Transcript Document
BIOSOPE Effects of UV radiation (UVR) on the molecular structure of DOM and its subsequent utilization by marine bacterioplankton in the South East Pacific M. Tedetti, B. Charrière, F. Joux*, M. Abboudi and R. Sempéré LMGEM, UMR 6117, CNRS/INSU, COM, Université de la Méditerranée *OOBanyuls, UMR CNRS/INSU, 7621 [email protected] Atmosphere UVA UVB aerosols CO2 7.5 Gt C yr-1 CO2. : 750 Gt C Ocean Gas exchanges CO2 UVA UVB Photosynthesis Primary production 50 Gt C yr-1 phytoplankton photochemistry CO2 bacteria Respiration DOC 700 Gt C nutrients - 100 m Mineralization organic carbon fluxes Tedetti et al., 2003 - 4000 m Sediment ~ 30 Gt C yr-1 Effects of UVR on bacterial mineralization of DOM (adapted from Obernosterer, 2000) sunlight UVR UVR air-water interface nitrates DOM photolysis photolysis biologically available photoproducts radicals refractory photoproducts - - sugars amino acids diacids + Bacteria OH. radicals - Bacterial production, Bacterial growth efficiency ? CO2 production by respiration Production of dicarboxylic acids and ketoacids in the atmosphere CHO R HOOC COOH Monaldehyde COOH R + Monoacide Azelaic + HOOC CHO Oxononanoic( COOH COOH O 4- oxoacid Succinic acid (C4) HOOC COOH OH Malic acid (hC4) HOOC R hn O3 COOH R OH. HOOC COOH Oxalic acid (C2) HOOC COOH Malonic acid (C3) Unsaturated fatty acid (Kawamura et al., 1996; Sempéré and Kawamura, 2003) TOMS-derived map of surface UV irradiance weighted by the erythemal action spectra (January 1, 2004) in kJ m-2 (http://jwocky.gsfc.nasa.gov/) BIOSOPE 10 % UV-B irradiance depth ~ 17 m (Vasilkov et al., 2001) Our objectives during Biosope To study the importance and the variability of UVR (A and B) and PAR intensity at the ocean surface and in the water column (0-200 m) in the South East Pacific Gyre To study the effects of UVR (A and B) and PAR on the molecular transformations of DOM (sugars, amino acids, carbonyl compounds including dicaboxylic acids, keto-acids and dicarbonyls) and on bacterial DNA damages in the oceanic surface layer To study the effects of UVR on the DOM bacterial cycling in term of bacterial production and bacterial growth efficiency (BGE) Scientific approach 1-Measurements of UVR and PAR intensity at the ocean surface using surface sensors (Satlantic OCR-504 I ) and in the water column (0-200 m) using a MICRO-PRO Profiler (Satlantic OCR-504 I/R). Relationships with TOMS products (collaboration with A. Vassilkov) 2-Water column profiles of dissolved organic compounds (sugars, amino acids, diacids) and bacterial DNA damages (ELISA protocols) at 4 depths (5, 80, 200, and 1000 m) 3-Irradiation experiments of freshly collected seawater: sunlight exposure of DOM (photoproduction of sugars, amino acids, diacids) and bacteria (photoproduction of bacterial DNA damages) followed by dark microbial degradation of DOM (bacterial production and bacterial respiration) Methods 1-Measurements of UVR and PAR intensity at the ocean surface using surface sensors (Satlantic OCR-504 I ) and in the water column (0-200 m) using a MICRO-PRO Profiler (Satlantic OCR-504 I/R). Relationships with Seawifs, TOMS products if possible (collaboration with A. Vassilkov and Biosope scientists) Satlantic's OCR-504 UV/PAR radiometers UV: 305, 325, 340, 380 nm (bandwidth: 2 and 10 nm) PAR: 412, 443, 490, 565 nm (bandwidth: 20 nm) Air Surface sensors (OCR-504 I) (on the ship deck) Real time surface reference for in-water measurements Surface irradiance (Es(λ) in W m-2) Dose (in kJ m-2) Simultaneously Underwater : MICRO-PRO Profiler (OCR-504 I/R) (Free Fall Profiling Vehicle) Real time profiling deployments (200 m operating depth) Measurements around solar noon 1m underwater Downwelling irradiance (Ed(λ, z), Upwelling radiance (Lu(λ, z), Surface radiometres UV and PAR (Satlantic®) 7 cm 11 cm 4.6 cm 17 cm OCR-504 UV (-B and -A) OCR-504 PAR λ = 305, 325, 340, 380 nm λ = 412, 443, 490, 565 nm width = 20 nm width = 2 et 10 nm Atmospheric UVR doses for August 2003, Marseille France Roof top (25 m) of the Faculty of Science Days Analysis of dissolved organic compounds Sugars :Waters HPLC, Dionex column HPAEC-PAD at 4 depths (5, 80, 200, and 1000 m) Amino-acids, OH.:Waters HPLC, Fluo. Dissolved (free and combined) individual sugars by HPAEC-PAD High Performance Anion-Exchange Chromatography and Pulsed Amperometry Detection (HPAEC-PAD) (Panagiotopoulos et al., 2001; 2003; Panagiotopoulos and Sempéré, 2004) Desalting of seawater samples using Bio-Rad ion-exchange resins (Mopper et al., 1992) Recoveries of desalting : 70–90 % at 20 nM (Tedetti and Sempéré, in prep.) Volume of seawater sample : 4 x 8 ml = 32 ml Detection level : 5 nM Total analysis time : 3h HPAEC-PAD chromatogram of dissolved sugars after desalting Recoveries of desalting : 70-90 % Tedetti and Sempéré, 2004 Amino-acid analysis by HPLC Phe Ileu Val Leu Lys OPA derivatisation technique followed by HPLC and spectrofluorimetry (Lindroth et Mopper,1979) - detection level : 2 -5 nM . -Reprod. < 5% Gaba Ala Thr Gly Ser Glu His Asp Tyr Phe Slight improvements : decrease coelution by using new column and new elution programme Collaboration with C. Lee (Stony Brooks Univ., USA) OH. radical production by HPLC Derivatization by benzoic acid (Qian et al., 2001) Salicylic acid : Highly fluorescent (300) COOH COOH OH + OH. BA + no fluorescent compounds OHBA OH. photoproduction = (OHAB photoproduction ) × 6,45 Volume of seawater sample : 2 x 100 ml = 200 ml Detection level : 0,5 nM Run : 25 min HPLC Chromatogram of acid salicylic solution (1,5 nM) 1,00 Salicylic acid mV 0,50 0,00 -0,50 -1,00 1,00 2,00 3,00 4,00 5,00 6,00 7,00 8,00 Minutes 9,00 10,00 11,00 12,00 13,00 14,00 15,00 Dicarboxylic acids in seawater : A new gas chromatography (GC) protocol (Tedetti et al., in prep.) Dicarboxylic acids, ketoacids and dicarbonyls Extraction by activated charcoal after intensive cleaning Elution by NH4OH-MeOH, CH2Cl2, Milli-Q Derivatisation by BF3/butanol (Kawamura, 1993). On board GC injection, FID detection Volume of seawater sample : 150 ml Detection level : ~ 10 nM Oxalic acid (C2) HOOC Malonic acid (C3) Succinic acid (C4) Glutaric acid (C5) Adipic acid (C6) Azelaic acid (C9) HOOC HOOC HOOC HOOC HOOC Recoveries 50-57 % COOH COOH COOH 20 % 90-95 % COOH 90-95 % COOH 90-95 % COOH 85-95 % Collaboration with K. Kawamura (Sapporo Univ. Japan)dC13 for individual diacids Detection of UV damages on bacterial DNA UV-B UV-C UV-B ADN Direct damages on DNA Cellular death Reparation STOP of DNA transcription and replication Mutation Joux, 2003 DNA damages 2 bases pyrimidiques adjacentes UV-B 90% Different reparation processes Dimères cyclobutane pyrimidine 10% 300 times more efficient 6-4 photoproduits in DNA blocking replication pyrimidone Detection: Seawater filtration (0.2 mm). Samples might be kept frozen. immunodetection : (ELISA test: addition of antobodies, spectrophotometry detection) Volume of seawater samples : 1-3 Liters Irradiation/incubation protocol Niskin bottle Seawater 0.8 µm ELISA BP 0.2 µm 16 l 8l 8l bacterial inoculum sugars amino acids diacids DOM solution 100 ml Quartz flasks 1 l Quartz flasks Sunlight exposure (8 h, around solar noon, on the ship deck) Full Sun Dark 20% 80% ELISA BP 1 l shot bottles sugars amino acids diacids Dark incubation (2 days) BP, BR Analytical protocol: summary Dissolved sugars (HPAEC - PAD) Desalination using ion-exchange resins Dissolved amino acids (HPLC) OPA derivatization (Lindroth and Mopper, 1979; Lee et al., 2000) OH. Radical production (HPLC) Diacids (GC - GC/MS) BF3/butanol derivatization Extraction of diacids using activated charcoal DNA damages ELISA experiment Bacterial Production Measurement of 3H-Leucine incorporation Bacterial Respiration Measurement of dissolved O2, concentrations (????) Strategy, types of samples Measurements of UVR and PAR intensity Around solar noon, light measurements : - 3 for each short stations (st 1-21) - 6 for each long stations (G1, G2, G3) - 6 for each station of specific sites (MARQ1-7, UPW1-7) Profiles of dissolved organic compounds and DNA damages Around solar noon, sampling: - 1 at 5 m (surface ?) for all stations (short, long, and specific sites) - 1 at 80, 200, and 1000 m for 7 stations (G1, G2, G3, UPW1, 7, MARQ1, 7) Irradiation experiments Around solar noon, at : - 1 at MARQ1 - 1 at G3 - between (MARQ1 and G3) Needs Volume of Seawater - All stations at the surface (5 m) : 3 Liters - MARQ and G3 in surface water : 16 Liters - G1, G2, G3, UPW1, 7, MARQ1, 7 at 80, 200, 1000 m : 3 Liters Volume of sample storage - Freezer: 35 Liters - 4 °C: 410 Liters Material : Problem with contamination for organics -Oven: 70 l : -Niskin bottles (Silicon rubbers and Viton o-rings) -Access for underwater radiometer Needs Space : Space on ship deck : 5 m2 for surface sensors and irradiation experiments Space for computer connected to the surface sensors : 1m Space for storage of the underwater radiometer : 2 m2 Chemistry lab. for organics : Regular airbench and laminar flow airbench. Lab: 10 m2 Access to isotope containers Chemicals, isotopes : Use of organic solvents, acids Isotopes : 3H-leucine Oxygen (??) Other types of samples Aerosols : High volume air sampler for organics (K. Kawamura, Sapporo, Japan) Sediment trap particles (sugars, amino-acids) Surface samples UVECO-program (CNRS PROOF / SOLAS) PIs: R. Sempéré and F. Joux www.com.univ-mrs.fr/LMGEM/uveco/ Induction of microbial community responses and dissolved organic matter transformations by UltraViolet radiation in marine ECOsystems May 2003-end May 2006 This projects involves 7 French laboratories and 30 scientists specialized in marine biogeochemistry other foreign scientists (Australia, Canada, Japan, and USA) UVR and global change Stratospheric ozone depletion UV-B Increase of aerosols, ozone (troposphere) Increase of winds frequency UV-A and UV-B vertical mixing Increase of greenhouse gases Variation of nebulosity UV-A and UV-B + + UV-B + Variation of UVR at the Earth’s surface Variation of UV penetration in seawater (UNEP/WMO, 2002; McKenzie et al., 2003; Häder et al., 2003). Adapted from Joux, 2003 Objectives To study cellular and molecular responses of marine microbial community to UV stress To better understand the molecular and physiological bases of the capacity of marine picocyanobacteria and heterotrophic bacteria to resist high fluxes of visible and ultraviolet light occurring in the top layer of oceans. To study degradation of DOM including polysaccharides, proteins, carbonyls and dimethylsulfide (DMS) as well as on subsequent effects on bacterial cycling. Atmospheric (at ground level at the Oceanographic Centre of Banyuls/mer and at the University of Marseille-Luminy) as well as submersible irradiances (in coastal areas of Banyuls/Mer and Marseille cities) will be monitored Experiments will be conducted in north-western Mediterranean coastal waters (Banyuls/Mer and Marseille), likely in open Mediterranean waters (cruise not defined yet) and in Pacific Ocean (Biosope). UVECO NAME LABORATORY JOUX Fabien CONAN Pascal PUJO-PAY Mireille LANTOINE François LEBARON Philippe GHIGLIONE Jean-François CATALA Philippe ZUDAIRE Laurent SEMPÉRÉ Richard TEDETTI Marc LOBB LOBB LOBB LOBB LOBB LOBB LOBB LOBB, LMGEM-COM LMGEM-COM Banyuls/FRA Banyuls/FRA Banyuls/FRA Banyuls/FRA Banyuls/FRA Banyuls/FRA Banyuls/FRA Banyuls/FRA Marseille/FRA Marseille/FRA ABBOUDI Maher VANWAMBEKE France LEFEVRE Dominique CHARRIERE Bruno MONZIKOFF André GOYET Catherine TOURATIER Franck BELVISO Sauveur PARTENSKY Frédéric LMGEM-COM LMGEM-COM LMGEM-COM LMGEM-COM LBCM Univ. Perpi. CEFREM LSCE SBR SBR SBR SBR Marseille/FRA Marseille/FRA Marseille/FRA Marseille/FRA Paris/FRA Perpignan/FRA Perpignan/FRA Gif/FRA Roscoff/FRA MARIE Dominique GARCZAREK Laurence SIX Christophe DUFRESNE Anne CHAMI Malik SBR LOV Roscoff/FRA Roscoff/FRA Roscoff/FRA Roscoff/FRA Villefranche/mer/FRA COURBES DE CALIBRATION DO / DOMMAGES ADN (dosés par HPLC) 2,5 y = 0,1214x + 0,0935 R2 = 0,9931 CPD 15 ng/puits DO 490 nm 2 1,5 1 0,5 0 0 5 10 15 Lésions/104 b 0,8 50 ng/puits 0,6 DO 490 nm 6- 4 photoproduits y = 2,1798x + 0,0087 R2 = 0,9939 0,4 0,2 0 0 0,1 Jeffrey et al. 1996. Photochem. Photobiol. 64:419-427. Joux et al. 1999. Appl. Envrion. Microbiol. 65:3820-3827. 0,2 Lésions/104 b 0,3 0,4 DNA damages 2 bases pyrimidiques adjacentes UV-B 90% Different reparation processes Photoreactivation 10% Dimères cyclobutane pyrimidine 6-4 photoproduits pyrimidone Yes NO Excision of nucleotides Yes Yes Recombination Yes Yes 300 times more efficient in DNA blocking replication DNA damage detection by immunodetection (ELISA Test) 1. Non specific absorbtion of the antigene for the detection of the DNA damages 3. Specific fixation of the antobodies on the antigene 4. Second specific antigene fixation associated to an enzyme against the first antibody 5. Colorimetric detection (spectrophotometry)