A gas chromatographic-mass spectrometric analysis of the esterifying alcohols of pumpkin seed protochlorophylls

The esterifying alcohols of protochlorophyll a and 4-vinyl-(4-desethyl)-protochlorophyll a (purified as the respective pheophytins) from pumpkin seeds were examined by gas chromatography-mass spectrometry. The results of the analysis suggested that pumpkin seed protochlorophyll a is esterified with all possible C₂₀ isoprenoid alcohols between and including geranylgeraniol and phytol, phytol comprising 90% or more of the mixture of esterifying alcohols, and that the 4-vinyl-(4-desethyl)-protochlorophyll a is esterified with farnesol and all possible C₂₀ isoprenoid alcohols between and including geranylgeranoid and phytanol, phytol comprising 50% or more of the mixture of esterifying alcohols. The 4-vinyl-(4-desethyl)-protochlorophyll a from a sample of older mature pumpkin seeds was found to be richer in esterifying alcohols corresponding to isoprenoid precursors of phytol then was the 4-vinyl-(4-desethyl)-protochlorophyll a from a sample of younger mature seeds. Other isoprenoid alcohols may have been present in very minor quantities in the mixtures of esterifying alcohols from the pumpkin seed protochlorophylls but were not looked for in this study. These results are discussed in terms of a biosynthetic accumulation of 4-vinyl-(4-desethyl)-protochlorophyll a in pumpkin inner seed-coat tissue.     

Production of Wax Esters during Aerobic Growth of Marine Bacteria on Isoprenoid Compounds

This paper describes the production of isoprenoid wax esters during the aerobic degradation of 6,10,14-trimethylpentadecan-2-one and phytol by four bacteria (Acinetobacter sp. strain PHY9, Pseudomonas nautica [IP85/617], Marinobacter sp. strain CAB [DSMZ 11874], and Marinobacter hydrocarbonoclasticus [ATCC 49840]) isolated from the marine environment. Different pathways are proposed to explain the formation of these compounds. In the case of 6,10,14-trimethylpentadecan-2-one, these esters result from the condensation of some acidic and alcoholic metabolites produced during the biodegradation, while phytol constitutes the alcohol moiety of most of the esters produced during growth on this isoprenoid alcohol. The amount of these esters formed increased considerably in N-limited cultures, in which the ammonium concentration corresponds to conditions often found in marine sediments. This suggests that the bacterial formation of isoprenoid wax esters might be favored in such environments. Although conflicting evidence exists regarding the stability of these esters in sediments, it seems likely that, under some conditions, bacterial esterification can enhance the preservation potential of labile compounds such as phytol.     

Squalenes,phytanes and other isoprenoids as major neutral lipids of methanogenic and thermoacidophilic “archaebacteria”

Summary The neutral lipids of nine species of methanogenic bacteria including five methanobacilli, two methanococci, a methanospirillum, one methanosarcina as well as two thermoacidophilic bacteria, Thermoplasma and Sulfolobus, were analyzed. The major components were C₃₀, C₂₅ and/or C₂₀ acyclic isoprenoid hydrocarbons with a continuous range of hydroisoprenoid homologues. The range of acyclic isoprenoids detected were from C₁₄ to C₃₀. Apart fromMetbanosarcina barkeri, squalene and/or hydrosqualene derivatives were the predominant components in all species studied. The components ofMetbanosarcina barkeri were a family of C₂₅ homologues. The distribution of the neutral lipid components and their specItIc variations in relative intensities emphasized the differences between the test organisms while the generic nature of the isoprenoid hydrocarbons demonstrated similarities between the diverse bacteria.The neutral lipid compositions from these bacteria, many of which exist in evironmental conditions like those described for the various evolutionary stages of the archean ecology, resemble the isoprenoid distribution isolated from ancient sediments and petroleum. Therefore, these findings may have major implications to biological and biogeochemical evolution.     

The independence of photosynthesis and aerobiosis from sterol biosynthesis in bacteria

Sterols were present in neither of two representative species of photosynthetic bacteria, Rhodopseudomonas spheroides and Chromatium vinosum. These organisms were grown under conditions commonly viewed as anaerobic. However, such conditions did not prevent Saccharomyces cerevisiae from biosynthesizing sterols, although they did induce accumulation of both 4,4-dimethyl and 4-desmethyl intermediates. Since the photosynthetic organisms did not biosynthesize sterols, bacterial photosynthesis must not be mated genetically or functionally to sterol biosynthesis. In contrast to what the literature records, Escherichia coli, grown under fully aerobic conditions, also failed to contain sterols which indicates that bacterial aerobiosis does not necessarily imply either the presence of sterol biosynthesis or a requirement for an exogenous source of sterols. Among the lipids of E. coli was a substance with the formula C₁₆H₃₂O₂ which moved in silica gel TLC at a rate similar to that of sterols and may have been a keto-alcohol of the same formula already isolated from coliforms. In the photosynthetic bacteria the major neutral lipid after saponification was phytol, in agreement with expectation based on the presence of bacteriochlorophyll-a.     

Lipid Metabolism of Rumen Ciliates and Bacteria: II. Uptake of Fatty Acids and Lipid Analysis of Isotrichia intestinalis and Rumen Bacteria with Further Information on Entodinium simplex

The total lipid and free fatty acid contents of Isotricha intestinalis, Entodinium simplex, and the rumen bacterial flora of the respective protozoa were determined. Warburg manometric data showed that the sodium salts of tributyrin, oleic, and acetic acids stimulated gas production in I. intestinalis, whereas tributyrin was stimulatory with E. simplex and less active with oleic and acetic acids. Rumen bacteria provided fatty acids produced lower manometric gaseous increases when compared with the protozoa. Volatile fatty acids were produced by I. intestinalis and rumen bacteria with tributyrin, but not with tripalmitin. Sodium oleate gave little volatile fatty acid response with I. intestinalis or rumen bacteria. Washed suspensions of I. intestinalis and rumen bacteria concentrated C¹⁴-labeled oleic, palmitic, stearic, and linoleic acids within the cells during short incubation periods. Autoradiographs demonstrated the conversion of C¹⁴-labeled oleic, palmitic, stearic, linoleic, and acetic acids in the rumen protozoa and bacterial cells.     

Impact of feeding by Arenicola marina (L.) and ageing of faecal material on fatty acid distribution and bacterial community structure in marine sediments: An experimental approach

The fate of ingested eukaryotic photoautotrophic fatty acids during gut transit in the lugworm Arenicola marina (L.) and the influence of A. marina's faeces on the evolution of fatty acid distribution and bacterial community structure in superficial sediments were studied under laboratory conditions. Dead phytoplanktonic cells (food portions) were fed to individual A. marina and subsequently incubated, or allowed to directly incubate in the presence of fresh egesta or non-ingested sediment. Changes in fatty acid composition and genetic structure of bacterial communities during gut transit and/or incubation were monitored using gas-chromatography/mass-spectrometry and a DNA fingerprint approach (RISA), respectively. Results, supported by principal component analyses, suggest that A. marina's feeding activity can directly and indirectly affect the lipid biomarker composition and the bacterial community structure of inhabited sediments. Faecal casts produced from food portions appeared qualitatively enriched in saturated fatty acids relative to (poly)unsaturated ones due, partly, to an increase of some bacterial fatty acids and to the preferential removal of some polyunsaturated fatty acids (PUFAs). The incubation of food portions in the presence of fresh A. marina's egesta (designed to study the indirect impact of feeding by A. marina) induced a significant increase in the concentrations of C₂₀ and C₂₂ polyunsaturated fatty acids (PUFAs), whereas these compounds almost disappeared following direct feeding and subsequent incubation, indicating that some dietary fatty acids may be more accessible to biodegradation following passage through the gut of A. marina. The aforementioned increase in PUFAs was attributed to a bacterial production during incubation, suggesting the presence of PUFA-producing bacteria in the fresh egesta of A. marina. Those bacteria were either enteric bacteria that were released with the egesta or ingested bacteria that have survived gut passage, as suggested by the variations of the bacterial community structure (i.e. RISA profiles) during incubation. The results suggest that aged faeces from A. marina might be, in some circumstances, of relatively high nutritional value to trophic levels which are unable to synthesize essential PUFAs de novo. The presence of PUFA-producing bacteria in guts of marine lugworms deserves further attention.     

Biodegradation of C5-C8 fatty acids and production of aroma volatiles by Myroides sp. ZB35 isolated from activated sludge

In the effluents of a biologically treated wastewater from a heavy oil-refining plant, C₅-C₈ fatty acids including pentanoic acid, hexanoic acid, heptanoic acid, octanoic acid, and 2-methylbutanoic acid are often detected. As these residual fatty acids can cause further air and water pollution, a new Myroides isolate ZB35 from activated sludge was explored to degrade these C₅-C₈ fatty acids in this study. It was found that the biodegradation process involved a lag phase that became prolonged with increasing acyl chain length when the fatty acids were individually fed to this strain. However, when fed as a mixture, the ones with longer acyl chains were found to become more quickly assimilated. The branched 2-methylbutanoic acid was always the last one to be depleted among the five fatty acids under both conditions. Metabolite analysis revealed one possible origin of short chain fatty acids in the biologically treated wastewater. Aroma volatiles including 2-methylbutyl isovalerate, isoamyl 2-methylbutanoate, isoamyl isovalerate, and 2-methylbutyl 2-methylbutanoate were subsequently identified from ZB35 extracts, linking the source of the fruity odor to these esters excreted by Myroides species. To our best knowledge, this is the first finding of these aroma esters in bacteria. From a biotechnological viewpoint, this study has revealed the potential of Myroides species as a promising source of aroma esters attractive for food and fragrance industries.     

Characterization of Benthic Microbial Community Structure by High-Resolution Gas Chromatography of Fatty Acid Methyl Esters

Fatty acids are a widely studied group of lipids of sufficient taxonomic diversity to be useful in defining microbial community structure. The extraordinary resolution of glass capillary gas-liquid chromatography can be utilized to separate and tentatively identify large numbers of fatty acid methyl esters derived from the lipids of estuarine detritus and marine benthic microbiota without the bias of selective methods requiring culture or recovery of the microbes. The gas-liquid chromatographic analyses are both reproducible and highly sensitive, and the recovery of fatty acids is quantitative. The analyses can be automated, and the diagnostic technique of mass spectral fragmentation analysis can be readily applied. Splitless injection on glass capillary gas chromatographic columns detected by mass spectral selective ion monitoring provides an ultrasensitive and definitive monitoring system. Reciprocal mixtures of bacteria and fungi, when extracted and analyzed, showed progressive changes of distinctive fatty acid methyl esters derived from the lipids. By manipulating the environment of an estuarine detrital microbial community with antibiotics and culture conditions, it was possible to produce a community greatly enriched in eucaryotic fungi, as evidenced by scanning electron microscopic morphology. The fatty acid methyl esters from the lipids in the fungus-enriched detritus showed enrichment of the C₁₈ dienoic and the C₁₈ and C₂₀ polyenoic esters. Manipulation of the detrital microbiota that increased the procaryotic population resulted in an absence of large structures typical of fungal mycelia or diatoms, as evidenced by scanning electron microscopy, and a significantly larger proportion of anteiso- and isobranched C₁₅ fatty acid esters, C₁₇ cyclopropane fatty acid esters, and the cis-vaccenic isomer of the C₁₈ monoenoic fatty acid esters. As determined by these techniques, a marine settling community showed greater differences in bacterial as contrasted to microeucaryotic populations when compared with the microbial communities of benthic cores.     

Quantitative assessment of crosstalk between the two isoprenoid biosynthesis pathways in plants by NMR spectroscopy

Plants have been shown to use the mevalonate pathway for the biosynthesis of sterols and triterpenes in the cytoplasm and the recently discovered deoxyxylulose phosphate pathway for the biosynthesis of a variety of hemiterpenes, monoterpenes, diterpenes, as well as for the biosynthesis of carotenoids and the phytol side chain of chlorophyll in plastids. Despite the compartmental separation, at least one terpene precursor can be exchanged between the two pathways. In order to assess quantitatively the crosstalk between the two isoprenoid pathways, [2-¹³C₁]mevalonolactone or [U-¹³C₆]glucose were supplied to cell cultures of Catharanthus roseus grown under illumination or in darkness. Sitosterol, lutein and phytol were isolated and analysed by NMR spectroscopy. The incorporations of exogenous [2-¹³C₁]mevalonolactone were 48% and 7% into the DMAPP and IPP precursors of sitosterol and lutein, respectively. With [U-¹³C₆]glucose as precursor, at least 95% of sitosterol precursors were obtained via the mevalonate pathway, whereas phytol appeared to be biosynthesised via the deoxyxylulose phosphate pathway (approximately 60%) as well via the mevalonate pathway (approximately 40%). The apparent ratios for the contribution of the two pathways depend on the nature of the precursor supplied as well as the nature of the target compound. Thus, crosstalk between the two terpenoid pathways cannot be explained in detail by a simple two compartment model and requires an additional in depth study of complex regulatory mechanisms.     

Carbon and hydrogen isotopic fractionation during lipid biosynthesis in a higher plant (Cryptomeria japonica)

Compound-specific carbon and hydrogen isotopic compositions of lipid biomolecules (n-alkanes, n-alkanoic acids, n-alkanols, sesquiterpenes, diterpenes, phytol, diterpenols and β-sitosterol), extracted from Cryptomeria japonica leaves, were determined in order to understand isotopic fractionations occurring during lipid biosynthesis in this species. All lipid biomolecules were depleted in both ¹³C and D relative to bulk tissue and ambient water, respectively. n-Alkyl lipids associated with the acetogenic pathway were depleted in ¹³C relative to bulk tissue by 2.4-9.9‰ and depleted in D relative to ambient water by 91-152‰. C₁₅- and C₃₀-isoprenoid lipids (sesquiterpenes, squalene and β-sitosterol) associated with the mevalonic-acid pathway are depleted in ¹³C relative to bulk tissue by 1.7-3.1‰ and depleted in D relative to ambient water by 212-238‰. C₂₀-isoprenoid lipids (phytol and diterpenoids) associated with the non-mevalonic-acid pathway were depleted in ¹³C relative to bulk tissue by 4.6-5.9‰ and depleted in D relative to ambient water by 238-303‰. Phytol was significantly depleted in D by amounts up to 65‰ relative to other C₂₀ isoprenoid lipids. The acetogenic, mevalonic-acid and non-mevalonic-acid pathways were clearly discriminated using a cross-plot between the carbon and hydrogen isotopic fractionations.     

Poly-extremotolerant bacterium isolated from reverse osmosis reject: an implication toward waste water management

We demonstrate the tolerance of bacterial strain SM2014 to various unsustainable conditions and suggest its implication in waste water management. Its sustainability to reverse osmosis pressure (2.1 MPa) during desalination, and survival percentage of 73 % under hyperbaric conditions (pressure tension of 3.1 MPa under absolute oxygen atmosphere) confirmed its pressure tolerance. The growth of this strain at pH 9 or 10 and at 60 °C alone or in combination revealed its unique physiology as poly-extremotolerant strain. As an adaptive mechanism, the ratio of saturated to unsaturated fatty acids changed with growth conditions. Under poly-extreme condition long chain saturated fatty acid (C_18:0, C_16:0, C_14:0, C_12:0) predominated at the expense of unsaturated fatty acids. The nucleotide BLAST of 16S rRNA gene sequence of strain SM2014 with the NCBI gene bank sequences showed its close identity to Bacillus licheniformis with a similarity match of 94 %. The secretion of industrially valuable enzymes proteinase, lipase and amylase under such harsh conditions further signified potential of this strain as a source of extremozymes. Its unique characteristics underscore its relevance in waste water management.     

Production of a Polyunsaturated Isoprenoid Wax Ester during Aerobic Metabolism of Squalene by Marinobacter squalenivorans sp. nov.

This paper describes the production of 5,9,13-trimethyltetradeca-4E,8E,12-trienyl-5,9,13-trimethyltetradeca-4E,8E,12-trienoate during the aerobic degradation of squalene by a Marinobacter strain, 2Asq64, isolated from the marine environment. A pathway involving initial cleavage of the C₁₀-C₁₁ or C₁₄-C₁₅ double bonds of the squalene molecule is proposed to explain the formation of this polyunsaturated isoprenoid wax ester. The isoprenoid wax ester content reached 1.1% of the degraded squalene at the mid-exponential growth phase and then decreased during the stationary phase. The wax ester content increased by approximately threefold in N-limited cultures, in which the ammonium concentration corresponds to conditions often found in marine sediments. This suggests that the bacterial formation of isoprenoid wax esters might be favored in such environments. The bacterial strain is then characterized as a member of a new species, for which we propose the name Marinobacter squalenivorans sp. nov.     

Organic acid production from CO2/H2 and CO/H2 by mixed-culture anaerobes

The gases CO, CO₂, and H₂ were used as substrates in anaerobic fermentations producing organic acids. Various mixed bacterial sources were used, including sewage sludge digester effluent, rabbit feces, and soil. Nonsterile microorganism selection was carried out using CO₂/H₂ and CO/H₂ as the primary carbon and energy sources. Cultures were grown in specially designed, high-pressure (to 70 psig) flasks. Methanogenic bacteria were eliminated from the cultures. Liquid products of the fermentations were acetic through caproic acids, with the even-numbered acids predominating. Carbon balances showed conclusively that acetic acid was formed from carbon contained in the CO or CO₂ feed gas. Measurements made included rates of acid product formation, cell density, and degree of gas utilization. Limited characterization of the microorganisms was also performed. Production of organic acids by mixed culture inocula from CO₂/H₂ or CO/H₂ had not been reported previously. Application of this work is to the production of organic chemicals from synthesis gas (SNG), produced by the gasification of fossil fuels (peat, lignite, and various ranks of coals), biomass (agricultural and forest residues, and various biomass crops grown expressly for energy recovery), and municipal solid waste.     

Differences in lipid composition between free-living and initially adhered cells of a Gram-negative bacterium

The phospholipid fatty acid composition and poly--hydroxybutyrate (PHB) content of initially adhered and free-living cells of a Pseudomonas sp. isolated from the rape plant Brassica napus were examined with gas chromatography (GC). Five different adhesion experiments were made including variations in surface charge (hydrophilic and lipophilic), temperature, media composition and time of adhesion. Lipids and poly--hydroxybutyrate (PHB) were extracted with a chloroform-methanol-water mixture, hydrolyzed and esterified with pentafluorobenzyl bromide. Analysis was performed with capillary gas chromatography and flame ionization detection. A pronounced difference in both the ratio saturated/unsaturated fatty acids and in PHB content between free-living and adhered bacteria were found. The free-living bacteria has a significantly smaller ratio of saturated/unsaturated C₁₆ and C₁₈ fatty acids and also a smaller ratio of total C₁₈/total C₁₆ fatty acids. Bacteria adhered to the lipophilic surface had a higher ratio of saturated to unsaturated C₁₆ fatty acids than at the hydrophilic surface. There were no major differences between the treatments regarding the amount of bacteria adhered to the surface or their lipid composition.     

Fractionation of Carbon Isotopes during Biogenesis of Atmospheric Isoprene

The stable carbon isotope composition of isoprene emitted from leaves of red oak (Quercus rubra L.) was measured. Isoprene was depleted in ¹³C relative to carbon recently fixed by photosynthesis. The difference in isotope composition between recently fixed carbon and emitted isoprene was independent of the isotopic composition of the source CO₂. β-Carotene, an isoprenoid plant constituent, was depleted in ¹³C relative to whole leaf carbon to the same degree as isoprene, but fatty acids were more depleted. Isoprene emitted from leaves fed abscisic acid was much less depleted in ¹³C than was isoprene emitted from unstressed leaves. We conclude that isoprene is made from an isoprenoid precursor that is derived from acetyl-CoA made from recent photosynthate. The carbon isotope composition of isoprene in the atmosphere is likely to be slightly more negative (less ¹³C) than C₃ plant material but when plants are stressed the isotopic composition could vary.     

Conversion of coconut oil to methyl ketones by two Aspergillus species

Isolates of Aspergillus ruber and A. repens have been grown on coconut oil as the sole carbon source in shake culture. Methyl ketones (C₅-C₁₃) were isolated by solvent extraction and analysed by combined gas chromatography and mass spectrometry. 2-Undecanone was the main volatile product reflecting the high concentration of dodecanoic acid in the original coconut oil. The reactivity of the individual short chain fatty acids as substrates for production of methyl ketones would appear to decrease with increasing molecular weight of the acid after taking into account the greater volatility of the lower molecular weight homologues. 2-Hexanone and 2-octanone were produced by all isolates in low concentration (< 1%). Nonanoic acid and 2-heptanone were converted into 2-octanone. Low concentrations of secondary alcohols were formed under aerobic conditions. It is suggested that the production of methyl ketones by partial β-oxidation is too closely related to mainstream metabolism to be of use in the biochemical taxonomy of the genus.     

Changes in molecular species composition of nocardomycolic acids in nocardia rubra by the growth temperature

Nocardomycolic acids from Nocardia rubra were fully separated and characterized by a combination of argentation thin-layer chromatography and gas chromatography — mass spectrometry (GCMS). The occurrence of 20 or more different molecular species of mycolic acids was demonstrated. GCMS analysis of each subclass of mycolic acids after separation on AgNO₃ thin-layer chromatography revealed that in general the major species consisted of the even-carbon mycolic acids ranging from C₃₈ to C₅₂. However, the most abundant species differed by the subclasses; C₄₄ being in saturated, C₄₆ in monoenoic and C₄₆ in dienoic mycolic acids, respectively. All these acids were shown to possess C₁₂ or C₁₄ alkyl branch at 2 position, while double bonds were located in longer straight chain alkyl unit.By using this method, distinctive changes in mycolic acid composition by growth temperature were observed. The ratios of saturated, monoenoic to dienoic mycolic acids in a mixture of certain carbon numbered mycolic acids varied greatly, according to the shift of growth temperature. The mass fragmentographic analysis, monitoring M-15 ions derived from the loss of methyl group from the molecular ions showed the lower temperature (15°C) grown cells contained more unsaturated (especially dienoic) mycolic acids, while the higher temperature (40°C) grown cells contained more saturated mycolic acids in both extractable and cell-wall bound lipids. These changes in mycolic acid composition occurred shortly after shifting up the growth temperature from 20°C to 43°C at a logarithmic stage of the bacterial growth.     

Bacterial Degradation of N-Lauroyl-L-valine

Studies were conducted on the degradation of N-lauroyl-L-valine by type cultured bacteria. Many strains could utilize sodium N-lauroyl-L-valinate as carbon and nitrogen sources for their growth. Metabolism of N-lauroyl-L-valine was investigated in detail using Ps. aeruginosa AJ2116. Laurie acid was identified by gas chromatography suggesting cleavage of N-acyl linkage in N-lauroyl-L-valine.

Laurie acid might be metabolized to capric acid (C₁₀) and caprylic acid (C₈) becuase the accumulated substances gave nearly identical peaks with those of authentic fatty acids on gas chromatograms. The experiment using N-lauroyl-L-valine (¹⁴C) indicated that ¹⁴CO₂ was produced as a final product. Valine was not detected because it might be metabolized very rapidly immediately after its release.

It was supposed that the enzymes or enzyme systems degrading N-lauroyl-L-valine might be constitutive from the experiment using two kinds of cells grown in the medium containing N-lauroyl-L-valine or nutrient broth.     

Paleoecology of Neoproterozoic hypersaline environments: Biomarker evidence for haloarchaea,methanogens, and cyanobacteria

While numerous studies have examined modern hypersaline ecosystems, their equivalents in the geologic past, particularly in the Precambrian, are poorly understood. In this study, biomarkers from ~820 million year (Ma)‐old evaporites from the Gillen Formation of the mid‐Neoproterozoic Bitter Springs Group, central Australia, are investigated to elucidate the antiquity and paleoecology of halophiles. The sediments were composed of alternating laminae of dolomitized microbial mats and up to 90% anhydrite. Solvent extraction of these samples yielded thermally well‐preserved hydrocarbon biomarkers. The regularly branched C₂₅ isoprenoid 2,6,10,14,18‐pentamethylicosane, the tail‐to‐tail linked C₃₀ isoprenoid squalane, and breakdown products of the head‐to‐head linked C₄₀ isoprenoid biphytane, were particularly abundant in the most anhydrite‐rich sediments and mark the oldest current evidence for halophilic archaea. Linear correlations between isoprenoid concentrations (normalized to n‐alkanes) and the anhydrite/dolomite ratio reveal microbial consortia that fluctuated with changing salinity levels. Halophilic archaea were the dominant organisms during periods of high salinity and gypsum precipitation, while bacteria were prevalent during stages of carbonate formation. The irregularly branched C₂₅ isoprenoid 2,6,10,15,19‐pentamethylicosane (PMI), with a central tail‐to‐tail link, was also abundant during periods of elevated salinity, highlighting the activity of methanogens. By contrast, the irregularly branched C₂₀ isoprenoid 2,6,11,15‐tetramethylhexadecane (crocetane) was more common in dolomite‐rich facies, revealing that an alternate group of archaea was active during less saline periods. Elevated concentrations of isotopically depleted heptadecane (n‐C₁₇) revealed the presence of cyanobacteria under all salinity regimes. The combination of biomarkers in the mid‐Neoproterozoic Gillen Formation resembles lipid compositions from modern hypersaline cyanobacterial mats, pointing to a community composition that remained broadly constant since at least the Neoproterozoic. However, as a major contrast to most modern hypersaline environments, the Gillen evaporites did not yield any evidence for algae or other eukaryotes.     

Simultaneous capillary gas chromatographic profiling of medium- and long-chain fatty acid methyl esters with split injection: Correction for injection-related discrimination by the ‘bracketing’ method

Split injection-related discrimination can be a source of inaccuracy and imprecision in quantitative capillary gas chromatographic profiling methods for compounds with relatively big differences in boiling points, such as the methyl esters of medium- and long-chain fatty acids prepared from biological materials. We systematically investigated a standard containing equal masses of saturated fatty acid methyl esters, with chain lengths from C₅ to C₂₆, under different injection conditions, including injection temperature, sample volume and split ratio. Day-to-day performance was studied under one set of conditions. Normalized peak areas, reciprocal response factors, using either C₁₇ or C₂₃ as an internal standard, and ‘bracketed’ reciprocal response factors (peak area of each analyte divided by half the sum of the peak areas of two adjacent esters were calculated. In all experiments the bracketed reciprocal response factors were found to be closest to unity with the lowest coefficients of variation.