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Microbial Models: The Genetics
of Bacteria and Viruses
Chapter 18
Figure 1. Typical mosaic
pattern on flue-cured
tobacco leaves infected with
Tobacco mosaic virus.
(Courtesy H.D. Shew)
LE 18-2
Virus
Bacterium
Animal
cell
Animal cell nucleus
0.25 µm
LE 18-4
Capsomere
of capsid
Membranous
envelope
Capsid
RNA
Capsomere
DNA
Glycoprotein
18  250 mm
20 nm
Tobacco mosaic virus
RNA
Head
Tail
sheath
Tail
fiber
DNA
Glycoprotein
70–90 nm (diameter)
80–200 nm (diameter)
50 nm
Adenoviruses
50 nm
Influenza viruses
80  225 nm
50 nm
Bacteriophage T4
LE 18-5
Entry into cell and
uncoating of DNA
VIRUS
DNA
Capsid
Transcription
Replication
HOST CELL
Viral DNA
mRNA
Viral DNA
Capsid
proteins
Self-assembly of
new virus particles
and their exit from cell
Activity: Viral
Reproductive Cycle
LE 18-6
Lytic Cycle
Attachment
Phage assembly
Head
Tails
Release
Entry of phage DNA
and degradation of
host DNA
Tail fibers
Assembly
Synthesis of viral
genomes and proteins
Activity: Lytic Cycle
LE 18-7
Phage
DNA
The phage attaches to a
host cell and injects its DNA.
Daughter cell
with prophage
Many cell divisions
produce a large
population of
bacteria infected with
the prophage.
Phage DNA
circularizes
Phage
Bacterial
chromosome
Lytic cycle
The cell lyses, releasing phages.
Occasionally, a prophage
exits the bacterial chromosome,
initiating a lytic cycle.
Lysogenic cycle
Certain factors
determine whether
Lytic cycle or Lysogenic cycle
is induced
is entered
New phage DNA and proteins are
synthesized and assembled into phages.
The bacterium reproduces
normally, copying the prophage
and transmitting it to daughter cells.
Prophage
Phage DNA integrates into the
bacterial chromosomes, becoming a
prophage.
Activity: Lytic & Lysogenic
Cycle
Class/Family Envelope Examples/Disease
I. Double-stranded DNA (dsDNA)
Adenovirus
No
Papovavirus
No
Herpesvirus
Yes
Poxvirus
Yes
Respiratory diseases, animal
tumors
Papillomavirus (warts,
cervical cancer):
polyomavirus (animal
tumors)
Herpes simplex I and II (cold
sores, genital sores);
varicella zoster (shingles,
chicken pox); Epstein-Barr
virus (mononucleosis,
Burkitt’s lymphoma)
Smallpox virus, cowpox virus
Class/Family Envelope
Examples/Disease
II. Single-stranded DNA (ssDNA)
Parvovirus
No
B19 parvovirus (mild rash)
III. Double-stranded RNA (dsRNA)
Reovirus
No
Rotavirus (diarrhea),
Colorado tick fever virus
Class/Family Envelope Examples/Disease
IV. Single-stranded RNA (ssRNA); serves as
mRNA
Picornavirus No
Rhinovirus (common
cold); poliovirus, hepatitis
A virus, and other enteric
(intestinal) viruses
Coronavirus Yes
Severe acute respiratory
syndrome (SARS)
Flavivirus
Yes
Yellow fever virus, West
Nile virus, hepatitis C virus
Togavirus
Yes
Rubella virus, equine
encephalitis viruses
Class/Family Envelope Examples/Disease
V. ssRNA; template for mRNA synthesis
Filovirus
Yes
Orthomyxovir Yes
us
Paramyxoviru Yes
s
Rhabdovirus Yes
Ebola virus (hemorrhagic
fever)
Influenza virus
Measles virus; mumps
virus
Rabies virus
VI. ssRNA; template for DNA synthesis
Retrovirus
Yes
HIV (AIDS); RNA tumor
viruses (leukemia)
Figure 18.9 Viral infection of plants
Figure 18-12
LE 18-13
PRIONS = infectious proteins which cause degenerative brain diseases
(like mad cow disease); most likely transmitted in food
Prion
Original
prion
Many prions
Normal
protein
New
prion
LE 18-14
Replication fork
Origin of
replication
Termination
of replication
Figure 18.x7 E. coli
Figure 18.x8 E. coli dividing
Figure 18.x10 Plasmids
Figure 18.12 Detecting genetic recombination in bacteria
Figure 18.13 Transduction (Layer 4)
LE 18-17
Sex pilus
5 µm
Figure 18.15 Conjugation and recombination in E. coli (Layer 4)
Figure 18.16 Insertion sequences, the simplest transposons
Figure 18.17 Insertion of a transposon and creation of direct repeats
LE 18-19
Insertion sequence
5
3
3
5
Inverted
repeat
Transposase gene
Inverted
repeat
Transposon
Insertion
sequence
Antibiotic
resistance gene
Insertion
sequence
5
3
3
5
Inverted repeat
Transposase gene
Figure 18.18 Anatomy of a composite transposon
LE 18-20
Regulation of enzyme
activity
Precursor
Regulation of enzyme
production
Feedback
inhibition
Enzyme 1
Gene 1
Enzyme 2
Gene 2
Regulation
of gene
expression
Enzyme 3
Gene 3
Enzyme 4
Gene 4
Enzyme 5
Tryptophan
Gene 5
LE 18-21a
trp operon
Promoter
Promoter
Genes of operon
DNA
Regulatory
gene
mRNA
trpE
trpR
3
trpC
trpB
trpA
C
B
A
Operator
Start codon Stop codon
RNA
polymerase
mRNA 5
5
E
Protein
trpD
Inactive
repressor
D
Polypeptides that make up
enzymes for tryptophan synthesis
Tryptophan absent, repressor inactive, operon on
LE 18-21b_1
DNA
mRNA
Active
repressor
Protein
Tryptophan
(corepressor)
Tryptophan present, repressor active, operon off
LE 18-21b_2
DNA
No RNA made
mRNA
Active
repressor
Protein
Tryptophan
(corepressor)
Tryptophan present, repressor active, operon off
LE 18-22a
Promoter
Regulatory
gene
Operator
lacl
DNA
lacZ
No
RNA
made
3
mRNA
5
Protein
RNA
polymerase
Active
repressor
Lactose absent, repressor active, operon off
LE 18-22b
lac operon
DNA
lacZ
lacl
3
mRNA
5
lacA
Permease
Transacetylase
RNA
polymerase
mRNA 5
-Galactosidase
Protein
Allolactose
(inducer)
lacY
Inactive
repressor
Lactose present, repressor inactive, operon on
Activity: lac Operon
LE 18-23
Promoter
DNA
lacl
lacZ
CAP-binding site
Active
CAP
cAMP
RNA
Operator
polymerase
can bind
and transcribe
Inactive lac
repressor
Inactive
CAP
Lactose present, glucose scarce (cAMP level high): abundant lac
mRNA synthesized
Promoter
DNA
lacl
CAP-binding site
Inactive
CAP
lacZ
Operator
RNA
polymerase
can’t bind
Inactive lac
repressor
Lactose present, glucose present (cAMP level low): little lac
mRNA synthesized
Figure 18.x6 Herpes
Figure 18.x1 Smallpox
Figure 18.x3 Polio
LE 18-8
Capsid
Capsid and viral genome
enter cell
RNA
HOST CELL
Envelope (with
glycoproteins)
Viral genome (RNA)
Template
mRNA
ER
Glycoproteins
Capsid
proteins
Copy of
genome (RNA)
New virus
LE 18-11
Young ballet students in Hong
Kong wear face masks to
protect themselves from the
virus causing SARS.
The SARS-causing agent is a
coronarvirus like this one
(colorized TEM), so named for
the “corona” of glyco-protein
spikes protruding form the
envelope.
Figure 18.x4 Hepatitis
Figure 18.x5 Influenza epidemic
Figure 18.x2 Measles
LE 18-9
Glycoprotein
Viral envelope
Capsid
Reverse
transcriptase
RNA
(two identical
strands)
LE 18-10
HIV
Membrane of
white blood cell
HOST CELL
Reverse
transcription
Viral RNA
0.25 µm
HIV entering a cell
RNA-DNA
hybrid
DNA
NUCLEUS
Provirus
Chromosomal
DNA
RNA genome
for the
next viral
generation
New HIV leaving a cell
mRNA
Activity: HIV Reproductive
Cycle
Figure 18.7x1 HIV infection