Reverse genetics on a non-model organism

1. Reverse genetics on a non-model organism

2. Reverse genetics • Gene in hand. What’s its function?

3. Thiomicrospiras JANNASCH (H.W.), WIRSEN (C.O.), NELSON (D.C.) and ROBERTSON (L.A.): Thiomicrospiracrunogena sp. nov., a colorless, sulfur-oxidizing bacterium from a deep-sea hydrothermal vent. Int. J. Syst. Bacteriol., 1985, 35, 422-424.

4. Genetically manipulating a nonmodel organism • Competence? • Conjugation? • What works on the relatives?

5. Genetically manipulating a nonmodel organism • Take a comprehensive EKS approach • Competence • Electroporation • Buffers, voltages, growth stage • Chemical competence • Buffers, growth stage, heat shock conditions • Natural competence • Growth stage • Vector • Conjugation • Mating with E. coli = success! • pRL27 for random mutagenesis • pLD55 for site-directed mutagenesis

6. Things to tweak for mating • Growth stage of recipient cells • Exponential, stationary? • Mating medium • FW heterotroph + SW lithoautotroph= TLA? • TASW + LB, 30oC • Mating interval (o/n) • Recovery interval (o/n) • Strength of initial counterselection • Antibiotic conc’n

7. Functional genomics projectMicrobial physiology (MCB 4404L) • Seniors • 50 students (2X25) • Bio/Microbio/BMS majors • 2 student assistants (volunteers from class)

8. Our system: Thiomicrospiracrunogena Chemolithoautotroph *requirements for growth: O2, thiosulfate, CO2, ammonia or nitrate, phosphate Motile 14 methyl-accepting chemotaxis protein (MCP) genes *14 ‘noses’ to sense nutrients or toxins *what does each MCP detect????

9. Steps to find what each MCP detects • Characterize chemotaxis in wild-type • Make 14 mutant strains • Screen the phenotype of the mutant strains • Write this up in a lab report.

10. 1. Characterize chemotaxisin wild-type T. crunogena • We tested for chemotaxis toward: • High O2 • Low O2 • Thiosulfate • Phosphate • Nitrate • Ammonia • Bicarbonate

11. Chemotaxis assay Cell suspension Chemotaxissolution

12. 2. Make 14 mutant strains, each with one of its methyl-accepting chemotaxis genes interrupted

13. 2. Making 14 MCP mutant strains using site-directed mutagenesis 2. Ligate PCR product intoworkhorse plasmid (pRC3.1); TCCE Amplify target genesfrom T. crunogenagDNAvia PCR 3. Subject plasmid to Tn5-mediatedmutagenesis in vitro; TCCE 7. Mate into T. crunogena 4. Screen clones for Tn5-interruptedtarget gene 5. Amplify interrupted target genes via PCR 6. Ligate interrupted genesinto mating plasmid (pLD55); TCCE

14. E. coli T. cruno E. coli T. cruno • E. coli (blue) carrying a plasmid (black), which carries a plasmid that contains a methyl-accepting chemotaxis gene interrupted by a transposon(yellow) that contains a kanamycin resistance gene (red), is mated with T. crunogena (pink) RecA 2. The transposon (yellow) cannot hop off the plasmid, as this plasmid does not express a transposase enzyme. Instead, the RecA protein catalyzes homologous recombination between the mutated gene on the plasmid and the wild-type gene on the chromosome, conferring kanamycinresistance on the recipient cell.

15. Second selection to remove wt copy • Fusaric acid to impair TetR cells • Selects for double recombinants

16. 3. Screening the phenotype of the 14 MCP mutant strains • Redo the chemotaxis assay, but use the mutant strains of T. crunogenainstead of wild-type • Does chemotaxis change in any of the mutants? • Can we correlate a nutrient to a particular MCP?

17. Next semester • Pick up where we left off • Mate into T. crunogena • See if chemotaxis behavior changes • Functional complementation in E. coli