1. Bacterial Genome & Variations

2. Bacteria allow researchers
Rapid reproduction, mutation, and genetic recombination contribute to the genetic diversity of bacteria
Bacteria allow researchers
to investigate molecular genetics in the simplest true organisms

3. The Bacterial Genome and Its Replication
The bacterial chromosome
Is usually a double stranded circular DNA molecule with few associated proteins
4.6 million base pairs
~4,400 genes compared to our 25,000
Proteins cause chromosomes to supercoil in nucleoid region
In addition to the chromosome
Many bacteria have plasmids, smaller circular DNA molecules that can replicate independently of the bacterial chromosome

4. Bacterial cells divide by binary fission
Which is preceded by replication of the bacterial chromosome
Replication starts at one replication fork only
Very quick. E. coli doubling time is 20 minutes
Replication fork
Origin of replication
Termination of replication
Figure 18.14

5. Mutation and Genetic Recombination as Sources of Genetic Variation
Since bacteria can reproduce rapidly
New mutations can quickly increase a population’s genetic diversity
Numerous spontaneous mutations ~ 9 million/day in host cell.
Spontaneous mutations do not play a big role though. More diversity comes from genetic recombination

6. Vaughn Cooper & Richard Lenski’s experiment testing whether prokaryotes evolve rapidly in response to environmental change
Established 12 populations of E.coli from a single colony
Followed populations for 3,000 days.
Performed serial dilutions each day on each population to keep cultures fresh.
Growth medium in each culture contained low levels of glucose & other vital resources (to stress out the bacteria)
Samples from each culture were taken often to compare them to the original sample’s bacteria
Results show that despite living in a minimal environment, the bacteria evolved through acquiring beneficial mutations.

7. Can bacteria acquire genes from another bacterium?
Further genetic diversity
Can arise by recombination of the DNA from two different bacterial cells
EXPERIMENT
Figure 18.15
Researchers had two mutant strains, one that could make arginine but not tryptophan (arg+ trp–) and one that could make tryptophan but not arginine (arg trp+). Each mutant strain and a mixture of both strains were grown in a liquid medium containing all the required amino acids. Samples from each liquid culture were spread on plates containing a solution of glucose and inorganic salts (minimal medium), solidified with agar.
Mutant strain arg+ trp–
Mixture
Mutant strain arg-- trp+

8. Mutant strain arg+ trp– Mutant strain arg– trp+
Only the samples from the mixed culture, contained cells that gave rise to colonies on minimal medium, which lacks amino acids.
RESULTS
Colonies grew
Mutant strain arg+ trp–
Mutant strain arg– trp+
No colonies (control)
Mixture
Because only cells that can make both arginine and tryptophan (arg+ trp+ cells) can grow into colonies on minimal medium, the lack of colonies on the two control plates showed that no further mutations had occurred restoring this ability to cells of the mutant strains. Thus, each cell from the mixture that formed a colony on the minimal medium must have acquired one or more genes from a cell of the other strain by genetic recombination.
So how did this happen?
CONCLUSION
arg+ trp+ cells

9. Mechanisms of Gene Transfer and Genetic Recombination in Bacteria
Three processes bring bacterial DNA from different individuals together
Transformation
Transduction
Conjugation

10. Transformation Transformation
Is the alteration of a bacterial cell’s genotype and phenotype by the uptake of naked, foreign DNA from the surrounding environment
The “Thank you very much” method of genetic recombination
Remember Griffith’s transforming S & R pneumonia bacteria

11. Transduction In the process known as Transduction
Phages carry bacterial genes from one host cell to another

12. Generalized vs Specialized Transduction
Specialized occurs with temperate phages that integrate genome as prophages.
Generalized

13. Conjugation and Plasmids
Conjugation aka: bacterial “sex”
Is the direct transfer of genetic material between bacterial cells that are temporarily joined
One way transfer: F+ male(donor) with F factor gene to F- female (recipient)
Figure 18.17
Sex pilus or mating bridge
1 m

14. Conjugation and transfer of an F plasmid from an F+ donor to an F recipient
Figure 18.18a
A cell carrying an F plasmid is F+ cell) can form a mating bridge with an F– cell and transfer its F plasmid.
A single strand of F plasmid breaks at a specific point (tip of blue arrowhead) and begins to move into the recipient cell. As transfer continues, the donor plasmid rotates(red arrow). 2
DNA replication occurs inboth donor and recipient cells, using the single parental strands of the F plasmid as templates to synthesize complementary strands. 3
The plasmid in the recipient cell circularizes. Transfer and replication result in a compete F plasmid in each cell. Thus, both cells are now F+. 4
F Plasmid
Bacterial chromosome
Bacterial chromosome
F+ cell
Mating bridge 1
Conjugation and transfer of an F plasmid from an F+ donor to an F– recipient
F– cell

17. How do bacteria “acquire” resistance to antibiotics?
Mutation in a chromosomal gene of the bacterium can make it antibiotic resistant
Mutation might alter the intracellular target protein the antibiotic would have worked on
Mutation might not allow bacteria to take up the antibiotic into its cell in the first place. Its cell wall may be altered to resist it.
“Resistant genes” which code for enzymes that destroys or hinders antibiotic effectiveness
Resistance genes are usually located on a plasmid

18. R plasmids and Antibiotic Resistance
Confer resistance to various antibiotics