Oxygen supply by photosynthesis to an implantable islet cell device.

Transplantation of islet cells is an effective treatment for type 1 diabetes with critically labile metabolic control. However, during islet isolation, blood supply is disrupted, and the transport of nutrients/metabolites to and from the islet cells occurs entirely by diffusion. Adequate oxygen supply is essential for function/survival of islet cells and is the limiting factor for graft integrity. Recently, we developed an immunoisolated chamber system for transplantation of human islets without immunosuppression. This system depended on daily oxygen supply. To provide independence from this external source, we incorporated a novel approach based on photosynthetically-generated oxygen. The chamber system was packed sandwich-like with a slab of immobilized photosynthetically active microorganisms (Synechococcus lividus) on top of a flat light source (LEDs, red light at 660 nm, intensity of 8 µE/m(2)/s). Islet cells immobilized in an alginate slab (500-1,000 islet equivalents/cm(2)) were mounted on the photosynthetic slab separated by a gas permeable silicone rubber-Teflon membrane, and the complete module was sealed with a microporous polytetrafluorethylene (Teflon) membrane (pore size: 0.4 µm) to protect the contents from the host immune cells. Upon illumination, oxygen produced by photosynthesis diffused via the silicone Teflon membrane into the islet compartment. Oxygen production from implanted encapsulated microorganisms was stable for 1 month. After implantation of the device into diabetic rats, normoglycemia was achieved for 1 week. Upon retrieval of the device, blood glucose levels returned to the diabetic state. Our results demonstrate that an implanted photosynthetic bioreactor can supply oxygen to transplanted islets and thus maintain islet viability/functionality.

Nutritional and lifestyle habits and water-fiber interaction in colorectal adenoma etiology.

Adenomatous polyps are neoplasms that may progress to colorectal cancer. The role of diet and other lifestyle habits in their etiology is now being elucidated. The aim of this study was to evaluate effects of nutritional habits, weight and weight gain, tobacco smoking, and physical activity in adenoma etiology. A quantified dietary history questionnaire was designed to evaluate long-term dietary habits in addition to more recent ones. The study population comprised 196 adenoma patients and matched asymptomatic, screened controls. Statistical analysis used multivariate conditional logistic models, adjusting for total energy intake and physical activity. Odds ratios (ORs) and 95% confidence intervals (CIs) for adenoma associated with highest versus lowest tertiles of mean daily intake were as follows: for energy, OR 3.7 and CI 2.1-6.7; for animal fat, OR 2.4 and CI 1.2-4.7; for tobacco smoking, OR 3.1 and CI 1.1-2.8; and for weight gain, OR 2.2 and CI 1.2-4.1 (P for linear trend for all, < or = 0.01). Significant negative associations were found with intake of total carbohydrates (OR, 0.3; CI, 0.1-0.7) and fluids (OR, 0.4; CI, 0.2-0.8) (P for both < 0.01) as well as for physical activity (OR, 0.6; CI, 0.3-0.9; P = 0.03). Increased risk for adenoma was observed with decreased intake of carotene (OR, 0.6; CI, 0.3-1.0; P = 0.06), vitamin E (OR, 0.6; CI, 0.3-1.0; P = 0.07), and dietary fiber (OR, 0.6; CI, 0.3-1.3; not significant). The OR of interaction between water and dietary fiber was significant (OR, 0.7; CI, 0.6-0.9; P = 0.01), suggesting a synergistic protective effect. Specific dietary and lifestyle habits were identified as independent factors associated with colorectal adenomas; of special interest is the interaction between water and fiber intake. Avoiding these factors might delay or prevent neoplasia.

Photosynthesis of Prochlorothrix hollandica under Sulfide-Rich Anoxic Conditions.

The photosynthetic activity and photosystem II fluorescence of Prochlorothrix hollandica were studied under anoxic, sulfide-rich conditions. Oxygenic photosynthetic activity with water as the electron donor was highly resistant to inhibition by sulfide. Cells still retained 50% of their oxygenic photosynthetic activity at >1 mM sulfide. In the presence of DCMU [N-(3,4-dichlorophenyl)-N(prm1)-dimethylurea], an inhibitor of photosystem II activity, P. hollandica cells exhibited a low but significant anoxygenic photosynthetic activity when sulfide was present. This activity increased with higher sulfide concentrations and reached maximal rates at concentrations exceeding 1 mM sulfide. The effects of hydroxylamine on both oxygen evolution and fluorescence induction kinetics were similar to those observed for sulfide. It was concluded that the oxidizing site of photosystem II was the site of sulfide action leading to reduced or even fully inhibited electron donation to photosystem II. These observations bear similarity to the situation in some cyanobacteria in which both hydroxylamine and sulfide inhibit electron donation from H(inf2)O to P(inf680). The high resistance of photosystem II to sulfide is related to the hydrophobic nature of the manganese-stabilizing protein in P. hollandica (T. S. Mor, A. F. Post, and I. Ohad, Biochim. Biophys. Acta 1141:206-212, 1993). The observed sulfide tolerance of P. hollandica may confer a competitive advantage in its natural environment, where it forms a dominant fraction of phytoplankton in waters in which sulfide presence is a recurring phenomenon.

Potential contribution of the diazotrophic cyanobacterium, Cyanothece sp. strain 51142, to a bioregenerative life support system.

Long-duration manned space missions will likely require the development of bioregenerative means of life support. Such a Controlled Ecological Life Support System (CELSS) would use higher plants to provide food and a breathable atmosphere for the crew and employ a waste processing system to recover elements for recycling. The current study identifies ways in which a cyanobacterial component may enhance the sustainability of a space-deployed CELSS, including balancing CO2/O2 gas exchange, production of bioavailable N, dietary supplementation, and contingency against catastrophic failure of the higher plant crops. Relevant quantitative data have been collected about the cyanobacterium, Cyanothece sp. strain ATCC 51142, a large, aerobic, unicellular diazotroph. This organism grew rapidly (466 g dry wt. m-3 d-1) and under diverse environmental conditions, was amenable to large-scale culture, could be grown with relative energy efficiency (3.8% conversion), could actively fix atmospheric N2 (35.0 g m-3 d-1), could survive extreme environmental insults, and exhibited gas exchange properties (assimilatory quotient of 0.49) that may be useful for correcting the gas exchange ratio imbalances observed between humans and higher plants. It is suggested that a diazotrophic cyanobacterium, like Cyanothece sp. strain ATCC 51142, may be a safe, effective, and renewable complement or alternative to physicochemical backup systems in a CELSS.

Evaluation of Cyanothece sp. ATCC 51142 as a candidate for inclusion in a CELSS.

Controlled ecological life support systems (CELSS) have been proposed to make long-duration manned space flights more cost-effective. Higher plants will presumably provide food and a breathable atmosphere for the crew. It has been suggested that imbalances between the CO2/O2 gas exchange ratios of the heterotrophic and autotrophic components of the system will inevitably lead to an unstable system, and the loss of O2 from the atmosphere. Ratio imbalances may be corrected by including a second autotroph with an appropriate CO2/O2 gas exchange ratio. Cyanothece sp. ATCC 51142 is a large unicellular N2-fixing cyanobacterium, exhibiting high growth rates under diverse physiological conditions. A rat-feeding study showed the biomass to be edible. Furthermore, it may have a CO2/O2 gas exchange ratio that theoretically can compensate for ratio imbalances. It is suggested that Cyanothece spp. could fulfill several roles in a CELSS: supplementing atmosphere recycling, generating fixed N from the air, providing a balanced protein supplement, and protecting a CELSS in case of catastrophic crop failure.

Compositional and toxicological evaluation of the diazotrophic cyanobacterium, Cyanothece sp. strain ATCC 51142.

Compositional analyses of Cyanothece sp. strain ATCC 51142 showed high protein (50-60%) and low fat (0.4-1%) content, and the ability to synthesize vitamin B12. The amino acid profile indicated that Cyanothece sp. was a balanced protein source. Fatty acids of the 18:3n-3 type were also present. Mineral analyses indicated that the cellular biomass may be a good source of Fe, Zn and Na. Caloric content was 4.5 to 5.1 kcal g dry weight-1 and the carbon content was approximately 40% on a dry weight basis. Nitrogen content was 8 to 9% on a dry weight basis and total nucleic acids were 1.3% on a dry weight basis. Short-term feeding studies in rats followed by histopathology found no toxicity or dietary incompatibility problems. The level of uric acid and allantoin in urine and tissues was low, suggesting no excess of nucleic acids, as sometimes reported in the past for a cyanobacteria-containing diet. The current work discusses the potential implications of these results for human nutrition applications.

Purification and characterization of sulfide-quinone reductase, a novel enzyme driving anoxygenic photosynthesis in Oscillatoria limnetica.

An enzyme catalyzing sulfide quinone oxido-reduction (E.C.1.8.5.'.; SQR) has been purified in an active form, from thylakoids of the cyanobacterium Oscillatoria limnetica. It is composed of a single polypeptide of about 57 kDa. The catalytic activity of the purified enzyme is similar to the membrane-bound form in its kinetic parameters: apparent Km for sulfide equals 8 microM; Vmax of 100-150 mumol of plastoquinone-1 reduced/mg protein/h; quinone-substrate specificity; differential sensitivity to quinone analog inhibitors, the most potent of which being aurachin C (I50 = 7 nM), and specific inducibility by sulfide. Taken together, they suggest that the purified SQR is the enzyme catalyzing anoxygenic photosynthesis in cyanobacteria. The UV and visible absorption and fluorescence spectra of the purified SQR are typical of a flavoprotein. Both the absorption and fluorescence intensities are reduced by sulfide. The SQR activity is inhibited by KCN, a flavoprotein inhibitor. We have sequenced so far 29 amino acid residues of the SQR NH2 terminus and found that from the second residue, this sequence contains the highly conserved fingerprint of the NAD/FAD-binding domain of many NAD/FAD-binding enzymes (Wierenga, R. K., Terpstra, P., and Hol, W. G. S. (1986) J. Mol. Biol. 187, 101-107). This suggests that the SQR enzyme is a flavoprotein which contains binding sites for sulfide and quinone and that the electron transfer between the two is mediated by FAD.

Sulfide quinone reductase (SQR) activity in Chlorobium.

Membranes of the green sulfur bacterium, Chlorobium limicola f. thiosulfatophilum, catalyze the reduction of externally added isoprenoid quinones by sulfide. This activity is highly sensitive to stigmatellin and aurachins. It is also inhibited by 2-n-nonyl-4-hydroxyquinoline-N-oxide, antimycin, myxothiazol and cyanide. It is concluded that in sulfide oxidizing bacteria like Chlorobium, sulfide oxidation involves a sulfide-quinone reductase (SQR) similar to the one found in Oscilatoria limnetica [Arieli, B., Padan, E. and Shahak, Y. (1991) J. Biol. Chem. 266, 104-111].

Sulfide-induced sulfide-quinone reductase activity in thylakoids of Oscillatoria limnetica.

Sulfide-dependent partial electron-transport reactions were studied in thylakoids isolated from cells of the cyanobacterium Oscillatoria limnetica, which had been induced to perform sulfide-driven anoxygenic photosynthesis. It was found that these thylakoids have the capacity to catalyze electron transfer, from sulfide to externally added quinones, in the dark. Assay conditions were developed to measure the reaction either as quinone-dependent sulfide oxidation (colorimetrically) or as sulfide-dependent quinone reduction (by UV dual-wavelength spectrophotometry). The main features of this reaction are as follows. (i) It is exclusively catalyzed by thylakoids of sulfide-induced cells. Noninduced thylakoids lack this reaction. (ii) Plastoquinone-1 or -2 are equally good substrates. Ubiquinone-1 and duroquinone yield somewhat slower rates. (iii) The apparent Km for plastoquinone-1 was 32 microM and for sulfide about 4 microM. Maximal rates (at 25 degrees C) were about 75 mumol of quinone reduced per mg of chlorophyll.h. (iv) The reaction was not affected by extensive washes of the membranes. (v) Unlike sulfide-dependent NADP photoreduction activity of these thylakoids, which is sensitive to all the specific inhibitors of the cytochrome b6f complex, the new dark reaction exhibited differential sensitivity to these inhibitors. 2-n-Nonyl-4-hydroxyquinoline-N-oxide was the most potent inhibitor of both light and dark reactions, working at submicromolar concentrations. 5-n-Undecyl-6-hydroxy-4,7-dioxobenzothiazole also inhibited the two reactions to a similar extent, but at 10 times higher concentrations than 2-n-nonyl-4-hydroxyquinoline-N-oxide. 2,5-Dibromo-3-methyl-6-isopropyl-p-benzoquinone, 2-iodo-6-isopropyl-3-methyl-2',4,4'-trinitrodiphenyl ether, and stigmatellin had no effect on the dark reaction at concentrations sufficient to fully inhibit the light reaction from sulfide. We propose that the sulfide-induced factor which enables the use of sulfide as the electron donor for anoxygenic photosynthesis in Oscillatria limnetica is a membrane-bound sulfide-quinone reductase. Its site of interaction is suggested to be either the cytochrome b6 (at the Qc quinone binding site or the bH site) or the plastoquinone pool. The analogy to other anoxygenic photosynthetic systems is discussed.

Sulfide induction of synthesis of a periplasmic protein in the cyanobacterium Oscillatoria limnetica.

Two proteins which may play a role in the induction of anoxygenic photosynthesis in Oscillatoria limnetica have been demonstrated by comparing the pattern of labeling during pulses of [35S]methionine of cells incubated under inducing conditions [anaerobic conditions plus 3-(3,4-dichlorophenyl)-1,1-dimethylurea, light, and sulfide) with that of cells incubated under noninducing conditions (without sulfide). The major inducible protein has an apparent molecular mass of 11.5 kilodaltons and is associated with a less strongly labeled 12.5-kilodalton protein. The synthesis of both proteins commences within the first 30 min of induction and continues throughout the 2-h induction period. Since these proteins are not synthesized in the presence of dithionite without sulfide, low redox potential alone is insufficient as an inducer of these proteins. Lysozyme treatment and/or osmotic shock of intact cells results in the release of the sulfide-induced proteins. Our data thus indicate that these proteins are located in the periplasmic space of the cells.

Sulfide-dependent photosynthetic electron flow coupled to proton translocation in thylakoids of the cyanobacterium Oscillatoria limnetica.

Light-induced proton translocation coupled to sulfide-dependent electron transport has been studied in isolated thylakoids of the cyanobacterium Oscillatoria limnetica. The thylakoids are obtained by osmotic shock of washed spheroplasts, prepared with glycine-betaine as the osmotic stabilizer. 13C NMR studies suggests that betaine is the major osmoregulator in O. limnetica. Thylakoid preparations obtained from both sulfide-induced anoxygenic cells and noninduced oxygenic cells are capable of proton pumping coupled to phenazinemethosulfate-mediated cyclic electron flow. However, only in the induced thylakoids can sulfide-dependent proton gradient (delta pH) formation be measured, using either NADP or methyl viologen as the terminal acceptor. Sulfide-dependent delta pH formation correlates with a high-affinity electron donation site (apparent Km 44 microM at pH 7.9). This site is not lost upon washing of the thylakoids. In addition, both sulfide-dependent electron transport and delta pH formation are sensitive to inhibitors of the cytochrome b6f complex such as 2-n-nonyl-4-hydroxyquinoline-N-oxide, 2,4-dinitrophenyl ether of 2-iodo-4-nitrothymol, or stigmatellin. Sulfide-dependent NADP photoreduction of low affinity (which does not saturate by as much as 7 mM sulfide) is detected in both induced and noninduced thylakoids, but this activity is insensitive to the inhibitors and is not coupled to proton transport. It is suggested that the adaptation of O. limnetica to anoxygenic photosynthesis involves the induction of a thylakoid factor(s) which creates a high-affinity site for sulfide, and the transfer of its electrons via the cytochrome b6f complex, coupled to proton translocation.

Sulfur metabolism in Beggiatoa alba.

The metabolism of sulfide, sulfur, and acetate by Beggiatoa alba was investigated under oxic and anoxic conditions. B. alba oxidized acetate to carbon dioxide with the stoichiometric reduction of oxygen to water. In vivo acetate oxidation was suppressed by sulfide and by several classic respiratory inhibitors, including dibromothymoquinone, an inhibitor specific for ubiquinones. B. alba also carried out an oxygen-dependent conversion of sulfide to sulfur, a reaction that was inhibited by several electron transport inhibitors but not by dibromothymoquinone, indicating that the electrons released from sulfide oxidation were shuttled to oxygen without the involvement of ubiquinones. Intracellular sulfur stored by B. alba was not oxidized to sulfate or converted to an external soluble form under aerobic conditions. On the other hand, sulfur stored by filaments of Thiothrix nivea was oxidized to extracellular soluble oxidation products, including sulfate. Sulfur stored by filaments of B. alba, however, was reduced to sulfide under short-term anoxic conditions. This anaerobic reduction of sulfur was linked to the endogenous oxidation of stored carbon and to hydrogen oxidation.

Energy in avian eggs and hatchlings: utilization and transfer.

Energy content of eggs, hatchlings, and egg components (albumen, yolk, true hatchling = hatchling without spare yolk, and spare yolk) and the energy spent for metabolism were analyzed in 50 species of birds divided into four maturity types. Mass-specific energy density on the basis of fresh egg content mass appears to be mass-independent within each maturity group but different among the groups. Mass-specific energy densities calculated on the basis of dry component mass are the same for albumen, yolk, and spare yolk in all maturity groups but are different for true hatchlings, precocial hatchlings being richer in energy than all others. The gross production efficiency (hatchling energy/egg energy) of 63.7% +/- 7.8 SD does not differ significantly among maturity types. Total production efficiency (true hatchling energy/egg energy minus spare yolk energy) averaged 57.0% +/- 7.0% (SD) in all types. The inefficiency attributed to fuel loss in metabolism is 34.7% +/- 11.0% (SD) of the total energy used; hence losses in extraembryonic tissues and meconium average 8.3% of the total energy used. The cost of transforming the chemical potential energy in the egg into living tissues (including maintenance costs) is about 0.5 J X J-1. The energy densities of the dry matter in the egg and the energy transformation efficiencies and costs seem to be independent of maturity type. The differences among maturity types reside in the different water concentrations in eggs and hatchlings, in the density of chemical potential energy in the dry matter of true hatchlings, and in the different amounts of energy transferred untransformed from the egg to the spare yolk.