GENETIC ENGINEERING
INTRODUCTION For thousands of years people have changed the characteristics of plants and animals. For thousands of years people have changed the characteristics of plants and animals. –Through selective breeding –Through the exploitation of mutations Since breeders have been able to take advantage of naturally occurring mutations, they have dreamed of being able to artificially create mutations. Since breeders have been able to take advantage of naturally occurring mutations, they have dreamed of being able to artificially create mutations.
The ability to design new varieties of plants and animals has now become a reality through genetic engineering The ability to design new varieties of plants and animals has now become a reality through genetic engineering Genetic engineering involves the manipulation of genes within a cell or organism to bring about a change in the genetic makeup of an organism Genetic engineering involves the manipulation of genes within a cell or organism to bring about a change in the genetic makeup of an organism There are several methods of gene manipulation currently used, most of which include the removal and insertion of genetic material into organisms There are several methods of gene manipulation currently used, most of which include the removal and insertion of genetic material into organisms
GENE MAPPING One of the most important processes in gene manipulation is that of finding the location of genes on the chromosomes One of the most important processes in gene manipulation is that of finding the location of genes on the chromosomes gene mapping involves the finding of the particular location on the strand of DNA that contains the genes that control certain traits gene mapping involves the finding of the particular location on the strand of DNA that contains the genes that control certain traits The arrangement of the nitrogen bases (A,T,C,G) on the molecule of DNA determine the genetic code The arrangement of the nitrogen bases (A,T,C,G) on the molecule of DNA determine the genetic code
The process of mapping the genes on the strands of DNA involves the use of molecules that act as probes The process of mapping the genes on the strands of DNA involves the use of molecules that act as probes –The probes attach themselves to certain parts of the DNA where the nucleotides join each other –The probe looks for combinations of where the nitrogen bases join in certain sequences –Once the probe locates the nucleotides, the sequences of Adenine(A), thymine(T), Cytosine(C) and Guanine(G) can be listed in a map
Although coding is extremely complex, the code is the same in all organisms. Although coding is extremely complex, the code is the same in all organisms. –The nucleotides only pair with certain other nucleotides. –The pairing of nucleotides is the phenomena that makes genetic engineering possible.
Gene splicing Once the location of the DNA sequence has been located, scientists can use restrictiion enzymes to separate the DNA at a particular location on the gene Once the location of the DNA sequence has been located, scientists can use restrictiion enzymes to separate the DNA at a particular location on the gene Once the pieces of DNA are removed other DNA canbe spliced in or recombined with the remaining DNA Once the pieces of DNA are removed other DNA canbe spliced in or recombined with the remaining DNA –This results in recombinant DNA
–The new form of DNA will reproduce with the new characteristics of the introduced DNA The first genetic splicing was done using bacteria The first genetic splicing was done using bacteria –Bacteria has plasmids (circular shaped pieces of DNA) that float freely in the cell’s fluid –By selection the proper enzyme, scientists cut out part of the plasmid DNA and insert DNA from another organism –The DNA replicates and the new bacteria produced from the spliced DNA holds the desired characteristics
One of the first uses of gene splicing was the manufacture of human insulin One of the first uses of gene splicing was the manufacture of human insulin –Scientists isolated the DNA sequence that regulates the production of insulin –The DNA segment is spliced into the DNA of the E.coli bacteria –The bacteria carrying the DNA for insulin production reproduces and passes the capability along to the next generation
–The bacteria are produced in large quantities through a process called fermentation –When the proper number of bacteria are reproduced, they are removed from the fermentation tanks and are taken apart to retrieve the insulin produced. –The insulin is then separated, purified, and the remains of the bacteria are destroyed –This procedure provides a ready relatively inexpensive supply of insulin for those people who need it
Bacteria have become the manufacturing centers for many substances that have made the lives of humans better and more productive Bacteria have become the manufacturing centers for many substances that have made the lives of humans better and more productive –Vaccines –Hormones Bovine somatotropin (BST) Bovine somatotropin (BST) –A relatively recent agricultural innovation using genetic engineering
–A hormone composed of protein that that is produced by the animal’s pituitary gland –Helps control the production of milk by assisting the regulation of nutrients into the production of milk or fat –Supplementary BST causes the cow to produce less fat and more milk –By splicing genetic material into E. coli bacteria the hormone can be produced at relatively low cost
Tissue culture Tissue culture- the process of regenerating plants from a single cell Tissue culture- the process of regenerating plants from a single cell Through the introduction of new DNA into a single cell, a completely new plant of different genetic makeup can be grown Through the introduction of new DNA into a single cell, a completely new plant of different genetic makeup can be grown