Movement of the helical domain of the epsilon subunit is required for the activation of thermophilic F1-ATPase

The inhibitory effect of epsilon subunit in F(1)-ATPase from thermophilic Bacillus PS3 was examined focusing on the structure-function relationship. For this purpose, we designed a mutant for epsilon subunit similar to the one constructed by Schulenberg and Capaldi (Schulenberg, B., and Capaldi, R. A. (1999) J. Biol. Chem. 274, 28351-28355). We introduced two cysteine residues at the interface of N-terminal beta-sandwich domain (S48C) and C-terminal alpha-helical domain (N125C) of epsilon subunit. The alpha(3)beta(3)gammaepsilon complex containing the reduced form of this mutant epsilon subunit showed suppressed ATPase activity and gradual activation during the measurement. This activation pattern was similar to the complex with the wild type epsilon subunit. The conformation of the mutant epsilon subunit must be fixed and similar to the reported three-dimensional structure of the isolated epsilon subunit, when the intramolecular disulfide bridge was formed on this subunit by oxidation. This oxidized mutant epsilon subunit could form the alpha(3)beta(3)gammaepsilon complex but did not show any inhibitory effect. The complex was converted to the activated state, and the cross-link in the mutant epsilon subunit in the complex was efficiently formed in the presence of ATP-Mg, whereas no cross-link was observed without ATP-Mg, suggesting the conformation of the oxidized mutant epsilon subunit must be similar to that in the activated state complex. A non-hydrolyzable analog of ATP, 5'-adenylyl-beta,gamma-imidodiphosphate, could stimulate the formation of the cross-link on the epsilon subunit. Furthermore, the cross-link formation was stimulated by nucleotides even when this mutant epsilon subunit was assembled with a mutant alpha(3)beta(3)gamma complex lacking non-catalytic sites. These results indicate that binding of ATP to the catalytic sites induces a conformational change in the epsilon subunit and triggers transition of the complex from the suppressed state to the activated state.     

Synchronized domain-opening motion of GroEL is essential for communication between the two rings

Escherichia coli chaperonin GroEL consists of two stacked rings of seven identical subunits each. Accompanying binding of ATP and GroES to one ring of GroEL, that ring undergoes a large en bloc domain movement, in which the apical domain twists upward and outward. A mutant GroEL(AEX) (C138S,C458S,C519S,D83C,K327C) in the oxidized form is locked in a closed conformation by an interdomain disulfide cross-link and cannot hydrolyze ATP (Murai, N., Makino, Y., and Yoshida, M. (1996) J. Biol. Chem. 271, 28229-28234). By reconstitution of GroEL complex from subunits of both wild-type GroEL and oxidized GroEL(AEX), hybrid GroEL complexes containing various numbers of oxidized GroEL(AEX) subunits were prepared. ATPase activity of the hybrid GroEL containing one or two oxidized GroEL(AEX) subunits per ring was about 70% higher than that of wild-type GroEL. Based on the detailed analysis of the ATPase activity, we concluded that inter-ring negative cooperativity was lost in the hybrid GroEL, indicating that synchronized opening of the subunits in one ring is necessary for the negative cooperativity. Indeed, hybrid GroEL complex reconstituted from subunits of wild-type and GroEL mutant (D398A), which is ATPase-deficient but can undergo domain opening motion, retained the negative cooperativity of ATPase. In contrast, the ability of GroEL to assist protein folding was impaired by the presence of a single oxidized GroEL(AEX) subunit in a ring. Taken together, cooperative conformational transitions in GroEL rings ensure the functional communication between the two rings of GroEL.     

Oxidation of a Cysteine Residue in Elongation Factor EF-Tu Reversibly Inhibits Translation in the Cyanobacterium Synechocystis sp. PCC 6803

Translational elongation is susceptible to inactivation by reactive oxygen species (ROS) in the cyanobacterium Synechocystis sp. PCC 6803, and elongation factor G has been identified as a target of oxidation by ROS. In the present study we examined the sensitivity to oxidation by ROS of another elongation factor, EF-Tu. The structure of EF-Tu changes dramatically depending on the bound nucleotide. Therefore, we investigated the sensitivity to oxidation in vitro of GTP- and GDP-bound EF-Tu as well as that of nucleotide-free EF-Tu. Assays of translational activity with a reconstituted translation system from Escherichia coli revealed that GTP-bound and nucleotide-free EF-Tu were sensitive to oxidation by H₂O₂, whereas GDP-bound EF-Tu was resistant to H₂O₂. The inactivation of EF-Tu was the result of oxidation of Cys-82, a single cysteine residue, and subsequent formation of both an intermolecular disulfide bond and sulfenic acid. Replacement of Cys-82 with serine rendered EF-Tu resistant to inactivation by H₂O₂, confirming that Cys-82 was a target of oxidation. Furthermore, oxidized EF-Tu was reduced and reactivated by thioredoxin. Gel-filtration chromatography revealed that some of the oxidized nucleotide-free EF-Tu formed large complexes of >30 molecules. Atomic force microscopy revealed that such large complexes dissociated into several smaller aggregates upon the addition of dithiothreitol. Immunological analysis of the redox state of EF-Tu in vivo showed that levels of oxidized EF-Tu increased under strong light. Thus, resembling elongation factor G, EF-Tu appears to be sensitive to ROS via oxidation of a cysteine residue, and its inactivation might be reversed in a redox-dependent manner.     

Studies of Interaction between Chloroplast Coupling Factor 1 and Nucleotides by Circular Dichroism and Ultra-Violet Spectroscopies

When ADP, CDP, GDP, IDP or UDP was mixed with chloroplast couplingfactor 1 (CF₁) in the presence of MgCl₂, changes were inducedin the ultraviolet absorption spectrum as well as the circulardichroism spectrum. These changes were about 70% complete inone minute. Also, these two changes were similar in the concentrationcurves of nucleotides, the competition between ADP with CDP,the inhibition by PP₁, and the requirement for divalent cations.A minor difference was also noted in the requirement for divalentcations by some of the nucleotides. The order of the affinitiesof these nucleotides for CF₁ was: ADP>CDP>UDP>IDP>GDP.The UV spectral changes induced by these nucleotides are interpretedas shifts of the absorption spectra of bound nucleotides bysome 10 nm to longer wavelengths accompanied by decrease inabsorbance. In difference CD spectra, negative peaks were foundat about the same wavelengths of the absorption peaks of therespective nucleotides. Ca²⁺ was as effective as Mg²⁺ to these changes induced by ADPor GDP, but less effective than Mg²⁺ for those induced by CDP,UDP or IDP. In the presence of EDTA, the changes induced byADP were somewhat lower and those induced by CDP, UDP or IDPbecame almost zero. However, the UV absorbance change inducedby GDP was larger in the presence of EDTA than in the presenceof Mg²⁺ or Ca²⁺. (Received October 27, 1980; Accepted February 27, 1981)