L 5 - Bacterial genetics.pptx.pdf

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L 5 - Bacterial genetics

Dr. Janita Pinto

September 9, 2024

www.gmu.ac.ae COLLEGE OF PHARMACY
 Learning objectives
On completion of this unit, the student will be able to:

Describe the structure and function of DNA and RNA

Describe the genetic transfer mechanisms used by bacteria to obtain new genes (transformation,
conjugation, lysogenic conversion and transduction)

Describe the various mechanisms of mutations as part of genetic variation

Differentiate the genetic and non-genetic basis of drug resistance
 Bacterial Genetics

Bacterial genetics is used as a model to
understand DNA replication, genetic
characters, their changes & transfer to
next generations.
 The bacterial chromosome
The bacterial chromosome is a single circular molecule
of double-stranded DNA approximately 1000 times as
long as the cell itself.

It exists in a highly folded state and this supercoiling is
brought about by topoisomerase enzymes.

In prokaryotic cells the chromosome is not surrounded
by a nuclear membrane but exists free in the cytoplasm
condensed into areas called chromatin bodies.

The chromosome may duplicate itself every 20 minutes
during exponential growth.
The bacterial chromosome

Prokaryotic genomes are very small with very little space
between the genes.

E. coli has approximately 4000 genes and the length of the DNA
molecule is about 1mm.

On the other hand a yeast cell has approximately 6000 genes in
a genome three times the size of E. coli.
 Bacterial genetics

The genetic material of a typical bacterium, Escherichia coli, consists
of a single circular DNA molecule containing 4,000 genes; and a
human cell has about 23,000 genes on 46 chromosomes.

A few bacteria (Eg, Vibrio cholerae) have genomes consisting of two
circular DNA molecules.

Bacteria are haploid; in other words, they have a single chromosome
and therefore a single copy of each gene.
Central Dogma :
DNA RNA Polypeptide
Transcription
Genetic information is stored in DNA in the form of a
code (3 bases) called codon.
RNA polymerase forms a single polyribonucleotide
strand, called mRNA, using DNA as a template; this
process is called transcription.
Translation
The ribosomes contain rRNA and proteins, transfer the
message into the primary structure of proteins via –
aminoacyl transfer (tRNA)
Translation (polypeptide synthesis)

Bacteria have no nucleus, transcription
and translation is coupled, meaning that
the nascent mRNA attaches to a
ribosome and is translated at the same
time it is transcribed.
This coupled transcription and translation
allows for the rapid response to changes
in the environment.
 Bacterial DNA Replication

The replication of bacterial DNA begins at one point and moves
in both directions (ie, bidirectional replication).
Replication of the bacterial chromosome is tightly controlled,
and the number of each chromosomes (when more than one is
present) per growing cell falls between one and four.
The two daughter chromosomes are separated, or resolved,
before cell division, so that each progeny cell gets one of the
daughter DNAs. This is accomplished with the aid
of topoisomerases, enzymes that alter the supercoiling of
dsDNA
Some Enzymes Involved in DNA Replication
and Their Functions
14
Bacterial chromosome replication
 Antibiotics That Affect Transcription and
Translation
Drugs that inhibit protein synthesis may exert their influence
on transcription or translation.

For example, the rifamycins used in tuberculosis treatment
bind to RNA polymerase, blocking the initiation step of
transcription. Rifamycins are selectively more active against
bacterial RNA polymerase than they are against eukaryotic RNA
polymerase.
 Antibiotics That Affect Transcription and
Translation
One group of antibiotics (including erythromycin and
spectinomycin) prevents translation by interfering with the
attachment of mRNA to ribosomes.

Chloramphenicol, lincomycin, and tetracycline bind to the
ribosome in a way that blocks the elongation of the
polypeptide, and aminoglycosides (such as streptomycin)
inhibit peptide initiation and elongation.
 Genetic Information In Bacteria
Chromosome Single, circular, supercoiled Haploid; carries ~ 2000 genes
Properties: virulence, pathogenicity & resistance

Plasmid Extrachromosomal; circular DNA
Replicate independently
Can integrate into bacterial chromosomal DNA (Episome)

Transposons A transposon can jump from a plasmid to a bacterial chromosome
or from one plasmid to another plasmid. In this manner, multiple
drug-resistant plasmids are generated.
Jumping genes, Cannot replicate independently
They often contain several genes, including those necessary for
their migration from one genetic locus to another. In doing so, they
create insertion mutations.
 EXTRACHROMOSOMAL GENETIC
MATERIAL – PLASMIDS
Extra-chromosomal genetic (Circular DNA) material.
Confer Drug resistance and toxigenicity
No role in the normal functioning of host bacterium.
Important vectors in genetic engineering.

EPISOME
Covalently closed DNA circles (bacterial chromosomes and plasmids), which contain genetic
information necessary for their own replication, are called replicons or episomes.

Types of plasmids
R plasmid (drug resistance): contain resistance transfer factor (RTF) and the R
determinant
F plasmid (maleness )
 Horizontal Gene Transfer in Bacteria
Any transfer of DNA that results in organisms acquiring new genes that did not come directly from parent
organisms is called horizontal gene transfer.
DNA transfer between bacterial cells typically involves small
pieces of DNA in the form of plasmids or chromosomal fragments.
Chromosomal fragments that have escaped from a lysed bacterial
cell are also commonly involved in the transfer of genetic information
between cells. An important difference between plasmids and
fragments is that while a plasmid has its own origin of replication
and is stably replicated and inherited, chromosomal fragments must
integrate themselves into the bacterial chromosome in order to be
replicated and eventually passed to progeny cells.
Mechanisms of Gene Transfer

1. Transformation: direct transfer
2. Transduction: transfer by means of a bacteriophage
3. Conjugation: transfer through sex pili
Conjugation
Transfer of DNA from one bacterium to the other through
conjugation tube (sex pilus)
1.The donor (F+) cell makes a copy of its F factor
and transmits this to a recipient (F−) cell. The F−
cell is thereby changed into an F+ cell capable of
producing a pilus and conjugating with other cells.
No additional donor genes are transferred at this
time.

2. In a variation on that process, called high-
frequency Recombination (Hfr), the plasmid
becomes integrated into the donor chromosome
before instigating transfer to the recipient cell.
Biomedical importance of conjugation

Special resistance (R) plasmids, or factors, that carry genes for
resisting antibiotics and other drugs are commonly shared
among bacteria through conjugation.
Transfer of R factors can confer multiple resistance to
antibiotics such as tetracycline, chloramphenicol, streptomycin,
sulfonamides, and penicillin.
Other types of R factors carry genes for resistance to heavy
metals (nickel and mercury) or for synthesizing virulence factors
(toxins, enzymes, and adhesion molecules) that increase the
pathogenicity of the bacterial strain.
 Transformation
Direct uptake and absorption of bacterial DNA by a recipient cell
Griffith’s experiment
 Transduction

Transfer of a portion of the DNA from one
bacterium to another by means of a bacteriophage.

Plasmids can also be transduced.

Most widely used mechanism of gene transfer among
prokaryotes
 Types of transduction

In generalized transduction, random fragments of disintegrating host DNA are taken up by the
phage during assembly. Virtually any gene from the bacterium can be transmitted through this
means.

In specialized transduction, a highly specific part of the host genome is regularly incorporated
into the virus. Several cases of specialized transduction have medical importance.

The virulent strains of bacteria such as Corynebacterium diphtheriae, Clostridium spp., and
Streptococcus pyogenes all produce toxins with profound physiological effects, whereas
nonvirulent strains do not produce these toxins. It turns out that the toxins are produced by
bacteriophage genes that have been introduced by transduction.
Generalised Transduction
Specialized transduction
 Pathogenicity Islands

Some of the horizontally transferred genes in bacteria have the ability to make their new

hosts pathogenic, or able to cause disease. These are termed pathogenicity islands.

These islands contain multiple genes that are coordinated to create a new trait in the

bacterium, such as the ability to scavenge iron (important for the bacterium causing the

plague, Yersinia pestis) or the ability to produce exotoxins (seen in Staphylococcus

aureus).
Mutations: Changes in the Genetic Code

Changes in the genetic code can occur by two means: mutation and recombination.
Mutation means a change in the nucleotide sequence of the organism’s genome.

Mutations can be either spontaneous or induced by exposure to some external
mutagenic agent. All cells have enzymes that repair damaged DNA.

When the degree of damage exceeds the ability of the enzymes to make repairs,
mutations occur.

Mutation-induced changes in DNA nucleotide sequences range from a single nucleotide
to addition or deletion of large sections of genetic material.
Summary of Genetic Transfer
Mechanisms
Learning Resources
Barer MR, Irving W, Swann A, Perera N. Medical Microbiology: A
Guide to Microbial Infections. 19th Ed. Elsevier Ltd; 2018, ISBN:
978-0-7020-7200-0. https://www.clinicalkey.com/#!/content/book/3-
s2.0-B9780702072000000023
Murray PR, Rosenthal KS, Pfaller MA. Medical Microbiology. 8th
ed. Elsevier Ltd; 2016. ISBN: 978-0-323-29956-5.
https://www.clinicalkey.com/#!/content/book/3-s2.0-
B978032329956500080X
Additional Reading
Levinson W. Review of Medical Microbiology and Immunology, 13th
Ed. USA: McGraw-Hill Companies; 2014. ISBN-13: 978-
0071818117.
9/9/2024