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Microbial Overview: Physiology and Evolution

Microbial Overview: Physiology and Evolution. Prokaryotes vs Eukaryotes Nutritional Types What Controls Who Lives Where & When? Microbial Evolution on Earth Eukaryote: Endosymbiotic Theory Mechanisms of Prokaryote Evolution. Phylogenetic Tree of Life (3 Domains).

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Microbial Overview: Physiology and Evolution

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  1. Microbial Overview:Physiology and Evolution Prokaryotes vs Eukaryotes Nutritional Types What Controls Who Lives Where & When? Microbial Evolution on Earth Eukaryote: Endosymbiotic Theory Mechanisms of Prokaryote Evolution

  2. Phylogenetic Tree of Life(3 Domains)

  3. Prokaryote “Anatomy” Overview Cell envelope: Collectively all the structures outside from the plasma membrane.

  4. Eukaryote Cell “Anatomy” Peroxisome: Oxidizes amino acids, fatty acids and alcohol; self replicating. Vacuole: membrane bound; liquid filled; storage of reserves and/or wastes. Cell Wall: cellulose and lignin in plants; chitin in fungi; no peptidoglycan

  5. Nutritional Types

  6. What Lives Where and Why? “Everything is everywhere, the environment selects” Martinus Beijerinck (ca. 1890) • Tolerance to All Environmental Factors (Shelford’s Law of Tolerance) • Growth Limiting Resource (Liebig’s Law of the Minimum)

  7. Environmental Factors • Nutrients (org/inorg; macro/micro/trace) • Temperature • Solute Concentration and Water Activity • pH (acidity versus alkalinity) • Oxygen Concentration • Barometric Pressure • Electromagnetic Radiation

  8. Oxygen Requirement Types 2 to 10% atm O2

  9. “Microbial Lasagna”

  10. Microbial interactions control populations, too • Positive interactions: • Commensalism • Protocooperation • Mutualism • Negative Interactions: • Amensalism: • Competition: • Intraspecific • Interspecific • Predation (e.g. Bdellovibrio) • Parasitism

  11. Predation and Disease (Parasitism) Control Populations Too! • Protozoa and other “grazers” • May be selective. • Viral Lysis • Highly selective.

  12. Over 3.5 billion years of “microbes” Micro-fossils of “cyanobacteria” and contemporary stromatolites.

  13. * Early Earth Conditions? * Theories of the origin of life? Biogenisis (“Primordial Soup”) – not enough time! Panspermia? Hydrothermal Vent (no UV, reduced inorganics, reactive surfaces) * Evolution of Life Mutation Natural Selection * Photosynthesis, Poisonous O2, and Aerobic Respiration * Endosymbiotic Hypothesis for Eukaryotes

  14. Acquisition of aerobic respiration from alpha-proteobacterium. Acquisition of photosynthesis and Calvin Cycle from cyanobacterium. Happened more than once?

  15. Major challenges for endosymbiotic theory • Most extant prokaryotes have rigid cell walls and don’t do phagocytosis. • Hard to explain the nucleus (!) and flagella. (Eukaryotic flagella have a 9+2 arrangement of protein strands, vs. single strand for prokaryotic flagella.)

  16. Phylogenetic Tree of Life: Extremophiles Rooted Tree based on 16SrRNA and 18SrRNA sequence data. All extant life has evolved; evidence lost by extinction. How does evolution work? We need to consider the molecule processes!

  17. Genotype Phenotype

  18. Bacterial Genomes • Chromosomal Map • Only structural genes versus splash map • Mostly single chromosome • Size: 1-5 Mbp • Many complete sequences (TIGR)! • Plasmids: • Size: 2-200 bp • Conjugative or not • Copy number varies • Gene functions vary

  19. Scope of Mutation: • A mutation is any change in the proper nucleic acid sequence of a specific gene in a cell’s genome. It may result from a single base pair mismatch during DNA replication. • Mutation can create genetic diversity within a population; either beneficial, neutral, bad, or lethal. • Mutation could result in a new phenotype that is advantageous to successful reproduction of the mutated individual; this depends on particular environmental conditions, called selective pressures. • Such beneficial mutations stay within a population from generation to generation, and drive the evolution of that species. • Bad or lethal mutations are often lost from a population over subsequent generations.

  20. Mutation types: • Macrolesions (large sequence sections) • Deleted a-b-c-d-e-f-g-h → a-b-c-g-h • Inserted a-b-c-d-e-f-g-h → a-b-c-d-x-y-z-e-f-g-h • Inverted a-b-c-d-e-f-g-h → a-b-c-f-e-d-g-h • Duplicated a-b-c-d-e-f-g-h → a-b-c-d-e-f-d-e-f-g-h • Microlesions (1 or 2 bp alteration) • Point Mutations (Base Substitutions) ACTG → ATTG • Frameshifts (Insertions or Deletions) see the cat eat the rat → see thc ate att her at • Mechanisms of microlesion mutation types • Spontaneous (1 per million; most corrected; 1 per billion remain) • Chemical mutagens • Radiation as mutagens

  21. Genetic Recombination: • Two DNA molecules may recombine segments of their molecule in a process called crossing over. • This is a relatively common event between chromosome copies in eukaryotes during meiosis. (Note the example here.) • Prokaryote chromosomes, viral DNA, and smaller fragments of “foreign” DNA may recombine, adding new genes (or different alleles) to an individual cell. • Bacteria can receive a foreign source of DNA for recombination through one of three different mechanisms of Genetic Exchange.

  22. Transposable Elements: “Jumping Genes” • Transposable elements (insertion sequences and transposons) can tranfer copies of themselves to other DNA molecules (chromosome, plasmid, or viral DNA). • Antibiotic resistance genes rapidly spread within and between bacterial populations by transposons carried on F factors called R plasmids.

  23. Horizontal Gene Transfer(= lateral gene exchange) • Conjugation • Tranformation • Transduction

  24. Where in Nature?

  25. Summary of Prokaryote Evolution Mechanisms • Mutation (micro or macro) changes genotype and possibly phenotype. • Mobile genetic elements (insertions sequences and transposons) may rearrange genes between and within DNA molecules and this may cause mutations. • Horizontal gene transfer (conjugation, transformation, transduction) may result in recombination of completely new genes. • Selective pressures in the environment determine if a new phenotype becomes dominant in a population. • Many changes in genotype are neutral or benign to phenotype and survival; these “cryptic” changes over time may result in genetic drift, i.e. a harmless variation of a gene randomly becomes dominant.

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