Microbe presentation


Published on

  • Be the first to comment

No Downloads
Total views
On SlideShare
From Embeds
Number of Embeds
Embeds 0
No embeds

No notes for slide

Microbe presentation

  1. 1. Microbes Presented by Jessica Susser, Amol Mehta, Brittany Ham, Sidra Jocus, Liana Harotian
  2. 2. A microbe is defined as any microscopic organism (otherwise known as microorganisms) What are microbes? Examples: Bacteria, Archaea, Viruses, small parasites
  3. 3. Important microbes of the deep: BACTERIA
  4. 4. What are Bacteria? <ul><ul><li>Bacteria are single-cell prokaryotes, meaning they lack a nucleus and membrane-bound organelles. </li></ul></ul>Depending on their species, they can be aerobic (requiring oxygen) or anaerobic
  5. 5. Where are Bacteria found in the oceans? Everywhere! All throughout the ocean, in every water column. Some live independently, while others form symbiotic relationships with other organisms.
  6. 6. Cyanobacteria (blue-green algae) Photosynthetic Greek: “kyanós” meaning blue Fossils as old as 3.5 mya Found in extreme environments (high salinity areas, deep sea vents, etc)
  7. 7. Cyanobacteria: Continued They account for ~ 25% of Earth’s photosynthetic production Their electronic activity is an important pathway for conversion of solar energy into chemical energy They can include unicellular or colonial species
  8. 8. Cyanobacteria and Ocean Acidification Genus Trichodesmium increased photosynthetic rates under elevated CO 2 conditions Bloom-forming Nodularia decreased cellular division rates under elevated CO 2 conditions Possible explanation for difference: Different ecological strategy of the two bacteria
  9. 9. Nitrogen Cycling <ul><ul><li>Nitrogen fixation: Atmospheric N 2 (cannot be used by most organisms) is made into NH3 by nitrogen fixing organisms (including bacteria). </li></ul></ul><ul><ul><li>Nitrofication: Ammonium (NH 4 +) is made when an organism dies and is decomposed by decomposers (mostly fungi and bacteria). The Ammonium is the converted into nitrate (NO3-) by “nitrifying” bacteria and can be used by plants and other organisms. </li></ul></ul><ul><li>Nitrogen is vital to all forms of life </li></ul><ul><ul><li>Denitrofication: Nitrate is converted into atmospheric N2 by “denitrifying bacteria.” This N 2 cannot be used by organisms until it is fixated by nitrogen fixating bacteria. </li></ul></ul>Nitrogen moves throughout the atmosphere through the Nitrogen Cycle: <ul><li>Oceans cycle a lot of Nitrogen; they cycle the most of any location on Earth. </li></ul>
  10. 10. Some Cyanobacteria fixate nitrogen <ul><li>Nitrogen fixation can only take place in anoxic (without oxygen) conditions, so many nitrogen-fixating bacteria live in sediments, fixate nitrogen at night, or have developed symbiotic relationships with marine organisms </li></ul>
  11. 11. Symbiotic Relationships Many nitrogen-fixing bacteria have symbiotic relationships with diatoms (unicellular, photosynthesizing organisms), and these bacteria contribute significantly to global nitrogen fixation Some nitrogen-fixing Cyanobacteria live in coral-reefs and have symbiotic relationships with the coral. Nitrogen fixing and nitrifying bacteria also live in sponges. Symbiotic bacteria inside microscopic life forms called diatoms take nitrogen from the air, enabling them to thrive in the nutrient-poor tropical Atlantic Ocean. Credit: David Caron US National Science Foundation
  12. 12. <ul><li>Nitrogen-fixing Cynobacteria may increase the rate of Nitrogen-fixation at higher concentrations of CO 2 . This may help to offset global warming because it would stimulate growth of photosynthetic organisms which take in CO 2 . </li></ul>
  13. 13. ARCHAEA Genetically and biochemically different from bacteria Methane producers Very small; usually less than one micron long (1/1000 of a meter) Discovered in 1970’s by Dr. Carl Woese and his colleagues at the University of Illinois while studying relationships among prokaryotes
  14. 14. Four groups of Archaea <ul><li>Methanogens </li></ul><ul><li>Extreme halophiles </li></ul><ul><li>Sulfate-reducing archaea </li></ul><ul><li>Extreme thermophiles </li></ul>
  15. 15. Archaea Environment: Extreme living conditions Hydrothermal vents in deep ocean (methanogens, sulfate reducers, and extreme thermophiles) Hot springs (methanogens, sulfate reducers, and extreme thermophiles) Highly saline land-locked seas (halophiles) Extremely alkaline or acid waters Anoxic muds in marshes or at the bottom of the ocean (methanogens) Deep underground petroleum deposits
  16. 16. However... New research shows that archaeans do not only live in extreme environments, but are also abundant in plankton in the open sea, as well as coral in coastal marine environments
  17. 17. Example of Archaea: Halobacterium They live in extremely saline waters They contain pigment (bacteriorhodopsin) that gives the archaea its color and provides it with chemical energy (similar to a pigment found in our retinae)
  18. 18. Effects of ocean acidification: Archaea might actually benefit from ocean acidification because they can survive in highly acidic water However, those archaeans which are found in plankton and coral may be negatively affected by the decline of plankton and coral populations due to acidification
  19. 19. <ul><ul><li>Czerny, J., Barcelos e Ramos, J., & Riebesell, U., 2009. Influence of elevated CO2 concentrations on cell division and nitrogen fixation rates in the bloom-forming cyanobacterium Nodularia spumigena. Biogeosciences 6(9): 1865-1875 </li></ul></ul><ul><ul><li>D eLong, E.F. “Archaea in Coastal Marine Environments.” Proceedings of the National Academy of Sciences of the United States of America (PNAS) . 89 (1992): 5685-5689. Boston University Library 27 September 2010 < http://www.pnas.org/content/89/12/5685.short >. </li></ul></ul><ul><ul><li>Hutchins, D.A. et al. 2007. CO2 control of Trichodesmium N2 fixation, photosynthesis, growth rates, and el- emental ratios: implications for past, present, and future ocean biogeochemistry. Limnol. Oceanogr. 52:1293–1304. </li></ul></ul><ul><ul><li>Introduction to the Archaea. Ben Waggoner and B.R. Speer. 1994-2006. University of California Museum of Paleontology. 27 September 2010 < http://www.ucmp.berkeley.edu/archaea/archaea .html >. </li></ul></ul><ul><ul><li>Flore, Clara L. Jarret, Jessica K. Olson, Nathan D. Lesser, Michael P. “Nitrogen fixation and nitrogen transmormations in marine symbioses. Trends in Microbiology. 2010. </li></ul></ul><ul><ul><li>Guinotte, J. M. and Fabry, V. J. (2008), Ocean Acidification and Its Potential Effects on Marine Ecosystems. Annals of the New York Academy of Sciences, 1134: 320–342. doi: 10.1196/ </li></ul></ul><ul><ul><li>&quot;Microbes in the Ocean - Sea, Oceans, Effects, Temperature, Important, Types, Plants, Source, Marine, Oxygen, Human, Pacific.&quot; Water: Science and Issues. Web. 29 Sept. 2010. < http://www.waterencyclopedia.com/Mi-Oc/Microbes- </li></ul></ul>Works Cited <ul><li>Berman-Frank, Llana; Lundgren, Pernilla; Chen, Yi-Bu; Kupper, Hendrik; Kolber, Zbigniew; Bergman, Brigitta; Falkowski, Paul. “Segregation of Nitrogen Fixation and Oxygenic Photosynthesis in Marine Cyanobacterium Trichodesmium.” </li></ul>
  20. 20. <ul><ul><li>Molles, Manuel C. Ecology Concepts and Applications Fifth Edition. Boston: McGraw Hill, 2010. </li></ul></ul><ul><ul><li>Wegley, Linda, Yanan Yu, Mya Breitbart, Veronica </li></ul></ul><ul><ul><li>Casas, David I. Kline, Forest Rohwer. “Coral-associated Archaea.” Marine Ecology Progress Series 273 (2004): 89-96. < http://www.marine.usf.edu/genomics/PDFs%20of%20papers/wegleyetal2004.pdf >. </li></ul></ul>