The Role of the Bacterioneuston in Air-Sea Gas Exchange Emma Harrison University of Newcastle-upon-Tyne, UK.

Slides:

Advertisements

Similar presentations

DOGEE-SOLAS: The UK SOLAS Deep Ocean Gas Exchange Experiment Matt Salter.

Advertisements

UK Ocean Acidification The Sea Surface Consortium is one of seven multi-partner consortium projects making up the UK Ocean Acidification research programme.

Global Change Research in Belgium Guy P. Brasseur Max Planck Institute for Meteorology Chair, International Geosphere Biosphere Programme (IGBP)

Emissions From The Oceans To The Atmosphere Deposition From The Atmosphere To The Oceans And The Interactions Between Them Tim Jickells Laboratory for.

Effects of variable rainfall and increased nitrogen deposition on nitrous oxide production in a semi-arid grassland ecosystem A forethought of global change.

MCB 306 MICROBIAL ECOLOGY LECTURERS Dr. Akintokun, A.K Dr. Balogun,S.O.

Isolation and Physiological Characterization of a Halophilic Host- Phage System from Solar Salterns in Baja California, Mexico or Extreme Halophiles:

Arranged by: 1.Nur Laely Mubarokah 2.Lita Purnamasari 3.Andhis Exsa Seftilian 4.Anindita safitri 5.Rizqi Nur Amalia.

Determination of host-associated bacterial communities In the rhizospheres of maize, acorn squash, and pinto beans.

Sensing Winter Soil Respiration Dynamics in Near-Real Time Alexandra Contosta 1, Elizabeth Burakowski 1,2, Ruth Varner 1, and Serita Frey 3 1 University.

Coupled Ocean and Atmosphere Climate Dynamics ENVI3410.

Laboratory for Marine Microbial Ecology

What Needs to be Done? Environmental Impacts Carol Turley and Jerry Blackford Plymouth Marine Laboratory, UK CCS R & D Workshop, Royal Academy of Engineering,

The Role of the Bacterioneuston in Air-Sea Gas Exchange

Geomicrobiology.

Week 4 Lectures November 2001 Microbial Ecology and Geochemical Cycles.

Brock Biology of Microorganisms

Geomicrobiology. Course Goals At the end of this course you will be able to… –Intelligently converse with microbiologists, geologists, environmental scientists.

Lecture 1. Microorganisms: an overview Chapter 1. Microorganisms and Microbiology Chapter 2. An overview of microbial life. Cell and viral structures DNA.

The Sorcerer II Global ocean sampling expedition Katrine Lekang Global Ocean Sampling project (GOS) Global Ocean Sampling project (GOS) CAMERA CAMERA METAREP.

Isolation of Viruses Infecting Marine Bacteria Jennifer Yan Mentors: Dr. Stephen Giovannoni Dr. Mike Schwalbach Giovannoni Lab Department of Microbiology.

GEOF236 CHEMICAL OCEANOGRAPHY (HØST 2012) Christoph Heinze University of Bergen, Geophysical Institute and Bjerknes Centre for Climate Research Prof. in.

 Biotic- Living  Organism- any living thing  Population- a group of the same organisms living in the same area  Community- a group of different populations.

Aquarium Biogeography and Succession of Microbial Communities in Aquatic Built Environments Nitrification Results in Coral Pond 1 The nitrite levels in.

Chapter 22 Table of Contents Section 1 An Interconnected Planet

Prokaryotes vs. Eukaryotes. The Endosymbiotic Theory.

Molecular Microbial Ecology

Copyright © 2002 Pearson Education, Inc., publishing as Benjamin Cummings Section D: A Survey of Prokaryotic Diversity 1.Molecular systematics is leading.

Microbial Community Biomarker in Barnegat Bay Evangelina Pena 1, Lora McGuinness 1, Gary Taghon 1, Lee Kerkhof 1 Introduction Efforts to remediate anthropogenic.

The NEWS Atmospheric Diabatic Heating Profile Product  A ten year dataset of clouds, rainfall, and atmospheric heating between 40°N and 40°S has been.

SOME ASPECTS OF ACCUMULATED CARBON IN FEW BRYOPHYTE- DOMINATED ECOSYSTEMS: A BRIEF MECHANISTIC OVERVIEW Mahesh Kumar SINGH Department of Botany and Plant.

Structure of the microbial food webs at the air-water interface Philippe Lebaron Ingrid Obernosterer Observatoire Océanologique, Banyuls-sur-mer.

Diversity of uncultured candidate division SR1 in anaerobic habitats James P. Davis Microbial & Molecular Genetics Oklahoma State University.

Diversity of bacteria associated with Montastraea spp. across sea water quality gradient in the United States Virgin Islands S. Arora, M.E. Brandt, N.

The Other Carbon Dioxide Problem Ocean acidification is the term given to the chemical changes in the ocean as a result of carbon dioxide emissions.

A current world debate. Colorado Prepared Graduate Competencies: Evaluate evidence that the Earth is a complex system of interactions between the geosphere,

Marine Geochemistry 2 Reference: Schulz and Zabel Marine Geochemistry Springer, New York pp. ISBN X.

Carbon Cycle Gr 9 Science. Carbon Cycle Fourth most abundant element in universe Building block of all living things Main Pathway– in and out of living.

Chapter 22 Table of Contents Section 1 An Interconnected Planet

The Surface Ocean - Lower Atmosphere Study Rob Upstill-Goddard University of Newcastle upon Tyne.

Opportunities for Research in the Dynamics of Water Processes in the Environment at NSF Pam Stephens Directorate of Geosciences, NSF Directorate of Geosciences,

Bacterial and Archaeal Communities in the Brine/Seawater Interface of Four Different Brine Lakes in the Mediterranean Sea. Henk Bolhuis Paul van der Wielen.

Objective Data  The outlined square marks the area of the study arranged in most cases in a coarse 24X24 grid.  Data from the NASA Langley Research Center.

Conservation management for an uncertain future Mike Morecroft.

Department of Environmental Earth System Science Stanford University

Ecosystems: Components, Energy Flow, and Matter Cycling G. Tyler Miller’s Living in the Environment 13 th Edition Chapter 4 G. Tyler Miller’s Living in.

Ecology: Interactions of Life  Biosphere- part of Earth that supports life; includes the top portion of Earth’s crust, all the waters that cover.

The Earth as a System Earth’s Spheres. Earth System Science (ESS) The study of the interactions between and among events and Earth’s spheres A relatively.

Introduction to Ecology Ecology is the study of the interactions between organisms and the living (BIOTIC) and nonliving (ABIOTIC) components of their.

WP 7: Microbial diversity and activity, in particular N cycling Objectives 1.To determine the impact of changing pH on prokaryotes: production and respiration,

What are they and how do they work?. Cell Review  Smallest functional unit of life  Cell theory  All living things are made of cells  Single or multi-cellular.

Diploma thesis (Spanien – Österreich): Title of the Project: “Effect of burning of Mediterranean macchia on ecosystem nitrogen stocks and the soil-atmosphere.

Biodiversity & Sustainability. Biomes a large naturally occurring community of flora and fauna occupying a major habitat, e.g., forest or tundra.

AN ATMOSPHERIC CHEMIST’S VIEW OF THE WORLD FiresLand biosphere Human activity Lightning Ocean physics chemistry biology.

Systems Microbiology Biology 475. Systems microbiology aims to integrate basic biological information with genomics, transcriptomics, metabolomics, glycomics,

OEAS 604: Final Exam Tuesday, 8 December 8:30 – 11:30 pm Room 3200, Research Innovation Building I Exam is cumulative Questions similar to quizzes with.

The Dynamic Earth Ch. 3. Earth is a system System: a group of parts working together  Which of the following are systems?  A gas tank, air filter, water.

HUMAN IMPACT Human Impact involves discussion of human activities that impact our environment.

DELAWARE NATIONAL ESTUARINE RESEARCH RESERVE Promoting stewardship of the nation’s coastal areas through science and education …

Fatty Acid Recovery and Identification in Mars Analogue Soil Samples Kimberly Lykens Mentor: Michael Tuite Jet Propulsion Laboratory Planetary Chemistry.

WMO Global Atmosphere Watch (GAW) – oppertunities for WGNE 31 st WGNE meeting, April 2016, CSIR, Pretoria, South Africa.

Impact of varied precipitation and N deposition on grassland soil microbial communities and GHG flux Emma L. Aronson Allison lab UC Irvine May 17, 2012.

Quantitative Phylogenetic Assessment of Microbial Communities in Diverse Environments Xinjun Zhang.

Aim: How is ecology the study of the environment?

Surface Ocean – Lower Atmosphere Study

The bacterial ecology of the sheep mammary gland

Earth’s Layers Chapter 22 Section 1 An Interconnected Planet

Chapter 22 Table of Contents Section 1 An Interconnected Planet

Introduction to Biodiversity

Ch Community Ecology pp

Presentation transcript:

The Role of the Bacterioneuston in Air-Sea Gas Exchange Emma Harrison University of Newcastle-upon-Tyne, UK

Bacterioneuston??

Sea Surface Microlayer Widespread, unique and dynamic habitat covering ~70% of the Earth’s surface Microlayer ranges between 1 – 1000 μm Definition highly debatable Rich and diverse community of microorganisms which thrive on the interaction between the atmosphere and the water column

Extreme Environment? ? ?

Bacterioneuston Bacteria tolerant to this extreme environment Estimated that the bacteria present in the bacterioneuston are more abundant when compared to subsurface waters Preliminary data obtained from North Sea, UK, has suggested bacterioneuston dominated by; - Vibrio sp - Pseudoalteromonas sp BUT This is not necessarily the case everywhere!

Why is the bacterioneuston important?

Many exchanges take place across the air-sea boundary The interface between the microlayer and the atmosphere is 1000 µm of the sea surface and µm of the atmosphere Consequently, effects of this boundary on air-sea gas fluxes of GREENHOUSE GASES could be considerable Interactions with the Air-Sea Boundary

Microbial metabolism of climatically active trace gases such as CH 4, N 2 O, CO, DMS and methyl halides in the bacterioneuston may exert important controls on air-sea gas exchange Determining the diversity, abundance and activity of the major groups of microorganisms in the bacterioneuston and their involvement in trace gas cycling are a high priority in the UK SOLAS projects

Research Aims Specific objectives; 1.To determine the bacterial community structure of the bacterioneuston with specific reference to bacteria that metabolise trace gases 2.Investigate the role of the microbial populations on gas exchange rates in controlled laboratory gas exchange tank experiments 3.To measure rates of invasive (i.e. air to water) and evasive (i.e. water to air) air-sea exchange of selected atmospheric trace gases Project in collaboration with Warwick University, UK

Objective One “Analysis of the bacterial community structure of the bacterioneuston” Bacterioneuston sampled by sterile, polycarbonate filters Removes the top layer of water from the interface through surface tension Construct gene libraries representative of the microbial community by use of 16S rRNA sequence data Application of PCR and DGGE allows the study of these complex communities Overcomes; - small sample size - poor culturability of neuston bacteria

Acquiring Bacterioneuston Samples Sampling at Blyth Harbour, North East England

Microbial Community Structure From Blyth Harbour

Bacterial community structure in the microlayer is distinct when compared to the subsurface waters This is also true for Archaea and Eukarya

Objective Two “Roles of the bacterioneuston investigated through gas exchange tank” Purpose built gas exchange tank Closed system The microbial community structure will be correlated with changes in the gas exchange rates Conditions altered and experiments will use local seawater (North Sea), river water (River Tyne), Milli-RO and artificial seawater prepared in Milli-RO

Objective Three “Measure the invasive and evasive rates of atmospheric trace gases” Coupling of two gas chromatographs with gas tank to create a fully automated system to measure CH 4, CO, N 2 O and SF 6 concurrently Tank headspace circulated through gas chromatographs Gas fluxes quantified by estimating their transfer velocities, k w Estimate k w by measuring evasion rates of inert volatile tracer, SF 6 with Schmidt number based scaling for each individual trace gas

Conclusion Knowledge of the biology and population structure within the bacterioneuston is still in its infancy Unclear what role these microorganisms play Is clear the sea surface microlayer has the potential to impact the cycling of reactive trace gases and the exchange rate of these gases across the air-sea boundary Using a combination of molecular ecology techniques and an understanding of gas exchange, the knowledge of this unique and dynamic environment will be greatly improved

Acknowledgements Many thanks to the following… Supervisors; Rob Upstill-Goddard (University of Newcastle) Colin Murrell (University of Warwick) Michael Cunliffe (University of Warwick) for his support and advice on molecular ecology and for microbial community structure work Grant Forster for technical assistance UK SOLAS Project Natural Environment Research Council, UK