1 / 30

Separating DNA Molecules: Gel Electrophoresis and the Southern Blot

Separating DNA Molecules: Gel Electrophoresis and the Southern Blot. Electrophoresis involves separating molecules based on electrical charge, size, and shape Gel electrophoresis allows scientists to isolate DNA of interest. Gel Electrophoresis. Figure 8.7a. Gel Electrophoresis. Figure 8.7b.

eve-vinson
Download Presentation

Separating DNA Molecules: Gel Electrophoresis and the Southern Blot

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Separating DNA Molecules: Gel Electrophoresis and the Southern Blot • Electrophoresis involves separating molecules based on electrical charge, size, and shape • Gel electrophoresis allows scientists to isolate DNA of interest

  2. Gel Electrophoresis Figure 8.7a

  3. Gel Electrophoresis Figure 8.7b

  4. Gel Electrophoresis • DNA has negative charge; drawn by electric current toward positive electrode • Agarose makes up gel; acts as molecular sieve • Smaller fragments migrate faster and further than larger ones • Determine size by comparing distance migrated to that of standards and constructing standard curve

  5. Southern Blot • DNA transferred from gel to nitrocellulose membrane • Probes used to localize DNA sequence of interest • Northern blot – used to detect RNA • Uses of Southern blots • Genetic “fingerprinting” • Diagnosis of infectious disease • Demonstrate incidence and prevalence of organisms that cannot be cultured

  6. Southern Blot Figure 8.8

  7. DNA Microarrays • Consists of molecules of single stranded DNA immobilized on glass slides, silicon chips, or nylon membranes • Single stranded, fluorescently-labeled DNA washed over an array will adhere only at locations on the array where there are complementary DNA sequences • Scientists use DNA microarrays for various uses • Monitoring gene expression • Diagnosis of infection • Identification of organisms in an environmental sample

  8. Inserting DNA into Cells • Goal of DNA technology is insertion of DNA into cell (transformation) • Can use vectors and natural methods of transformation, transduction, and conjugation • Artificial methods • Electroporation • Protoplast fusion • Injection – gene gun and microinjection

  9. Inserting DNA into Cells Figure 8.10a-c

  10. Inserting DNA into Cells Figure 8.10d

  11. Applications of Recombinant DNA Technology • Genome Mapping • Locating genes • Nucleotide sequencing

  12. Genome Mapping • Locating genes on a nucleic acid molecule • Provides useful facts concerning metabolism, growth characteristics, and relatedness to others

  13. Locating Genes by Restriction Fragmentation Figure 8.11

  14. Nucleotide Sequencing Figure 8.12

  15. Uses of Genome Mapping • Drug development • Vaccine development • Relate DNA sequence data to protein function

  16. Applications of Recombinant DNA Technology • Pharmaceutical and Therapeutic Applications • Protein synthesis • Vaccines • Genetic screening • DNA fingerprinting • Gene therapy • Medical diagnosis • Xenotransplants

  17. Protein Synthesis • Creation of synthetic peptides for cloning

  18. Vaccines • Production of safer vaccines • Subunit vaccines (pathogen’s antigen) • Introducing genes of pathogens into common fruits and vegetables • Injecting humans with plasmid carrying gene from pathogen; humans synthesize pathogen’s proteins • Clinical trials promising for vaccine against malaria

  19. Genetic Screening • DNA microarrays used to screen patients, prospective parents, and fetuses for inherited disease caused by mutations • Can also identify pathogen’s DNA in blood or tissues • HIV

  20. DNA Fingerprinting Figure 8.13

  21. Gene Therapy • Missing or defective genes replaced with normal copies • Some patients’ immune systems reacted negatively • Successfully treated patients with severe combined immunodeficiency disease • Others that may respond well – cystic fibrosis, sickle cell anemia, some types of hemophilia, some types of diabetes

  22. Medical Diagnosis • PCR, fluorescent genetic probes, and DNA microarrays are used for diagnostic applications • Patient specimens can be examined for the presence of gene sequences unique to certain pathogens • HIV, hepatitis virus, …

  23. Xenotransplants • Animal cells, tissues, or organs introduced into human body • Theoretically feasible to insert human genes into animals to direct them to produce organs and tissues for transplantation into humans

  24. Applications of Recombinant DNA Technology • Agricultural applications • Herbicide resistance • Salt tolerance • Freeze resistance • Pest resistance • Improvements in nutritional value and yield • BGH • Transgenic organisms – recombinant plants and animals altered by addition of genes from other organisms

  25. Ethics and Safety of Recombinant DNA Technology • Supremacist view – humans are of greater value than animals • Long-term effects of transgenic manipulations are unknown • Unforeseen problems arise from every new technology and procedure • Natural genetic transfer could deliver genes from transgenic plants and animals into other organisms • Transgenic organisms could trigger allergies or cause harmless organisms to become pathogenic

  26. Ethics and Safety of Recombinant DNA Technology • Studies have not shown any risks to human health or environment • Standards imposed on labs involved in recombinant DNA technology • Can create biological weapons using same technology

  27. Ethics and Safety of Recombinant DNA Technology • Ethical issues • Routine screenings? • Who should pay? • Genetic privacy rights? • Profits from genetically altered organisms? • Required genetic screening? • Forced correction of “genetic abnormalities?”

More Related