Microbial growth
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Jan 20, 2021
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About This Presentation
MICROBIAL GROWTH BY SIVASANGARI SHANMUGAM
Slide Content
GROWTH
DEFINITION
Growth implies increase in size resulting from cell multiplication and cell expansion, as
well as maturation of tissues. However, growth, while accentuating increased cell number and
size, also necessitates programmed cell death, leading to the production of the final body form.
Thus, growth is an incredibly complex phenomenon, which involves changes in body
form, metabolism, and body processes.
GROWTH CURVE
The bacterial growth curve represents the number of live cells in a bacterial population
over a period of time.
Bacterial growth curves a curve on a graph that shows the changes in size of a bacterial
population over time in a culture. The bacteria are cultured in sterile nutrient medium and
incubated at the optimum temperature for growth. Samples are removed at intervals and the
number of viable bacteria is counted.
1. LAG PHASE: This initial phase is characterized by cellular activity but not growth. A
small group of cells are placed in a nutrient rich medium that allows them to
synthesize proteins and other molecules necessary for replication. These cells increase in
size, but no cell division occurs in the phase.
2. EXPONENTIAL (LOG) PHASE: After the lag phase, bacterial cells enter the
exponential or log phase. This is the time when the cells are dividing by binary fission and
doubling in numbers after each generation time. Metabolic activity is high
as DNA, RNA, cell wall components, and other substances necessary for growth are
generated for division. It is in this growth phase that antibiotics and disinfectants are most
effective as these substances typically target bacteria cell walls or the protein synthesis
processes of DNA transcription and RNA translation.
3. STATIONARY PHASE: Eventually, the population growth experienced in the log phase
begins to decline as the available nutrients become depleted and waste products start to
DEFINITION
Growth implies increase in size resulting from cell multiplication and cell expansion, as
well as maturation of tissues. However, growth, while accentuating increased cell number and
size, also necessitates programmed cell death, leading to the production of the final body form.
Thus, growth is an incredibly complex phenomenon, which involves changes in body
form, metabolism, and body processes.
GROWTH CURVE
The bacterial growth curve represents the number of live cells in a bacterial population
over a period of time.
Bacterial growth curves a curve on a graph that shows the changes in size of a bacterial
population over time in a culture. The bacteria are cultured in sterile nutrient medium and
incubated at the optimum temperature for growth. Samples are removed at intervals and the
number of viable bacteria is counted.
1. LAG PHASE: This initial phase is characterized by cellular activity but not growth. A
small group of cells are placed in a nutrient rich medium that allows them to
synthesize proteins and other molecules necessary for replication. These cells increase in
size, but no cell division occurs in the phase.
2. EXPONENTIAL (LOG) PHASE: After the lag phase, bacterial cells enter the
exponential or log phase. This is the time when the cells are dividing by binary fission and
doubling in numbers after each generation time. Metabolic activity is high
as DNA, RNA, cell wall components, and other substances necessary for growth are
generated for division. It is in this growth phase that antibiotics and disinfectants are most
effective as these substances typically target bacteria cell walls or the protein synthesis
processes of DNA transcription and RNA translation.
3. STATIONARY PHASE: Eventually, the population growth experienced in the log phase
begins to decline as the available nutrients become depleted and waste products start to
accumulate. Bacterial cell growth reaches a plateau, or stationary phase, where the number of
dividing cells equals the number of dying cells. This results in no overall population growth.
Under the less favorable conditions, competition for nutrients increases and the cells become
less metabolically active. Spore forming bacteria produce endospores in this phase
and pathogenic bacteria begin to generate substances (virulence factors) that help them
survive harsh conditions and consequently cause disease.
4. DEATH PHASE: In the death phase, the number of living cells decreases exponentially
and population growth experiences a sharp decline. As dying cells lyse or break open, they
spill their contents into the environment making these nutrients available to other bacteria.
This helps spore producing bacteria to survive long enough for spore production. Spores are
able to survive the harsh conditions of the death phase and become growing bacteria when
placed in an environment that supports life.
GENERATION TIME
Generation time, the time that is required for a cell to complete one full growth cycle. If
every cell in the population is capable of forming two daughter cells, has the same average
generation time, and is not lost through lyses, the doubling time of the cell number in a
population will equal the generation time.
SYNCHRONOUS GROWTH
Synchronous growth is the growth of bacteria such that all the bacteria are at the same
stage in their growth cycle (e.g., exponential phase, stationary phase). Because the same cellular
reactions occur simultaneously throughout the bacterial population, synchronous growth permits
the detection of events not normally detectable in a single cell or in a population consisting of
bacteria in various stages of growth.
dividing cells equals the number of dying cells. This results in no overall population growth.
Under the less favorable conditions, competition for nutrients increases and the cells become
less metabolically active. Spore forming bacteria produce endospores in this phase
and pathogenic bacteria begin to generate substances (virulence factors) that help them
survive harsh conditions and consequently cause disease.
4. DEATH PHASE: In the death phase, the number of living cells decreases exponentially
and population growth experiences a sharp decline. As dying cells lyse or break open, they
spill their contents into the environment making these nutrients available to other bacteria.
This helps spore producing bacteria to survive long enough for spore production. Spores are
able to survive the harsh conditions of the death phase and become growing bacteria when
placed in an environment that supports life.
GENERATION TIME
Generation time, the time that is required for a cell to complete one full growth cycle. If
every cell in the population is capable of forming two daughter cells, has the same average
generation time, and is not lost through lyses, the doubling time of the cell number in a
population will equal the generation time.
SYNCHRONOUS GROWTH
Synchronous growth is the growth of bacteria such that all the bacteria are at the same
stage in their growth cycle (e.g., exponential phase, stationary phase). Because the same cellular
reactions occur simultaneously throughout the bacterial population, synchronous growth permits
the detection of events not normally detectable in a single cell or in a population consisting of
bacteria in various stages of growth.
CONTINUOUS CULTIVATION
Continuous culture is a set of techniques used to reproducibly cultivate microorganisms
at submaximal growth rates at different growth limitations in such a way that
the culture conditions remain virtually constant (in 'steady state') over extended periods of time.
FACTORS INFLUENCING MICROBIAL GROWTH
TEMPERATURE
Psychrophiles are cold-loving bacteria. Their optimum growth temperature is between -
5C and 15C. They are usually found in the Arctic and Antarctic regions and in streams
fed by glaciers.
Mesophiles are bacteria that grow best at moderate temperatures. Their optimum growth
temperature is between 25C and 45C. Most bacteria are mesophilic and include common
soil bacteria and bacteria that live in and on the body.
Thermophiles are heat-loving bacteria. Their optimum growth temperature is between
45C and 70C and are commonly found in hot springs and in compost heaps.
Hyperthermophiles are bacteria that grow at very high temperatures. Their optimum
growth temperature is between 70C and 110C. They are usually members of the Archaea
and are found growing near hydrothermal vents at great depths in the ocean.
OXYGEN REQUIREMENTS
Obligate aerobes are organisms that grow only in the presence of oxygen. They obtain
their energy through aerobic respiration.
Microaerophils are organisms that require a low concentration of oxygen (2% to 10%) for
growth, but higher concentrations are inhibitory. They obtain their energy through
aerobic respiration.
Continuous culture is a set of techniques used to reproducibly cultivate microorganisms
at submaximal growth rates at different growth limitations in such a way that
the culture conditions remain virtually constant (in 'steady state') over extended periods of time.
FACTORS INFLUENCING MICROBIAL GROWTH
TEMPERATURE
Psychrophiles are cold-loving bacteria. Their optimum growth temperature is between -
5C and 15C. They are usually found in the Arctic and Antarctic regions and in streams
fed by glaciers.
Mesophiles are bacteria that grow best at moderate temperatures. Their optimum growth
temperature is between 25C and 45C. Most bacteria are mesophilic and include common
soil bacteria and bacteria that live in and on the body.
Thermophiles are heat-loving bacteria. Their optimum growth temperature is between
45C and 70C and are commonly found in hot springs and in compost heaps.
Hyperthermophiles are bacteria that grow at very high temperatures. Their optimum
growth temperature is between 70C and 110C. They are usually members of the Archaea
and are found growing near hydrothermal vents at great depths in the ocean.
OXYGEN REQUIREMENTS
Obligate aerobes are organisms that grow only in the presence of oxygen. They obtain
their energy through aerobic respiration.
Microaerophils are organisms that require a low concentration of oxygen (2% to 10%) for
growth, but higher concentrations are inhibitory. They obtain their energy through
aerobic respiration.
Obligate anaerobes are organisms that grow only in the absence of oxygen and, in fact,
are often inhibited or killed by its presence. They obtain their energy through anaerobic
respiration or fermentation.
Aerotolerant anaerobes, like obligate anaerobes, cannot use oxygen to transform energy
but can grow in its presence. They obtain energy only by fermentation and are known as
obligate fomenters.
Facultative anaerobes are organisms that grow with or without oxygen, but generally
better with oxygen. They obtain their energy through aerobic respiration if oxygen is
present, but use fermentation or anaerobic respiration if it is absent. Most bacteria are
facultative anaerobes.
pH
Neutrophiles grow best at a pH range of 5 to 8.
Acidophiles grow best at a pH below 5.5.
Alkaliphiles grow best at a pH above 8.5.
OSMOSIS
Osmosis is the diffusion of water across a membrane from an area of higher water
concentration (lower solute concentration) to lower water concentration (higher solute
concentration). Osmosis is powered by the potential energy of a concentration gradient and does
not require the expenditure of metabolic energy. While water molecules are small enough to pass
between the phospholipids in the cytoplasmic membrane, their transport can be enhanced by
water transporting transport proteins known as aquaporins. The aquaporins form channels that
span the cytoplasmic membrane and transport water in and out of the cytoplasm.
To understand osmosis, one must understand what is meant by a solution. A solution
consists of a solute dissolved in a solvent . In terms of osmosis, solute refers to all the molecules
or ions dissolved in the water (the solvent). When a solute such as sugar dissolves in water, it
forms weak hydrogen bonds with water molecules. While free, unbound water molecules are
are often inhibited or killed by its presence. They obtain their energy through anaerobic
respiration or fermentation.
Aerotolerant anaerobes, like obligate anaerobes, cannot use oxygen to transform energy
but can grow in its presence. They obtain energy only by fermentation and are known as
obligate fomenters.
Facultative anaerobes are organisms that grow with or without oxygen, but generally
better with oxygen. They obtain their energy through aerobic respiration if oxygen is
present, but use fermentation or anaerobic respiration if it is absent. Most bacteria are
facultative anaerobes.
pH
Neutrophiles grow best at a pH range of 5 to 8.
Acidophiles grow best at a pH below 5.5.
Alkaliphiles grow best at a pH above 8.5.
OSMOSIS
Osmosis is the diffusion of water across a membrane from an area of higher water
concentration (lower solute concentration) to lower water concentration (higher solute
concentration). Osmosis is powered by the potential energy of a concentration gradient and does
not require the expenditure of metabolic energy. While water molecules are small enough to pass
between the phospholipids in the cytoplasmic membrane, their transport can be enhanced by
water transporting transport proteins known as aquaporins. The aquaporins form channels that
span the cytoplasmic membrane and transport water in and out of the cytoplasm.
To understand osmosis, one must understand what is meant by a solution. A solution
consists of a solute dissolved in a solvent . In terms of osmosis, solute refers to all the molecules
or ions dissolved in the water (the solvent). When a solute such as sugar dissolves in water, it
forms weak hydrogen bonds with water molecules. While free, unbound water molecules are
small enough to pass through membrane pores, water molecules bound to solute are not
concentration, the lower the concentration of free water molecules capable of passing through the
membrane.
Most bacteria require an isotonic environment or a hypotonic environment for optimum
growth. Organisms that can grow at relatively high salt concentration (up to 10%) are said to be
osmotolerant. Those that require relatively high salt concentrations for growth, like some of the
Archaea that require sodium chloride concentrations of 20 % or higher halophiles.
MINERALS
1. Sulfur
Sulfur is needed to synthesizes sulfur-containing amino acids and certain vitamins.
Depending on the organism, sulfates, hydrogen sulfide, or sulfur-containing amino acids may be
used as a sulfur source.
2. Phosphorus
Phosphorus is needed to synthesize phospholipids , DNA, RNA, and ATP . Phosphate ions
are the primary source of phosphorus.
3. Potassium, magnesium, and calcium
These are required for certain enzymes to function as well as additional functions.
4. Iron
Iron is a part of certain enzymes.
5. Trace elements
Trace elements are elements required in very minute amounts, and like potassium,
magnesium, calcium, and iron, they usually function as cofactors in enzyme reactions. They
include sodium, zinc, copper, molybdenum, manganese, and cobalt ions. Cofactors usually
function as electron donors or electron acceptors during enzyme reactions.
concentration, the lower the concentration of free water molecules capable of passing through the
membrane.
Most bacteria require an isotonic environment or a hypotonic environment for optimum
growth. Organisms that can grow at relatively high salt concentration (up to 10%) are said to be
osmotolerant. Those that require relatively high salt concentrations for growth, like some of the
Archaea that require sodium chloride concentrations of 20 % or higher halophiles.
MINERALS
1. Sulfur
Sulfur is needed to synthesizes sulfur-containing amino acids and certain vitamins.
Depending on the organism, sulfates, hydrogen sulfide, or sulfur-containing amino acids may be
used as a sulfur source.
2. Phosphorus
Phosphorus is needed to synthesize phospholipids , DNA, RNA, and ATP . Phosphate ions
are the primary source of phosphorus.
3. Potassium, magnesium, and calcium
These are required for certain enzymes to function as well as additional functions.
4. Iron
Iron is a part of certain enzymes.
5. Trace elements
Trace elements are elements required in very minute amounts, and like potassium,
magnesium, calcium, and iron, they usually function as cofactors in enzyme reactions. They
include sodium, zinc, copper, molybdenum, manganese, and cobalt ions. Cofactors usually
function as electron donors or electron acceptors during enzyme reactions.
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