Lesson 3: Microbial Nutrition PDF

Summary

These notes detail the requirements for microbial nutrition, including macronutrients, micronutrients, and various types of microbial nutrition. It covers aspects like carbon sources, energy sources, and electron sources, as well as growth requirements like temperature, gases, and specific conditions.

Full Transcript

LESSON 3: MICROBIAL NUTRITION

 Macronutrients / Macroelements
 required by microorganism in relatively large amount
 C, H, O, N, S, Ca, P, Fe, K, Mg
 Cations: K, Ca, Mg, Fe
 K - required for the activity of enzymes, osmoregulation, pH homeostasis, protein
synthesis
 Ca - for heat resistance, required in cell division and cell membrane
 Mg - stabilizing ribosomes and membrane

 Micronutrients / Trace Elements
 Required by microorganism in relatively small amount
 Normally part of enzymes and cofactors, aid in catalysis of reactions and maintenance of
protein structure
 Fe2+ & Fe3+ - cofactor of enzymes and electron carrying proteins, part of cytochromes
 Vitamins - functions as coenzymes, required growth factor
 Manganese - aids enzymes catalyzing the transfer of phosphate groups
 Zinc - present at the active site of some enzyme, catalytic subunits of E. coli aspartate
carbomoyl transferase
 Molybdenum, nickel, copper

 Nutritional Types of Microorganisms
Carbon Sources
 Autotrophs - use CO2 as sole or principal source of carbon, uses light as energy
source
 Heterotrophs - use reduced pre-formed organic molecules as carbon sources

Energy Sources
 Phototrophs - use light as energy source
 Chemotrophs - obtain energy from the oxidation of chemical compounds (organic /
inorganic)

Electron Sources
 Lithotrophs - use reduced inorganic substances as electron source
 Organotrophs - extract electrons from organic compounds

Note: They could be combined. Ex:
 Photolitotrophs - photo + litho
 Photolithotrophic autotrophs - photo + litho + autotrophs
 Chemoorganotrophic heterotrophs - chemo + organo + heterotrophs

 Requirements for Nitrogen, Phosphorus, and Sulfur
 Nitrogen
 Needed for the synthesis of amino acids, purines, pyramidines, some carbohydrates and
lipids, enzyme cofactors
 In most autotrophs and many non photosynthetic microbes (Cyanobacteria Rhizobium) :
 Reduce nitrate to ammonia
 Incorporate ammonia in assimilatory nitrate reduction
 Phosphorus
 Present in nucleic acids, phospholipids, ATP, several cofactors, some proteins and cell
components
 Used by ALL microbes
 Sulfur
 Needed for synthesis of amino acids (cysteine, methionine), some carbohydrates (biotin,
thiamine)
 Some microbes require reduced form of sulfur such as cysteine

 Growth Factors
 Used by microbes that lack one or more enzymes needed for the cell components or
precursors of the mentioned components
Major Classes:
 Amino acids
 for protein synthesis
 Purines & Pyrimidines
 For nucleic acid synthesis
 Vitamins
 Small organic molecules that make up all or part of enzymes cofactors, only very
small amounts sustain growth

 Growth Requirements
Gaseous Requirements
 Aerobic Bacteria
 require oxygen for growth
 Obligate aerobes to grow only in the presence of oxygen (Pseudomonas aeruginosa)
 Anaerobic Bacteria
 Grow in absence of oxygen (Clostridium tetani)
 Obligate anaerobes - may die on exposure to oxygen
 Facultative anaerobes - can grow in presence of oxygen & survive without
oxygen via anaerobic respiration or fermentation
 Microaerophilic Bacteria
 Proliferate (increase in #) in the presence of low oxygen tension

Temperature Requirements
 Most important factor that can affect growth of microorganisms
 Temperature range - must not be above the maximum or below the minimum as it can
affect growth
 Optimum - growth occurs best (ex: pathogenic bacteria, -37 degrees C)
Temperature classes (in degrees C):
 Psychrophiles
- 15 or lower
- max: -10
  Psychrotrophs / Facultative Psychrophiles
 20 - 30
 max: 35
 Mesophiles
 25 - 40
 min: 15-20,
max: 45
 Thermophiles
 55 - 60
 min: 45

Other Requirements:
 Moisture and drying
 Hydrogen ion concentration
 Light
 Osmotic effect
 Mechanical and sonic stress

 Growth Media
Culture Media
 Nutrient solutions tailored to the particular organism to be grown
 It must be sterilized before use thru heating of medium under pressure in an autoclave
 Prepared selectively or differentially or both
2 classes:
 Defined media - exact composition of a defines medium (quali and quanti sense) is
known, prepared by adding precise amounts of pure inorganic or organic chemicals to
distilled water
 Complex media - made from digests of microbial, animal, plant products like milk
protein (casein), beef extract, soybeans (tryptic soy broth), yeast cells (yeast extract)

Based on Consistency
 Solid medium
 Contains 2% agar
 Used for colony morphology, pigmentation, hemolysis
 Ex: nutrient agar, blood agar

 Liquid medium
 No agar
 Used for inoculum preparation, blood culture, isolation of pathogens from a mixture
 Becomes cloudy as indication of growth
 Ex: nutrient broth

 Semi solid medium
 For checking motility

Based on Nutritional Component
1. Simple media
  Aka basal media
 Used for non-fastidious (not having complex nutritional requirements) bacteria
 Ex: nutrient agar and broth
2. Defined media
 All the ingredients are known
(quali and quanti)
3. Complex media
 Contain undefined ingredients and the exact contents are known
 Ex: nutrient broth, tryptic soya broth, MacConkey agar (for Lactobacillus)
 May contain undefined components:
 Peptones - prepared by partial proteolytic digestion of meat, casein, soyameal,
gelatin, and other protein sources
 Meat extract - aqueous extracts from lean beef and contain amino acids,
peptides, nucleotides, organic acids, minerals, vitamins
 Yeast extract - from brewer’s yeast and contain an excellent source of vit B,
nitrogen, carbon compounds

Based on Functional Use / Application
1. Enriched medium
 Broth or solid medium containing a rich supply of special nutrients
 Used for fastidious microbes
 Ex: blood agar, chocolate agar
2. Indicator media
 Contain an indicator which changes color when a bacterium grows in them
 Ex: Christensen’s urease medium
3. Transport media
 Used for transporting the samples
 Delicate organisms may not survive the time taken for transporting specimen w/o it
 Ex: buffered glycerol saline
4. Anaerobic media
 Used to grow anaerobic organisms
 Ex: Robertson’s cooked meat medium
5. Differential medium
 One to which an indicator (typically a dye) is added, which reveals by a color change
whether a particular metabolic reaction has occurred during growth
 Ex: MacConkey agar (for lactose fermentation)
6. Selective media
 Contain compounds that inhibit the growth of some microbes but not others
 Ex: Eosin Methylene Blue (EMB) - contains dyes that are not for gram positive bacteria
and allows growth of gram negative bacilli and enteric bacilli - coliforms and faccal
coliforms

Isolation of Pure Cultures
 A pure culture is needed to characterize and identify an individual species
 Culture methods include:
1. Stab culture
 Prepared by puncturing a suitable medium - with a long, straight wire
 Used to study oxygen requirements
2. Pour plate method
 Gives an estimate of the viable bacterial count in a suspension
 Used for quantitative urine cultures
  Should be avoided when trying to determine viable cell counts of heat-sensitive bacteria
isolate
3. Liquid culture
 Inoculated by touching with a charged loop or by adding inoculum with pipettes or
syringes
 Used for blood culture, sterility tests & continuous culture methods
4. Anaerobic culture methods
5. Streak culture
 Isolation of bacteria in pure culture from clinical specimens
6. Lawn culture
 Provides a uniform surface growth of the bacterium
 Can be used for bacteriophage typing, antibiotic sensitivity testing, preparation of
bacterial antigens and vaccines
 Prepared by flooding the surface of the plate with a liquid suspension of the bacterium
7. Stroke culture
 Made in tubes containing agar slope or slant provide a pure growth of bacterium for slide
agglutination and other diagnostic tests

Laboratory Culture of Microorganisms
1. Agar
 Used to solidify the culture media
 An algal polysaccharide first used in the classical studies of Robert Koch
 Solid media immobilize cells so that as they grow, they accumulate in a pile to form
visible, isolated cell masses called colonies
2. Colony morphology
 Visible characteristics of a colony
 Used to identify microbes but is routinely used to determine if culture is:
 Pure - only one microbe
 Contaminated - undesired organisms co-occur
 Mixed - many microbes present
3. Aseptic technique
 Series of steps by which microbes are transferred between growth media without
contamination.
 Contamination can be introduced from microbes in the air, in liquid droplets, or on
surfaces
 Streak plate technique - method for obtaining pure cultures that contain a single
microbe, and of verifying culture purity using inoculating loop

 Microbial Growth
Growth
 Increase in number of cells (binary fission)
 Cell division following enlargement of a cell to twice its minimum size
 During cell division, each daughter cell receives a chromosomes and sufficient copies of
all other cell constituents to exist as an independent cell

Four Phases of Microbial Growth
1. Lag phase
 Initial phase, bacteria are metabolically active but not dividing
2. Log phase (exponential phase)
 Time of exponential growth
 Period when the growing cell population doubles at regular intervals (balanced growth)
3. Stationary phase
 Growth reaches plateau as the number of dying cells equals the number of dividing cells
 Not net increase or decrease in cell number, thus growth rate=0
 Cell prepares for maintenance and survival
4. Death phase
 Exponential decrease in number of living cells
 Decline phase - total number of cells decreases due to cell death

Generation time = time per generation/
number of generations
(aka doubling time) - time required for cell to separate

N - final cell number
No - initial cell number
N - number of generations during the period of exponential growth

Synchronous Growth
 Microbiological culture or a cell culture that contains cells that are all in the same growth
stage
 Information about growth behaviour of individual bacteria can be obtained by
synchronous cultures
 Synchronized cultures must be composed of cells which are all at the same stage of the
bacterial cell cycle

Continuous Culture
 The cultures so far discussed for growth of bacterial populations are called batch
cultures (describes the growth of microbes in a fixed volume of liquid enclosed within a
container such as a test tube or a flask)
 Since the nutrients are not renewed, exponential growth is limited to a few generations
 Chemostat - most common type of continuous culture device
 An open system aiming to attain steady state

Diauxic Growth
 Used to describe the growth phases of a microbes in batch culture as it metabolizes a
mixture of 2 sugars
 Resulting in 2 separate growth phases

Methods for Measurement of Cell Mass
Microscopic cell count - total count of microbial numbers can be observed and enumerated
here
Viable cell - one that is alive and able to grow
Viable count - performed by spreading microbes on solid media and counting colonies, aka
plate count (requiring agar plates)
Spread-plate & Pour-plate - 2 ways in performing plate count
Colony-forming units (CFU) - expressed as the number data from viable counts
A. Direct Microscopic Count
 A counting chamber consisting of a ruled slide and a coverslip is employed
 Constructed in a manner that the coverslip, slide, and ruled lines delimit a known value
 The number of bacteria in a small known volume is directly counted microscopically
 The number of bacteria in the larger original sample is determined by extrapolation

B. Electronic Enumeration of Cells
 The microbial suspension is forced through a small hole or orifice in the coulter chamber
 An electrical current flow through the hole and electrodes placed on both sides of the
orifice measure its electrical resistance

C. Plate Count Method
 Standard Plate Count (SPC) - number of bacterial colonies that develop on a medium
in a petri dish seeded with a known amount of inoculum
 Volume (usually 0.1–1.0 ml) of culture is pipetted into an empty
sterile Petri plate. Molten agar medium, tempered to just above gelling temperature
(50°C), is then added and gently mixed before
allowing the agar to solidify.

D. Membrane Filter Technique
 The number of bacterial in aquatic sample can be determined from direct counts after
the bacteria have been trapped on special membrane filters such as nitrocellulose more
size filter or a black polycarbonate membrane filter

E. Turbidimetric Methods
 When bacteria growing in a liquid medium are mixed, the culture appears turbid due to
bacterial culture acting as a colloidal suspension that blocks and reflects light passing
through the culture

F. Determination of Nitrogen Content
 The major constituent of cell material is protein, and since nitrogen is a characteristic
part of proteins, one can measure a bacterial populations or cell crop in terms of
bacterial nitrogen

G. Determination of Dry Weight
 Measure some quantifiable cell property that increases as a direct result of microbial
growth
 Simplest technique is to measure the weight of cells in a sample
H. Measurement of Specific Chemical Changes
 Detects specific changes caused in growth medium as a result of multiplication of cells
 Includes detecting activity cell products such as acid and gas production

I. Spread-plate Method
 A volume of an appropriately diluted culture is spread over the surface of an agar plate
using sterile glass spreader