Диссертация (1091621), страница 18
Текст из файла (страница 18)
– V.58. – №.2. –P.97-102.White D.A., Hird L.C., Ali S.T. Production and characterization of a trehalolipidbiosurfactant produced by the novel marine bacterium Rhodococcus sp., strainPML026 // J Appl Microbiol. – 2013. – V .115. – №3. – P .744-55.Kugler J.H., Kraft A., Heissler S., Muhle-Goll C., Luy B., Schwack W., Syldatk C.,Hausmann R. Extracellular aromatic biosurfactant produced by Tsukamurellapseudospumae and T. spumae during growth on n-hexadecane // J Biotechnol. – 2015.– V.211. – P. 107-14.Konishi M., Fukuoka T., MoritaT., Imura T., Kitamoto D. Production of new types ofsophorolipids by Candida batistae // J Oleo Sci.
– 2008. – V.57. – N.6. – P. 359-69.Daverey A., Pakshirajan K. Sophorolipids from Candida bombicola using mixedhydrophilic substrates: production, purification and characterization // Colloids Surf BBiointerfaces. – 2010. – V.79. – №.1. – P.
246-53.11731.32.33.34.35.36.37.38.39.40.41.42.43.44.45.46.Elshafie A.E.J., Al-Wahaibi S.J., Al-Bemani Y.M., Al-Bahry A.S., Al-Maqbali S.N.Banat, D., Sophorolipids Production by Candida bombicola ATCC 22214 and itsPotential Application in Microbial Enhanced Oil Recovery // Front Microbiol. – 2015.– V.6. – P. 1324.Morita T.K., Fukuoka M., Imura T., Kitamoto T. Physiological differences in theformation of the glycolipid biosurfactants, mannosylerythritol lipids, betweenPseudozyma antarctica and Pseudozyma aphidis // Appl Microbiol Biotechnol.
–2007. – V.74. – №.2. – P. 307-15.Suthar H., Nerurkar A. Characterization of Biosurfactant Produced by Bacilluslicheniformis TT42 Having Potential for Enhanced Oil Recovery // Appl BiochemBiotechnol. – 2016. – V.180. – №.2. – P. 248-60.Biniarz P.B., Feder-Kubis G., Krasowska J. The lipopeptides pseudofactin II andsurfactin effectively decrease Candida albicans adhesion and hydrophobicity //Antonie van Leeuwenhoek. – 2015. – V.108.
– №.2. – P. 343-353.Bao M.P., Wang Y., Sun L., Li P., Cao Y. Lipopeptide biosurfactant productionbacteria Acinetobacter sp. D3-2 and its biodegradation of crude oil // EnvironmentalScience: Processes & Impacts. – 2014. – V.16. – №.4. – P. 897-903.Peng F., Wang Y., Sun F., Liu Z., Lai Q., Shao Z.
A novel lipopeptide produced by aPacific Ocean deep-sea bacterium, Rhodococcus sp. TW53 // J Appl Microbiol. –2008. – V.105. – №3. – P. 698-705.Morikawa M.D., Takao H., Murata T., Shimonishi S., Imanaka Y. A new lipopeptidebiosurfactant produced by Arthrobacter sp. strain MIS38 // J Bacteriol. – 1993. –V.175. – №.20. – P. 6459-66.Cooper D.G., Zajic J.E., Gerson D.F. Production of surface-active lipids byCorynebacterium lepus // Applied and Environmental Microbiology. – 1979.
– V.37 –№.1. – P. 4-10.Macdonald C.R., Cooper D.G., Zajic J.E. Surface-active lipids from Nocardiaerythropolis grown on hydrocarbons // Applied and Environmental Microbiology. –1981. – V.41. – №.1. – P. 6.Bodour A.A., Guerrero-Barajas C., Jiorle BV. Structure and characterization offlavolipids, a novel class of biosurfactants produced by Flavobacterium sp. strainMTN11 // Applied and Environmental Microbiology. – 2004. – V.70. – P.
6.Nwaguma I.V., Chikere C.B., Okpokwasili G.C. Isolation, characterization, andapplication of biosurfactant by Klebsiella pneumoniae strain IVN51 isolated fromhydrocarbon-polluted soil in Ogoniland, Nigeria // Bioresources and Bioprocessing. –2016. – V.3. – №1.
– P. 40.Janek T., Lukaszewicz M., Krasowska A. Identification and characterization ofbiosurfactants produced by the Arctic bacterium Pseudomonas putida BD2 // ColloidsSurf B Biointerfaces. – 2013. – V.110. – P. 379-86.Navon-Venezia S.Z., Gottlieb Z., Legmann A., Carmeli R., Ron S., Rosenberg E.Z.,Alasan, a new bioemulsifier from Acinetobacter radioresistens // Appl EnvironMicrobiol. – 1995. – V.61. – №.9. – P. 3240-4.Navon-Venezia S.B., Ron E., Rosenberg, E. Z. The bioemulsifier alasan: role ofprotein in maintaining structure and activity // Applied Microbiology andBiotechnology. – 1998.
-V.49. – №.4. – P. 382-384.Toren A.O., Paitan E., Ron Y., Rosenberg E Z. The Active Component of theBioemulsifier Alasan from Acinetobacter radioresistens KA53 Is an OmpA-LikeProtein // Journal of Bacteriology. – 2002. – V.184. – №.1. – P. 165-170.Kaplan N., Zosim Z., Rosenberg E. Reconstitution of emulsifying activity ofAcinetobacter calcoaceticus BD4 emulsan by using pure polysaccharide and protein //Appl Environ Microbiol. – 1987. – V.53.
– №.2. – P. 440-6.11847.48.49.50.51.52.53.54.55.56.57.58.59.60.61.62.Morikawa M., Daido H., Takao T., Murata S., Shimonishi Y., Imanaka T. A newlipopeptide biosurfactant produced by Arthrobacter sp. strain MIS38 // J Bacteriol. –1993. – V.175. – №.20. – P. 6459-66.Yakimov M.M., Wray V., Fredrickson H.L. Characterization of a new lipopeptidesurfactant produced by thermotolerant and halotolerant subsurface Bacilluslicheniformis BAS50 // Applied and Environmental Microbiology. – 1995. – V.61. –№.5. – P. 1706-1713.Neu T.R.
and Poralla K. Emulsifying agents from bacteria isolated during screeningfor cells with hydrophobic surfaces // Applied Microbiology and Biotechnology. –1990. – V.32. – №.5. – P. 521-525.Cooper D.G. and Zair J.E. Surface active compounds from microorganisms // AdvAppl Microbiol. – 1980. – V.26. – P. 4.Asselineau J.
The chemical structure of the cord factor of Mycobacterium tuberculosis// Biochimica et Biophysica Acta. – 1956. – V.20. – P. 11.Ryll R., Kumazawa Y. and Yano I. Immunological properties of trehalose dimycolate(cord factor) and other mycolic acid-containing glycolipids--a review // MicrobiolImmunol. – 2001. – V.45. – №12. – P. 801-11.Ristau C.A. and Wagner A. Formation of novel anionic trehalosetetraesters fromRhodococcus erythropolis under growth limiting conditions // Biotechnology letters.
–1983. – V.5. – №.2. – P. 6.Kretschmer A., Bock H., and Wagner F. Chemical and physical characterization ofInterfacial-Active Lipids from Rhodococcus erythropolis grown on n-alkanes //Applied and Environmental Microbology. – 1982. – V.44. – №.4. – P. 7.Ueda S.F., Naka N., Sakaguchi T., Ozeki I., Yano Y., Kasama I., Kobayashi T.Structure-activity relationship of mycoloyl glycolipids derived from Rhodococcus sp.4306 // Microb Pathog. – 2001. – V.30. – №.2. – P. 91-9.Niescher S., Lang S., Kaschabek S.R, Schlomann M. Identification and structuralcharacterization of novel trehalose dinocardiomycolates from n- alkane - grownRhodococcus opacus 1CP // Appl Microbiol Biotechnol . – 2006.
– V .70. – P. 605611.Tomiyasu I.Y., Kurano J., Kato F., Kaneda Y., Imaizun K., Yano S., Occurrence of anovel glycolipid, 'trehalose 2,3,6'-trimycolate' in a psychrophilic, acid-fast bacterium,Rhodococcus aurantiacus (Gordona aurantiaca) // FEBS Letters. – 1986. – V.203. –№.2 . – P. 239-242.Kurane R., Kakuno T., Kiyohara M., Tajima T., Hirano M., Taniguchi Y. ChemicalStructure of Lipid Bioflocculant Produced by Rhodococcus erythropolis // Bioscience,Biotechnology, and Biochemistry.
– 1995. – V.59. – №.9. – P. 1652-1656.Ivshina I.B., Kuyukina M.S. Rhodococcus Biosurfactants: Biosynthesis, Properties,and Potential Applications Biology of Rhodococcus in Microbiology Monographs 16 /Alvarez H.M. (ed). – Springer -Verlag Berlin. – 2010. – P.291-309.Singer M.E., Finnerty W.R., Tunelid A. Physical and chemical properties of abiosurfactant synthesized by Rhodococcus species H13-A // Can J Microbiol. – 1990.– V.36. – №.11.
– P. 746-50.Uchida Y., T.R., Chino M., Hirano J.,Tabuchi T. Extracellular accumulation of monoand di-succinoyl trehalose lipids by strain of Rhodococcus erythropolis grown on nalkans // Agric Biol Chem. – 1989. – V.53. – №3. – P. 6.Espuny M.J., Mercadè M.E., Manresa A. Characterization of trehalose tetraesterproduced by a waste lube oil degrader Rhodococcus sp. 51T7 // Toxicological &Environmental Chemistry. – 1995. – V.48. – №.(1-2). – P. 83-88.11963.64.65.66.67.68.69.70.71.72.73.74.75.76.77.Tuleva B., Cohen R., Stoev G., Stoineva I. Production and structural elucidation oftrehalose tetraesters (biosurfactants) from a novel alkanothrophic Rhodococcuswratislaviensis strain // J Appl Microbiol.
– 2008. – V.104. – №.6. – P.1703-10.Suzuki T., Tanaka K., Matsubara I., Kinoshita S. Trehalose Lipid and α-Branched-βhydroxy Fatty Acid Formed by Bacteria Grown on n-Alkanes // Agricultural andBiological Chemistry. – 2014. – V.33. – №.11. – P. 1619-1627.Peng F., L.Z., Wang L., Shao Z. An oil-degrading bacterium: Rhodococcuserythropolis strain 3C-9 and its biosurfactants // J Appl Microbiol. – 2007. – V.102. –№.6. – P.1603-11.Zheng C., Yu L., Huang L.,Wu Q. Study of the biosurfactant-producing profile in anewly isolated Rhodococcus ruber strain // Ann Microbiol. – 2009. – V.59. – №.4. –P. 6.Sudo T., Wakamatsu Y.,Shibahara M., Nomura N., Nakahara T., Suzuki A.,Kobayashi Y., Jin C., Murata T., Yokoyama K.K., Induction of the differentiation ofhuman HL-60 promyelocytic leukemia cell line by succinoyl trehalose lipids //Cytotechnology.
– 2000. – V.33. – №.(1-3). – P. 259-64.Zaragoza A., Espuny M. J., Teruel J. A., Marques A., Manresa A., Ortiz A.,Hemolytic activity of a bacterial trehalose lipid biosurfactant produced byRhodococcus sp.: evidence for a colloid-osmotic mechanism // Langmuir. – 2010. –V.26. – №.11. – P. 8567-72.Zaragoza A., Espuny M. J., Teruel J. A., Marques A., Manresa A., Ortiz A.,Interaction of a Rhodococcus sp. trehalose lipid biosurfactant with model proteins:thermodynamic and structural changes // Langmuir.