Bacterial Cell Structure Lecture PDF

Summary

This lecture covers the structure of bacterial cells, including taxonomy, identification, morphology, and various cell components.

Full Transcript

Bacterial Cell Structure

Dr. Nasreldin Elhadi, PhD
Professor of Microbiology
CLS Department, College of Applied Medical Sciences
Imam Abdulrahman Bin Faisal University

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 Bacterial Cell Structure
In
 Taxonomy
 Kingdom, Division, Class, Order, Family, Tribe, Genus and Species
Family = has “–aceae” ending
Genus = “Human last name”
Species = “Human first name”
When in print, genus and species are italicized. (Staphylococcus aureus)
When written, genus and species are underlined. (Staphylococcus aureus)
a wet
 Staphylococcus sp. is used when referring to the genus as a
whole when the species is not identified.
 “sp.” – singular (Staphylococcus sp.)
 “spp.” – plural (Staphylococcus spp.)

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 Bacterial Cell Structure

 Bacteria Identification: test each bacterial culture for
a variety of metabolic characteristics and compare the
results with known results.
 All organisms are either “prokaryotes”, “eukaryotes”, or
“archaebacteria”
 Archaebacteria
in
 Resembles eukaryotes
 Found in microorganisms that grow under extreme
environmental conditions
ClikeSeawater

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 Bacterial Cell Structure

s It Q whichoftheoptions
 EUKARYOTES – is eukaryotic

fungi, algae,
protozoa, animal
cells, and plant cells
 Cells have nuclei
that contains DNA
and are complex
 Most cells do NOT
have a cell wall

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 Bacterial Cell Structure

 PROKARYOTES -
bacteria
 Do not have a
membrane-bound
nucleus
 DNA is a single circular
chromosome
 Have both cell (plasma)
membrane AND cell
wall.

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 Bacterial Cell Structure

 Bacterial morphology
 The study of the morphology of bacteria
requires the use of microscopes 1(light example
microscope,2phase contrast microscope,
3dark-field microscope,a fluorescence

microscope and 5electron microscope).
 bacteria range in size from 0.2
micrometers (m) to 1.5 micrometers.
 human eye can only see objects >200 m

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 Bacterial Cell Structure

 There are various shapes
including
 cocci,
 curves,
 spirals and
 rods.

Some bacterial shapes
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 Bacterial Cell Structure

I A
Arrangements
Pairs:
551
 diplococci

im
 diplobacilli
Clusters:
b ee
 staphylococci
III

Chains:
1
 Streptococcus
i'm
 Streptobacilli

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 Bacterial Cell Structure

Anatomy of a bacterial cell
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Bacterial Cell Structure

Cell wall:
 Bacteria maintain their shape by a
strong rigid outer cover, the cell
wall. You are here.
 Bacteria can be divided broadly into
two main groups according to their
Gram stain reaction which reflect
the structure of their cell walls.
 Some bacteria stain Gram positive
(purple), whereas other gram
negative (red).

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 Bacterial Cell Structure
 Gram Positive (G+) Cell Wall
 Very thick protective peptidoglycan layer
in
 Many G+ antibiotics act by preventing synthesis of peptidoclycan
 Consists of cross-linked chains of glycan
 Also contain teichoic acid and liptoeichoic acid
 Unique structure makes these bacteria G+

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 Bacterial Cell Structure

 Gram Negative (G-) Cell Wall
 Two layers; inner is much thinner than G+ cell walls
 The outer membrane contains lipopolysaccharides
(LPS). Outer wall contains several molecules like
lipopolysaccharides (LPS) and Lipid A which is
responsible for producing fever and shock in
infections with G- bacteria

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 Bacterial Cell Structure

 Gram Negative (G-) Cell Wall
 Lipopolysaccharides (LPS) are a characteristic feature of gram negative
bacteria and are also termed endotoxins.
 Endotoxins are involved in the pathogenesis of gram negative bacteria
infections.

toxin

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 Bacterial Cell Structure
important
Comparison between G+ and G- cell wall
G+ cell wall G- cell wall
 Very thick peptidoglycan layer Very thin peptidoglycan
 Contain Teichoic acids and No teichoic acids
liptoeichoic Outer wall contains several
 In acid-fast cells, contains mycolic molecules, including
acid Lipid A which is responsible for
 Many G+ antibiotics act by producing fever and shock in
preventing synthesis of infections with G- bacteria
peptidoclycan
 Unique structure makes these
bacteria G+

Bacterial Cell Walls

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 Bacterial Cell Structure

 G+ cocci in
clusters→

 G- bacilli (rods)→

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 Bacterial Cell Structure

 Acid Fast Cell Wall – mainly Mycobacteria and
Nocardia
 Have a G+ cell wall structure but also a waxy layer of
glycolipids and fatty acids (mycolic acid)
 Waxy layer makes them difficult to gram stain
 Can be decolorized by acid-alcohol, hence the name
“acid fast”

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 Bacterial Cell Structure

 Absence of Cell Wall – mainly Mycoplasma and
Ureaplasma
 Lack of cell wall results in a variety of shapes microscopically.
 (They may be spherical or disc like).
 Some bacteria produce slime layers
 Slime layer is a lose gelatinous sheath usually deposited around
the bacterial cell wall.
 It is usually composed of polysaccharides.
 In some bacteria, the slime layer becomes thick due to the
presence of some nitrogen compounds and forms a capsule.

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 Bacterial Cell Structure

 Some bacteria produce a capsule
caps

 In most bacterial species it is
made up of a complex
polysaccaharide
 Protect the bacteria from
phagocytosis
capsule
 Capsule usually does not stain, cell
but can appear as a clear area
(halo-like)

Adevice forexamining
this bacteria
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 Bacterial Cell Structure
4111566
 Cell Appendages
 Flagella – exterior protein filaments that rotate
and cause bacteria to be motile.
 There are four types of arrangement of flagella:
 Monotrichous: These organisms have a single
polar flagellum.
 Lophotrichous: they have a multiple flagella at
one pole.
 Amphitrichous: The have single polar flagella or
multiple of flagella at both poles.
 Peritrichous: Flagella are distributed all round
the cell.
 A large number of bacteria including a few coccal
forms, about one half of bacilli and almost all of
the spirilla and vibrios are motile by means of
flagella.
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 Bacterial Cell Structure
 Cell Appendages
 Flagella

main
caus
c
way

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 Bacterial Cell Structure
IIIb
 Cell Appendages Important forabsorption
 Pili (fimbriae) – hairlike projections
that aid in attachment to surfaces.
 Fimbriae are virulence factors
enabling bacteria to adhere to
various mammalian cell surfaces, an
important initial step to
colonization of mucosal surfaces, e.g.
Nisseria gonorrhoeae produce
fimbriae that bind to specific
receptors of cervical epithelial cells.
 Fimbriae or pili are involved in
genetic material (DNA) transfer
between bacteria, a process called
conjugation.
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 Bacterial Cell Structure

 Nuclear material
 Single circular molecule of double
stranded DNA.
 Smaller extra-chromosomal DNA
molecules called plasmids, that can
replicate independently, may also
be present.
 Plasmids control important
phenotypic properties of
pathogenic bacteria, including
antibiotic resistance and toxin
production.
 Ribosomes: The cytoplasm has
many ribosomes which contain RNA
and proteins, and are involved in
protein synthesis.
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 Bacterial Cell Structure

 Cytoplasmic inclusion

 Various cellular inclusions which serve as energy and
nutrient reserves may be present in the cytoplasm.
 Inclusions can be organic (glycogen) or inorganic
(Sulfur, polyphosphate).
 The size of these inclusions can increase in a
favourable environment and decrease when conditions
are adverse, e.g. Corynebacterium diphtheriae may
contain high energy phosphate reserves inclusions.

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 Bacterial Cell Structure
 Endospores (Spores)
slat
 Spores are small, metabolically dormant
cells with a thick wall, formed
intracellular by members of the genera
own
Bacillus and Clostridium. itspreseffechiffpportant
 Spores are highly resistant to adverse
environmental conditions and may
survive desiccation, disinfectants, or
boiling water for several hours.
 Spores can remain dormant for long
periods, and they are able to germinate
in response to certain conditions such as
the presence of specific sugars.

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 Bacterial Cell Structure
EH
 Endospores (Spores)
 Spores have important role in the
epidemiology of certain human
diseases such as anthrax,
aww
tetanus
way and gasaway gangrene.
 The eradication of spores is of
particular importance in some
processes, e.g. in the
sterilization of instruments prior
to surgery and in food canning
for the removal of Clostridium
botulinum to prevent botulism.
Adevice forexamining
Botoxis extracted this bacteria
from

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Bacterial Cell Structure

 Microscopic Shapes
 Cocci (spherical)
 Bacilli
o.ws
(rod-shaped)
as
 Spirochetes (helical)
 Groupings
 Singly
It is notimportant that we
 Pairs talked aboutabove Fusiform
is
 Clusters
to
Palisading
 Chains
 Palisading

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 Bacterial Cell Structure

 Size and length
 Short
 Long It is notimportant that we
talked aboutabove
 Filamentous
 Fusiform
 Curved
 Pleomorphic

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 Bacterial Cell Structure
 Common Bacterial Stain Reading
 Gram Stain (Differential stain) – to be covered in lab
The gram stain was developed in 1884 by the Danish bacteriologist
Hans Gram.
The Gram stain classifies bacteria into gram-positive and gram-
negative.

Gram stain of Staphylococcus aureus

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 Bacterial Cell Structure

 Gram Stain (Differential stain)

i

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 Thank you…questions

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