Biogeosciences www.biogeosciences.net 1726-4170 1726-4189 6 12 2009 10.5194/bg-6-3017-2009 http://www.biogeosciences.net/6/3017/2009/ http://www.biogeosciences.net/6/3017/2009/bg-6-3017-2009.html http://www.biogeosciences.net/6/3017/2009/bg-6-3017-2009.pdf 3017 3034 2009-12-15 Short scale (6 h) temporal variation of sinking fluxes of planktonic and terrigeneous lipids at 200 m in the NW Mediterranean Sea L. Méjanelle laurence.mejanelle@obs-banyuls.fr J. Dachs LOOB, UMR CNRS 7651, Avenue Fontaulé, BP 44, 66650 Banyuls Sur Mer, France Department of Environmental Chemistry, IDAEA, CSIC, 18–24 C/Jordi Girona, 08034 Barcelona, Catalonia, Spain Drifting sediment trap measurements were carried out at high temporal frequency in the northwestern Mediterranean Sea in the course of the DYNAPROC 2 campaign, during the transition between late summer to autumn conditions. Molecular biomarkers were analyzed in selected subsets of consecutive samples collected for 6 h at 200 m depth. Fluxes of <i>n</i>-alkanes, long-chain alkenones, sterols and steroid ketones show high variability between consecutive 6-h samples, comparable in range to seasonal variability. <i>n</i>-Alkane export ranges from 1.4 to 29.7&mu;g m^&minus;2 d^&minus;1, fluxes of C₃₇ alkenones varies from 0 to 14.2 &mu;g m^&minus;2 d^&minus;1. Fluxes of sterols, steroid ketones and C₃₀ alkane diol respectively range from 31 to 377, 2.2 to 46 and 0.3 to 9.3 &mu;g m^&minus;2 d^&minus;1. Biomarker flux ranges are coherent with the relatively low primary production and the low export ratio encountered during the study. Molecular characteristics of biomarker composition is consistent with reworked algal and zooplanktonic organic matter. Lipid biomarker composition points to the dominance of haptophytes over dinoflagellates in the exported material, and to a minor contribution of diatoms and eustigmatophytes. The intrusion of coastal water at the study site was recorded by an enhanced imprint of higher plant <i>n</i>-alkanes. <br><br> Two processes can be responsible for the pulses in biomarker flux: changes in the magnitude of particle flux (dry weight mass flux) and changes in the concentration of biomarkers in the particles. <br><br> Concurrent variability in fluxes, significant Pearson correlations between fluxes of biomarkers of haptophytes, dinoflagellates, eustigmatophytes, zooplankton activity and higher plants (alkenones, dinosterol, alkyl diols, dehydrocholesterol, steroid ketones, <i>p</i><0.01, <i>n</i>=31, suggest that the short term temporal variability of biomarker export fluxes depends primarily on the intensity of particle dry weight flux. Biomarker concentrations vary on a relatively narrower range than biomarker fluxes, indicating that changes in particle composition (due to degradation or change in source apportionment) has a weaker influence on flux variability. Thus, particle aggregation and sinking are key processes to explain the dynamic of biomarker export at a temporal scale of 6 h. None the less, abrupt changes of OC-normalized concentrations of biomarkers, in the time scale of 6 h, indicate that the exported particles composition also show short-time variability. Highest biomarker flux values recorded by the trap samples from 27 to 29 September correspond to highest values of zooplankton biomass integrated between the surface and 200 m. The decrease in primary production after the October wind events is echoed by minima in biomarker flux values. Despite these correspondences, the coupling between primary production and biomarker export is complex. % vor jede Referenz Andersen, V., Goutx, M., Prieur, L., and Dolan, J. R.: Short-scale temporal variability of physical, biological and biogeochemical processes in the NW Mediterranean Sea: an introduction, Biogeosciences, 6, 453–461, 2009. Alves, C., Oliveira, T., Pio, C., Silvestre, A. J. D, Fialho, P., Barata, F., and Legrand, M.: Characterisation of carbonaceous aerosols from the Azorean Island of Terceira, Atmos. Environ., 41, 1359–1373, 2007. Béthoux, J.-P. and Prieur, L.: Hydrologie et circulation en Méditerranée Nord-Occidentale, Pétroles et Techniques, 299, 25–34, 1983. Bligh, E. G. and Dyer, W. J.: A rapid method of total lipid extraction and purification, Can. J. Biochem. Physiol., 37, 911–917, 1959. Budge S. M. and Parrish C. C.: Lipid biogeochemistry of plankton, settling matter and sediments in Trinity Bay, Newfoundland. II. Fatty Acids, Org. Geochem., 29(5), 1547–1559, 1998. Burns, K. A., Greenwood, P., Benner, R., Summons, R. S., and Brunskill, G. J.: Vertical fluxes of hydrocarbons on the Northwest Shelf of Australia as estimated by a sediment trap study, Org. Geochem., 32, 1241–1255, 2001. Burns, K. A., Greenwood, P., Benner, R., Brinkman, D., Brunskill, G. J., Codi, S., and Zagorskis, I.: Organic biomarkers for tracing carbon cycling in the Gulf of Papua (Papua New Guinea), Cont. Shelf. Res., 24, 2373–2394, 2003. Christodoulou, S., Marty, J.-C., Miquel, J.-C., Volkman J. K., and Rontani, J.-F.: Use of lipids and their deradation products as biomarkers for carbon cycling in the northwestern Maditerranean Sea, Mar. Chem., 113, 25–45, 2009. Clark, R. C. and Blumer, M. : Distribution of $n$-parafins in marine organisms and sediments, Limnol. Oceanogr., 12, 79–87, 1967. Conte, M. H., Volkman, J. K., and Eglinton G.: Lipid biomarkers of the Haptophyta, in: The Haptophyte Algae, edited by: Green, J. C. and Leadbeater, B. S. C., Systematics Association Special volume, 51, 351–377, 2004. Conte, M. H., Eglinton, G., and Madureira, L. A. S.: Long-chain alkenones and alkyl alkenoates as paleotemperature indicators: their production, flux and early sedimentary diagenesis in the Eastern North Atlantic, Org. Geochem., 19, 287–298, 1992. Cripps, G. C.: Hydrocarbons in the seawater and pelagic organisms of the Soutehrn Ocean, Polar Biol., 10, 393–402, 1990. Dachs, J., Bayona, J. M., Fowler, S. W., Miquel, J.-C., and Albaigés, J.: Evidence for cyanobacterial inputs and heterotrophic alteration of lipids in sinking particles in the Alboran Sea (SW Mediterranean), Mar. Chem., 60, 189–201, 1998. Davis, J. B.: Paraffinic hydrocarbons in the sulfate-reducing bacterium \textitDesulfovibrio \textitdesulfuricans, Chem. Geol., 3, 155–160, 1968. Dunstan, G. A., Brown, M. R., and Volkman, J. K.: Cryptophyceae and rhodophyceae; chemotaxonomy, phylogeny, and application, Phytochem., 66, 2557–2570, 2005. Eglinton, G. and Hamilton, R. J.: Leaf epicutilar waxes, Science, 156, 1322–1335, 1967. Gelin, F., Volkman, J. K., de Leeuw, J. W., and Sinninghe Damsté, J. S.: Midchain hydroxy long-chain fatty acids in microalgae from the genus \textitNannochloropsis, Phytochem., 45, 641–646, 1997. Goad, L. J. and Whithers, N.: Identification of 27-nor-(24R)-24-methylcholesta-5,22-dien-3$\beta $-ol and brassicasterol as the major sterols of the marine dinoflagellate \textitGymnodinium simplex, Lipids, 17, 853–858, 1982. Goutx, M., Momzikoff, A., Striby, L., Andersen, V., Marty J.-C., and Vescovali, I.: High-frequency fluxes of labile compounds in the central Ligurian Sea, northwestern Mediterranean, Deep-Sea Res. I, 47, 533–556, 2000. Grimalt, J. O. and Albaigés, J.: Sources and occurrence of C$_12$-C$_22$ $n$-alkane distributions with even carbon number preference in sedimentary environments, Geochim. Cosmochim. Acta, 51, 1379–1384, 1987. Grimalt, J. O., Simoneit, B. R. T., Gómez-Belichón, J. I., Fisher, K., and Dymond J.: Ascending and descending fluxes of lipid compounds in North atlantic and North Pacific abyssal waters, Nature, 345, 147–150, 1990. Grimalt, J. O., Calvo, E., and Pelejero, C.: Sea surface paleotemperature errors in UK$_37^'$ estimation due to alkenone measurements near the limit of detection, Paleoceanography, 16, 226–232, 2001. Guieu, C., Bozec, Y., Blain, S., Ridame, C., Sarthou, G., and Leblond, N.: Impact of high Saharan dust inputs on dissolved iron concentrations in the Mediterranean Sea, Geophys.Res. Lett., 29(19), 1911, doi:10.1029/2001GL014454, 2002. Han, J. and Clavin, M.: Hydrocarbon distribution of algae and bacteria, and microbiological activity in sediments, P. Natl. Acad. Sci. USA, 64, 436–443, 1969. Harvey, H. R., Eglinton, G., O'Hara, S. C., and Corner, E. D. S.: Biotransformation and assimilation of dietary lipids by \textitCalanus feeding on a dinoflagellate, Geochim. Cosmochim. Acta, 51, 3031–3040, 1987. Hinrichs, K.-U., Summons, R. E., Orphan, V., Sylva, S. P., and Hayes, J. M.: Molecular and isotopic analysis of anaerobic methane-oxidizing communities in marine sediments, Org. Geochem., 31, 1685–1701, 2000. Jetter, R. and Riederer, M.: Long-chain alkanediols, ketoaldehydes, ketoalcohols and ketoalkyl esters in the cuticular waxes of \textitOsmunda regalis fronds, Phytochem., 52, 907–915, 1999. Kawamura, K., Ishimura, Y., and Yamazaki, K.: Four years' observations of terrestrial lipid class compounds in marine aerosols from the western North Pacific, Global Biogeochem. Cy., 17(1), 3-1–3-19, doi:10.1029/2001GB001810, 2003. Körtzinger, A., Schulz-Bull, D. E., Petrick, G., and Duinker, J. C.: Evidence for dissolution of fatty acids in sediment traps: Impact on flux estimates, J. Geophys. Res., 99(C2), 3407–3415, 1994. Lasternas, S., Tunin-Ley, A., Ibañez, F., Andersen, V., Pizay, M.-D., and Lemée, R.: Dynamics of microphytoplankton abundance and diversity in NW Mediterranean Sea during late summer condition (DYNAPROC 2 cruise; September–October 2004), Biogeosciences Discuss., 5, 5163–5202, 2008. Mansour, M. P., Volkman, J. K., and Blackburn, S. I.: The effect of growth phase on the lipid class, fatty acid and sterol composition in the marine dinoflagellate \textitGymnodinium sp. in batch culture, Phytochem., 63, 145–153, 2003. Marty, J.-C., Nicolas, E., Miquel, J.-C., and Fowler, S. W.: Particulate fluxes of organic compounds and their relationship to zooplankton fecal pellets in the northwestern Mediterranean Sea, Mar.Chem., 46, 387–405, 1994. Marty, J. C., Garcia, N., and Raimbault, P.: Phytoplankton dynamics and primary production under late summer conditions in the NW Mediterranean Sea, Deep Sea Res. I, 55, 1131–1149, 2008. Marty, J. C., Goutx, M., Guigue, C., Leblond, N., and Raimbault, P.: Short-term changes in particulate fluxes measured by drifting sediment traps during end summer oligotrophic regime in the NW Mediterranean Sea, Biogeosciences, 6, 887–899, 2009. Méjanelle, L., Sanchez-Gargallo, A., Bentaleb, I., and Grimalt, J. O.: Long chain $n$-alkyl diols, hydroxy ketones and sterols in a marine eustigmatophyte, \textitNannochloropsis gaditana, and in \textitBrachionus plicatilis feeding on the algae, Org. Geochem., 34, 527–538, 2003. Matsueda, H. and Handa, N.: Vertical flux of hydrocarbons as measured in sediment traps in the eastern north Pacific Ocean, Mar.Chem., 20, 179–195, 1986. Migon, C., Sandroni, V., and Béthoux, J.-P.: Atmospheric input of anthropogenic phosphorus to the northwest Mediterranean during the oligotrophic season, Mar. Environ. Res., 52(5), 413–426, 2001. Mousseau, L., Lefevre, D., Narcy, F., Nival, P., and Andersen, V.: A one-month study of the zooplankton community at a fixed station in the Ligurian Sea: the potential impact of the species composition on the mineralization of organic matter, Biogeosciences Discuss., 6, 995–1019, 2009. Nichols, P. D., Volkman, J. K., Hallegraeff, G. M., and Blackburn S. I.: Sterols and fatty acids of the red tide flagellates \textitHeterosigma akashiwo and \textitChattonella antiqua (Raphidophycea), Phytochem., 26, 2537–2541, 1987. O'Neill, L. P., Benitez-Nelson, C. R., Styles, R. M., Tappa, E., and Thunell, R. C.: Diagenetic effects on particulate phosphorus samples collected using formalin-poisoned sediments traps, Limnol. Oceanogr. Methods, 3, 308–317, 2005. Parrish, C. C., Eadies, B. J., Gardner, W. S., and Cavaletto, J. F.: Lipid class and alkane distribution in settling particles of the upper Laurentian Great Lakes, Org. Geochem.,~18,~33–40, 1992. Piretti, M. V., Pagliuca, G., Boni, L., Pistocchi, R., Diamante, M., and Gazotti, T.: Investigation of 4-methyl sterols from cultured algal strains, J. Phycol., 33, 61–67, 1997. Prahl, F. G., Muehlhausen, L. A., and Zahnle, D. I.: Further evaluation of long-chain alkenones as indicators of paleoceanographic conditions, Geochim. Cosmochim. Acta, 52, 2303–2310, 1988. Prahl, F. G., Dymond, J., and Sparrow M. A.: Annual biomarker record for export production in the central Arabian Sea, Deep-Sea Res. II, 47, 1581–1604, 2000. Raybaud, V., Nival, P., Mousseau, L., Gubanova, A., Altukhov, D., Khvorov, S., Ibañez, F., and Andersen, V.: Short term changes in zooplankton community during the summer-autumn transition in the open NW Mediterranean Sea: species composition, abundance and diversity, Biogeosciences, 5, 1765–1782, 2008. Rosell-Melé, A., Comes P., Müller, P. J., and Ziveri, P.: Alkenone fluxes and anomalous UK$_37^'$ values during 1989–1990 in the Northest Atlantic (48&deg; N 21&deg; W), Mar. Chem., 71, 251–264, 2000. Sicre, M.-A., Ternois, Y., Miquel, J.-C., and Marty, J.-C.: Alkenones in the Northwestern Mediterranean Sea: interannual variability and vertical transfer, Geophys. Res. Lett., 26(12), 1735–1738, 1999. Sikes, E. L., O'Leary, T., Nodder, S. D., and Volkman, J. K.: Alkenone temperature records and biomarker flux at the subtropical front of the chatham rise, SW Pacific Ocean, Deep-Sea Res., 52, 721–748, 2005. Sinninghe Damsté, J. S., Kuypers, M., Schouten, S., Schulte, S., and Rullkötter, J.: The lycopane/C$_31$ $n$-alkane ratio as a proxy to assess palaeoxicity during sediment deposition, Earth Planet. Sci. Lett., 209, 215–226, 1993. Steward, G., Cochran, J. K., Miquel, J. C., Masqué, P., Szlosek, J., Rodriguez y Baena, A. M., Fowler, S. W., Gasser, B., and Hirschberg, D. J.: Comparing POC export from $^234$Th/$^238$U and $^210$Po/$^210$Pb disequilibria with estimates from sediment traps in the northwest Mediterranean, Deep-Sea Res. I, 54, 1549–1570, 2007. Summons, R. E., Bradley, A. S., Jahnke, L. L., and Waldbauer, J. R.: Steroids, triterpenoids and molecular oxygen, Philos. T. Roy. Soc. B, 361, 951–968, doi:10.1098/rstb.2006.1837, 2006. Ternois, Y., Sicre, M.-A., Boireau, A., Mart, J.-C., and Miquel, J.-C.: Production pattern of alkenones in the Mediterranean Sea, Geophys. Res. Lett., 23(22), 3171–3174, 1996. Ternois, Y., Sicre, M.-A., Boireau, A., Conte, M. H., and Eglinton G.: Evaluation of long-chain alkenones as paleo-temperature indicators in the Mediterranean Sea, Deep-Sea Res., 44, 271–286, 1997. Ternois, Y., Sicre, M.-A., Boireau, A., Beaufort, L., Miquel, J.-C., and Jeandel C.: Hydrocarbons, sterols and alkenones in sinking particles in the Indian Ocean sector of the Southern Ocean, Org. Geochem., 28, 489–501, 1998. Tolosa, I., Leblond, N., Copin-Montaigut, C., Marty, J.-C., de Mora, S., and Prieur, L.: Distribution of sterol and fatty alcohol biomarkers in particulate matter from the frontal structure of the Alboran Sea (S.W. Mediterranean Sea), Mar. Chem., 82, 161–183, 2003. Tolosa, I., Leblond, N., Marty, J.-C., de Mora, S., and Prieur, L.: Export fluxes of organic carbon and lipid biomarkers from the frontal structure of the Alboran Sea (SW Mediterranean Sea) in winter, J. Sea Res., 54, 125–142, 2005. Versteegh, G. J. M., Jansen, J. H. F., de Leeuw, J. W., and Schneider, R. R.: Mid-chain diols and keto-ols in SE Atlantic sediments: A new tool for tracing past sea surface water masses?, Geochim. Cosmochim. Acta, 11, 1879–1892, 2000. Villanueva, J. and Grimalt, J. O.: Pitfalls in the chromatographic determination of the alkenone UK$_37^'$ index for paleotemperature estimation, J. Chromatogr. A, 723, 285–291, 1996. Volkman, J. K.: A review of sterol markers for marine and terrigeneous matter, Org. Geochem., 9, 83–99, 1986. Volkman, J. K., Johns, R. B., Gillian, F. T., and Perry G. J.: Microbial lipids of an intertidal sediment, Geochim. Cosmochim. Acta, 44, 1133–1143, 1980. Volkman, J. K., Barrett, S. M., Dunstan, G. A., and Jeffrey, S. W.: C$_30$-C$_32$ alkyl diols and unsaturated alcohols in microalgae of the class Eustigmatophyceae, Org. Geochem., 18(1), 131–138, 1992. Volkman, J. K., Barrett, S. M., Dunstan, G. A., and Jeffrey, S. W.: Geochemical significance of the occurrence of dinosterol and other 4-methyl sterols in a marine diatom, Org. Geochem., 20(1), 7–15, 1993. Volkman, J. K., Barrett, S., and Blackburn, S.: Eustigmatophyte microalgae are potential sources of C$_29$ $n$-alcohols and C$_28$-C$_32$ $n$-alkyl diols in freshwater environments, Org. Geochem., 30, 307–318, 1999. Volkman, J. K., Barrett, S., Blackburn, S., Mansour, M., Sikes, E., and Gelin, F.: Microalgal biomarkers: A review of recent research developments, Org. Geochem., 29, 1163–1179, 1998. Wang, G., Kawamura, K., and Lee, M.: Comparison of organic compositions in dust storm and normal aerosol samples collected at Gosan, Jeju Island, during spring 2005, Atmos. Environ., 43, 219–227, 2009. Wakeham, S. G. and Canuel, E. A.: Lipid composition of the pelagic crab \textitPleuroncodes planipedes, its feces and sinking particulate organic matter in the equatorial North Pacific Ocean, Org. Geochem., 9, 331–343, 1986. Wakeham, S. G. and Canuel, E. A.: Organic geochemistry of particulate matter in the eastern tropical North Pacific Ocean: Implications for particle dynamics, J. Mar. Res., 46, 183–213, 1988. Wakeham, S. G. and Lee, C.: Organic geochemistry of particulate matter in the ocean: The role of particles in oceanic sedimentary cycles, Org. Geochem., 14, 83–96, 1989. Wakeham, S. G. and Beier, J. A.: Fatty acids and sterol biomarkers as indicators of particulate matter source and alteration processes in the Black Sea, Deep-Sea Res., 38, S943–S968, 1991. Wakeham, S. G., Peterson, M. L., Hedges, J. I., and Lee, C.: Lipid biomarker fluxes in the Arabian Sea, with a comparison to the equatorial Pacific Ocean, Deep-Sea Res. II, 49, 2265–2301, 2002. Wakeham, S. G., Lee, C., Peterson, M. L., Liu, Z., Szlosek, J., Putman, I. F., and Xue, J.: Organic biomarkers in the twilight zone – series and settling velocity sediment traps during MedFlux, Deep-Sea Res. II, 56(18), 1437–1453, doi:10.1016/j.dsr2.2008.11.030, 2009.