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Cloning into Plasmids

Cloning into Plasmids. Restriction Fragment Cloning & PCR Cloning by the Topo TA ™ Method. Cloning Vectors. The molecular analysis of DNA has been made possible by the cloning of DNA. The two molecules that are required for cloning are the DNA to be cloned and a cloning vector.

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Cloning into Plasmids

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  1. Cloning into Plasmids Restriction Fragment Cloning & PCR Cloning by the Topo TA™ Method

  2. Cloning Vectors • The molecular analysis of DNA has been made possible by the cloning of DNA. The two molecules that are required for cloning are the DNA to be cloned and a cloning vector. • Cloning vector - a DNA molecule that carries foreign DNA into a host cell, replicates inside a bacterial (or yeast) cell and produces many copies of itself and the foreign DNA • Three features of all cloning vectors • sequences that permit the propagation of itself in bacteria (or in yeast for YACs) • a cloning site to insert foreign DNA; the most versatile vectors contain a site that can be cut by many restriction enzymes • a method of selecting for bacteria (or yeast for YACs) containing a vector with foreign DNA; uually accomplished by selectable markers for drug resistance

  3. Types of Cloning Vectors • Plasmid - an extrachromosomal circular DNA molecule that autonomously replicates inside the bacterial cell; cloning limit: 100 to 10,000 base pairs or 0.1-10 kilobases (kb) • Phage - derivatives of bacteriophage lambda; linear DNA molecules, whose region can be replaced with foreign DNA without disrupting its life cycle; cloning limit: 8-20 kb • Cosmids - an extrachromosomal circular DNA molecule that combines features of plasmids and phage; cloning limit - 35-50 kb • Bacterial Artificial Chromosomes (BAC) - based on bacterial mini-F plasmids. cloning limit: 75-300 kb • Yeast Artificial Chromosomes (YAC) - an artificial chromosome that contains telomeres, origin of replication, a yeast centromere, and a selectable marker for identification in yeast cells; cloning limit: 100-1000 kb

  4. General Steps of Cloning with Any Vector • prepare the vector and DNA to be cloned by digestion with restriction enzymes to generate complementary ends (exception Topo cloning see later slides) • ligate the foreign DNA into the vector with the enzyme DNA ligase • introduce the DNA into bacterial cells (or yeast cells for YACs) by transformation • select cells containing foreign DNA by screening for selectable markers (usually drug resistance)

  5. Restriction & Ligation

  6. Insertion of Restriction Fragment into Vector Multi Cloning Site

  7. The pUC 18 or 19 Cloning Vector Lac Z α RE Sites in blue occur only once in the plasmid

  8. Transformation and Selection White White Blue Dead Screening

  9. The Topo TA PCR Cloning Vector

  10. Features of Topo Vector • EcoR I sites flanking the PCR product insertion site for easy removal of inserts • Kanamycin and ampicillin resistance genes for your choice of selection in E. coli • Easy blue/white screening of recombinant colonies • Promoter/priming sites for in vitro transcription

  11. The Topo TA Cloning Process

  12. Why Are We Topo Cloning? • PCR generates the exact gene fragment we want to clone. • PCR products and no other DNA are ligated into the Topo vector by the topoisomerase. • Ligation is highly efficent (as high as 90%). • Selection of transformants is highly effiecient • A very large number of white colonies is generated

  13. Generating Riboprobes T7 Bacteriophage RNA polymerase can be used to transcribe the insert in the leftward direction to make single stranded RNA. The strand which is copied (template strand) depends on the orientation of the insert. We will need to restriction map our plasmid s to determine the orientation of the insert. Since insertion is random. Both orientations should be represented in our clone population. We need to select plasmids which will generate RNA which is complimentary to the mRNA we are attempting to localize by in situ hybridization.

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