Krios I-Titan Krios I at Diamond
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Andreas
Schedlbauer
,
Xu
Han
,
Wouter
Van Bakel
,
Tatsuya
Kaminishi
,
Borja
Ochoa-Lizarralde
,
Idoia
Iturrioz
,
Retina
Çapuni
,
Ransford
Parry
,
Ronny
Zegarra
,
David
Gil-Carton
,
Jorge P.
López-Alonso
,
Kristina
Barragan Sanz
,
Letizia
Brandi
,
Claudio O.
Gualerzi
,
Paola
Fucini
,
Sean R.
Connell
Diamond Proposal Number(s):
[17171, 31586]
Open Access
Abstract: The initiation phase is the rate-limiting step of protein synthesis (translation) and is finely regulated, making it an important drug target. In bacteria, initiation is guided by three initiation factors and involves positioning the start site on the messenger RNA within the P-site on the small ribosomal subunit (30S), where it is decoded by the initiator fMet–tRNA. This process can be efficiently inhibited by GE81112, a natural hydrophilic, noncyclic, nonribosomal tetrapeptide. It is found in nature in three structural variants (A, B, and B1 with molecular masses of 643–658 Da). Previous biochemical and structural characterization of GE81112 indicates that the primary mechanism of action of this antibiotic is to (i) prevent the initiator fMet–tRNA from binding correctly to the P-site and (ii) block conformational rearrangements in initiation factor IF3, resulting in an unlocked 30S preIC state. In this study, using cryo-EM, we have determined the binding site of GE81112 in initiation complexes (3.2–3.7 Å) and on empty ribosomes (2.09 Å). This binding site is within the mRNA channel but remote from the binding site of the initiation factors and initiator fMet–tRNA. This suggests that it acts allosterically to prevent the initiator fMet–tRNA from being locked into place. The binding mode is consistent with previous biochemical studies and recent work identifying the key pharmacophores of GE81112.
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Oct 2025
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Krios I-Titan Krios I at Diamond
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Diamond Proposal Number(s):
[22006, 30374]
Open Access
Abstract: During synthesis of the ribosomal RNA precursor, RNA polymerase I (Pol I) monitors DNA integrity but its response to DNA damage remains poorly studied. Abasic sites are among the most prevalent DNA lesions in eukaryotic cells, and their detection is critical for cell survival. We report cryo-EM structures of Pol I in different stages of stalling at abasic sites, supported by in vitro transcription studies. Slow nucleotide addition opposite abasic sites occurs through base sandwiching between the RNA 3′-end and the Pol I bridge helix. Templating abasic sites can also cause Pol I cleft opening, which enables the A12 subunit to access the active center. Nucleotide addition opposite the lesion induces a translocation intermediate where DNA bases tilt to form hydrogen bonds with the new RNA base. These findings reveal unique mechanisms of Pol I stalling at abasic sites, differing from arrest by bulky lesions or abasic site handling by RNA polymerase II.
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Jun 2025
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Krios I-Titan Krios I at Diamond
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Carlos
Lopez-Robles
,
Stefano
Scaramuzza
,
Elsa
Astorga-Simon
,
Morié
Ishida
,
Chad D.
Williamson
,
Soledad
Banos-Mateos
,
David
Gil-Carton
,
Miguel
Romero-Durana
,
Ander
Vidaurrazaga
,
Juan
Fernandez-Recio
,
Adriana L.
Rojas
,
Juan S.
Bonifacino
,
Daniel
Castaño-Díez
,
Aitor
Hierro
Diamond Proposal Number(s):
[20113, 17171]
Open Access
Abstract: Recycling of membrane proteins enables the reuse of receptors, ion channels and transporters. A key component of the recycling machinery is the endosomal sorting complex for promoting exit 1 (ESCPE-1), which rescues transmembrane proteins from the endolysosomal pathway for transport to the trans-Golgi network and the plasma membrane. This rescue entails the formation of recycling tubules through ESCPE-1 recruitment, cargo capture, coat assembly and membrane sculpting by mechanisms that remain largely unknown. Herein, we show that ESCPE-1 has a single-layer coat organization and suggest how synergistic interactions between ESCPE-1 protomers, phosphoinositides and cargo molecules result in a global arrangement of amphipathic helices to drive tubule formation. Our results thus define a key process of tubule-based endosomal sorting.
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Jun 2023
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Krios II-Titan Krios II at Diamond
Krios III-Titan Krios III at Diamond
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Diamond Proposal Number(s):
[15997, 22006]
Open Access
Abstract: Pyruvate carboxylase (PC) is a tetrameric enzyme that contains two active sites per subunit that catalyze two consecutive reactions. A mobile domain with an attached prosthetic biotin links both reactions, an initial biotin carboxylation and the subsequent carboxyl transfer to pyruvate substrate to produce oxaloacetate. Reaction sites are at long distance, and there are several co-factors that play as allosteric regulators. Here, using cryoEM we explore the structure of active PC tetramers focusing on active sites and on the conformational space of the oligomers. The results capture the mobile domain at both active sites and expose catalytic steps of both reactions at high resolution, allowing the identification of substrates and products. The analysis of catalytically active PC tetramers reveals the role of certain motions during enzyme functioning, and the structural changes in the presence of additional cofactors expose the mechanism for allosteric regulation.
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Oct 2022
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Krios I-Titan Krios I at Diamond
Krios II-Titan Krios II at Diamond
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Andreas
Schedlbauer
,
Idoia
Iturrioz
,
Borja
Ochoa-Lizarralde
,
Tammo
Diercks
,
Jorge Pedro
Lopez-Alonso
,
José Luis
Lavin
,
Tatsuya
Kaminishi
,
Retina
Çapuni
,
Neha
Dhimole
,
Elisa
De Astigarraga
,
David
Gil-Carton
,
Paola
Fucini
,
Sean R.
Connell
Diamond Proposal Number(s):
[17171, 15422]
Open Access
Abstract: While a structural description of the molecular mechanisms guiding ribosome assembly in eukaryotic systems is emerging, bacteria use an unrelated core set of assembly factors for which high-resolution structural information is still missing. To address this, we used single-particle cryo–electron microscopy to visualize the effects of bacterial ribosome assembly factors RimP, RbfA, RsmA, and RsgA on the conformational landscape of the 30S ribosomal subunit and obtained eight snapshots representing late steps in the folding of the decoding center. Analysis of these structures identifies a conserved secondary structure switch in the 16S ribosomal RNA central to decoding site maturation and suggests both a sequential order of action and molecular mechanisms for the assembly factors in coordinating and controlling this switch. Structural and mechanistic parallels between bacterial and eukaryotic systems indicate common folding features inherent to all ribosomes.
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Jun 2021
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Krios I-Titan Krios I at Diamond
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Diamond Proposal Number(s):
[6916, 17171]
Open Access
Abstract: Glycogen and starch are the major carbon and energy reserve polysaccharides in nature, providing living organisms with a survival advantage. The evolution of the enzymatic machinery responsible for the biosynthesis and degradation of such polysaccharides, led the development of mechanisms to control the assembly and disassembly rate, to store and recover glucose according to cell energy demands. The tetrameric enzyme ADP-glucose pyrophosphorylase (AGPase) catalyzes and regulates the initial step in the biosynthesis of both α-polyglucans. AGPase displays cooperativity and allosteric regulation by sensing metabolites from the cell energy flux. The understanding of the allosteric signal transduction mechanisms in AGPase arises as a long-standing challenge. In this work, we disclose the cryoEM structures of the paradigmatic homotetrameric AGPase from Escherichia coli (EcAGPase), in complex with either positive or negative physiological allosteric regulators, fructose-1,6-bisphosphate (FBP) and AMP respectively, both at 3.0 Å resolution. Strikingly, the structures reveal that FBP binds deeply into the allosteric cleft and overlaps the AMP site. As a consequence, FBP promotes a concerted conformational switch of a regulatory loop, RL2, from a “locked” to a “free” state, modulating ATP binding and activating the enzyme. This notion is strongly supported by our complementary biophysical and bioinformatics evidence, and a careful analysis of vast enzyme kinetics data on single-point mutants of EcAGPase. The cryoEM structures uncover the residue interaction networks (RIN) between the allosteric and the catalytic components of the enzyme, providing unique details on how the signaling information is transmitted across the tetramer, from which cooperativity emerges. Altogether, the conformational states visualized by cryoEM reveal the regulatory mechanism of EcAGPase, laying the foundations to understand the allosteric control of bacterial glycogen biosynthesis at the molecular level of detail.
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Nov 2020
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Krios I-Titan Krios I at Diamond
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Diamond Proposal Number(s):
[17171]
Open Access
Abstract: The vertical double β-barrel major capsid protein (MCP) fold, fingerprint of the PRD1-adeno viral lineage, is widespread in many viruses infecting organisms across the three domains of life. The discovery of PRD1-like viruses with two MCPs challenged the known assembly principles. Here, we present the cryo-electron microscopy (cryo-EM) structures of the archaeal, halophilic, internal membrane-containing Haloarcula californiae icosahedral virus 1 (HCIV-1) and Haloarcula hispanica icosahedral virus 2 (HHIV-2) at 3.7 and 3.8 Å resolution, respectively. Our structures reveal proteins located beneath the morphologically distinct two- and three-tower capsomers and homopentameric membrane proteins at the vertices that orchestrate the positioning of pre-formed vertical single β-barrel MCP heterodimers. The cryo-EM based structures together with the proteomics data provide insights into the assembly mechanism of this type of viruses and into those with membrane-less double β-barrel MCPs.
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Mar 2019
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Krios I-Titan Krios I at Diamond
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Abstract: RNA polymerase I (Pol I) transcribes ribosomal DNA (rDNA) to produce the ribosomal RNA (rRNA) precursor, which accounts for up to 60% of the total transcriptional activity in growing cells. Pol I monitors rDNA integrity and influences cell survival, but little is known about how this enzyme processes UV-induced lesions. We report the electron cryomicroscopy structure of Pol I in an elongation complex containing a cyclobutane pyrimidine dimer (CPD) at a resolution of 3.6 Å. The structure shows that the lesion induces an early translocation intermediate exhibiting unique features. The bridge helix residue Arg1015 plays a major role in CPD-induced Pol I stalling, as confirmed by mutational analysis. These results, together with biochemical data presented here, reveal the molecular mechanism of Pol I stalling by CPD lesions, which is distinct from Pol II arrest by CPD lesions. Our findings open the avenue to unravel the molecular mechanisms underlying cell endurance to lesions on rDNA.
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Aug 2018
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Krios I-Titan Krios I at Diamond
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Fabrizio
Martino
,
Mohinder
Pal
,
Hugo
Muñoz-Hernández
,
Carlos F.
Rodríguez
,
Rafael
Núñez-Ramírez
,
David
Gil-Carton
,
Gianluca
Degliesposti
,
J. Mark
Skehel
,
Mark
Roe
,
Chrisostomos
Prodromou
,
Laurence H.
Pearl
,
Oscar
Llorca
Diamond Proposal Number(s):
[13312, 13520, 15997]
Open Access
Abstract: The R2TP/Prefoldin-like co-chaperone, in concert with HSP90, facilitates assembly and cellular stability of RNA polymerase II, and complexes of PI3-kinase-like kinases such as mTOR. However, the mechanism by which this occurs is poorly understood. Here we use cryo-EM and biochemical studies on the human R2TP core (RUVBL1–RUVBL2–RPAP3–PIH1D1) which reveal the distinctive role of RPAP3, distinguishing metazoan R2TP from the smaller yeast equivalent. RPAP3 spans both faces of a single RUVBL ring, providing an extended scaffold that recruits clients and provides a flexible tether for HSP90. A 3.6 Å cryo-EM structure reveals direct interaction of a C-terminal domain of RPAP3 and the ATPase domain of RUVBL2, necessary for human R2TP assembly but absent from yeast. The mobile TPR domains of RPAP3 map to the opposite face of the ring, associating with PIH1D1, which mediates client protein recruitment. Thus, RPAP3 provides a flexible platform for bringing HSP90 into proximity with diverse client proteins.
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Apr 2018
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Krios I-Titan Krios I at Diamond
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Diamond Proposal Number(s):
[13520, 14507]
Open Access
Abstract: The R2TP complex, comprising the Rvb1p-Rvb2p AAA-ATPases, Tah1p, and Pih1p in yeast, is a specialized Hsp90 co-chaperone required for the assembly and maturation of multi-subunit complexes. These include the small nucleolar ribonucleoproteins, RNA polymerase II, and complexes containing phosphatidylinositol-3-kinase-like kinases. The structure and stoichiometry of yeast R2TP and how it couples to Hsp90 are currently unknown. Here, we determine the 3D organization of yeast R2TP using sedimentation velocity analysis and cryo-electron microscopy. The 359-kDa complex comprises one Rvb1p/Rvb2p hetero-hexamer with domains II (DIIs) forming an open basket that accommodates a single copy of Tah1p-Pih1p. Tah1p-Pih1p binding to multiple DII domains regulates Rvb1p/Rvb2p ATPase activity. Using domain dissection and cross-linking mass spectrometry, we identified a unique region of Pih1p that is essential for interaction with Rvb1p/Rvb2p. These data provide a structural basis for understanding how R2TP couples an Hsp90 dimer to a diverse set of client proteins and complexes.
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Jul 2017
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