Bacterial genetic recombination can occur through transformation, transduction, or conjugation. Transformation involves DNA uptake from dead bacteria. Transduction involves DNA transfer by bacteriophages. Conjugation involves DNA transfer through cell-to-cell contact via plasmids or sex pili. Plasmids are small extrachromosomal DNA molecules that can replicate independently and be transferred between bacteria. Episomes can exist independently or integrate into chromosomes, and include plasmids, viruses, and transposons.
2. INTRODUCTION
• Genetic recombination - transfer of DNA from one
organism (donor) to another organism (recipient).
The transferred donor DNA may then be integrated
into the recipient's genetic material by various
mechanisms
• Like mutation, genetic recombination contributes to
genetic diversity of a population, which is the source
of variation in evolution
4. TRANSFORMATION
• Genetic recombination in which a DNA
fragment from a dead, degraded bacterium
enters a competent recipient bacterium and it
is exchanged for a piece of the recipient's
DNA.
• Involves 4 steps
5. 1. A donor bacterium dies and is degraded
The 4 steps in
Transformation
6. 2. A fragment of DNA from the dead donor
bacterium binds to DNA binding proteins on the
cell wall of a competent, living recipient bacterium
7. 3. The Rec A protein promotes genetic exchange
between a fragment of the donor's DNA and the
recipient's DNA
10. Transduction
• Another method by which genetic recombination
takes place in bacteria is Transduction.
• Genetic recombination in which a DNA fragment
is transferred from one bacterium to another by a
bacteriophage.
11. What are Bacteriophages?
• Bacteriophage (phage) are obligate intracellular
parasites that multiply inside bacteria by making use of
some or all of the host biosynthetic machinery (i.e.,
viruses that infect bacteria).
12. Transduction (cont’d)
• There are two types of transduction:
– Generalized transduction: A DNA fragment is
transferred from one bacterium to another by a lytic
bacteriophage that is now carrying donor bacterial
DNA due to an error in maturation during the lytic life
cycle.
– Specialized transduction: A DNA fragment is
transferred from one bacterium to another by a
temperate bacteriophage that is now carrying donor
bacterial DNA due to an error in spontaneous
induction during the lysogenic life cycle
13. Seven steps in Generalised
Transduction
1. A lytic bacteriophage adsorbs to a
susceptible bacterium.
14. 2. The bacteriophage genome enters the
bacterium. The genome directs the
bacterium's metabolic machinery to
manufacture bacteriophage components
and enzymes
15. 3. Occasionally, a bacteriophage head or capsid
assembles around a fragment of donor
bacterium's nucleoid or around a plasmid
instead of a phage genome by mistake.
17. 5. The bacteriophage carrying the donor
bacterium's DNA adsorbs to a recipient
bacterium
18. 6. The bacteriophage inserts the donor
bacterium's DNA it is carrying into the recipient
bacterium .
19. 7. The donor bacterium's DNA is exchanged
for some of the recipient's DNA.
20. Six steps in Specialised
Transduction
1. A temperate bacteriophage adsorbs to a
susceptible bacterium and injects its genome .
21. 2. The bacteriophage inserts its genome into the
bacterium's nucleoid to become a prophage.
22. 3. Occasionally during spontaneous induction, a small piece of
the donor bacterium's DNA is picked up as part of the phage's
genome in place of some of the phage DNA which remains in
the bacterium's nucleoid.
23. 4. As the bacteriophage replicates, the segment of bacterial
DNA replicates as part of the phage's genome. Every phage
now carries that segment of bacterial DNA.
25. 6. The bacteriophage genome carrying the
donor bacterial DNA inserts into the recipient
bacterium's nucleoid.
26. Bacterial Conjugation
• Bacterial Conjugation is genetic recombination in
which there is a transfer of DNA from a living donor
bacterium to a recipient bacterium. Often involves a
sex pilus.
• The 3 conjugative processes
I. F
+
conjugation
II. Hfr conjugation
III. Resistance plasmid conjugation
27. • F+ Conjugation- Genetic recombination in which
there is a transfer of an F+ plasmid (coding only for a
sex pilus) from a male donor bacterium to a female
recipient bacterium.
• Doesn’t include chromosomal DNA.
• Involves a sex (conjugation) pilus.
• Other plasmids present in the cytoplasm of the
bacterium, such as those coding for antibiotic
resistance, may also be transferred during this
process.
I. F+ Conjugation
Process
28. The 4 stepped F+ Conjugation
1. The F+ male has an F+ plasmid coding for a sex
pilus and can serve as a genetic donor
29. 2. The sex pilus adheres to an F- female (recipient).
One strand of the F+ plasmid breaks
30. 3. The sex pilus retracts and a bridge is created
between the two bacteria. One strand of the F+
plasmid enters the recipient bacterium
31. 4. Both bacteria make a complementary strand of the F+ plasmid and
both are now F+ males capable of producing a sex pilus. There was
no transfer of donor chromosomal DNA although other plasmids the
donor bacterium carries may also be transferred during F+
conjugation.
32. II. Hfr Conjugation
• Genetic recombination in which fragments of
chromosomal DNA from a male donor
bacterium are transferred to a female recipient
bacterium following insertion of an F+ plasmid
into the nucleoid of the donor bacterium.
• Involves a sex (conjugation)pilus.
33. 5 stepped Hfr Conjugation
1. An F+ plasmid inserts into the donor bacterium's nucleoid
to form an Hfr male.
34. 2. The sex pilus adheres to an F- female (recipient).
One donor DNA strand breaks in the middle of the
inserted F+ plasmid.
35. 3. The sex pilus retracts and a bridge forms between the
two bacteria. One donor DNA strand begins to enter the
recipient bacterium. The two cells break apart easily so
the only a portion of the donor's DNA strand is usually
transferred to the recipient bacterium.
36. 4. The donor bacterium makes a complementary copy
of the remaining DNA strand and remains an Hfr male.
The recipient bacterium makes a complementary
strand of the transferred donor DNA.
37. 5. The donor DNA fragment undergoes genetic
exchange with the recipient bacterium's DNA. Since
there was transfer of some donor chromosomal DNA
but usually not a complete F+ plasmid, the recipient
bacterium usually remains F-
38. III. RESISTANT PLASMID CONJUGATION
• Genetic recombination in which there is a
transfer of an R plasmid (a plasmid coding for
multiple antibiotic resistance and often a sex
pilus) from a male donor bacterium to a
female recipient bacterium.
• Involves a sex (conjugation) pilus
39. 4 Stepped Resistant Plasmid
Conjugation
1. The bacterium with an R-plasmid is multiple
antibiotic resistant and can produce a sex pilus (serve
as a genetic donor).
40. 2. The sex pilus adheres to an F- female
(recipient). One strand of the R-plasmid breaks.
41. 3. The sex pilus retracts and a bridge is created
between the two bacteria. One strand of the R-
plasmid enters the recipient bacterium.
42. 4. Both bacteria make a complementary strand of
the R-plasmid and both are now multiple
antibiotic resistant and capable of producing a sex
pilus.
43. PLASMIDS
• A plasmid is a small DNA molecule within a cell that
is physically separated from a chromosomal DNA and
can replicate independently.
44. • Plasmids carry genes that may benefit survival of the
organism (e.g. antibiotic resistance), and can
frequently be transmitted from one bacterium to
another (even of another species) via horizontal gene
transfer.
• Plasmids usually are very small and contain additional
information.
45. TYPES OF PLASMIDS
Plasmids are classified :
By their ability to be transferred to other bacteria:
1 . Conjugative plasmids
• The sexual transfer of plasmids to another bacterium
through a pilus.
46. 3 . Mobilisable
• Intermediate class of plasmids
• Mobilizable, and carry only a subset of the genes
required for transfer.
•Can 'parasitise' another plasmid, transferring at high
frequencyin the presence of a conjugative plasmid.
2 . Non-conjugative :
• Non-conjugative plasmids don’t initiate conjugation
• Only be transferred with the help of conjugative
plasmids
47. 2. By function
1. Fertility-(F) plasmids,
They are capable of conjugation (they contains the genes for
the pili).
2. Resistance-(R) plasmids,
Contain gene (s) that can build resistance against one or
several antibiotics or poisons.
3. Col-plasmids,
Contain genes coding for colicines, proteins that can kill
other bacteria.
4. Degradative plasmids,
Able to digest unusual substances, e.g., toluene or salicylic
acid.
5. Virulence plasmids,
Turn a bacterium into a pathogen.
48. EPISOMES
• An episome is a portion of genetic material that can
exist independent of the chromosome at some
times, while at other times is able to integrate into
the chromosome.
• Examples of episomes include :
Insertion sequences and transposons.
Viruses
F factor
49. 1. Tranposons and insertion sequence
• Transposons and insertion sequences are
episomes.
• Also known as mobile genetic elements.
• Capable of existing outside of the chromosome.
• Also designed to integrate into the chromosome
and then move from one cell to another.
• Transposons can carry other genetic material
with them.
50. 2. Viruses
• Viruses are another example of an episome.
• Viruses will integrate their genetic material into the
host chromosome.
3. F factor
• F factor that has integrated into the host
chromosome is known as Hfr.
• Hfr stands for high frequency of recombination.
51. IN SUMMURY
BACTERIAL RECOMBINATION occurs in 3 ways
• Transformation
• Transduction
• Recombination
PLASMIDS :
Autonomously replicating extra chromosomal DNA
EPISOMES:
Piece of genetic material capable of existing independent
of chromosome as well as in integrated form.