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. Growth Requirements Associations
Organisms live in association with different species
Antagonistic relationships
Synergistic relationships
Symbiotic relationships
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5. Growth Requirements 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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6. Figure 6.17 Binary fission events-overview
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7. Growth of Microbial Populations
ANIMATION Binary Fission
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8. Figure 6.18 Comparison of arithmetic and logarithmic growth-overview
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9. 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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10. Figure 6.19 Two growth curves of logarithmic growth-overview
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11. Figure 6.20 Typical microbial growth curve
Stationary phase
Death (decline) phase
Log (exponential) phase
Number of live cells (log)
Lag phase
Time
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12. 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
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13. 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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14. Figure 6.22 Estimating microbial population size-overview
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15. Figure 6.23 Use of membrane filtration to estimate microbial population-overview
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16. 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
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4 tubes positive
2 tubes positive
1 tube positive

17. Figure 6.25 The use of a cell counter for estimating microbial numbers-overview
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18. Growth of Microbial Populations
Measuring Microbial Growth
Indirect methods
Metabolic activity
Dry weight
Turbidity
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19. Figure 6.26 Spectrophotometry-overview
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20. 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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21. Case Study–Can a trip to the dentist be life threatening?
Details of the case
Why do we get our teeth cleaned?
Why does Betty feel so bad?
What has happened?
Will the biofilm return?
How did they figure out Betty had septicemia?
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