Discovery of alkenones with variable methylene‐interrupted double bonds: implications for the biosynthetic pathway

Zheng, Yinsui; Dillon, James; Zhang, Yifan; Huang, Yongsong

doi:10.1111/jpy.12461

Cited by 27 publications

(38 citation statements)

References 42 publications

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“…We recently reported double bond positions of tri-unsaturated alkenone isomers (Dillon et al, 2016;Zheng et al, 2016) by imine derivatization of the alkenone carbonyl group and dimethyl disulfide (DMDS) double bond adduction, using a new gas chromatographic separation method that provides higher selectivity of derivatized alkenones than conventional methods (Longo et al, 2013). In contrast to the OsO 4 oxidation method (de Leeuw et al, 1980;Rontani et al, 2001, DMDS can separately and consecutively bind to individual double bonds in an alkenone molecule (termed DMDS-1), creating products with distinct mass fragments at any given double bond position without significantly decreasing the product volatility (Buser et al, 1983;Dillon et al, 2016).…”

Section: Introductionmentioning

confidence: 99%

“…In contrast to the OsO 4 oxidation method (de Leeuw et al, 1980;Rontani et al, 2001, DMDS can separately and consecutively bind to individual double bonds in an alkenone molecule (termed DMDS-1), creating products with distinct mass fragments at any given double bond position without significantly decreasing the product volatility (Buser et al, 1983;Dillon et al, 2016). To account for fragments that are structurally symmetric (i.e., ions which may be assigned to two different double bond positions on opposite sides of the alkyl chain based on the mass spectra for DMDS adducts), compounds can be further derivatized using cyclobutylimine to arrive at a structurally unique solution (Zheng et al, 2016).…”

Section: Introductionmentioning

confidence: 99%

“…Despite our initial success (Longo et al, 2013;Dillon et al, 2016;Zheng et al, 2016), there are major problems with published procedures for alkenone DMDS adduction. In our experience, applying published DMDS adduction procedures (Francis, 1981;Leonhardt and DeVilbiss, 1985;Yamamoto et al, 1991;Xu et al, 2001;van Soelen et al, 2014;Zhao et al, 2014) to alkenones, has frequently resulted in the lack of alkenone adducts in GC-MS analyses and even the complete absence of the original alkenones (i.e., total sample loss).…”

Section: Introductionmentioning

confidence: 99%

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Optimizing the yield of transient mono-dimethyl disulfide adducts for elucidating double bond positions of long chain alkenones

Richter

Dillon

Rott

et al. 2017

Organic Geochemistry

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Long chain alkenones (LCAs) are among the most successful biomarkers for paleotemperature reconstructions. However, fundamental questions regarding the biosynthesis and cellular functions of alkenones in haptophyte algae remain poorly understood. Recent discoveries of LCAs with double bond positions and chain lengths that differ from common structures further highlight the importance of continued research into structural variations of this important class of lipid biomarkers to improve LCA applications as temperature proxies. Double bond positions on alkyl chains can be effectively determined by preparing mono-double bond adducts with dimethyl disulfide (DMDS-1), and subsequent gas chromatography-mass spectrometry (GC-MS) analysis. However, previously published procedures for adduct preparation were originally designed for mono-unsaturated fatty acids, and generally produce low product yields when applied to alkenones. Here we demonstrate that the problem originates mainly from DMDS and alkenone overreaction at high temperatures and for long time periods, and, secondarily, insufficient amount of iodine catalyst. The overreaction results in DMDS reacting with multiple double bonds, and the possible formation of intermolecular linkages, creating non-volatile products. These products are of little use for elucidating alkenone structures. We demonstrate that by reducing the reaction temperature and time, and by using an optimal amount of iodine, we can maximize the yield of transient DMDS-1 adducts for alkenone structure determination.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Optimizing the yield of transient mono-dimethyl disulfide adducts for elucidating double bond positions of long chain alkenones

Richter

Dillon

Rott

et al. 2017

Organic Geochemistry

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“…The Littorina Sea phase is distinguished from other phases by the presence of the alkenones of shorter chain‐length as well as the absence of tri‐unsaturated isomers and C 39 and C 40 alkenones. The presence of the shorter chain alkenones is an indicator for the presence of Group II haptophytes (Zheng, Dillon, et al, ; Zheng, Huang, et al, ). The final shift in alkenone distribution corresponds to the change from the Littorina Sea into the Modern Baltic phase and represents a mixed Groups II and III signal indicated by the presence of the C 35:2 , C 36:2 , and C 39 ethyl alkenones (Figure ).…”

Section: Resultsmentioning

confidence: 99%

“…These shorter chain alkenones have also appeared in an E. huxleyi culture after being kept in cultivation for a few years (Prahl et al, ). In contrast to the C 37 ‐C 40 alkenones, the C 35 and C 36 are thought to be synthesized from the C 37:2 and C 38:2 , respectively, via β‐oxidation and produced by mutants of Group II species in the natural environment (Zheng, Dillon, et al, ; Zheng, Huang, et al, ). Finally, Group III produce the standard suite of C 37 methyl and C 38 ethyl and methyl alkenones, with low abundance of the C 39 ethyl alkenones in some cases (Longo et al, ).…”

Section: Introductionmentioning

confidence: 99%

Alkenone Distributions and Hydrogen Isotope Ratios Show Changes in Haptophyte Species and Source Water in the Holocene Baltic Sea

Weiss

Massalska

Hennekam

et al. 2020

Geochem Geophys Geosyst

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The Baltic Sea, a dynamic, marginal marine basin, experienced a number of large changes in salinity during the Holocene as a result of fluctuations in global and local sea level related to melting of glacial ice sheets and subsequent isostatic rebound. These changes likely had pronounced effects on the species composition of haptophytes, a common phytoplankton group found in the Baltic Sea. This dynamic environment provides the ideal setting to study how species change impacts distribution and hydrogen isotope ratios of long‐chain alkenones (δ2HC37), haptophyte‐specific biomarkers. Here we analyzed the aforementioned parameters in Holocene sediments covering the contrasting hydrological phases of the Baltic Sea. Alkenone distributions changed with different Baltic Sea salinity phases, suggesting that species shifts coincide with salinity change. δ2HC37 values show two major shifts: one in the middle of the freshwater Ancylus Lake phase (10.6 to 7.7 ka) and a second at the transition from the brackish Littorina Sea phase (7.2 to 3 ka) into the fresher Modern Baltic (3 ka to the present). The first shift represents a significant enrichment of 50‰, which cannot be explained by salinity or species changes only. At this time, the isotopically depleted ice sheets had melted, and only the relatively enriched freshwater source remained. The second shift, coincident with a change in distribution, is likely caused by a change in species composition alone. These findings show that hydrogen isotope ratios of long‐chain alkenones, combined with their relative distribution, can be used to reconstruct changes in source water.

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Unusual Shorter‐Chain C₃₅ and C₃₆ Alkenones from Commercially Grown Isochrysis sp. Microalgae

O’Neil

Gale

Nelson

et al. 2021

J Americ Oil Chem Soc

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Unusual shorter-chain alkenones (C 35 and C 36 ) were the dominant alkenones (rather than C 37 and C 38 ) isolated from commercially grown Tisochrysis lutea microalgae. Structures of the alkenones were determined by analyzing the alkenones and their products following a butenolysis reaction by comprehensive two-dimensional gas chromatography coupled to a high-resolution time-of-flight mass spectrometer (GC × GC-TOF HRMS). The major alkenones were identified as (15E,22E)-heptatriaconta-15,22-dien-2-one and (16E,23E)-octatriaconta-16,23-dien-3-one, similar to one previous finding of abundant shorter-chain alkenones in a culture of Emiliania huxleyi CCMP2758, yet distinguishing them from C 35 and C 36 alkenones extracted from Black Sea sediments with different double bond positions. Our data suggest a possible shared trigger (e.g. nutrient stress) that may occur during cultivation resulting in shorter-chain alkenones from both the aforementioned E. huxleyi and T. lutea. Moreover, for T. lutea, short-chain alkenone biosynthesis can be accompanied by lower alkenone content but higher amounts of valuable docosahexaenoic acid (DHA). These results, therefore, extend beyond alkenones and are important to established and emerging algal oil-based industries.Keywords Isochrysis Á Tisochrysis Á Alkenones Á Omega-3 fatty acids Á Butenolysis Á Comprehensive twodimensional gas chromatography

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Discovery of alkenones with variable methylene‐interrupted double bonds: implications for the biosynthetic pathway

Cited by 27 publications

References 42 publications

Optimizing the yield of transient mono-dimethyl disulfide adducts for elucidating double bond positions of long chain alkenones

Optimizing the yield of transient mono-dimethyl disulfide adducts for elucidating double bond positions of long chain alkenones

Alkenone Distributions and Hydrogen Isotope Ratios Show Changes in Haptophyte Species and Source Water in the Holocene Baltic Sea

Unusual Shorter‐Chain C₃₅ and C₃₆ Alkenones from Commercially Grown Isochrysis sp. Microalgae

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Discovery of alkenones with variable methylene‐interrupted double bonds: implications for the biosynthetic pathway

Cited by 27 publications

References 42 publications

Optimizing the yield of transient mono-dimethyl disulfide adducts for elucidating double bond positions of long chain alkenones

Optimizing the yield of transient mono-dimethyl disulfide adducts for elucidating double bond positions of long chain alkenones

Alkenone Distributions and Hydrogen Isotope Ratios Show Changes in Haptophyte Species and Source Water in the Holocene Baltic Sea

Unusual Shorter‐Chain C35 and C36 Alkenones from Commercially Grown Isochrysis sp. Microalgae

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Unusual Shorter‐Chain C₃₅ and C₃₆ Alkenones from Commercially Grown Isochrysis sp. Microalgae