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Introduction to Microbiology (BIOL 260) Microbes in Our Lives • Microorganisms or microbes: organisms that are too small to be seen with the unaided eye ─Bacteria ─Fungi ─Protozoa ─Viruses Microorganisms: What do they do? • Decompose organic waste as well as environmental pollutants and toxins (bioremediation) • Are producers in the ecosystem by photosynthesis • Produce industrial chemicals such as ethyl alcohol and some enzymes • Produce fermented foods such as vinegar, cheese, and bread • Normal intestinal flora aid in our food digestion and produce vitamins B and K for us (normal microbiota) • A minority are pathogenic Why study microbiology? • Allows humans to ─ Prevent food spoilage ─ Prevent disease occurrence ◦ Develop aseptic techniques to prevent contamination in medical environments ─ Treat infectious diseases ─ Understand certain body processes ─ Produce foods and therapeutic agents Examples of microorganisms Haemophilus influenzae Mucor (bread mold) Amoeba Volvox (pond algae) HIV particles budding from a T cell Figure 1.1 Classification of Organisms • Three domains: ─ Bacteria (cell walls contain peptidoglycan) ─ Archaea (if present, cell walls lack peptidoglycan) ─ Eukarya ◦ Protists (slime molds, protozoa, algae) ◦ Fungi (unicellular yeasts, multicellular molds and mushrooms) ◦ Plants ◦ Animals (sponges, worms, insects and vertebrates) Taxonomic Hierarchy Scientific naming (binomial nomenclature): Genus species Figure 10.5 Naming and Classifying Microorganisms: Scientific Nomenclature • Each organism has two names: the genus and specific epithet (underlined or italicized) ─ Saccharomyces cerevisiae ─ Escherichia coli ─ Staphylococcus aureus ─ S. cerevisiae, E. coli, S. aureus • Scientific names of organisms may be descriptive or honor a scientist Major groups of microorganisms: Bacteria • Prokaryotic • Unicellular organisms • Peptidoglycan cell walls • Reproduction: Binary fission • Diverse range of energy sources Figure 1.1a Major Groups of Microorganisms: Archaea • Prokaryotic • Lack peptidoglycan • Often live in extreme environments ─ Extreme halophiles ─ Extreme thermophiles Figure 4.5b Major Groups of Microorganisms: Fungi • Eukaryotic • Chitin cell walls • Unicellular or multicellular organisms ─ Molds and mushrooms are multicellular ─ Yeasts are unicellular Figure 1.1b Major Groups of Microorganisms: Protozoa • Eukaryotic • Unicellular • May be motile via pseudopods, cilia, or flagella Figure 1.1c Major Groups of Microorganisms: Microscopic Algae • Eukaryotic • Cellulose cell walls • Energy source: photosynthesis Figure 1.1d Major Groups of Microorganisms: Viruses • Acellular • DNA/RNA core surrounded by a protein coat ─ Coat may be enclosed in a lipid envelope • Replicate only when they are in a living host cell ─ Obligate intracellular parasites Figure 1.1e Major Groups of Microorganisms: Animal Parasites • Eukaryotic • Multicellular animals • Helminths: Parasitic flatworms and round worms • Microscopic stages in life cycles Adult tapeworm Figure 12.28 A Brief History of Microbiology The first observations… • 1665: Robert Hooke reported that life’s smallest structural units are “cells” ─ Cell Theory: All living things are composed of cells • 1673-1723: Anton van Leeuwenhoek describes “animalcules” ─ Observed live organisms in rainwater, tooth scrapings, feces, etc. etc. ─ Opened up the world of previously invisible microorganisms Figure 1.2b The Debate Over Spontaneous Generation From where does such microscopic life arise? • Spontaneous generation: the long-held hypothesis that some living organisms arise from nonliving matter ─ An intangible “vital force” in the air triggers spontaneous generation ─ Subject of controversy among supporters and opponents The Biogenesis Hypothesis • 1858: Rudolf Virchow challenged the spontaneous generation hypothesis with the concept of biogenesis ─ Biogenesis: Living organisms arise only from preexisting life • Spontaneous generation vs. Biogenesis debate continued until 1861… The Theory of Biogenesis Supported • Pasteur’s S-shaped flask kept microbes out but let air in Figure 1.3 Support for the Biogenesis Theory • 1861: Louis Pasteur demonstrated that microorganisms ─ Are present in the air ─ Can contaminate sterile solutions ─ BUT the air cannot CREATE microorganisms Applications to current laboratory and medical practices • Pasteur’s work also demonstrated that living microbes can be killed by heat (sterilization) • These and other discoveries form the basis of aseptic techniques ─ Techniques that prevent contamination from unwanted microorganisms The Golden Age of Microbiology • 1857-1914 • Immunity • Antimicrobial drugs • Fermentation • Pasteurization • Relationship between microbes and disease ─ “Germ theory of disease” The Golden Age of Microbiology: The Germ Theory of Disease Theory that microbes can cause disease • 1865: Pasteur found that a silkworm disease was caused by a protozoan • 1867: Joseph Lister began treating surgical wounds with phenol ─ Significant reduction in surgical wound infections and deaths ─ Proved that microorganisms cause surgical wound infections The Golden Age of Microbiology: The Germ Theory of Disease • 1876: Robert Koch provided proof that a bacterium causes anthrax ─ Koch’s Postulates: the experimental steps used to prove that a specific microbe causes a specific disease The Golden Age of Microbiology: Vaccination • 1880: Pasteur coined the term vaccination ─ From vacca, Latin for cow ─ 1796: Edward Jenner inoculated an 8-year-old with cowpox pustule ◦ The child was protected from smallpox infection for life (immunity)