Identification and quantification of biosurfactants produced by the marine bacterium Alcanivorax borkumensis by hyphenated techniques.

A novel biosurfactant was discovered to be synthesized by the marine bacterium Alcanivorax borkumensis in 1992. This bacterium is abundant in marine environments affected by oil spills, where it helps to degrade alkanes and, under such conditions, produces a glycine-glucolipid biosurfactant. The biosurfactant enhances the bacterium's attachment to oil droplets and facilitates the uptake of hydrocarbons. Due to its useful properties expected, there is interest in the biotechnological production of this biosurfactant. To support this effort analytically, a method combining reversed-phase high-performance liquid chromatography (HPLC) with high-resolution mass spectrometry (HRMS) was developed, allowing the separation and identification of glycine-glucolipid congeners. Accurate mass, retention time, and characteristic fragmentation pattern were utilized for species assignment. In addition, charged-aerosol detection (CAD) was employed to enable absolute quantification without authentic standards. The methodology was used to investigate the glycine-glucolipid production by A. borkumensis SK2 using different carbon sources. Mass spectrometry allowed us to identify congeners with varying chain lengths (C6-C12) and degrees of unsaturation (0-1 double bonds) in the incorporated 3-hydroxy-alkanoic acids, some previously unknown. Quantification using CAD revealed that the titer was approximately twice as high when grown with hexadecane as with pyruvate (49 mg/L versus 22 mg/L). The main congener for both carbon sources was glc-40:0-gly, accounting for 64% with pyruvate and 85% with hexadecane as sole carbon source. With the here presented analytical suit, complex and varying glycolipids can be identified, characterized, and quantified, as here exemplarily shown for the interesting glycine-glucolipid of A. borkumensis.

Hyphenation of supercritical fluid chromatography with different detection methods for identification and quantification of liamocin biosurfactants.

Liamocins are a class of biosurfactants with growing interest. However, methods for identification and quantification of liamocins on the molecular level are lagging behind. Therefore, we developed a chromatographic separation based on supercritical fluid chromatography (SFC) for liamocins and structurally related exophilins. The different congeners could be separated on a charge modulated hydroxyethyl amide functionalized silica-based column. Coupling to high-resolution mass spectrometry (MS) revealed four exophilin species and four liamocin species with mannitol and arabitol as polyol head group in a sample of the yeast-like fungus Aureobasidium pullulans (A. pullulans). In contrast to a recently published reversed phase high-performance liquid chromatography (HPLC) method, the different subclasses (exophilins, mannitol liamocins and arabitol liamocins) were additionally separated by means of SFC. The structures were confirmed by their accurate masses and tandem mass spectrometry (MS/MS). A complementary quantification method was developed using SFC coupled to charged-aerosol detection (CAD) to overcome the disadvantages of quantification by means of MS without authentic standards. A flow compensation by varying the make-up flow was used to obtain a constant composition of the mobile phase during detection and to ensure a stable detector response. The concentrations of the individual liamocin species were determined using an external calibration with n-octyl-ß-d-glycopyranoside. The total amount of these concentrations agrees with the dry weight of an aliquot of the heavy oil. The developed SFC-based method has the advantage of shorter analysis time and superior selectivity compared to the previously published LC separation. In brief, the here presented SFC hyphenations enable comprehensive analysis of liamocin biosurfactants providing identification and absolute quantification of individual congeners.