Lecture Notes: Viruses, Bacteria, & Archaea (2024-2025) PDF

Summary

These lecture notes cover viruses, bacteria and archaea in detail. They include the course outline, learning outcomes and different types of viruses, bacteria and archaea. The document covers topics including the structure and characteristics of each.

Full Transcript

BIOLOGY 1 ASB0204

Topic 10:
Viruses, Bacteria and
Archaea
Dr. Nur Akmal Ishak
Dr. Ezyana Kamal Bahrin
Biology Unit,
Centre for Foundation Studies in Science of Universiti
Putra Malaysia (ASPutra),
Universiti Putra Malaysia
 The Invisible Us – The Human Microbiome in
Health and Disease
Microbiome is the community of
microorganisms (such as fungi,
bacteria and viruses) that exists
in a particular environment.

The latest study from the
American Academy of
Microbiology estimates each
human ecosystem contains
around 100 trillion cells of
microorganisms and just 37
trillion human cells.

2
 COURSE OUTLINE

01 02 03 04
Viruses The The The
Prokaryotes Bacteria Archaea
Learning Outcomes

By the end of this lecture, you will be able to:

1. Explain the basic structure and life cycle of virus.
2. Explain the basic structure and characteristic of bacteria and
archaea.
3. Relate the importance of microorganisms in life.
 Lesson

01
Viruses
The Structure of Virus
Virus is a very small (~ 20 – 300
nm).
Virus can be characterized by their:

❑size and shape (helical,
polyhedral, complex)
❑presence or absence of outer
envelope
❑type of nucleic acid (DNA/RNA)

6
The Structure of Virus
Each type has at least two parts: Covering and Inner Core
Capsid (protein coat)
Outer layer composed of protein subunits
Covering called capsomers.
Envelope (not found in all viruses)
Virus particle Some viruses have an outer membranous envelope
surrounding the capsid.
Nucleic acid core (DNA or RNA)
Inner core surrounded by a capsid.

Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
Various proteins (E.g. enzymes)

24.1 The status &
Structure of Viruses
Further reading: page
500-502
7
Examples of DNA Viruses

TEM 80,000X TEM 90,000X

Adenovirus: DNA virus with a polyhedral capsid T-even bacteriophage: DNA virus with a polyhedral
and a fiber at each corner. head and a helical tail.
fiber protein capsid
fiber

protein unit
DNA
neck
tail sheath
capsid DNA
tail fiber

pins base plate
a. b.

8
a: © Dr. Hans Gelderblom/Visuals Unlimited; b: © Eye of Science/Photo Researchers, Inc.
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
Examples of RNA Viruses
c. d.

TEM 500,000X 20nm
Influenza virus: RNA virus with a spherical capsid
Tobacco mosaic virus: RNA virus with a helical
Surrounded by an envelope with spikes.
capsid.
spikes capsid

RNA
RNA
envelope

capsid

Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
9
c: © Dr. O. Bradfute/Peter Arnold/Photolibrary; d: © K.G. Murti/Visuals Unlimited
Characteristics of Viruses:
1. Parasitic Nature of Virus
Viruses are obligate intracellular
parasitic:
❑ Can reproduce only within host cells
using resources of a host.

❑ Incapable to replicate its own genetic
material.

❑ Once inside a living/host cell, they
hijacks the cell’s protein synthesis
machinery to replicate nucleic acids,
capsids, viral enzyme.

10
Obligate: restricted to a particular function or mode of life.
Characteristics of Viruses: HOST SPECIFIC
2. Viruses are host specific Viruses infect specific types
Tobacco mosaic virus Rabies of organisms (bacteria, plants,
fungi, animals etc.).

What determines the
specificity of a virus for
a host cell?
Host specific : tobacco plant Host specific : mammals
Determined by structure of
HIV Hepatitis
molecules in naked
capsid/spikes on virus,

lock and key with a
receptor on a host cells at
the outer surface.
Host specific : white blood cells Host specific : liver cells
11
 Reproductive Cycles of Bacteriophages:
1. Lytic cycle
Bacteriophages : viruses that infect bacteria

✔ Virus injects DNA into the
host cells

✔ Host cell start copying viral
DNA and making capsid
and accessory parts

✔ Then, cell lyses (burst)
releasing the viruses to
infect other cells
12
Reproductive Cycles of Bacteriophages:
2. Lysogenic cycle
✔ After DNA is insert, it is integrated into host
cell’s DNA with no destruction of the host DNA.
Viral
reproduction
✔ Phage is latent (existing in hidden/dormant) and
does not occur
latent viral DNA is called prophage. immediately
but may occur in
✔ The prophage is replicated along with host DNA the future.
(lysogenic cells).

✔ Lysogenic cells carry a copy of the prophage
genome.

✔ Certain environmental factor (UV radiation,
nutrients availability, chemical treatment, etc)
can induce prophage to reenter the lytic stage.
13
 phage
1. Lytic and lysogenic cycles of Bacteriophage
1. ATTACHMENT
Phage attaches to cell surface of bacterium.

Phage bind to
specific host cells
based on host-
specific match
between phage and
host cell receptors.

14

14
 Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.

1.1. ATTACHMENT
ATTACHMENT
Phage attaches
Capsid to cell
combines withsurface of bacterium.
receptor.

bacterial nucleic acid
cell wall

bacterial
capsid
DNA

2. PENETRATION
LYTIC Viral DNA enters host.
Virus injects
CYCLE its genome into
the cytoplasm
of host cell.
viral
DNA

15
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
1. ATTACHMENT
1. ATTACHMENT
Phage attaches
Capsid to cellwith
combines surface of bacterium.
receptor.
bacterial nucleic acid
cell wall

bacterial
capsid
DNA

2. PENETRATION
Viral DNA enters host.

LYTIC viral
DNA

CYCLE

New viral 3. BIOSYNTHESIS
components are Viral components are synthesized.
synthesized
using host cell’s
machinery and 16
energy.
 Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
1. ATTACHMENT
1. ATTACHMENT
Phage attaches
Capsid to cell
combines surface
with of bacterium.
receptor.
bacterial nucleic acid
cell wall

bacterial
DNA capsid

2. PENETRATION
Viral DNA enters host.

LYTIC
CYCLE viral
DNA

4. MATURATION 3. BIOSYNTHESIS
Assembly of viral components. Viral components are synthesized.

Viral components
are assembled
into new viruses. 17
 Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
1. ATTACHMENT
1. ATTACHMENT
Phage attaches
Capsid to cellwith
combines surface of bacterium.
receptor.
bacterial nucleic acid
cell wall

bacterial
DNA capsid

New viruses 5. RELEASE 2. PENETRATION
New viruses leave host cell. Viral DNA enters host.
exit host cell
through lysis or
budding in
order to infect
LYTIC viral
DNA
new host cells. CYCLE

4. MATURATION 3. BIOSYNTHESIS
Assembly of viral components. Viral components are synthesized.

18
 Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
1. ATTACHMENT
1. ATTACHMENT
Phage attaches
Capsid to cell
combines withsurface of bacterium.
receptor.
bacterial nucleic acid
cell wall

bacterial
DNA capsid

5. RELEASE 2. PENETRATION
New viruses leave host cell. Viral DNA enters host. INTEGRATION Viral DNA is integrated
into bacterial DNA and then is passed
on when bacteria reproduce.

LYTIC viral
DNA
viral
CYCLE DNA

LYSOGENI
4. MATURATION
Assembly of viral components.
3. BIOSYNTHESIS
Viral components are synthesized. C
CYCLE

19
 1. ATTACHMENT
1. ATTACHMENT
Phage attaches to cell surface of 24.3 Viral Replication
Capsid
bacterium.combines with receptor.
bacterial
Can you differentiate lytic and
nucleic acid
cell wall lysogenic cycles?

bacterial
DNA
capsid
Further reading: page 503
di
5. RELEASE 2. PENETRATION
New viruses leave host cell. Viral DNA enters host. INTEGRATION Viral DNA is integrated
into bacterial DNA and then is passed
on when bacteria reproduce.
LYTIC viral
DNA
CYCLE viral
DNA

LYSOGENI
4. MATURATION 3. BIOSYNTHESIS C
Assembly of viral components. Viral components are synthesized.
CYCLE
prophage

20
daughter cells
© Eye of Science/Science Source
2. Reproductive Cycle of Retrovirus
Animal ricus

Entry
Attachment
Capsid and
Animal virus nucleic acid is
attaches to host- release into
host cell
cell receptor. cytoplasm.
Enveloped viruses
Capsid is
fuse with animal removed by
cell’s plasma enzymes.
membrane. Uncoating
releases viral
DNA or RNA
22
 Reverse transcription

Retroviruses contain reverse
transcriptase (Example: HIV, the
virus that causes AIDS).
Carries out reverse transcription
from RNA to copy of DNA
(cDNA)
cDNA becomes integrated into
host DNA.
Replicated when host DNA is
replicates (cell division).
HIV may remain in the host
genome latent for years.
23
 Biosynthesis

Maturation

Release How antiviral drugs
are developed?
These 3 steps are the
same as bacteriophage but Read page 510 & 511
in the case of HIV, it is
released by budding from
24
the plasma membrane.
 Summary of Virus Subtopic
Structure of Virus HOW VIRUS REPRODUCED?
1 Lytic cycles of Bacteriophage
✔ Covering: Capsid &
Envelope
Attachment (A) Penetration (P)
Biosynthesis (B) Maturation (M)
✔ Inner core: Nucleic acid Release (R)
core (DNA or RNA) &
various protein 2 Lytic and lysogenic cycles of
Bacteriophage
Characteristics of Virus A P Integration (I) B M R
✔ Parasitic Nature of Virus:
obligate intracellular 3 Life cycle of retroviruses
parasitic. A P Reverse transcription (RT) B
✔ Viruses are host specific M R
25
 Lesson

02 The
Prokaryotes
The Structure of Prokaryotes (include
bacteria and archaea)
The length ranges from 1 to 5 µm.
Most prokaryotes are unicellular.
Lack a membrane-bounded nucleus and organelles.
contains ribosomes and storage granules.
Most prokaryotes have cell wall.
To support and maintain its shape
The cell wall is made up from peptidoglycan.
However, peptidoglycan is absent in archaea.
structure of pro

27
 Many prokaryote species produce
a capsule/slime layer that
surrounds the cell wall.
Made of polysaccharide or
protein.
Protect the bacteria against
phagocytosis (eg:
Streptococcus pneumoniae).
Use to attach to surfaces such
as rocks, plant roots and
human teeth. -

reproduction

Fimbriae and pili is for attach to
cell surfaces and transmitting
DNA between bacteria.
29
 Prokaryotic Cell Shapes

Bacteria can be further classified in
terms of their three basic shapes:
Spiral (spirilli)
Rod (bacilli)
Round (cocci)

30
 Prokaryote Reproduction
Prokaryotes reproduce asexually by binary fission. required lo
pick up
Genetic material can be exchanged among prokaryotes and resulting dua from
genetic recombination. final bactering

Transduction Conjugation Transformation
⮚ Occurs when ⮚ Conjugation pilus forms ⮚ Occurs when
31
bacteriophages carry between two cells bacterium picks up free
portions of bacterial ⮚ Donor cell passes DNA pieces of DNA from
DNA from one cell to to recipient cell through other prokaryotes
another virus as vectors the pilus ⮚ Becomes incorporated
⮚ Serve as vectors into genome
 lesson

03
The Bacteria
 The Bacteria
Most bacterial cells are protected by a cell wall.
-Contains peptidoglycan

Bacteria are commonly differentiated using the Gram stain procedure.
When washed after staining:
Gram-positive bacteria retain dye and appear purple
Gram-negative bacteria do not retain dye and appear pink
Gram-negative bacteria have a second plasma membrane which
blocks antibiotic drugs, making infections difficult to treat.

33 The difference is dependent on the construction of the cell wall.
 is peptidoglycan
purple
- at first both
after
hav purple
introducing
pink stain,
has pink,
only gramit
gram
It) hav purple
for membrane
pink plasma
purple for peptidoglycon

34

Gram-negative (pink) Gram-positive (purple)
thin peptidoglycan layer thick peptidoglycan layer
Bacterial Oxygen Requirements

Oxygen requirements

Obligate Obligate Facultative
aerobes anaerobes anaerobes

unable to grow in the
presence of free oxygen
35
able to grow in either
unable to grow in the the presence or
absence of free absence of free oxygen
oxygen Examples: Botulism, gas
gangrene, and tetanus
Modes of Nutrition
Mode of nutrition Energy source Description
Autotroph
Photoautotroph Sunlight Use energy from sunlight to synthesize organic
compounds.
eg: cyanobacteria
Chemoautotroph Inorganic chemicals Obtain energy by oxidizing inorganic chemical
y does not use
carbora substances such as ammonia or hydrogen sulfide.
Heterotroph
Photoheterotroph Sunlight Obtain their carbon from other organism but use
chlorophyll and other photosynthetic pigments to
trap sunlight energy.
eg: purple nonsulfur bacteria
Chemoheterotro Organic compounds depend on organic molecules for both carbon and
ph energy.
eg: decomposer and pathogenic bacteria
 Prokaryote Relationships with Other Organisms

Prokaryotes interact with other organisms in both beneficial and harmful
ways.
Commensalism
Mutualism Refer to page 529 and
Parasitism discuss on this topic.

37
 ⮚ Commensalism
One population modifies the environment in
such a way that a second population
benefits.
Obligate anaerobes live in our intestine
because bacterium E. coli uses up oxygen.

⮚ Mutualism
Both species benefit from association.
Mutualistic bacteria live in human
intestines and release vitamins K and B12
which help produce blood components.
38
⮚ Parasitism
Parasite benefits at host expense; disease-
causing bacteria are called pathogens
Many form endospores
 Prokaryote Relationships with Other Organisms

Prokaryotes interact with other organisms in both beneficial and harmful
ways.
Commensalism
Mutualism Refer to page 529 and
Parasitism discuss on this topic.

39
Bacteria and Disease

40
 Endospore-forming Bacterium

Some bacteria form resistant endospores under
unfavorable conditions.
Examples: Bacillus spp.and Clostridium
spp.
Endospores can survive without nutrients.
Resistant to:
ultraviolet radiation, desiccation,
high temperature, extreme freezing
41 and chemical disinfectants.
Endospores can be destroyed by burning
or by autoclaving.
The endospore of Clostridium tetani
Antibiotics
Antibiotics

Inhibit protein Inhibit cell wall
biosynthesis biosynthesis

Penicillin
Affect bacterial but
Erythromycin Tetracycline Ampicillin
not animal cells
Fluroquinolone

Bacterial resistance to antibiotics is increasing. Refer to page 535 and
discuss on this topic.
42
 lesson

04
The Archaea
 The Archaea

Archaea were formerly considered
bacteria.

Other differences:
Archaea do not have peptidoglycan in
their cell walls like the bacteria.
Archaea are biochemically more like
eukarya than bacteria.
Archaea are now thought to be more
44
closely related to eukarya than to
bacteria.
 Many live in harsh conditions:

Methanogens

Produce methane from
hydrogen gas and carbon
dioxide.
Commonly found in the guts of
animals, deep layers of marine
sediment, hydrothermal vents,
and wetlands.

course title
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course title
46
46
 Eldra Solomon
Charles Martin
Diana W. Martin
Linda R. Berg

Chapter 24
Viruses and Subviral
Agents

Chapter 25
Bacteria and Archaea
References:
 THE END
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course title