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The ATP-binding cassette subfamily B member 1 (ABCB1) multidrug transporter P-glycoprotein plays a central role in clearance of xenobiotics in humans and is implicated in cancer resistance to chemotherapy. We used double electron electron resonance spectroscopy to uncover the basis of stimulation of P-glycoprotein adenosine 5′-triphosphate (ATP) hydrolysis by multiple substrates and illuminate how substrates and inhibitors differentially affect its transport function. Our results reveal that substrate-induced acceleration of ATP hydrolysis correlates with stabilization of a high-energy, post-ATP hydrolysis state characterized by structurally asymmetric nucleotide-binding sites. By contrast, this state is destabilized in the substrate-free cycle and by high-affinity inhibitors in favor of structurally symmetric nucleotide binding sites. Together with previous data, our findings lead to a general model of substrate and inhibitor coupling to P-glycoprotein.

Double electron–electron resonance and computer simulations are used to describe conformational dynamics in the ATP-binding cassette transporter Pgp, which has an important role in the clearance of xenobiotics and cancer resistance to chemotherapy. Not as easy as ABC Despite numerous biochemical and structural studies, it remains unclear how ATP-binding cassette (ABC) transporters convert energy from ATP hydrolysis into the translocation of substrates across cellular membranes. Now, Hassane Mchaourab and colleagues have combined double electron–electron resonance (DEER) and computer simulations to describe a two-stroke ATP hydrolysis cycle that leads the mammalian ABC transporter Pgp from an inward- to an outward-facing conformation. The results have implications for basic cellular processes such as the clearance of xenobiotics as well as clinical issues such as cancer resistance to chemotherapy. ATP binding cassette (ABC) transporters of the exporter class harness the energy of ATP hydrolysis in the nucleotide-binding domains (NBDs) to power the energetically uphill efflux of substrates by a dedicated transmembrane domain (TMD) 1 , 2 , 3 , 4 . Although numerous investigations have described the mechanism of ATP hydrolysis and defined the architecture of ABC exporters, a detailed structural dynamic understanding of the transduction of ATP energy to the work of substrate translocation remains elusive. Here we used double electron–electron resonance 5 , 6 and molecular dynamics simulations to describe the ATP- and substrate-coupled conformational cycle of the mouse ABC efflux transporter P-glycoprotein (Pgp; also known as ABCB1), which has a central role in the clearance of xenobiotics and in cancer resistance to chemotherapy 7 . Pairs of spin labels were introduced at residues selected to track the putative inward-facing to outward-facing transition. Our findings illuminate how ATP energy is harnessed in the NBDs in a two-stroke cycle and elucidate the consequent conformational motion that reconfigures the TMD, two critical aspects of Pgp transport mechanism. Along with a fully atomistic model of the outward-facing conformation in membranes, the insight into Pgp conformational dynamics harmonizes mechanistic and structural data into a novel perspective on ATP-coupled transport and reveals mechanistic divergence within the efflux class of ABC transporters.

Cell survival under nutrient-deprived conditions relies on cells’ ability to adapt their organelles and rewire their metabolic pathways. In yeast, glucose depletion induces a stress response mediated by mitochondrial fragmentation and sequestration of cytosolic ribosomes on mitochondria. This cellular adaptation promotes survival under harsh environmental conditions; however, the underlying mechanism of this response remains unknown. Here, we demonstrate that upon glucose depletion protein synthesis is halted. Cryo-electron microscopy structure of the ribosomes show that they are devoid of both tRNA and mRNA, and a subset of the particles depicted a conformational change in rRNA H69 that could prevent tRNA binding. Our in situ structural analyses reveal that the hibernating ribosomes tether to fragmented mitochondria and establish eukaryotic-specific, higher-order storage structures by assembling into oligomeric arrays on the mitochondrial surface. Notably, we show that hibernating ribosomes exclusively bind to the outer mitochondrial membrane via the small ribosomal subunit during cellular stress. We identify the ribosomal protein Cpc2/RACK1 as the molecule mediating ribosomal tethering to mitochondria. This study unveils the molecular mechanism connecting mitochondrial stress with the shutdown of protein synthesis and broadens our understanding of cellular responses to nutrient scarcity and cell quiescence. Cells adapt to low glucose by halting protein synthesis and altering organelle shape. Here the authors showed that hibernating ribosomes tether to mitochondria and form arrays on the membrane, acting as a pro-survival mechanism in dormant yeast cells.

The nascent polypeptide-associated complex (NAC) co-translationally screens all nascent proteins and regulates their access to the signal recognition particle (SRP) to ensure the fidelity of protein targeting to the endoplasmic reticulum (ER). However, the mechanism by which NAC prevents the mistargeting of nascent mitochondrial proteins remains unclear. Here, we identified a molecular switch in NAC that allows its central barrel domain to adopt a stabilized conformation on ribosomes exposing a mitochondrial targeting sequence (MTS). Mutations of the MTS on the nascent chain or in the NAC switch region increases NAC barrel dynamics and reduces its binding to the ribosome. This leads to an impaired ability of NAC to prevent mistargeting by SRP and causes ER stress in human cells. Our work reveals how NAC detects nascent mitochondrial proteins early in translation and prevents their promiscuous access to SRP, elucidating the structural basis that underlies this role and providing novel insights into protein targeting fidelity with broader implications for cellular proteostasis.

Cell survival under nutrient-deprived conditions relies on cells’ ability to adapt their organelles and to rewire their metabolic pathways. In the fission yeast Schizosaccharomyces pombe, nutrient depletion is an unfavorable condition for protein synthesis and triggers a response characterized by mitochondrial fragmentation and the sequestration of cytosolic ribosomes on mitochondria. The molecular mechanism underlying ribosomal sequestration remains elusive. In this study, we performed time-lapse in situ cryo-electron tomography and cryo-electron microscopy complemented by biochemical experiments to elucidate the molecular details of this adaptive response. Our analysis indicate that upon glucose depletion protein synthesis is halted, causing ribosomes to enter an inactive state characterized by a conformational change that obstructs the peptidyl transferase center. Our in situ experiments reveal the presence of oligomeric arrays of hibernating ribosomes tethered to the mitochondrial surface. Surprisingly, ribosomes bind to the outer mitochondrial membrane via the small ribosomal subunit, an interaction facilitated by the ribosomal protein RACK1-orthologue Cpc2. Our experiments show that ribosome tethering is important for cell survival under glucose depletion conditions. This study broadens our understanding of the cellular adaptations triggered by nutrient scarcity and the underlying molecular mechanisms that regulate cell quiescence.

Membrane sculpting proteins shape the morphology of cell membranes and facilitate remodeling in response to physiological and environmental cues. Complexes of the monotopic membrane protein caveolin function as essential curvature-generating components of caveolae, flask-shaped invaginations that sense and respond to plasma membrane tension. However, the structural basis for caveolin’s membrane remodeling activity is currently unknown. Here, we show, using cryo-electron microscopy, that the human caveolin-1 complex is composed of 11 protomers organized into a tightly packed disc with a flat membrane-embedded surface. The structural insights suggest a new mechanism for how membrane sculpting proteins interact with membranes and reveal how key regions of caveolin-1, including its scaffolding, oligomerization, and intramembrane domains, contribute to its function. Cryo-electron microscopy reveals that Caveolin-1 oligomerizes into a tightly packed disc with a flat membrane-binding surface.

Caveolin-1 (CAV1) is a membrane sculpting protein that oligomerizes to generate flask-shaped invaginations of the plasma membrane known as caveolae. Mutations in CAV1 have been linked to multiple diseases in humans. Such mutations often interfere with oligomerization and the intracellular trafficking processes required for successful caveolae assembly, but the molecular mechanisms underlying these defects have not been structurally explained. Here, we investigate how a breast cancer-associated mutation in one of the most highly conserved residues in CAV1, P132L, affects CAV1 structure and oligomerization. We show that P132 is positioned at a major site of protomer-protomer interactions within the CAV1 complex, providing a structural explanation for why the mutant protein fails to homo-oligomerize correctly. Using a combination of computational, structural, biochemical, and cell biological approaches, we find that despite its homo-oligomerization defects P132L is capable of forming mixed hetero-oligomeric complexes with wild type CAV1 and that these complexes can be incorporated into caveolae. These findings provide insights into the fundamental mechanisms that control the formation of homo- and hetero-oligomers of caveolins that are essential for caveolae biogenesis, as well as how these processes are disrupted in human disease. Competing Interest Statement The authors have declared no competing interest.

Abstract Processing of the amyloid precursor protein (APP) via the amyloidogenic pathway is associated with the etiology of Alzheimer’s disease. The cleavage of APP by β-secretase to generate the transmembrane 99-residue C-terminal fragment (C99) and subsequent processing of C99 by γ-secretase to yield amyloid-β (Aβ) peptides are essential steps in this pathway. Biochemical evidence suggests amyloidogenic processing of C99 occurs in cholesterol- and sphingolipid-enriched liquid ordered phase membrane raft domains. However, direct evidence that C99 preferentially associates with rafts has remained elusive. Here, we test this idea by quantifying the affinity of C99-GFP for raft domains in cell-derived giant plasma membrane vesicles. We find that C99 is essentially excluded from ordered domains in HeLa cells, SH-SY5Y cells and neurons, instead exhibiting a strong (roughly 90%) affinity for disordered domains. The strong association of C99 with disordered domains occurs independently of its cholesterol binding activity, homodimerization, or the familial Alzheimer disease Arctic mutation. Finally, we confirm previous studies suggesting that C99 is processed in the plasma membrane by α-secretase, in addition to the well-known γ-secretase. These findings suggest that C99 itself lacks an intrinsic affinity for raft domains, implying either that amyloidogenic processing of the protein occurs in disordered regions of the membrane, that processing involves a marginal sub-population of C99 found in rafts, or that as-yet-unidentified protein-protein interactions involving C99 in living cells drive it into rafts to promote its cleavage therein. Competing Interest Statement The authors have declared no competing interest. * Abbreviations Aβ amyloid-β APP amyloid precursor protein BACE1 β-site amyloid precursor protein cleaving enzyme 1 DRM detergent resistant membrane GPMV giant plasma membrane vesicle GUV giant unilamellar vesicle Ld liquid disordered Lo liquid ordered TfR transferrin receptor TMD transmembrane domain v number of GPMVs measured

Highly stable oligomeric complexes of the monotopic membrane protein caveolin serve as fundamental building blocks of caveolae. Current evidence suggests these complexes are disc shaped, but the details of their structural organization and how they assemble are poorly understood. Here, we address these questions using single particle electron microscopy of negatively stained recombinant 8S complexes of human Caveolin-1. We show that 8S complexes are toroidal structures ~15 nm in diameter that consist of an outer ring, an inner ring, and central protruding stalk. Moreover, we map the position of the N- and C-termini and determine their role in complex assembly, and visualize the 8S complexes in heterologous caveolae. Our findings provide critical insights into the structural features of 8S complexes and allow us to propose a new model for how these highly stable membrane-embedded complexes are generated. Competing Interest Statement The authors have declared no competing interest.