Bacterial Genetics PDF

Summary

These notes cover bacterial genetics, outlining the molecular structure of DNA, DNA replication processes in bacteria, the relationship between genotype and phenotype, and different pathways of inter-bacterial gene transfer. It also discusses the role of plasmids and bacteriophages in bacterial genomes and their influence on microbial structures and functions. The notes present basic concepts of bacterial genetics.

Full Transcript

Bacterial genetics

Samanthika Jagoda, BVSc (Perad), MVM (Massey), PhD (Tokyo)
 Learning Objectives
On completion of the course, the student should be able to:

Describe the molecular structure of DNA, including base
pairing and 5’→ 3’orientation

Describe the process of DNA replication in a bacterial cell

Explain the relationship between genotype and phenotype

Describe the different pathways through which the inter-
bacterial gene transfer is materialized and how genetic
variation can influence microbial structures and their
functions
 Genetics: Manipulation of DNA to study
cellular and organismal functions
 Genetic information in bacteria is encoded in
DNA

All of the DNA found in a bacterial cell is
collectively referred to as bacterial genome
 Bacterial genome

1. Chromosome
2. Plasmids
3. Bacteriophage DNA
Bacteriophage DNA
1. Bacterial chromosome
Small, circular, double stranded DNA
Located in the cytoplasm - floating freely
Self replicating
Size may vary -less than 5Mb
Most bacteria are HAPLOID – single chromosome
per cell (one copy of each gene)
Exceptions: e.g Vibrio cholerae – 2 chromosomes
*HW
 Chromosome is supercoiled and tightly
packaged in the bacterial nucleoid
Total length – 1mm
(1000 times larger than the entire cell)
Core genome Accessory genome
Genes located on the Genes located on the
chromosome plasmids and
bacteriophages

The subset of genes Genes that are variably
that are present in all present among individual
genomes genomes

Offer a selective advantage
to the bacterial cell/not
Essential for normal essential for viability
survival of the e.g encodes for resistance to
bacterium antibiotics, proteins inhibitory to
other bacteria, virulence factors –
toxins, capsule, attachment
proteins
2. Plasmids

Extrachromosomal genetic elements

Closed, circular, double stranded DNA

Located in the cytoplasm, much smaller than the
chromosome (vary from 5 to 500 kb in size)

Can replicate independently of the chromosome

Mobile - can move between bacteria of the same or
different species ( a mobile genetic element)
 Plasmids encode traits that are not essential for bacterial
viability

Control pathogenic properties
resistance to antibiotics
production of toxins
synthesis of cell surface structures required for
adherence or colonization

Virulence factors encoded by plasmids
tetanus toxin of Clostridium tetani -Tetanus
Capsule of Bacillus anthracis - Anthrax
3. Bacteriophages (bacterial viruses/phages)
extrachromosomal genetic material
Phage genomes vary in size (2 to 200 kilobases
per strand)
Consist of double-stranded DNA or single-
stranded DNA
Encodes for exotoxins
e.g Phage CTX encodes cholera toxin in
Vibrio cholarae
Bacteriophages
Bacteria can acquire an accessory genome through the
horizontal transfer of genetic elements
Watson-Crick double helical structure of DNA

Complete DNA
molecule consists of
two long chains
wrapped around
each other in a
double helix

The helix has two
grooves between
the two strands
 Base Pairing

A’s pair only with T’s and G’s pair only with C’s
Each A-and-T pair and each G-and-C pair in DNA is called
a complementary base pair
 The 5′ and 3′ Ends

has a phosphate the last nucleotide lacks
attached to its 5′ a phosphate at its 3′
carbon that does not carbon. Because it has
connect it to another only a hydroxyl group
nucleotide
 Antiparallel Construction

In a DNA molecule, two chains run in opposite orientations
 Replication of bacterial DNA
Bacteria reproduce by binary fission – produce
two genetically similar daughter cells

Genetic material must replicate accurately so
that progeny inherit all of the specific genetic
determinants (the genotype) of the parental
organism
Two old strands are separated and used as templates to synthesize
new complementary strands
 Replication of the chromosome in bacteria;

begins at a specific location – origin of
chromosomal replication (oriC)

goes on at a rate of 1000 nucleotides per second
Replication begins in at one point and moves in both directions from there

The structure where the two strands are separated and the new
synthesis is occurring is referred to as the replication fork
 Replication of bacterial DNA
DNA unwind – two parent strands separate (DNA
helicase)

Each parent DNA strand acts as a template for the
synthesis of new complementary DNA strand
(DNA polymerase)

Ends of new strands are joined to form circular
chromosome ( DNA ligase)
What is a gene?

Genes are a small part of larger DNA molecules

It is the basic unit of heredity that determines a
particular characteristic or trait

Most genes are codes describing how to make
different types of protein (encode proteins)
 Bacterial genomes differ in size (0.6 to 8.0 Mb)

Usually contain DNA to encode 1000-4000
different genes

Gene density is relatively high in bacteria
(1 gene per 1.1 kilobase of DNA)

E.coli
4.6 X 106 base pairs
4126 bacterial proteins
 Gene expression

Transcription of DNA into messenger RNA and translation of
mRNA into amino acids that form protein
 We can describe any particular DNA molecule using
the first letters of these bases
eg. ATGCGCTGGTAG

This string of letters is called a DNA sequence

Each 3-nucleotide sequence, called a codon, carries
information for a specific amino acid
 The genetic code
Like DNA, proteins can be thought of as strings of letters

Instead of four bases (A, T, G, C), proteins have 20 amino
acids.
Every three bases in a gene (codon) encodes one amino acid
e.g ATG encodes the amino acid methionine
 The genetic code

There are 64 different three letter words that can be made
with a four letter alphabet
(There are 64 different codons in DNA)

The assignment of each of the possible codons to
amino acids
(correspondence between codons and amino acids)
is called the genetic code
The genetic code determines how the nucleotides in
mRNA specify the amino acids in a polypeptide
 Genotype Phenotype
(inherited genetic information) (all the observable properties of an organism)
Actual sequence of DNA of the organism

Some genetic information is expressed under defined
environmental conditions (nutrient availability)
e.g Bacillus anthracis capsule only in vivo

Both genotype and environment can influence phenotypic
expression
 Why bacteria are suitable for genetic
experiments?
Bacteria are haploid – easy to produce mutant phenotypes
Very short generation time
Multiply asexually (by cell division) -all the progeny are
genetically identical to their parent and to each other
Can be propagated in a small space – agar plate
Possible to obtain a measurable number of discrete colonies
by serial dilutions
Possible to select rare mutants by providing selective
conditions
Can be stored in a dormant state for long time
Ability to exchange DNA between strains of a bacterium
 Bacterial colonies are clones of the
original bacterium
Each colony is composed of millions of bacteria, all derived
from the original bacterium