Claudio Anselmi scite author profile

We used electron cryotomography of mitochondrial membranes from wild-type and mutant Saccharomyces cerevisiae to investigate the structure and organization of ATP synthase dimers in situ. Subtomogram averaging of the dimers to 3.7 nm resolution revealed a V-shaped structure of twofold symmetry, with an angle of 86°between monomers. The central and peripheral stalks are well resolved. The monomers interact within the membrane at the base of the peripheral stalks. In wild-type mitochondria ATP synthase dimers are found in rows along the highly curved cristae ridges, and appear to be crucial for membrane morphology. Strains deficient in the dimer-specific subunits e and g or the first transmembrane helix of subunit 4 lack both dimers and lamellar cristae. Instead, cristae are either absent or balloon-shaped, with ATP synthase monomers distributed randomly in the membrane. Computer simulations indicate that isolated dimers induce a plastic deformation in the lipid bilayer, which is partially relieved by their side-by-side association. We propose that the assembly of ATP synthase dimer rows is driven by the reduction in the membrane elastic energy, rather than by direct protein contacts, and that the dimer rows enable the formation of highly curved ridges in mitochondrial cristae.membrane-protein oligomerization | membrane deformation | molecular dynamics simulations | bioenergetics | ATP synthesis T he F 1 F o ATP synthase is a highly conserved molecular machine that catalyses the production of ATP from ADP and P i in energy-converting membranes of eukaryotes and bacteria.

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Coupling of remote alternating-access transport mechanisms for protons and substrates in the multidrug efflux pump AcrB

Eicher

et al. 2014

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Membrane transporters of the RND superfamily confer multidrug resistance to pathogenic bacteria, and are essential for cholesterol metabolism and embryonic development in humans. We use high-resolution X-ray crystallography and computational methods to delineate the mechanism of the homotrimeric RND-type proton/drug antiporter AcrB, the active component of the major efflux system AcrAB-TolC in Escherichia coli, and one most complex and intriguing membrane transporters known to date. Analysis of wildtype AcrB and four functionally-inactive variants reveals an unprecedented mechanism that involves two remote alternating-access conformational cycles within each protomer, namely one for protons in the transmembrane region and another for drugs in the periplasmic domain, 50 Å apart. Each of these cycles entails two distinct types of collective motions of two structural repeats, coupled by flanking α-helices that project from the membrane. Moreover, we rationalize how the cross-talk among protomers across the trimerization interface might lead to a more kinetically efficient efflux system.DOI: http://dx.doi.org/10.7554/eLife.03145.001

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Coarse-Grained Model of Proteins Incorporating Atomistic Detail of the Active Site

et al. 2005

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We present a novel approach to explore the conformational space of globular proteins near their native state. It combines the advantages of coarse-grained models with those of all-atoms simulations, required to treat molecular recognition processes. The comparison between calculated structural properties with those obtained with all-atoms molecular dynamics simulations establishes the accuracy of the model. Our method has the potential to be extended to molecular recognition processes in systems whose characteristic size and time scale prevent an analysis based on all-atoms molecular dynamics.

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Structural insights into the mechanism of activation of the TRPV1 channel by a membrane-bound tarantula toxin

et al. 2016

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Venom toxins are invaluable tools for exploring the structure and mechanisms of ion channels. Here, we solve the structure of double-knot toxin (DkTx), a tarantula toxin that activates the heat-activated TRPV1 channel. We also provide improved structures of TRPV1 with and without the toxin bound, and investigate the interactions of DkTx with the channel and membranes. We find that DkTx binds to the outer edge of the external pore of TRPV1 in a counterclockwise configuration, using a limited protein-protein interface and inserting hydrophobic residues into the bilayer. We also show that DkTx partitions naturally into membranes, with the two lobes exhibiting opposing energetics for membrane partitioning and channel activation. Finally, we find that the toxin disrupts a cluster of hydrophobic residues behind the selectivity filter that are critical for channel activation. Collectively, our findings reveal a novel mode of toxin-channel recognition that has important implications for the mechanism of thermosensation.DOI: http://dx.doi.org/10.7554/eLife.11273.001

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Claudio Anselmi

Structure of the yeast F ₁ F _o -ATP synthase dimer and its role in shaping the mitochondrial cristae

Coupling of remote alternating-access transport mechanisms for protons and substrates in the multidrug efflux pump AcrB

Coarse-Grained Model of Proteins Incorporating Atomistic Detail of the Active Site

Structural insights into the mechanism of activation of the TRPV1 channel by a membrane-bound tarantula toxin

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Claudio Anselmi

Structure of the yeast F 1 F o -ATP synthase dimer and its role in shaping the mitochondrial cristae

Coupling of remote alternating-access transport mechanisms for protons and substrates in the multidrug efflux pump AcrB

Coarse-Grained Model of Proteins Incorporating Atomistic Detail of the Active Site

Structural insights into the mechanism of activation of the TRPV1 channel by a membrane-bound tarantula toxin

Contact Info

Product

Resources

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Structure of the yeast F ₁ F _o -ATP synthase dimer and its role in shaping the mitochondrial cristae