Publications

• A tightly bound quinone functions in the ubiquinone reaction sites of quinoprotein alcohol dehydrogenase of an acetic acid bacterium, Gluconobacter suboxydans.

  Matsushita K., Kobayashi Y., Mizuguchi M., Toyama H., Adachi O., Sakamoto K., Miyoshi H.

  Quinoprotein alcohol dehydrogenase (ADH) of acetic acid bacteria is a membrane-bound enzyme that functions as the primary dehydrogenase in the ethanol oxidase respiratory chain. It consists of three subunits and has a pyrroloquinoline quinone (PQQ) in the active site and four heme c moieties as el ... >> More

  Quinoprotein alcohol dehydrogenase (ADH) of acetic acid bacteria is a membrane-bound enzyme that functions as the primary dehydrogenase in the ethanol oxidase respiratory chain. It consists of three subunits and has a pyrroloquinoline quinone (PQQ) in the active site and four heme c moieties as electron transfer mediators. Of these, three heme c sites and a further site have been found to be involved in ubiquinone (Q) reduction and ubiquinol (QH2) oxidation respectively (Matsushita et al., Biochim. Biophys. Acta, 1409, 154-164 (1999)). In this study, it was found that ADH solubilized and purified with dodecyl maltoside, but not with Triton X-100, had a tightly bound Q, and thus two different ADHs, one having the tightly bound Q (Q-bound ADH) and Q-free ADH, could be obtained. The Q-binding sites of both the ADHs were characterized using specific inhibitors, a substituted phenol PC16 (a Q analog inhibitor) and antimycin A. Based on the inhibition kinetics of Q2 reductase and ubiquinol-2 (Q2H2) oxidase activities, it was suggested that there are one and two PC16-binding sites in Q-bound ADH and Q-free ADH respectively. On the other hand, with antimycin A, only one binding site was found for Q2 reductase and Q2H2 oxidase activities, irrespective of the presence of bound Q. These results suggest that ADH has a high-affinity Q binding site (QH) besides low-affinity Q reduction and QH2 oxidation sites, and that the bound Q in the QH site is involved in the electron transfer between heme c moieties and bulk Q or QH2 in the low-affinity sites. << Less

  Biosci. Biotechnol. Biochem. 72:2723-2731(2008) [PubMed] [EuropePMC]

• [Goat smallpox in Chad: study of the pathogeny of the virus in sheep and goats].

  Bidjeh K., Ganda K., Diguimbaye C.

  A local strain of goat pox virus was tested in goats and sheep. The results showed that 65% of goats and 20% of sheep reacted positively. Only goats died few days after the inoculation (55%) and no mortality was recorded in the sheep. The strict species specificity of this strain was not observed. ... >> More

  A local strain of goat pox virus was tested in goats and sheep. The results showed that 65% of goats and 20% of sheep reacted positively. Only goats died few days after the inoculation (55%) and no mortality was recorded in the sheep. The strict species specificity of this strain was not observed. The difference of sensitivity between sheep and goats was statistically significant. << Less

  Rev Elev Med Vet Pays Trop 44:33-36(1991) [PubMed] [EuropePMC]

• The PQQ-alcohol dehydrogenase of Gluconacetobacter diazotrophicus.

  Gomez-Manzo S., Contreras-Zentella M., Gonzalez-Valdez A., Sosa-Torres M., Arreguin-Espinoza R., Escamilla-Marvan E.

  The oxidation of ethanol to acetic acid is the most characteristic process in acetic acid bacteria. Gluconacetobacter diazotrophicus is rather unique among the acetic acid bacteria as it carries out nitrogen fixation and is a true endophyte, originally isolated from sugar cane. Aside its peculiar ... >> More

  The oxidation of ethanol to acetic acid is the most characteristic process in acetic acid bacteria. Gluconacetobacter diazotrophicus is rather unique among the acetic acid bacteria as it carries out nitrogen fixation and is a true endophyte, originally isolated from sugar cane. Aside its peculiar life style, Ga. diazotrophicus, possesses a constitutive membrane-bound oxidase system for ethanol. The Alcohol dehydrogenase complex (ADH) of Ga. diazotrophicus was purified to homogeneity from the membrane fraction. It-exhibited two subunits with molecular masses of 71.4 kDa and 43.5 kDa. A positive peroxidase reaction confirmed the presence of cytochrome c in both subunits. Pyrroloquinoline quinone (PQQ) of ADH was identified by UV-visible light and fluorescence spectroscopy. The enzyme was purified in its full reduced state; potassium ferricyanide induced its oxidation. Ethanol or acetaldehyde restored the full reduced state. The enzyme showed an isoelectric point (pI) of 6.1 and its optimal pH was 6.0. Both ethanol and acetaldehyde were oxidized at almost the same rate, thus suggesting that the ADH complex of Ga. diazotrophicus could be kinetically competent to catalyze, at least in vitro, the double oxidation of ethanol to acetic acid. << Less

  Int J Food Microbiol 125:71-78(2008) [PubMed] [EuropePMC]

• Function of multiple heme c moieties in intramolecular electron transport and ubiquinone reduction in the quinohemoprotein alcohol dehydrogenase-cytochrome c complex of Gluconobacter suboxydans.

  Matsushita K., Yakushi T., Toyama H., Shinagawa E., Adachi O.

  Alcohol dehydrogenase (ADH) of acetic acid bacteria functions as the primary dehydrogenase of the ethanol oxidase respiratory chain, where it donates electrons to ubiquinone. ADH is a membrane-bound quinohemoprotein-cytochrome c complex which consists of subunits I (78 kDa), II (48 kDa), and III ( ... >> More

  Alcohol dehydrogenase (ADH) of acetic acid bacteria functions as the primary dehydrogenase of the ethanol oxidase respiratory chain, where it donates electrons to ubiquinone. ADH is a membrane-bound quinohemoprotein-cytochrome c complex which consists of subunits I (78 kDa), II (48 kDa), and III (14 kDa) and contains several hemes c as well as pyrroloquinoline quinone as prosthetic groups. To understand the role of the heme c moieties in the intramolecular electron transport and the ubiquinone reduction, the ADH complex of Gluconobacter suboxydans was separated into a subunit I/III complex and subunit II, then reconstituted into the complex. The subunit I/III complex, probably subunit I, contained 1 mol each of pyrroloquinoline quinone and heme c and exhibited significant ferricyanide reductase, but no Q1 reductase activities. Subunit II was a triheme cytochrome c and had no enzyme activity, but it enabled the subunit I/III complex to reproduce the Q1 and ferricyanide reductase activities. Hybrid ADH consisting of the subunit I/III complex of G. suboxydans ADH and subunit II of Acetobacter aceti ADH was constructed and it had showed a significant Q1 reductase activity, indicating that subunit II has a ubiquinone-binding site. Inactive ADH from G. suboxydans exhibiting only 10% of the Q1 and ferricyanide reductase activities of the active enzyme has been isolated separately from active ADH (Matsushita, K., Yakushi, T., Takaki, Y., Toyama, H., and Adachi, O (1995) J. Bacteriol. 177, 6552-6559). Using these active and inactive ADHs and also isolated subunit I/III complex, we performed kinetic studies which suggested that ADH contains four ferricyanide-reacting sites, one of which was detected in subunit I and the others in subunit II. One of the three ferricyanide-reacting sites in subunit II was defective in inactive ADH. The ferricyanide-reacting site remained inactive even after alkali treatment of inactive ADH and also after reconstituting the ADH complex from the subunits, in contrast to the restoration of Q1 reductase activity and the other ferricyanide reductase activities. Thus, the data suggested that the heme c in subunit I and two of the three heme c moieties in subunit II are involved in the intramolecular electron transport of ADH into ubiquinone, where one of the two heme c sites may work at, or close to, the ubiquinone-reacting site and another between that and the heme c site in subunit I. The remaining heme c moiety in subunit II may have a function other than the electron transfer from ethanol to ubiquinone in ADH. << Less

  J. Biol. Chem. 271:4850-4857(1996) [PubMed] [EuropePMC]

• Generation mechanism and purification of an inactive form convertible in vivo to the active form of quinoprotein alcohol dehydrogenase in Gluconobacter suboxydans.

  Matsushita K., Yakushi T., Takaki Y., Toyama H., Adachi O.

  Alcohol dehydrogenase (ADH) of acetic acid bacteria is a membrane-bound quinohemoprotein-cytochrome c complex involved in vinegar production. In Gluconobacter suboxydans grown under acidic growth conditions, it was found that ADH content in the membranes was largely increased but the activity was ... >> More

  Alcohol dehydrogenase (ADH) of acetic acid bacteria is a membrane-bound quinohemoprotein-cytochrome c complex involved in vinegar production. In Gluconobacter suboxydans grown under acidic growth conditions, it was found that ADH content in the membranes was largely increased but the activity was not much changed, suggesting that such a condition produces an inactive form of ADH (inactive ADH). A similar phenomenon could be also observed in Acetobacter aceti, another genus of acetic acid bacteria. Furthermore, aeration conditions were also shown to affect ADH production; the ADH level was increased and was present as an active form under low-aeration conditions, while the ADH level was decreased and was present mainly as an inactive form under high-aeration conditions. Inactive ADH was solubilized from the membranes of G. suboxydans grown in acidic and high-aeration conditions and was purified separately from the normal, active form of ADH (active ADH). In spite of having 10 times less enzyme activity than active ADH, inactive ADH could not be distinguished from active ADH with respect to their subunit compositions, molecular sizes, and prosthetic groups. Inactive ADH, however, had a relatively loose conformation with a partially oxidized state, while active ADH had a tight conformation with a completely reduced state, suggesting that inactive ADH may lack a right subunit's interaction and that one of the heme c components may be inactivated. Reactivation from such an inactive ADH occurred either by shifting of the pH of the culture medium up during the cultivation or by incubation of the resting cells at the neutral pH region in the presence of an energy source such as D-sorbitol. Such an activation of ADH was repressed by the addition of a proton uncoupler and could not occur in the spheroplasts. Thus, the results suggest that inactive ADH could be generated abundantly under acidic growth conditions and converted to the active form at a neutral culture pH. The data also suggest that some periplasmic component may be involved in the conversion of inactive ADH into the active form by consuming some forms of energy. << Less

  J. Bacteriol. 177:6552-6559(1995) [PubMed] [EuropePMC]

• The quinohemoprotein alcohol dehydrogenase of Gluconobacter suboxydans has ubiquinol oxidation activity at a site different from the ubiquinone reduction site.

  Matsushita K., Yakushi T., Toyama H., Adachi O., Miyoshi H., Tagami E., Sakamoto K.

  Alcohol dehydrogenase (ADH) of acetic acid bacteria functions as the primary dehydrogenase of the ethanol oxidase respiratory chain, where it donates electrons to ubiquinone. In addition to the reduction of ubiquinone, ADHs of Gluconobacter suboxydans and Acetobacter aceti were shown to have a nov ... >> More

  Alcohol dehydrogenase (ADH) of acetic acid bacteria functions as the primary dehydrogenase of the ethanol oxidase respiratory chain, where it donates electrons to ubiquinone. In addition to the reduction of ubiquinone, ADHs of Gluconobacter suboxydans and Acetobacter aceti were shown to have a novel function in the oxidation of ubiquinol. The oxidation activity of ubiquinol was detected as an ubiquinol:ferricyanide oxidoreductase activity, which can be monitored by selected wavelength pairs at 273 and 298 nm with a dual-wavelength spectrophotometer. The ubiquinol oxidation activity of G. suboxydans ADH was shown to be two times higher in 'inactive ADH', whose ubiquinone reductase activity is 10 times lower, than with normal 'active' ADH. No activity could be detected in the isolated subunit II or subunit I/III complex, but activity was detectable in the reconstituted ADH complex. Inactive and active ADHs exhibited a 2-3-fold difference in their affinity to ubiquinol despite having the same affinity to ubiquinone. Furthermore, the ubiquinol oxidation site in ADH could be distinguished from the ubiquinone reduction site by differences in their sensitivity to ubiquinone-related inhibitors and by their substrate specificity with several ubiquinone analogues. Thus, the results strongly suggest that the reactions occur at different sites. Furthermore, in situ reconstitution experiments showed that ADH is able to accept electrons from ubiquinol present in Escherichia coli membranes, suggesting the ubiquinol oxidation activity of ADH has a physiological function. Thus, ADH of acetic acid bacteria, which has ubiquinone reduction activity, was shown to have a novel ubiquinol oxidation activity, of which the physiological function in the respiratory chain of the organism is also discussed. << Less

  Biochim. Biophys. Acta 1409:154-164(1999) [PubMed] [EuropePMC]