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Introduction to Southern Hybridization. Michael Melzer Plant & Environmental Protection Sciences University of Hawaii at Manoa. Outline. History/Background Info Goals of Southern hybridization Example Other applications. History/Background.
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Introduction to Southern Hybridization Michael Melzer Plant & Environmental Protection Sciences University of Hawaii at Manoa
Outline • History/Background Info • Goals of Southern hybridization • Example • Other applications
History/Background • ‘Southern’ hybridization named after Sir Edwin Southern • Developed in 1975 • One of the most highly cited scientific publications • Earned Sir Southern a Lasker Award in 2005
History/Background • Spawned naming of related techniques: Northern blot (RNA) Western blot (Protein) Eastern blot (???) Southern blot (DNA)
Goals of Southern Hybridization • Immobilize DNA onto a permanent substrate • Identify DNA sequence (gene) of interest
2 copies of gene X Example – Looking for Gene X Arabidopsis thaliana
extract DNA ? copies of gene X Example – Looking for Gene X Capsella rubella
Step 1. Restriction Enzyme Digestion EcoR I EcoR I EcoR I EcoR I
_ + Step 2. Gel Electrophoresis
Goals of Southern Hybridization Immobilize DNA onto a permanent substrate • ‘Membrane’ • paper-like matrix • nylon or nitrocellulose • usually has a slight positive charge
A C T T G A T G A A C T Step 3. DNA Denaturation • Eliminate hydrogen bonds with sodium hydroxide (NaOH)
Step 4. Transfer DNA to Membrane • Two methods for transferring DNA to a membrane • capillary • electrophoretic
Goals of Southern Hybridization • Immobilize DNA onto a permanent substrate • Identify DNA sequence (gene) of interest
Step 5. Making a Probe • A probe is a small (25-2000 bp) length of DNA or RNA • Complementary to the sequence (gene) of interest • Labeled for subsequent detection procedures
2 copies of gene X Step 5. Making a Probe Arabidopsis thaliana
Step 5. Making a Probe Gene X from Arabidopsis Partial or full-length probes by PCR
Step 5. Making a Probe Gene X from Arabidopsis Partial probes by random-priming
Step 5. Making a Probe Denature template with heat
Step 5. Making a Probe Add random primers
Step 5. Making a Probe Extend random primers with polymerase
Step 5. Making a Probe A probe complementary to the sequence (Gene X) of interest!
Step 5. Making a Probe • How do we detect the probe? • Radioactivity (α32P)
Step 5. Making a Probe • How do we detect the probe? • Digoxigenin (DIG) U
Step 6. Pre-hybridization Prehybridization buffers contain ‘blocking reagents’ that occupy available binding sites on the membrane
Step 12. Detection • DIG-labeled probes emitting minute amounts of light (chemiluminescence) • 32P-labeled probes emitting ß-particles
Step 12. Detection • DIG-labeled probes emitting minute amounts of light (chemiluminescence) • 32P-labeled probes emitting ß-particles • Autoradiography film can detect this radiation
Conclusion • How many copies of ‘Gene X’ does Capsella rubella possess? 3 Capsella rubella
Other Applications • DNA fingerprinting • RFLP or VNTRs • Dot or slot blot • Colony or plaque lifts • Microarray analysis
Other Applications • DNA fingerprinting • RFLP or VNTRs • Dot or slot blot • Colony or plaque lifts • Microarray analysis
Other Applications • DNA fingerprinting • RFLP or VNTRs • Dot or slot blot • Colony or plaque lifts • Gene expression
Other Applications • DNA fingerprinting • RFLP or VNTRs • Dot or slot blot • Colony or plaque lifts • Gene expression
Other Applications • Microarray technology