1. 27 Prokaryotes and the Origins of Metabolic Diversity

2. Archaea live in extreme environments and have cell walls with no peptidoglycan, have histone and methionine for initial amino acid. Formerly eubacteria

3. Most bacteria range from 1- 5 um while eukaryotes range from 10- 100 um

4. Coccus shape

6. Bacillus shape

7. Helical or spiral shape eg. Spirochetes Helical or spiral shape eg. Spirochetes

9. Simple cell wall with relatively large amounts of peptidoglycan Penicillin prevents crosslinking in the peptidoglycan and prevents the formation of a functional cell wall in gram positive bacteria Simple cell wall with relatively large amounts of peptidoglycan Penicillin prevents crosslinking in the peptidoglycan and prevents the formation of a functional cell wall in gram positive bacteria More complex cell wall with less peptidoglycan AND with an outer membrane with lipopolysaccharides - carbohydrates bonded to lipids -often toxic

11. gonorrhea bacterium Sticky capsules found on the outside of bacteria will provide protection and glue together the cells Pilli can be used for adhesion or conjugation

12. Flagellin is wound in a tight spiral to form a helical filament, which is attached to another protein which forms a curved hook. The basal apparatus rotates the filament - it is powered by protons that have been pumped toward the plasma membrane In contrast Eukaryotic flagella have a 9+2 microtubular structure

13. Bacteria can show taxis - the movement towards or away from a stimulus eg. Chemotaxis Bacteria can show taxis - the movement towards or away from a stimulus eg. Chemotaxis

14. Nucleoid region containing genophore -prokaryotic DNA Nucleoid region containing genophore -prokaryotic DNA Prokaryotes have smaller ribosomes that respond to different antibiotics that prevent them from doing protein synthesis

15. Reproduction by binary fission is a form of asexual reproduction However genetic recombination can occur by transformation, conjugation and transduction

17. 4 Categories of Prokaryotes Photoautotrophs - cyanobacteria Chemoautotrophs - extracts energy by oxidizing inorganic substances Photoheterotrophs - can use light to generate ATP, but must eat for carbon Chemoheterotroph - consumer P 508

18. Nutritional Diversity Most are chemoheterotrophs some are saprovores obtaining their energy from dead organic matter - a key feature ecologically in that it recycles material some are parasites

19. Nitrogen Metabolism Nitrogen is a key component of proteins and nucleic acids Nitrogen gas is unusable by most organisms

20. Nitrogen Fixation Many prokaryotes including cyanobacteria can take N 2 and change it to NH 3 in a process called nitrogen fixation cyanobacteria

21. Nitrogen Fixation N itrogen fixation must occur in an anaerobic environment Hetrocyst are sealed cells were nitrogen fixation occurs

23. Nitrogen Metabolism Chemoautotrophic bacteria such as Nitrosomonas can convert NH 3 into NO 2 + Pseudomonas can denitrify NO 2 + and NO 3 + back to N 2.

24. Nitrosomonas Pseudomonas Rhizobia Azotobacter

25. Metabolic Relationships to Oxygen Obligate aerobes must have O 2 to live Facultative aerobes will use O 2 if present but can live anaerobically. Obligate anaerobes will be poisoned by O 2.

26. Possible sources of ATP for early cells ATP available in the primordial soup FeS and H 2 S are used by chemoautotrophs to produce ATP

27. Origin of Photosynthesis Photosensitive pigments embedded in the plasma membrane ex. Bacteriorhodopsin found in some archea pumps H+ outside of cell and that is used to generate ATP. Some others used light to drive electrons from H 2 S (hydrogen sulfide) to NADP+. First photosynthetic organisms could only make ATP not carbon compounds (Photosystem I).

28. Cyanobacteria Many prokaryotes including cyanobacteria can make ATP and carbohydrates. Using photosystem II they could generate oxygen Mats of these fossilized into stramatolites Oxidizing atmosphere forms about 2.1 – 2.7 billion years ago

29. Carl Woese used signature sequences, regions of SSU-rRNA that are unique, to establish a phylogeny of prokaryotes. This is a line of evidence which separates Archaea into its own domain. Fig. 27.13

30. Copyright © 2002 Pearson Education, Inc., publishing as Benjamin Cummings Essay Question: What are the lines of evidence that allowed scientist to place Archaea into its own Domain EX: Specific SSU rRNA sequences are found in archaea and not bacteria PMRIIAHTS PRIMA THIS

31. Methanogens obtain energy by using CO 2 to oxidize H 2 replacing methane as a waste. Methanogens are among the strictest anaerobes. They live in swamps and marshes where other microbes have consumed all the oxygen. –Methanogens are important decomposers in sewage treatment. Other methanogens live in the anaerobic guts of herbivorous animals, playing an important role in their nutrition. –They may contribute to the greenhouse effect, through the production of methane.

32. Extreme halophiles live in such saline places as the Great Salt Lake and the Dead Sea. Some species merely tolerate elevated salinity; others require an extremely salty environment to grow. –Colonies of halophiles form a purple-red scum from bacteriorhodopsin, a photosynthetic pigment very similar to the visual pigment in the human retina. Copyright © 2002 Pearson Education, Inc., publishing as Benjamin Cummings Fig. 27.14

33. Extreme thermophiles thrive in hot environments. –The optimum temperatures for most thermophiles are 60 o C-80 o C. –Sulfolobus oxidizes sulfur in hot sulfur springs in Yellowstone National Park. –Another sulfur-metabolizing thermophile lives at 105 o C water near deep-sea hydrothermal vents. Copyright © 2002 Pearson Education, Inc., publishing as Benjamin Cummings

34. Ongoing life depends on the recycling of chemical elements between the biological and chemical components of ecosystems. –If it were not for decomposers, especially prokaryotes, carbon, nitrogen, and other elements essential for life would become locked in the organic molecules of corpses and waste products. –Prokaryotes also mediate the return of elements from the nonliving components of the environment to the pool of organic compounds. 1. Prokaryotes are indispensable links in the recycling of chemical elements in ecosystems Copyright © 2002 Pearson Education, Inc., publishing as Benjamin Cummings

35. Prokaryotes have many unique metabolic capabilities. –They are the only organisms able to metabolize inorganic molecules containing elements such as iron, sulfur, nitrogen, and hydrogen. –Cyanobacteria not only synthesize food and restore oxygen to the atmosphere, but they also fix nitrogen. This stocks the soil and water with nitrogenous compounds that other organisms can use to make proteins. –When plants and animals die, other prokaryotes return the nitrogen to the atmosphere. Copyright © 2002 Pearson Education, Inc., publishing as Benjamin Cummings

36. In commensalism, one symbiont receives benefits while the other is not harmed or helped by the relationship. In parasitism, one symbiont, the parasite, benefits at the expense of the host. In mutualism, both symbionts benefit. For example, while the fish provides bioluminescent bacteria under its eye with organic materials, the fish uses its living flashlight to lure prey and to signal potential mates. Bacteria in our intestine produces Vitamin K. Fig. 27.15

37. Prokaryotes are involved in all three categories of symbiosis with eukaryotes. –Legumes (peas, beans, alfalfa, and others) have lumps in their roots which are the homes of mutualistic prokaryotes (Rhizobium) that fix nitrogen that is used by the host. The plant provides sugars and other organic nutrients to the prokaryote. –Fermenting bacteria in the human vagina produce acids that maintain a pH between 4.0 and 4.5, suppressing the growth of yeast and other potentially harmful microorganisms. Other bacteria are pathogens. Copyright © 2002 Pearson Education, Inc., publishing as Benjamin Cummings

38. Some pathogens produce symptoms of disease by invading the tissues of the host. –The actinomycete that causes tuberculosis is an example of this source of symptoms. More commonly, pathogens cause illness by producing poisons, called exotoxins and endotoxins. Copyright © 2002 Pearson Education, Inc., publishing as Benjamin Cummings

39. Exotoxins are proteins secreted by prokaryotes. Exotoxins can produce disease symptoms even if the prokaryote is not present. –Clostridium botulinum, which grows anaerobically in improperly canned foods, produces an exotoxin that causes botulism. –An exotoxin produced by Vibrio cholerae causes cholera, a serious disease characterized by severe diarrhea. –Even strains of E. coli can be a source of exotoxins, causing traveler’s diarrhea. Copyright © 2002 Pearson Education, Inc., publishing as Benjamin Cummings

40. Endotoxins are components of the outer membranes of some gram-negative bacteria. –The endotoxin-producing bacteria in the genus Salmonella are not normally present in healthy animals. –Salmonella typhi causes typhoid fever. –Other Salmonella species, including some that are common in poultry, cause food poisoning. Copyright © 2002 Pearson Education, Inc., publishing as Benjamin Cummings

41. Since the discovery that “germs” cause disease, improved sanitation and improved treatments have reduced mortality and extended life expectancy in developed countries. –More than half of our antibiotics (such as streptomycin and tetracycline) come from the soil bacteria Streptomyces. This genus uses to prevent encroachment by competing microbes. Copyright © 2002 Pearson Education, Inc., publishing as Benjamin Cummings

42. The decline (but not removal) of bacteria as threats to health may be due more to public- health policies and education than to “wonder- drugs.” For example, Lyme disease, caused by a spirochete spread by ticks that live on deer, field mice, and occasionally humans, can be cured if antibiotics are administered within a month after exposure. If untreated, Lyme disease causes arthritis, heart disease, and nervous disorders. The best defense is avoiding tick bites and seeking treatment if bit and a character- istic rash develops. Copyright © 2002 Pearson Education, Inc., publishing as Benjamin Cummings Fig. 27.17

43. The application of organisms to remove pollutants from air, water, and soil is bioremediation. –The most familiar example is the use of prokaryote decomposers to treat human sewage. –Anaerobic bacteria decompose the organic matter into sludge (solid matter in sewage), while aerobic microbes do the same to liquid wastes. Copyright © 2002 Pearson Education, Inc., publishing as Benjamin Cummings Fig. 27.18

44. –Soil bacteria, called pseudomonads, have been developed to decompose petroleum products at the site of oil spills or to decompose pesticides. Copyright © 2002 Pearson Education, Inc., publishing as Benjamin Cummings Fig. 27.19

45. Humans also use bacteria as metabolic “factories” for commercial products. –The chemical industry produces acetone, butanol, and other products from bacteria. –The pharmaceutical industry cultures bacteria to produce vitamins and antibiotics. –The food industry used bacteria to convert milk to yogurt and various kinds of cheese. The development of DNA technology has allowed genetic engineers to modify prokaryotes to achieve specific research and commercial outcomes. Copyright © 2002 Pearson Education, Inc., publishing as Benjamin Cummings