Sebastian Hiller

Solution structure of the integral human membrane protein VDAC-1 in detergent micelles.

The voltage-dependent anion channel (VDAC) mediates trafficking of small molecules and ions across the eukaryotic outer mitochondrial membrane. VDAC also interacts with antiapoptotic proteins from the Bcl-2 family, and this interaction inhibits release of apoptogenic proteins from the mitochondrion. We present the nuclear magnetic resonance (NMR) solution structure of recombinant human VDAC-1 reconstituted in detergent micelles. It forms a 19-stranded β barrel with the first and last strand parallel. The hydrophobic outside perimeter of the barrel is covered by detergent molecules in a beltlike fashion. In the presence of cholesterol, recombinant VDAC-1 can form voltage-gated channels in phospholipid bilayers similar to those of the native protein. NMR measurements revealed the binding sites of VDAC-1 for the Bcl-2 protein Bcl-xL, for reduced β–nicotinamide adenine dinucleotide, and for cholesterol. Bcl-xL interacts with the VDAC barrel laterally at strands 17 and 18.

Automated projection spectroscopy (APSY).

This work presents the automated projection spectroscopy (APSY) method for the recording of discrete sets of j projections from N-dimensional (N > or = 3) NMR experiments at operator-selected projection angles and automatic identification of the correlation cross peaks. The result from APSY is the fully automated generation of the complete or nearly complete peak list for the N-dimensional NMR spectrum from a geometric analysis of the j experimentally recorded, low-dimensional projections. In the present implementation of APSY, two-dimensional projections of the N-dimensional spectrum are recorded by using techniques developed for projection-reconstruction spectroscopy [Kupce,E.& Freeman, R. (2004) J. Am. Chem. Soc. 126, 6429-6440]. All projections are peak-picked with the available automated routine atnos. The previously undescribed algorithm GAPRO (geometric analysis of projections) uses vector algebra to identify subgroups of peaks in different projections that arise from the same resonance in the N-dimensional spectrum, and from these subgroups it calculates the peak positions in the N-dimensional frequency space. Unambiguous identification thus can be achieved for all cross peaks that are not overlapped with other peaks in at least one of the N dimensions. Because of the correlation between the positions of corresponding peaks in multiple projections, uncorrelated noise is efficiently suppressed, so that APSY should be quite widely applicable for correlation spectra of biological macromolecules, which have intrinsically low peak density in the N-dimensional spectral space.

A Proton-Detected 4D Solid-State NMR Experiment for Protein Structure Determination

Owing to recent advances in instrumentation, methodology and sample-preparation techniques, solid-state NMR spectroscopy is providing unique insights into biological structures at atomic resolution. Three-dimensional structures of proteins and other biological macromolecules can now be determined that are difficult to characterize by X-ray diffraction or solution NMR. Still, the task remains demanding and new methodological developments are needed to make the structure determination more reliable. While it has been demonstrated that assignments are feasible for proteins with over 200 residues, the structure-determination step remains difficult, mainly because spectral overlap introduces ambiguities in restraint assignments during the process of structure generation. These ambiguities can in some cases be resolved, but remain a potential source of errors. Herein, we present an experimental approach that combines the efficient measurement of longrange proton–proton distances in sparsely isotope-labelled samples with proton-detected 3D and 4D correlation spectroscopy. We demonstrate the method in the context of structure determination of the 76-amino-acid protein ubiquitin. Sparsely distributed protons in an otherwise perdeuterated protein yield highly resolved H spectra. The corresponding samples are produced either by expressing perdeuterated protein followed by H back exchange at about 30% of the exchangeable sites or by using suitable precursors to label exclusively a methyl group of alanine, isoleucine, valine or leucine during protein expression. Under fast magic-angle spinning (55 kHz), coherences in such spin systems are sufficiently long-lived to allow not only dipolar, but also scalar-coupling based polarization transfer. H detection increases the sensitivity by a factor of 8 compared to C detection. Similar deuteration schemes have been exploited in solution-state NMR to increase resolution and sensitivity, and to collect precise NOE restraints. An additional advantage arises in the solid phase. In such samples, even the closest H neighbour often corresponds to a long-range contact and dipolar truncation is not an issue, allowing highly-efficient first-order dipolar-recoupling experiments to be used to obtain distance information. Here we use the dipolar recoupling enhanced by amplitude modulation (DREAM) mixing scheme (Figure 1) that provides particularly high polarization-transfer efficiencies due to its adiabatic nature.

GSDMD membrane pore formation constitutes the mechanism of pyroptotic cell death

Pyroptosis is a lytic type of cell death that is initiated by inflammatory caspases. These caspases are activated within multi‐protein inflammasome complexes that assemble in response to pathogens and endogenous danger signals. Pyroptotic cell death has been proposed to proceed via the formation of a plasma membrane pore, but the underlying molecular mechanism has remained unclear. Recently, gasdermin D (GSDMD), a member of the ill‐characterized gasdermin protein family, was identified as a caspase substrate and an essential mediator of pyroptosis. GSDMD is thus a candidate for pyroptotic pore formation. Here, we characterize GSDMD function in live cells and in vitro. We show that the N‐terminal fragment of caspase‐1‐cleaved GSDMD rapidly targets the membrane fraction of macrophages and that it induces the formation of a plasma membrane pore. In vitro, the N‐terminal fragment of caspase‐1‐cleaved recombinant GSDMD tightly binds liposomes and forms large permeability pores. Visualization of liposome‐inserted GSDMD at nanometer resolution by cryo‐electron and atomic force microscopy shows circular pores with variable ring diameters around 20 nm. Overall, these data demonstrate that GSDMD is the direct and final executor of pyroptotic cell death.

Structural and functional characterization of the integral membrane protein VDAC-1 in lipid bilayer nanodiscs

Biophysical studies of membrane proteins are often impeded by the requirement for a membrane mimicking environment. Detergent micelles are the most common choice, but the denaturing properties make them unsatisfactory for studies of many membrane proteins and their interactions. In the present work, we explore phospholipid bilayer nanodiscs as membrane mimics and employ electron microscopy and solution NMR spectroscopy to characterize the structure and function of the human voltage dependent anion channel (VDAC-1) as an example of a polytopic integral membrane protein. Electron microscopy reveals the formation of VDAC-1 multimers, an observation that is consistent with results obtained in native mitochondrial outer membranes. High-resolution NMR spectroscopy demonstrates a well folded VDAC-1 protein and native NADH binding functionality. The observed chemical shift changes upon addition of the native ligand NADH to nanodisc-embedded VDAC-1 resemble those of micelle-embedded VDAC-1, indicating a similar structure and function in the two membrane-mimicking environments. Overall, the ability to study integral membrane proteins at atomic resolution with solution NMR in phospholipid bilayers, rather than in detergent micelles, offers exciting novel possibilities to approach the biophysical properties of membrane proteins under nondenaturing conditions, which makes this technology particular suitable for protein-protein interactions and other functional studies.

PDCD4 inhibits translation initiation by binding to eIF4A using both its MA3 domains

Programmed Cell Death 4 (PDCD4) is a protein known to bind eukaryotic initiation factor 4A (eIF4A), inhibit translation initiation, and act as a tumor suppressor. PDCD4 contains two C-terminal MA3 domains, which are thought to be responsible for its inhibitory function. Here, we analyze the structures and inhibitory functions of these two PDCD4 MA3 domains by x-ray crystallography, NMR, and surface plasmon resonance. We show that both MA3 domains are structurally and functionally very similar and bind specifically to the eIF4A N-terminal domain (eIF4A-NTD) using similar binding interfaces. We found that the PDCD4 MA3 domains compete with the eIF4G MA3 domain and RNA for eIF4A binding. Our data provide evidence that PDCD4 inhibits translation initiation by displacing eIF4G and RNA from eIF4A. The PDCD4 MA3 domains act synergistically to form a tighter and more stable complex with eIF4A, which explains the need for two tandem MA3 domains.

The 3D structures of VDAC represent a native conformation

The most abundant protein of the mitochondrial outer membrane is the voltage-dependent anion channel (VDAC), which facilitates the exchange of ions and molecules between mitochondria and cytosol and is regulated by interactions with other proteins and small molecules. VDAC has been studied extensively for more than three decades, and last year three independent investigations revealed a structure of VDAC-1 exhibiting 19 transmembrane beta-strands, constituting a unique structural class of beta-barrel membrane proteins. Here, we provide a historical perspective on VDAC research and give an overview of the experimental design used to obtain these structures. Furthermore, we validate the protein refolding approach and summarize the biochemical and biophysical evidence that links the 19-stranded structure to the native form of VDAC.

The structural basis of autotransporter translocation by TamA

TamA is an Escherichia coli Omp85 protein involved in autotransporter biogenesis. It comprises a 16-stranded transmembrane β-barrel and three POTRA domains. The 2.3-Å crystal structure reveals that the TamA barrel is closed at the extracellular face by a conserved lid loop. The C-terminal β-strand of the barrel forms an unusual inward kink, which weakens the lateral barrel wall and creates a gate for substrate access to the lipid bilayer.

Nonmicellar systems for solution NMR spectroscopy of membrane proteins.

Integral membrane proteins play essential roles in many biological processes, such as energy transduction, transport of molecules, and signaling. The correct function of membrane proteins is likely to depend strongly on the chemical and physical properties of the membrane. However, membrane proteins are not accessible to many biophysical methods in their native cellular membrane. A major limitation for their functional and structural characterization is thus the requirement for an artificial environment that mimics the native membrane to preserve the integrity and stability of the membrane protein. Most commonly employed are detergent micelles, which can however be detrimental to membrane protein activity and stability. Here, we review recent developments for alternative, nonmicellar solubilization techniques, with a particular focus on their application to solution NMR studies. We discuss the use of amphipols and lipid bilayer systems, such as bicelles and nanolipoprotein particles (NLPs). The latter show great promise for structural studies in near native membranes.

HP1(Swi6) mediates the recognition and destruction of heterochromatic RNA transcripts.

HP1 proteins are major components of heterochromatin, which is generally perceived to be an inert and transcriptionally inactive chromatin structure. Yet, HP1 binding to chromatin is highly dynamic and robust silencing of heterochromatic genes can involve RNA processing. Here, we demonstrate by a combination of in vivo and in vitro experiments that the fission yeast HP1(Swi6) protein guarantees tight repression of heterochromatic genes through RNA sequestration and degradation. Stimulated by positively charged residues in the hinge region, RNA competes with methylated histone H3K9 for binding to the chromodomain of HP1(Swi6). Hence, HP1(Swi6) binding to RNA is incompatible with stable heterochromatin association. We propose a model in which an ensemble of HP1(Swi6) proteins functions as a heterochromatin-specific checkpoint, capturing and priming heterochromatic RNAs for the RNA degradation machinery. Sustaining a functional checkpoint requires continuous exchange of HP1(Swi6) within heterochromatin, which explains the dynamic localization of HP1 proteins on heterochromatin.