Microbiology-1 English (3. Week) PDF

Summary

This document is a presentation on microbiology, focusing on the anatomy, structure, and function of bacteria. It covers topics such as bacterial cell structure, cytoplasmic membrane, endospores, sporulation, and germination. Also included are details on the various genera of bacteria.

Full Transcript

MICROBIOLOGY-I
GENERAL BACTERIOLOGY

Assist. Prof. Dr. Halit ŞÜKÜR
([email protected])

Near East University
Faculty of Veterinary Medicine
Department of Microbiology
 Anatomic Structure of the Bacteria
1- External structure
2- Internal structure
Anatomic Structure of the
Bacteria
Internal Structure
External  Cytoplasmic membrane
Structure Cytoplasm

Cellwall  Mesosom

 Nucleotide
Capsule  Ribosome

Flagella  Cytoplasmic granules

 Endospore
Fimbriae (pilus) Pigment

 Others (plasmid, phage, transposon,

trace element)
CYTOPLASMIC MEMBRANE CYTOPLASMİC MEMBRANE

Under the cell wall, it is thin and generally of the same structure
in bacteria

It consists of two layers

 It has a protein and phospholipid structure on the surface facing
the periplasmic space and cytoplasm

 The inner region contains the hydrophobic ends of the
phospholipid

 Membrane proteins exist in two forms: peripheral and integral.
 CYTOPLASMIC MEMBRANE
FUNCTION
 It surrounds and protects to cytoplasm

 It allows selective permeability and osmosis

 It includes enzymes:

 Cytochrome enzymes

 Official enzymes in lipid synthesis

 Official enzyme in cell wall synthesis

 TCA enzymes

 DNA replicase enzymes

 Regulates the activities (hydrolytic and energy metabolism) of
some enzymes

 Participate in DNA replication

 Constitutes the origin of mesosom

 Plays a role in cell division and sporulation
 CYTOPLASMIC MEMBRANE
Selective permeability and transport
-Passive transport (diffusion)
Slow, no need for energy
Play a role the concentration, electrical and pressure

differences
-Active transport
The passage of large molecules
Need for energy
Carrier proteins are involved (enzymes, permease enzymes)
E.g. : β-galactosidase system for lactose
Phosphotransferase system acts in transition membrane
Cytoplasm
- It consist of liquid, organic and inorganic materials

Mesosom
- It is originated from cytoplasmic membrane
- Vesicular or lamellar type and opens periplasmic space
- Takes part in replication and some transport processes

 Ribosome
- It consists of RNA and protein
- It sizes 70 S (50+30)
- Numerous in which growing bacteria
- It is involved synthesis of proteins and enzymes

 Nucleotide
- DNA, double-stranded helix
 Cytoplasmic Granules
Volutin (Babes-Ernst) granules
- Structure in polymerized inorganic metaphosphate
(polymetaphosphate)
- Source of energy and phosphate
- It is shown by Neisser and Albert staining
 Lipid granules

- The structure in lipid particles (polybetahydroxybutyrate)
- The source of carbon and energy
- It is shown with Sudan black
 Polysaccharide granules

- Structure of glucose homo or heteropolymer
- The source of carbon and energy
 Sulfur granules

- It is found in sulfur bacteria
-Source of energy
 ENDOSPORE
 When reduced food sources in their environment,
some bacteria (e.g.; B. anthracis, B. subtilis, C.
tetani, C. botulinum) occurs endospores which is
resistant against physical (frost, dry, heat) and
chemical effects (toxic substances) to protect
themselves

 Spores structures is too durable that even
isolated from 3000 years soil samples
 ENDOSPORE
 Endospores can be oval or round shape

 Spores may be appropriately sized to the diameter of
the cell or may be greater than diamater of the cell
(e.g.; Clostridium species, appear as the drumstick)

 Endospores are stained by special staining methods
such as Modified Ziehl-Neelsen or Spore staining

 According to bacterial species endospores positions
are shown in four ways :

 Central

 Subterminal

 Terminal

 Lateral
 Locations of Endospores in Bacteria

1: Central endospor (smaller than the diameter bacillus)

2-5: Terminal endospor

3: Subterminal endospor

4: Central endospor (greater than the diameter
bacillus)

6: Lateral endospor
Clostridium botulinum (subterminal)
Clostridium tetani (terminal)
Bacillus anthracis (central)
 ENDOSPORE
An important and discriminative property of Bacillaceae family
Aerobic – Bacillus spp. (B. anthracis, B. subtilis, B. cereus, B. megaterium)
Anaerobic – Clostridium spp. (C. tetani, C. botulinum, C. perfringens,
C. chauvoei, C. haemolyticum, C. novyi)
Is not seen in cocci and spiral shaped bacteria
Oval or round shaped, found in different places in bacterium
Diameter of the spore can be smaller (Bacillus spp.) or larger (Clostridium spp.)
than the bacterium
If large, bacterium takes the shape of lemon, racket, hammer or shuttle
In Bacillus anthracis spores appear in vitro and in aerobic conditions
In Clostridium spp. spores appear both in vivo and in vitro, and in anaerobic
conditions
 Endospor Structure (from inside to out)
-Core
-Cytoplasm
-Cytoplasmic membrane of spore
-Cell Wall of spore
-Cortex
-Outer membrane (dipicolinic acid, DPA)
-Exosporium
 SPORULATION

 Developing spores is called "Sporulation", and the
developed spores' process to get vegetative forms are called
"Germination".

Endotrophic and exotrophic sporulation
 In Bacillus spp. endotrophic sporulation
 In Clostridium spp. exotrophic sporulation
 SPORULATION

 Sporulation needs carbon and energy
 Amino acids and metal ions stimulate
sporulation
Poly-beta hydroxybutyric acid accumulation at
one end or in the centre of bacterium and the cell
becomes more refractile
 This material is used as an energy and carbon
source
 Elongation of nuclear material towards one end
 Location of nuclear material to the site of
sporulation
 Septum formation originating from mesosomes
 Pre-sporulation
 Formation of cortex by the accumulation of
peptidoglycan, dipicolinic acid and Ca
 Exosporium formation
 Termination of sporulation within 5-13 hours
SPORULATION
 GERMINATION

Development of vegetative forms from spores
 Activation: spore is activated with activating elements such as
oxygen, pH, heat, humid, nutrients
 closely related with environmental conditions, breaking off
disulphide bounds found in outer membrane and exosporium

 Germination: amino acids, minerals and water enter the cell
and activate lytic enzymes

 Extension outward: new developed vegetative bacterium
elongates within the spore and consequently protrudes from the
spore

 Development of vegetative form within 2 hours
 PİGMENT

When bacteria growth in general or specific solid
medias, they form colonies with specific colors for
their genus. Bacteria capable of reproduction
under aerobic conditions have a larger number of
species in terms of pigment formation compared to
anaerobic ones.
Pigments: They are divided into 2 basic groups as
non-photosynthetic and photosynthetic ones.
 PİGMENT

Non-photosynthetic pigments
Water soluble
(Pseudomonas aeruginosa)
Pyocyanin (blue-green color)
Fluorecein (yellow-green color)
Non-water soluble
(Sarcina lutea (yellow), S. aureus (golden yellow),
M.tuberculosis (yellow- red))
Photosynthetic pigments

According to their structures;
-Carotenoids
- Anthocyanins
- Melanins
- Phenazine derivatives
-Quinones
- Pyrroles
- Other
 PLASMID
Structure: Double stranded helix and
circular DNA sequence
Function: They give bacteria resistance to
antibiotics as well as other special
characters.
 TRANSPOSONS (Tn)
Structure: Short DNA sequences; They
are found on the chromosome or plasmids
of bacteria and mobile.
Function: It plays a role in the resistance
of bacteria to antibiotics.
 BACTERIOPHAGES
Structure: It consists of nucleic acid (DNA or
RNA) and the surrounding protein-like capsid.
Function: Creating a function in bacteria and
causing their lysis. Some of them can integrate
into bacterial DNA and become a continuation of
the chromosome and replicate with it (prophage),
they do not kill the bacteria.