chapter_7_Microbial Nutrition and Growth - Summer 2020.pdf

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Microbial Growth
and Nutrition

Chapter 7

How do bacteria grow?????
• 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

2

Chapter 6
Elements of Microbial
Nutrition, Ecology and Growth
• Topics
– Microbial Nutrition
– Environmental Factors
– Microbial Growth

3

Microbial Nutrition
• Chemical analysis
• Sources of essential nutrients
• Transport mechanisms

4

Bacteria are composed of different elements and molecules, with
water (70%) and proteins (15%) being the most abundant.

Table 7.2 Analysis of the chemical composition
of an E. coli cell.

5

Sources of essential nutrients
• Required for metabolism and growth
– Carbon source
– Energy source

6

Carbon source
• Heterotroph (depends on other life
forms)
– Organic molecules
– Ex. Sugars, proteins, lipids

• Autotroph (self-feeders)
– Inorganic molecules
– Ex. CO2
7

Growth factors
• Essential organic nutrients
• Not synthesized by the microbe, and
must be supplemented
• Ex. Amino acids, vitamins

8

Energy source
• Chemoheterotrophs
• Photoautotrophs
• Chemoautotrophs

9

Chemoheterotrophs
• Derive both carbon and energy from
organic compounds
– Saprobic
• decomposers of plant litter, animal matter, and
dead microbes

– Parasitic
• Live in or on the body of a host

10

Photoautotroph
• Derive their energy from sunlight
• Transform light rays into chemical
energy
• Primary producers of organic matter for
heterotrophs
• Primary producers of oxygen
• Ex. Algae, plants, some bacteria
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Chemoorganic autotrophs
• Two types
– Chemoorganic autotroph
• Derives their energy from organic compounds
and their carbon source from inorganic
compounds

– Lithoautotrophs
• Neither sunlight nor organics used, rather it
relies totally on inorganics

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Methanogens are an example of a chemoautotroph.

Fig. 7.1 Methane-producing archaea

13

Summary of the different nutritional categories based on carbon
and energy source.

Table 7.3 Nutritional categories of microbes by energy
and carbon source.

14

Representation of a saprobe and its mode of action.

Fig. 7.2 Extracellular digestion in a saprobe with a cell wall.

15

Transport mechanisms
•
•
•
•

Osmosis
Diffusion
Active transport
Endocytosis

16

Osmosis
• Diffusion of water through a permeable
but selective membrane
• Water moves toward the higher solute
concentrated areas
– Isotonic
– Hypotonic
– Hypertonic
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Representation of the osmosis process.

Fig. 7.3 Osmosis, the diffusion of water through a selectively
permeable membrane

18

Cells with- and without cell walls, and their responses to different
osmotic conditions (isotonic, hypotonic, hypertonic).

Fig. 7.4 Cell responses to solutions of differing osmotic
content.

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Diffusion
• Net movement of molecules from a high
concentrated area to a low concentrated
area
• No energy is expended (passive)
• Concentration gradient and permeability
affect movement

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A cube of sugar will diffuse from a concentrated area into a more
dilute region, until an equilibrium is reached.

Fig. 7.5 Diffusion of molecules in aqueous solutions

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Facilitated diffusion
• Transport of polar molecules and ions
across the membrane
• No energy is expended (passive)
• Carrier protein facilitates the binding
and transport
– Specificity
– Saturation
– Competition
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Representation of the facilitated diffusion process.

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Fig. 7.6 Facilitated diffusion

Active transport
• Transport of molecules against a
gradient
• Requires energy (active)
• Ex. Permeases and protein pumps
transport sugars, amino acids, organic
acids, phosphates and metal ions.
• Ex. Group translocation transports and
modifies specific sugars
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Endocytosis
• Substances are taken, but are not
transported through the membrane.
• Requires energy (active)
• Common for eucaryotes
• Ex. Phagocytosis, pinocytosis

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Example of the permease, group translocation, and endocytosis
processes.

Fig. 7.7 Active transport

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Summary of the transport processes in cells.

Table 7.4 Summary of transport processes in cells

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Environmental Factors
•
•
•
•
•
•

Temperature
Gas
pH
Osmotic pressure
Other factors
Microbial association
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Temperature
•
•
•
•

For optimal growth and metabolism
Psychrophile – 0 to 15 °C
Mesophile- 20 to 40 °C
Thermophile- 45 to 80 °C

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Growth and metabolism of different ecological groups based on
ideal temperatures.

Fig. 7.8 Ecological groups by temperature

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Example of a psychrophilic photosynthetic Red snow organism.

Red snow

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Figure 6.4 Microbial growth-overview

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Gas
• Two gases that most influence microbial
growth
– Oxygen
• Respiration
• Oxidizing agent

– Carbon dioxide

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Oxidizing agent
• Oxygen metabolites are toxic
• These toxic metabolites must be
neutralized for growth
• Three categories of bacteria
– Obligate aerobe
– Facultative anaerobe
– Obligate anaerobe
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Obligate aerobe
• Requires oxygen for metabolism
• Possess enzymes that can neutralize
the toxic oxygen metabolites
– Superoxide dismutase and catalase

• Ex. Most fungi, protozoa, and bacteria

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Facultative anaerobe
• Does not require oxygen for
metabolism, but can grow in its
presence
• During minus oxygen states, anaerobic
respiration or fermentation occurs
• Possess superoxide dismutase and
catalase
• Ex. Gram negative pathogens
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Obligate anaerobes
• Cannot use oxygen for metabolism
• Do not possess superoxide dismutase
and catalase
• The presence of oxygen is toxic to the
cell

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Anaerobes must grow in an oxygen minus environment, because
toxic oxygen metabolites cannot be neutralized.

Fig. 7.10 Culturing technique for anaerobes

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Thioglycollate broth enables the identification of aerobes,
facultative anaerobes, and obligate anaerobes.

Fig. 7.11 Use of
thioglycollate broth to
demonstrate
oxygen requirements.

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Oxygen
1. Obligate aerobes – Only aerobic growth, oxygen is
required for growth (approx. 20%).
2. Facultative – both aerobic and anaerobic growth,
oxygen can be used, but is not required, and
oxygen does not hinder growth. (E. coli)
3. Obligate anaerobes- Only anaerobic growth, microbe
is poisoned by oxygen, growth ceases.
(Genus Clostridium)
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pH
• Cells grow best between pH 6-8
(around
pH7 = neutrophiles)
• Exceptions would be acidophiles (pH 0),
and alkalinophiles (pH 10).

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pH
(measurement of acidity & alkalinity)
1. Neutrophiles - pH 6-8 (7.2 optimal)
Most pathogens

2. Acidophiles - pH 0-6, Helicobacter
pylori
3. Alkalinophiles - pH 8-12
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Osmotic pressure
•
•
•
•
•

Halophiles
Requires high salt concentrations
Withstands hypertonic conditions
Ex. Halobacterium
Facultative halophiles
– Can survive high salt conditions but is not
required
– Ex. Staphylococcus aureus
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Osmotic pressure (H2O)
1. Turgid – Bacterial cells don’t burst (lyse)
because they have a cell wall.
2. Plasmolysis – Cell membrane shrinks away
from the cell wall.
3. Halophiles – Require high concentrations of
salt. (30% NaCl for bacteria
from the dead sea, ordinary
bacteria approx 1.5%)
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Other factors
• Radiation- withstand UV, infrared
• Barophiles – withstand high pressures
• Spores and cysts- can survive dry
habitats

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Ecological association
• Influence microorganisms have on other
microbes
– Symbiotic relationship
– Non-symbiotic relationship

46

Symbiotic
• Organisms that live in close nutritional
relationship
• Types
– Mutualism – both organism benefit
– Commensalism – one organisms benefits
– Parasitism – host/microbe relationship

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An example of commensalism, where Staphylococcus aureus
provides vitamins and amino acids to Haemophilus influenzae.

Fig. 7.12 Satellitism, a
type of commensalism

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Non-symbiotic
• Organisms are free-living, and do not
rely on each other for survival
• Types
– Synergism – shared metabolism, not
required
– Antagonism- competition between
microorganisms
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Interrelationships between
microbes and humans
• Can be commensal, parasitic, and
synergistic
• Ex. E. coli produce vitamin K for the
host

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• 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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Figure 6.7 Plaque (biofilm) on a human tooth

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Microbial Growth
•
•
•
•

Binary fission
Generation time
Growth curve
Enumeration of bacteria

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Binary fission
• The division of a bacterial cell
• Parental cell enlarges and duplicates its
DNA
• Septum formation divides the cell into
two separate chambers
• Complete division results in two
identical cells
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Representation of the steps in binary fission of a rod-shaped
bacterium.

Fig. 7.13 Steps in binary fission of a rod-shaped bacterium.

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Figure 6.17 Binary fission
events-overview

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Generation time
• The time required for a complete
division cycle (doubling)
• Length of the generation time is a
measure of the growth rate
• Exponentials are used to define the
numbers of bacteria after growth

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Representation of how a single bacterium doubles after a
complete division, and how this can be plotted using exponentials.

Fig. 7.14 The mathematics of population growth

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Figure 6.18 Comparison of arithmetic and logarithmic growth-overview

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Growth curve
•
•
•
•

Lag phase
Log phase
Stationary phase
Death phase

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Lag phase
• Cells are adjusting, enlarging, and
synthesizing critical proteins and
metabolites
• Not doubling at their maximum growth
rate

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Log phase
• Maximum exponential growth rate of
cell division
• Adequate nutrients
• Favorable environment

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Stationary phase
• Survival mode – depletion in nutrients,
released waste can inhibit growth
• When the number of cells that stop
dividing equal the number of cells that
continue to divide

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Death phase
• A majority of cells begin to die
exponentially due to lack of nutrients
• A chemostat will provide a continuous
supply of nutrients, thereby the death
phase is never achieved.

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The four main phases of growth in a bacterial culture.

Fig. 7.15 The growth curve in a bacterial culture.

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Enumeration of bacteria
• Turbidity
• Direct cell count
• Automated devices
– Coulter counter
– Flow cytometer
– Real-time PCR

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The greater the turbidity, the larger the population size.

Fig. 7.16 Turbidity measurements as indicators of growth

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The direct cell method counts the total dead and live cells in a
special microscopic slide containing a premeasured grid.

Fig. 7.17 Direct microscopic count of bacteria.

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A Coulter counter uses an electronic sensor to detect and count
the number of cells.

Fig. 7.18 Coulter counter

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