Classification of Microorganisms PDF

Summary

This document provides a classification of microorganisms, focusing on bacteria. It details the differences between prokaryotic and eukaryotic cells, offering a breakdown of various bacterial shapes and arrangements. The document also touches upon staining techniques and nutritional classification.

Full Transcript

CLASSIFICATION OF MICROORGANISMS

Dr. Anna Kafintu-Kwashie
(MLS.D, Mphil )
SBAHS, korle -bu
Classifications of micro
organisms

Organisms are generally organized into subspecies,
species, genera, families, and higher orders.

Classification of bacteria is the orderly arrangement of
bacteria in groups
Classification of Microorganisms
 Cells are divided into two basic types, which are as follows:
1. Prokaryotic cells
2. Eukaryotic cell

 Prokaryotic cells are smaller when compared with eukaryotic cells.
In Prokaryotic , the cytoplasm is enclosed by the cell membrane,
the cell organelles freely float, without any membrane, in this cytoplasm.
Nucleus is called nucleoid as it lacks the membrane surrounding it;
that is, it contains a naked DNA molecule.

Blue green algae and bacteria are examples of prokaryotes.
Prokaryote and Eukaroyte
Eukaryotic are organisms that can be multicellular or
unicellular cell organism
Examples are protists, plants, fungi or animals.
Similarites between prokaryotic and Eukaroytic
( both have DNA, Ribosomes, cytoplasm, cell
membrane,
Most have cell wall but not animal cells
Differences between Prokaryotic and Eukayotic cell

Prokaryotic cells Eukaryotic cell

They lack a true nucleus to contain DNA They have a well defined nucleus
and have a nucleoid region where the
genetic material is found in a form of a
circular DNA molecule
No membrane bound Organelles Have Membrane bound organelles
(nucleus , mitochondria, Endoplasmic
reticulum, Golgi apparatus
Depending on the type of Eukaryotic, plant
cells have chloroplasts whilst Animal cell do
not have
Size - They are usually smaller in size with a They are usually larger with a size range
size range from 0.5 to 5um from 10 to 100um
Cell division (divide by Binary fission) Cell division (divide by mitosis for somatic
cells and meiosis for reproductive cells)
Differences between Prokaryotic and Eukayotic
cell

Prokaryotic cells Eukaryotic cell

Cell wall – many have cell walls which Plants cells have cell walls, composed of
provide structural support, shape and cellulose, while animal cells lacks cell wall
protection
Flagella and Cilia – are used for Have both flagella and cilia and more
locomotion and ar structurally different compex internal structures
Reproduction- reproduce rapidly by binary Reproduction is generally slow due to the
fission complexity of mitosis ad meiosis
Genetic Material- They have a single Genetic Material – they have multiple
circular DNA molecule linear molecules organized into
chromosomes
 BACTERIA CELL
Bacteria are single-celled microorganisms with prokaryotic
cells, which are single cells that do not have organelles or a
true nucleus and are less complex than eukaryotic cells.

COMMON FEATURES
NUCLEUS

CYTOPLASM

CELL WALL
THE BACTERIAL CELL
 Characteristics of bacteria

Bacteria are single-celled organisms.

They lack organelles such as chloroplasts and mitochondria,

Do not have the true nucleus.

Their DNA, a double strand that is continuous and circular,
located in a nucleoid.
Have a cell membrane and a cell wall that is often made
of peptidoglycan.
Reproduction occurs through binary fission
Bacterial morphology and arrangement
Bacteria have one of three
a. Rod (bacilus)
basic shapes,
b. Cocci (coccus) spherical
Coccus (round or oval)
c. Curve

Spiral (curve, spiral, or d. Pairs
twisted)
e. Rods in chains

Bacillus (rod-shaped) f. Cocci in chains

g. Cocci in Tetrads

h. Cocci in clusters
 Cocci:
These are round or oval bacteria measuring about 0.5 –
1.0 µm in diameter. When multiplying cocci may form
i. Pairs: called diplococci eg, meningococci and
gonococci.
ii. Chains: called streptococci eg, streptococcus
pyogenes.
iii. Groups: called staphylococci eg, Staphylococcus
aureus
 Bacilli
These are stick-like bacteria with rounded, tapered (fusiform),
square or swollen ends.

Short rods with rounded ends are often called cocciobacilli. They
may

Form chains eg Streptobacilli species.

Form branching chains eg, lactobacilli.

Mass together eg, Mycobacterium leprae.

Attached at various angles resembling Chinese letters eg
Corynebacterium diphtheria
 Vibrio
These are small slightly curved rods measuring 3 –
4µm in length by 0.5µm in width.
Vibrios are comma-shaped rods with a small twist.

Most vibrios are motile with single flagellum at one
end.
They show a rapid darting motility eg, Vibrio cholera.
 Spiral Bacteria

Spiral bacteria are twisted and commonly occur in two
forms:

Spirillum (spirilla plural)
Spirochetes.

These cells resemble long, twisted coils.
 Spirilla bacteria
Spirilla bacteria are elongated, spiral-shaped, rigid
cells.
These cells may also have flagella, which are long
protrusion used for movement, at each end of the cell.
An example of a spirillum bacterium is Spirillum minus,
which causes rat-bite fever.
 Spirochetes
Spirochetes bacteria are long, tightly coiled, spiral-shaped cells. mmThey are more flexible than
spirilla bacteria.

Examples of spirochetes bacteria include

1. Borrelia burgdorferi, which causes Lyme disease

2. Treponema pallidum, which causes syphilis.

Spirochaetes are divided into three groups

 Treponemes eg: Treponema pallidum, Treponema pertenue.

 Borreliae eg: Borrelia duttoni, Borrelia vincenti.

 Leptospires eg: Leptospira interrogans,
 Ricketsiae
Although classified as bacteria ricketsiae resemble
viruses in that they replicate only in living cells and
are unable to survive as free-living organisms.
Unlike viruses the ricketsiae contain both DNA and
RNA, multiply by binary fission and have cell walls
composed of peptidoglycan.
 NUCLEUS
BACTERIA
ANIMAL
Prokaryotic=primitive
Eukaryotic=true nuclear structure
nucleus

No nuclear membrane
Nuclear membrane
One chromosome
Many chromosomes
 NUCLEUS

Also called-nucleoid, nuclear body

Genetic information

1mm long, double stranded DNA, circular

Coiled up (like wool)
Stains with Giemsa but not the usual bacterial stains
Usually only one per cell
 CYTOPLASM

BACTERIA
ANIMAL

Nuclear organelles No internal
membranous
Mitochondria structures
Golgi apparatus
Endoplasmic reticulum
RIGID CELL WALL
 Cytoplasm
Watery soft gel

Cytoplasmic inclusions-

Granules – store of reserve material

lipid, polysaccharide, volutin

Contains-organic & inorganic solutes
Vitamins

Coenzymes

Ribosomes

Network of fine fibrils with

connections extending to the nucleus
 Cytoplasmic membrane
An important feature of all bacteria
Visible by Microscopy

Typical unit membrane

10% of dry weight of the cell

Delicate membrane, described as a fluid mosaic
 Functions of cytoplasmic membranes
1. Selective permeability-active, passive
2. Electron transport-like mitochondria
3. Excretion of hydrolytic enzymes
4. Has receptors for chemotactic system
5. Has enzymes and carrier molecules for synthesis of DNA
and cell wall
 Bacteria cell
Wall
The cell wall is mainly made up of murein (also called peptidoglycan),
which is a polysaccharide chain cross-linked by peptides containing d-
amino acids.

Bacterial cell wall is made up of peptidoglycan, fungi cell wall of
chitin, and plant cell wall of cellulose.

Archaea differ from bacteria by lacking peptidoglycan in their cell wall.

In bacteria, two different types of cell wall composition can be seen, one
in Gram positive bacteria and the other in Gram-negative bacteria

NB: bacteria are classified as gram positive or gram negative
according to their response to the Gram staining procedure.
 CELL WALL
Rigid, 10-25 nm thick

Supports the weak cytoplasmic membrane

Gives bacteria it’s shape

Can withstand the high osmotic pressure in the cell (5-
25 atmospheres)

Mycoplasma has no cell wall
Cell Wall Differences between Gram-Positive
and Gram-Negative Bacteria
GRAM +VE
GRAM -VE

Mainly peptidoglycan Little peptidoglycan,
between two unit
Lipoteichoic acids membranes
Potential space is-
Teichoic acids periplasmic space
Lipoprotein attached to
outer membrane
Lipopolysaccharides LPS
GRAM +VE BACTERIA
Mainly
peptidoglycan

Lipoteichoic acids

Teichoic acids
GRAM –VE BACTERIA

Little peptidoglycan,
between two unit
membranes
Potential space is-
periplasmic space
Lipoprotein attached to outer
membrane
Lipopolysaccharides LPS
EXTERNAL STUCTURES
FLAGELLA
Flagellin

PILI (fimbria)
Pilin

CAPSULE
Protein
Polysaccharide
Polypeptide
ARRANGEMENT OF FLAGELLA
 STRUCTURES INVOLVED IN ATTACHMENT
2. Glycocalyx - forms multicellular aggregates by binding the cells
together.
Some bacteria are involved in plaque formation leading to dental
caries.

3. Pili: similar to fimbriae but are fewer (sometimes only one per
cell) and longer. F-pilus (sex pilus) fertility factor.

(a) Pili that act as receptor sites for attachment of some phages

(b) Pili that act as sex pili for bacterial conjugation processes/

Adhesion to mucosal surfaces during colonization

(c) Pili that help in the attachment of pathogenic bacteria to human
tissues
 External structures

1. Flagella:

Flagella are whip-like structures protruding from the bacterial cell wall and are
responsible for bacterial motility (i.e. movement). Organisms which are motile
are vibrios, spirilla and spirochetes. The fagellum is made up of thousand
molecules of a protein subunit called Flagelin.

The arrangement of flagella include:
Peritrichous - Multiple flagella found at several locations about the cell

Polar - Single flagellum found at one of the cell poles. (Monotrichous)

Lophotrichous - A tuft of flagella found at one cell pole
 Capsule Capsule function

Firm gelatinous material- Protects against damage and
wide/microcapsule destruction
Antigenic, different strains such as Lysozyme,
differ Phagocytosis, etc
Addition of anticapsular AB
causes increase in size
Seen by negative staining
 Bacteria Identification
There are several other approaches also to classify bacteria based on
different aspects, which are discussed in the following sections.

Some bacteria can be identified through simple visual inspection.
Identification first begins with evaluating the appearance of the bacterial
colony followed by examination under the microscope for considering their
shape, groupings, and features such as the number and location of flagella.

Staining techniques are employed to mediate identification in addition
to various culture techniques such as the use of differential special culture
medium.

Many other biochemical tests are employed to identify bacterial by-
products, and sophisticated tests (Polymerase Chain Reaction based) are
available to analyse the DNA of the bacteria
 Bacteria Identification (Morphological
identification)
Based on their morphology, the bacteria can be divided
into the following groups:

1. Filamentous or higher bacteria (actinomycetes)
2. (a) Gram-positive bacilli (i) Aerobes (e.g.,
Corynebacterium and Bacillus)
(ii) Anaerobes (e.g., Clostridium and Lactobacillus)

(b) Gram-positive cocci (c) Gram-negative cocci (d)
Gram-negative bacilli
 NUTRITIONAL CLASSIFICATION

Based on their energy requirements, the bacteria can be classified into the following:

1. Energy classification
(a) Phototrophs: They derive energy from sunlight.
b) Chemotrophs: They use chemicals to derive energy.

2. Based on their ability to synthesize essential metabolites, the bacteria can be
classified into the following:
(a) Autotrophs: They synthesize organic compounds from carbon dioxide and nitrogen.
(b) Heterotrophs: They depend on preformed organic compounds (e.g., pathogens).

3. Based on their oxygen requirements, the bacteria can be classified into the following:
(a) Aerobes (b) Anaerobe
 Bacteria Identification
NUTRITIONAL CLASSIFICATION-

4. Based on temperature, the bacteria can be classified
into the following:

(a) Psychrophiles (below 20°C)
(b) Mesophiles: (25°C to 40°C)
(c) Thermophiles: (55°C to 80°C)
 BIOCHEMICAL CLASSIFICATION

1. Lactose fermenting
2. Non-lactose fermenting
3. Late lactose fermenting
4. Production of indole, H2 S, catalase, oxidase,
urease etc
CLASSIFICATION BASED ON STAINING REACTION

1. Based on Gram staining, the bacteria can be
classified into the following:
(a) Gram-positive bacteria
(b) Gram-negative bacteria

2. Based on acid-fast staining, the bacteria can be
classified into the following:
(a) Acid-fast bacilli
(b) Non-acid-fast bacill
 Staining techniques by Grams Method
Make slide by smear, drop, or cytocentrifuged samples

Gram stain

Crystal violet: primary stain

Gram’s iodine: mordant/fixative

Acetone-ethanol: decolorizer

Safranin: counterstain

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Gm+ve cocci & Gm-ve bacilli

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 Staining techniques for Mycobacterial species (Acid-fast stains)
– for staining of organisms with high degree of fatty (mycolic) acids—
waxy
render the cells resistant to decolorization: “acid-fast”
Mycobacterium sp., Nocardia sp., Cryptosporidium sp. are acid-fast

Procedure Ziehl-Neelsen
heat drives in primary stain (carbolfuchsin)

Decolorize with 20% sulpheric acid (H2SO4)

Counterstain with methylene blue or malachite green
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Mycobacteria species

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