Lecture 4: Bacteriophages and its Vectors PDF

Summary

This lecture covers the fundamentals of bacteriophages, including their types, infection cycles, and applications in cloning and genetic studies. The document details the various stages of the lytic and lysogenic cycles. It explains the importance of phage in DNA replication, the methods for phage isolation, and plaque assays for measuring phage titers.

Full Transcript

BACTERIOPHAGES

TYPES:

λ phage M13 phage
PHAGE INFECTION CYCLE

VIRULENT PHAGES

Infect bacteria

Specific phage enzymes
coded by the phage
chromosome cause phage
DNA replication

Capsid proteins
synthesized and phage
particles reassembled and
released from the cell
LYTIC CYCLE

PHAGE DNA IS NEVER
MAINTAINED IN A STABLE
CONDITION IN THE HOST
 INTEGRATIVE PLASMID

TEMPERATE PHAGES
hage DNA (λ phage) in a similar fashion gets integrated into the bacterial genom

PROPHAGE LYSOGEN

 Prophages remain quiescent, and the lysogen is indistinguishable
from an uninfected cell

 Prophage is eventually released from the host genome by reverting
to lytic mode
 LYSOGENIC INFECTION CYCLE OF BACTERIOPHAGE λ

http://www.wwnorton.com/college/biology/microbiology2/ch/10/etopics.aspx

New phage
particles
synthesized
λ DNA excises
from the host
chromosome

Can possibly
maintained for 1000s
OGENIC GENE TRANSCRIPTIONS

1. PR and PL get activated upon circularization leading to synthesis of immediate
early transcripts (N and cro) that terminate at tL and tR
2. N protein allows tR and tL terminators being overridden, so subsequent
transcription gives rise to delayed early transcripts – cII and cIII.
3. cIII protein protects cII against degradation by host proteases.
4. cII activates promoter PRE (promoter for repressor establishment) that stimulates
production of cI, which is a repressor molecule inactivating P R and PL thus
switching off the lambda genome. (confers immunity to superinfection)
5. cII also activates promoter PINT that, in conjunction with host proteins, mediates
site-specific recombination across att and a similar sequence in the bacterial
TIC GENE TRANSCRIPTIONS

1. PR and PL get activated upon circularization leading to synthesis of immediate
early transcripts
2. N protein allows subsequent transcription gives rise to cII and cIII.
3. If conditions don’t favor stabilization of cII, PRE is not activated, cI not synthesized,
and rest of phage genome continues with transcription (further ensured by Cro
that inactivates PRM.
4. O and P cause DNA replication. Q causes activation of P R’ and expression of late
genes (encoding head and tail proteins). Int and Xis cause phage excision.
 ISOLATION OF PHAGE DN

Deproteinizati
on to remove
capsid

The extracellular λ titre is
extremely low. To increase the
yield, cultures need to be
“induced” such that lytic
processes predominate.

Most strains of λ carry a
temperature-sensitive
mutation (ts) in the cI gene.
cI+ cells in lysogeny
cIts cells in lysogeny at 30 C
cIts cells enter lytic cycle at 42 C
 Phage infection is visualized as plaques on an
agar medium

Each plaque is derived from a
single infected cell and therefore
contains identical phage particles
Virus titers are
measured in terms of
“plaque forming
units/mL”

17 plaques =

17 / (0.1 * 10-6) =

1.7 * 108 PFU/mL
PLAQUE ASSAY:
Dulbecco, R., & Vogt, M.
(1953). Cold Spring Harbor
Symp. Quant. Biol., 18, 273-
279
tp://www.virology.ws/2009/07/06/detecting-viruses-the-plaque-assay/
17 plaques
 GENETIC MAP OF BACTERIOPHAGE λ

Essential features of the λ genome (useful for cloning purposes)
include:
 clustering of functionally-related genes (46 genes encoded that can be
turned “on” or “off” as a group rather than individually).

 Linear double-stranded DNA with two free ends (but contain a 12-nt
stretch of ssDNA on either ends that are complementary to each other).
se of the cos sites:

w circularization of the linear DNA, which is necessary for insertion into the host g

ing circle” mechanism of replication

If the overall length of the genome is not altered greatly, then addition of
“new” genes in the internal regions (excluding cos sites and its immediate
neighbours) will not affect the phage life cycle.
ning strategies using λ phage
Potential drawbacks:
1. Only upto 3 kb DNA can be
inserted
2. The entire genome contains
more than one recognition
sequence for every known
RE

15 kb
Region can be replaced with “new” genes
without affecting the ability of the phage to
infect E.coli cells
oval of this region causes the phage to be only in “lytic” mode
ural selection to get rid of all (or all except one) RE recognition sequenc
 INSERTION VECTORS

Remove the non-
essential region and
religate the DNA

Can carry up to 8 kb new Can carry up to 10 kb new DNA in the
DNA in the cI region polylinker containing lacZ’ gene (single RE
(single RE sites) sites)
 REPLACEMENT VECTOR
Contains two recognition sites for RE for inserting new D

Digest with other REs to
prevent its own re-
insertion

Can carry larger fragments
of DNA
Utilize different REs for
cloning

Recombinants λ phage cannot infect E.coli with integrated DNA from P2
usually selected phages (sensitive to P2 prophage inhibition, spi+). Insertion
on the basis of of new DNA causes change from Spi+ to Spi- enabling
size
 M13 DNA does not integrate into the bacterial genome
M13 phage
M13 DNA is circular and entirely single stranded
New phage particles are continuously assembled and
released without lysing the host cells (infected bacterium
survive but grow at a slower rate)
Infects only E.coli
that have F-pili
(conjugation-
proficient cells)

Upto 1000 phage particles may
be released into the medium per
cell per generation
 Can be isolated similar to a plasmid

Replicates until about 100 copies
occur per cell
Replication of RF becomes asymmetric with
accumulation of viral-encoded ssDNA-binding
protein that binds to the phage DNA and
prevents synthesis of complementary strand.
he M13 Genome M13 genome is only 6407 nt in length
(circular and entirely ssDNA)
Capsid consists of only 3 proteins (3 genes)
unlike λ with 15 proteins
Simpler infection cycle – no genes for
insertion into host genome

Small size ideal for use as a cloning vector.
Most useful for obtaining single stranded
versions of cloned genes for
sequencing
in vitro (oligonucleotide-directed)
mutagenesis.
nstruction of M13 based vectors
M13 genome has ten genes essential for the replication of the phage
Intergenic sequence where new DNA can be inserted is only 507nt long
and contains the ori

Blue plaques on X-gal agar
No unique RE site present
 Introducing a
unique EcoRI
site in the lacZ
(Gronenborn and
Messing, 1978) using in
vitro mutagenesis

Addition of a
polylinker with
multiple RE sites
and sticky EcoRI site

Four possible cloning
sites have now been
generated

Maximum limit for
cloning