prokaryotes antiquity meso- zoic ceno- zoic...
TRANSCRIPT
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Prokaryotes (Domains Bacteria & Archaea)
KEY POINTS 1. Decomposers: recycle organic and
inorganic molecules in environment; makes them available to other organisms.
2. Essential components of symbioses. 3. Encompasses the origins of metabolism and
metabolic diversity. 4. Origin of photosynthesis and formation of
atmospheric Oxygen
Animals
Colonization of land
Paleozoic Meso-
zoic Humans
Ceno- zoic
Origin of solar system and Earth
Prokaryotes Proterozoic Archaean Billions of years ago
1 4
3 2
Multicellular eukaryotes
Single-celled eukaryotes
Atmospheric oxygen
ANTIQUITY
• >3.5 BILLION years old.
• Alone for 2 billion years
General characteristics 1. Small: compare to
10-100µm for eukaryotic cell; single-celled; may form colonies.
2. Lack membrane-enclosed organelles.
3. Cell wall present, but different from plant cell wall.
0.5-5µm
General characteristics
4. Occur everywhere, most numerous organisms.
– More individuals in a handful of soil then there are people that have ever lived.
– By far more individuals in our gut than eukaryotic cells that are actually us.
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General characteristics
5. Metabolic diversity established nutritional modes of eukaryotes.
General characteristics
6. Important decomposers and recyclers
General characteristics
6. Important decomposers and recyclers • Form the basis of
global nutrient cycles.
General characteristics
7. Symbionts!!!!!!! • Parasites • Pathogenic
organisms. • About 1/2 of all
human diseases are caused by Bacteria
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General characteristics
7. Symbionts!!!!!!! • Parasites • Pathogenic
organisms. • Extremely important
in agriculture as well.
Pierce’s disease is caused by Xylella fastidiosa, a Gamma Proteobacteria. It causes over $56 million in damage annually in California. That’s with $34 million spent to control it! = $90 million in California alone.
General characteristics
7. Symbionts!!!!!!! • Commensalists • They are
everywhere (really). • There can be 10
million cells per square centimeter of skin.
General characteristics
7. Symbionts!!!!!!! • Mutualists • Eukaryotic life
would be impossible without this.
General characteristics 7. Symbionts!!!!!!!
• Mutualists • Allows herbivorous
(plant-feeding) animals to digest cellulose and other low-quality plant tissues.
• Termites • Ungulates “chewing the
cud” • Lagomorph coprophagy
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General characteristics 7. Symbionts!!!!!!!
• Mutualists • Mealybug endosymbionts
with endosymbionts.
General characteristics 7. Symbionts!!!!!!!
• Mutualists • Komodo dragons and their “toxins”.
• Hunt large prey and can inflict fairly minor wound.
• Prey die fairly quickly from wound.
• Infection by highly pathogenic Pasteurella multocida (Gamma Proteobacteria).
• Prominent in saliva of dragons, but dragons have an anti-Pasteurella antibody.
TAXONOMY is problematic
• Relationships obscured by billions of years of evolution
• Also obscured by unique bacterial means of recombination (more later).
• Grouped primarily by DNA sequence data.
• Immense genetic/genomic diversity.
Current taxonomy is stabilizing
• Note that “Prokaryote” is paraphyletic. Why?
• Two Domains: • Archaea: extremophiles
(mostly), ancient, probable progenitors of eukaryotes.
• Bacteria: most commonly-encountered prokaryotes.
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Characteristics
• Cell Surface • Motility • Genome • Reproduction & Growth • Metabolic Diversity • Nitrogen Metabolism • Oxygen Relationships
Cell Surface
• Archaea: plasma membrane of ether-lipids (unique in life).
• Bacteria: a sugar polymer - peptidoglycan
Cell Surface • Cell wall is often
modified with structures to adhere to substrate.
• Many secrete a sticky capsule or adhere by fimbriae (ocasionally called pili).
Motility • ~half the species can move. 1. Flagella most common
(different structure from eukaryote)
2. Spiral filaments: spirochetes corkscrew
3. Gliding over slimy secretions (via flagellar motors without filament)
• Capable of taxis (photo, chemo, geo, etc.)
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Genome
• Small genomes: ~1/1000th DNA content of eukaryotes.
• No membrane enclosed nucleus.
• DNA concentrated in ‘nucleoid’ region.
Genome • One major chromosome,
double stranded DNA molecule in ring.
• Sometimes several small DNA rings of few genes: plasmids. – Replicate independently of
main chromosome. – Permit recombination via
conjugation (later). – Involved in resistance to
antibodies/antibiotics.
Genome
• Broadly, replication & translation of genetic info like that of eukaryotes; differ in details and simplicity.
• Used in first DNA recombinant research. • Genetic recombination: Not like eukaryotes
(e.g. chiasma & crossing over)!! – Transformation – Conjugation – Transduction
Genome: Recombination via transformation
• DNA taken up from the environment
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Genome: Recombination via conjugation
• Direct transfer of DNA between cells.
• Both plasmids and portions of bacterial chromosome.
Genome: Recombination via transduction
• Transfer of DNA via phage viruses.
Reproduction & Growth • Meiosis & Mitosis NOT
PRESENT. • Asexual binary
fission. • DNA replication can be
nearly continuous in ideal conditions (depends on pH, salinity, temperature, etc.)
• Generation times as fast as 20 minutes
Metabolic Diversity
• Nutrition: • Requires a source of carbon for
synthesizing organic compounds: either carbon dioxide or living matter.
• Requires a source of energy to drive reactions: either light or chemical.
Metabolism
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Metabolic Diversity: Source of Carbon
• AUTOTROPHS: Need only carbon dioxide (CO2) as carbon source
• HETEROTROPHS: Need at least one organic nutrient as carbon source (e.g. glucose; petroleum)
• Both of these present in domain Eucarya as well.
Metabolism Metabolic Diversity: Source of Energy
• PHOTOTROPHS: Need only sunlight as energy source
• CHEMOTROPHS: Derive energy from oxidation of organic molecules.
• Both of these present in domain Eucarya as well.
Metabolism
Metabolic Diversity: Combined
Which of these are present in multicellular Eucarya?
Metabolism
Energy Source:
Sun Environment
CO2 Photoautotroph Chemoautotroph
Organic molecules
Photoheterotroph Chemoheterotroph
Car
bon
Sou
rce:
Photoautotrophs
• Use sun for energy, CO2 for carbon.
• Photosynthetic bacteria (e.g. cyanobacteria).
• Present in many plants and single-celled Eucarya
Metabolism
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Chemoautotrophs • Oxidize inorganics
(H2S, NH3) for energy. • Need only CO2 as
carbon source. • Unique to Bacteria and
Archaea. • E.g. Methanococcus
jannaschii lives on hydrothermal vents at 2600m below sea level.
• Reduces H2 + CO2 to CH4 + 2H2O.
Metabolism
Photoheterotrophs
• Get enery from light but must obtain carbon in organic form (NOT CO2).
• Unique to Bacteria and Archaea.
• E.g. Halobacterium salinarium.
Metabolism
Chemoheterotrophs • Consume organic
molecules for both energy and carbon.
• Common among prokaryotes: – saprobes
(decomposers) – parasites (rely on
living hosts) • Also widespread in
Protista, Animalia, Plantae.
Metabolism
Nitrogen metabolism • Nitrogen fixation: • The only* mechanism that
makes atmospheric Nitrogen available to other organisms.
• Convert N2 into ammonia (NH3) which is quickly protonated into ammonium (NH4
+). • Essential for multicellular
life!
Metabolism
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Oxygen Relationships • Aerobic vs. Anaerobic • Obligate aerobes: use O2 for
cellular respiration. • Facultative anaerobes: use
O2 if it is present by carry out anaerobic respiration or fermentation in anaerobic environment.
• Obligate anaerobes: poisoned by O2; use anaerobic respiration or fermentation.
• Cellular respiration: – Carbohydrates + O2 →CO2
+ H2O + energy • Fermentation:
– Carbohydrates →CO2 + ethanol + energy
• Anaerobic respiration: – Carbohydrates + [X] →
bicarbonate + [X-] + energy – Where [X] is a substance
other than O2 that accepts electrons such as nitrates or sulfates
Oxygen Relationships
• Early life (during the Archaean) was primarily anaerobic.
• Evolution of photosynthesis in Cyanobacteria changed all this.
Taxonomy of Prokaryotes • Archaea or Archaebacteria
– Methanogens – Halophiles – Thermophiles
• Bacteria or Eubacteria – Protobacteria – Chlamyidias – Spirochetes – Cyanobacteria – Gram-positive bacteria
Archaea or Archaebacteria • Live in extreme
environments (extremophiles): sulfur hot springs, deep sea vents, high salt environments.
• Lack peptidoglycan, unique plasma membrane of liquids
• Likely sister group of Eukaryotes
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Archaea or Archaebacteria
• Methanogens – Use H2 to reduce
CO2 to methane (CH4).
– Chemoautotrophs – Anaerobic – In swamps, marshes,
deep sea vents, important decomposers.
Archaea or Archaebacteria
• Halophiles – Saline environments. – Salinity several times
higher than sea water.
– Photoheterotrophs
Archaea or Archaebacteria
• Thermophiles – 60º-80ºCpH 2-4
optimal – Chemoautotrophs – Oxidize HS
Bacteria or Eubacteria
• Grouped by molecular systematics.
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Bacteria or Eubacteria
Proteobacteria • VERY diverse, grouped
into five taxa based on DNA sequence data.
• Includes most types of metabolism that we’ve discussed.
• Includes most of the types of symbioses we’ve discussed
• Review the summary in Figure 27.16.
Bacteria or Eubacteria Gram positive Bacteria: • Simple peptidoglycan cell wall. • Rival Proteobacteria in
diversity. • Most are free-living
decomposers. • Some pathogenic (e.g. strains
of Staphylococcus, Streptococcus, Bacillus anthracis, Clostridium botulinum).
• Include the mycoplasms--the only bacteria that lack cell walls
Bacteria or Eubacteria Cyanobacteria:
• Photoautotrophs • Only prokaryotes with
plant-like, O2-generating photosynthesis.
• Present in freshwater and marine environments.
• Often colonial--first steps toward multicellularity?
Bacteria or Eubacteria
Spirochetes: • Helical • Recall motility: move by
means of rotating, internal, flagellum-like filaments.
• Free-living and parasitic.
• Chemoheterotrophs (like us).
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Bacteria or Eubacteria
Chlamydias: • ALL are parasites of
animals. • Intercellular. • Lack peptidoglycan in
the cell wall (are they gram-positive or gram-negative?).
• Most common form of STD in USA (urethritis).
Prokaryotes: Summary
• You should now have a good sense of prokaryote biology and diversity.
• Including roles in metabolism, symbioses, global energy cycles.
• Important distinguishing characteristics of cell wall, motility, genome, replication.
• General aspects of their systematics.