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Prokaryotes

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Title: Prokaryotes


1
Prokaryotes
  • Bacteria and Archaea
  • Chapter 27

2
Small Size
3
Two Domains
4
Phylogeny of Domains
5
Bacteria include every mode of nutrition and
metabolism
6
Archaea
  • Single celled microorganisms
  • Reproduce asexually
  • Identified as separate Domain in 1977
  • First archaea were discovered in extreme
    conditions. Called extremophiles

6
7
Halophiles salt lovers
8
Thermophiles
Live at very high temperatures
9
Methanogens
  • Use CO2 to Oxidize H2 release CH4
  • Release methane
  • O2 is toxic to them
  • Found in anoxic conditions such as swamps, deep
    caves, and intestines of animals

10
Bacteria
11
Peptidoglycan Cell Walls
12
Movement
13
Internal Membranes
14
Endospores
  • Dormant tough but not reproductive structures
  • Ensures survival of bacterium. Resistant to
    ultraviolet, gamma radiation, temperature
    fluctuation, household disinfectants...
  • found in soil, and water

15
Bacterial DNA
Bacteria have circular DNA
16
Bacteria Plasmids
  • Extra-chromosome DNA that is separate from the
    bacterial chromosomal DNA
  • Separate self replication
  • can be transfered to other bacteria and other
    bacteria species

16
17
Symbiotic relationships
18
Bioluminescent bacteria
18
19
Human symbiotic relationships
20
Termites have specialized bacteria that helps
them digest celluloseTermites comprise 50 of
the animal biomass in Africa
21
Humans have a long history of using prokaryotes
22
Commercial use of prokaryotesWastewater Treatment
23
Commercial use of prokaryotesBioremediation
24
Ecosystem Services
25
Protists
  • Chapter 28

26
Aquatic Producers are often Protists
Green Algae Diatoms
Diatoms
27
What are Protists
  • They are not plants, animals or fungi
  • Diverse assortment of eukaryotes
  • Most are unicellular with complex cells
  • Found in damp soil, oceans and even human bodies

28
Nutritional Diversity
  • Autotrophs
  • Heterotrophs
  • Mixitrophs

29
Asexual Reproduction
30
Sexual Reproduction
31
Ciliates
Cillated Pellicle
32
Paramecium
33
Diatoms 10,000 species
Photosynthetic with golden accessory pigments
34
Diatom
Silica in Cell Wall
35
Psuedopod-equipped Protists
  • Heterotrophic
  • Psuedopods or axopods
  • With or without cell walls
  • Ameoba is a well known psuedopod

36
Slime Molds
  • Mycetozoans were thought to be fungi
  • Now understood to be case of evolutionary
    convergence
  • Two main branches
  • Plasmodial slime molds
  • Cellular slime molds

37
Plasmodial slime moldone super cell
38
Multicellular Brown Algae Phaeophyta
  • May grow up to 60 meters
  • Provide 3 demensional habitats for marine species
  • Plant like structures, holdfast, stipe, and
    blades
  • Pneumatocysts are gas-filled bladders, located at
    the base of blades provides Boyance

Blade
Stipe
Hold -fast
39
Laminaria at low tide
40
Kelp Forest
41
Chlorophyta
  • Green algae
  • Autotrophic
  • Plant-like chloroplasts and pigments
  • Cellulose cell walls
  • Red and Green algae are the closest relatives to
    plants

42
Cladophora form large filamentous mats
43
  • http//www.youtube.com/watch?vPoiAKcIls6sfeature
    related

44
Fungi and nutrient cycling
  • Chapters 31 and 54

45
Fungi
  • Heterotrophic Decomposers or Symbionts

46
Fungal Characteristics
  • Heterotrophic
  • Decomposers
  • Opportunistic parasites
  • Many produce mycotoxins as metabolic by-products
  • Aerobic or facultative anaerobes
  • Cell wall composed of chitin
  • more closely related to animals than plants
  • Grow best in warm, moist environments

47
Dimorphic
  • Found in two physical forms
  • Unicellular Yeasts
  • Multicellular Molds and Mushrooms
  • Hyphae
  • Mycelium hyphal mass

48
Reproduction by Spore Formation
  • Asexual
  • Haploid spores formed on hyphae
  • Fragmentation
  • Broken fragments of hyphae
  • Sexual
  • Two mating hyphae types fuse and produce spores

49
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50
Penicillium (Blue-green Mold)
51
Basidiocarps
52
Fig. 31-20
53
  • http//www.youtube.com/watch?vJeF952Xfz4feature
    relmfu

54
Lichens (Fungal-Algal Symbiosis)
55
Lichen Structure
56
Mycorrhizae
  • Plant roots and symbiotic fungi
  • Increased nutrient (P) absorption
  • Greater surface area
  • Enzyme excretions
  • Increased plant bimass
  • may have originally started as parasitism
  • Most plants have Mycorrhizae infections

57
Mycorrhizae
58
The Nation that Destroys Its Soil Destroys
Itself F.D.R.
  • Farmland productivity often suffers from chemical
    contamination, mineral deficiencies, acidity,
    salinity, and poor drainage
  • Healthy soils improve plant growth by enhancing
    plant nutrition

59
Soil is a living, finite resource
  • Plants obtain most of their water and minerals
    from the upper layers of soil
  • Living organisms play an important role in these
    soil layers
  • This complex soil ecosystem is fragile
  • Topsoil contains bacteria, fungi, algae, other
    protists, insects, earthworms, nematodes, and
    plant roots
  • These organisms help to decompose organic
    material and mix the soil

60
Rocks Contribute Minerals
  • Weathering
  • Erosion
  • Transportation
  • Sedimentation

61
Grain Size
  • Sand
  • 2.1 mm to .05 mm
  • Silt
  • Less than .05 mm but greater than .002 mm
  • Clay
  • Less than .002 mm

62
Soil Texture
  • Soil particles are classified by size from
    largest to smallest they are called sand, silt,
    and clay
  • Soil is stratified into layers called soil
    horizons
  • Topsoil consists of mineral particles, living
    organisms, and humus, the decaying organic
    material

63
Soil
  • Minerals
  • Water
  • Air
  • Dead Organic material
  • Organisms

64
(No Transcript)
65
Water and soil interact
  • Soil particle size influences
  • water transport nutrients
  • soil moisture
  • Water flows through and evaporates quickly from
    sandy soils
  • Clay soils bind water which prevent plants from
    absorbing

66
Litter and Topsoil
  • Most plant root biomass
  • Most nutrient turnover
  • Most decomposer biomass
  • Most microbial activity

67
Litter Decomposers
68
2. Global C sources and sinks (CO2)
Atmosphere 750
Net deforestation 0.9
3.2/yr
Combustion 6
GPP 120
Plant R 45
Soil R 75
560
92
90
Rivers .8
Soils 1500
Oceans 38000
Values are 1015 g C, fluxes are annual
Schlesinger 1997
69
3. Nutrient cycling
Litterfall
Decomposition
Nutrient uptake
70
Decomposition over Time
71
Litter and Topsoil Organisms
72
Size of Soil Microorganisms
73
Soil Protozoa
  • Decomposers
  • Consumers

74
Producers
75
Soil Fungi
  • Decomposers
  • Symbionts

76
Soil Actinomycetes
  • Fungus-like bacteria
  • Some are symbiotic with plants
  • Some produce antibiotics

77
Soil Bacteria
  • Producers
  • Decomposers
  • Mineralizers

78
Soil Bacteria and Plant Nutrition
  • The layer of soil bound to the plants roots is
    the rhizosphere
  • The rhizosphere has high microbial activity
    because of sugars, amino acids, and organic acids
    secreted by roots

79
Rhizobacteria
  • Free-living rhizobacteria thrive in the
    rhizosphere, and some can enter roots
  • Rhizobacteria can play several roles
  • Produce hormones that stimulate plant growth
  • Produce antibiotics that protect roots from
    disease
  • Absorb toxic metals or make nutrients more
    available to roots

80
Bacteria in the Nitrogen Cycle
  • Nitrogen is often an important limiting nutrient
    for plant growth
  • The nitrogen cycle transforms nitrogen and
    nitrogen-containing compounds
  • Most soil nitrogen comes from actions of soil
    bacteria

81
Nitrogen-Fixing Bacteria A Closer Look
  • N2 is abundant in the atmosphere, but unavailable
    to plants
  • Nitrogen fixation is the conversion of nitrogen
    from N2 to NH3
  • Symbiotic relationships with nitrogen-fixing
    bacteria provide some plant species with a
    built-in source of available N
  • Most commonly legumes beans, peas

82
N2
N2
Atmosphere
Atmosphere
Nitrate and nitrogenous organic compounds exported
in xylem to shoot system
Soil
Nitrogen-fixing bacteria
N2
Denitrifying bacteria
H (from soil)
NH4
Soil
NO3 (nitrate)
NH3 (ammonia)
NH4 (ammonium)
Ammonifying bacteria
Nitrifying bacteria
Organic material (humus)
Root
83
Nitrogen Cycle
84
Nitrogen Fixation
  • N2 NH4
  • Nitrogen gas is fixed as ammonium ion.
  • Photosynthetic
  • Nitrogen Fixing
  • Nostoc and Anabaena
  • Specialized cells
  • heterocysts

85
Non-Photosynthetic Nitrogen Fixers
  • Free-living heterotrophic bacteria
  • Azotobacter
  • Azomonas
  • Symbiotic heterotrophic bacteria
  • Rhizobium
  • Mesquite Trees are Facultative N-Fixers

86
Ammonification
C2H2O2 NH4
Amino acid
  • Carried out by many heterotrophic microbes.

87
Nitrification
  • NH4 -gt NO2- -gt NO3-2
  • Oxidation carried out by aerobic,
    chemoautotrophic (mineralizing) bacteria

88
Denitrification
  • NO3-2 NO2- N2
  • Pseudomonas and Paracoccus
  • Carried out by anaerobic, heterotrophic microbes
  • How can we measure denitrification?

89
Nitrogen cycle summary
  • Nitrogen fixation
  • (Gas) N2 ? NH4
  • Ammonification
  • (organism) Amino Acid ? NH4
  • Nitrification
  • NH4 ? NO2 ? NO3 (Mineral)
  • Denitrification
  • (Mineral) NO3 ? NO2 ? N2 (Gas)
  • Carried out by cyanobacteria, Rhizobium,
    heterotrophs, bacteria, fungi
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