1 / 16

Geomicrobiology

Geomicrobiology. Course Goals. At the end of this course you will be able to… Intelligently converse with microbiologists, geologists, environmental scientists and engineers about the role microorganisms play in the cycling of elements

ursa
Download Presentation

Geomicrobiology

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Geomicrobiology

  2. Course Goals • At the end of this course you will be able to… • Intelligently converse with microbiologists, geologists, environmental scientists and engineers about the role microorganisms play in the cycling of elements • Use several techniques to identify and characterize microorganisms in any environment • Relate microbial physiology, genetics, cell structure, and metabolism to the effect, role, or signature that microbes uniquely imprint on their surroundings

  3. Grading • Crib Sheets 20% • Discussion participation 20% • Mid term exam 20% • Final Exam 20% • Poster 20%

  4. Basic Microbiology Primer • Microorganisms exist as single cells or cell clusters – almost all of them are invisible to the naked eye as individuals but can be readily seen as communities • As opposed to most ‘higher order’ life om earth, microbes can eat and breathe things besides organic carbon and oxygen  this makes them critical to cycling of compounds that are able to be oxidized or reduced in water

  5. Cell sizes and shape • Most cells are between 0.1 and 5 mm in diameter • Several shapes are common: • Rod or bacilli • Spherical or cocci • Spiral • Other forms – including square, sheathed, stalked, filamentous, star, spindle, lobed, pleomorphic forms

  6. 100 µm 20 µm 0.5 µm Microbes on the head of a pin, false color SEM images, from j. Rogers, http://people.westminstercollege.edu/faculty/jrogers/V%20prokaryotes.ppt#298,3,Slide 3

  7. Figure 27.3 The most common shapes of prokaryotes http://people.westminstercollege.edu/faculty/jrogers/V%20prokaryotes.ppt#298,3,Slide

  8. Diversity • There are likely millions of different microbial species • Scientists have identified and characterized ~10,000 of these • Typical soils contain hundreds- thousands of different species • Very extreme environments contain as little as a few different microbes

  9. Microbial evolution • Oldest fossil evidence - ~3.5 g.a (Stromatolites) • Evidence for microbial activity argued for deposits > 3.7 g.a. • Couple fossil evidence with genomic information (analysis of function from genetic info) • Put against backdrop of early earth conditions • Significant atmospheric O2 after 2.0 g.a. • Look at most ‘primitive’ microbes in selected environments (similar to early earth)

  10. Tree of life

  11. Characterizing microbes • Morphological and functional – what they look like and what they eat/breathe • Based primarily on culturing – grow microbes on specific media – trying to get ‘pure’ culture • Genetic – Determine sequence of the DNA or RNA – only need a part of this for good identification • Probes – Based on genetic info, design molecule to stick to the DNA/RNA and be visible in a microscope

  12. Classification of life forms: • Eukaryotic = Plants, animals, fungus, algae, and even protozoa • Prokaryotic = archaea and bacteria • Living cells can: • Self-feed • Replicate (grow) • Differentiate (change in form/function) • Communicate • Evolve Can purely chemical systems do these things? All of these things? Why do we care to go through this ?

  13. Tree of life

  14. New perspectives on ‘the tree of life’ • Recently suggested (Norm Pace, 2006) that the word prokaryote be thrown out – archea and bacteria are as different from one another as they are from eukayotes • Most trees are constructed from 16S rRNA sections – 1500 base pairs out of 1 million serves to decipher all differences – what about coding in other areas?? – starting to see distinct differences in exact 16S genotypes suggesting whole genome comparison needed – problem is that currently requires cultures for most samples • Strain level differences – how do we decide what is really in the same species yet may be slightly different – how do we do this for eukaryotic organisms? How might we do this for archaea and bacteria???

  15. Environmental limits on life • Liquid H2O – life as we know it requires liquid water • Redox gradient – conditions which limit this? • Range of conditions for prokaryotes much more than that of eukaryotes – inactive stasis • Spores can take a lot of abuse and last very long times • Tougher living = less diversity • Closer to the limits of life – Fewer microbes able to function

  16. Microbes and Thermodynamics • First and foremost, the basic tenet relating microbial activity with thermodynamic descriptions of physical and chemical systems is: Equilibrium = Death • Why then are microbes on seemingly every corner of the planet’s surface? Why might we expect to find them on other planets?

More Related