1. Dynamics of Prokaryotic Growth Chapter 4
2. Principles of Bacterial Growth Prokaryotic cells divide by binary fission
One cell divides into two
Two into four etc.
Cell growth is exponential
Doubling of population with each cell division
Exponential growth has important health consequences
Generation time
Time it takes for population to double
A.k.a doubling time
Varies among species
3. Growth can be calculated
Nt = N0 x 2n
(Nt ) number of cells in population
(N0 ) original number of cells in the population
(n) number of divisions
Example
N0 = 10 cells in original population
n = 12
4 hours assuming 20 minute generation time
Nt = 10 x 212
Nt = 10 x 4,096
Nt = 40,960 Principles of Bacterial Growth
4. Bacterial Growth in Nature Conditions in nature have profound effect on microbial growth
Cells sense changing environment
Synthesize compounds useful for growth
Cells produce multicellular associations to increase survivability
Example
Biofilms
Slime layers
5. Biofilm
Formation begins with planktonic bacteria attach to surfaces
Other bacteria attach and grow on initial layer
Has characteristic architecture
Contain open channels for movement of nutrient and waste
Cells within biofilms can cause disease
Treatment becomes difficult
Architecture resist immune response and antimicrobials
Bioremediation is beneficial use of biofilm Bacterial Growth in Nature
6. Interactions of mixed microbial communities
Prokaryotes live in mixed communities
Many interactions are cooperative
Waste of one organism nutrient for another
Some cells compete for nutrient
Synthesize toxic substance to inhibit growth of competitors Bacterial Growth in Nature
7. Obtaining Pure Culture Pure culture defined as population of cells derived from single cell
All cells genetically identical
Cells grown in pure culture to study functions of specific species
Pure culture obtained using special techniques
Aseptic technique
Minimizes potential contamination
Cells grown on culture media
Can be broth (liquid) or solid form
8. Obtaining Pure Culture Culture media can be liquid or solid
Liquid is broth media
Used for growing large numbers of bacteria
Solid media is broth media with addition of agar
Agar marine algae extract
Liquefies at temperatures above 95°C
Solidifies at 45°C
Remains solid at room temperature and body temperature Bacteria grow in colonies on solid media surface
All cells in colony descend from single cell
Approximately 1 million cells produce 1 visible colony
9. Obtaining Pure Culture Streak-plate method
Simplest and most commonly used in bacterial isolation
Object is to reduce number of cells being spread
Solid surface dilution
Each successive spread decreases number of cells per streak
10. Bacterial Growth in �Laboratory Conditions Cells in laboratory grown in closed or batch system
No new input of nutrient and no release of waste
Population of cells increase in predictable fashion
Follows a pattern called growth curve
11. Bacterial Growth in �Laboratory Conditions The Growth Curve
Characterized by five distinct stages
Lag stage
Exponential or log stage
Stationary stage
Death stage
Phase of prolonged decline
12. Bacterial Growth in �Laboratory Conditions Lag phase
Number of cells does not increase in number
Cells prepare for growth
“tooling up”
Log phase
Period of exponential growth
Doubling of population with each generation
Produce primary metabolites
Compounds required for growth
Cells enter late log phase
Synthesize secondary metabolites
Used to enhance survival
Antibiotics
13. Stationary phase
Overall population remains relatively stable
Cells exhausted nutrients
Cell growth = cell death
Dying cell supply metabolites for replicating cells
Death phase
Total number of viable cells decreases
Decrease at constant rate
Death is exponential
Much slower rate than growth Bacterial Growth in �Laboratory Conditions
14. Phase of prolonged decline
Once nearly 99% of all cells dead, remaining cells enter prolonged decline
Marked by very gradual decrease in viable population
Phase may last months or years
Most fit cells survive
Each new cell more fit that previous Bacterial Growth in �Laboratory Conditions
15. Colony growth on solid medium
In colony, cells eventually compete for resources
Cells grow exponentially and eventually compete for nutrients
Position within colony determines resource availability
Cells on edge of colony have little competition and significant oxygen stores
Cells in the middle of colony have high cell density
Leads to increased competition and decreased availability of oxygen Bacterial Growth in �Laboratory Conditions
16. Continuous culture
Bacterial culture can be maintained
Continuous exponential growth can be sustained by use of chemostat
Continually drips fresh nutrients in
Releases same amount of waste product Bacterial Growth in �Laboratory Conditions
17. Environmental Factors on Growth As group, prokaryotes inhabit nearly all environments
Some live in “comfortable” habitats
Some live in harsh environments
Most of these are termed extremophiles and belong to domain Archaea
Major conditions that influence growth
Temperature
Oxygen
pH
Water availability
18. Environmental Factors on Growth Temperature
Each species has well defined temperature range
Within range lies optimum growth temperature
Prokaryotes divided into 5 categories
Psychrophile
Optimum temperature -5°C to 15°C
Found in Arctic and Antarctic regions
Psychrotroph
20°C to 30°C
Important in food spoilage
Mesophile
25°C to 45°C
More common
Disease causing
Thermophiles
45°C to 70°C
Common in hot springs
Hyperthermophiles
70°C to 110°C
Usually members of Archaea
Found in hydrothermal vents
19. Oxygen
Prokaryotes divided based on oxygen requirements
Obligate aerobes
Absolute requirement for oxygen
Use for energy production
Obligate anaerobes
No multiplication in presence of oxygen
May cause death
Facultative anaerobes
Grow better with oxygen
Use fermentation in absence of oxygen
Microaerophiles
Require oxygen in lower concentrations
Higher concentration inhibitory
Aerotolerant anaerobes
Indifferent to oxygen, grow with or without
Does not use oxygen to produce energy Environmental Factors on Growth
20. pH
Bacteria survive within pH range
Neutrophiles
Multiply between pH of 5 to 8
Maintain optimum near neutral
Acidophiles
Thrive at pH below 5.5
Maintains neutral internal pH pumping out protons (H+)
Alkalophiles
Grow at pH above 8.5
Maintain neutral internal pH through sodium ion exchange
Exchange sodium ion for external H+ Environmental Factors on Growth
21. Environmental Factors on Growth Water availability
All microorganisms require water for growth
Water not available in all environments
In high salt environments
Bacteria increase internal solute concentration
Synthesize small organic molecules
Osmotolerant bacteria tolerate high salt environments
Bacteria that require high salt for cell growth termed halophiles
22. Nutritional Factors on Growth Growth of prokaryotes depends on nutritional factors as well as physical environment
Main factors to be considered are:
Required elements
Growth factors
Energy sources
Nutritional diversity
23. Required elements
Major elements
Carbon, oxygen, hydrogen, nitrogen, sulfur, phosphorus, potassium, magnesium, calcium and iron
Essential components for macromolecules
Organisms classified based on carbon usage
Heterotrophs
Use organism carbon as nutrient source
Autotrophs
Use inorganic carbon (CO2) as carbon source
Trace elements
Cobalt, zinc, copper, molybdenum and manganese
Required in minute amounts Nutritional Factors on Growth
24. Growth factors
Some bacteria cannot synthesize some cell constituents
These must be added to growth environment
Referred to as growth factors
Organisms can display wide variety of factor requirements
Some need very few while others require many
These termed fastidious Nutritional Factors on Growth
25. Energy Sources
Organisms derive energy from sunlight or chemical compounds
Phototrophs
Derive energy from sunlight
Chemotrophs
Derive energy from chemical compounds
Organisms often grouped according to energy source Nutritional Factors on Growth
26. Nutritional Diversity
Organisms thrive due to their ability to use diverse sources of carbon and energy
Photoautotrouphs
Use sunlight and atmospheric carbon (CO2) as carbon source
Called primary producers (Plants)
Chemolithoautotrophs
A.k.a chemoautotrophs or chemolitotrophs
Use inorganic carbon for energy and use CO2 as carbon source
Photoheterotrophs
Energy from sunlight, carbon from organic compounds
Chemoorganoheterotrophs
a.k.a chemoheterotrophs or chemoorganotrophs
Use organic compounds for energy and carbon source
Most common among humans and other animals Nutritional Factors on Growth
27. Laboratory Cultivation Knowing environmental and nutritional factors makes it possible to cultivate organisms in the laboratory
Organisms are grown on culture media
Media is classified as complex media or chemically defined media
28. Complex media
Contains a variety of ingredients
There is no exact chemical formula for ingredients
Can be highly variable
Examples include
Nutrient broth
Blood agar
Chocolate agar Laboratory Cultivation
29. Chemically defined media
Composed of precise amounts of pure chemical
Generally not practically for routine laboratory use
Invaluable in research
Each batch is chemically identical
Does not introduce experimental variable Laboratory Cultivation
30. Special types of culture media
These are used to detect or isolate particular organisms
Are divided into selective and differential media Laboratory Cultivation
31. Selective media
Inhibits the growth of unwanted organisms
Allows only sought after organism to grow
Example
Thayer-Martin agar
For isolation of Neisseria gonorrhoeae
MacConkey agar
For isolation of Gram-negative bacteria Laboratory Cultivation
32. Laboratory Cultivation Differential media
Contains substance that bacteria change in recognizable way
Example
Blood agar
Certain bacteria produce hemolysin to break down RBC
Hemolysis
MacConkey agar
Contains pH indicator to identify bacteria the produce acid
33. Providing appropriate atmospheric conditions
Bacteria can be grouped by oxygen requirement
Capnophile
Microaerophile
Anaerobe Laboratory Cultivation
34. Capnophile
Require increased CO2
Achieve higher CO2 concentrations via
Candle jar
CO2 incubator
Microaerophile
Require higher CO2 than capnophile
Incubated in gastight jar
Chemical packet generates hydrogen and CO2 Laboratory Cultivation
35. Laboratory Cultivation Anaerobe
Die in the presence of oxygen
Even if exposed for short periods of time
Incubated in anaerobe jar
Chemical reaction converts atmospheric oxygen to water
Organisms must be able to tolerate oxygen for brief period
Reducing agents in media achieve anaerobic environment
Agents react with oxygen to eliminate it
Sodium thioglycolate
Anaerobic chamber also used for cultivation
36. Detecting Bacterial Growth Variety of techniques to determine growth
Number of cells
Total mass
Detection of cellular products
37. Direct cell count
Useful in determining total number of cells
Does not distinguish between living and dead cells
Methods include
Direct microscopic count
Use of cell counting instruments Detecting Bacterial Growth
38. Detecting Bacterial Growth Direct microscopic count
One of the most rapid methods
Number is measured in a know volume
Liquid dispensed in specialized slide
Counting chamber
Viewed under microscope
Cells counted
Limitation
Must have at least 10 million cells per ml to gain accurate estimate
39. Detecting Bacterial Growth Cell counting instruments
Counts cells in suspension
Cells pass counter in single file
Instrument measure changes in environment
Coulter counter
Detects changes in electrical resistance
Flow cytometer
Measures laser light
40. Viable cell count
Used to quantify living cells
Cells able to multiply
Valuable in monitoring bacterial growth
Often used when cell counts are too low for other methods
Methods include
Plate counts
Membrane filtration
Most probable numbers Detecting Bacterial Growth
41. Detecting Bacterial Growth Plate counts
Measures viable cells growing on solid culture media
Count based on assumption the one cell gives rise to one colony
Number of colonies = number of cells in sample
Ideal number to count
Between 30 and 300 colonies
Sample normally diluted in 10-fold increments
Plate count methods
pour-plates
Spread-plates methods
42. Detecting Bacterial Growth Membrane filtration
Used with relatively low numbers
Known volume of liquid passed through membrane filter
Filter pore size retains organism
Filter is placed on appropriate growth medium and incubated
Cells are counted
43. Detecting Bacterial Growth Most probable numbers (MPN)
Statistical assay
Series of dilution sets created
Each set inoculated with 10-fold less sample than previous set
Sets incubated and results noted
Results compared to MPN table
Table gives statistical estimation of cell concentration
44. Biomass measurement
Cell mass can be determined via
Turbidity
Total weight
Amounts of cellular chemical constituents Detecting Bacterial Growth
45. Detecting Bacterial Growth Turbidity
Measures with spectrophotometer
Measures light transmitted through sample
Measurement is inversely proportional to cell concentration
Must be used in conjunction with other test once to determine cell numbers
Limitation
Must have high number of cells
46. Total Weight
Tedious and time consuming
Not routinely used
Useful in measuring filamentous organisms
Wet weight
Cells centrifuged down and liquid growth medium removed
Packed cells weighed
Dry weight
Packed cells allowed to dry at 100°C 8 to 12 hours
Cells weighed Detecting Bacterial Growth
47. Detecting cell products
Acid production
pH indicator detects acids that result from sugar breakdown
Gas production
Gas production monitored using Durham tube
Tube traps gas produced by bacteria
ATP
Presence of ATP detected by use of luciferase
Enzyme catalyzes ATP dependent reaction
If reaction occurs ATP present ? bacteria present Detecting Bacterial Growth
