Mediator toxicity and dual effect of glucose on the lifespan for current generation by Cyanobacterium Synechocystis PCC 6714 based photoelectrochemical cells

Journal of Chemical Technology and Biotechnology

Volumn 86, Issue 1, 2011, Pages 109-114

  Xie, Xuan Hui ^a   Li, Erin Lin ^a   Kang Tang, Zi ^a  

^a HONG KONG UNIVERSITY OF SCIENCE AND TECHNOLOGY   (Hong Kong)

Author keywords

Current generation; Cyanobacterium Synechocystis PCC 6714; Electron shuttling mediator; Glucose; Lifespan; Viability

Indexed keywords

CELL PHYSIOLOGY; CELL VIABILITY; CHLOROPHYLL CONTENTS; CURRENT DISCHARGE; CURRENT GENERATION; CURRENT RESPONSE; CYANOBACTERIUM SYNECHOCYSTIS; DARK CONDITIONS; DISCHARGE CURRENTS; DUAL EFFECT; DUAL ROLE; ENERGY RESERVES; ENERGY SOLUTIONS; GROWTH CURVES; HETEROTROPHIC CONDITIONS; LIFE SPAN; LIMITING FACTORS; PRACTICAL USE; PRIMARY FACTORS; REGULATORY EFFECTS; SYSTEMATIC TEST; TOXIC EFFECT; VIABILITY; VITAMIN K;

CARBOHYDRATES; CARBON DIOXIDE; CHLOROPHYLL; CYTOLOGY; METABOLISM; PHOTOELECTROCHEMICAL CELLS; PHYSIOLOGY; TOXICITY;

GLUCOSE;

CARBOHYDRATE; CARBON DIOXIDE; CHLOROPHYLL; GLUCOSE; GLYCOGEN; MENADIONE;

ARTICLE; AUTOTROPHY; CELL FUNCTION; CELL VIABILITY; CHLOROPHYLL CONTENT; ELECTRODE; GROWTH CURVE; HETEROTROPHY; LIFESPAN; NONHUMAN; PHOTOCHEMISTRY; SYNECHOCYSTIS; TOXICITY;

CYANOBACTERIA; SYNECHOCYSTIS SP.; SYNECHOCYSTIS SP. PCC 6714;

EID: 78650044728     PISSN: 02682575     EISSN: 10974660     Source Type: Journal    
DOI: 10.1002/jctb.2489     Document Type: Article

References (36)

1. Lewis NS, Toward cost-effective solar energy use. Science 315: 798-801 (2007).
2. Hoffert MI, Caldeira K, Benford G, Criswell DR, Green C, Herzog H, et al, Advanced technology paths to global climate stability: energy for a greenhouse planet. Science 298: 981-987 (2002).
3. Lewis NS and Nocera DG, Powering the planet: Chemical challenges in solar energy utilization. Proc Natl Acad Sci USA 103: 15729-15735 (2006).
4. Cogdell RJ, Isaacs NW, Howard TD, McLuskey K, Fraser NJ and Prince SM, How photosynthetic bacteria harvest solar energy. J Bacteriol 181: 3869-3879 (1999).
5. Mathews JA, Carbon-negative biofuels. Energy Policy 306: 940-945 (2008).
6. Esper B, Badura A and Rögner M, Photosynthesis as a power supply for (bio)hydrogen production. TRENDS Plant Sci 11: 543-549 (2006).
7. Chiao M, Lam KB and Lin L, Micromachined microbial and photosynthetic fuel cells. J Micromech Microeng 16: 2547-2553 (2006).
8. Yagishita T, Sawayama S, Tsukahara KI and Ogi T, Performance of photosynthetic electrochemical cells using immobilized Anabaena variabilis M-3 in discharge/culture cycles. J Ferment Bioeng 85: 546-549 (1998).
9. Tanaka K, Tamamushi R and Ogawa T, Bioelectrochemical fuel cells operated by the cyanobacterium, Anabaena variabilis. J Chem Technol Biotechnol 35B: 191-197 (1985).
10. Torimura M, Miki A, Wadano A, Kano K and Ikeda T, Electrochemical investigation of cyanobacteria Synechococcus sp. PCC7942-catalyzed photoreduction of exogenous quinones and photoelectrochemical oxidation of water. J Electroanal Chem 496: 21-28 (2001).
11. Martens N and Hall EAH, Diaminodurene as a mediator of a photocurrent using intact cells of cyanobacteria. Photochem Photobiol 59: 91-98 (1994).
12. Fu CC, Su CH, Hung TC, Hsieh CH, Suryani D and Wu WT, Effects of biomass weight and light intensity on the performance of photosynthetic microbial fuel cells with Spirulina platensis. Bioresource Technol 100: 4183-4186 (2009).
13. Jang JK, Pham TH, Chang IS, Kang KH, Moon H, Cho KS, et al, Construction and operation of a novel mediator- and membrane-less microbial fuel cell. Process Biochem 39: 1007-1012 (2004).
14. Peterkofsky A and Gazdar C, Glucose and the metabolism of adenosine ${3':5'}$-cyclic monophosphate in Escherichia coli. Proc Natl Acad Sci USA 68: 2794-2798 (1971).
15. Mackinney G, Absorption of light by chlorophyll solutions. J Biol Chem 140: 315-322 (1941).
16. Huang JJ, Kolodny NH, Redfearn JT and Allen MM, The acid stress response of the cyanobacterium Synochocystis sp. strain PCC 6308. Arch Microbial 177: 486-493 (2002).
17. Mikkat S, Hagemann M and Schoor A, Active transport of glucosylglycerol is involved in salt adaptation of the cyanobacterium Synechocystis sp. strain PCC 6803. Microbiology 142: 1725-1732 (1996).
18. Kim J, Jia H and Wang P, Challenges in biocatalysis for enzyme-based biofuel cells. Biotechnol Adv 24: 296-308 (2006).
19. Davis F and Higson SPJ, Biofuel cells-recent advances and applications. Biosens Bioelectron 22: 1224-1235 (2007).
20. Mohana Y and Das D, Effect of ionic strength, Cation exchanger and inoculum age on the performance of microbial fuel cells. Int J Hydrogen Energy 34: 7542-7546 (2009).
21. Daniel DK, Mankidy BD, Ambarish K and Manogari R, Construction and operation of a microbial fuel cell for electricity generation from wastewater. Int J Hydrogen Energy 34: 7555-7560 (2009).
22. Sharma T, Reddy ALM, Chandra TS and Ramaprabhu S, Development of carbon nanotubes and nanofluids based microbial fuel cell. Int J Hydrogen Energy 33: 6749-6754 (2008).
23. Lies DP, Hernandez ME, Kappler A, Mielke RE, Gralnick JA and Newman DK, Shewanella oneidensis strain MR-1 uses overlapping pathways for iron reduction at a distance and by direct contact under conditions relevant for biofilms. Appl Environ Microbiol 71: 4414-4426 (2005).
24. Gorby YA, Yanina S, McLean JS, Rosso KM, Moyles D, Dohnalkova A, et al, Electrically conductive bacterial nanowires produced by Shewanella oneidensis strain MR-1 and other microorganisms. Proc Natl Acad Sci USA 103: 11358-11363 (2006).
25. Myers JM and Myers CR, Role of the tetraheme cytochrome CymA in anaerobic electron transport in cells of Shewanella putrefaciens MR-1 with normal levels of menaquinone. J Bacteriol 182: 67-75 (2000).
26. Wang YF, Tsujimura S, Cheng SS and Kano K, Self-excreted mediator from Escherichia coli K-12 for electron transfer to carbon electrodes. Appl Microbiol Biotechnol 76: 1439-1446 (2007).
27. Sakai H, Nakagawa T, Tokita Y, Hatazawa T, Ikeda T, Tsujimura Sa, et al, A high-power glucose/oxygen biofuel cell operating under quiescent conditions. Energy Environ Sci 2: 133-138 (2009).
28. Chumnantana R, Yokochi N and Yagi T, Vitamin B6 compounds prevent the death of yeast cells due to menadione, a reactive oxygen generator. Biochim Biophys Acta 1722: 84-91 (2005).
29. Samuilov VD, Bulakhov AV, Kiselevsky DB, Kuznetsova YE, Molchanova DV, Sinitsyn SV, et al, Tolerance to antimicrobial agents and persistence of Escherichia coli and cyanobacteria. Biochemistry (Moscow) 73: 833-838 (2008).
30. +-ATPase and reductase activities in plants. Plant Sci 170: 936-941 (2006).
31. Elanskaya IV, Grivennikova VG, Groshev VV, Kuznetsova GV, Semina ME and Timofeev KN, Role of NAD(P)H: Quinone oxidoreductase encoded by drgA gene in reduction of exogenous quinones in Cyanobacterium Synechocystis sp. PCC 6803 cells. Biochemistry (Moscow) 69: 137-142 (2004).
32. Smith AJ, Modes of cyanobacterial carbon metabolism, in The Biology of Cyanobacteria, ed by Carr NG and Whitton BA. Blackwell, Oxford, pp 47-85 (1982).
33. Kahlon S, Beeri K, Ohkawa H, Hihara Y, Murik O, Suzuki I, et al, A putative sensor kinase, Hik31, is involved in the response of Synechocystis sp. strain PCC 6803 to the presence of glucose. Microbiology+, 152: 647-655 (2006).
34. Ryu JY, Song JY, Lee JM, Jeong SW, Chow WS, Choi SB, et al, Glucose-induced expression of carotenoid biosynthesis genes in the dark is mediated by cytosolic pH in the cyanobacterium Synechocystis sp. PCC 6803. J Biol Chem 279: 25320-25325 (2004).
35. Lebedeva NV and Semenenko VE, Photosynthesis regulation by glucose and its stereochemical analog in the cyanobacterium Synechocystis sp. PCC 6803. Russian J Plant Physiol 47: 580-584 (2000).
36. Gómez-Baena G, López-Lozano A, Gil-Martínez J, Lucena JM, Diez J, Candau P, et al, Glucose uptake and its effect on gene expression in Prochlorococcus. PLoS ONE 3: e3416 (2008).