Biostimulation of n-Alkane Degradation in Diesel Fuel-Spiked Soils

Nutrient enhancement of bioremediation with nitrogen, namely biostimulation, increases process performance. Selection of a proper nitrogen source is critical for bioremediation applications. In this study, the effects of different nitrogen sources on biodegradation of C₁₀–C₂₅ n-alkane compounds in diesel fuel-spiked soil were revealed, and the most appropriate nitrogen source for biodegradation of semi- and non-volatile n-alkanes was investigated. Bioremediation of diesel fuel contaminated soil was monitored in lab-scale reactors for 15 days. Ammonium sulfate, potassium nitrate and urea were used as nitrogen sources. Carbon dioxide and oxygen levels in the reactors were recorded to monitor microbiological activity. Contaminant removal process was investigated by pH, heterotrophic plate count, total petroleum hydrocarbons (TPH) and C₁₀–C₂₅ n-alkane analyses. First-order kinetic constants were calculated via respirometric and contaminant concentration data. According to total C₁₀–C₂₅ n-alkane removal levels and degradation rate constants, ammonium sulfate addition resulted in the most efficient contaminant removal followed by potassium nitrate and urea. Simultaneous degradation of individual n-alkanes was observed for all of the nitrogen sources. Urea addition changed the distribution of individual n-alkane concentrations relative to the pre-experimental concentrations. Nitrogen source type had no differential effect on degradation rates of semi- (C₁₀–C₁₆) and non-volatile (C₁₇–C₂₅) fractions.     

Utilization of normal alkanes by yeasts

A stable mixed yeast culture designated as Culture 4, consisting of Candida intermedia and Candida lipolytica was investigated. The culture was judged stable based on uniformity of fermentation results and the nearly constant ratio of the two organisms at the completion of fermentations. However, the ratio of the two organisms at different times during the fermentation was not determined. The mixed culture grew more rapidly on n-alkanes than did C. intermedia; C. lipolytica did not grow on unsupplemented mineral salt–n-alkane medium. Solid n-alkanes were dissolved in 2,6,0,14-tetramethylpentadecane (pristane) for investigation as carbon sources. With Culture 4, on n-alkanes ranging from pentadecane (C₁₅) through octacosane (C₂₈), cell yields were 74.2–89.5%; generation times were 3.0–8.0 hr. during the exponential growth phase. The fastest growth rates and highest cell yields were obtained with docosane (C₂₂) as substrate. The cells obtained contained 6.75–8.81% nitrogen and 1.9–13.4% lipid. Crude protein yields were 34.4–47.6%. The oxidation of n-alkanes by C. intermedia was studied manometrically with resting whole cells. The alkaneoxidizing system of this organism appears to be constitutive and nonspecific for alkane substrates.     

Production of fatty acids and lipid by a Candida sp. growing on a fraction of n-alkanes predominating in tridecane

A Candida sp. was grown on a fraction of n-alkanes (dodecane 22%, tridecane 48%, tetradecane 28%) as sole carbon source. The growth rate was increased most markedly by using high concentrations of n-alkanes (16.7% v/v). When grown in a 5 liter fermentor, the yeast reached its highest yield (60 g. of cell dry wt/l) with a concomitant high yield of fatty acids (21 g of fatty acids/l), by using a nitrogen-deficient medium. To achieve good growth, it was essential to use an inoculum (1 part into 10) of rapidly growing cells and beneficial to increase the agitation rate gradually once growth had begun. After 108 hr maximum conversions of substrate to product were: 71.5% (w/w) for alkanes into cells and 24.8% (w/w) for alkanes into fatty acids. Of the, total fatty acids at the end of the fat-accumulating phase of growth 54% were shorter in chain length than palmitic acid (C₁₆H₃₂O₂). When grown on glucose, as sole carbon source, less than 2% of the total fatty acids were shorter than palmitic acid. When n-alkanes were added to cells growing on glucose, short-chain fatty acids (C₁₀ to C₁₄) were synthesized immediately, indicating a derepressed enzyme system for hydrocarbon assimilation and the absence of diauxie. The production of these acids was at the apparent sacrifice of linoleic acid synthesis. In spite of the high conversion ratios, it is concluded that it would be uneconomical to produce fatty acids, even expensive ones such as lauric acid, by microbial transformation of n-alkanes.     

A Hypothetical Cyclic Pathway for the Metabolism of Odd-carbon n-Alkanes or Propionyl-CoA via Seven-carbon Tricarboxylic Acids in Yeasts

An extensive study has been undertaken to elucidate the physiological significance of threo-D_s-2-methylisocitric acid produced mainly from odd-carbon n-alkanes by a mutant strain of Candida lipolytica. The mutant strain showed slower growth responses to odd-carbon n-alkanes, especially of shorter chain-length, and failed to utilize this acid as sole carbon source, whereas the parent strain and many other yeasts tested were able to utilize this acid. About one half of yeasts tested accumulated this acid extracellularly. Under a thiamine-deficient condition, amounts of pyruvate produced by the parent strain from odd-carbon n-alkanes were ten times as large as those from even-carbon n-alkanes. A scheme for the partial oxidation of propionyl-CoA to pyruvate via C₇-tricarboxylic acid by yeasts was supposed. This scheme may offer suggestion on the metabolism of propionyl-CoA by other living organisms. A hypothetical pathway of citrate accumulation from odd-carbon n-alkane was also presented.     

Effects of Chain-length of Alkane Substrate on Fatty Acid Composition and Biosynthetic Pathway in Some Candida Yeasts

Cellular fatty acid compositions of Candida tropicalis pK 233 and Candida lipolytica NRRL Y -6795 and the time-course changes during yeast growth were studied using individual n-alkanes of various chain lengths (from C₁₁ to C₁₈) and a mixture of n-alkanes (C₁₁ to C₁₈) as a sole carbon source. Observed relationships of the chain-length of n-alkane substrate to time-course changes and final patterns of the fatty acid compositions of these yeasts, especially those of the cells grown on odd-carbon alkanes, indicated that “intact incorporation mechanism,” that is, accumulation of the fatty acid having the same chain-length as that of the alkane substrate used was predominant in the yeasts cultivated on a longer alkane such as n-heptadecane and n-octadecane. On the other hand, “chain elongation pathway” and “de novo synthesis pathway” following β-oxidation of substrate were simultaneously operative in the cells growing on a relatively shorter alkane such as undecane and dodecane.     

Fatty Acid Compositions of Triglyceride and Phospholipid from Candida tropicalis Grown on n-Alkanes

The content of total cellular lipid of Candida tropicalis grown on a mixture of n-alkanes (C₁₀–C₁₈) was about 20% of the dry cell weight at the exponential growth phase and 14% at the early stationary phase. Phospholipid corresponded to approximately 70 % of the total lipid independent of the growth phases. The composition of cellular lipid classes did not change significantly during the growth. On the other hand, a drastic time-course change in fatty acid composition was observed. The proportion of odd-chain fatty acids, one of the most specific cellular components of the yeast grown on the n-alkane mixture, increased in both phospholipid and triglyceride along with the yeast growth. In the meantime, the proportion of polyunsaturated fatty acids varied markedly during the course of cultivation, showing a peak at the early growth phase. The high content of polyunsaturated fatty acids at the early stages of growth correlated to the contents of these acids in phospholipid rather than in triglyceride.     

Utilization of n-alkanes by a newly isolated strain of Acinetobacter venetianus: the role of two AlkB-type alkane hydroxylases

A bacterial strain capable of utilizing n-alkanes with chain lengths ranging from decane (C₁₀H₂₂) to tetracontane (C₄₀H₈₂) as a sole carbon source was isolated using a system for screening microorganisms able to grow on paraffin (mixed long-chain n-alkanes). The isolate, identified according to its 16S rRNA sequence as Acinetobacter venetianus, was designated A. venetianus 6A2. Two DNA fragments encoding parts of AlkB-type alkane hydroxylase homologues, designated alkMa and alkMb, were polymerase chain reaction-amplified from the genome of A. venetianus 6A2. To study the roles of these two alkM paralogues in n-alkane utilization in A. venetianus 6A2, we constructed alkMa, alkMb, and alkMa/alkMb disruption mutants. Studies on the growth patterns of the disruption mutants using n-alkanes with different chain lengths as sole carbon source demonstrated central roles for the alkMa and alkMb genes in utilization of C10 to C18 n-alkanes. Comparative analysis of these patterns also suggested different substrate preferences for AlkMa and AlkMb in n-alkane utilization. Because both single and double mutants were able to grow on n-alkanes with chain lengths of C20 and longer, we concluded that yet another enzyme(s) for the utilization of these n-alkanes must exist in A. venetianus 6A2.     

Leaf wax <Emphasis Type="Italic">n</Emphasis>-alkane chemotaxonomy of bamboo from a tropical rain forest in Southwest China

The leaf waxes of 23 woody bamboo species of three subgenera, Dendrocalamus, Bambusa and Dendrocalamopsis, from the Xishuangbanna tropical rain forest in Southwest China were analyzed by gas chromatography and coupled gas chromatography–mass spectrometry. The waxes of the Dendrocalamus species are dominated by C₂₇ and C₂₉ n-alkanes and their average chain length (ACL) has an average of 28.3. In marked contrast to the Dendrocalamus species, the wax composition of the Bambusa species is characterized by a broad distribution of major n-alkanes from C₂₇ to C₃₅, greater ACL values (>29) and an enhanced relative abundance (>30%) of n-alkanes with a carbon number greater than 30. Unlike the Dendrocalamus species and the Bambusa species, the Dendrocalamopsis species do not have a distinct n-alkane distribution; in some species the n-alkane distribution is comparable to that in the Bambusa species and in others to that in the Dendrocalamus species. The lipid data suggest that it might be reasonable to classify the controversial Dendrocalamopsis group as an independent genus separate from the Bambusa genus. On the basis of their smaller diversity of the dominant n-alkanes and their lower ACL values, the Dendrocalamus species might be more evolutionarily advanced than the Bambusa species, with the Dendrocalamopsis species being at an intermediate stage. The evolution and classification of the woody bamboos inferred from leaf wax n-alkanes are consistent with morphological investigations reported previously.     

Microbial Production of Long-chain Dicarboxylic Acids from n-Alkanes

Strain M-l which was derived from Candida cloacae 310 as a mutant unable to assimilate dicarboxylic acid (DC) produced large amount of DCs from n-alkanes, as expected. It produced DCs with the same number of carbon atoms as those of n-alkanes used (9 to 18 carbon atoms). Among DCs produced, n-tetradecane ω,φ′-dicarboxylic acid (DC-16) from n-hexadecane (n-C₁₆) was most abundantly accumulated and the highest level of DC-16, i.e., 29.3g/liter was obtained by resting cells.

On the other hand, since the growth rate of strain M-l on n-alkane markedly decreased in comparison with that of the parent strain, other carbon source which supported the growth of strain M-l was necessary for the production of DC from n-alkane by growing cells. When acetic acid was used as carbon source for the growth in DC-16 production from n-C₁₆, the highest level of DC-16, i.e., 21.8 g/liter was obtained ofter 3 days' cultivation.     

Microbial Incorporation of Fatty Acids Derived From n-Alkanes Into Glycerides and Waxes

When n-alkanes with 13 to 20 carbon atoms were fed to a Nocardia closely related to N. salmonicolor, the produced cellular triglycerides and aliphatic waxes invariably contained fatty acids with an even or an odd number of carbon atoms subject to this feature of the n-alkane substrate. Beta-oxidation and C₂ addition are both operative, as evidenced by the spectra of fatty acids incorporated into the cellular lipid components. There is no distinction in the rate of microbial incorporation of the odd-or even-numbered carbon chains. The fatty acids are apparently directly derived from the long chain n-alkanes, rather than synthesized via the classic C₂-condensation route. The alcohol component of waxes produced by the Nocardia is invariably of the same chain length as the n-alkane substrate.     

Microbial Production of Long-chain Dicarboxylic Acids from n-Alkanes

Microorganisms which produced n-alkane ω,ω′-dicarboxylic acid (DC) from n-alkane were selected from natural sources. It was found that the best three producers thus obtained belonged to yeast. All of the stock cultures which are able to assimilate n-alkane and are belonged to genus Candida and Pichia were also found to produce DC from n-alkane.

Candida cloacae 310, a representative strain selected from natural source, was able to produce DCs having 5 to 16 carbon atoms from various n-alkanes. Among them, DCs with 5 to 9 carbon atoms were more heavily accumulated than those with more than 9, except those with the same number of carbon atoms as the substrates which were the main products from the substrates with less than 15 carbon atoms. It was also clearly demonstrated that DCs with odd carbons alone were produced from n-alkanes with odd carbons, while DCs with even carbons alone from n-alkanes with even carbons.

Then, cultural conditions of Candida cloacae 310 were studied for the production of DC-12 from n-dodecane (n-C₁₂) which showed the highest yield among the observed accumulation.

Under the optimum conditions, 2.28 g/liter of DC-12 was obtained together with 1.86 g/liter of DC-6 and 0.82 g/liter of DC-8 after 72 hr’ cultivation in a synthetic medium containing 100 ml of n-C₁₂ per liter.     

Utilization of gas oil by a yeast culture

A mixed yeast culture (Culture 4) was grown on representative gas oil samples as well as paraffin wax. Culture 4 was found to utilize n-paraffinic hydrocarbons almost quantitatively from most gas oil fractions; significant alteration of other hydrocarbon components was not detected. Generation times of 4.0–9.0hr. were typical during the exponential growth phase in fermentations with various gas oil fractions. Cell yields were 70–90% based on n-paraffin utilization. The culture appeared to exhibit maximum efficiency of n-alkane removal in the C₁₉ to C₂₄ range. The cells recovered from the fermentations contained 8.8–9.3% nitrogen. Paraffin wax also served as a suitable carbon source when dissolved in 2,6,10,14-tertramethylpentadecane (pristane). However, substrate utilization appeared to be incomplete.     

Corecovery of lipids and fermentable sugars from Rhodosporidium toruloides using ionic liquid cosolvents: Application of recycle to batch fermentation

This work evaluates the ability of an ionic liquid‐methanol cosolvent system to extract lipids and recycle fermentable sugars recovered from oil‐bearing Rhodosporidium toruloides grown in batch culture on defined media using glucose and xylose as carbon sources. Growth on the recycled mixed carbon substrate was successful with glucose consumed before xylose and overall cell mass to lipid yields (Y_P/X) between 57% and 61% (w/w relative to whole dried cell mass) achieved. Enzymatic hydrolysis of the delipified carbohydrate fraction recovered approximately 9%–11% (w/w) of the whole dried cell mass as fermentable sugars, which were successfully recycled as carbon sources without further purification. In total, up to 70% (w/w) of the whole dried cell mass was recovered as lipids and fermentable sugars and the substrate to lipid yields (Y_P/S) was increased from 0.12 to 0.16 g lipid/g carbohydrate consumed, highlighting the promise of this approach to process lipid bearing cell biomass. © 2014 American Institute of Chemical Engineers Biotechnol. Prog., 30:1239–1242, 2014     

Precession-forced changes in South West African vegetation during Marine Isotope Stages 101–100 (2.56–2.51 Ma)

The intensification of Northern Hemisphere Glaciation (iNHG) is one of the critical climate thresholds in the Cenozoic. This study focuses on marine sediments recovered from Marine Isotope Stages 101/100 at the Ocean Drilling Program Site 1083 to assesses the impact of the iNHG on continental southern African vegetation through n-alkane (straight-chain hydrocarbon) abundance and δ¹³C values. The n-alkane abundance data yield a convoluted signal due to the number of controlling factors such as the source area, transportation routes and vegetation type. The C₃₁ n-alkane δ¹³C values, however, exhibit a cyclic pattern with a periodicity of c. 20 ka, and are not correlated to the abundance data. It is inferred that the signal does not represent a change in the geographical source of n-alkanes. Instead, we suggest that the variations are caused by water-stress-induced changes in either carbon isotope fractionation during C₃ photosynthesis or subtle changes in the proportion of C₃ and C₄ plants. These changes, unlike variations in oceanographic proxies, closely track precessional forcing factors and are independent of the prevailing obliquity-forced glacial/interglacial cycles. We conclude that the varying monsoon strength, rather than pCO₂ or temperature change, forced changes in southern African vegetation during this period.     

Isolation and Identification of n-Butane-assimilating Bacterium

A bacterial strain capable of assimilating gaseous n-alkanes was newly isolated from activated sludge by enrichment culture technique using n-butane as the sole carbon source. The strain was identified as Pseudomonas butanovora sp. nov. It utilised n-alkanes of C₂~C₉, primary alcohols and carboxylic acids for growth, but did not utilize sugars and C₁ compounds. The cell yields on gaseous n-alkanes, such as ethane, propane and n-butane, were 80% or more. The maximum specific growth rate on n-butane was 0.22 hr^?1 at 30°C, pH 7.0. Dried cells of this new isolate grown on n-butane contained 73% pure protein.     

Aliphatic Hydrocarbons of Cladosporium resinae Cultured on Glucose,Glutamic Acid,and Hydrocarbons

The carbon source markedly influenced the qualitative and quantitative composition of cellular hydrocarbons in Cladosporium resinae. Total lipid and hydrocarbon content was greater in cells grown on n-alkanes than in cells grown on glucose or glutamic acid. Glucose-grown cells contained a spectrum of aliphatic hydrocarbons from C₇ to C₃₆; pristane and n-hexadecane comprised 98% of the total. Cells grown on glutamic acid contained C₇ to C₂₃ hydrocarbons; n-tridecane, n-tetradecane, n-hexadecane, and pristane made up 74% of the total. n-Decane-grown cells yielded C₈ to C₃₂ compounds, and n-hexadecane (96%) was the major hydrocarbon. Cells grown on individual n-alkanes from C₁₁ to C₁₅ all contained C₁₁ to C₂₈ hydrocarbons, and cells grown on n-hexadecane contained C₁₁ to C₃₂ hydrocarbons. In n-undecane-grown cells, n-hexadecane and pristane made up 92% of the total, but in cells grown on C₁₂ to C₁₆ n-alkanes the major cellular hydrocarbon was the one on which the cells were grown. This suggests that cells cultured on n-alkanes of C₁₂ or longer accumulate n-alkanes prior to oxidizing them.     

Cellular lipid accumulation by Pseudomonas aeruginosa 44T1

Summary Growth of Pseudomonas aeruginosa strain 44T1 on glucose, an n-alkane mixture or olive oil was characterized by the formation of intracellular lipid inclusions and extracellular accumulation of rhamnolipids. Maximum values of cellular lipid accumulation were obtained in olive-oil-grown cells and reached up to 38% w/w of its dry biomass. The principal fatty acids of cellular lipids drived from P. aeruginosa cultures varied with the carbon source employed. The major fatty acids detected were palmitic and trans-oleic acids. Arachidonic acid was only found in medium containing glucose or the n-alkane mixture. Offprint requests to: A. Manresa     

Degradation of Car Engine Base Oil by Rhodococcus sp. NDKK48 and Gordonia sp. NDKY76A

Two microorganisms (NDKK48 and NDKY76A) that degrade long-chain cyclic alkanes (c-alkanes) were isolated from soil samples. Strains NDKK48 and NDKY76A were identified as Rhodococcus sp. and Gordonia sp., respectively. Both strains used not only normal alkane (n-alkane) but also c-alkane as a sole carbon and energy source, and the strains degraded more than 27% of car engine base oil (1% addition).     

A preliminary reconstruction of the paleoecological and paleoclimatic history of the Chinese Loess Plateau from the application of biomarkers

This study provides a preliminary reconstruction of paleoecological and paleoclimatic history over the central Chinese Loess Plateau (CLP) during the last 8.1 Ma based on biomarker records from the earliest of the Chaona stratigraphic section. Throughout the section, we found variations in n-alkane and n-alkan-2-one distributions and dramatic changes in six other biomarker proxies: 1) n-alkanes (C₂₇ + C₂₉)/(C₃₁ + C₃₃) ratios, 2) n-alkanes C₂₇/C₃₁ ratios, 3) CPI (carbon preference index) values for CPI_(H)ALK, 4) values for CPI_(H)KET, 5) n-alkane mean chain lengths ACL-ALK, and 6) n-alkan-2-ones C₂₉/C₃₁ ratios. The C₂₉ n-alkanes dominate the red clay sediments with little variability, indicating that trees dominated the CLP and that the climate was relatively stable and less variable during the 8.1–2.6 Ma period. In contrast, the C₃₁ n-alkanes dominate the loess–paleosol sediments, and biomarkers vary with relatively greater amplitude and higher frequency, indicating that grasses dominated the CLP and the climate was more arid and variable. These biomarker records chronicle a drying and cooling trend on the CLP since 4 Ma. These records can be further divided into four stages with boundaries around 5.6, 3.8 and 2.6 Ma, indicating that the CLP vegetation and climate experienced four evolutionary phases, broadly consistent with those inferred from other available proxy data.