Petroleum bioremediation — a multiphase problem

Microbial degradation of hydrocarbons is a multiphase reaction, involving oxygen gas, water-insoluble hydrocarbons, water, dissolved salts and microorganisms. The fact that the first step in hydrocarbon catabolism involves a membrane-bound oxygenase makes it essential for microorganisms to come into direct contact with the hydrocarbon substrate. Growth then proceeds on the hydrocarbon/water interface. Bacteria have developed two general strategies for enhancing contact with water-insoluble hydrocarbons: specific adhesion mechanisms and production of extracellular emulsifying agents. Since petroleum is a complex mixture of many different classes of hydrocarbons, of which any particular microorganism has the potential to degrade only part, it follows that the microorganisms must also have a mechanism for desorbing from used' oil droplets.The major limitations in bioremediation of hydrocarbon-contaminated water and soil is available sources of nitrogen and phosphorus. The usual sources of these materials, e.g. ammonium sulfate and phosphate salts, have a high water solubility which reduces their effectiveness in open systems because of rapid dilution. We have attempted to overcome this problem by the use of a new controlled-release, hydrophobic fertilizer, F-1, which is a modified urea-formaldehyde polymer containing 18% N and 10% P as P₂O₅. Microorganisms were obtained by enrichment culture that could grow on crude oil as the carbon and energy source and F-1 as the nitrogen and phosphorus source. The microorganisms and the F-1 adhered to the oil/water interface, as observed microscopically and by the fact that degradation proceeded even when the water phase was removed and replaced seven times with unsupplemented water — a simulated open system. Strains which can use F-1 contain a cell-bound, inducible enzyme which depolymerizes F-1.After optimizing conditions in the laboratory for the use of F-1 and the selected bacteria for degrading crude oil, a field trial was performed on an oil contaminated sandy beach between Haifa and Acre, Israel, in the summer of 1992. The sand was treated with 5 g F-1 per kg sand and inoculated with the selected bacteria; the plot was watered with sea water and plowed daily. After 28 days the average hydrocarbon content of the sand decreased from 5.1 mg per g sand to 0.6 mg per g sand. Overall, there was an approx. 86% degradation of pentane extractables as demonstrated by dry weight, I.R. and GLC analyses. An untreated control plot showed only a 15% decrease in hydrocarbons. During the winter of 1992, the entire beach (approx. 200 tons of crude oil) was cleaned using the F-1 bacteria technology. The rate of degradation was 0.06 mg g^-1 sand day^-1 (10°C) compared to 0.13 mg g^-1 sand day^-1 during the summer (25°C).     

Cleanup standards for petroleum hydrocarbons. Part 1. Review of methods and recent developments

Many states across the U.S. use the total petroleum hydrocarbon (TPH) measurement as a regulatory tool for setting cleanup standards for underground storage tank sites and other petroleum‐related sites requiring cleanup. In Part I of this article, alternative techniques for developing site‐specific cleanup standards for petroleum hydrocarbons are reviewed, including the use of chemical fingerprinting, constituent analysis, and risk assessment methods that address hydrocarbons found in the environment. New developments in standard setting for petroleum hydrocarbons are described, including risk‐based standards for hydrocarbon mixtures and ecological risk‐based approaches. In Part 2 of this article, the cost‐effectiveness and accuracy of the most commonly used of these approaches will be evaluated by comparing a generic TPH cleanup standards approach with site‐specific cleanup standards approaches for two actual sites in Washington State, a neighborhood gas station and a former bulk fuel storage facility.     

On‐site bioremediation treatment system design and on‐site analytical screening of hydrocarbon‐contaminated dredge sediments

In early 1991, a petroleum refining facility located on the Blair Waterway in Commencement Bay near Tacoma, Washington, wished to deepen its berthing facility. Sediments had accumulated in the berthing area adjacent to the facility's petroleum handling dock to the extent that tanker ships could go aground during low tides. A preliminary sediment characterization program had indicated that elevated polynuclear aromatic hydrocarbons such as anthracene and phenanthrene, and total petroleum hydrocarbons exceeded Puget Sound Dredge Disposal Analysis maximum level guidelines for unconfined, open‐water disposal. Enviros designated an on‐shore sediment treatment facility to receive the dredged sediments. Design criteria and construction details of a treatment area capable of accommodating 8000 yd³ of sediments are presented. Onsite, real‐time sediment analysis for total petroleum hydrocarbon (TPH) concentrations was conducted by an onsite mobile laboratory. Laboratory techniques to expedite sediment analysis for TPH using infrared spectrophotometry are described.     

Biodegradation of Petroleum Tar by Pseudomonas Spp. From Oil Field of Assam,India

ABSTRACT

Petroleum tar produced during the processing of crude oil is one of the earth's major pollutants. The potential of certain soil bacteria in the biodegradation of petroleum tar was assessed to develop an active indigenous bacterial consortium for bioremediation of petroleum tar–polluted sites of Assam, India. In vitro enrichment cultures of five Pseudomonas spp. were found to metabolize petroleum tar. The Fourier transform infrared (FTIR) analyses of the enrichment cultures revealed the presence of the functional groups, viz., –OH, –CHO, C?O, and –COOH, which provided evidence for the biodegradation of petroleum tar. Further, gas chromatography–flame ionization detection (GC-FID) analyses revealed complete degradation of low-molecular-weight hydrocarbons, and the subsequent appearance of some additional peaks reflected the formation of intermediate metabolites during the degradation of petroleum tar. A mixed culture with 0.1% Tween 80 as a surfactant exhibited almost complete degradation in contrast to the degradation by the mixed culture without Tween 80. This confirmed the effect of a surfactant for acceleration of the biodegradation process of petroleum tar.     

Analysis for petroleum products in marine environments

Petroleum is composed of a complex mixture of hydrocarbons that readily undergo chemical and biological conversions on entering aquatic environments. These conversions lead to the formation of a host of oxygenated products, some of which are potentially toxic to marine life and to the consumer of fishery products. State-of-the-art analytical methods, as employed in our laboratories, utilize glass-capillary gas chromatography in conjunction with mass spectrometry to analyze environmental samples containing trace amounts of aliphatic and aromatic petroleum hydrocarbons. These procedures are applied on a routine basis to the analysis of seawater, sediments and tissues of marine organisms. Despite this analytical proficiency, a need exists for analyzing oxygenated and other polar petroleum products in environmental samples. For example, techniques such as high-performance liquid chromatography (HPLC), in conjunction with on-line fluorometric assay techniques and mass spectrometry, make possible the analysis of polar oxygenated compounds resulting from both chemical and biological conversions. These methodologies are first steps toward the development of routine assay procedures for environmental samples. Current techniques for hydrocarbon analyses and new methods for analyzing polar aromatic compounds are discussed.     

辽河油田土壤石油污染及其微生物群落特征

本研究采取辽河油田曙光采油厂、欢喜岭采油厂和锦州采油厂井场周边土壤,并以未污染稻田土壤作为对照,分析了各采样点的土壤理化性质、石油烃浓度组成及土壤微生物群落结构。结果表明: 1) 3个采油厂井场周边土壤均受到严重的石油烃污染,但其石油烃浓度及组成存在一定的差异,曙光和欢喜岭采油厂土壤石油烃平均浓度是锦州采油厂的2倍以上;曙光采油厂土壤中胶质沥青质含量最高,而欢喜岭和锦州采油厂土壤中烷烃含量最高,比例均在40%以上。2)与稻田土壤相比,锦州采油厂土壤微生物操作分类单元(OTU)、Chao1指数和Shannon指数升高,而其在曙光和欢喜岭采油厂土壤中降低;各采油厂土壤样品中存在相同的优势菌门及菌属,但丰度存在较大差异。锦州采油厂土壤中分枝杆菌属、假单胞菌属的丰度高,曙光采油厂土壤中鞘氨醇单胞菌属、类诺卡氏菌属、马赛菌属的丰度高,而欢喜岭采油厂土壤中溶杆菌属、硫杆菌属、假节杆菌属的丰度高。3)相关分析表明,鞘氨醇单胞菌属、类诺卡氏菌属、硫杆菌属、马赛菌属、假节杆菌属与总石油烃、总有机碳和胶质沥青质含量呈显著正相关,分枝杆菌属、溶杆菌属、假单胞菌属与总氮和总磷呈显著正相关。本研究系统分析了不同采油厂土壤中石油烃、土壤理化性质和微生物群落特征,揭示了辽河油田污染土壤中特定的优势菌属和群落结构,为辽河油田石油烃污染土壤修复功能微生物筛选及修复过程菌群构建提供理论依据,也为其他油田高效降解菌筛选提供了方法借鉴。     

Cleanup standards for petroleum hydrocarbons. part 2. Case study comparisons of site‐specific cleanup standards with generic TPH standards

Many states across the U.S. use the total petroleum hydrocarbon (TPH) measurement as a regulatory tool for setting cleanup standards for underground storage tank sites and other petroleum‐related sites requiring cleanup. In Part 1 of this article (Michelsen and Petito Boyce, J. Soil Contam., 2(2): 109–124), alternative techniques and new methods for developing site‐specific cleanup standards for petroleum hydrocarbons were reviewed, including the use of chemical fingerprinting, constituent analysis, and human health and ecological risk assessment methods. In Part 2 of this article, the cost effectiveness and accuracy of these approaches are evaluated by comparing a generic TPH cleanup standards approach with site‐specific cleanup standards approaches for two actual sites in Washington State, a neighborhood gas station and a former bulk fuel storage facility. Based on these case studies, as well as consideration of other available approaches discussed in Part 1 of this article, recommendations are provided for selecting the most appropriate method of developing cleanup standards at a petroleum‐contaminated site.     

Effects of amendments on biodegradation of crude petroleum by sediment bacteria from Bonny River Estuary

The biodegradation of Bonny light crude petroleum by bacteria in batch culture was enhanced by the addition to culture media, of 0.2 mg of urea and soya bean lecithin per 100 ml of crude oil, sediment and water mixture. Biodegradation was found to be purely an aerobic process. There was a direct relationship between hydrocarbon content and proportion (%) of total heterotrophic count that was capable of growing on crude petroleum as sole carbon and energy source.     

Use of Rice Husk as Bulking Agent in Bioremediation of Automobile Gas Oil Impinged Agricultural Soil

Evaluation of rice husk (RH) as bulking agent in bioremediation of automobile gas oil (AGO) hydrocarbon polluted agricultural soil using renewal by enhanced natural attenuation (RENA) as control was the subject of the present investigation. The effect of different parameters such as total petroleum hydrocarbon (TPH), dehydrogenase activity (DHA), optical density and pH on bioremediation performance were evaluated. The studied parameters such as microbial dynamics, percentage degradation and DHA were found to be higher in RH-amended system and differed significantly with control at P < 0.05. RH resulted in high removal efficiency of 97.85 ± 0.93% under a two-month incubation period, while RENA had lesser removal efficiency of 53.15 ± 3.81%. Overall hydrocarbon biodegradation proceeded very slowly in the RENA particularly from week 0 to 4. Experimental data perfectly fitted into the first-order kinetic and generated high r² values (0.945), first-order degradation constant (0.47 day^?1), and shorter degradation half-life (1.50 d)—t_1/2 = Ln2/K and Ln2 numerically equals to 0.693 and hence written as 0.693/K. Micrococcus luteus and Rhizopus arrhizus were isolated in the present study, which displayed extreme AGO hydrocarbon biodegradative abilities. The use of RH in hydrocarbon-polluted soil significantly increased biodegradation rate and resulted in effective AGO cleanup within 2 months period. Therefore, RH provides an alternative source of bioremediation material in field application for abundant petroleum hydrocarbon soil pollution.     

气态烃诱导下油气微生物数量及功能基因变化特征

【目的】烃类渗漏是地球化学循环中的自然垂直运移现象。油气微生物勘探技术就是通过检测油气微生物在烃类渗漏条件下形成的异常特征进而预测下伏油气藏。然而,上浮烃类比重小,使得油气微生物丰度小,缺乏对油气藏地表烃类与油气微生物的深入认识。【方法】本研究在人工模拟环境下,采用培养法和定量PCR对油气微生物数量和油气功能基因的变化特征进行研究。【结果】人工模拟的不同渗漏环境,在一定的驯化培养周期下分别考察甲烷氧化菌和丁烷氧化菌数量变化特征,甲烷氧化菌与丁烷氧化菌在不同烃源中呈现不同的发育情况;同时,在气态烃高浓度阳性对照和微渗漏条件下,油气指示基因pmo A与bom X基因丰度呈现增长现象,然而经过吹脱实验基因丰度仍能指示出曾经发育的油气微生物,在油气微生物勘探检测分析时间尺度上精度高于数量水平的检测。【结论】本研究考察了土壤中油气微生物的数量和功能基因变化特征,为烃类渗漏与油气微生物之间的相关性研究奠定了基础,为油气微生物勘探提供直接实验依据。     

Environmental fate of the chemical mixtures: Crude oil,JP‐5, mineral spirits,and diesel fuel

Petroleum hydrocarbon mixtures in soils and groundwater present unique challenges in the estimation of potential human exposures and subsequent health risks. A major component of risk assessment affected by mixtures is the evaluation of environmental fate. The fate of petroleum mixtures may be evaluated by using either of three approaches: (1) the evaluation of the fate of indicator chemical(s), (2) the evaluation of the fate of the mixture as a whole with a surrogate, and (3) the evaluation of the fate of the hydrocarbon mixture as a whole. The limiting factor in the selection of an approach is the availability of information on specific chemical constituents in the mixture. The evaluation of environmental fate requires quantitative information regarding the distribution, mobility, and degradation/transformation as represented by various physicochemical properties. In addition to the availability of this information, the selection of the evaluation method should be consistent with the goals of the project, as each approach will produce different results. This presentation discusses the issues related to the identification and implementation of each of the approaches to the evaluation of the environmental fate of four petroleum mixtures (crude oil, JP‐5, mineral spirits, and diesel) for risk assessment purposes.     

The Use of Conocarpus lancifolius Trees for the Remediation of Oil-Contaminated Soils

The role of the Conocarpus lancifolius tree in remediaitng oil-contaminated soil, which was bioremediated using conventional methods, was investigated. The selected tree was used to phytoremediate bioremediated oil-contaminated soil for three successive growing seasons. At the end of the phytoremediation experiment, 85.7% of measurable total petroleum hydrocarbon (TPH) was degraded in Conocarpus lancifolius rhizosphere, and the detectable concentrations of some poly aromatic hydrocarbons (PAHs) were less than 0.02 ppm. A number of hydrocarbon degrading microorganisms (HDMs) were isolated at 35°C under aerobic conditions, and were identified using 16S rRNA gene sequencing and fatty acid methyl ester (FAME) analysis. The efficiency of the isolated HDMs in degrading a mixture of hydrocarbon compounds (HC) was assessed. Among the bacterial isolates, Rhodococcus equi was distinguished from the other isolates because of its efficient degradation of some compounds in the HC mixture.

Samples were also collected from Conocarpus lancifolius vegetative parts and were analyzed for heavy metal and mineral accumulation. The results demonstrated that the Conocarpus lancifolius tree was able to uptake high levels of chromium (Cr), vanadium (V), and nickel (Ni) and accumulate them in the tree's roots. Additionally, Conocarpus trees tolerated high concentration and accumulated several metals in all plant tissues. These metals included aluminum (Al), calcium (Ca) and iron (Fe).     

胜利油田采油区土壤石油污染状况及其微生物群落结构

基于不同开采年代新油井(2011—)和老油井(1966—2003年)周边土壤的调查取样,研究了采油区土壤石油污染状况,利用PCR-DGGE和克隆测序技术,探讨了新、老油井周边土壤微生物的群落结构.结果表明:油井周边土壤均受到不同程度的石油污染,其石油烃含量大多高于土壤石油污染临界值(500 mg·kg^-1),且老油井周边土壤污染水平更高.污染土壤石油烃含量与土壤有机碳、全氮和速效钾含量呈显著正相关.老油井周边土壤微生物群落多样性指数随污染水平的增大而减小,新油井则呈相反的趋势.DGGE图谱优势条带测序结果表明,油井周边土壤均存在明显的优势菌,大多为石油烃相关菌和烃类降解菌,如微杆菌属、链霉菌属、迪茨氏菌属、黄杆菌属及α、γ变形菌等.
     

Human Risk Assessment of Contaminated Soils by Oil Products: Total TPH Content Versus Fraction Approach

Petroleum hydrocarbons may cause risks for humans and the environment that must be properly managed. Some methodologies cluster hundreds of hydrocarbon substances into one single parameter, total petroleum hydrocarbon (TPH) ranged from C10 to C40. Several national policies establish a maximum acceptable concentration in soil to directly consider if a site is seriously contaminated; this scope may be described as a total content approach. Another approach considers TPH division into fractions according to their physico-chemical and toxicological properties, performed in terms of the environmental behavior (aliphatic and aromatic compounds) and the equivalent carbon number (EC). This approach lets us determine the associated risk for human health through the Human Risk Index (HRI). The consequences of application of the total content and fraction approaches is discussed in this study, evaluating the differences in the approach for volatile and semi-volatile hydrocarbons and also in regard to the origin of the contamination. When focusing on volatile substances, the fraction approach is much more restrictive than the total content approach where all oil products are assessed in the same way. When assessing semi-volatile hydrocarbons, their behavior varies depending on the oil product. This work contributes to the implementation of risk-based assessment for petroleum hydrocarbons.     

Surfactant enhances biodegradation of hydrocarbons: Microcosm and field study

The purpose of the present study was to provide new methods that would increase the rates of biodegradation of petroleum hydrocarbons in soil, thus reducing the time required to achieve a satisfactory level of residual hydrocarbon in an ex situ bioremediation. Results of laboratory studies on several techniques were used to guide our implementation of these methods in controlled field studies. Soils contaminated with nonvolatile hydrocarbons were treated with various combinations of (1) an anionic surfactant guanidinium cocoate (CGS), (2) a consortium of hydrocarbon‐degrading microorganisms, (3) a slow‐release form of nitrogen:urea, and (4) the bulking agent vermiculite. Laboratory results describing the activity of CGS have been presented previously (Jain et al., 1992). The amount and rate of hydrocarbon loss in treated soil was compared with hydrocarbon lost in soil that received no amendment other than water (water only). We also used a sheen screen method (Nelson et al., 1995), to assess the effectiveness of our field application of microorganisms.     

小黑麦对石油污染盐碱土壤细菌群落与石油烃降解的影响

为了研究小黑麦对石油污染盐碱土壤中的细菌群落与石油烃降解率的影响,采用高通量测序技术,设置0 g/kg,1 g/kg和5 g/kg三个石油浓度,以未种植小黑麦的土壤作为对照,对6组不同处理的盐碱土壤样品的细菌群落结构及其多样性进行测定,并分析土壤中的石油烃降解率。结果表明:在土壤石油浓度为1 g/kg和5 g/kg时,小黑麦根际土壤中的石油烃降解率相较对照组分别提高了36.67%和33.20%。从6个土壤样品中分别获得21398—27899条测序序列。在石油污染土壤中,小黑麦根际土壤的细菌群落多样性和丰度均大于对照组的土壤。同时,在"门","纲","属"的分类水平上,小黑麦根际土壤细菌群落中的一些根际细菌的相对丰度增加了,主要包括变形菌门(Proteobacteria)、酸杆菌门(Acidobacteria)、γ-变形菌纲(Gammaproteobacteria)、烷烃降解菌科-未命名菌属(Alcanivoracaceae_norank)、黄单胞菌属(Xanthomonas)、亚硝化单胞菌-不可培养菌属(Nitrosomonadaceae_unculture)等。有一些相对丰度增加的根际细菌是以石油及石油分解物为碳源的微生物。本研究证明种植小黑麦改变了石油污染盐碱土壤根际土壤细菌群落结构组成和多样性,促进了降解石油微生物群落的构建,显著提高了盐碱土壤石油污染的降解效果。研究结果为石油污染盐碱土壤的植物修复奠定了理论基础。     

Earthworm-assisted bioremediation of petroleum hydrocarbon–contaminated soils from motorcar mechanic workshops in Ibadan,Oyo State,southwestern Nigeria

Enhanced microbial bioremediation of petroleum hydrocarbon–contaminated (PHC) soils with the earthworm Alma millisoni and the bacterium Bacillus spp. was conducted. The petroleum-contaminated topsoils (PCTS) (0–15 cm) collected from motorcar mechanic workshops were thoroughly mixed, sieved, and air dried for 7 days. The pH, water holding capacity (WHC), total nitrogen (N), organic carbon (OC), heavy metal (HM), and bacteriological analysis of the soil samples were evaluated. The indigenous bacterial isolates were subjected to 1%, 5%, and 50% of spent engine oil (SEO), incubated for 7 days at 37°C, and the isolate with the highest tolerance pattern was used for the remediation. Out of four indigenous bacteria isolated, Bacillus spp. had the highest tolerance to SEO. Preliminary exposure assessments of A. millisoni to PHC soils (100%, 60%, 50%, and 40% PHC) were carried out using 48-h avoidance response, coiling exhibition, swollen clitelium, 14-day survival tests, and antioxidant enzyme activities such as catalase (CAT), superoxide dismutase (SOD), glutathione S-transferase (GST), and glutathione peroxidase (GPx). Subsequently, four treatments of 1 kg soil mixed with 100%, 75%, 50%, and 0% PCTS were designed and spiked with 20 g of dried cow dung. Each of the treatments consisted of four setups, viz., A. millisoni alone, A. millisoni and Bacillus spp., Bacillus spp. alone, and control. The bacterial counts, total petroleum hydrocarbon (TPH), total and bioavailable HM, and total OC and N of the soils were evaluated every 7 days for 35 days. Significant increases in the activities of CAT, SOD, GPx, and GST compared with control were recorded in A. millisoni exposed to the various treatments. Treatment with combined A. millisoni and Bacillus spp. resulted in significant (p < .05) reduction in TPH, reduction in total and bioavailable heavy metals, and increased total OC and N of the soil compared with other treatments. The percentage reduction in TPH and heavy metals with concomitant increase in total OC and total N recorded in the 50% PHC soils followed the order A. millisoni and Bacillus spp. > A. millisoni alone > Bacillus spp. alone. Hence, enhanced bioremediation using A. millisoni and Bacillus spp. may be a good biocatalyst in the remediation of petroleum hydrocarbon–contaminated soils.     

Distribution and biodegradation potential of oil-degrading bacteria in North Eastern Japanese coastal waters

Abstract The distribution of oil-degrading microorganism in samples of surface water and sediment from North Eastern Japanese coastal waters was studied. Modified natural sea water (NSW) agar supplemented with emulsified crude oil (Arabian light, 5 g 1⁻¹) was used to enumerate oil-degrading bacteria. In addition, filtered samples were inoculated into NSW broth containing weathered crude oil. Incubation was carried out at 20°C for 7–10 days. Populations of oil-degrading microorganisms ranged from 3–230 CFU 100 ml⁻¹ in surface waters and 2.9 × 10³ to 1.2 × 10⁵ CFU g⁻ in sediment samples. Analysis of variance showed that oil-degraders were heterogenously distributed. Six mixed populations selected from 20 samples were studied to determine which of the constituent microflora were capable of crude oil biodegradation. Among 51 strains selected for identification, only 61% could be identified which formed 17 different bacterial species. Acinetobacter species (14 strains), Psychrobacter immobilis (9 strains) and Gram-positive cocci (10 strains) were the predominant types. Oil-degrading activity by various mixed populations (three each from water and sediment samples) was determined by using a conventional total weight reduction technique. Reduction in amount of various aliphatic and aromatic hydrocarbon substrates was verified using gas chromatography and high pressure liquid chromatography. Biodegradation of crude oil ranged from 35–58%. One mixed population of the sediment samples degraded more hydrocarbon (both aliphatic and aromatic) and the biodegradation of the aromatic hydrocarbon reached as high as 48%.     

小叶白蜡接种外生菌根真菌对土壤石油烃的降解效果

采用盆栽实验研究了小叶白蜡(Fraxinus sogdiana)接种4种外生菌根真菌(E1-毛边滑锈伞(Hebeloma mesophaeusm)、E2-劣味乳菇(Lactarius insulsns)、E3-松塔牛肝菌(Stro-bilomyces floccopus)和E4-丝膜菌(Cortinarius russus)对沈抚灌区土壤石油烃的降解效果。结果表明:在白蜡不同组合双接种及混合接种中,以混合接种对土壤石油烃的降解效果最好,降解率比对照提高23.6%;其次为双接种中的E1E3和E2E4组合,降解率分别比对照提高21.0%和12.7%。接种外生菌根真菌可促进白蜡生长,尤其可明显提高其根生物量,增加侧根数,接种E1E3、E2E4和混合菌使白蜡侧根数分别增加了100%、67%和81%。相关分析表明,石油烃降解率与白蜡的侧根数呈显著相关,可能是其降解率提高的主要原因。     

A Comparative Study on Biosurfactant Activity of Crude Oil–Degrading Bacteria and Its Correlation to Total Petroleum Hydrocarbon Degradation

In this study, 11 bacteria isolated from Tapis crude oil–contaminated sites were identified by using biochemical tests and 16S rDNA gene sequencing. Their abilities to biodegrade Tapis crude oil was determined by gas chromatography before they were further screened for biosurfactant activity by employing qualitative (blood agar hemolysis, microplate assay, drop-collapse test), semiquantitative (emulsification formation), and quantitative (surface tension measurement) methods. Four isolates, namely, Acinetobacter baumanii UKMP-12T, Pseudomonas aeruginosa UKMP-14T, Rhodococcus sp. UKMP-5T, and Rhodococcus sp. UKMP-7T, exhibited high percentages in total petroleum hydrocarbon (TPH) degradation. A strong correlation between the emulsification index (E ₂₄) and surface tension measurement (r _s = +.866) as shown by Spearman rank correlation analysis suggested that these two methods were more reliable to predict biosurfactant activity. The TPH removal was also positively correlated to the ability of bacterial isolates to reduce the surface tension of growth medium, as revealed by Pearson correlation test (r_p = +.886). In conclusion, not all the biosurfactant detection protocols employed were effective. Nevertheless, the measurement of surface tension and E ₂₄ determination provided a rather rapid, easy, reproducible, and accurate result in identifying bacteria with biosurfactant-producing ability.