Residues in the Polar Loop of Subunit c in Escherichia coli ATP Synthase Function in Gating Proton Transport to the Cytoplasm

Rotary catalysis in F₁F₀ ATP synthase is powered by proton translocation through the membrane-embedded F₀ sector. Proton binding and release occur in the middle of the membrane at Asp-61 on the second transmembrane helix (TMH) of subunit c, which folds in a hairpin-like structure with two TMHs. Previously, the aqueous accessibility of Cys substitutions in the transmembrane regions of subunit c was probed by testing the inhibitory effects of Ag⁺ or Cd²⁺ on function, which revealed extensive aqueous access in the region around Asp-61 and on the half of TMH2 extending to the cytoplasm. In the current study, we surveyed the Ag⁺ and Cd²⁺ sensitivity of Cys substitutions in the loop of the helical hairpin and used a variety of assays to categorize the mechanisms by which Ag⁺ or Cd²⁺ chelation with the Cys thiolates caused inhibition. We identified two distinct metal-sensitive regions in the cytoplasmic loop where function was inhibited by different mechanisms. Metal binding to Cys substitutions in the N-terminal half of the loop resulted in an uncoupling of F₁ from F₀ with release of F₁ from the membrane. In contrast, substitutions in the C-terminal half of the loop retained membrane-bound F₁ after metal treatment. In several of these cases, inhibition was shown to be due to blockage of passive H⁺ translocation through F₀ as assayed with F₀ reconstituted into liposomes. The results suggest that the C-terminal domain of the cytoplasmic loop may function in gating H⁺ translocation to the cytoplasm.     

Manipulating the Length of the <Emphasis Type="Italic">b</Emphasis> Subunit F<Subscript>1</Subscript> Binding Domain in F<Subscript>1</Subscript>F<Subscript>0</Subscript> ATP Synthase from <Emphasis Type="Italic">Escherichia coli</Emphasis>

The peripheral stalk of F₁F₀ ATP synthase is composed of a parallel homodimer of b subunits that extends across the cytoplasmic membrane in F₀ to the top of the F₁ sector. The stalk serves as the stator necessary for holding F₁ against movement of the rotor. A series of insertions and deletions have been engineered into the hydrophilic domain that interacts with F₁. Only the hydrophobic segment from {val-121} to {ala-132} and the extreme carboxyl terminus proved to be highly sensitive to mutation. Deletions in either site apparently abolished enzyme function as a result of defects is assembly of the F₁F₀ complex. Other mutations manipulating the length of the sequence between these two areas had only limited effects on enzyme function. Expression of a b subunit with insertions with as few as two amino acids into the hydrophobic segment also resulted in loss of F₁F₀ ATP synthase. However, a fully defective b subunit with seven additional amino acids could be stabilized in a heterodimeric peripheral stalk within a functional F₁F₀ complex by a normal b subunit.     

pH-dependent Ca2+ binding to the F0 c-subunit affects proton translocation of the ATP synthase from Synechocystis 6803

It was shown before (Wooten, D. C., and Dilley, R. A. (1993) J. Bioenerg. Biomembr. 25, 557–567; Zakharov, S. D., Li, X., Red'ko, T. P., and Dilley, R. A. (1996) J. Bioenerg. Biomembr. 28, 483–493) that pH dependent reversible Ca²⁺ binding near the N- and C-terminal end of the 8 kDa subunit c modulates ATP synthesis driven by an applied pH jump in chloroplast and E. coli ATP synthase due to closing a proton gate proposed to exist in the F₀ H⁺ channel of the F₀F₁ ATP synthase. This mechanism has further been investigated with the use of membrane vesicles from mutants of the cyanobacterium Synechocystis 6803. Vesicles from a mutant with serine at position 37 in the hydrophilic loop of the c-subunit replaced by the charged glutamic acid (strain plc 37) has a higher H⁺/ATP ratio than the wild type and therefore shows ATP synthesis at low values of _H ⁺. The presence of 1 mM CaCl₂ during the preparation and storage of these vesicles blocked acid–base jump ATP formation when the pH of the acid side (inside) was between pH 5.6 and 7.1, even though the pH of the acid–base jump was thermodynamically in excess of the necessary energy to drive ATP formation at an external pH above 8.28. That is, in the absence of added CaCl₂, ATP formation did occur under those conditions. However, when the base stage pH was 7.16 and the acid stage below pH 5.2, ATP was formed when Ca²⁺ was present. This is consistent with Ca²⁺ being displaced by H⁺ ions from the F₀ on the inside of the thylakoid membrane at pH values below about 5.5. Vesicles from a mutant with the serine of position 3 replaced by a cysteine apparently already contain some bound Ca²⁺ to F₀. Addition of 1 mM EGTA during preparation and storage of those vesicles shifted the otherwise already low internal pH needed for onset of ATP synthesis to higher values when the external pH was above 8. With both strains it was shown that the Ca²⁺ binding effect on acid–base induced ATP synthesis occurs above an internal pH of about 5.5. These results were corroborated by ⁴⁵Ca²⁺- ligand blot assays on organic solvent soluble preparations containing the 8 kDa F₀ subunit c from the S-3-C mutant ATP synthase, which showed ⁴⁵Ca²⁺ binding as occurs with the pea chloroplast subunit III. The phosphorylation efficiency (P/2e), at strong light intensity, of Ca²⁺ and EGTA treated vesicles from both strains were almost equal showing that Ca²⁺ or EGTA have no other effect on the ATP synthase such as a change in the proton to ATP ratio. The results indicate that the Ca²⁺ binding to the F₀ H⁺ channel can block H⁺ flux through the channel at pH values above about 5.5, but below that pH protons apparently displace the bound Ca²⁺, opening the CF₀ H⁺ channel between the thylakoid lumen and H⁺ conductive channel.     

Mutagenesis Studies of the F1F0 ATP Synthase b Subunit Membrane Domain

A homodimer of b subunits constitutes the peripheral stalk linking the F₁ and F₀ sectors of the Escherichia coli ATP synthase. Each b subunit has a single-membrane domain. The constraints on the membrane domain have been studied by systematic mutagenesis. Replacement of a segment proximal to the cytoplasmic side of the membrane had minimal impact on F₁F₀ ATP synthase. However, multiple substitutions on the periplasmic side resulted in defects in assembly of the enzyme complex. These mutants had insufficient oxidative phosphorylation to support growth, and biochemical studies showed little F₁F₀ ATPase and no detectable ATP-driven proton pumping activity. Expression of the b _N2A,T6A,Q10A subunit was also oxidative phosphorylation deficient, but the b _N2A,T6A,Q10A protein was incorporated into an F₁F₀ complex. Single amino acid substitutions had minimal reductions in F₁F₀ ATP synthase function. The evidence suggests that the b subunit membrane domain has several sites of interaction contributing to assembly of F₀, and that these interactions are strongest on the periplasmic side of the bilayer.     

The Increase in the Number of Accessible SH-Groups in the Enterococcal Membrane Vesicles by ATP and Nicotinamide Adenine Dinucleotides

The number of accessible SH groups was determined in membrane vesicles prepared from Enterococcus hirae grown under anaerobic conditions at alkaline pH (pH 8.0). Addition of ATP or nicotinamide adenine dinucleotides (NAD⁺+NADH) to the vesicles caused a ∼4-fold or ∼1.9-fold increase in the number of SH-groups, respectively. This was inhibited by treatment with N-ethylmaleimide. The increase was significant when ATP and NAD⁺+NADH both were added. The change was lacking in the presence of the F₀F₁-ATPase inhibitors N,N′-diclohexylcarbodiimide or sodium azide. This was also absent in atp mutant with defect in the F₀F₁-ATPase and, in addition, it was less in potassium ion–free medium. These results are correlated with data about K⁺-dependent F₀F₁-ATPase activity, suggesting a relationship between the F₀F₁-ATPase and K⁺ uptake Trk-like system. The latter may be regulated by NAD or NADH mediating conformational changes.     

The carboxyl-terminal helical domain of the ATP synthase γ subunit is involved in ε subunit conformation and energy coupling

The γ subunit located at the center of ATP synthase (F_OF₁) plays critical roles in catalysis. Escherichia coli mutant with Pro substitution of the γ subunit residue γLeu218, which are located the rotor shaft near the c subunit ring, decreased NADH-driven ATP synthesis activity and ATP hydrolysis-dependent H⁺ transport of membranes to ~60% and ~40% of the wild type, respectively, without affecting F_OF₁ assembly. Consistently, the mutant was defective in growth by oxidative phosphorylation, indicating that energy coupling is impaired by the mutation. The ε subunit conformations in the γLeu218Pro mutant enzyme were investigated by cross-linking between cysteine residues introduced into both the ε subunit (εCys118 and εCys134, in the second helix and the hook segment, respectively) and the γ subunit (γCys99 and γCys260, located in the globular domain and the carboxyl-terminal helix, respectively). In the presence of ADP, the two γ260 and ε134 cysteine residues formed a disulfide bond in both the γLeu218Pro mutant and the wild type, indicating that the hook segment of ε subunit penetrates into the α₃β₃-ring along with the γ subunits in both enzymes. However, γ260/ε134 cross-linking in the γLeu218Pro mutant decreased significantly in the presence of ATP, whereas this effect was small in the wild type. These results suggested that the γ subunit carboxyl-terminal helix containing γLeu218 is involved in the conformation of the ε subunit hook region during ATP hydrolysis and, therefore, is required for energy coupling in F_OF₁.     

Relationship of K+-Uptaking System with H+-Translocating ATPase in Enterococcus hirae, Grown at a High or Low Alkaline pH

Potassium ion pool was studied in glycolyzing Enterococcus hirae, grown at high or low alkaline pH (pH 9.5 and 8.0, respectively). Energy-dependent increase of K⁺ pool was lower for the wild-type cells, grown at pH 9.5, than that for the cells grown at pH 8.0. It was inhibited by N,N′-dicyclohexylcarbodiimide (DCCD). The stoichiometry of DCCD-inhibited K⁺ influx to DCCD-inhibited H⁺ efflux for the wild-type cells, grown at pH 9.5 or 8.0, was fixed for different K⁺ external activity. DCCD-inhibited ATPase activity of membrane vesicles was significantly stimulated by K⁺ for the wild-type cells grown at pH 9.5, and required K⁺ for the wild-type cells grown at pH 8.0, while the levels of α and β subunits of the F₁ and b subunit of the F₀ were lower for the cells grown at pH 9.5 than that for the cells grown at pH 8.0. Such an ATPase activity was residual in membrane vesicles from the atpD mutant with a nonfunctional F₀F₁. ATPase activity of membrane vesicles from the mutant with defect in Na⁺-ATPase was higher for the cells grown at pH 9.5 than that for the cells grown at pH 8.0, and was inhibited by DCCD. An energy-dependent increase of K⁺ pool in this bacterium, grown at a high or low alkaline pH, is assumed to occur through a K⁺ uptaking system, most probably the Trk. The latter functions in a closed relationship with the H⁺-translocating ATPase F₀F₁. Received: 30 June 1997 / Accepted: 4 August 1997     

Osmomechanics of the Propionigenium modestum Fo Motor

In Propionigenium modestum, ATP is manufactured from ADP and phosphate by the enzyme ATP synthase using the free energy of an electrochemical gradient of Na⁺ ions. The P. modestum ATP synthase is a clear member of the family of F-type ATP synthases and the only major distinction is an extension of the coupling ion specificity to H⁺, Li⁺, or Na⁺, depending on the conditions. The use of Na⁺ as a coupling ion offers unique experimental options to decipher the ion-translocation mechanism and the osmotic and mechanical behavior of the enzyme. The single a subunit and the oligomer of c subunits are part of the stator and rotor, respectively, and operate together in the ion-translocation mechanism. During ATP synthesis, Na⁺ diffuses from the periplasm through the a subunit channel onto the Na⁺ binding site on a c subunit. From there it dissociates into the cytoplasm after the site has rotated out of the interface with subunit a. In the absence of a membrane potential, the rotor performs Brownian motions into either direction and Na⁺ ions are exchanged between the two compartments separated by the membrane. Upon applying voltage, however, the direction of Na⁺ flux and of rotation is biased by the potential. The motor generates torque to drive the rotation of the subunit, thereby releasing tightly bound ATP from catalytic sites in F₁. Hence, the membrane potential plays a pivotal role in the torque-generating mechanism. This is corroborated by the fact that for ATP synthesis, at physiological rates, the membrane potential is indispensable. We propose a catalytic mechanism for torque generation by the F_o motor that is in accord with all experimental data and is in quantitative agreement with the requirement for ATP synthesis.     

Subunit Organization of the Stator Part of the F 0 Complex from Escherichia coli ATP Synthase

Membrane-bound ATP synthases (F₁F₀) catalyze the synthesis of ATP via a rotary catalyticmechanism utilizing the energy of an electrochemical ion gradient. The transmembrane potentialis supposed to propel rotation of a subunit c ring of F₀ together with subunits and of F₁,hereby forming the rotor part of the enzyme, whereas the remainder of the F₁F₀ complexfunctions as a stator for compensation of the torque generated during rotation. This reviewfocuses on our recent work on the stator part of the F₀ complex, e.g., subunits a and b. Usingepitope insertion and antibody binding, subunit a was shown to comprise six transmembranehelixes with both the N- and C-terminus oriented toward the cytoplasm. By use of circulardichroism (CD) spectroscopy, the secondary structure of subunit b incorporated intoproteoliposomes was determined to be 80% -helical together with 14% turn conformation, providingflexibility to the second stalk. Reconstituted subunit b together with isolated ac subcomplexwas shown to be active in proton translocation and functional F₁ binding revealing the nativeconformation of the polypeptide chain. Chemical crosslinking in everted membrane vesiclesled to the formation of subunit b homodimers around residues bQ37 to bL65, whereas bA32Ccould be crosslinked to subunit a, indicating a close proximity of subunits a and b near themembrane. Further evidence for the proposed direct interaction between subunits a and b wasobtained by purification of a stable ab ₂ subcomplex via affinity chromatography using Histags fused to subunit a or b. This ab ₂ subcomplex was shown to be active in proton translocationand F₁ binding, when coreconstituted with subunit c. Consequences of crosslink formationand subunit interaction within the F₁F₀ complex are discussed.     

Energy transformation coupled to formate oxidation during anaerobic fermentation

A correlation between the rate of ATP synthesis by F₀F₁ ATP synthase and formate oxidation by formate hydrogen lyase (FHL) has been found in inside-out membrane vesicles of the Escherichia coli mutant JW 136 (Δhya/Δhyb) with double deletions of hydrogenases 1 and 2, grown anaerobically on glucose in the absence of external electron acceptors at pH 6.5. ATP synthesis was suppressed by the H⁺-ATPase inhibitors N,N′-dicyclohexylcarbodiimide, sodium azide, and the uncoupler carbonyl cyanide m-chlorophenylhydrazone. Copper ions inhibited formate-dependent hydrogenase and ATP-synthase activities but did not affect the ATPase activity of the vesicles. The maximal rate of ATP synthesis (0.83 μmol/min per mg protein) was determined at simultaneous application of sodium formate, ADP, and inorganic phosphate, and was stimulated by K⁺ ions. The results confirm the assumption of a dual role of hydrogenase 3, the formate hydrogen lyase subunit that can couple the reduction of protons to H₂ and their translocation through membrane with chemiosmotic synthesis of ATP.     

ATP Synthases With Novel Rotor Subunits: New Insights into Structure,Function and Evolution of ATPases

ATPases with unusual membrane-embedded rotor subunits were found in both F₁F₀ and A₁A₀ ATP synthases. The rotor subunit c of A₁A₀ ATPases is, in most cases, similar to subunit c from F₀. Surprisingly, multiplied c subunits with four, six, or even 26 transmembrane spans have been found in some archaea and these multiplication events were sometimes accompanied by loss of the ion-translocating group. Nevertheless, these enzymes are still active as ATP synthases. A duplicated c subunit with only one ion-translocating group was found along with “normal” F₀ c subunits in the Na⁺ F₁F₀ ATP synthase of the bacterium Acetobacterium woodii. These extraordinary features and exceptional structural and functional variability in the rotor of ATP synthases may have arisen as an adaptation to different cellular needs and the extreme physicochemical conditions in the early history of life.     

The <Emphasis Type="Italic">b</Emphasis><Subscript>arg36</Subscript> contributes to efficient coupling in F<Subscript>1</Subscript>F<Subscript>O</Subscript> ATP synthase in <Emphasis Type="Italic">Escherichia coli</Emphasis>

In Escherichia coli, the F₁F_O ATP synthase b subunits house a conserved arginine in the tether domain at position 36 where the subunit emerges from the membrane. Previous experiments showed that substitution of isoleucine or glutamate result in a loss of enzyme activity. Double mutants have been constructed in an attempt to achieve an intragenic suppressor of the b _arg36→ile and the b _arg36→glu mutations. The b _arg36→ile mutation could not be suppressed. In contrast, the phenotypic defect resulting from the b _arg36→glu mutation was largely suppressed in the b _{arg36→glu,glu39→arg} double mutant. E. coli expressing the b _{arg36→glu,glu39→arg} subunit grew well on succinate-based medium. F₁F_O ATP synthase complexes were more efficiently assembled and ATP driven proton pumping activity was improved. The evidence suggests that efficient coupling in F₁F_O ATP synthase is dependent upon a basic amino acid located at the base of the peripheral stalk.     

Electron transport chain and energy transduction in Paracoccus denitrificans under autotrophic growth conditions

Cells of Paracoccus denitrificans grown autotrophically with H₂ as energy source contained a branched respiratory chain. The presence of two terminal oxidases was indicated by two cyanide sensitive sites (K _i =10^-5 M and K _i =10^-3 M). While oxidation of NADH and succinate apparently proceeded via both electron pathways as shown by the inhibition of respiration with cyanide and Antimycin A, oxidation of H₂ involved only the terminal oxidase which was less sensitive to KCN. Oxidation of H₂ was not inhibited by rotenone, and sensitive to only relatively high concentrations of Antimycin A (50 nmol/mg).Under our growth conditions, autotrophic cells contained only very small amounts of cytochrome a +a ₃ . A cytochrome b was able to bind CO (with a peak at 418 nm and a trough at 434 nm in the reduced plus CO minus reduced difference spectrum). This cytochrome b had the spectral characteristics of cytochrome o and could be the alternate oxidase. The respiratory chain contained two b cytochromes (b ₅₅₆ and b ₅₆₂ at 77°K); under steady state conditions only b ₅₅₆ was significantly reduced by NADH and succinate while both b ₅₅₆ and b ₅₆₂ were reduced by H₂.Measurement of respiration-driven proton translocation by spheroplasts showed that the oxidation of H₂ by O₂ was associated with a vectorial ejection of H⁺ (in the outward direction) with aH⁺/O value of 6 to 7.A similar result was obtained with succinate. Oxidation of endogenous substrates gave H⁺/O values corresponding to a H⁺/site ratio of 3 with 3 sites functioning in absence of inhibitors, two sites in the presence of rotenone and one site in the presence of antimycin. The H⁺/O values indicated that two energy transducing sites were involved in the oxidation of H₂ by O₂.Measurement of ATP synthesis in membrane vesicles confirmed that phosphorylation was coupled to H₂ oxidation. However, such determinations which necessitated the use of inverted vesicles, gave P/O values too low to allow any conclusions to be made on the number of coupling sites.     

ATP synthases: bioinformatic based insights into how their electrochemically driven motor comprised of subunits a and c might serve as a drug target

ATP synthases, widely distributed in bacteria, eukaryotic mitochondria and chloroplasts, are highly conserved multi-subunit complexes. Although the conserved acidic residue in the transmembrane helix of the c subunit functions in H⁺ transport, the surrounding residues differ among species. Such divergence could lead to different regulatory modes since pH-dependent H⁺ transport has been demonstrated in E. coli with a c subunit carrying an additional acidic residue in the helix. There is further divergence in the number of c subunits that form the ring structure which is determined by the higher ordered structure. Recently, it was suggested that certain chemicals recognize the a and c subunits of pathogenic bacterial F₀. Since there may be structural divergence even in well-conserved ATP synthases, the c subunit-ring as well as the a subunit in F₀ could be targets for drugs for specific bacterial species.     

Structure and function of the yeast vacuolar membrane proton ATPase

Our current work on a vacuolar membrane proton ATPase in the yeastSaccharomyces cerevisiae has revealed that it is a third type of H⁺-translocating ATPase in the organism. A three-subunit ATPase, which has been purified to near homogeneity from vacuolar membrane vesicles, shares with the native, membrane-bound enzyme common enzymological properties of substrate specificities and inhibitor sensitivities and are clearly distinct from two established types of proton ATPase, the mitochondrial F₀F₁-type ATP synthase and the plasma membrane E₁E₂-type H⁺-ATPase. The vacuolar membrane H⁺-ATPase is composed of three major subunits, subunita (M _r =67 kDa),b (57kDa), andc (20 kDa). Subunita is the catalytic site and subunitc functions as a channel for proton translocation in the enzyme complex. The function of subunitb has not yet been identified. The functional molecular masses of the H⁺-ATPase under two kinetic conditions have been determined to be 0.9–1.1×10⁵ daltons for single-cycle hydrolysis of ATP and 4.1–5.3×10⁵ daltons for multicycle hydrolysis of ATP, respectively.N,N-Dicyclohexylcarbodiimide does not inhibit the former reaction but strongly inhibits the latter reaction. The kinetics of single-cycle hydrolysis of ATP indicates the formation of an enzyme-ATP complex and subsequent hydrolysis of the bound ATP to ADP and Pi at a 7-chloro-4-nitrobenzo-2-oxa-1,3-diazolesensitive catalytic site. Cloning of structural genes for the three subunits of the H⁺-ATPase (VMA1, VMA2, andVMA3) and their nucleotide sequence determination have been accomplished, which provide greater advantages for molecular biological studies on the structure-function relationship and biogenesis of the enzyme complex. Bioenergetic aspects of the vacuole as a main, acidic compartment ensuring ionic homeostasis in the cytosol have been described.Abbreviations CCCP carbonyl cyanidem-chlorophenyl hydrazone - DCCD N,N-dicyclohexylcarbondiimide - DES diethylstilbestrol - DIDS 4,4-diisothiocyano-2,2-stilbene disulfonic acid - NBD-Cl 7-chloro-4-nitrobenzo-2-oxa-1,3-diazole - Pi inorganic phosphate - SDS sodium dodecylsulfate - SF6847 3,5-di-tert-butyl-4-hydroxybenzylidenemalononitrile - SITS 4-acetamide-4-isothiocyanatostilbene-2,2-disulfonic acid - ZW3-14 N-tetradecyl-N,N-dimethyl-3-ammonio-1-propanesulfonate     

High-level expression of soluble subunit b of F1F0 ATP synthase in Escherichia coli cell-free system

The overexpression of subunit b of F₁F₀ adenosine triphosphate (ATP) synthase from Escherichia coli is so toxic that it even prevents the transformation of plasmids encoding this protein into E. coli BL21 (DE3). In the present work, E. coli cell-free system was chosen as an alternative to express this highly toxic membrane protein. This protein was either produced as precipitates followed by detergent resolubilization or expressed as a soluble form with detergent addition. Among several types of tested detergents, Brij 58 could effectively solubilize approximately 85% of the target membrane protein within a wide range of concentration (48 to 178 times critical micelle concentration [CMC]) with little effect on the expression level. With the presence of Brij 58 at the final concentration of 96 times CMC in the E. coli cell-free system, 789 μg/mL of soluble subunit b was achieved after 4 h biosynthesis, which is the highest level for the expression of membrane proteins in a batch-mode cell-free expression system. The present work provides a rapid and efficient procedure of expressing one membrane protein with high cytotoxicity in the cell-free system and will be helpful to further exploration of reconstituting F₁F₀ ATP synthase into liposome or polymer vesicle to design a nanoelectromechanical system device.     

The Oligomeric Subunit c Rotor in the Fo Sector of ATP Synthase: Unresolved Questions in Our Understanding of Function

We have proposed a model for the oligomeric c-rotor of the F_o sector of ATP synthase and its interaction with subunit a during H⁺-transport driven rotation. The model is based upon the solution structure of monomeric subunit c, determined by NMR, and an extensive series of cross-linking distance constraints between c subunits and between subunits c and a. To explain the complete set of cross-linking data, we have suggested that the second transmembrane helix rotates during its interaction with subunit a in the course of the H⁺-translocation cycle. The H⁺-transport coupled rotation of this helix is proposed to drive the stepwise movement of the c-oligomeric rotor. The model is testable and provides a useful framework for addressing questions raised by other experiments.     

H+ transport and coupling by the F0 sector of the ATP synthase: Insights into the molecular mechanism of function

The F₀ sector of the ATP synthase complex facilitates proton translocation through the membrane, and via interaction with the F₁ sector, couples proton transport to ATP synthesis. The molecular mechanism of function is being probed by a combination of mutant analysis and structural biochemistry, and recent progress on theEscherichia coli F₀ sector is reviewed here. TheE. coli F₀ is composed of three types of subunits (a, b, andc) and current information on their folding and organization in F₀ is reviewed. The structure of purified subunitc in chloroform-methanol-H₂O resembles that in native F₀, and progress in determining the structure by NMR methods is reviewed. Genetic experiments suggest that the two helices of subunitc must interact as a functional unit around an essential carboxyl group as protons are transported. In addition, a unique class of suppressor mutations identify a transmembrane helix of subunita that is proposed to interact with the bihelical unit of subunitc during proton transport. The role of multiple units of subunitc in coupling proton translocation to ATP synthesis is considered. The special roles of Asp61 of subunitc and Arg210 of subunita in proton translocation are also discussed.     

Inheritance of body color in the brown planthopper, Nilaparvata lugens

The segregation frequencies of color phenotypes of F₁, F₂, and backcross progenies revealed that the body coloration of the brown planthopper, Nilaparavata lugens(Stål), exhibited multiple allelism. Monogene for color morphism exists in three allelic forms >-b ⁺ (brown or wild type), b ^o (orange) and b ^b (black). The dominance relationship was b ^b>b ⁺>b ^o. The relationship between phenotype and genotype in N. lugens was not fixed. The six possible genotypes produced eight phenotypes.

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Résumé Les fréquences de ségrégation des différentes colorations de F₁, F₂ et des croisements en retour ont montré que la coloration du corps de Nilaparvata lugens est due à un multi-allèlisme. Le monogène pour la couleur existe sous trois formes allèliques: b⁺ (brun ou sauvage), b^o (orange) et b^b (noir). Les relations de dominance étaient: b^b>b⁺>b^o. On n'a pas établi les relatios entre phénotypes et génotypes chez N. lugens. Les 6 génotypes possibles produisent 8 phénotypes.