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Chapter 6: Microbial Growth Microbial Growth • Microbial growth = growth in population ─ Increase in number of cells, not cell size • Two main categories of requirements for microbial growth: ─ Physical requirements (environmental conditions) ◦ Temperature, pH, osmotic pressure ─ Chemical requirements Physical Requirements for Growth: Temperature • Temperature ─ Minimum growth temperature ─ Optimum growth temperature ─ Maximum growth temperature • Three main classifications ─ Psychrophiles (optimum ~120C) ─ Psychrotrophs (optimum ~230C) ─ Mesophiles (optimum ~370C) ─ Thermophiles (optimum above 500C) Physical Requirements for Growth: Temperature Refrigeration Cause majority of food spoilage Figure 6.1 Hansen’s Disease (Leprosy) • Mycobacterium leprae • Optimal growth temperature: 30°C ─ Grows in peripheral nerves, nasal mucosa and skin cells Figure 22.8 Physical Requirements for Growth: pH • pH ─ Most bacteria grow between pH 6.5 and 7.5 ─ Molds and yeasts grow optimally between pH 5 and 6 ─ Acidophiles grow in acidic environments (pH<5.5) ─ Alkaliphiles grow in basic environments (pH>8.5) • Acidic foods (pickles, sauerkraut) preserved by acids from bacterial fermentation • Growth media used in the laboratory contain buffers Physical Requirements for Growth: Osmotic Pressure • Osmotic Pressure ─ Hypertonic environments (=high osmotic pressure), increased salt or sugar, cause plasmolysis ◦ Obligate halophiles require high osmotic pressure ◦ Facultative halophiles tolerate high osmotic pressure (>2% salt) ─ Nutrient agar has a high percentage of water to maintain low osmotic pressure (bacterial cells are 80-90% water) Low osmotic pressure High osmotic pressure Water flow Low solute concentration/ High water concentration High solute concentration/ Low water concentration Physical Requirements for Growth: Osmotic Pressure • Plasmolysis: cell growth is inhibited when the plasma membrane pulls away from the cell wall ─ Added salt or sugar is another method of preserving food Isotonic solution Hypertonic solution (high osmotic pressure) Figure 6.4 Chemical Requirements for Growth • Carbon ─ Structural organic molecules, energy source ◦ Heterotrophs use organic carbon sources ◦ Autotrophs use CO2 • Nitrogen, Sulfur, Phosphorus ─ For synthesis of amino acids, nucleotides, vitamins, phospholipids ─ Most bacteria decompose proteins to obtain N ─ Inorganic ions are sources for these elements (NH4+, NO3-, PO43-, SO42-) Chemical Requirements for Growth • Trace Elements (Iron, Copper, Zinc) ─ Inorganic elements required in small amounts, usually as enzyme cofactors ─ Often present in tap water • Organic Growth Factors ─ Organic compounds obtained from the environment (i.e. the organism cannot synthesize them) ─ Vitamins, amino acids Chemical Requirements for Growth: Oxygen • Oxygen (O2) Obligate aerobes Facultative anaerobes Obligate anaerobes Aerotolerant anaerobes Microaerophiles Chemical Requirements for Growth: Oxygen • Aerotolerance of individual organisms depends on their ability to handle oxygen toxicity ─ Oxygen radical species: O2-, O22-, OH . ─ Presence/lack of enzymes that neutralize toxic oxygen species ◦ SOD (Superoxide dismutase) ◦ Catalase/peroxidase Chemical Requirements for Growth: Oxygen • Oxygen (O2) Obligate aerobes Facultative anaerobes Express SOD and catalase Obligate anaerobes Don’t express SOD/catalase Aerotolerant anaerobes Tolerate oxygen (express SOD/catalase) but incapable of using it for growth Microaerophiles Require oxygen, but at lower levels than in the air Culture Media • Culture Medium: Nutrients prepared for microbial growth ─ Source of energy, carbon, nitrogen, sulfur, phosphorus, trace elements and organic growth factors • Sterile: No living microbes • Inoculum: Introduction of microbes into medium to initiate growth • Culture: Microbes growing in/on culture medium Culture Media: Agar • Complex polysaccharide • Used as solidifying agent for culture media in Petri plates, slants, and deeps • Generally not metabolized by microbes ─ Agar is not a nutrient • Liquefies above 100°C ─ Can incubate at a wide range of temperatures Culture Media Anaerobic Culture Media: Broth cultures • Reducing broth media ─ Contain chemicals (thioglycollate) that combine with dissolved O2 to deplete it from the media Anaerobic Culture Methods: Agar Cultures • Anaerobic jar ─ Oxygen and H2 combine to form water Figure 6.5 Culture Media: Selective and Differential Media • Selective media: suppress growth of unwanted microbes and encourage growth of desired microbes • Differential media: make it easy to distinguish colonies of different microbes Enterobacter aerogenes on EMB E. coli on EMB Figure 6.9b, c Obtaining Pure Cultures • A pure culture contains only one species or strain • A colony is a population of cells arising from a single cell or spore or from a group of attached (identical) cells ─ One colony arises from one colony-forming unit (CFU) • Specimens (pus, sputum, food) typically contain many different microorganisms ─ Common way to isolate a single species from a mixture of microorganisms: Streak plate method Streak Plate Method for Isolation of a Pure Species • Use loop to pick colony • Inoculate broth • Pure culture Figure 6.10a, b Microbial Growth in Hosts: Biofilms • Microbial communities ─ 3-dimensional “slime” ─ i.e. dental plaque, soap scum • Share nutrients • Sheltered from harmful factors • Cell-to-cell communication: quorum sensing Figure 6.5 Bacterial biofilm growing on a micro-fibrous material Microbial Growth in Hosts: Biofilms & Quorum Sensing • Quorum sensing allows a form of bacterial communication ─ Individual cells can sense the accumulation of signaling molecules (autoinducers) ◦ Informs individual cells about surrounding cell density ◦ May change the behavior (gene expression) of individual cells − Results in a coordinated response by the whole population http://biofilmbook.hypertextbookshop.com/public_version/ Prokaryotic Reproduction: Binary Fission Figure 6.11 Reproduction in Prokaryotes: Generation Time Generation time: the time required for one population doubling ─ Varies with species and environmental conditions Reproduction in Prokaryotes: Generation Number • Generation number: the number of times a cell population has doubled in a given time under given conditions Figure 6.12b Reproduction in Prokaryotes: Growth Plot Logarithmic Arithmetic Figure 6.13 Bacterial Growth Curve • Lag: little/no cell division ─ Adapting to new medium ─ *Metabolically active* • Log: exponential growth ─ Most metabolically active ─ Gen. time at constant minimum • Stationary: equilibrium phase ─ Growth rate = death rate ─ Nutrients exhausted, waste accumulation, pH changes • Death: logarithmic decline Figure 6.14 Measuring Microbial Growth • To determine the size of a bacterial population in a specimen, cell counting techniques are used ─ Often there are too many cells per ml or gram of specimen… ◦ A small proportion of the specimen (a dilution) is counted ◦ The number of cells in the original specimen can be calculated based on the count in the small dilution Direct Measurements of Microbial Growth: Viable Cell Count • Plate Counts: Perform serial dilutions of a sample • How many cells are in 1 mL of original culture? DF=1 DF: 10-1 10-2 10-3 10-4 10-5 Figure 6.15, top portion Direct Measurements of Microbial Growth: Viable Count • Inoculate one agar plate with each serial dilution Figure 6.16 Direct Measurements of Microbial Growth: Viable Count • After incubation, count colonies on plates that have 30300 colonies (CFUs) Figure 6.15 Direct Measurements of Microbial Growth • Filtration ─ Ideal when microbial density is low in a sample Figure 6.17a, b Direct Measurements of Microbial Growth Disadvantages: -Likely to count dead cells -Motile cells can be difficult to count Figure 6.19