Visualizing maturation factor extraction from the nascent ribosome by the AAA-ATPase Drg1.

The AAA-ATPase Drg1 is a key factor in eukaryotic ribosome biogenesis that initiates cytoplasmic maturation of the large ribosomal subunit. Drg1 releases the shuttling maturation factor Rlp24 from pre-60S particles shortly after nuclear export, a strict requirement for downstream maturation. The molecular mechanism of release remained elusive. Here, we report a series of cryo-EM structures that captured the extraction of Rlp24 from pre-60S particles by Saccharomyces cerevisiae Drg1. These structures reveal that Arx1 and the eukaryote-specific rRNA expansion segment ES27 form a joint docking platform that positions Drg1 for efficient extraction of Rlp24 from the pre-ribosome. The tips of the Drg1 N domains thereby guide the Rlp24 C terminus into the central pore of the Drg1 hexamer, enabling extraction by a hand-over-hand translocation mechanism. Our results uncover substrate recognition and processing by Drg1 step by step and provide a comprehensive mechanistic picture of the conserved modus operandi of AAA-ATPases.

Somatic genetic rescue of a germline ribosome assembly defect.

Indirect somatic genetic rescue (SGR) of a germline mutation is thought to be rare in inherited Mendelian disorders. Here, we establish that acquired mutations in the EIF6 gene are a frequent mechanism of SGR in Shwachman-Diamond syndrome (SDS), a leukemia predisposition disorder caused by a germline defect in ribosome assembly. Biallelic mutations in the SBDS or EFL1 genes in SDS impair release of the anti-association factor eIF6 from the 60S ribosomal subunit, a key step in the translational activation of ribosomes. Here, we identify diverse mosaic somatic genetic events (point mutations, interstitial deletion, reciprocal chromosomal translocation) in SDS hematopoietic cells that reduce eIF6 expression or disrupt its interaction with the 60S subunit, thereby conferring a selective advantage over non-modified cells. SDS-related somatic EIF6 missense mutations that reduce eIF6 dosage or eIF6 binding to the 60S subunit suppress the defects in ribosome assembly and protein synthesis across multiple SBDS-deficient species including yeast, Dictyostelium and Drosophila. Our data suggest that SGR is a universal phenomenon that may influence the clinical evolution of diverse Mendelian disorders and support eIF6 suppressor mimics as a therapeutic strategy in SDS.

Mechanism of completion of peptidyltransferase centre assembly in eukaryotes.

During their final maturation in the cytoplasm, pre-60S ribosomal particles are converted to translation-competent large ribosomal subunits. Here, we present the mechanism of peptidyltransferase centre (PTC) completion that explains how integration of the last ribosomal proteins is coupled to release of the nuclear export adaptor Nmd3. Single-particle cryo-EM reveals that eL40 recruitment stabilises helix 89 to form the uL16 binding site. The loading of uL16 unhooks helix 38 from Nmd3 to adopt its mature conformation. In turn, partial retraction of the L1 stalk is coupled to a conformational switch in Nmd3 that allows the uL16 P-site loop to fully accommodate into the PTC where it competes with Nmd3 for an overlapping binding site (base A2971). Our data reveal how the central functional site of the ribosome is sculpted and suggest how the formation of translation-competent 60S subunits is disrupted in leukaemia-associated ribosomopathies.

A Thermodynamic Funnel Drives Bacterial Lipopolysaccharide Transfer in the TLR4 Pathway.

The Gram-negative bacterial outer membrane contains lipopolysaccharide, which potently stimulates the mammalian innate immune response. This involves a relay of specialized complexes culminating in transfer of lipopolysaccharide from CD14 to Toll-like receptor 4 (TLR4) and its co-receptor MD-2 on the cell surface, leading to activation of downstream inflammatory responses. In this study we develop computational models to trace the TLR4 cascade in near-atomic detail. We demonstrate through rigorous thermodynamic calculations that lipopolysaccharide molecules traversing the receptor cascade fall into a thermodynamic funnel. An affinity gradient for lipopolysaccharide is revealed upon extraction from aggregates or realistic bacterial outer membrane models and transfer through CD14 to the terminal TLR4/MD-2 receptor-co-receptor complex. We subsequently assemble viable CD14/TLR4/MD-2 oligomers at the plasma membrane surface, and observe lipopolysaccharide exchange between CD14 and TLR4/MD-2. Collectively, this work helps to unravel the key structural determinants governing endotoxin recognition in the TLR4 innate immune pathway.

Cryo-electron microscopy of membrane proteins.

Membrane proteins represent a large proportion of the proteome, but have characteristics that are problematic for many methods in modern molecular biology (that have often been developed with soluble proteins in mind). For structural studies, low levels of expression and the presence of detergent have been thorns in the flesh of the membrane protein experimentalist. Here we discuss the use of cryo-electron microscopy in breakthrough studies of the structures of membrane proteins. This method can cope with relatively small quantities of sample and with the presence of detergent. Until recently, cryo-electron microscopy could not deliver high-resolution structures of membrane proteins, but recent developments in transmission electron microscope technology and in the image processing of single particles imaged in the microscope have revolutionized the field, allowing high resolution structures to be obtained. Here we focus on the specific issues surrounding the application of cryo-electron microscopy to the study of membrane proteins, especially in the choice of a system to keep the protein soluble.

A polar SxxS motif drives assembly of the transmembrane domains of Toll-like receptor 4.

Like all members of the Toll-like receptor (TLR) family, TLR4 comprises of a large ectodomain (ECD) involved in ligand recognition at the cell-surface, and a cytosolic Toll/interleukin-1 receptor (TIR) signalling domain, linked by a lipid membrane-anchored transmembrane (TM) domain (TMD). Binding of immunostimulatory pathogen-associated molecular patterns (PAMPs) such as bacterial lipopolysaccharide (LPS) to myeloid differentiation factor 2 (MD-2) coreceptor-complexed TLR4 leads to its dimerization, resulting in productive juxtaposition of TIR domains and the initiation of pro-inflammatory innate immune responses. Whilst the process of PAMP recognition is relatively well understood, thanks to numerous high-resolution crystallographic structures of ECDs, the mechanism by which such recognition is translated into TMD dimerization and activating conformational changes is less clear. Based on available biophysical and biochemical experimental data, ab initio modelling, and multiscale molecular dynamics (MD) simulations entailing a total of >13µs and >200µs of atomistic and coarse-grained sampling, respectively, we investigate the structural basis for TLR4 TMD dimerization within a biologically relevant lipid membrane environment. A key polar-xx-polar (637SxxS640) motif is shown to drive association of the TLR4 TMDs, and to maintain a flexible interface, which may be disrupted by selected point mutations. Furthermore, MD simulations of various TMD+ECD constructs have been used to investigate the coupling between domains, revealing that flexible linkers abrogate dimerization via aggregation of ECDs at the membrane surface, explaining previous biochemical observations. These results improve our understanding of the assembly and signalling mechanisms of TLR4, and pave the way for rational structure-based development of membrane-associated immunomodulatory molecules.

Full-length, Oligomeric Structure of Wzz Determined by Cryoelectron Microscopy Reveals Insights into Membrane-Bound States.

Wzz is an integral inner membrane protein involved in regulating the length of lipopolysaccharide O-antigen glycans and essential for the virulence of many Gram-negative pathogens. In all Wzz homologs, the large periplasmic domain is proposed to be anchored by two transmembrane helices, but no information is available for the transmembrane and cytosolic domains. Here we have studied purified oligomeric Wzz complexes using cryoelectron microscopy and resolved the transmembrane regions within a semi-continuous detergent micelle. The transmembrane helices of each monomer display a right-handed super-helical twist, and do not interact with the neighboring transmembrane domains. Modeling, flexible fitting and multiscale simulation approaches were used to study the full-length complex and to provide explanations for the influence of the lipid bilayer on its oligomeric status. Based on structural and in silico observations, we propose a new mechanism for O-antigen chain-length regulation that invokes synergy of Wzz and its polymerase partner, Wzy.

The cystic fibrosis transmembrane conductance regulator (CFTR) and its stability.

The cystic fibrosis transmembrane conductance regulator (CFTR) is responsible for the disease cystic fibrosis (CF). It is a membrane protein belonging to the ABC transporter family functioning as a chloride/anion channel in epithelial cells around the body. There are over 1500 mutations that have been characterised as CF-causing; the most common of these, accounting for ~70 % of CF cases, is the deletion of a phenylalanine at position 508. This leads to instability of the nascent protein and the modified structure is recognised and then degraded by the ER quality control mechanism. However, even pharmacologically 'rescued' F508del CFTR displays instability at the cell's surface, losing its channel function rapidly and it is rapidly removed from the plasma membrane for lysosomal degradation. This review will, therefore, explore the link between stability and structure/function relationships of membrane proteins and CFTR in particular and how approaches to study CFTR structure depend on its stability. We will also review the application of a fluorescence labelling method for the assessment of the thermostability and the tertiary structure of CFTR.

The severity of hereditary porphyria is modulated by the porphyrin exporter and Lan antigen ABCB6.

Hereditary porphyrias are caused by mutations in genes that encode haem biosynthetic enzymes with resultant buildup of cytotoxic metabolic porphyrin intermediates. A long-standing open question is why the same causal porphyria mutations exhibit widely variable penetrance and expressivity in different individuals. Here we show that severely affected porphyria patients harbour variant alleles in the ABCB6 gene, also known as Lan, which encodes an ATP-binding cassette (ABC) transporter. Plasma membrane ABCB6 exports a variety of disease-related porphyrins. Functional studies show that most of these ABCB6 variants are expressed poorly and/or have impaired function. Accordingly, homozygous disruption of the Abcb6 gene in mice exacerbates porphyria phenotypes in the Fech(m1Pas) mouse model, as evidenced by increased porphyrin accumulation, and marked liver injury. Collectively, these studies support ABCB6 role as a genetic modifier of porphyria and suggest that porphyrin-inducing drugs may produce excessive toxicities in individuals with the rare Lan(-) blood type.

The role of protein-protein interactions in Toll-like receptor function.

As part of the innate immune system, the Toll-like receptors (TLRs) represent key players in the first line of defense against invading foreign pathogens, and are also major targets for therapeutic immunomodulation. TLRs are type I transmembrane proteins composed of an ectodomain responsible for ligand binding, a single-pass transmembrane domain, and a cytoplasmic Toll/Interleukin-1 receptor (TIR) signaling domain. The ectodomains of TLRs are specialized for recognizing a wide variety of pathogen-associated molecular patterns, ranging from lipids and lipopeptides to proteins and nucleic acid fragments. The members of the TLR family are highly conserved and their ectodomains are composed of characteristic, solenoidal leucine-rich repeats (LRRs). Upon ligand binding, these rigid LRR scaffolds dimerize (or re-organize in the case of pre-formed dimers) to bring together their carboxy-terminal transmembrane and TIR domains. The latter are proposed to act as a platform for recruitment of adaptor proteins and formation of higher-order complexes, resulting in propagation of downstream signaling cascades. In this review, we discuss the protein-protein interactions critical for formation and stability of productive, ligand-bound TLR complexes. In particular, we focus on the large body of high-resolution crystallographic data now available for the ectodomains of homo- and heterodimeric TLR complexes, as well as inhibitory TLR-like receptors, and also consider computational approaches that can facilitate our understanding of the ligand-induced conformational changes associated with TLR function. We also briefly consider what is known about the protein-protein interactions involved in both TLR transmembrane domain assembly and TIR-mediated signaling complex formation in light of recent structural and biochemical data.