1. Microbial Nutrition and Growth
Chapter 6
Microbial Nutrition and Growth

2. Result of microbial growth is discrete colony
Growth Requirements
Microbial growth
Increase in a population of microbes
Result of microbial growth is discrete colony
An aggregation of cells arising from single parent cell
Reproduction results in growth
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3. Microbes obtain nutrients from variety of sources
Growth Requirements
Organisms use a variety of nutrients for their energy needs and to build organic molecules and cellular structures
Most common nutrients contain necessary elements such as carbon, oxygen, nitrogen, and hydrogen
Microbes obtain nutrients from variety of sources
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4. Nutrients: Chemical and Energy Requirements
Growth Requirements
Nutrients: Chemical and Energy Requirements
Sources of carbon, energy, and electrons
Two groups of organisms based on source of carbon
Autotrophs
Heterotrophs
Two groups of organisms based on source of energy
Chemotrophs
Phototrophs
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5. Figure 6.1 Four basic groups of organisms

6. Nutrients: Chemical and Energy Requirements
Growth Requirements
Nutrients: Chemical and Energy Requirements
Oxygen requirements
Oxygen is essential for obligate aerobes
Oxygen is deadly for obligate anaerobes
How can this be true?
Toxic forms of oxygen are highly reactive and excellent oxidizing agents
Resulting oxidation causes irreparable damage to cells
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7. Nutrients: Chemical and Energy Requirements
Growth Requirements
Nutrients: Chemical and Energy Requirements
Oxygen requirements
Four toxic forms of oxygen
Singlet oxygen
Superoxide radicals
Peroxide anion
Hydroxyl radical
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8. Figure 6.2 Catalase test

9. Nutrients: Chemical and Energy Requirements
Growth Requirements
Nutrients: Chemical and Energy Requirements
Oxygen requirements
Aerobes
Anaerobes
Facultative anaerobes
Aerotolerant anaerobes
Microaerophiles
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10. Figure 6.3 Oxygen requirements of organisms-overview

11. Nutrients: Chemical and Energy Requirements
Growth Requirements
Nutrients: Chemical and Energy Requirements
Nitrogen requirements
Anabolism often ceases because of insufficient nitrogen
Nitrogen acquired from organic and inorganic nutrients
All cells recycle nitrogen from amino acids and nucleotides
Nitrogen fixation by certain bacteria is essential to life on Earth
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12. Nutrients: Chemical and Energy Requirements
Growth Requirements
Nutrients: Chemical and Energy Requirements
Other chemical requirements
Phosphorus
Sulfur
Trace elements
Required only in small amounts
Growth factors
Necessary organic chemicals that cannot be synthesized by certain organisms
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13. Physical Requirements
Growth Requirements
Physical Requirements
Temperature
Effect of temperature on proteins
Effect of temperature on membranes of cells and organelles
If too low, membranes become rigid and fragile
If too high, membranes become too fluid
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14. Figure 6.4 Microbial growth-overview

15. Thermophiles Mesophiles Hyperthermophiles Growth rate Psychrophiles
Figure 6.5 Four categories of microbes based on temperature ranges for growth
Thermophiles
Mesophiles
Hyperthermophiles
Growth rate
Psychrophiles
Temperature (°C)

16. Figure 6.6 An example of psychrophile-overview

17. Physical Requirements
Growth Requirements
Physical Requirements pH
Organisms are sensitive to changes in acidity
H+ and OH– interfere with H bonding
Neutrophiles grow best in a narrow range around neutral pH
Acidophiles grow best in acidic habitats
Alkalinophiles live in alkaline soils and water
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18. Physical Requirements
Growth Requirements
Physical Requirements
Physical effects of water
Microbes require water to dissolve enzymes and nutrients
Water is important reactant in many metabolic reactions
Most cells die in absence of water
Some have cell walls that retain water
Endospores and cysts cease most metabolic activity
Two physical effects of water
Osmotic pressure
Hydrostatic pressure
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19. Physical Requirements
Growth Requirements
Physical Requirements
Physical effects of water
Osmotic pressure
Pressure exerted on a semipermeable membrane by a solution containing solutes that cannot freely cross membrane
Hypotonic solutions have lower solute concentrations
Hypertonic solutions have greater solute concentrations
Restricts organisms to certain environments
Obligate and facultative halophiles
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20. Physical Requirements
Growth Requirements
Physical Requirements
Physical effects of water
Hydrostatic pressure
Water exerts pressure in proportion to its depth
Barophiles live under extreme pressure
Their membranes and enzymes depend on pressure to maintain their shape
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21. Associations and Biofilms
Growth Requirements
Associations and Biofilms
Organisms live in association with different species
Antagonistic relationships
Synergistic relationships
Symbiotic relationships
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22. Associations and Biofilms
Growth Requirements
Associations and Biofilms
Biofilms
Complex relationships among numerous microorganisms
Develop an extracellular matrix
Adheres cells to one another
Allows attachment to a substrate
Sequesters nutrients
May protect individuals in the biofilm
Form on surfaces often as a result of quorum sensing
Many microorganisms more harmful as part of a biofilm
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23. Figure 6.7 Plaque (biofilm) on a human tooth

24. Culturing Microorganisms
Inoculum introduced into medium
Environmental specimens
Clinical specimens
Stored specimens
Culture
Act of cultivating microorganisms or the microorganisms that are cultivated
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25. Figure 6.8 Characteristics of bacterial colonies-overview

26. Culturing Microorganisms
Obtaining Pure Cultures
Cultures composed of cells arising from a single progenitor
Progenitor is termed a CFU
Aseptic technique prevents contamination of sterile substances or objects
Two common isolation techniques
Streak plates
Pour plates
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27. Figure 6.9 Streak plate method of isolation-overview

28. Figure 6.10 Pour plate method of isolation-overview

29. Culturing Microorganisms
Culture Media
Majority of prokaryotes have not been grown in culture medium
Six types of general culture media
Defined media
Complex media
Selective media
Differential media
Anaerobic media
Transport media
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30. Figure 6.11 Slant tube containing solid media
Butt

31. Figure 6.12 An example of the use of a selective medium
Bacterial colonies
Fungal colonies
pH 7.3
pH 5.6

32. Figure 6.13 The use of blood agar as a differential medium
Beta-hemolysis
Alpha-hemolysis
No hemolysis (gamme-hemolysis)

33. Acid fermentation with gas
Figure The use of carbohydrate utilization tubes as differential media
Durham tube (inverted tube to trap gas)
No fermentation
Acid fermentation with gas

34. Figure 6.15 Use of MacConkey agar as a selective and differential medium-overview

35. Figure 6.16 An anaerobic culture system
Clamp
Airtight lid
Chamber
Palladium pellets to catalyze reaction removing O2
Envelope containing chemicals to release CO2 and H2
Methylene blue (anaerobic indicator)
Petri plates

36. Culturing Microorganisms
Special Culture Techniques
Techniques developed for culturing microorganisms
Animal and cell culture
Low-oxygen culture
Enrichment culture
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37. Culturing Microorganisms
Preserving Cultures
Refrigeration
Stores for short periods of time
Deep-freezing
Stores for years
Lyophilization
Stores for decades
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38. Growth of Microbial Populations
ANIMATION Bacterial Growth: Overview
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39. Growth of Microbial Populations
ANIMATION Binary Fission
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40. Figure 6.17 Binary fission events-overview

41. Figure 6.18 Comparison of arithmetic and logarithmic growth-overview

42. Growth of Microbial Populations
Generation Time
Time required for a bacterial cell to grow and divide
Dependent on chemical and physical conditions
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43. Figure 6.19 Two growth curves of logarithmic growth-overview

44. Figure 6.20 Typical microbial growth curve
Stationary phase
Death (decline) phase
Log (exponential) phase
Number of live cells (log)
Lag phase
Time

45. Growth of Microbial Populations
ANIMATION Bacterial Growth Curve
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46. Figure 6.21 Schematic of chemostat
Fresh medium with a limiting amount of a nutrient
Flow-rate regulator
Sterile air of other gas
Culture vessel
Culture
Overflow tube

47. Growth of Microbial Populations
Measuring Microbial Reproduction
Direct methods
Serial dilution and viable plate counts
Membrane filtration
Most probable number
Microscopic counts
Electronic counters
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48. Figure 6.22 Estimating microbial population size-overview

49. Figure 6.23 Use of membrane filtration to estimate microbial population-overview

50. Inoculate 1.0 ml into each of 5 tubes
Figure The most probable number (MPN) method for estimating microbial numbers
1.0 ml
1.0 ml
Undiluted
1:10
1:100
Inoculate 1.0 ml into each of 5 tubes
Phenol red, pH color indicator, added
Incubate
Results
4 tubes positive
2 tubes positive
1 tube positive

51. Figure 6.25 The use of a cell counter for estimating microbial numbers-overview

52. Growth of Microbial Populations
Measuring Microbial Growth
Indirect methods
Metabolic activity
Dry weight
Turbidity
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53. Figure 6.26 Spectrophotometry-overview

54. Growth of Microbial Populations
Measuring Microbial Reproduction
Genetic methods
Isolate DNA sequences of unculturable prokaryotes
Used to estimate the number of these microbes
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