Fatty Acid Composition of Cladosporium resinae Grown on Glucose and on Hydrocarbons

J Bacteriol. 1971 November; 108(2): 777–781.

PMCID: PMC247140

Fatty Acid Composition of Cladosporium resinae Grown on Glucose and on Hydrocarbons

J. J. Cooney and C. M. Proby

Department of Biology, University of Dayton, Dayton, Ohio 45409

This article has been cited by other articles in PMC.

Abstract

Cladosporium resinae was grown in submerged cultures on glucose; on Jet-A commercial aviation fuel; and on a series of n-alkanes, n-decane through n-tetradecane. Cell yield was greatest on glucose and least on Jet-A; n-alkanes were intermediate. Among n-alkanes cell yield decreased as chain length increased, except for n-dodecane, which supported less growth than n-tridecane or n-tetradecane. The total fatty acids of stationary-phase cells were analyzed by gas-liquid chromatography. In all cases the predominant fatty acids were 16:0, 18:1, and 18:2. The fatty acid composition of glucose-grown cells was similar to that of hydrocarbon-grown cells. Cells grown on n-tridecane or n-tetradecane yielded small amounts of acids homologous to the carbon source, but a similar correlation was not noted for n-decane, n-undecane, or n-dodecane. Cells grown on n-undecane or n-tridecane contained more odd-carbon fatty acids than cells grown on the other substrates, and the effect was more pronounced in n-tridecane-grown cells. Thus, the fatty acids of this organism are derived chiefly from de novo synthesis rather than from direct incorporation of oxidized hydrocarbons. The extent of direct incorporation increases as the chain length of the hydrocarbon growth substrate is increased.

Full text

Full text is available as a scanned copy of the original print version. Get a printable copy (PDF file) of the complete article (681K), or click on a page image below to browse page by page. Links to PubMed are also available for Selected References.

Selected References

These references are in PubMed. This may not be the complete list of references from this article.

Bird, CW; Molton, P. The biochemical status of metabolites of alkane-utilizing Pseudomonas organisms. Biochem J. 1969 Oct;114(4):881–884. [PubMed]
Bowman, RD; Mumma, RO. The lipids of Phythium ultimum. Biochim Biophys Acta. 1967 Dec 5;144(3):501–510. [PubMed]
Bushnell, LD; Haas, HF. The Utilization of Certain Hydrocarbons by Microorganisms. J Bacteriol. 1941 May;41(5):653–673. [PubMed]
DAVIS, JB. MICROBIAL INCORPORATION OF FATTY ACIDS DERIVED FROM N-ALKANES INTO GLYCERIDES AND WAXES. Appl Microbiol. 1964 May;12:210–214. [PubMed]
Dunlap, KR; Perry, JJ. Effect of substrate on the fatty acid composition of hydrocabon-utilizing microorganisms. J Bacteriol. 1967 Dec;94(6):1919–1923. [PubMed]
Dunlap, KR; Perry, JJ. Effect of Substrate on the Fatty Acid Composition of Hydrocarbon- and Ketone-utilizing Microorganisms. J Bacteriol. 1968 Aug;96(2):318–321. [PubMed]
Edmonds, P. Selection of test organisms for use in evaluating microbial inhibitors in fuel-water systems. Appl Microbiol. 1965 Sep;13(5):823–824. [PubMed]
Edmonds, P; Cooney, JJ. Lipids of Pseudomonas aeruginosa cells grown on hydrocarbons and on trypticase soy broth. J Bacteriol. 1969 Apr;98(1):16–22. [PubMed]
Foppen, FH; Gribanovski-Sassu, O. Lipids produced by Epicoccum nigrum in submerged culture. Biochem J. 1968 Jan;106(1):97–100. [PubMed]
Fredricks, KM. Products of the oxidation of n-decane by Pseudomonas aeruginosa and Mycobacterium rhodochrous. Antonie Van Leeuwenhoek. 1967;33(1):41–48. [PubMed]
Fulk, WK; Shorb, MS. Production of an artifact during methanolysis of lipids by boron trifluoride-methanol. J Lipid Res. 1970 May;11(3):276–277. [PubMed]
Iizuka, H; Lin, HT; Iida, M. Ester formation from n-alkanes by fungi isolated from aircraft fuel. Z Allg Mikrobiol. 1970;10(3):189–196. [PubMed]
Klug, MJ; Markovetz, AJ. Degradation of hydrocarbons by members of the genus Candida. II. Oxidation of n-alkanes and l-alkenes by Candida lipolytica. J Bacteriol. 1967 Jun;93(6):1847–1852. [PubMed]
Koman, V; Betina, V; Baráth, Z. Fatty acid, lipid and cyanein production by Penicillium cyaneum. Arch Mikrobiol. 1969;65(2):172–180. [PubMed]
Makula, R; Finnerty, WR. Microbial assimilation of hydrocarbons. I. Fatty acids derived from normal alkanes. J Bacteriol. 1968 Jun;95(6):2102–2107. [PubMed]
Makula, R; Finnerty, WR. Microbial assimilation of hydrocarbons. II. Fatty acids derived from 1-alkenes. J Bacteriol. 1968 Jun;95(6):2108–2111. [PubMed]
Markovetz, AJ, Jr; Cazin, J; Allen, JE. Assimilation of alkanes and alkenes by fungi. Appl Microbiol. 1968 Mar;16(3):487–489. [PubMed]
MORRISON, WR; SMITH, LM. PREPARATION OF FATTY ACID METHYL ESTERS AND DIMETHYLACETALS FROM LIPIDS WITH BORON FLUORIDE--METHANOL. J Lipid Res. 1964 Oct;5:600–608. [PubMed]
Nyns, EJ; Auquière, JP; Wiaux, AL. Taxonomic value of the property of fungi to assimilate hydrocarbons. Antonie Van Leeuwenhoek. 1968;34(4):441–457. [PubMed]
Rambo, GW; Bean, GA. Fatty acids of the mycelia and conidia of Fusarium oxysporum and Fusarium roseum. Can J Microbiol. 1969 Aug;15(8):967–968. [PubMed]
Ratledge, C. Microbial conversions of n-alkanes to fatty acids: A new attempt to obtain economical microbial fats and fatty acids. Chem Ind. 1970 Jun 27;26:843–854. [PubMed]
Tyrrell, D. The fatty acid composition of four entomogenous imperfect fungi. Can J Microbiol. 1969 Jul;15(7):818–820. [PubMed]