Microbial Biotechnology (408 AMB) PDF

Summary

These lecture notes cover Microbial Biotechnology (408 AMB). The content delves into definitions, classifications, and specific mechanisms like isolating antibiotics and their modes of action within the context of microbial life.

Full Transcript

Microbial Biotechnology
(408 AMB)

Dr. Aya Samir
 What is the BIOTECHNOLOGY
The United Nations Convention on Biological
Diversity defines biotechnology as:
"Any technological application that uses biological
systems or living organisms to make or modify
products or processes for specific use.“
Biotechnology is any technique that uses living
organisms or substances from those organisms:
to make or modify a product or processes,
to improve plants or animals,
to develop microorganisms for specific uses.
 What is the BIOTECHNOLOGY

Biotechnology is the application of scientific and
engineering principles to the possessing of raw
materials by biological agents to provide
commercial products and services.
 Raw Organic materials
Materials Inorganic materials

Microorganisms
Biological Microbial products
Agents Animal cells
Plant cells
 Disciplines of biotechnology

Red Green
Biotechnology Biotechnology

White Blue
Biotechnology Biotechnology
Disciplines of biotechnology
 MICROBIAL BIOTECHNOLOGY

Application of scientific and engineering
principles to the possessing of raw
materials by microorganisms or
microbial substances to provide
commercial products and services.
The microbial products are classified according to
the industrial sectors to 6 groups
Area of Application
application
Enzymes, polysaccharides, organic
Chemical sector
solvents, organic acids, …. etc
Antibiotics, therapeutic enzymes,
Pharmaceutical
vaccines, antibodies, human
and health
hormones, biosensors, gene
sector
therapy,……etc.
Energy sector Ethanol, methane (biogas)
Food sector Baker's yeast, food additives,
beverages, single cell protein
 Area of Application
application
Microbial pesticides, microbial
fertilizers, tissue culture, transfer of
nif-gene for nitrogen fixation from
Agricultural legumes to cereals, increasing milk,
sector meat and egg production from farm
animals, veterinary vaccines,
production of animal feed from single
cell protein
Environmental Removing heavy metals from water,
sector biodegradation of oil, plastics, ….. etc.
 Antimicrobial Agents

Chemical compounds biosynthetically or
synthetically produced to Kill or inhibit the
growth or metabolism of the
microorganisms without serious toxicity to
the host.
Among the antimicrobial agents are
antibacterial drugs, antiviral agents,
antifungal agents, and antiparasitic drugs.
 Antibiotics
Definition:
The antibiotics are secondary metabolites
produced by some microorganisms to kill or
inhibit the growth of other microorganisms even
when used with low concentration.
Antibiotic - producing microorganisms:
Bacteria
Actinomycetes
Fungi
Classification of antibiotics:
The antibiotics are classified according to:

Antimicrobial Chemical
spectrum structure

Manner of Producer Mode of
biosynthesis strain action
 Antimicrobial Spectrum

What is the antimicrobial spectrum?

The range of microbial species susceptible to
specific antimicrobial agent.
 Antimicrobial Spectrum
According to the antimicrobial spectrum,
the antibiotics are classified into 2 groups:

A: Broad spectrum B: Narrow spectrum
antibiotics antibiotics

The antibiotic is The antibiotic is
active against a active against a
wide range of narrow range of
microorganisms microorganisms
Antimicrobial Spectrum

The spectra of activity may
change with acquisition of
resistance genes
Narrow spectrum Broad spectrum
antibiotic antibiotic
 Antibiotics Mode of Action

The major actions of antibiotics include:
1. Inhibition of cell wall synthesis.
Chemical structure of Chemical structure of
peptidoglycan in G+ peptidoglycan in G-
bacteria bacteria
 Antibiotics Mode of Action

The major actions of antibiotics include:
1. Inhibition of cell wall synthesis.
In order for bacteria to increase their size
following binary fission, the following actions
must be completed:
breaking down links in the peptidoglycan.
inserting new peptidoglycan monomers.
reformation of the peptide cross links.
 Antibiotics Mode of Action
The following sequence of steps occur:
Step 1. Bacterial enzymes called autolysins are
synthesized to:
Lysis of the glycoside bonds between the
peptidoglycan monomers.
Lysis of the peptide cross-bridges.
Step 2. The peptidoglycan monomers are synthesized
in the cytoplasm and bind to bactoprenol to
transport them across the cytoplasmic
membrane and interact with transglycosidase
enzyme to insert the monomers into existing
peptidoglycan.
 Antibiotics Mode of Action

Step 3. Transglycosylase (transglycosidase)
enzymes insert and link new
peptidoglycan monomers into the
breaks in the peptidoglycan.

Step 4. Finally, transpeptidase enzymes reform the
peptide cross-links between the glycan
chains of peptidoglycan to make the wall
strong.
 Antibiotics Mode of Actions

The major actions of antibiotics include:
1. Inhibition of cell wall synthesis.
Preventing the transpeptidation reaction
Binding the antibiotics to transpeptidase
enzymes.
Binding the antibiotics directly to the
terminal D-alanyl-D-alanine peptide on
the peptidoglycan precursors.
Binding the antimicrobial agent to Interfering with the
transpeptidase enzyme leads to action of
transglycosidase
Autolysin enzyme
Preventing releasing
transpeptidation
Degrading
the existing Preventing the
Preventing cross- cell wall insertion of new
linkage of the peptidoglycan
two glycan linked monomers
peptide chains

Weak and self-
degrading cell wall
Mycoplasma is resistant Archaea are resistant
to these antibiotics to these antibiotics

it does not have cell they have pseudo -
wall peptidoglycan in
the cell wall
Unlike bacteria, archaea
lack peptidoglycan in their cell *
wall but have
pseudopeptidoglycan, which *
is different in the chemical
structure.
It lacks D-amino acids
It lacks N-acetylmuramic
acid. *
N-acetylglucoseamine
binds N-
acetyltalosaminuronic acid
*
through β-1,3 glycosidic
bond.
Cell wall of archaea provides both chemical and physical
protection, and prevent macromolecules from
contacting the cell membrane.
2. Destruction of the
cell membrane
Some antibiotics cause
formation of pores or
channels across the cell
membrane.

Permeabilization of the
cell membrane.

The transport into and
out of the cell is impaired.
 3. Inhibition of protein synthesis

Binding to the
Binding to the 30s 50s ribosomal
ribosomal subunit subunit

Blocking the
attachment Misreading of Interference
of tRNA mRNA with binding of
amino acids to
the protein
4. Inhibition of nucleic acids synthesis.
Some antibiotics can inhibit any of the steps of
DNA or RNA replication.

5. Competitive inhibition.
Competitive inhibition is a form of enzyme
inhibition in which binding the inhibitor to the
active site or allosteric site on the enzyme
prevents binding the substrate.
The antibiotic structure is similar to the enzyme
substrate, so the antibiotic can compete with
the substrate for the active site of the enzyme and
inhibits the synthesis of the end product.
 Competitive inhibitors could bind to an allosteric
site of the enzyme and prevent substrate binding.
 Although there are a number of different
antibiotics, they work in one of two ways:
Bactericidal antibiotics that kill the bacteria. The
action of bactericidal antibiotics are irreversible
so once sensitive cells are exposed to a
bactericidal antibiotic, they die. A bactericidal
antibiotics usually either interferes with the
formation of the bacterial cell wall or its cell
contents.
Bacteriostatic antibiotics that inhibit the bacterial
growth and reproduction. Upon exposure to a
bacteriostatic antibiotic, cells in a susceptible
population stop dividing. However if the agent is
removed, the cells once again multiply.
Bacteriostatic agent Bactericidal agent
Some drugs that are bacteriostatic at lower
concentrations can be bactericidal at
higher concentrations.
 Isolation of Antimicrobials-producing
Microorganisms
It is used to isolate antimicrobials-
Crowded producing microorganisms without
plate regarding to what type of the
method microorganisms will be sensitive to
the antimicrobial compound.
The test microorganism is used as
Spot-on- an indicator for presence of the
lawn antimicrobial activity.
method
 Crowded Plate Method

The aseptic conditions must be considered
1.Preparing serial decimal dilutions.
2.Transferring 1 ml of each selected dilution to 1 plate.
1g 1 ml 1 ml 1 ml 1 ml

Soil
sample

1 ml

1:10 1:100 1:1000 1:10000 1:100000
3. Melting the nutrient agar medium at 100°c
using a water bath.
4. Cooling the melted medium to 50°c.
5. Pouring the medium into the plates.
6. Mixing the medium and inoculum by a
circular movement of the plates.
7. Allowing the plates to set.
8. Incubating the plates in the inverted position
at 30 °C / 24-48h.
After the incubation:
The colonies which produce antimicrobial
compound are indicated by an area of agar
around the colonies that is free of any
microbial growth (zone of inhibition).
Such colonies are subcultured and purified by
streaking method.
The purified culture is ready for testing what
type of the microorganisms will be sensitive
to the antimicrobial compound.
Disadvantages of this method:
1. This method is used to isolate an antibiotic –
producing microorganism without regarding to what
type of the microorganisms will be sensitive to the
antibiotic, and it is important to isolate an
antibiotic – producing microorganism with activity
against specific microorganism not against unknown
microorganism.
2. This method does not necessarily select the
antibiotic – producing microorganisms because the
inhibition zone may be attributed to other causes as
rapid utilization of nutrients by some microorganisms
causing the growth inhibition of nearby
microorganisms.
 Spot-on-Lawn Method

The aseptic conditions must be considered
1. Melting the nutrient agar medium at 100°c.
2. Cooling the melted medium to 50°c.
3. Pouring the medium into the plates.
4. Allowing the plates to set.
5. Preparing serial decimal dilutions.
6. Spreading 1 ml of the selected dilutions on the
surface of nutrient agar medium.
7. Incubating the plates at 30 °C / 24-48 h.
8. Pouring the nutrient agar medium inoculated
with the test microorganism into the plates
as an overlay.
9. The plates are further incubated at the
optimum temperature for the test
microorganism / 24-48 h.
10. The antimicrobial activity is indicated by the
zone of the inhibited growth of the indicator
microorganism around the colony that
produce antimicrobial compound.