Chemical Heterogeneity in Inbred European Population of the Invasive Hornet Vespa velutina nigrithorax.

Invasive social insect populations that have been introduced to a new environment through a limited number of introduction events generally exhibit reduced variability in their chemical signatures (cuticular hydrocarbons) compared to native populations of the same species. The reduced variability in these major recognition cues could be caused by a reduction of genetic diversity due to a genetic bottleneck. This hypothesis was tested in an inbred European population of the invasive hornet Vespa velutina nigrithorax. Our results show that, in spite of the limited amount of genetic diversity present in the European population, the chemical signatures of individuals were highly heterogeneous according to their caste, sex, and colony origin. In queens, some specific saturated and unsaturated hydrocarbons were identified. These results suggest that epigenetic and/or environmental factors could play a role in modifying cuticular hydrocarbon profiles in this introduced hornet population despite the observed reduction of genetic diversity.

Endocrine control of cuticular hydrocarbon profiles during worker-to-soldier differentiation in the termite Reticulitermes flavipes.

The social organization of termites, unlike that of other social insects, is characterized by a highly plastic caste system. With the exception of the alates, all other individuals in a colony remain at an immature stage of development. Workers in particular remain developmentally flexible; they can switch castes to become soldiers or neotenics. Juvenile hormone (JH) is known to play a key role in turning workers into soldiers. In this study, we analyzed differences in cuticular hydrocarbon (CHC) profiles among castes, paying particular attention to the transition of workers to soldiers, in the subterranean termite species Reticulitermes flavipes. CHCs have a fundamental function in social insects as they serve as cues in inter- and intraspecific recognition. We showed that (1) the CHC profiles of the different castes (workers, soldiers, nymphs and neotenics) are different and (2) when workers were experimentally exposed to a JH analog and thus induced to become soldiers, their CHC profiles were modified before and after the worker-presoldier molt and before and after the presoldier-soldier molt.

Controlling the functionality of cytochrome c(1) redox potentials in the Rhodobacter capsulatus bc(1) complex through disulfide anchoring of a loop and a beta-branched amino acid near the heme-ligating methionine.

The cytochrome c(1) subunit of the ubihydroquinone:cytochrome c oxidoreductase (bc(1) complex) contains a single heme group covalently attached to the polypeptide via thioether bonds of two conserved cysteine residues. In the photosynthetic bacterium Rhodobacter (Rba.) capsulatus, cytochrome c(1) contains two additional cysteines, C144 and C167. Site-directed mutagenesis reveals a disulfide bond (rare in monoheme c-type cytochromes) anchoring C144 to C167, which is in the middle of an 18 amino acid loop that is present in some bacterial cytochromes c(1) but absent in higher organisms. Both single and double Cys to Ala substitutions drastically lower the +320 mV redox potential of the native form to below 0 mV, yielding nonfunctional cytochrome bc(1). In sharp contrast to the native protein, mutant cytochrome c(1) binds carbon monoxide (CO) in the reduced form, indicating an opening of the heme environment that is correlated with the drop in potential. In revertants, loss of the disulfide bond is remediated uniquely by insertion of a beta-branched amino acid two residues away from the heme-ligating methionine 183, identifying the pattern betaXM, naturally common in many other high-potential cytochromes c. Despite the unrepaired disulfide bond, the betaXM revertants are no longer vulnerable to CO binding and restore function by raising the redox potential to +227 mV, which is remarkably close to the value of the betaXM containing but loop-free mitochondrial cytochrome c(1). The disulfide anchored loop and betaXM motifs appear to be two independent but nonadditive strategies to control the integrity of the heme-binding pocket and raise cytochrome c midpoint potentials.

Large scale domain movement in cytochrome bc(1): a new device for electron transfer in proteins.

Recently, crystallographic, spectroscopic, kinetic and biochemical genetic data have merged to unveil a large domain movement for the Fe-S subunit in cytochrome bc(1). In this evolutionarily conserved enzyme, the domain motion acts to conduct intra-complex electron transfer and is essential for redox energy conversion.

Probing the role of the Fe-S subunit hinge region during Q(o) site catalysis in Rhodobacter capsulatus bc(1) complex.

The ubihydroquinone:cytochrome c oxidoreductase, or bc(1) complex, functions according to a mechanism known as the modified Q cycle. Recent crystallographic data have revealed that the extrinsic domain containing the [2Fe2S] cluster of the Fe-S subunit of this enzyme occupies different positions in various crystal forms, suggesting that this subunit may move during ubihydroquinone oxidation. As in these structures the hydrophobic membrane anchor of the Fe-S subunit remains at the same position, the movement of the [2Fe2S] cluster domain would require conformational changes of the hinge region linking its membrane anchor to its extrinsic domain. To probe the role of the hinge region, Rhodobacter capsulatus bc(1) complex was used as a model, and various mutations altering the hinge region amino acid sequence, length, and flexibility were obtained. The effects of these modifications on the bc(1) complex function and assembly were investigated in detail. These studies demonstrated that the nature of the amino acid residues located in the hinge region (positions 43-49) of R. capsulatus Fe-S subunit was not essential per se for the function of the bc(1) complex. Mutants with a shorter hinge (up to five amino acid residues deletion) yielded functional bc(1) complexes, but contained substoichiometric amounts of the Fe-S subunit. Moreover, mutants with increased rigidity or flexibility of the hinge region altered both the function and the assembly or the steady-state stability of the bc(1) complex. In particular, the extrinsic domain of the Fe-S subunit of a mutant containing six proline residues in the hinge region was shown to be locked in a position similar to that seen in the presence of stigmatellin. Interestingly, the latter mutant readily overcomes this functional defect by accumulating an additional mutation which shortens the length of the hinge. These findings indicate that the hinge region of the Fe-S subunit of bacterial bc(1) complexes has a remarkable structural plasticity.

Proteolytic cleavage of the Fe-S subunit hinge region of Rhodobacter capsulatus bc(1) complex: effects of inhibitors and mutations.

The three-dimensional structure of the mitochondrial bc(1) complex reveals that the extrinsic domain of the Fe-S subunit, which carries the redox-active [2Fe2S] cluster, is attached to its transmembrane anchor domain by a short flexible hinge sequence (amino acids D43 to S49 in Rhodobacter capsulatus). In various structures, this extrinsic domain is located in different positions, and the conformation of the hinge region is different. In addition, proteolysis of this region has been observed previously in a bc(1) complex mutant of R. capsulatus [Saribas, A. S., Valkova-Valchanova, M. B., Tokito, M., Zhang, Z., Berry E. A., and Daldal, F. (1998) Biochemistry 37, 8105-8114]. Thus, possible correlations between proteolysis, conformation of the hinge region, and position of the extrinsic domain of the Fe-S subunit within the bc(1) complex were sought. In this work, we show that thermolysin, or an endogenous activity present in R. capsulatus, cleaves the hinge region of the Fe-S subunit between its amino acid residues A46-M47 or D43-V44, respectively, to yield a protease resistant fragment with a M(r) of approximately 18 kDa. The cleavage was affected significantly by ubihydroquinone oxidation (Q(o)) and ubiquinone reduction (Q(i)) site inhibitors and by specific mutations located in the bc(1) complex. In particular, using either purified or detergent dispersed chromatophore-embedded R. capsulatus bc(1) complex, we demonstrated that while stigmatellin blocked the cleavage, myxothiazol hardly affected it, and antimycin A greatly enhanced it. Moreover, mutations in various regions of the Fe-S subunit and cyt b subunit changed drastically proteolysis patterns, indicating that the structure of the hinge region of the Fe-S subunit was modified in these mutants. The overall findings establish that protease accessibility of the Fe-S subunit of the bc(1) complex is a useful biochemical assay for probing the conformation of its hinge region and for monitoring indirectly the position of its extrinsic [2Fe2S] cluster domain within the Q(o) pocket.

Uncovering the [2Fe2S] domain movement in cytochrome bc1 and its implications for energy conversion.

In crystals of the key respiratory and photosynthetic electron transfer protein called ubihydroquinone:cytochrome (cyt) c oxidoreductase or cyt bc(1), the extrinsic [2Fe2S] cluster domain of its Fe-S subunit assumes several conformations, suggesting that it may move during catalysis. Herein, using Rhodobacter capsulatus mutants that have modifications in the hinge region of this subunit, we were able to reveal this motion kinetically. Thus, the bc(1) complex (and possibly the homologous b(6)f complex in chloroplasts) employs the [2Fe2S] cluster domain as a device to shuttle electrons from ubihydroquinone to cyt c(1) (or cyt f). We demonstrate that this domain movement is essential for cyt bc(1) function, because a mutant enzyme with a nonmoving Fe-S subunit has no catalytic activity, and one with a slower movement has lower activity. This motion is apparently designed with a natural frequency slow enough to assure productive Q(o) site charge separation but fast enough not to be rate limiting. These findings add the unprecedented function of intracomplex electron shuttling to large-scale domain motions in proteins and may well provide a target for cyt bc(1) antibiotics.

Structure and function of the bacterial bc1 complex: domain movement, subunit interactions, and emerging rationale engineering attempts.

The ubiquinol: cytochrome c oxidoreductase, or the bc1 complex, is a key component of both respiratory and photosynthetic electron transfer and contributes to the formation of an electrochemical gradient necessary for ATP synthesis. Numerous bacteria harbor a bc1 complex comprised of three redox-active subunits, which bear two b-type hemes, one c-type heme, and one [2Fe-2S] cluster as prosthetic groups. Photosynthetic bacteria like Rhodobacter species provide powerful models for studying the function and structure of this enzyme and are being widely used. In recent years, extensive use of spontaneous and site-directed mutants and their revertants, new inhibitors, discovery of natural variants of this enzyme in various species, and engineering of novel bc1 complexes in species amenable to genetic manipulations have provided us with a wealth of information on the mechanism of function, nature of subunit interactions, and assembly of this important enzyme. The recent resolution of the structure of various mitochondrial bc1 complexes in different crystallographic forms has consolidated previous findings, added atomic-scale precision to our knowledge, and raised new issues, such as the possible movement of the Rieske Fe-S protein subunit during Qo site catalysis. Here, studies performed during the last few years using bacterial bc1 complexes are reviewed briefly and ongoing investigations and future challenges of this exciting field are mentioned.

Resistance mutations reveal the atovaquone-binding domain of cytochrome b in malaria parasites.

Atovaquone represents a class of antimicrobial agents with a broad-spectrum activity against various parasitic infections, including malaria, toxoplasmosis and Pneumocystis pneumonia. In malaria parasites, atovaquone inhibits mitochondrial electron transport at the level of the cytochrome bc1 complex and collapses mitochondrial membrane potential. In addition, this drug is unique in being selectively toxic to parasite mitochondria without affecting the host mitochondrial functions. A better understanding of the structural basis for the selective toxicity of atovaquone could help in designing drugs against infections caused by mitochondria-containing parasites. To that end, we derived nine independent atovaquone-resistant malaria parasite lines by suboptimal treatment of mice infected with Plasmodium yoelii; these mutants exhibited resistance to atovaquone-mediated collapse of mitochondrial membrane potential as well as inhibition of electron transport. The mutants were also resistant to the synergistic effects of atovaquone/ proguanil combination. Sequencing of the mitochondrially encoded cytochrome b gene placed these mutants into four categories, three with single amino acid changes and one with two adjacent amino acid changes. Of the 12 nucleotide changes seen in the nine independently derived mutants 11 replaced A:T basepairs with G:C basepairs, possibly because of reactive oxygen species resulting from atovaquone treatment. Visualization of the resistance-conferring amino acid positions on the recently solved crystal structure of the vertebrate cytochrome bc1 complex revealed a discrete cavity in which subtle variations in hydrophobicity and volume of the amino acid side-chains may determine atovaquone-binding affinity, and thereby selective toxicity. These structural insights may prove useful in designing agents that selectively affect cytochrome bc1 functions in a wide range of eukaryotic pathogens.

Substitution of the sixth axial ligand of Rhodobacter capsulatus cytochrome c1 heme yields novel cytochrome c1 variants with unusual properties.

The cytochrome (cyt) c1 heme of the ubihydroquinone:cytochrome c oxidoreductase (bc1 complex) is covalently attached to two cysteine residues of the cyt c1 polypeptide chain via two thioether bonds, and the fifth and sixth axial ligands of its iron atom are histidine (H) and methionine (M), respectively. The latter residue is M183 in Rhodobacter capsulatus cyt c1, and previous mutagenesis studies revealed its critical role for the physicochemical properties of cyt c1 [Gray, K. A., Davidson, E., and Daldal, F. (1992) Biochemistry 31, 11864-11873]. In the homologous chloroplast b6f complex, the sixth axial ligand is provided by the amino group of the amino terminal tyrosine residue. To further pursue our investigation on the role played by the sixth axial ligand in heme-protein interactions, novel cyt c1 variants with histidine-lysine (K) and histidine-histidine axial coordination were sought. Using a R. capsulatus genetic system, the cyt c1 mutants M183K and M183H were constructed by site-directed mutagenesis, and chromatophore membranes as well as purified bc1 complexes obtained from these mutants were characterized in detail. The studies revealed that these mutants incorporated the heme group into the mature cyt c1 polypeptides, but yielded nonfunctional bc1 complexes with unusual spectroscopic and thermodynamic properties, including shifted optical absorption maxima (lambdamax) and decreased redox midpoint potential values (Em7). The availability and future detailed studies of these stable cyt c1 mutants should contribute to our understanding of how different factors influence the physicochemical and folding properties of membrane-bound c-type cytochromes in general.

The nuoM arg368his mutation in NADH:ubiquinone oxidoreductase from Rhodobacter capsulatus: a model for the human nd4-11778 mtDNA mutation associated with Leber's hereditary optic neuropathy.

Mutation at position 11778 in the nd4 gene of the human mitochondrial complex I is associated with Leber's hereditary optic neuropathy. Type I NADH:ubiquinone oxidoreductase of Rhodobacter capsulatus displays similar properties to complex I of the mitochondrial respiratory chain. The NUOM subunit of the bacterial enzyme is homologous to the ND4 subunit. Disruption of the nuoM gene led to a bacterial mutant exhibiting a defect in complex I activity and assembly. A nuoM-1103 point mutant reproducing the nd4-11778 mutation has been introduced in the R. capsulatus genome. This mutant showed a reduced ability to grow in a medium containing malate instead of lactate which indicated a clear impairment in oxidative phosphorylation capacity. NADH supported respiration of porous bacterial cells was significantly decreased in the nuoM-1103 mutant while no significant reduction could be observed in isolated bacterial membranes. As it has been observed in the case of the nd4-11778 mitochondrial mutation, proton-pump activity of the bacterial enzyme was not affected by the nuoM-1103 mutation. All these data which reproduce most of the biochemical features observed in patient mitochondria harboring the nd4-11778 mutation show that the R. capsulatus complex I might be used as a useful model to investigate mutations of the mitochondrial DNA which are associated with complex I deficiencies in human pathologies.

The 49-kDa subunit of NADH-ubiquinone oxidoreductase (Complex I) is involved in the binding of piericidin and rotenone, two quinone-related inhibitors.

Piericidin is a potent inhibitor of the mitochondrial and bacterial type I NADH-ubiquinone oxidoreductases (Complex I) and is considered to bind at or close to the ubiquinone binding site(s) of the enzyme. Piericidin-resistant mutants of the bacterium Rhodobacter capsulatus have been isolated and the present work demonstrates that a single missense mutation at the level of the gene encoding the peripheral 49-kDa/NUOD subunit of Complex I is definitely associated with this resistance. Based on this original observation, we propose a model locating the binding site for piericidin (and quinone) at the interface between the hydrophilic and hydrophobic domains of Complex I.

The complex I from Rhodobacter capsulatus.

The NADH-ubiquinone oxidoreductase (type I NDH) of Rhodobacter capsulatus is a multisubunit enzyme encoded by the 14 genes of the nuo operon. This bacterial enzyme constitutes a valuable model for the characterization of the mitochondrial Complex I structure and enzymatic mechanism for the following reasons. (i) The mitochondria-encoded ND subunits are not readily accessible to genetic manipulation. In contrast, the equivalents of the mitochondrial ND1, ND2, ND4, ND4L, ND5 and ND6 genes can be easily mutated in R. capsulatus by homologous recombination. (ii) As illustrated in the case of ND1 gene, point mutations associated with human cytopathies can be reproduced and studied in this model system. (iii) The R. capsulatus model also allows the recombinant manipulations of iron-sulfur (Fe-S) subunits and the assignment of Fe-S clusters as illustrated in the case of the NUOI subunit (the equivalent of the mitochondrial TYKY subunit). (iv) Finally, like mitochondrial Complex I, the NADH-ubiquinone oxidoreductase of R. capsulatus is highly sensitive to the inhibitor piericidin-A which is considered to bind to or close to the quinone binding site(s) of Complex I. Therefore, isolation of R. capsulatus mutants resistant to piericidin-A represents a straightforward way to map the inhibitor binding sites and to try and define the location of quinone binding site(s) in the enzyme. These illustrations that describe the interest in the R. capsulatus NADH-ubiquinone oxidoreductase model for the general study of Complex I will be critically developed in the present review.

Distal genes of the nuo operon of Rhodobacter capsulatus equivalent to the mitochondrial ND subunits are all essential for the biogenesis of the respiratory NADH-ubiquinone oxidoreductase.

Seven out of the 13 proteins encoded by the mitochondrial genome of mammals (peptides ND1 to ND6 plus ND4L) are subunits of the respiratory NADH-ubiquinone oxidoreductase (complex I). The function of these ND subunits is still poorly understood. We have used the NADH-ubiquinone oxidoreductase of Rhodobacter capsulatus as a model for the study of the function of these proteins. In this bacterium, the 14 genes encoding the NADH-ubiquinone oxidoreductase are clustered in the nuo operon. We report here on the biochemical and spectroscopic characterization of mutants individually disrupted in five nuo genes, equivalent to mitochondrial genes nd1, nd2, nd5, nd6 and nd4L. Disruption of any of these genes in R. capsulatus leads to the suppression of NADH dehydrogenase activity at the level of the bacterial membranes and to the disappearance of complex I-associated iron-sulphur clusters. Individual NUO subunits can still be immunodetected in the membranes of these mutants, but they do not form a functional subcomplex. In contrast to these observations, disruption of two ORFs (orf6 and orf7), also present in the distal part of the nuo operon, does not suppress NADH dehydrogenase activity or complex I-associated EPR signals, thus demonstrating that these ORFs are not essential for the biosynthesis of complex I.

The Release of Isoprenoids by Locust Corpora Allata in vitro.

Corpora allata of the African locust Locusta migratoria, incubated in vitro, biosynthesized together with juvenile hormone III (JH-III), several molecules labelled by both [2-(14)C] sodium acetate and L-[methyl-(3)H] methionine. By a combination of chromatographic procedures including reverse phase-high-performance liquid chromatography (HPLC), normal phase HPLC and thin layer chromatography (TLC), four labelled compounds were separated. They were isoprenoids, as revealed by inhibition of their synthesis by the hydroxy-methylglutaryl-coenzyme A (HMG-CoA) reductase inhibitor fluvastatin and restoration by exogenous mevalonolactone. They could be produced by incubating corpora allata with JH-III, suggesting that they were JH-III metabolites. They were produced by the corpora allata from both males and females and released into the incubation medium. Their rate of synthesis changed considerably depending on the sample, and in some cases they were the major isoprenoic products of the corpora allata.

Hydroxy juvenile hormones: new putative juvenile hormones biosynthesized by locust corpora allata in vitro.

The in vitro production of sesquiterpenoids was investigated by using corpora allata (CA) of the African locust Locusta migratoria migratorioides. Labeled products from unstimulated biosynthesis were extracted, purified by normal phase HPLC, and derivatized to determine the functional groups present. An extra hydroxyl group was detected in each of two juvenile hormone (JH) biosynthetic products. One compound, NP-8, was found to co-migrate with a chemically-synthesized (Z)-hydroxymethyl isomer, 12'-OH JH-III, but not with the (E)-hydroxymethyl isomer, 12-OH JH III. Mass spectral analyses further supported the identity of the synthetic material with that biosynthesized by the corpora allata. A second compound was identified as the 8'-OH JH-III based on spectroscopic analyses. 12'-OH JH-III exhibited morphogenetic activity when tested on the heterospecific Tenebrio test. These data suggest that 12'-OH JH-III and 8'-OH JH-III are additional biosynthetically-produced and biologically-active juvenile hormones, and constitute the first known members of the class of hydroxy juvenile hormones (HJHs).

Genetic evidence for the existence of two quinone related inhibitor binding sites in NADH-CoQ reductase.

Using the NADH-CoQ reductase of Rhodobacter capsulatus as a model for the mitochondrial Complex I, we have for the first time isolated bacterial mutants resistant to piericidin-A, a classical inhibitor of the mitochondrial enzyme. Their sensitivity to other inhibitors directed towards the quinone binding domain of complex I gives direct genetic evidence for the existence of two inhibitor binding sites.

Identification of five Rhodobacter capsulatus genes encoding the equivalent of ND subunits of the mitochondrial NADH-ubiquinone oxidoreductase.

We previously reported the sequencing of two genes (ndhA and ndhI) encoding two of the subunits of the type-I NADH-ubiquinone oxidoreductase from Rhodobacter capsulatus (Rc). The present paper deals with the cloning and characterization of a chromosomal fragment clustering five new Rc genes which encode subunits of this enzyme. This gene cluster is located immediately downstream from ndhA and ndhI, and also contains two unidentified open reading frames (urf2, urf3). The five genes, nuoJ, nuoK, nuoL, nuoM and nuoN, encode proteins related, respectively, to mitochondrial (mt) subunits ND6, ND4L, ND5, ND4 and ND2. The overall organization of the nuo genes identified in Rc shows similarity to that of the Paracoccus denitrificans (Pd) nqo gene cluster.