Microbial Genetics Lesson 5 PDF

Summary

This document is a lesson on microbial genetics, covering learning objectives, genes, genomes, and the genetic information of microbes. It explains the importance of DNA and horizontal gene transfer in microorganisms.

Full Transcript

9/3/2024

Learning objectives:
▪ Describe the importance of DNA

Microbial
▪ Describe microbial genetics and the central dogma of molecular biology
▪ Differentiate vertical from horizontal gene transfer

▪ Describe the mechanisms of horizontal gene transfer

Genetics
▪ Explain how mechanisms of horizontal gene transfer contributes to the spread of
antibiotic resistance genes in the clinical and environmental setting

Irish A. Rabano
Instructor IV
Centro Escolar University – Manila

Introducing Genes and Genomes Microbial genetics
▪ Genetics ▪ is the study of the mechanisms of heritable information in microorganisms
▪ study of heredity in general and of genes in particular
▪ study of inherited traits, rooted in DNA, and their variations and transmission
▪ Heredity
▪ Transmission of inherited traits from generation to generation
▪ Genes
▪ A section of a DNA molecule whose sequence of building blocks instructs a cell to produce a
particular protein
▪ Genomes
▪ The complete set of genetic instructions in the cells of a type of organism.
▪ DNA is the information molecule for all living organisms. All of the DNA of an organism is
called its genome.
▪ Genomics – The field that analyzes and compares genomes
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Genetic Information of Microbes Nucleoid-associated proteins (NAPs)

▪ Bacterial genome
▪ The bacterial genome is usually contained in a circular DNA molecule which is supercoiled and
localized within the nucleoid of the cell.
▪ Size of bacterial genome: usually less than 500,000 base pairs (500 kb) to 5 million base pairs (5 Mb)
▪ (The major pattern in bacterial genome size is that, on average, free-living species have larger genomes than
parasitic species which in turn have larger genomes than obligate pathogens)

▪ Exceptions:
▪ Some bacteria have two or more chromosomes
▪ Vibrio, Burkholderia, Leptospira and Brucella species
▪ Some chromosomes may be linear
▪ Borrelia burgdorferi  Bacteria have a cell cycle with a duration on the order of tens of minutes.
▪ Some chromosomes may be large  As a consequence, genome folding and transcription are intimately coupled with genome
▪ Bacillus megaterium may be as large as 30 MB
replication.

(Brocken et al., 2018)

Operon - (Bacterial Gene Organization)
a set of functionally related structural genes adjacent to a
▪ A typical bacterial genome has common transcriptional control site (promoter and operator)
approximately 4,400 genes
(humans 25,000)
▪ The genome of bacteria
encodes:
▪ Biochemical functions necessary for
survival
▪ Virulence factors for pathogenic
bacteria
▪ Non-coding regions
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- any DNA molecule regardless of its specific nature

(diCenzo and Finan, 2017)

Plasmid Genetic Information of Microbes
Extrachromosomal DNA
– found in bacteria, archaea, some fungi ▪ Bacterial DNA (Deoxyribonucleic acid)
– usually small, closed circular DNA molecules ▪ Circular chromosome + plasmid
Exist and replicate independently of chromosome
Contain few genes that are non-essential

– confer selective advantage to host
(e.g., drug resistance, E. coli: plasmid
encodes toxins produced and bacterial
attachment to intestinal cells)

Plasmids are used in genetic engineering as
gene transfer vectors
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DNA is a nucleic acid and nucleotides are the
building blocks of all nucleic acids.
1

2

3

Three essential components:
1. Nitrogenous base
2. Phosphate group
3. Pentose sugar (a 5-carbon sugar)
Polymers - a substance or material consisting of very large molecules called
macromolecules, composed of many repeating subunits or monomers
Lipids – fatty acids, Carbohydrates – monosaccharides, Proteins – amino acids Nucleic acids - nucleotide What is the structure of a DNA? Orientation?

Phosphate of one nucleotide
attaches to the 3rd C-OH
group of the sugar of the
2nd nucleotide, thereby
forming 5’ → 3’ linkage

Nitrogenous base
Purines – Guanine and
adenine
The phosphate residue is attached to
the 5′ carbon of the sugar
Pyrimidines – Cytosine,
The hydroxyl group is attached to the thymine, and uracil
3′ carbon of the sugar
The nitrogenous bases is attached in
the 1’ carbon of the sugar
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Central Dogma of Molecular Biology
The central dogma of molecular biology is a theory stating that genetic information flows
DNA only in one direction, from DNA, to RNA, to protein, or RNA directly to protein.
RNA
1. Sugar =
1. Sugar = ribose ▪ Central Dogma
deoxyribose
2. Bases = A,C, ▪ Replication – Transcription - Translation
2. Bases = A,C,
G, U
G, T
3. Single
3. Double
stranded
stranded
4. Leaves the
4. Stays in
nucleus
nucleus

DNA replication is semi-conservative

DNA
REPLICATION
DNA must be replicated in order to ensure that each
new cell receives the correct number of chromosomes.
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DNA REPLICATION
Purpose: create a duplicate copy of the double stranded DNA
Site: DNA replication occurs in the nucleoid
Template: Both strands (leading and lagging strands)
Control: Origin of replication

STAGES OF DNA REPLICATION:
1. Initiation
2. Elongation
3. Termination

TRANSCRIPTION TRANSLATION
DNA to mRNA to protein DNA to mRNA to protein

Synthesis of proteins from the information
Double stranded DNA must be TRANSCRIBED
into a single stranded mRNA
contained in a molecule of messenger RNA
(mRNA).
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In an mRNA, the instructions for building a polypeptide are RNA nucleotides (AUGC) read in
groups of three = Codons
TRANSLATION
Translation is the decoding of an mRNA
message into a polypeptide chain
(protein)
Purpose: convert a sequence of mRNA into a
sequence of amino acids to make proteins
Site: ribosomes in the cytoplasm
Template: mRNA

Key components: tRNA, ribosomes, mRNA

What are the ways that genes can be transferred?
1. REPRODUCTION - Binary fission

Exchange of
▪ Vertical gene transfer - Transfer of genetic material from
parental organism to progeny
Gene Transfer refers to the
Genetic transfer of DNA containing
functional genes between any two
How do they get genetic variability?
2. Horizontal Gene Transfer - Transfer of genetic material
organisms
Information between unrelated individuals
▪ Transformation: Bacteria take up DNA from their
environment
▪ Conjugation: Bacteria directly transfer genes to another cell
▪ Transduction: Bacteriophages (bacterial viruses) move
genes from one cell to another
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Transposable Elements
Conjugation ▪ A transposable element (TE, transposon, or jumping gene)
▪ Transposons can insert into plasmids which can be transferred to recipient cells by conjugation
▪ a donor bacterium transfers a copy of a
▪ Designed to move from one location to another within a DNA molecule by a process known as transposition.
plasmid to a recipient bacterium, through
a pilus via direct cell to cell contact  Transposable elements are flanked by inverted repeats and often contain multiple antibiotic resistance
▪ Donor cell – has (F+) conjugative genes
plasmid ▪ All transposable elements code for the enzyme transposase, the enzyme responsible allowing
▪ F (fertility) factor is a conjugative plasmid transposition to occur, and have short inverted repeats (IRs) at each end.
transferred from cell to cell by conjugation
▪ F factor is an episome = genetic element
that can insert into chromosome or
replicate as circular plasmid
▪ Recipient cell – (F-) does not contain
conjugative plasmid

30

Kinds of Transposition
Transposable elements Transposition is the process by which transposons move within a genome from
one location to another.
▪ A transposable element (TE, transposon, or
jumping gene) There are two main kinds of transposition mechanisms, that determine how
▪ Designed to move from one location to
transposable elements copy and move within the genome:
another within a DNA molecule by a
process known as transposition. 1. Replicative Transposition
▪ All transposable elements code for the (Copy-and-Paste Mechanism):
enzyme transposase, the enzyme
responsible allowing transposition to occur,
and have short inverted repeats (IRs) at  The transposable element creates a copy of
each end. itself at a new genomic location while
leaving the original element intact at its
original site. This mechanism increases the
overall number of transposable elements
within the genome.
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Kinds of Transposition Transformation
▪ New genes are acquired directly from the
environment often recombines with genes on
2. Non-replicative or Conservative bacterial chromosome
Transposition (Cut-and-Paste ▪ Requirement:
Mechanism) ▪ Donor cell – lysed and released naked DNA to
environment
 In non-replicative transposition, the ▪ Recipient cell – must be in a state of competence
transposable element is physically ▪ Natural competence
moved from one location to another
▪ genetically predisposed to be able to uptake
without creating a copy. This mechanism foreign DNA
can lead to the loss of the original element ▪ Artificial competence
from its original site. ▪ May be induced in the laboratory
▪ Heat shock and electroporation
 Once inside the cell, the DNA must be incorporated into the bacterial chromosome by RecA, for the genes
to be expressed.

How does bacterial transformation work in the laboratory?
Why transform bacteria?
Definition of terms:
Restriction enzymes - cleaves 1) to make multiple copies of DNA called DNA cloning
DNA sequences at sequence-
specific sites, producing DNA 2) to make large amounts of specific human proteins, for example human
fragments with a known insulin, which can be used to treat people with Type I diabetes.
sequence at each end
Ligase - a DNA-joining enzyme

3) to genetically modify a bacterium or other cell
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Bacteriophage Classified into two major groups: Virulent and Temperate
Transduction
 Transfer of genes from a donor to a
recipient by a bacteriophage
(replicating virus)
 Does not require physical contact
between the cell donating the DNA
and the cell receiving the DNA (which
occurs in conjugation)

 There are two different types of transduction:
generalized transduction and specialized transduction.

Bacteriophage Bacteriophages are viruses that infect bacteria. Bacteriophages may have a lytic
cycle or a lysogenic cycle, and a few viruses are capable of carrying out both.
Generalized transduction
In generalized transduction, the bacteriophages can pick up any portion of the host's genome
▪ Lytic (virulent and temperate phage) ▪ Lysogenic (temperate phage)
▪ Phage which multiply on bacteria and kill the ▪ Quiescent state in cell; does not result in  a bacterial host cell is infected with
cell by lysis at the end of the life cycle immediate lysing of the host cell. either a virulent or a temperate
▪ Viral genome will integrate with host DNA bacteriophage engaging in the lytic
and replicate along with it fairly harmlessly, cycle of replication
or may even become established as a
plasmid  During the assembly stage, random
▪ As the lysogenic cycle allows the host cell to pieces of bacterial DNA are
continue to survive and reproduce, the virus mistakenly packaged into a phage
is reproduced in all of the cell’s offspring. head, resulting in the production of
▪ The virus remains dormant until host a transducing particle
conditions deteriorate  can bind to a new bacterial host
▪ the endogenous phages (known as cell and inject their DNA inside =
prophages) become active
gene expression
▪ initiate the reproductive cycle, resulting in
lysis of the host cell
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Specialized transduction
In contrast, with specialized transduction, the bacteriophages pick up only specific Application
portions of the host's DNA.
Transduction is used to insert the genes of choices in animals and plant cells to
 Can only occur with temperate modify the genetic constituents and get the desired characteristics.
bacteriophage; lysogenic cycle
 Bacteriophage injects viral DNA inside It can be used for gene therapy. It has huge potential to cure genetic diseases.
 DNA integrates host cell chromosome forming a
It is an important tool in genetics and molecular biology research.
prophage
 When such lysogenic cell is exposed to
certain stimulus, it causes induction of
virus genome from host cell genome and
begins lytic cycle
 Induction – prophage is excised from bacterial
chromosomes
 Phage genome carries a part of bacterial DNA
(that on its sides)

Molecular Recombination
Types of Recombination
▪ In each of the cases of Horizontal Gene Transfer, the process is only
successful if the genes can be expressed by the altered cell.
▪ Thus, the donor DNA must be recombined with the recipients chromosome
Homologous Recombination
 Involves the exchange of
For the genes to be expressed, genetic material between two
similar or identical DNA
the DNA must be recombined with the
sequences, usually between
recipient’s chromosome. homologous chromosomes or
sister chromatids.
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Types of Recombination
Site-specific recombination
 DNA strand exchange takes place
between DNA segments that possess at
least a certain degree of sequence
homology but no extensive homology.
 The exchange of genetic material at
END OF PRESENTATION.
specific target sites on DNA molecules,
mediated by specific enzymes
recognizing unique DNA sequences.
 Often used by viruses to insert their
genome into the chromosomes of their
host. This type of recombination is also
used by transposable elements.