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Chromosome mapping in bacteria

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Presentation on theme: "Chromosome mapping in bacteria"— Presentation transcript:

1 Chromosome mapping in bacteria

2 Bacterial colonies, each derived from a single cell

3 Mixing bacterial genotypes produces rare recombinants

4 Mixing bacterial genotypes produces rare recombinants

5 Hayes Experiment Conjugation between two auxotrophic strains A y B
Streptomycin: antibiotic “kill” bacteria, but it does not destroy them Conclusion: both strains do not have the same role Strain A: donor, with fertility factor F Strain B: receptor, it must survive

6 F plasmids transfer during conjugation
Integration of the F plasmid creates an Hfr strain Isolated by Hayes y Cavalli-Sforza from strains F+ Transfer gene frequency 1000 times higher than F+ Do not transfer plasmid/fertility Hfr (High Frequency of Recombinants) Integration of the F plasmid F in the chromosome

7 The “blender” experiment” Wollman y Jacob, 1957
Mating Hfr aziR tonR lac+ gal+ StrS F- aziS tonS lac- gal- StrR Each phenotype number is counted in every sample (exconjugants) Colony number goes up as the sample extraction time

8 The F integration site determines the order of gene
transfer in HFRs

9 Two types of DNA transfer can take place during conjugation

10 A single crossover cannot produce a viable recombinant
Figure 5-16

11 The generation of various recombinants by crossing over in
different regions

12 Faulty outlooping produces F´, an F plasmid that contains
chromosomal DNA

13 Bacteria exchange DNA by several processes

14 Cycle of a phage that lyses the host cells

15 Transduction Lederberg y Zinder (1951) Experiments on Salmonella
Transfer of genes between two strains without contact If filter pore size was smaller than a virus, transfer did not take place

16 Generalised transduction by random incorporation of bacterial
DNA into phage heads

17 Frequency of cotransduction
Donor: leu+ thr+ azir It is infected by the phage. Phage lysate collected removing surviving donor bacteria Used to infect receptor bacteria Receptor: leu– thr– azis One of the markers (phenotypes) is selected Then, checked colony phenotypes for the other genes Fcotransductionleu-azi = nº colonies leu+ azi+ nº colonies leu+ Selected marker Unselected markers 1 leu % azir, 2% thr+ 2 thr % leu+, 0% azir 3 leu+ y thr+ 0% azir

18 Cotransduction map Frequency of cotransduction: frequency of colonies showing the selected marker and one of the not selected markers The closer two genes are to each other, the more likely they are to be transducted by the same transductant particle Cotransduction frequency is an inverse measure of distance La FC es mayor entre thr-leu que entre thr-azi thr thr leu azi 2/3 50

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