Global structural changes of an ion channel during its gating are followed by ion mobility mass spectrometry

Konijnenberg, Albert; Yilmaz, Duygu; Ingólfsson, Helgi I.; Dimitrova, Anna; Marrink, Siewert J.; Li, Zhuolun; Vénien-Bryan, Catherine; Sobott, Frank; Koçer, Armağan

doi:10.1073/pnas.1413118111

Cited by 64 publications

(95 citation statements)

References 61 publications

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“…This model was verified and revised by further studies through electron paramagnetic resonance spectroscopy (24) and an electrostatic repulsion test (25). More recently, a study through the native ion mobility-mass spectrometry demonstrated that MscL has the inherent structural flexibility to achieve large global structural changes in the absence of a lipid bilayer (26).…”

Section: Significancementioning

confidence: 86%

Mechanical coupling of the multiple structural elements of the large-conductance mechanosensitive channel during expansion

Guo

et al. 2015

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

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The prokaryotic mechanosensitive channel of large conductance (MscL) is a pressure-relief valve protecting the cell from lysing during acute osmotic downshock. When the membrane is stretched, MscL responds to the increase of membrane tension and opens a nonselective pore to about 30 Å wide, exhibiting a large unitary conductance of ∼3 nS. A fundamental step toward understanding the gating mechanism of MscL is to decipher the molecular details of the conformational changes accompanying channel opening. By applying fusionprotein strategy and controlling detergent composition, we have solved the structures of an archaeal MscL homolog from Methanosarcina acetivorans trapped in the closed and expanded intermediate states. The comparative analysis of these two new structures reveals significant conformational rearrangements in the different domains of MscL. The large changes observed in the tilt angles of the two transmembrane helices (TM1 and TM2) fit well with the helix-pivoting model derived from the earlier geometric analyses based on the previous structures. Meanwhile, the periplasmic loop region transforms from a folded structure, containing an ω-shaped loop and a short β-hairpin, to an extended and partly disordered conformation during channel expansion. Moreover, a significant rotating and sliding of the N-terminal helix (N-helix) is coupled to the tilting movements of TM1 and TM2. The dynamic relationships between the N-helix and TM1/TM2 suggest that the N-helix serves as a membraneanchored stopper that limits the tilts of TM1 and TM2 in the gating process. These results provide direct mechanistic insights into the highly coordinated movement of the different domains of the MscL channel when it expands. mechanosensitive channel | gating mechanism | crystal structure | membrane protein | osmoregulation

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Section: Significancementioning

confidence: 86%

Mechanical coupling of the multiple structural elements of the large-conductance mechanosensitive channel during expansion

Guo

et al. 2015

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

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“…Recently there has been an upsurge in the use of other non-ionic detergents for native MS analysis of MPs, for example, Triton X-100, tetraethylene glycol monooctyl ether (C8E4), octaethylene glycol monododecyl ether (C12E8), lauryldimethylamine N-oxide (LDAO), and n-octyl-b-D-glucoside (b-OG) (Fig. 4) as it has been shown that these detergent micelles dissociate at much lower activation energies, often resulting in MP ions that are more native-like [95][96][97]. These detergent micelles may be dissociated more easily than those formed by DDM as their non-ionic nature means that the only stabilizing forces are hydrophobic interactions which are weakened in the gas-phase, whilst DDM and b-OG micelles are also stabilized by hydrogenbonding [95].…”

Section: Detergent-based Reconstitution Methods For Native Msmentioning

confidence: 99%

“…4) as it has been shown that these detergent micelles dissociate at much lower activation energies, often resulting in MP ions that are more native-like [95][96][97]. These detergent micelles may be dissociated more easily than those formed by DDM as their non-ionic nature means that the only stabilizing forces are hydrophobic interactions which are weakened in the gas-phase, whilst DDM and b-OG micelles are also stabilized by hydrogenbonding [95]. It has also been proposed that the relative ease of detergent removal may relate to the stability of the protein within Fig.…”

Section: Detergent-based Reconstitution Methods For Native Msmentioning

confidence: 99%

“…Detergents are a poor mimic of the native bilayer, may not permit the retention of MP-lipid interactions [101], and in many cases disturb the correct, functional oligomeric state of MP assemblies [90,95,96]. Consequently, a variety of detergent-free methods have been developed to solubilize MPs for biophysical analyses, namely nanodiscs [102], bicelles [103], liposomes [104], styrene maleic acid lipid particles (SMALPs) (also called lipodisq) [93] and amphipols (Fig.…”

Section: Detergent-free Methods For Native Msmentioning

confidence: 99%

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Mass spectrometry-enabled structural biology of membrane proteins

Calabrese

Radford

2018

Methods

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a b s t r a c tThe last $25 years has seen mass spectrometry (MS) emerge as an integral method in the structural biology toolkit. In particular, MS has enabled the structural characterization of proteins and protein assemblies that have been intractable by other methods, especially those that are large, heterogeneous or transient, providing experimental evidence for their structural organization in support of, and in advance of, high resolution methods. The most recent frontier conquered in the field of MS-based structural biology has been the application of established methods for studying water soluble proteins to the more challenging targets of integral membrane proteins. The power of MS in obtaining structural information has been enabled by advances in instrumentation and the development of hyphenated mass spectrometry-based methods, such as ion mobility spectrometry-MS, chemical crosslinking-MS and other chemical labelling/footprinting-MS methods. In this review we detail the insights garnered into the structural biology of membrane proteins by applying such techniques. Application and refinement of these methods has yielded unprecedented insights in many areas, including membrane protein conformation, dynamics, lipid/ligand binding, and conformational perturbations due to ligand binding, which can be challenging to study using other methods.

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“…Later on, an improved open E. coli MscL (EcMscL) 3D structure was determined using both ensemble and single molecule site-directed fluorofore labelling (SDFL) FRET spectroscopy in combination with MD simulations 6,10,11 in agreement with the X-ray structure of an expanded form of an archaeal MscL homolog from Methanosarcina acetivorans 12 . While the overall gating-related structural changes in MscL have largely been established 8,11,13,14 the structural dynamics and physiological role of the C-terminal domain has thus far been controversial. Several studies have suggested that the C-terminus should remain intact during gating and could function as a molecular sieve 15,16 , while others suggested that this helical bundle should actively participate in gating and that opening of the MscL channel was accompanied by complete dissociation of the bundle 13,17 .…”

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confidence: 99%

Structural Dynamics of the MSCL C-Terminal Domain

Martinac

Bavi

Cortes

et al. 2017

Biophysical Journal

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The large conductance mechanosensitive channel (MscL), acts as an osmoprotective emergency valve in bacteria by opening a large, water-filled pore in response to changes in membrane tension. In its closed configuration, the last 36 residues at the C-terminus form a bundle of five α-helices co-linear with the five-fold axis of symmetry. Here, we examined the structural dynamics of the C-terminus of EcMscL using site-directed spin labelling electron paramagnetic resonance (SDSL EPR) spectroscopy. These experiments were complemented with computational modelling including molecular dynamics (MD) simulations and finite element (FE) modelling. Our results show that under physiological conditions, the C-terminus is indeed an α-helical bundle, located near the five-fold symmetry axis of the molecule. Both experiments and computational modelling demonstrate that only the top part of the C-terminal domain (from the residue A110 to E118) dissociates during the channel gating, while the rest of the C-terminus stays assembled. This result is consistent with the view that the C-terminus functions as a molecular sieve and stabilizer of the oligomeric MscL structure as previously suggested.The bacterial mechanosensitive channel of large conductance (MscL), has become a prototype molecular system in the study of mechanotransduction and its evolutionary origins 1,2 . The three-dimensional (3D) structure of MscL from Mycobacterium tuberculosis (MtMscL) in its closed conformation was resolved at 3.5 Å 3 . The channel is a homopentamer consisting of N-and C-terminal domains facing the cytoplasm and TM1 and TM2 transmembrane helices connected by a periplasmic loop [3][4][5][6] . The closed channel structure was also determined in the lipid bilayer by site-directed spin labelling electron paramagnetic resonance (SDSL EPR) spectroscopy 7 . Moreover, the open channel structure was also determined by SDSL EPR spectroscopy 8 allowing for estimation of the size of the open channel pore in a very good agreement with electrophysiological sieving studies 9 . Later on, an improved open E. coli MscL (EcMscL) 3D structure was determined using both ensemble and single molecule site-directed fluorofore labelling (SDFL) FRET spectroscopy in combination with MD simulations 6,10,11 in agreement with the X-ray structure of an expanded form of an archaeal MscL homolog from Methanosarcina acetivorans 12 . While the overall gating-related structural changes in MscL have largely been established 8,11,13,14 the structural dynamics and physiological role of the C-terminal domain has thus far been controversial. Several studies have suggested that the C-terminus should remain intact during gating and could function as a molecular sieve 15,16 , while others suggested that this helical bundle should actively participate in gating and that opening of the MscL channel was accompanied by complete dissociation of the bundle 13,17 . More recently, the X-ray structure of the EcMscL C-terminus domain was obtained at 1. 45 Å 18 , suggesting that even in the absence ...

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Global structural changes of an ion channel during its gating are followed by ion mobility mass spectrometry

Cited by 64 publications

References 61 publications

Mechanical coupling of the multiple structural elements of the large-conductance mechanosensitive channel during expansion

Mechanical coupling of the multiple structural elements of the large-conductance mechanosensitive channel during expansion

Mass spectrometry-enabled structural biology of membrane proteins

Structural Dynamics of the MSCL C-Terminal Domain

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