Candida famata (Candida flareri)

Yeast

Volumn 29, Issue 11, 2012, Pages 453-458

  Dmytruk, Kostyantyn V ^a   Sibirny, Andriy A ^a,b  

^a INSTITUTE OF CELL BIOLOGY   (Ukraine)

^b UNIVERSITY OF RZESZÓW   (Poland)

Author keywords

Candida famata; Riboflavin; Yeast

Indexed keywords

FLAVINE ADENINE NUCLEOTIDE; FLAVINE MONONUCLEOTIDE; RIBOFLAVIN; SODIUM CHLORIDE;

ARTICLE; BIOTRANSFORMATION; CANDIDA FAMATA; CONCENTRATION (PARAMETERS); FUNGAL STRAIN; GENE IDENTIFICATION; INSERTIONAL MUTAGENESIS; METABOLIC ENGINEERING; MOLECULAR CLONING; MUTAGENESIS; NONHUMAN; PRIORITY JOURNAL; SACCHAROMYCES CEREVISIAE; SALT TOLERANCE; SYNTHESIS;

BIOTECHNOLOGY; CANDIDA; IRON; METABOLIC ENGINEERING; METABOLIC NETWORKS AND PATHWAYS; RIBOFLAVIN; SALINE SOLUTION, HYPERTONIC; UNITED STATES;

CANDIDA; DEBARYOMYCES HANSENII;

EID: 84869065740     PISSN: 0749503X     EISSN: 10970061     Source Type: Journal    
DOI: 10.1002/yea.2929     Document Type: Article

References (36)

1. Abbas CA, Sibirny AA. 2012. Genetic control of biosynthesis and transport of riboflavand flavnucleotides and construction of robust biotechnological producers. Microbiol Mol Biol Rev 75: 321-360.
2. Abbas C, Voronovsky AY, Fayura LR, et al. 2006. Transformation systems for flavinogenic yeast. US Patent No. 007009045 (B2).
3. Barnett JA, Paye RW, Yarrow D (eds). 2000. Yeast: characterization and identification, Cambridge University Press: Cambridge.
4. Coursolle D, Baron DB, Bond DR, et al. 2010. The Mtr respiratory pathway is essential for reducing flavins and electrodes Shewanella oneidensis. J Bacteriol 192: 467-474.
5. Crossley RA, GaskDJ, Holmes K, et al. 2007. Riboflavbiosynthesis is associated with assimilatory ferric reduction and iron acquisition by Campylobacter jejuni. Appl Environ Microbiol 73: 7819-7825.
6. Dmytruk KV, Abbas CA, Voronovsky AY, et al. 2004. Cloning of structural genes involved riboflavsynthesis of the yeast Candida famata. Ukr Biokhim Zh 76: 78-87.
7. Dmytruk KV, Voronovsky AY, Sibirny AA. 2006. Insertion mutagenesis of the yeast Candida famata (Debaryomyces hansenii) by random integration of linear DNA fragments. Curr Genet 50: 183-191.
8. Dmytruk KV, Yatsyshyn VY, Sybirna NO, et al. 2011. Metabolic engineering and classic selection of the yeast Candida famata (Candida flareri) for construction of the strains with enhanced riboflavproduction. Metab Eng 13: 82-88.
9. Dujon B, Sherman D, Fischer G, et al. 2008. Genome evolution yeasts. Nature 430: 35-44.
10. Fitzpatrick DA, Logue ME, Stajich JE, et al. 2006. A fungal phylogeny based on 42 complete genomes derived from supertree and combined gene analysis. BMC Evol Biol 6: 99.
11. Groenewald M, Daniel HM, Robert V, et al. 2008. Polyphasic re-examination of Debaryomyces hansenii strains and reinstatement of D. hansenii, D. fabryi and D. subglobosus. Persoonia 21: 17-27.
12. Gunde-Cimerman N, Ramos J, Plemenitas A. 2009. Halotolerant and halophilic fungi. Mycol Res 113(11): 1231-1241.
13. Heefner DL, Weaver CA, Yarus MJ, et al. 1992. Method for producing riboflavwith Candida famata. US Patent No. 5164303 (17 November 1992).
14. Hickey RJ. 1945. The inactivation of iron by 2, 2′-bipyrimidine and its effect on riboflavsynthesis by Clostridium acetobutylicum. Arch Biochem 8: 439-447.
15. Higa A, Miyamoto E, Ur Rahman L, et al. 2008. Root tip-dependent, active riboflavsecretion by Hyoscyamus albus hairy roots under iron deficiency. Plant Physiol Biochem 46: 452-460.
16. Ishchuk OP, Dmytruk KV, Rohulya OV, et al. 2008. Development of a promoter assay system for the flavinogenic yeast Candida famata based on the Kluyveromyces lactis ß-galactosidase LAC4 reporter gene. Enz Microb Technol 42: 208-215.
17. Knight SA, Lesuisse E, Stearman R, et al. 2002. Reductive iron uptake by Candida albicans: role of copper, iron and the TUP1 regulator. Microbiology 148: 29-40.
18. Lesuisse E, Labbe P. 1992. Iron reduction and trans-plasma membrane electron transfer the yeast Saccharomyces cerevisiae. Plant Physiol 100(2): 769-777.
19. Nakase T, Suzuki M. 1985. Taxonomic studies on Debaryomyces hansenii (Zopf) Lodder et Kreger-van Rij and related species. I. Chemotaxonomic investigations. J Gen Appl Microbiol 31: 49-69.
20. Nguyen HV, GaillardC, Neuveglise C. 2009. Differentiation of Debaryomyces hansenii and Candida famata by rRNA gene intergenic spacer fingerprinting and reassessment of phylogenetic relationships among D. hansenii, C. famata, D. fabryi, C. flareri (D. subglobosus) and D. prosopidis: description of D. vietnamensis sp. nov. closely related to D. nepalensis. FEMS Yeast Res 9: 641-662.
21. Prillinger H, Molnar O, Eliskases-Lechner F, et al. 1999. Phenotypic and genotypic identification of yeasts from cheese. Antonie Van Leeuwenhoek 75: 267-283.
22. Sanchez S, DemaA. 2008. Metabolic regulation and overproduction of primary metabolites. Microb Biotechnol 1(4): 283-319.
23. Shavlovskii GM, Logvinenko EM. 1988. Supersynthesis of flavins microorganisms and its molecular mechanism (review of the literature). Prikl Biokhim Mikrobiol 24: 435-447 [Russian].
24. Sibirny AA, Boretsky YR. 2009. Pichia guilliermondii. Yeast Biotechnology: Diversity and Applications, Satyanarayana T, Kunze G (eds). Springer Science: New York; 113-134.
25. Stahmann K-P, Revuelta JL, Seulberger H. 2000. Three biotechnical processes using Ashbya gossypii, Candida famata or Bacillus subtilis compete with chemical riboflavproduction. Appl Microbiol Biotechnol 53: 509-516.
26. Stenchuk NN, Kutsiaba VI, Kshanovskaia BV, et al. 2001. Effect of rib83 mutation on riboflavbiosynthesis and iron assimilation Pichia guilliermondii. Mikrobiologiia 70: 753-758 [Russian].
27. Tanner FW, Voinovich Jr C, Van Lanen JM. 1945. Riboflavproduction by Candida species. Science 101: 180-181.
28. Vardja T, Vardja R, Pudersell K, et al. 2004. Riboflavexcretion from the excised roots of Hyoscyamus niger. Pharm Biol 42: 353-359.
29. Voronovsky AA, Abbas CA, Fayura LR, et al. 2002. Development of a transformation system for the flavinogenic yeast Candida famata. FEMS Yeast Res 2(3): 381-388.
30. Voronovsky AY, Abbas CA, Dmytruk KV, et al. 2004. Candida famata (Debaryomyces hansenii) DNA sequences containing genes involved riboflavsynthesis. Yeast 21: 1307-1316.
31. Vorwieger A, Gryczka C, Czihal A, et al. 2007. Iron assimilation and transcription factor controlled synthesis of riboflavplants. Planta 226: 147-158.
32. Wang L, Chi Z, Wang X, et al. 2008. Isolation and characterization of Candida membranifaciens subsp. flavinogenie W14-3, a novel riboflavin-producing marine yeast. Microbiol Res 163: 255-266.
33. WeinsteLH, Purvis ER, Meiss AN, et al. 1954. Chelates, absorption and translocation of ethylenediaminetetraacetic acid by sunflower plants. J Agric Food Chem 2: 421-424.
34. Worst DJ, Gerrits MM, Vandenbrouke-Grauls CM, et al. 1998. Helicobacter pylori ribBA-mediated riboflavproduction is involved iron acquisition. J Bacteriol 180: 1473-1479.
35. Yatsyshyn VY, Fedorovych DV, Sibirny AA. 2010. Medium optimization for production of flavmononucleotide by the recombinant straof the yeast Candida famata using statistical designs. Biochem Eng J 49: 52-60.
36. Yatsyshyn VY, Ishchuk OP, Voronovsky AY, et al. 2009. Production of flavmononucleotide by metabolically engineered yeast Candida famata. Metab Eng 11: 163-167.