Microbial Ecology, Nutrition, and Growth PDF

Summary

This presentation, titled "Elements of Microbial Nutrition, Ecology, and Growth," provides an overview of key concepts in microbiology. The document covers topics such as microbial nutrition, environmental factors influencing microbial growth, and different types of microbes based on energy and carbon sources.

Full Transcript

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

2
 Microbial Nutrition
Chemical analysis
Sources of essential nutrients
Transport mechanisms

3
 Microbial nutrition
Macronutrients – required in large
quantities; play principal roles in cell
structure & metabolism
– proteins, carbohydrates
Micronutrients or trace elements –
required in small amounts; involved in
enzyme function & maintenance of
protein structure
– manganese, zinc, nickel
4
 Nutrients
Inorganic nutrients– atom or molecule that
contains a combination of atoms other than
carbon and hydrogen
– metals and their salts (magnesium sulfate, ferric
nitrate, sodium phosphate), gases (oxygen,
carbon dioxide) and water
Organic nutrients- contain carbon and
hydrogen atoms and are usually the products
of living things
– methane (CH4), carbohydrates, lipids, proteins,
and nucleic acids
5
 Chemical composition of
cytoplasm
70% water
proteins
96% of cell is composed of 6 elements
– Carbon
– Hydrogen
– Oxygen
– Nitrogen
– Phosphorous
– Sulfur 6
 Obtaining Carbon
Heterotroph – an organism that must
obtain carbon in an organic form made
by other living organisms such as
proteins, carbohydrates, lipids and
nucleic acids

Autotroph - an organism that uses CO2,
an inorganic gas as its carbon source
– not dependent on other living things
7
 Nitrogen
Main reservoir is nitrogen gas (N2)
79% of earth’s atmosphere is N2
Nitrogen is part of the structure of proteins, DNA,
RNA & ATP – these are the primary source of N
for heterotrophs
Some bacteria & algae use inorganic N nutrients
(NO3-, NO2-, or NH3)
Some bacteria can fix N2
Regardless of how N enters the cell, it must be
converted to NH3, the only form that can be
combined with carbon to synthesize amino acids,
etc.
8
 Oxygen
major component of carbohydrates,
lipids and proteins
plays an important role in structural &
enzymatic functions of cell
component of inorganic salts (sulfates,
phosphates, nitrates) & water
O2 makes up 20% of atmosphere
essential to metabolism of many
organisms
9
 Hydrogen
major element in all organic compounds
& several inorganic ones (water, salts &
gases)
gases are produced & used by
microbes
roles of hydrogen
– maintaining pH
– forming H bonds between molecules
– serving as the source of free energy in
oxidation-reduction reactions of respiration10
 Phosphorous
main inorganic source is phosphate (PO4-3)
derived from phosphoric acid (H3PO4) found
in rocks & oceanic mineral deposits
key component of nucleic acids, essential to
genetics
serves in energy transfers (ATP)

11
 Sulfur
widely distributed in environment, rocks,
sediments contain sulfate, sulfides,
hydrogen sulfide gas and sulfur
essential component of some vitamins
and the amino acids: methionine &
cysteine
contributes to stability of proteins by
forming disulfide bonds

12
 Important mineral ions
Potassium
Sodium
Calcium
Magnesium
Iron

13
Bacteria are composed of different elements and molecules, with
water (70%) and proteins (15%) being the most abundant.

Analysis of the chemical composition of an E. coli cell. 14
Sources of essential nutrients
Required for metabolism and growth
– Carbon source
– Energy source

15
 Carbon source
Heterotroph (depends on other life
forms)
– Organic molecules
– Ex. Sugars, proteins, lipids
Autotroph (self-feeders)
– Inorganic molecules
– Ex. CO2

16
 Growth factors
Essential organic nutrients
Not synthesized by the microbe, and
must be supplemented
Ex. Amino acids, vitamins

17
 Energy source
Chemoheterotrophs
Photoautotrophs
Chemoautotrophs

18
 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

19
Representation of a saprobe and its mode of action.

20
Extracellular digestion in a saprobe with a cell wall.
 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
21
 Two types of autotrophs

– 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

22
Methanogens are an example of a chemoautotroph.

Methanococcus jannaschii, (motile, inhabits hot vents
in the seafloor, uses H gas as E source

SEM of a small colony of Methanosarcina

Methane-producing archaea 23
Summary of the different nutritional categories based on carbon
and energy source.

24
 Transport mechanisms
Passive transport –do not require energy,
substances exist in a gradient and move from areas
of higher concentration towards areas of lower
concentration
– Osmosis - water
– Diffusion
– Facilitated diffusion – requires a carrier
Active transport – require energy and carrier
proteins, gradient independent
– Carrier-mediated active transport
– Group translocation – transported molecule
chemically altered
– Bulk transport – endocytosis, exocytosis,
25
pinocytosis
 Osmosis
Diffusion of water through a permeable
but selective membrane
Water moves toward the higher solute
concentrated areas
– Isotonic- solute concn of the envt= solute concn of the cell’s internal envt
(cytoplasm) ----same rate of water movt == no net charge in cell volume
– Most stable

– Hypotonic- lower solute concn in the external envt than the cell’s internal
envt
– Pure water ---most hypotonic envt for cells bec it has no solute
– Net direction: fr. Hypotonic soln into the cell ----- if no CW, it will swell and burst

– Hypertonic- higher solute concn in the external envt than the cell’s
cytoplasm
– This will force the water to diffuse out of the cell = high osmotic pressure/potential
(growth-limiting effect ---- method of preservation) 26
Representation of the osmosis process (the diffusion of water
through a selectively permeable membrane).

27
Cells with- and without cell walls, and their responses to different
osmotic conditions (isotonic, hypotonic, hypertonic).

28
 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

29
A cube of sugar will diffuse from a concentrated area into a more
dilute region, until an equilibrium is reached.

30
Diffusion of molecules in aqueous solutions
 Facilitated diffusion
Transport of polar molecules and ions
across the membrane
No energy is expended (passive)
Carrier protein facilitates the binding
and transport
– Specificity – bind and transport only a single type of molecule
– Saturation – rate of transport is limited by the no. of binding sites of TP
– Competition – 2 molecules of similar shape can bind to the same binding
site on a CP

31
Representation of the facilitated diffusion process.

(Conformational change in the protein)

Facilitated diffusion – involves attachment of a molecule to a
specific protein-carrier 32
 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
33
 Endocytosis
Substances are taken, but are not
transported through the membrane.
Requires energy (active)
Common for eukaryotes
Ex. Phagocytosis, pinocytosis

34
Example of the carrier-mediated active transport (permease).

The membrane proteins (permease) have attachment sites for esssential
nutrient molecules. As these molecules bind to the permease, they are
pumped into the cell’s interior through special membrane protein channels.
Microbes have these systems for transporting various ions.

35
Active transport
Example of group translocation.

In this process, the molecule is actively captured, but along the
route of transport, it is chemically altered. By coupling transport
with synthesis, the cell conserves energy.

36
Example of endocytosis processes.

Solid particles are phagocytosed by large cell extensions (pseudopods)
and fluids, and/or dissolved substances are pinocytosed into vesicles by
very fine cell protrusions (microvilli). Oil droplets fuse with the membrane
and are released directly into the cell.
37
 38
Brownian movt --- natural tendency of an atom to be in constant random motion
 Environmental Factors
Temperature
Gas
pH
Osmotic pressure
Other factors
Microbial association

39
 Temperature
For optimal growth and metabolism
Psychrophile – 0 to 15 °C
Mesophile- 20 to 40 °C
Thermophile- 45 to 80 °C

40
Growth and metabolism of different ecological groups based on
ideal temperatures.

Cardinal temp range depends on habitats: typhus rickettsia = 32 – 38; rhinovirus = 33-35; S. aureus = 6-46
E. faecalis = 0 - 44 41
42
 Five groups based on optimum growth temperature

1.Psychrophiles: cold-loving
2.Psychrotrophs: Grow between 0 C and 20 to 30 C;
Cause food spoilage
3.Mesophiles: moderate-temperature-loving
4.Thermophiles: Optimum growth temperature of 50 to
60 C; Found in hot springs and organic compost
5.Hyperthermophiles: Optimum growth temperature
>80 C
Effect of amount of food on its cooling rate
Example of a psychrophilic photosynthetic Red snow organism.

Early summer snowbank provides a perfect habitat for psychrophilic, photosynthetic organisms like Chlamydomonas
nivalis 46
 Addtl terms
Psychrotrophs (facultative
psychrophiles) – grow slowly in cold but
have an opt. temp above 20°C ---ex. L.
monocytogenes and S. aureus
Thermoduric microbes – survives short
exposure to high temp but are normally
mesophiles --- contaminants of heated
or pasteurized foods (ex. Giardia,
Bacillus and Clostridium
47
 Gas
Two gases that most influence microbial
growth
– Oxygen
Respiration
Oxidizing agent
– Carbon dioxide

48
 Oxidizing agent
Oxygen metabolites are toxic
These toxic metabolites must be
neutralized for growth
Three categories of bacteria
– Obligate aerobe
– Facultative anaerobe
– Obligate anaerobe

49
 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
(Micrococcus and Bacillus)

50
Toxic Forms of Oxygen

Singlet oxygen: Oxygen boosted to a higher-energy
state and is reactive
Superoxide free radicals: O2–

Peroxide anion: O22–

Hydroxyl radical (OH)
 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 (intestinal
bact and staphylococci)
52
 Obligate anaerobes
Cannot use oxygen for metabolism
Do not possess superoxide dismutase
and catalase
The presence of oxygen is toxic to the
cell

53
Anaerobes must grow in an oxygen-minus environment, because
toxic oxygen metabolites cannot be neutralized.

Anaerobic or CO2 indicator system

54
Culturing technique for anaerobes
Thioglycollate broth enables the identification of aerobes,
facultative anaerobes, and obligate anaerobes.

P. aeruginosa
S. aureus
E. coli
C. butyricum

Use of thioglycollate
broth to demonstrate
oxygen requirements.
56
Oxygen requirements

57
The Effect of Oxygen on the Growth of Various Types of
Bacteria
 pH
Cells grow best between pH 6-8 (6.5 and 7.5: Neutrophils
Exceptions would be acidophiles (pH 0), and alkalinophiles
(pH 10).
Some bacteria are very tolerant of acidity or thrive in it:
Acidophiles(preferred pH range 1 to 5)
Molds and yeasts grow best between pH 5 and 6
Euglena mutabilis – grows in acid pools with a pH bet 0-1.0
Thermoplasma – lives in hot, coal piles at a pH of 1-2
Molds – tolerates moderate acid --- common spoilage of
pickled foods
Proteus spp. – pH10
59
 Osmotic pressure
Hypertonic environments (increased salt or sugar; higher
in solutes than inside the cell ) cause plasmolysis due to
high osmotic pressure
Obligate (extreme) halophiles vs. facultative halophiles
Halophiles
Requires high salt concentrations (high osmotic pressure
Withstands hypertonic conditions
Obligates: opt = 25%, 9% min.
Ex. Halobacterium and Halococcus
Facultative halophiles (osmotolerant= tolerate high
osmotic pressure)
– Can survive high salt conditions but is not required;
0.1%- 20%
– Ex. Staphylococcus aureus
60
 Other factors
Radiation- UV, x-rays, cosmic rays
Barophiles – withstand high pressures
Spores and cysts- can survive dry
habitats/ extreme drying --- enzymes
are inactivated

62
 Ecological association
Influence microorganisms have on other
microbes
– Symbiotic relationship
– Non-symbiotic relationship

63
 Symbiotic
Organisms that live in close nutritional
relationship
Types
– Mutualism – both organism benefit
ex. Termite & protozoa; bacteria and
protozoa (in ruminants)
– Commensalism – one organisms benefits
– Parasitism – host/microbe relationship
64
An example of commensalism, where Staphylococcus aureus
provides vitamins and amino acids to Haemophilus influenzae.

Satellitism, a type of
65
commensalism
 Non-symbiotic
Organisms are free-living, and do not
rely on each other for survival
Types
– Synergism – shared metabolism ---soil
bacteria(provide the plant with minerals) and plant roots(provides growth factors)
– members cooperate and share nutrients

– Antagonism- competition between
microorganisms ---- production of antibiotics (e.g. bacteriocin)
– some members are inhibited or destroyed by others

66
 Biofilms

✓ Microbial communities form slime or hydrogels
✓ Starts via attachment of planktonic bacterium to
surface structure.
✓ Bacteria communicate by chemicals via quorum
sensing
✓ Share nutrients; Sheltered from harmful factors
(disinfectants etc.)
✓ Cause of most nosocomial infections

Clinical Focus: Delayed Bloodstream Infection
Following Catheterization
 Microbial
Associations

Non-symbiotic
Symbiotic Orgs.are free-
Orgs. live in close living;
nutritional relationships
relationship are not required
for survival

mutualism commensalism parasitism synergism antagonism

69
 Interrelationships between
microbes and humans
Human body = rich habitat for symbiotic
bacteria (e.g. skin and alimentary tract)
Can be commensal, parasitic, and
synergistic
Ex. E. coli in the intestine
Lactobacillus in vagina

70
 Microbial Growth
“Growth” = the acquisition of biomass
leading to cell division, or reproduction
Reqmnts: nutrients and proper
environmental factors
2 levels: 1)synthesis of new cell
components and inc. in size, 2) inc. in
the no. of cells

71
 Microbial Growth
Binary fission
Generation time
Growth curve
Enumeration of bacteria

72
 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

73
Representation of the steps in binary fission of a rod-shaped
bacterium.

74
 Binary Division
1 to 2 to 4 to 8 to ?
 Generation time
The time required for a complete division
cycle (= doubling time)
Length of the generation time is a measure of
the growth rate
Exponentials are used to define the numbers
of bacteria after growth
vary markedly with the species of
microorganism and environmental conditions;
--- can range from 10 minutes for a few
bacteria to several days with some eucaryotic
microorganisms; (20 min (E. coli) to > 24h (M. tuberculosis)
76
 Mean Generation Time
and Growth Rate
The mean generation time (doubling time) is
the amount of time required for the
concentration of cells to double during the log
stage. It is expressed in units of minutes;
time required for cell to divide
1
Growth rate (min-1) =
mean generation time
Mean generation time can be determined
directly from a semilog plot of bacterial
concentration vs time after inoculation
Mean Generation Time
and Growth Rate
Representation of how a single bacterium doubles after a
complete division, and how this can be plotted using exponentials.

79
The mathematics of population growth
Bacterial Growth Curve: Arithmetic vs. Exponential Plotting
 Growth curve
Shows population growth of the culture
Illustrates the dynamics of growth
The standard bacterial growth curve
describes various stages of growth a pure
culture of bacteria will go through,
beginning with the addition of cells to
sterile media and ending with the death of
all of the cells present.
Usually analyzed in a closed system called
a batch culture; plotted as the logarithm
of cell number versus the incubation time.
83
 Phases of Growth (in growth
curve)
Lag phase
Log phase
Stationary phase
Death phase

84
 Lag phase
Cells are adjusting, enlarging, and
synthesizing critical proteins and metabolites
Not doubling at their maximum growth rate
“flat” period of adjustment, enlargement; little
growth
associated with a physiological adaptation
to the new environment
varies considerably in length depending
upon the condition of the microorganisms
and the nature of the medium
85
 Log phase

Maximum exponential growth rate of
cell division
Adequate nutrients
Favorable environment
=== active growth

86
 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
------ rate of cell growth equals rate of cell death
cause by depleted nutrients & O2, excretion of
organic acids & pollutants
==Cell death may result from Nutrient limitation
& Toxic waste accumulation (e.g. acid buildup
from fermentation); as well as O2 depletion,
critical population level reached 87
 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.
as limiting factors intensify, cells die
exponentially in their own wastes

88
The four main phases of growth in a bacterial culture.

The growth curve in a bacterial culture. 89
 Measurement of bacterial
growth
Turbidity
Direct cell count
Automated devices
– Coulter counter
– Flow cytometer
– Real-time PCR

90
1)Turbidity = Absorbance method
Based on the diffraction or “scattering” of
light by bacteria in a broth culture
Light scattering is measured as optical
absorbance in a spectrophotometer
Optical absorbance is directly proportional
to the concentration of bacteria in the
suspension = Light scattered is
proportional to number of cells.
Use a spectrophotometer to accurately
measure absorbance, usually at
wavelengths around 400-600 nm.
91
1)Turbidity = Absorbance method
Accurate measure of cells when
concentration not too high. Easy and quick
to measure (can measure a sample in less
than a minute).
Measurement of cell mass may be used
to approximate the number of
microorganisms if a suitable parameter
proportional to the number of
microorganisms present is used. ---- Suitable
parameters may be dry weight, light scattering in liquid solutions, or
biochemical determinations of specific cellular constituents such as
protein, DNA, or ATP

92
The greater the turbidity, the larger the population size.

93
Turbidity measurements as indicators of growth
 Direct cell count method
Microscopic cell counts
– Calibrated “Petroff-Hausser counting chamber,”
similar to hemacytometer, w/c can also be used
– Generally very difficult for bacteria since cells
tend to move in and out of counting field
– Can be useful for organisms that cannot be
cultured
– Special stains (e.g. serological stains or stains
for viable cells) can be used for specific
purposes
 Direct cell count method
Microscopic cell counts
may be accomplished by direct
microscopic observation on specially
etched slides (such as Petroff-Hausser
chambers or hemocytometers) or by using
electronic counters like
Coulter Counters, count microorganisms as they flow through a small hole or orifice.

Direct cell count methods do not distinguish
between living and dead cells.
The direct cell method counts the total dead and live cells in a
special microscopic slide containing a premeasured grid.

Direct microscopic count of bacteria. 97
A Coulter counter uses an electronic sensor to detect and count
the number of cells.

98
Coulter counter
 Direct cell count method
Serial dilution and colony counting
– Also know as “viable cell counts”
– Concentrated samples are diluted by
serial dilution
– involve plating diluted samples (using a
pour plate or spread plate) onto suitable
growth media and monitoring colony
formation; this type of method counts only
those cells that are reproductively active

99
 Direct cell count method
Serial dilution and colony counting
– typically carried out by Colony Forming
Units (CFU) assay.

100
Measurement of Microbial Growth
Serial dilution (cont.)
– Diluted samples are spread onto media in petri
dishes and incubated
– Colonies are counted. The concentration of
bacteria in the original sample is calculated (from
plates with 25 – 250 colonies, from the FDA
Bacteriological Analytical Manual).
– A simple calculation, with a single plate
falling into the statistically valid range, is
given below:
CFU # colonies counted
in original sample =
ml (dilution factor)(volume plated, in ml)
 Measurement of
Microbial Growth
Serial dilution (cont.)
– If there is more than one plate in the
statistically valid range of 25 – 250
colonies, the viable cell count is
determined by the following formula:
 Measurement of Microbial Growth
CFU
=
 C
ml [(1* n1) + (0.1* n 2) +...] * d1 * V
Where:
C = Sum of all colonies on all plates between 25 -
250
n1= number of plates counted at dilution 1
(least diluted plate counted)
n2= number of plates counted at dilution 2
(dilution 2 = 0.1 of dilution 1)
d1= dilution factor of dilution 1
V= Volume plated per plate
Standard Plate Count

105
 Measuring Growth

MPN (Most Probable Number)
– Put 10, 1, and 0.1 ml into 10-mls broth
Repeat 5 times per volume
– Statistical accurate sampling
– Public Health Standards are written for
MPN

Chapter 6
Other Measurements of Microbial
Growth
Membrane filtration
Used for samples with low microbial
count/concentration
A measured volume (usually 1 to 100 ml) of
sample is filtered through a membrane filter
(typically with a 0.45 μm pore size)
The filter is placed on a nutrient agar medium and
incubated
Colonies grow on the filter and can be counted
Standards for Public Health:
0 E.coli / 100 ml of water
Direct microscopic count: Counting chambers (slides)
for microscope
Measurement of Microbial Growth

Mass determination
– Cells are removed from a broth culture by
centrifugation and weighed to determine
the “wet mass.”
– The cells can be dried out and weighed to
determine the “dry mass.”
Measurement of enzymatic activity or
other cell components
Measuring Microbial Growth

Direct Methods
Plate counts
Filtration
MPN
Direct microscopic count

Indirect Methods
Turbidity
Metabolic activity
Dry weight