Project description:The ribosome maturation factor Rea1 (or Midasin) catalyses the removal of assembly factors from large ribosomal subunit precursors and to promotes their export from the nucleus to the cytosol. Rea1 consists of nearly 5000 amino-acid residues and belongs to the AAA+ protein family. It consists of a ring of six AAA+ domains from which the ≈ 1700 amino-acid residue linker emerges that is subdivided into stem, middle and top domains. A flexible and unstructured D/E rich region connects the linker top to a MIDAS (metal ion dependent adhesion site) domain, which is able to bind the assembly factor substrates. Despite its key importance for ribosome maturation, the Rea1 mechanism driving assembly factor removal by Rea1 is still poorly understood. Here we demonstrate that the Rea1 linker 30 is essential for assembly factor removal. It rotates and swings towards the AAA+ ring following a complex remodelling scheme involving nucleotide independent as well as nucleotide dependent steps. ATP-hydrolysis is required to engage the linker with the AAA+ ring and ultimately with the AAA+ ring docked MIDAS domain. The interaction between the linker top and the MIDAS domain allows direct force transmission for assembly factor removal. To evaluate the conformational changes and spatial proximities in presence or absence of nucleotides we carried out XL-MS experiments using PhoX on purified Rea1 in presence of ATPgS, AMP-PNP or in Apo state (in XL triplicates each).

Project description:F1FO-ATP synthases play a central role in cellular metabolism, making the energy of the protonmotive force across a membrane available for a large number of energy-consuming processes. We determined the single-particle cryo-EM structure of active dimeric ATP synthase from mitochondria of Polytomella sp. at 2.7- 2.8 Å resolution. Separation of 13 well-defined rotary substates by 3D classification provides a detailed picture of the molecular motions that accompany c-ring rotation and result in ATP synthesis. Crucially, the F1 head rotates along with the central stalk and c-ring rotor for the first ~30° of each 120° primary rotary step. The joint movement facilitates flexible coupling of the stoichiometrically mismatched F1 and FO subcomplexes. Flexibility is mediated primarily by the interdomain hinge of the conserved OSCP subunit, a well-established target of physiologically important inhibitors. Our maps provide atomic detail of the c-ring/a-subunit interface in the membrane, where protonation and deprotonation of c-ring cGlu111 drives rotary catalysis. An essential histidine residue in the lumenal proton access channel binds a strong non-peptide density assigned to a metal ion that may facilitate c-ring protonation, as its coordination geometry changes with c-ring rotation. We resolve ordered water molecules in the proton access and release channels and at the gating aArg239 that is critical in all rotary ATPases. We identify the previously unknown ASA10 subunit and present complete de novo atomic models of subunits ASA1-10, which make up the two interlinked peripheral stalks that stabilize the Polytomella ATP synthase dimer.

Project description:Impact of monomeric and oligomeric α-synuclein on ATP synthase oxidation.

Project description:Magnesium (Mg2+) uptake systems are present in all domains of life given the vital role of this ion. Bacteria acquire Mg2+ via conserved Mg2+ channels and transporters. The transporters are required for growth when Mg2+ is limiting or during bacterial pathogenesis, but, despite their significance, there are currently no known structures for these transporters. Here we report the first structure of the Mg2+ transporter MgtA solved by single particle cryo-electron microscopy (cryo-EM). We obtained high resolution structures of both a homodimeric form (2.9 A), the first for a P-type ATPase, and a monomeric form (3.6 A). Each monomer unit of MgtA displays a structural architecture that is similar to other P-type ATPases with a transmembrane domain and two soluble domains. The dimer interface consists of contacts between residues in adjacent soluble nucleotide binding and phosphotransfer regions of the haloacid dehalogenase (HAD) domain. The ATP binding site and consequences of nucleotide binding were characterized by a combination of cryo-EM, molecular dynamics simulations, hydrogen-deuterium exchange mass spectrometry, and mutagenesis. Finally, our structure revealed a Mg2+ ion in the transmembrane segments, which, when combined with sequence conservation and mutagenesis studies, allowed us to propose a model for Mg2+ transport across the lipid bilayer. Our dimeric structures of MgtA also reveal regulatory features that have implications for related P-type ATPases such as the calcium pump SERCA.

Project description:Purified mitochondrial ATP synthase has been shown to form Ca2+-activated, large conductance channel activity similar to that of mitochondrial megachannel (MMC) or mitochondrial permeability transition pore (mPTP) but the oligomeric state required for channel formation is being debated. We reconstitute purified monomeric ATP synthase from porcine heart mitochondria into small unilamellar vesicles (SUVs) with the lipid composition of mitochondrial inner membrane and analyze its oligomeric state by electron cryomicroscopy. The cryo-EM density map reveals the presence of a single ATP synthase monomer with no density seen for a second molecule tilted at an 86o angle relative to the first. We show that this preparation of SUV-reconstituted ATP synthase monomers, when fused into giant unilamellar vesicles (GUVs), forms voltage-gated and Ca2+-activated channels with the key features of mPTP. Based on our findings we conclude that the ATP synthase monomer is sufficient, and dimer formation is not required, for mPTP activity.

Project description:Two identical sister copies of eukaryotic chromosomes are synthesised during S-phase. To facilitate their recognition as pairs for segregation in mitosis, sister chromatids are held together from their synthesis onwards by the chromosomal cohesin complex. It is thought that replication fork progression is coupled to establishment of sister chromatid cohesion, thus facilitating identification of replication products, but evidence for this has remained circumstantial. Here we show that three proteins required for sister chromatid cohesion, Eco1, Ctf4 and Ctf18 are found close to, and Ctf4 travels along chromosomes with replication forks. The ring-shaped cohesin complex is loaded onto chromosomes before S-phase in an ATP hydrolysis-dependent reaction. Cohesion establishment during DNA replication follows without further cohesin recruitment, and without need for cohesin to re-engage an ATP hydrolysis motif that is critical for its initial DNA binding. This provides evidence for cohesion establishment in the context of replication forks and imposes constraints on the mechanism involved. Keywords: ChIP on chip

Project description:The bioactive lipid intermediate palmitoyl CoA (PCoA) can inhibit mitochondrial ADP/ATP transport, though the physiological relevance of this regulation remains unclear. We questioned whether myocardial ischaemia was a pathological setting in which PCoA regulation of ADP/ATP transport would be beneficial. Secondly, whether the chronically elevated lipid content within the diabetic heart would make the mitochondria less sensitive to the inhibitory effects of PCoA, with detrimental consequences during ischaemia. Palmitoyl CoA acutely decreased ADP-stimulated state 3 respiration, increasing the Km for ADP 2-fold. The half maximal inhibitory concentration (IC50) of PCoA in control mitochondria was 22 µM. This inhibitory effect of PCoA on respiration was blunted in the diabetic mitochondria, with no significant difference in the Km in the presence of PCoA, and the IC50 increased to 32 µM PCoA. The competitive inhibition by PCoA was localised to the phosphorylation apparatus, particularly the ADP/ATP carrier (AAC). During ischaemia, the AAC imports ATP into the mitochondria, where it is hydrolysed by reversal of the ATP synthase, to regenerate the membrane potential. Addition of PCoA dose-dependently prevented this wasteful ATP hydrolysis for membrane repolarisation during ischaemia. However, this beneficial effect was blunted in the diabetic mitochondria. Finally, using 31P-magnetic resonance spectroscopy we demonstrated that diabetic hearts lose ATP more rapidly during ischaemia, with a 3-fold higher ATP decay rate compared with control hearts. In conclusion, PCoA plays a role in protecting mitochondrial energetics during ischaemia, by preventing wasteful ATP hydrolysis. However, this beneficial effect is blunted in diabetes, contributing to the impaired energy metabolism during myocardial ischaemia.

Project description:The ring-shaped cohesin complex is thought to fulfil its roles in sister chromatid cohesion, genome stability and gene regulation by topologically encircling DNAs. The ring is formed by two Structural Maintenance of Chromosome (SMC) subunits, whose ATPase heads are linked by a kleisin subunit. Additional components, including the Mis4Scc2/NIPL cohesin loader, engage the kleisin. Here, we visualize a DNA gripping intermediate during cohesin loading onto DNA by cryo-electron microscopy. ATP-dependent head engagement creates an interaction surface onto which Mis4Scc2/NIPL clamps the DNA. We use biophysical tools to establish the order of events during cohesin loading. DNA first traverses an N-terminal kleisin gate that was opened by ATP binding and closed again as the loader locks the DNA. Ensuing ATP hydrolysis and head disengagement, assisted by Mis4Scc2/NIPL, will complete DNA entry. A conserved kleisin N-terminal tail guides the DNA on its trajectory to successful topological DNA entry into the cohesin ring.

Project description:The chloroplast stromal CLP protease system is essential for growth and development. It consists of a proteolytic CLP core complex that likely dynamically interacts with oligomeric rings of CLPC1, CLPC2 or CLPD AAA+ chaperones. These ATP-dependent chaperones are predicted to bind and unfold CLP protease substrates, frequently aided by adaptors (recognins), and feed them into the proteolytic CLP core for degradation. To identify new substrates and possible also new adaptors for the chloroplast CLP protease system, we generated an in vivo CLPC1 substrate trap with a C-terminal STREPII affinity tag in Arabidopsis thaliana by mutating critical glutamate residues (E374A and E718A) in the two Walker B domains of CLPC1 required for hydrolysis of ATP (CLPC1-TRAP). Based on homology to non-plant CLPB/C chaperones, it is predicted that interacting substrates are unable to be released, i.e. they are trapped. When expressed in wild-type, this CLPC1-TRAP induced a dominant visible phenotype, whereas no viable mutants that express CLPC1-TRAP in the clpc1-1 null mutant could be recovered. Affinity purification of the CLPC1-TRAP resulted in a dozen proteins highly enriched compared to affinity purified CLPC1 with a C-terminal STREPII affinity tag (CLPC1-WT). These enriched proteins likely represent CLP protease substrates and/or new adaptors. Several of these trapped proteins over-accumulated in clp mutants and/or were found as interactions for the adaptor CLPS1, supporting their functional relationship to CLP function. Importantly, affinity purification of this CLPC1-TRAP also showed high enrichment of all CLPP, CLPR and CLPT subunits, indicating stabilization of the CLPC to CLP core interaction and providing direct support for their physical and functional interaction.

Project description:The chloroplast stromal CLP protease system is essential for growth and development. It consists of a proteolytic CLP core complex that likely dynamically interacts with oligomeric rings of CLPC1, CLPC2 or CLPD AAA+ chaperones. These ATP-dependent chaperones are predicted to bind and unfold CLP protease substrates, frequently aided by adaptors (recognins), and feed them into the proteolytic CLP core for degradation. To identify new substrates and possible also new adaptors for the chloroplast CLP protease system, we generated an in vivo CLPC1 substrate trap with a C-terminal STREPII affinity tag in Arabidopsis thaliana by mutating critical glutamate residues (E374A and E718A) in the two Walker B domains of CLPC1 required for hydrolysis of ATP (CLPC1-TRAP). Based on homology to non-plant CLPB/C chaperones, it is predicted that interacting substrates are unable to be released, i.e. they are trapped. When expressed in wild-type, this CLPC1-TRAP induced a dominant visible phenotype, whereas no viable mutants that express CLPC1-TRAP in the clpc1-1 null mutant could be recovered. Affinity purification of the CLPC1-TRAP resulted in a dozen proteins highly enriched compared to affinity purified CLPC1 with a C-terminal STREPII affinity tag (CLPC1-WT). These enriched proteins likely represent CLP protease substrates and/or new adaptors. Several of these trapped proteins over-accumulated in clp mutants and/or were found as interactions for the adaptor CLPS1, supporting their functional relationship to CLP function. Importantly, affinity purification of this CLPC1-TRAP also showed high enrichment of all CLPP, CLPR and CLPT subunits, indicating stabilization of the CLPC to CLP core interaction and providing direct support for their physical and functional interaction.