Lecture 3 Microbiology: Bacterial Heredity & Variation Lecture Notes PDF

Summary

This document is a lecture covering the topic of microbiology, specifically focusing on bacterial heredity and variation. It details aspects such as bacterial genetics, bacterial genome structures, and various gene transfer mechanisms. The document covers significant biological concepts.

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Lecture 3

Microbiology: Bacterial Heredity
&Variation

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 Content
Genetic material of bacteria (Chromosome, plasmid,
transposable element, integron and phage genome).
Bacterial phages (an overview). Mechanisms of
transfer and recombination of bacterial genes
(transformation, transduction, conjugation and
lysogenic conversion); gene mutation.
The significance of bacterial genetic variation (in drug
resistance, pathogenesis or virulence and variation,
diagnosis, and vaccination), and manipulation of
cloned DNA.

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 Bacterial Genetics
No feature is more central in bacterial diversity and power
to produce disease than their genetic mechanisms. New
media now deliver a constant stream of reports of new
antibiotic resistance and emerging pathogens.
Bacteria treated successfully with an antimicrobial for
decades suddenly appear to be resistant;
Diseases seemingly under control reappear;
New diseases (at least new for us) emerge and spread.
When traced to their origin most of these involve the
spread and breadth of genetic mechanisms, such as
mutation, recombination, transformation, transduction,
conjugation and transposition.

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 Bacterial genome
DNA molecules that
replicate as discrete
genetic units in bacteria
are called replicons.
In some bacterial strains
chromosome is the only
replicon present in the
cell.
Other bacterial strains
have additional replicons
such as plasmids and
bacteriophages.

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 Bacterial genome
Bacterial genome vary in size from about 4x109 to
8.6 x109 daltons (Da).
NOTE: 1 dalton = 1.660530000001 x 10-24 gram
1 gram = 6.02217364335 x 10+23 dalton
The smallest microbial genome is that of
Mycoplasma genitalium at 580,070 base pairs
encoding 525 genes. Some of the largest genomes
are those of the Cyanobacteria. Scytonema
hofmanni's genome is 12,073,012 base pairs in
size and has around 12,356 putative protein
coding genes.
Most bacteria have haploid genome, a single
chromosome – consisting of a circular double
stranded DNA molecule.
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 Bacterial genome
Bacterial genomes usually consist of a single circular
chromosome, but species with more than one
chromosome (eg. Deinococcus radiodurans), linear
chromosomes (eg. some Bacillis subtilis strains).
Linear chromosomes have been found in
Gram-positive Borrelia (cause of Lyme disease) and
Streptomyces spp.
One linear and one circular chromosome is found in
the Gram-negative bacteria Agrobacterium
tumerfaciens.
V.cholerae possesses 2 circular chromosoms.

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 How bacterial genome differs from
higher forms of life?
Every gene is composed of introns and exons: these are names given to
(functionally) different parts of a gene.
EXONS: coding portions of any gene - the exons of a gene contain the sequence
that actually codify the GENE'S PRODUCT - THE PROTEIN.
INTRONS: non-coding parts of any gene - the introns of a gene are sequences of
DNA that don't codify proteins. Their function is not totally clear, but they can be
transcripted into different RNAs, and these regions can also regulate genes
expression.

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Binary fission and generation time
Most bacteria reproduce by a relatively simple
asexual process called binary fission: each cell
increases in size and divides into two cells.
The time interval required for a bacterial cell to
divide or for a population of cells to double is
called the generation time. Generation times for
bacterial species growing in nature may be as
short as 15 minutes (20 min for E.coli) or as long
as several days (e.g. for Mycobacteria).

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Binary fusion

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 Mutation
Mutations are heritable changes in the
structure of genes.
The normal, usually active type of a gene is
called wild type allele.
The mutated, usually inactive form is called
mutant allele.

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 Mutation
Spontaneous development of mutations is a major
factor in the evolution of bacteria.
Mutations occur in nature with a low frequency
about 10-6 (one cell in a million).
Because bacteria is haploid, the consequences of
a mutation, even of a recessive one, are
immediately evident in the mutated cell.
Because the generation time of bacteria is short, it
does not take many hours for a mutant cell that
has arisen by chance to grow to the dominant cell
type if the mutation gives it a survival advantage.

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Development of antibiotic resistance

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 Kinds of mutations
There are several kinds of
mutations based on the nature of
the change in nucleotide
sequence of the affected gene(s).
A. Spontaneous or B. Induced.
Also mutations may be typed as:
Replacement or Substitution
(Point mutation), – involves
Missense mutation
substitution of one base with
another.
Missense mutation – when
changes in sequence of genes
changes mRNA transcript to a
different amino-acid (e.g. an AAG
– Lysine; GAG – Glutamate)
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 Kinds of mutation
Insertion – involves addition of many base pairs of nucleotides at a single
site.
Nonsense mutation –when replacement changes a codon specifying one
amino-acid to one specifying none (e.g.UAG - Tyrosine to UAA - STOP)
Deletion – remove a contiguous segments of many base pairs.
Microdeletion and microinsertion – involves removal of addition of a single
nucleotide.
Frame- shift mutation is caused by microdeletion and microinsertion,
which results in changes in reading frame by which the ribosomes
translate the mRNA from the mutated gene.
Duplication – produce a redundant segment of DNA, usually adjuscent to
(tandem) to original one.
Transversion – when purine nucleotide is changed with a pyrimidine or
vice versa
Suppressor mutation (reversal of mutant phenotype),
Lethal mutation
Conditional lethal mutant (Temperature sensitive mutant or ts mutant;
permissive temperature 37⁰C, Non-permissive temperature 39⁰C).

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Dr SOMESHWARAN, ASSISTANT PROFESSOR & CLINICAL MICROBIOLOGIST at KARPAGAM FACULTY OF MEDICAL SCIENCES AND RESEARCH

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 Recombination
Recombination is the process in which nucleic acid from different sources
are combined or re-arranged to produce a new nucleic sequence.
The source of recombinant chromosome may be another part of the same
chromosome (endogenote) or from outside the cell (exogenote) from
genetic mechanisms such as conjugation, transformation or transduction.
Homologous (generalized) recombination is a type of genetic
recombination in which nucleotide sequences are exchanged between two
similar or identical molecules of DNA. Generalized recombination requires
participation of the RecA enzyme, however other enzymes are also
necessary.
Site-specific recombination, also known as conservative site-specific
recombination, is a type of genetic recombination
Site specific recombination operates only in the unique sequences with
participation of RecBCD enzymes that are encoded by exogenote genes.
Rec A enzyme is not essential for the specific recombination.
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 Plasmids
The term plasmid was first
introduced by the American
molecular biologist Joshua
Lederberg in 1952.
Plasmids are considered as
transferable genetic
Joshua Lederberg
elements - “replicons”,
capable of autonomous
replication within the
suitable host.
Plasmid may be found in all
three major kingdoms:
Bacteria, Arhea and Eukaria.

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 Plasmid
A plasmid is an extra-chromosomal DNA
molecule separate from the chromosomal
DNA, capable to replicate independently of
the chromosomal DNA.
In many cases it is circular and double
stranded.
Plasmids occur naturally in bacteria, but
sometimes they are found in Eukaria as well.

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 Plasmids
Plasmid size varies from 1
to 200 kilobase pairs
(kbp). The number of
identical plasmids within
the single cell can range
anywhere from one to
even thousands.
Plasmids do not carry
genes essential for
survival, but info for
selective advantage.

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 Types of plasmids
There are two types of
plasmid integration into the
host bacteria:
a) Non-integrating plasmids
replicate independently
from the host
chromosome
b) Integrated plasmid is
called episome.
Episomes can insert into
bacterial chromosome,
where they become
permanent part of the
genome.

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 Grouping of plasmids
One way of grouping plasmids is by their ability to
transfer to other bacteria.
Conjugative plasmids carry so called tra genes that
mediate process of conjugation and are
responsible for transfer of plasmids into other
bacteria.
Non-conjugative plasmids are incapable of
initiating conjugation however they can be
transferred only with assistance of conjugative
plasmid.

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 Plasmids according to compatibility
groups
It is possible for plasmids of different types to
co-exist in a single cell. Seven different
plasmids have been found in E.coli.
But related plasmids are often incompatable,
in the sense that only one of them survives in
the cell line due to regulation of the vital
plasmid functions.
Therefore, plasmids can be assigned into
compatibility groups.

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 Classification of plasmids by their
functions
Another way to classify plasmids is by their
functions. There are 5 main classes:
Fertility – F-plasmids which contain tra genes.
They are capable of conjugation (transfer of genes
between the bacteria being in physical contact)
Resistance – R-plasmids that can build resistance
against antibiotics or poisons. Historically known
as R-factors before the nature of plasmids was
understood.

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 Classification of plasmids by their
functions
Col plasmids that code i.e. determine production of proteins
called bacteriocines since they able to kill other bacteria.
Bacteriocines are antibacterial agent that are active only
against similar or closely related bacterial strains. These are
growth inhibiting proteins which can inhibit the growth of
some closely related organisms, proteins produced by
bacteria to kill other microbes

Degradative plasmids that are capable for digestion of
unusual substances, e.g. toluene or salicylic acid.
Virulence plasmid which turn the bacteria into a pathogen
(one that causes a disease).

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 Use of plasmids
Plasmids are used in molecular biology for
production of large amounts of proteins. In this
case the researchers grow the bacteria containing
plasmids harboring the genes of interest. The
plasmid carrier bacteria is producing the protein in
large amounts. This is a cheap and easy way for
mass-production of certain proteins e.g. insulin or
even antibiotics.
Plasmids are now used to manipulate DNA and
may possibly be a tool for curing many diseases.

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 Mobile genetic elements –
“jumping genes”
Transposons are the segments of DNA that
can move from one site of DNA molecule to
other target sites of the same or a different
DNA molecule e.g. plasmid.
The process is called transposition and
occurs by a mechanism that is independent
from generalized recombination.
Transposones are not self replicating
elements.
They must integrate into other replicons to
be stably maintained in bacterial genomes.
The transposition relies of their ability to
Barbara McClintock –
synthesize their own specific recombination Nobel Prize 1983
enzymes – transposases. 30
 Transposons were first
discovered in corn,
where they cause varied
expression of color

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The major kind of transposable elements are insertion sequence (IS) elements and
transposons.
IS elements encode only proteins for their own transposition.
Insertion of IS elements into a gene causes mutation.
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IS elements are flanked by inverted repeats IR elements.
 Transposons
IS –insertion sequences are the simplest structures that
encode only the functions needed for transposition.
Complex transposons vary in length from about 2,000 to
more than 40,000 nucleotide pairs and contain insertion
sequences (or closely related sequences) at each end usually
as inverted repeats.

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 Role of transposons
Most transposons share a number of common features.
Each transposon encodes the functions necessary for
transposition, including production of transposase – an
enzyme that integrates with specific sequences present at
the ends of the transposon.
Transposons encode functions (e.g. antibiotic resistance,
substrate metabolism, etc.) beyond those needed for their
own transposition
Insertion of transposons often interrupts the linear
sequence of a gene and inactivates it.
Transposons have a major role in causing deletions,
duplications and inversions of DNA segments as well as
fusions between the replicons.

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Transposons sequences can hop to another
region of the genome and integrate

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 Mechanisms of transposition
A. Direct transposition
moves the
transposon to a new
site –”cut and paste
mechanism”.
B. Replicative
transposition leaves
a copy behind –
“copy and paste
mechanism”
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 Mechanisms of transposition
During transposition a short sequence of
target DNA is duplicated.
The duplication is presumed to involve an
assymetric cleavage of DNA at the target site.
If the transposon at the donor site is
replicated and a copy is inserted into the
target site the process is called integrative
transposition.

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 Regulation of gene transfer
Species of bacteria differ by their ability to
transfer DNA, but all the three mechanisms
are distributed among both Gram + and Gram-
species, however:
Only transformation is governed by bacterial
chromosome genes;
Transduction is totally mediated by
bacteriophage genes;
Conjugation is regulated by plasmid genes.

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Transformation – Griffith’s experiment

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 Transformation
Transformation – a 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:
1. A donor bacterium dies and is degraded
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
3. The Rec A protein promotes genetic exchange between a
fragment of the donor's DNA and the recipient's DNA
4. Exchange is complete

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 Transformation

The ability to take up DNA from the environment is called competence.
To be active in transformation DNA molecules must be at least 500 nucleotide pairs in length.
Any DNA present in environment is bound indiscriminately, however its further fate depends on
whether it shares homology with the portion of DNA of the recipient cell. In this case
transformation can occur, but heterologous DNA is degraded.
Other species do not naturally enter the competent state , can be made permeable to DNA by
treatment with agents that damage the cell envelope, making an artificial transformation
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possible.
 Conjugation
The process called conjugation is
the transfer of genetic information
from the donor (F+) to a recipient
(F-) bacterial cell in the process that
requires intimate cell contact.

Conjugation is plasmid encoded
process.
Conjugative plasmids contain the
genes responsible for transfer.
Nonconjugative plasmids are The 3 conjugative processes are known:
transferred by plasmid mobilization I. F + conjugation
by conjugative plasmid. II. Hfr conjugation
Conjugation may cross species lines III. Resistance plasmid conjugation

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 Conjugation
Plasmids responsible for conjugation are known as
Fertility factors (F) or Sex or Transfer factor.
F factor (is an plasmid coding for synthesis of Sex
pilus)
Cells carrying F factor = F+ Cells;
Cells lacking F factor = F- Cells;
Hfr cells: High frequency cells – the F factor is the
episome state i.e. in integrated with host
chromosome.
Conversion of F+ cell to Hfr cell is reversible;
F factor to F Prime (F’) factor
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 F+ Conjugation
Genetic recombination in which there is a
transfer of an F+ plasmid (coding only for a sex
pilus) but not chromosomal DNA from a male
donor bacterium to a female recipient
bacterium.
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.
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Conjugation

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Conjugation

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 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
2. The sex pilus adheres to an F- female (recipient). One
strand of the F+ plasmid breaks
3. The sex pilus retracts and a bridge is created between the
two bacteria. One strand of the F+ plasmid enters the
recipient bacterium
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

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 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.

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 5 stepped Hfr Conjugation
1. An F+ plasmid inserts into the donor
bacterium's nucleoid to form an Hfr male.
2. The sex pilus adheres to an F- female
(recipient). One donor DNA strand breaks
in the middle of the inserted F+ plasmid.
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.
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.
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
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bacterium usually remains F-
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 Composition of RTF
Plasmid consists of two
components:
A transfer factor RT,
helps conjugational
transfer, and resistant
determinant (r) to each
of the several drugs.
RTF + r are known as R
factor
R factor may contain
determinants as many as
8 or > 8 drugs

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 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.
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).
2. The sex pilus adheres to an F- female (recipient). One strand
of the R-plasmid breaks
3. The sex pilus retracts and a bridge is created between the
two bacteria. One strand of the R-plasmid enters the recipient
bacterium.
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
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 Phage T4
Phage structure Head

Collar
Tail

Fibers
Basal plate

Phage genetic map
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Phage Reproduction on the Bacterial Cell

Bacteriophage in action - to find the target and neutralize
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Lytic and Lysogenic cycles

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Lytic cycle

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Lysogenic cycle

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 Transduction
Transduction is the transfer of DNA fragments from
one bacterium to another bacterium by a
bacteriophage.
Transduction was discovered by Joshua Lederberg
and Norton Zinder in 1952.

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U tube experiment
Transduction was discovered by
Zinder and Lederberg while
searching for conjugation in S.
typhimurium. Lederberg-Zinder
experiment - After placing two
auxotrophic strain of Salmonella
on opposite side of the U-tube,
the researches recovered
prototrophs from the side with
the LA-22 strain, but not from the
containing the LA-2 strain. These
initial observations led to the
discovery of the phenomenon
called transduction.
----------------------------------
Phe=phenilalanin
Trp=tryptophan
Met=metionin 64
His=histidine
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 Generalized transduction

1 2

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3 4
Generalized transduction

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 Seven steps in Generalized Transduction
1. A lytic bacteriophage adsorbs to a susceptible bacterium.
2. The bacteriophage genome enters the bacterium. The
genome directs the bacterium's metabolic machinery to
manufacture bacteriophage components and enzymes
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.
4. The bacteriophages are released.
5. The bacteriophage carrying the donor bacterium's DNA
adsorbs to a recipient bacterium
6. The bacteriophage inserts the donor bacterium's DNA it is
carrying into the recipient bacterium.
7. The donor bacterium's DNA is exchanged for some of the
recipient's DNA.
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 Six steps in Specialized transduction
1. A temperate bacteriophage adsorbs to a susceptible
bacterium and injects its genome.
2. The bacteriophage inserts its genome into the bacterium's
nucleoid to become a prophage
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.
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.
5. The bacteriophage adsorbs to a recipient bacterium and
injects its genome.
6. The bacteriophage genome carrying the donor bacterial
DNA inserts into the recipient bacterium's nucleoid. 71
Genetic mechanism of drug-resistance
Bacteria acquire drug resistance through several Mechanisms
Mutations
Genetic transfer
Transformation
Transduction
Conjugation

Several Biochemical Mechanisms
Decreasing permeability of drugs
Attaining alternative pathways
Produce enzymes and inactivate drugs

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 Genetic manipulations of DNA
DNA cloning and other techniques can be used to manipulate and analyze
DNA and to produce useful new products and organisms. DNA cloning
permits production of multiple copies of a specific gene or other DNA
segment.
A recombinant plasmid is made by inserting restriction fragments from DNA
containing a gene of interest into a plasmid vector that has been cut open
by the same enzyme. Gene cloning results when the recombinant plasmid is
introduced into a host bacterial cell and the foreign genes are replicated
along with the bacterial chromosome as the host cell reproduces.
DNA technology is reshaping medicine and the pharmaceutical industry.
Medical applications include diagnostic tests for genetic and other diseases,
safer, more effective vaccines, and the prospect of treating or even curing
certain genetic disorders. Pharmaceutical applications include the
large-scale production of many new, and some previously scarce, drugs and
other medicines

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Your manual
Chapter 7. Microbial genetics

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Thank you

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