MicroBio6 Lecture PPT Ch04 HP PDF

Summary

This document is a microbiology lecture presentation about Bacterial Culture, Growth, and Development. It covers microbial nutrition, nutrient uptake, culturing techniques, growth cycles, biofilms, and cell differentiation. The lecture also describes various types of microbes based on carbon and energy acquisition like photoautotrophs and chemoheterotrophs. Note that the document is a lecture presentation and not a past paper.

Full Transcript

CHAPTER 4 Lecture
Slides

Bacterial Culture,
Growth, and
Development

Copyright © 2024 by W. W. Norton & Company, Inc.
 CHAPTER OVERVIEW

4.1 MICROBIAL NUTRITION
4.2 NUTRIENT UPTAKE
4.3 CULTURING AND COUNTING BACTERIA
4.4 THE GROWTH CYCLE
4.5 BIOFILMS
4.6 CELL DIFFERENTIATION
 4.1 MICROBIAL NUTRITION

 Essential nutrients are those that must be supplied from the
environment.
 Macronutrients

Major elements in cell macromolecules
– C, O, H, N, P, S

Cations necessary for protein function
– Mg2+, Ca2+, Fe2+, K+

 Micronutrients

Trace elements necessary for enzyme function
– Co, Cu, Mn, Zn
Nutrient Supplies Limit Microbial Growth
Microbes Build Biomass through Autotrophy or
Heterotrophy

 All of Earth’s life-forms are based on carbon, which
they acquire in different ways.
Autotrophs fix CO2 and assemble into organic
molecules (mainly sugars).
Heterotrophs use preformed organic molecules.
Microbes Build Biomass through Autotrophy or
Heterotrophy

 All organisms require an energy source.
Phototrophs obtain energy from chemical reactions
triggered by light.
Chemotrophs obtain energy from oxidation-
reduction reactions.
 Lithotrophs use inorganic molecules as a source
of electrons.
 Organotrophs use organic molecules.
Microbes Build Biomass through Autotrophy or
Heterotrophy

 In short, microbes are classified based on their carbon
and energy acquisition as follows:
Autotrophs
– Photoautotrophs
– Chemolithoautotrophs (or lithotrophs)
Heterotrophs
– Photoheterotrophs
– Chemoheterotrophs (or organotrophs)
Microbes Build Biomass through Autotrophy or
Heterotrophy

The Carbon Cycle
Energy Is Stored for Later Use

 A membrane potential is generated when chemical
energy is used to pump protons outside of the cell.
 The H+ gradient plus the charge difference form an
electrochemical potential called the proton motive force.
 The potential energy stored can be used to transport
nutrients, drive flagellar rotation, and make ATP by the
F1FO ATP synthase.
Energy Is Stored for Later Use
The Nitrogen Cycle

 N2 makes up nearly 79% of Earth’s atmosphere but is
unavailable for use by most organisms.
 Nitrogen fixers possess nitrogenase, which converts N2
to ammonium ions (NH4+).
 Nitrifiers oxidize ammonia to nitrate (NO3–).

 Denitrifiers convert nitrate to N2.
The Nitrogen Cycle
The Nitrogen Cycle

 Nitrogen-fixing bacteria may be free-living in soil or water,
or they may form symbiotic associations with plants.
Rhizobium are symbionts in leguminous plants such as
soybeans, chickpeas, and clover.
 4.2 NUTRIENT UPTAKE

 Membranes are designed to separate what is outside
the cell from what is inside.
 Selective permeability is achieved in three ways:
Substrate-specific carrier proteins, or permeases
Dedicated nutrient-binding proteins that patrol the
periplasmic space
Membrane-spanning protein channels or pores
Facilitated Diffusion

 Facilitated diffusion helps solutes move across a
membrane from a region of high concentration to one
of lower concentration.
It does not use energy and cannot move a molecule
against its gradient.
 Example: the aquaporin family that transports water
and small polar molecules such as glycerol
Facilitated Diffusion
Active Transport Requires Energy

1. Coupled transport systems are those in which energy
released by a driving ion moving down its gradient is
used to move a solute up its gradient.
In symport, the two molecules travel in the same
direction.
In antiport, the actively transported molecule
moves in the direction opposite to the driving ion.
Active Transport Requires Energy
Active Transport Requires Energy
Active Transport Requires Energy
ABC Transporters Are Powered by ATP

2. The largest family of energy-driven transport systems is the
ATP-binding cassette superfamily, or ABC transporters.
They are found in all three domains of life.
Three components: solute-binding protein, membrane-
spanning protein and ATPases.
 Two main types:
Uptake ABC transporters are critical for transporting
nutrients.
Efflux ABC transporters are generally used as multidrug
efflux pumps and do not need solute-binding proteins.
ABC Transporters Are Powered by ATP
Siderophores Are Secreted to Scavenge Iron

 Siderophores are specialized molecules secreted to
bind ferric ion (Fe3+) and transport it into the cell.
The iron is released into the cytoplasm and
reduced to the more useful ferrous (Fe2+) form.
 Note: Neisseria gonorrhoeae employs receptors on its
surface that bind human iron complexes and wrest the
iron from them.
Siderophores Are Secreted to Scavenge Iron
Group Translocation Avoids “Uphill” Battles

3. Group translocation is a process that uses energy to
chemically alter the substrate during its transport.
The phosphotransferase system (PTS) is an example
present in all bacteria.
It uses energy from phosphoenolpyruvate (PEP) to
attach a phosphate to specific sugars.
The system has a modular design that accommodates
different substrates.
Group Translocation Avoids “Uphill” Battles
 4.3 CULTURING AND COUNTING
BACTERIA

 Microbes in nature exist in complex, multispecies
communities, but for detailed studies they must be
grown separately in pure culture.
 After almost 140 years of trying, we have succeeded in
culturing less than 1% of the microorganisms around
us.
 The vast majority has yet to be tamed.
Bacteria Are Grown in Culture Media

 Bacteria are grown in culture media, which are of two
main types:
1. Liquid or broth
– Useful for studying the growth characteristics of a
pure culture
2. Solid (usually gelled with agar)
– Useful for trying to separate mixed cultures from
clinical specimens or natural environments
Bacteria Are Grown in Culture Media
Dilution Streaking and Spread Plates

 Pure colonies are isolated via two main techniques:
1. Dilution streaking (= Streak plate)
– A loop is dragged across the surface of an agar plate.
– Best to obtain single colonies.

2. Spread plate
– Tenfold serial dilutions are performed on a liquid culture.
– A small amount of each dilution is then plated.
– Best to count colonies.
– Only viable cells will grow.
Dilution Streaking and Spread Plates
Dilution Streaking and Spread Plates
Dilution Streaking and Spread Plates
Complex versus Minimal Defined Media

 Complex media are nutrient rich but poorly defined.
 Minimal defined media contain only those nutrients
that are essential for growth of a given microbe.
 Best for checking metabolism of a microbe.
Complex versus Minimal Defined Media

TABLE 4.1 Composition of Commonly Used Media
Medium Ingredients per liter Organisms cultured
Lysogeny broth; also Bacto tryptonea 10 g Many Gram-negative and Gram-positive
called Luria Bertani Bacto yeast extract 5g organisms (such as Escherichia coli and
broth (complex) NaCl 10 g Staphylococcus aureus, respectively)
Adjust to pH 7
M9 medium (defined) Glucose 2.0 g Gram-negative organisms such as E. coli
Na2HPO4 6.0 g (42 mM)
KH2PO4 3.0 g (22 mM)
NH4Cl 1.0 g (19 mM)
NaCl 0.5 g (9 mM)
MgSO4 2.0 mM
caC12 0.1 mM
Adjust to pH 7
Sulfur oxidizers NH4Cl 0.52 g Acidithiobacillus thiooxidans
(defined) KH2PO4 0.28 g
MgSO4 7H2O 0.25 g
CaCl2 0.07 g
Elemental sulfur 1.56 g
grown in an
atmosphere of 5% CO2
Adjust to pH 3
a
Bacto tryptone is a pancreatic digest of casein (bovine milk protein).
Selective, Differential, and Enrichment Media

 Enriched media are complex media to which specific
blood components are added.
 Selective media favor the growth of one organism over
another.
 Differential media exploit differences between two
species that grow equally well.
Selective, Differential, and Enrichment Media

 Several media used in
clinical microbiology
are both selective and
differential.
e.g., MacConkey
medium
Growth Factors and Uncultured Microbes

 Microbes can evolve to require specific growth factors
depending on the nutrient richness of their natural
ecological niche.
 Growth factors are specific nutrients not required by
other species.
A microbe needs them in order to be able to grow in
laboratory media.
e.g., Streptococcus pyogenes requires glutamic acid
and alanine because it can no longer synthesize
them.
Growth Factors and Uncultured Microbes

TABLE Growth Factors and Natural Habitats of
4.2 Organisms Associated with Disease
Organism Diseases Natural habitats Growth factors
Abiotrophia Osteomyelitis Humans and other animal Vitamin K, cysteine
species
Bordetella Whooping cough Humans and other animal Glutamate, proline, cysteine
species
Francisella Tularemia Wild deer, rabbits Complex, cysteine
Haemophilus Meningitis, chancroid Humans and other animal Hemin, NAD
species, upper respiratory
tract
Legionella Legionnaires' disease Soil, refrigeration cooling Cysteine
towers
Mycobacterium Tuberculosis, leprosy Humans Nicotinic acid (NAD),a alanine
(M. leprae is unculturable)
Shigella Bloody diarrhea Humans Nicotinamide (NAD)a
Staphylococcus Boils, osteomyelitis Widespread Complex requirement
Streptococcus Pharyngitis, rheumatic fever Humans Glutamate, alanine
pyogenes
Both nicotinamide and nicotinic acid are derived from NAD, nicotinamide adenine dinucleotide.
Growth Factors and Uncultured Microbes

 Some species have adapted so well to their natural
habitats that we still do not know how to grow them in
the lab.
Some of these uncultured organisms depend on
factors provided by other species that cohabit their
niche.
Growth Factors and Uncultured Microbes
 Growth Factors and Uncultured Microbes

 Obligate intracellular bacteria are also
unculturable.
e.g., Rickettsia prowazekii, the cause
of epidemic typhus fever, has
adapted to grow within the
cytoplasm of eukaryotic cells and
nowhere else.
Techniques for Counting Bacteria

 There are many reasons why it is important to know
the number of organisms in a sample.
 Counting or quantifying organisms invisible to the
naked eye is surprisingly difficult.
Each of the available techniques measures a
different physical or biochemical aspect of growth.
– Thus, cell density values derived from these techniques
may not necessarily agree with one another.
Techniques for Counting Bacteria

 Microorganisms can be counted directly by placing
dilutions on a special microscope slide called a Petroff-
Hausser counting chamber.
Techniques for Counting Bacteria

 Living cells may be distinguished
from dead cells by fluorescence
microscopy using fluorescent
chemical dyes.
Dead bacterial cells fluoresce
orange or yellow because
propidium (red) can enter the
cells and intercalate the base
pairs of DNA.
Live cells fluoresce green
because Syto-9 (green) enters
the cell.
Techniques for Counting Bacteria

 Direct counting without microscopy can be done using an
electronic technique that not only counts but also separates
populations of bacterial cells according to their distinguishing
properties.
 The instrument is called a fluorescence-activated cell sorter
(FACS) or flow cytometer.
Fluorescent cells are passed through a small orifice and then
past a laser.
Detectors measure light scattered in the forward direction
(measure of particle size) and to the side (particle shape or
granularity).
Techniques for Counting Bacteria
Techniques for Counting Bacteria
Techniques for Counting Bacteria

 A viable bacterium is defined as being capable of
replicating and forming a colony on a solid medium.
Viable cells can be counted via the pour plate
method.
 Microorganisms can be counted indirectly via
biochemical assays of cell mass, protein content, or
metabolic rate.
Also, by measuring optical density (OD) by which
dead cells also are counted.
 4.4 THE GROWTH CYCLE

 Most bacteria divide
by binary fission,
where one parent
cell splits into two
equal daughter cells.
 However, some
divide
asymmetrically.
 Hyphomicrobium
divides by budding.
Exponential Growth

 The growth rate, or rate of increase in cell numbers or
biomass, is proportional to the population size at a given
time.
Such a growth rate is called “exponential” because it
generates an exponential curve, a curve whose slope
increases continually.
If a cell divides by binary fission, the number of cells is
proportional to 2n.
– Where n = number of generations
Note: Some cyanobacteria divide by multiple fission.
Generation Time

 Generation time is the time it takes for a population to
double.
 For cells undergoing binary fission,

Nt = N0 x 2n

where Nt is the final cell number,
N0 is the original cell number, and
n is the number of generations.
Stages of Growth in a Batch Culture

 Exponential growth never lasts indefinitely.

 The simplest way to model the effects of a changing environment
is to culture bacteria in a batch culture.
A liquid medium within a closed system
 The changing conditions in this system greatly affect bacterial
physiology and growth.
This illustrates the remarkable ability of bacteria to adapt to
their environment.
For some bacteria, quorum sensing begins at the late log
phase.
Generation Time
Stages of Growth in Batch Culture
Stages of Growth in Batch Culture
Stages of Growth in Batch Culture

 Rhodopseudomonas
palustris, a
phototrophic,
aquatic Gram-
negative bacterium,
can enter a growth-
arrested state for
months during
carbon or nitrogen
restriction, but only
in the presence of
light.
Stages of Growth in Batch Culture
Continuous Culture

 In a continuous culture, all cells in a population
achieve a steady state, which allows detailed study of
bacterial physiology.
 The chemostat ensures logarithmic growth by
constantly adding and removing equal amounts of
culture medium.
A liquid medium within an open system
 Note that the human gastrointestinal tract is
engineered much like a chemostat.
Continuous Culture
Continuous Culture
 4.5 BIOFILMS

 In nature, many bacteria form specialized, surface-
attached communities called biofilms.
These can be constructed by one or multiple species and
can form on a range of organic or inorganic surfaces.
The Biofilm Life Cycle
The Biofilm Life Cycle
The Biofilm Life Cycle

 Bacterial biofilms form when nutrients are plentiful.
Once nutrients become scarce, individuals detach
from the community to forage for new sources of
nutrients.
 Biofilms in nature can take many different forms and
serve different functions for different species.
 The formation of biofilms can be cued by different
environmental signals in different species.
The Biofilm Life Cycle

 Chemical signals enable both aerobic and anaerobic
bacteria to communicate (quorum sensing) and in some
cases to form biofilms when population reaches a certain
number.
 Biofilm development involves:
The adherence of cells to a substrate
The formation of microcolonies
Exopolysaccharide (EPS) production by bacteria
Ultimately, the formation of complex channeled
communities that generate new planktonic cells
The Biofilm Life Cycle
The Biofilm Life Cycle
The Biofilm Life Cycle

 For many bacteria,
sessile (nonmoving) cells
in a biofilm chemically
“talk” to each other in
order to build
microcolonies and keep
water channels open.
Bacillus subtilis also
spins out a fibril-like
amyloid protein
called TasA, which
tethers cells and
strengthens biofilms.
 Biofilm Differentiation and Communication

 Bacteria growing in
biofilms also exhibit a
type of cell
differentiation
initiated by
physiological
conditions that
develop in different
layers of the biofilm.
Escherichia coli
biofilms exhibit
two-layer
differentiation vis-
à-vis oxygen
availability.
 4.6 CELL DIFFERENTIATION

 Bacteria faced with environmental stress undergo
complex molecular reprogramming that includes
changes in cell structure.
 Examples include:

1. Endospores of certain Gram-positive bacteria
2. Heterocysts of cyanobacteria
3. Fruiting bodies of Myxococcus xanthus
4. Aerial hyphae and arthrospores of Streptomyces
Endospores Are Bacteria in Suspended Animation

 Clostridium and Bacillus species can produce dormant
spores that are heat resistant.
 Starvation initiates an elaborate 8-hour genetic
program that involves:
An asymmetrical cell division process that
produces a forespore and ultimately an endospore
 Sporulation can be divided into discrete stages based
primarily on morphological appearance.
Endospores Are Bacteria in Suspended Animation
Endospores Are Bacteria in Suspended Animation
Cyanobacteria Differentiate to Fix Nitrogen

 Anabaena
differentiates into
specialized cells
called heterocysts.
 Allows it to fix
nitrogen
anaerobically while
maintaining oxygenic
photosynthesis
Myxococcus Differentiation Is a “Family” Gathering

 Myxococcus xanthus uses gliding motility.
 Starvation triggers the aggregation of 100,000 cells, which
form a fruiting body.
Actinomycetes: The Fungus-like Bacteria

 Streptomyces bacteria form mycelia and sporangia analogous to
those of fungi.
 As nutrients decline, aerial hyphae divide into arthrospores that
are resistant to drying.
Actinomycetes: The Fungus-like Bacteria