Microbial Genetics Lecture Notes PDF

Summary

This document is a lecture about Microbial Genetics, covering topics such as the structure and function of the genome, the central dogma, genetic regulation, and different types of bacterial genetic processes. The document includes diagrams and figures to illustrate concepts.

Full Transcript

Microbial Genetics

Instructions for building microbes
Introduction to Genetics and Genes

Genetics: The study of
heredity that explores:
– The transmission of
biological properties
(traits) from parents to
offspring
– The expression and
variation of those traits
– The structure and function
of genetic material
– How this material changes
Introduction to Genetics and Genes
 Structure and
Function of the Genome
The Levels of Structure
and Function of the Genome
Genome:
– The sum total of genetic
material of an organism
– Most exists in the form of
chromosome(s)
Prokaryotes (usually) have one
large circular chromosome
Eukaryotes have multiple linear
chromosomes
– Some may appear in non-
chromosomal sites
Plasmids: tiny extra pieces of
DNA
Eukaryotic organelles:
mitochondria and chloroplasts
– Genomics – study of structure,
function, evolution and
mapping of genomes
The Levels of Structure
and Function of the Genome
Genes: basic informational
packets
– Classical genetics: a
functional unit of heredity
– Molecular and biochemical
genetics: site on the
chromosome that provides
information for a certain cell
function
– Preferred definition: a
segment of DNA that contains
the necessary code to make a
protein or an RNA
 The Levels of Structure
and Function of the Genome
Genotype:
– the sum of all types of
genes constituting an
organism’s distinctive
genetic makeup

Phenotype:
– the expression of the
genotype that creates
certain structures or
functions
The DNA Code:
A Simple Yet Profound Message
Basic unit of DNA is a
nucleotide:
– Phosphate
– Deoxyribose sugar
– Nitrogenous base (A, C, G,
T)
Antiparallel arrangement:
– One side of the helix runs
in the opposite direction of
the other:
5’ to 3’ in one direction and
3’ to 5’ in the other
direction
– Significant factor in DNA
synthesis and protein
production
The Central Dogma is an oversimplification

The “central dogma” of
genetics:
– Transcription: DNA is
used to synthesize RNA
– Translation: RNA used to
produce proteins
The “central dogma” is
oversimplified.
– A wide variety of RNAs are
used to regulate gene
function
– The DNA that codes for these
crucial RNA molecules was
once called “junk” DNA.
The Master Genetic Code
The Master Genetic Code

This genetic code is (virtually) universal – what are the
implications of this for research, GMOs, cloning, etc.?
What are the implications for viral diseases
Genetic Regulation of Protein Synthesis

Operons:
– Found only in bacteria and archaea
– Coordinated set of genes regulated as a
single unit
– Can be inducible or repressible
A Repressible Operon

Repressible operons
are usually in the on
mode
Will only be turned off
when synthesis is no
longer required
Excess product serves
as a corepressor to
block the action of the
operon
Generally anabolic genes
An Inducible Operon
The lac operon is
inducible
– Regulator: composed of
the gene that codes for the
repressor, a protein
capable of repressing the
operon
– Control locus:
Promoter: recognized by
RNA polymerase
Operator: acts as an on/off
switch for transcription
– Structural locus: made
up of three genes, each
coding for a different
enzyme needed to
catabolize lactose
The Lac Operon
The repressor protein is
allosteric:
– Binding sites for the
operator sequence on
the DNA and lactose
– In the absence of
lactose, the repressor
binds to the operator,
blocking transcription of
structural genes
– The regulator gene lies
upstream of the operator
and is transcribed
constitutively
Alterations in growth – external perturbations

Normal growth can be
altered by changes to
the growth
environment
– Addition of antibiotics
– New media
– Different media
– Change in carbon source
utilized
DNA Recombination Events
Recombination:
– An event in which one bacterium donates DNA to
another bacterium
– The end result is a strain different from both the
donor and the recipient strain
– Plasmids: extrachromosomal DNA that is
transferable between cells
– Recombinant: any organism that contains and
expresses genes that originated in another
organism
Conjugation: Bacterial “Sex”
Transformation – capturing DNA from the
environment
Transformation discovered
through an elegant
experiment conducted in
the 1920s by Frederick
Griffith.
– Worked with encapsulated
and non-encapsulated
Streptococcus pneumoniae
and laboratory mice
– Encapsulated strains have a
smooth (S) colony
appearance
– Strains lacking a capsule have
a rough (R) appearance
Transformation – capturing DNA from the
environment

Transformation:
– The acceptance by a
bacterial cell of small
fragments of soluble
DNA from the
surrounding
environment
– Competent: cells that
are capable of accepting
genetic material through
transformation
When might transformation be advantageous?
When might it be detrimental?
Transformation
Transduction

Transduction:
– The process by which
bacteriophage serve as a
carrier of DNA from a donor
cell to a recipient cell
– DNA is packaged into viral
particles during assembly
– Occurs in a broad spectrum of
bacteria

The participating bacteria in a
single transduction event must
be the same species or closely
related – Why?
Transposable Elements
“Jumping genes” shift from one
part of the genome to another
Also called Transposons (Tn)
First proposed by Barbara
McClintock in 1951
Jumping genes are
widespread among cells and
viruses
Can carry antibiotic resistance
genes or virulence factors
Often carry transposase
enzyme that facilitates moving
around genome
 Mutations:
Changes in the Genetic Code
Mutation:
– Any change to the nucleotide sequence in the genome
– The driving force of evolution
– In microorganisms, mutations become evident in
altered gene expression
Altered pigment production
Development of resistance to a drug
Gain/loss of virulence, etc.
Wild type – unmutated organism present in the
highest numbers in a population
Different types of point mutations
Causes of Mutations

Spontaneous
mutation:
– A random change in
the DNA arising from
errors in replication
that occur randomly
Induced mutations:
– Result from exposure
to known mutagens
Repair of Mutations

Mismatch repair:
– A repair system can locate
mismatched bases that
were missed during
proofreading
– The base must be replaced
soon after the mismatch is
made, or it will not be
recognized by the repair
enzymes

What happens if a
mutation is not fixed?
Pathogenicity Islands

Have the ability to make
their hosts pathogenic.
– Contain multiple genes
that are coordinated to
create a new trait on the
bacterium
– Often flanked by
insertion sequences, and
carry mobility genes
– Different G+C content
from rest of
chromosome
Comparative genomics

Many mutations are not
repaired
Mutations are
permanent and
heritable
A small number of
mutations contribute to
the success of the
individual
Large accumulations of
mutations over time
lead to new strains with Inner ring = E. coli O157:H7 strain EC4115
vastly different niches Dark blue = Shigella spp.
and pathogenic Outermost three ring = E. fergusonii, E. albertii, and
Salmonella enterica
potentials All other tings = other E. coli strains