Bacterial Physiology PDF

Summary

This document provides an overview of bacterial physiology, including aspects like growth, metabolism, respiration, and other key biological processes.

Full Transcript

Bacterial growth
and metabolism
Objectives:

At the end of this lesson, students will be
able to
1.Define bacterial metabolism
2. Discuss bacterial growth requirements.
3. Clarify bacterial respiration
4. Explain bacterial products
5. Describe bacterial growth curve
Growth and Metabolism

It refers to all requirements and
biochemical reactions that occur in a cell
or organism that together enable them
to live, grow, and reproduce.
Bacteria multiply by simple
binary fission to maintain
a) growth,
b) multiplication,
c) metabolic processes
 Bacterial Nutrition

the main elements needed for bacterial nutrition are Carbon and nitrogen
* There are essential metabolites that cannot be synthetized by the bacteria. So, they must be
provided ready-made
* Example : (amino acids, vitamins, Na, K, Mg and Ca) called Growth factors
Gaseous requirements
of bacteria
Due to their differentability to produce catalase and superoxidase enzymes which destroy the harmful
metabolites, peroxides and superoxide, formed in the presence of oxygen
 Examples
 Obligatory aerobes: e.g. T.B and Pseudomonas.
 Aerobe facultative anerobes:- e.g. most pathogenic bacteria as Staphylococci, and E.coli.
 Obligatory anerobes: e.g. Clostridium
 d) Microaerophilic : e.g. Campylobacter species
 CO2:

All bacteria grow in the usual concentration of CO2 in
atmosphere (0.04%),
but some require higher percentage (5-10%)
e.g. Neisseria
 Moisture:
necessary for growth.
Drying is dangerous for life
but some bacteria may survive in a dry place for
weeks e.g. T.B.
Hydrogen ion concentration (pH):
Most pathogenic bacteria can grow at an optimum
pH around 7.5 i.e. neutral.
Some flourish in acidic (Lactobacilli),
while others in alkaline pH.( cholera)
Microbes can be classified according to the range
of temperature into :
psychro-, meso-, thermo-, and hyperthermophiles
Normal human microbiota and most pathogens are
mesophiles with temperature range 20-45 C and
optimal temperature of 37°C.
Bacterial Respiration

 It is an energy yielding metabolic process
 In which organic compounds (e.g. glucose)
produce ATP
 Either in presence of oxygen (aerobic respiration)
Or without it (anaerobic respiration).
 Energy is produced by electron transport
phosphorylation

 It is called phosphorylation due to the addition of
phosphate. Ex: to (ADP) to form (ATP).
Bacterial respiration is classified according into
aerobic & anaerobic respirsation
Bacterial fermentation
Definition :
A biological processes that occur in the dark and that do not involve respiratory
chains with oxygen or nitrate as electron acceptors.
ATP is formed only by substrate-level phosphorylation.
The bacteria carrying out fermentations are either facultative or obligate
anaerobes.
Facultative anaerobes grow as aerobic heterotrophs in the presence of oxygen;
under anaerobic conditions they carry out a fermentative metabolism.
In contrast, obligate anaerobes are not able to synthesize the components of an
oxygen-linked respiratory chain.
Fermentation vs anaerobic respiration

Anaerobic respiration Fermentation

Definition Energy production in the absence of Conversion of sugars into energy
o2 using ETC without O2 yielding less energy
Organisms Certain bacteria and some Yeassts bacteria and some muscle
eukaryotes like muscle cells cells
Final electron acceptor Nitrate , sulfate , CO2 Organic molecules eg; pyruvate
End products H2s, nh3, ethanol Lactic acid , ethanol , CO2

Process complexty More complex involves multiple Simple mainly glycolysis followed by
steps and pathways conversion
Fermentation vs anaerobic respiration

Anaerobic respiration Fermentation

Energy More efficient than fermentation Less efficient , rapid energy
production but less ATP
ATP yield Higher varies but generally more Lower typically 2ATP per glucose
than fermentation molecule
Use of glycolysis Yes , followed by multiple steps Yes , followed by fermentation
pathways
Summary of ATP Yield
Aerobic Respiration: 36-38 ATP per glucose.
Anaerobic Respiration: 2-36 ATP per glucose.
Fermentation: 2 ATP per glucose.
The significant difference in ATP yield arises from the
complete oxidation of glucose in aerobic respiration, partial
oxidation in anaerobic respiration, and minimal oxidation in
fermentation.
 Bacterial enzymes
Enzymes are biological catalysts which initiate and
accelerate chemical reactions without themselves being
changed.
The substance which is acted upon by an enzyme is
called a substrate
 Function
1- Nutritional:
bacteria produce enzymes to digest nutrients in their environment
2- Virulence:
to assist in the spread of these disease e.g fibrinolysin, hyaluronidase, hemolysin enzymes
3- Antibiotic resistance:
some bacteria produce enzymes to breakdown the attacking antibiotics e.g. production of β-
lactamase which destroys β- lactam ring of penicillin.

4- Laboratory diagnosis:
some of these enzymes can be used to identify bacteria causing diseases e.g. coagulase enzyme
is used to diagnose Staph aureus.
 Bacterial pigments
Function: Help identification of bacteria
Types
Endopigments
Non-diffusible,
i.e. remain bound to the organism.
e.g. golden yellow pigmentof Staph. Aureus
Exopigments
diffusible to the surrounding media
e.g. Pseudomonas aeruginosa produce (pyocyanin and pyoverdin pigments)
which turn the medium greenish
 Bacterial toxins
Definition:
They are highly poisonous substances produced
by certain bacterial species lead to tissue
damage

a) Endotoxin : non diffusible remain bound
to the body of the organism released only
when the organism disintegrates

b) Exotoxins : are diffusible pass to the
surrounding
Uses of Exotoxins:
Preparation of antitoxins (passive immunization)
Preparation of toxoid (active immunization)
The bacterial growth curve
 The growth cycle of bacteria has 4 major phases
 If a small number of bacteria are inoculated into a liquid nutrient medium
and the bacteria are counted at frequent intervals.
 These phases represented in a graphical form, plotting the logarithms of the number of viable
bacteria against the time in hours and termed growth curve
 a. Lag phase:
the first phase
during which the cell prepares for multiplication and
adapts on the new medium
(cells do not divide)
In vivo it corresponds to the incubation period of the
disease.
The length of this phase varies from few minutes to many
hours depends mainly upon
a. The nature of the organism e.g. E. coli has a short lag
phase, while T.B. has long lag phase
b. The size of the inoculum: the bigger the shorter the lag
phase
c. The stage from which the inoculum was taken e.g. if
inoculum is taken from a culture in the logarithmic phase
the lag phase will be very short.
d. The more suitable the medium, the shorter the lag
phase.
 b. Logarithmic phase:
This is the phase of rapid multiplication.
- In vivo, this phase corresponds to the acute
phase of the disease.
- Many antibiotics (e.g. penicillin) are most
effective during this phase
 c- Stationary phase :

During this phase, the rate of growth declines
due to exhaustion of food and O2and
accumulation of toxic metabolites
Any bacterial multiplication is balanced by an
increased death rate and the number of living
organisms remains constant.

Stationary-phase cells are more resistant to
antibiotics, since most antibiotics target
exponentially growing bacteria
In vivo, this phase corresponds to clinical
symptoms and signs of the disease are still
present, but the severity of the disease
decrease.
 d.Decline phase:

number of living organisms decreases until all
are dead and the culture becomes sterile.
In vivo, this phase corresponds to the
convalescent phase.
 Growth curve in dental plaque
Dental plaque (dental plaque biofilm )
It is a biofilm of microorganisms that grows on surfaces
within the mouth
A sticky deposit colorless / pale yellow or brown
commonly found between, on the front and behind teeth
it is one of the major causes for dental decay
Relating the growth phases to bacteria in dental plaque, four
stages of dental plaque biofilm growth are observed:

Stagee I attachment (lag),
Stage II growth (log),
Stage III maturity (stationary)
Stage IV dispersal (death)