Chemical synthesis of yeast mitochondrial ATP synthase membranous subunit 8

Chemical synthesis of highly hydrophobic peptides and proteins remains a challenging problem. Strong interchain associations within the peptide–resin matrix have to be overcome. A synthetic strategy for solid phase peptide synthesis is proposed, mainly based on prolonged coupling time using aprotic polar solvent mixtures. A tailored chromatographic purification was required to obtain a sample sufficiently pure for structural analysis. In this work, the total chemical synthesis of the membrane‐embedded yeast mitochondrial ATP synthase subunit 8 is described. The quality of the synthetic protein was checked by electrospray mass spectrometry, its tendency to adopt α‐helical secondary structure is evidenced by circular dichroism spectroscopy. Copyright © 1999 European Peptide Society and John Wiley & Sons, Ltd.     

Cell-free synthesis of membrane subunits of ATP synthase in phospholipid bicelles: NMR shows subunit a fold similar to the protein in the cell membrane

NMR structure determination of large membrane proteins is hampered by broad spectral lines, overlap, and ambiguity of signal assignment. Chemical shift and NOE assignment can be facilitated by amino acid selective isotope labeling in cell-free protein synthesis system. However, many biological detergents are incompatible with the cell-free synthesis, and membrane proteins often have to be synthesized in an insoluble form. We report cell-free synthesis of subunits a and c of the proton channel of Escherichia coli ATP synthase in a soluble form in a mixture of phosphatidylcholine derivatives. In comparison, subunit a was purified from the cell-free system and from the bacterial cell membranes. NMR spectra of both preparations were similar, indicating that our procedure for cell-free synthesis produces protein structurally similar to that prepared from the cell membranes.     

Interaction of transmembrane helices in ATP synthase subunit a in solution as revealed by spin label difference NMR

Subunit a in the membrane traversing F₀ sector of Escherichia coli ATP synthase is known to fold with five transmembrane helices (TMHs) with residue 218 in TMH IV packing close to residue 248 in TMH V. In this study, we have introduced a spin label probe at Cys residues substituted at positions 222 or 223 and measured the effects on the Trp ?NH indole NMR signals of the seven Trp residues in the protein. The protein was purified and NMR experiments were carried out in a chloroform-methanol-H₂O (4:4:1) solvent mixture. The spin label at positions 222 or 223 proved to broaden the signals of W231, W232, W235 and W241 located at the periplasmic ends of TMH IV and TMH V and the connecting loop between these helices. The broadening of W241 would require that the loop residues fold back on themselves in a hairpin-like structure much like it is predicted to fold in the native membrane. Placement of the spin label probe at several other positions also proved to have broadening effects on some of these Trp residues and provided additional constraints on folding of TMH IV and TMH V. The effects of the 223 probes on backbone amide resonances of subunit a were also measured by an HNCO experiment and the results are consistent with the two helices folding back on themselves in this solvent mixture. When Cys and Trp were substituted at residues 206 and 254 at the cytoplasmic ends of TMHs IV and V respectively, the W254 resonance was not broadened by the spin label at position 206. We conclude that the helices fold back on themselves in this solvent system and then pack at an angle such that the cytoplasmic ends of the polypeptide backbone are significantly displaced from each other.     

New insight into lysosomal protein storage disease: Delayed catabolism of ATP synthase subunit c in batten disease

Subunit c is normally present as an inner mitochondrial membrane component of the Fo sector of the ATP synthase complex, but in the late infantile form of neuronal ceroid lipofuscinosis (NCL) it was also found in lysosomes in high concentrations. Mechanism for specific accumulation of subunit c in lysosomes is not known. The rate of degradation of subunit c as measured by pulsechase and immunoprecipitation showed a marked delay of degradation in patients fibroblasts with late infantile form of NCL. There were no significant differences between control cells and cells with disease in the degradation of cytochrome oxidase subunit IV, an inner membrane protein of mitochondria. Measurement of labeled subunit c in mitochondrial and lysosomal fractions showed that the accumulation of labeled subunit c in the mitochondrial fraction can be detected before lysosomal appearance of radioactive subunit c, suggesting that subunit c accumulated as a consequence of abnormal catabolism in the mitochondrion and is transferred to lysosomes, through an autophagic process. There were no large differences of various lysosomal protease activities between control and patient cells. In patient cells sucrose loading caused a marked shift of lysosomal density, but did not a shift of subunit c containing storage body. The biosynthetic rate of subunit c and mRNA levels for P1 and P2 genes that code for it were almost the same in both control and patient cells. These findings suggest that a specific failure in the degradation of subunit c after its normal inclusion in mitochondria and its consequent accumulation in lysosomes.Special issue dedicated to Dr. Leon S. Wolfe.     

A new solution structure of ATP synthase subunit c from thermophilic Bacillus PS3, suggesting a local conformational change for H+-translocation

In F(o)F(1)-ATP synthase, an oligomer ring of F(o)c subunits acts as a rotary proton channel of the F(o)-proton motor. On the basis of the solution structure of the Escherichia coli F(o)c (EF(o)c) monomer, the rotation of the C-terminal helix coupled with the reorientation of the essential Asp61 side-chain on deprotonation was proposed to drive rotation of the whole c-ring. We have determined the NMR structure of F(o)c from thermophilic Bacillus PS3, TF(o)c, in an organic solvent mixture (chloroform/methanol (3:1, v/v)). Our results showed that, independent of pH, the carboxyl group of the essential Glu56 of TF(o)c protrudes toward the outside of the hairpin, a third orientation that differs from either of the two orientations in EF(o)c. Therefore, it would be inappropriate to draw conclusions about the mechanism of c-ring rotation on the basis of the conformations observed only for EF(o)c. The appearance of different hairpin structures shows that there are multiple energy minima for the hairpin structure in terms of helix rotation and axial displacement. The multiple energy minima may also provide a base for the different oligomeric states in the c-ring structure. A rotation mechanism of the F(o) motor coupled with H(+)-translocation is discussed on the basis of these results and the recently reported crystal structure of the c-ring from Ilyobacter tartaricus Na(+)-ATPase.     

The mitochondrial ATP synthase ofTrypanosoma brucei: Structure and regulation

The structure and regulation of theTrypanosoma brucei mitochondrial ATP synthase is reviewed. This enzyme complex which catalyzes the synthesis and hydrolysis of ATP within the mitochondrion is a multisubunit complex which is regulated in several ways. Several lines of evidence have shown that the ATP synthase is regulated through the life cycle ofTrypanosoma brucei. The enzyme complex is present at maximal levels in the procyclic form where mitochondrial activity is the highest and cytochromes and Kreb's cycle components are present. The levels of the ATP synthase are decreased in the bloodstream forms where the levels of the mitochondrial cytochromes are absent or substantially decreased. In recent preliminary work we have shown the presence of an ATP synthase inhibitor peptide which may indicate an additional level of complexity to the regulation.     

Solution structure of subunit F(6) from the peripheral stalk region of ATP synthase from bovine heart mitochondria

The ATP synthase enzyme structure includes two stalk assemblies, the central stalk and the peripheral stalk. Catalysis involves rotation of the central stalk assembly together with the membrane-embedded ring of c-subunits driven by the trans-membrane proton-motive force, while the alpha and beta-subunits of F(1) are prevented from co-rotating by their attachment to the peripheral stalk. In the absence of structures of either the intact peripheral stalk or larger complexes containing it, we are studying its individual components and their interactions to build up an overall picture of its structure. Here, we describe an NMR structural characterisation of F(6), which is a 76-residue protein located in the peripheral stalk of the bovine ATP synthase and is essential for coupling between the proton-motive force and catalysis. Isolated F(6) has a highly flexible structure comprising two helices packed together through a loose hydrophobic core and connected by an unstructured linker. Analysis of chemical shifts, (15)N relaxation and RDC measurements confirm that the F(6) structure is flexible on a wide range of timescales ranging from nanoseconds to seconds. The relationship between this structure for isolated F(6) and its role in the intact peripheral stalk is discussed.     

Nucleotide sequence of cDNA clones encoding the complete precursor for subunit delta of thylakoid-located ATP synthase from spinach

The nucleotide sequence of the entire nuclear-encoded precursor for subunit delta of the ATP synthase from spinach thylakoid membranes was determined by cDNA sequencing. Appropriate recombinant DNAs were selected from pBR322 and lambda gt11 libraries made from polyadenylated RNA of greening spinach seedlings. The mature protein consists of 187 amino acid residues corresponding to a molecular weight of 20468. The precursor protein (257 amino acid residues; M _r=27676) is probably processed between a Met-Val bond. The predicted secondary structure of the transit sequence (70 residues; 7.2 kDa) resembles that of the Rieske Fe/S polypeptide, but shows little similarity with those of stromal or luminal proteins. The comparison of the chloroplast delta amino acid sequence with the published delta sequences from respiratory ATP synthases of bacterial and mitochondrial sources and from the thylakoid ATP synthase of the cyanobacterium Synechococcus suggests substantial divergence at the genic level although structural elements appear to be remarkably conserved.     

Dimer ribbons of ATP synthase shape the inner mitochondrial membrane

ATP synthase converts the electrochemical potential at the inner mitochondrial membrane into chemical energy, producing the ATP that powers the cell. Using electron cryo-tomography we show that the ATP synthase of mammalian mitochondria is arranged in long approximately 1-microm rows of dimeric supercomplexes, located at the apex of cristae membranes. The dimer ribbons enforce a strong local curvature on the membrane with a 17-nm outer radius. Calculations of the electrostatic field strength indicate a significant increase in charge density, and thus in the local pH gradient of approximately 0.5 units in regions of high membrane curvature. We conclude that the mitochondrial cristae act as proton traps, and that the proton sink of the ATP synthase at the apex of the compartment favours effective ATP synthesis under proton-limited conditions. We propose that the mitochondrial ATP synthase organises itself into dimer ribbons to optimise its own performance.     

F1F0 ATP synthase subunit c is a substrate of the novel YidC pathway for membrane protein biogenesis

The Escherichia coli YidC protein belongs to the Oxa1 family of membrane proteins that have been suggested to facilitate the insertion and assembly of membrane proteins either in cooperation with the Sec translocase or as a separate entity. Recently, we have shown that depletion of YidC causes a specific defect in the functional assembly of F1F0 ATP synthase and cytochrome o oxidase. We now demonstrate that the insertion of in vitro-synthesized F1F0 ATP synthase subunit c (F0c) into inner membrane vesicles requires YidC. Insertion is independent of the proton motive force, and proteoliposomes containing only YidC catalyze the membrane insertion of F0c in its native transmembrane topology whereupon it assembles into large oligomers. Co-reconstituted SecYEG has no significant effect on the insertion efficiency. Remarkably, signal recognition particle and its membrane-bound receptor FtsY are not required for the membrane insertion of F0c. In conclusion, a novel membrane protein insertion pathway in E. coli is described in which YidC plays an exclusive role.     

The affinity purification and characterization of ATP synthase complexes from mitochondria

The mitochondrial F₁-ATPase inhibitor protein, IF₁, inhibits the hydrolytic, but not the synthetic activity of the F-ATP synthase, and requires the hydrolysis of ATP to form the inhibited complex. In this complex, the α-helical inhibitory region of the bound IF₁ occupies a deep cleft in one of the three catalytic interfaces of the enzyme. Its N-terminal region penetrates into the central aqueous cavity of the enzyme and interacts with the γ-subunit in the enzyme''s rotor. The intricacy of forming this complex and the binding mode of the inhibitor endow IF₁ with high specificity. This property has been exploited in the development of a highly selective affinity procedure for purifying the intact F-ATP synthase complex from mitochondria in a single chromatographic step by using inhibitor proteins with a C-terminal affinity tag. The inhibited complex was recovered with residues 1–60 of bovine IF₁ with a C-terminal green fluorescent protein followed by a His-tag, and the active enzyme with the same inhibitor with a C-terminal glutathione-S-transferase domain. The wide applicability of the procedure has been demonstrated by purifying the enzyme complex from bovine, ovine, porcine and yeast mitochondria. The subunit compositions of these complexes have been characterized. The catalytic properties of the bovine enzyme have been studied in detail. Its hydrolytic activity is sensitive to inhibition by oligomycin, and the enzyme is capable of synthesizing ATP in vesicles in which the proton-motive force is generated from light by bacteriorhodopsin. The coupled enzyme has been compared by limited trypsinolysis with uncoupled enzyme prepared by affinity chromatography. In the uncoupled enzyme, subunits of the enzyme''s stator are degraded more rapidly than in the coupled enzyme, indicating that uncoupling involves significant structural changes in the stator region.     

Structure of the human ATP synthase

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Neuronal cell surface ATP synthase mediates synthesis of extracellular ATP and regulation of intracellular pH

The ATP synthase is known to play important roles in ATP generation and proton translocation within mitochondria. Here, we now provide evidence showing the presence of functional ecto‐ATP synthase on the neuronal surface. Immunoblotting revealed that the α, β subunits of ATP synthase F₁ portion are present in isolated fractions of plasma membrane and biotin‐labelled surface protein from primary cultured neurons; the surface distribution of α, β subunits was also confirmed by immunofluorescence staining. Moreover, α and β subunits were also found in fractions of plasma membrane and lipid rafts isolated from rat brain, and flow cytometry analysis showed α subunits on the surface of acutely isolated brain cells. Activity assays showed that the extracellular ATP generation of cultured neurons could be compromised by α, β subunit antibodies and ATP synthase inhibitors. pH_i (intracellular pH) analysis demonstrated that at low extracellular pH, α or β subunit antibodies decreased pH_i of primary cultured neurons. Therefore, ATP synthase on the surface of neurons may be involved in the machineries of extracellular ATP generation and pH_i homoeostasis.     

Characterization of a highly diverged mitochondrial ATP synthase Fo subunit in Trypanosoma brucei

The mitochondrial F₁F_o ATP synthase of the parasite Trypanosoma brucei has been previously studied in detail. This unusual enzyme switches direction in functionality during the life cycle of the parasite, acting as an ATP synthase in the insect stages, and as an ATPase to generate mitochondrial membrane potential in the mammalian bloodstream stages. Whereas the trypanosome F₁ moiety is relatively highly conserved in structure and composition, the F_o subcomplex and the peripheral stalk have been shown to be more variable. Interestingly, a core subunit of the latter, the normally conserved subunit b, has been resistant to identification by sequence alignment or biochemical methods. Here, we identified a 17 kDa mitochondrial protein of the inner membrane, Tb927.8.3070, that is essential for normal growth, efficient oxidative phosphorylation, and membrane potential maintenance. Pull-down experiments and native PAGE analysis indicated that the protein is both associated with the F₁F_o ATP synthase and integral to its assembly. In addition, its knockdown reduced the levels of F_o subunits, but not those of F₁, and disturbed the cell cycle. Finally, analysis of structural homology using the HHpred algorithm showed that this protein has structural similarities to F_o subunit b of other species, indicating that this subunit may be a highly diverged form of the elusive subunit b.     

ATP synthase from Saccharomyces cerevisiae: location of subunit h in the peripheral stalk region

Subunit h is a component of the peripheral stalk region of ATP synthase from Saccharomyces cerevisiae. It is weakly homologous to subunit F6 in the bovine enzyme, and F6 can replace the function of subunit h in a yeast strain from which the gene for subunit h has been deleted. The removal of subunit h (or F6) uncouples ATP synthesis from the proton motive force. A biotinylation signal has been introduced following the C terminus of subunit h. It becomes biotinylated in vivo, and allows avidin to be bound quantitatively to the purified enzyme complex in vitro. By electron microscopy of the ATP synthase-avidin complex in negative stain and by subsequent image analysis, the C terminus of subunit h has been located in a region of the peripheral stalk that is close to the Fo membrane domain of ATP synthase. Models of the peripheral stalk are proposed that are consistent with this location and with reconstitution experiments conducted with isolated peripheral stalk subunits.     

Frontiers in ATP synthase research: Understanding the relationship between subunit movements and ATP Synthesis

How biological systems make ATP has intrigued many scientists for well over half the 20th century, and because of the importance and complexity of the problem it seems likely to continue to be a source of fascination to both senior and younger investigators well into the 21st century. Scientific battles fought to unravel the vast secrets by which ATP synthases work have been fierce, and great victories have been short-lived, tempered with the realization that more structures are needed, additional subunits remain to be conquered, and that during ATP synthesis, not one, but several subunits may undergo either significant conformational changes, repositioning, or perhaps even physical rotation similar to bacterial flagella^(1,2). In this introductory article, the author briefly summarizes our current knowledge about the complex substructure of ATP synthases, what we have learned from X-ray crystallography of the F₁ unit, and current evidence for subunit movements.     

Isolation and mapping of a putative b subunit of human ATP synthase (ATP-BL) from human leukocytes.

From a human-leukocyte cDNA library, we cloned cDNA encoding a novel protein, which has a significant homology with the b subunit of ATP synthase (proton-transporting ATPase, F1F0-ATPase; EC3.6.1.34) derived from Anabaena sp. strain PCC 7120. The cDNA has an open reading frame of 1314 nucleotides corresponding to 438 amino acids. The coding sequence was 37.9% identical over 57 amino acid with b subunit of ATP synthase. The 34-amino-acid region of the predicted peptide sequence displays a coiled-coil motif that could form a complex with some other protein(s). We designated this novel gene as ATP-BL because of its homology to the b subunit of ATP synthase. The ATP-BL locus was mapped by fluorescence in situ hybridization (FISH) and radiation hybrid mapping to the q24 region of chromosome 16.