Surfactant production by the Rhodococcus erythropolis sH-5 bacterium grown on various carbon sources

It has been shown that the Rhodococcus erythropolis sH-5 strain can produce surfactants associated and not associated with the cell wall. Their content depends on medium composition, the nature of the carbon source, and oxygen supply. The highest biosurfactant (bioSF) yield is achieved by growing R. erythropolis sH-5 in medium with 2% kerosene at neutral pH. It has been found that the bioSF yield and emulsification index for various hydrocarbons depend on the kind of the nitrogen source used by the bacterium, increasing with replacement of KNO₃ by NaNO₃. The yields of biomass and bioSF in R. erythropolis depend on growth temperatures (max at 30°C) but not on water quality (bidistillate, catholyte, or anolyte). It has been found that sH-5 produces more cell-associated bioSF than extracellular species.     

Pleomorphy of a budding bacterium on various carbon sources

Pleomorphy inHyphomicrobium T37 was manipulated by the use of different carbon (C₁) sources. Growth on methanol medium is characterized by the classical morphology as found inH. vulgare cells, accompanied by some cellular pleomorphy in the form of dichotomous lobing. Extensive cellular and colonial pleomorphy was observed on media containing methylamine.We thank Mrs. P. M. Scarborough and Mrs. J. Hardy for technical assistance.     

True cellulase production by Clostridium thermocellum grown on different carbon sources

Summary Clostridium thermocellum produced different levels of true cellulase (Avicelase) depending on the carbon source used for growth. In defined medium with fructose, the cellulase titer was seven times higher than with cells growing on cellobiose and four times higher than cells growing with glucose. During the lag phase on fructose, the differences were even more dramatic, i.e. 60 times higher than in cells growing on cellobiose and 40 times that of cells lagging or growing in glucose. In an attempt to detect factors that might contribute to these differences, we considered intracellular ATP, chemical potential (pH), electrical potential (Y), proton motive force (p), growth rate, and rates of uptake of inorganic phosphate and sugars. We noted a direct correlation between cellulase production and intracellular ATP levels and an inverse relationship of cellulase production with Y and p values. It thus appears that cellulase is best produced by cells high in ATP and low in Dp and its electrical component DY. There was no obvious relationship between the cellulase titer and the other parameters. Although the physiological significance of such correlations is unknown, the data suggest that further investigation is warranted.     

Production of surfactants by Rhodococcus erythropolis strain EK-1, grown on hydrophilic and hydrophobic substrates

The ability of Rhodococcus erythropolis strain EK-1 to produce surfactants when grown on hydrophilic (ethanol and glucose) and hydrophobic (liquid paraffins and hexadecane) substrates was studied. The strain was found to produce surfactants with emulsifying and surface-active properties. The production of surfactants depended on the composition of the nutritive medium, nature and concentration of the sources of carbon and nitrogen, and duration of cultivation. Chemically, surfactants produced by Rhodococcus erythropolis EK-1 grown on ethanol are a complex of lipids with polysaccharide-proteinaceous substances. The lipids include glycolipids (trehalose mono- and dicorynomycolates) and common lipids (cetyl alcohol, palmitic acid, methyl n-pentadecanoate, triglycerides, and mycolic acids).     

An unusual formaldehyde oxidizing system in Rhodococcus erythropolis grown on compounds containing methyl groups

Abstract During utilization of compounds containing methyl groups, the non-methylotrophic bacteria Rhodococcus erythropolis oxidized the methyl groups entirely to carbon dioxide. This oxidation was linked to the presence of an NAD-dependent formaldehyde dehydrogenase activity which was lost on dialysis. The activity could be restored by the addition of boiled extract but not by adding the known cofactors glutathione or tetrahydrofolate.
A further dehydrogenase activity with formaldehyde as substrate was found in ethanolgrown cells. This activity could be differentiated from that in methyl group metabolizing cells.     

Influence of the glycolipid-producing bacterium Rhodococcus erythropolis on the degradation of a hydrocarbon mixture by an original soil population

Summary The purpose of this investigation was to show whether or no employing a starter culture of the bacterium Rhodococcus erythropolis that produces 6,6-trehalosedicorynomycolates could replace the addition of purified biosurfactant known to accelerate hydrocarbon degradation by an original soil population in a stirred reactor. The rate of degradation, degree of elimination of hydrocarbons, mineralization and degree of oxidation were determined in order to assess the extent of degradation. In comparison with degradation by soil microorganisms only an acceleration of utilization of the hydrocarbons was observed in cultivations of growing cells of R. erythropolis, although the effect of purified trehalosedicorynomycolates is not reached. Except for a higher degree of oxidation a sufficient amount of trehalosedicorynomycolates bound to autoclaved biomass of R. erythropolis does not have any effect.     

An oil-degrading bacterium: Rhodococcus erythropolis strain 3C-9 and its biosurfactants

AIMS: To isolate a biosurfactant-producing bacterium and find new products within its culture. METHODS AND RESULTS: A biosurfactant-producing bacterium identified as Rhodococcus erythropolis (3C-9 strain) was isolated from seaside soil. When n-hexadecane was supplied as the sole carbon source, two types of biosurfactants (free fatty acids and glycolipids) were detected in the supernatant of the bacterial culture by use of thin layer chromatography (TLC). Gas chromatography-mass spectrometry (GC-MS) analysis revealed that the former consisted of at least 12 free fatty acids of chain lengths from C(9) to C(22); and the latter contained 2 kinds of glycolipids (a glucolipid and a trehalose lipid), which were detected by use of TLC, as well as GC-MS. The hydrophobic moieties of both glycolipids consisted of seven types of straight-chain fatty acids of varying compositions, with chain lengths ranging from C(10) to C(18). It was also noted that biosurfactants of strain 3C-9 were produced in a manner that was growth-related and cannot be synthesized from water-soluble substrates. The effects to enhance the solubility of polycyclic aromatic hydrocarbons and the degradation rate of hexadecane were also tested. CONCLUSIONS: The biosurfactants produced by strain 3C-9 of R. erythropolis included two kinds of glycolipids, as well as free fatty acids. These biosurfactants were notably different from those of previously reported Rhodococcus species, both in terms of their structure and chemical composition. SIGNIFICANCE AND IMPACT OF THE STUDY: Strain 3C-9 of R. erythropolis is a competitive candidate for use in oil spill cleanup operations, or in new biosurfactant exploration. The findings in this report show that Rhodococcus is a natural reservoir of new biosurfactants.     

Studies on utilization of acetonitrile by Rhodococcus erythropolis A10

A petrochemical wastewater isolate, capable of utilizing high concentrations of acetonitrile and acetamide as the sole source of carbon and nitrogen was identified as Rhodococcus erythropolis A10. Cell-free extracts of acetonitrile-grown cells exhibited activities corresponding to nitrile hydratase (EC 4.2.1.84) and amidase (EC 3.5.1.4), which mediate the two-step breakdown of acetonitrile into acetic acid and ammonia. Studies indicated that both these enzymes in R. erythropolis A10 are intracellular, inducible and capable of hydrolysing a wide range of nitriles, including simple (acetonitrile, propionitrile), branched-chain (isobutyronitrile) and dinitrile (succinonitrile). The specific activity of the amidase was found to be several-fold higher than nitrile hydratase.     

Kinetics of the degradation of aliphatic hydrocarbons by the bacteria Rhodococcus ruber and Rhodococcus erythropolis

Consumption of aliphatic hydrocarbons by the bacteria Rhodococcus ruber Ac-1513-D and Rhodococcus erythropolis Ac-1514-D grown on mixed n-alkanes and diesel fuel was studied. Consumption of diesel fuel hydrocarbons by the strains was less intense in comparison with the n-alkane mixture. The strains showed differences in growth rate and consumption of the substrates, which suggests that they possess different mechanisms of hydrocarbon uptake.     

Kinetics of the degradation of aliphatic hydrocarbons by the bacteria Rhodococcus ruber and Rhodococcus erythropolis

Consumption of aliphatic hydrocarbons by the bacteria Rhodococcus ruber Ac-1513-D and Rhodococcus erythropolis Ac-1514-D grown on mixed n-alkanes and diesel fuel was studied. Consumption of diesel fuel hydrocarbons by the strains was less intense in comparison with the n-alkane mixture. The strains showed differences in growth rate and consumption of the substrates, which suggests that they possess different mechanisms of hydrocarbon uptake.     

Enhanced anaerobic succinic acid production by Escherichia coli NZN111 aerobically grown on gluconeogenic carbon sources

Escherichia coli strain NZN111, a pflB and ldhA double mutant of E. coli W1485, is considered a candidate of succinic acid producer. However, it is reported that this strain fails to ferment glucose anaerobically. In this study, it was demonstrated that when a gluconeogenic carbon source was used to replace glucose in aerobic culture, the NZN111 cells restored the ability to ferment glucose in the subsequent anaerobic culture with succinic acid as the major product even though no further genetic manipulation had been carried out. Activities of enzymes including phosphoenolpyruvate (PEP) carboxykinase, PEP carboxylase, isocitrate lyase, malate dehydrogenase, malic enzyme, and pyruvate kinase in the NZN111 cells aerobically grown on different carbon sources were measured, and enhanced anaplerotic and oxaloacetate-reducing activities were revealed. Furthermore, supply of MgCO₃ or NaHCO₃ greatly improved succinate production by the malate-grown NZN111 cells. At the same time, pyruvic acid production was significantly reduced. When the malate-grown cells were anaerobically cultured in a salt medium with high pH buffering capacity, succinic acid was produced at a specific productivity of 308 mg/(g DCW h) with a molar yield of 1.31 mol succinic acid/mol glucose.     

Adenylate level in the mycelium of Penicillium nigricans Thom. grown on various carbon sources]

Concentrations of ATP and ADP and their dynamics during cultivation (2, 5, 9 and 13 days) of a highly productive strains of P. nigricans on a mineral medium in the presence of various carbon sources, such as glucose, succinate or acetate were studied. It was shown that the levels of ATP and ADP in the mycelium depended on the carbon source: the maximum and minimum ATP concentrations were found on the glucose and acetate media respectively, the maximum and minimum ADP concentrations showed inverse dependence. The concentrations of both adenylates on the same carbon source depended on the strain. The dynamics of the adenylates levels during cultivation showed an analogous dependence on the carbon source and the strain. Thus, the highly productive strain was characterized by a constant ATP level on glucose and succinate and variation on acetate, while the ADP level was characterized by a decrease by the 9th day of cultivation on any of the carbon sources. The low productive strain was characterized by variations in the level of ATP in any media used, stability of the ADP level by the 2nd--9th day of cultivation on the glucose medium and by the 2nd--5th day of cultivation on the succinate medium and a decrease by the 9th day of cultivation on the acetate and succinate media. The ratio of ATP/ADP at the phase of griseofulvin biosynthesis (9 days) markedly increased in both the strains when cultivated on the media with any of the carbon sources.     

Production of a Bioflocculant by Rhodococcus erythropolis S-1 Grown on Alcohols

Rhodococcus erythropolis strain S-1, which was isolated from soil, produces a bioflocculant. We have found that alcohols are useful carbon sources for its flocculant production. Ethanol was best for flocculant production and culture time. The bioflocculant produced on ethanol medium flocculated a wide range of suspended soils, alkaline and acid.     

Improvement of desulfurization activity in Rhodococcus erythropolis KA2-5-1 by genetic engineering

Rhodococcus erythropolis KA2-5-1 can desulfurize dibenzothiophene (DBT) into 2-hydroxybiphenyl. A cryptic plasmid, pRC4, which was derived from R. rhodochrous IFO3338, was combined with an Escherichia coli vector to construct an E. coli-Rhodococcus shuttle vector. The complete nucleotide sequence of 2582-bp pRC4 was analyzed. Based on the characteristics of its putative replication genes, pRC4 was assigned to the family of pAL5000-related replicons. The desulfurization gene cluster, dszABC, and the related reductase gene, dszD, cloned from KA2-5-1, were reintroduced into KA2-5-1 and efficiently expressed. The DBT desulfurization ability of the transformant carrying two dszABC clusters and one dszD on the vector was about 4-fold higher than that of the parent strain, and the transformant also showed improved desulfurization activity for light gas oil (LGO). Sulfur components in LGO before and after the reaction were analyzed with gas chromatography-atomic emission detection.