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Recombinant dna molecules

Plasmids with foreign DNA inserted into them are called recombinant DNA    molecules because they are created artificially and do not occur in nature. They are also called chimeric molecules because the origin of different parts of the molecules can be traced back to different species of biological organisms or even to chemical synthesis. Proteins that are expressed from recombinant DNA molecules are called recombinant proteins . Not all recombinant plasmids are capable of expressing genes. The recombinant DNA may need to be moved into a different vector (or host) that is better designed for gene expression. Plasmids may also be engineered to express proteins only when stimulated by certain environmental factors, so that scientists can control the expression of the recombinant proteins.

Art connection

Figure illustrates the steps in molecular cloning into a plasmid called a cloning vector. The vector has a lacZ gene, which is necessary for metabolizing lactose, and a gene for ampicillin resistance. Within the lacZ gene are restriction sites, sequences of DNA cut by a particular restriction enzyme. The DNA to be cloned and the plasmid are both cut by the same restriction enzyme. The restriction enzyme staggers the cuts on the two strands of DNA, such that each strand has an overhanging single-stranded bit of DNA. On one strand, the sequence of the overhang is GATC, and on the other, the sequence is CTAG. These two sequences are complementary, and allow the fragment of foreign DNA to anneal with the plasmid. An enzyme called ligase joins the two pieces together. The ligated plasmid is then transformed into a bacterial strain that lacks the lacZ gene and is sensitive to the antibiotic ampicillin. The bacteria are plated on media containing ampicillin, so that only bacteria that have taking up the plasmid (which has an ampicillin resistance gene) will grow. The media also contains X-gal, a chemical that is metabolized in the same way as lactose. Plasmids lacking the insert are able to metabolize X-gal, releasing a dye from X-gal that turns the colony blue. Plasmids with the insert have a disrupted lacZ gene and produce white colonies. Thus, colonies containing the cloned DNA can be selected on the basis of color.
This diagram shows the steps involved in molecular cloning.

You are working in a molecular biology lab and, unbeknownst to you, your lab partner left the foreign genomic DNA that you are planning to clone on the lab bench overnight instead of storing it in the freezer. As a result, it was degraded by nucleases, but still used in the experiment. The plasmid, on the other hand, is fine. What results would you expect from your molecular cloning experiment?

  1. There will be no colonies on the bacterial plate.
  2. There will be blue colonies only.
  3. There will be blue and white colonies.
  4. The will be white colonies only.

View an animation of recombination in cloning from the DNA Learning Center.

Cellular cloning

Unicellular organisms, such as bacteria and yeast, naturally produce clones of themselves when they replicate asexually by binary fission; this is known as cellular cloning    . The nuclear DNA duplicates by the process of mitosis, which creates an exact replica of the genetic material.

Reproductive cloning

Reproductive cloning is a method used to make a clone or an identical copy of an entire multicellular organism. Most multicellular organisms undergo reproduction by sexual means, which involves genetic hybridization of two individuals (parents), making it impossible for generation of an identical copy or a clone of either parent. Recent advances in biotechnology have made it possible to artificially induce asexual reproduction of mammals in the laboratory.

Parthenogenesis, or “virgin birth,” occurs when an embryo grows and develops without the fertilization of the egg occurring; this is a form of asexual reproduction. An example of parthenogenesis occurs in species in which the female lays an egg and if the egg is fertilized, it is a diploid egg and the individual develops into a female; if the egg is not fertilized, it remains a haploid egg and develops into a male. The unfertilized egg is called a parthenogenic, or virgin, egg. Some insects and reptiles lay parthenogenic eggs that can develop into adults.

Sexual reproduction requires two cells; when the haploid egg and sperm cells fuse, a diploid zygote results. The zygote nucleus contains the genetic information to produce a new individual. However, early embryonic development requires the cytoplasmic material contained in the egg cell. This idea forms the basis for reproductive cloning. Therefore, if the haploid nucleus of an egg cell is replaced with a diploid nucleus from the cell of any individual of the same species (called a donor), it will become a zygote that is genetically identical to the donor. Somatic cell nuclear transfer is the technique of transferring a diploid nucleus into an enucleated egg. It can be used for either therapeutic cloning or reproductive cloning.

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Source:  OpenStax, Genetics and evolution. OpenStax CNX. Aug 07, 2014 Download for free at https://legacy.cnx.org/content/col11595/1.2
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