) (see Fig. 1B). This gate fluctuates during translocation of the nascent polypeptide (13,14), although what factors govern its opening and closing are unclear (8,9,15).Given the two pathways presented by the translocon, there must exist a way to discriminate between proteins destined for the lipid membrane environment and proteins destined ...

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Section: Resultssupporting

confidence: 78%

Section: Resultsmentioning

confidence: 68%

mentioning

confidence: 94%

See 1 more Smart Citation

Free-energy cost for translocon-assisted insertion of membrane proteins

Gumbart

Chipot

Schulten

2011

Proc. Natl. Acad. Sci. U.S.A.

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“…[15][16][17]. Briefly, a physics-based model is used that considers the energy of the protein in the membrane as the sum of three dominant terms:…”

Section: Methodsmentioning

confidence: 99%

“…We previously developed a fast, hybrid continuum-atomistic model that treats the protein in atomistic detail, while implicitly representing the membrane using elasticity theory (15)(16)(17). Both our continuum model and MD simulations show that nhTMEM16 generates large-scale membrane deformations around the entire membrane-protein interface, including areas far away from the hydrophilic groove.…”

mentioning

confidence: 99%

Atomistic insight into lipid translocation by a TMEM16 scramblase

Bethel

Grabe

2016

Proc. Natl. Acad. Sci. U.S.A.

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103

159

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The transmembrane protein 16 (TMEM16) family of membrane proteins includes both lipid scramblases and ion channels involved in olfaction, nociception, and blood coagulation. The crystal structure of the fungal Nectria haematococca TMEM16 (nhTMEM16) scramblase suggested a putative mechanism of lipid transport, whereby polar and charged lipid headgroups move through the low-dielectric environment of the membrane by traversing a hydrophilic groove on the membrane-spanning surface of the protein. Here, we use computational methods to explore the membrane-protein interactions involved in lipid scrambling. Fast, continuum membrane-bending calculations reveal a global pattern of charged and hydrophobic surface residues that bends the membrane in a large-amplitude sinusoidal wave, resulting in bilayer thinning across the hydrophilic groove. Atomic simulations uncover two lipid headgroup-interaction sites flanking the groove. The cytoplasmic site nucleates headgroup-dipole stacking interactions that form a chain of lipid molecules that penetrate into the groove. In two instances, a cytoplasmic lipid interdigitates into this chain, crosses the bilayer, and enters the extracellular leaflet, and the reverse process happens twice as well. Continuum membrane-bending analysis carried out on homology models of mammalian homologs shows that these family members also bend the membrane-even those that lack scramblase activity. Sequence alignments show that the lipid-interaction sites are conserved in many family members but less so in those with reduced scrambling ability. Our analysis provides insight into how large-scale membrane bending and protein chemistry facilitate lipid permeation in the TMEM16 family, and we hypothesize that membrane interactions also affect ion permeation.TMEM16 | lipid scrambling | continuum membrane models | simulation | anoctamin T he compositional asymmetry between the leaflets of the plasma membrane influences the signaling properties of cells. Scramblases are a class of proteins that disrupt membrane asymmetry by facilitating the transfer of phospholipids from one leaflet to the other in an energy-independent manner. These transmembrane proteins play a role in events such as coagulation of the blood and cellular apoptosis by transporting phosphatidylserine (PS) from the inner leaflet to the outer leaflet of the plasma membrane (1). In particular, transmembrane protein 16 (TMEM16) family members have gained recent attention for their role in phospholipid scrambling in platelets and fungi. The TMEM16 family members have diverse functions. For example, TMEM16A and -B are calcium-activated chloride channels, TMEM16F is a nonspecific cation channel and scramblase, and the fungal Aspergillus fumigatus TMEM16 is another dual scramblase/ion channel (2-6).The structure of the Nectria haematococca TMEM16 (nhTMEM16) membrane protein revealed a possible mechanism for phospholipid conduction across the membrane (Fig. 1A) (7). The protein forms a dimer, and each subunit has a hydrophilic groove composed of polar...

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Soft‐wall ion transfer channel accurately predicts sterically hindered ion channel permeability

Kim

Song

Kim

et al. 2022

Bulletin Korean Chem Soc

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We provide a simple and systematic computational model to study ion channel permeability using density functional theory. While existing permeability models with a hard-wall steric hindrance factor work reasonably well for large ions, they severely inhibit the permeation of small ions through channel pores.Here, by introducing a steric hindrance factor that allows pore expansion due to intrinsically soft ion transfer channel walls, the new permeability model accurately describes the effect of steric hindrance stemming from the soft and flexible ion channel wall. Most importantly, the soft-wall ion transfer channel model works for a wide range of ionic radii from fluoride to gluconate. In addition, we show that strong local electrostatic interaction between densely charged ions such as fluoride and bicarbonate and ion channels with ion binding sites significantly promotes the permeation processes. K E Y W O R D S density functional theory (DFT), ion channel permeability, soft-wall ion transfer channel (SWITCH)

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A Continuum Method for Determining Membrane Protein Insertion Energies and the Problem of Charged Residues

Cited by 75 publications

References 46 publications

Free-energy cost for translocon-assisted insertion of membrane proteins

Free-energy cost for translocon-assisted insertion of membrane proteins

Atomistic insight into lipid translocation by a TMEM16 scramblase

Soft‐wall ion transfer channel accurately predicts sterically hindered ion channel permeability

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