Genetic Mutation

 

Every organism has a set of genes and half of the genes of that organism come from each parent. The combinations of the genes causes the variation of individuals within the species. The genes of a butterfly, an ape or a fowl carry the code that determines the appearance and the character of the butterfly, the ape and the fowl. The genetic code allows an overwhelming variety within the species of the kind. However, a mutation of the gene will not break through the barrier of the species or the kind. A mutation is basically a gene that has an abnormality in relation to its normal configuration. The abnormality can then be passed to successive offspring, thereby producing a marked difference. There are many different types of mutations. The smallest possible genetic mutation is a 'point-mutation'. This occurs in the DNA when the base-pairs combine with the 'wrong' partner. Multiple point-mutations are common and are found to increase substantially by the effect of mutagens. Mutations are, of course, heritable and these can extend to whole or part chromosomal mutations. Because many genes are affected by a chromosomal mutation, these often have drastic ramifications on the offspring.

Genetic mutation  may be a stronghold of science fiction and comic books, but its presence is very real, and still not always understood. At a basic level, mutation causes a gene or genetic  sequence to change from its original or intended purpose. It can be caused by a variety of internal or external sources, and the effects can be positive or negative for the organism that undergoes mutation.

There are several factors that can cause genetic mutation to occur. In the normal process of cellular division, mutation can occur when gene properties do not copy properly to the new cell. Radiation, such as that from ultraviolet sources, can also cause mutation. Radiation-caused mutation can be very dangerous, but has also been harnessed for medical use, as in treating malignant tumors. Viruses, which attack an organism on a cellular level, can also be responsible for genetic mutation.

Mutation is essential to the evolution of a species. Some genetic mutations can be beneficial to a species, serving a purpose like increasing immunity to a common disease. The introduction of mutation into a species encourages gene pool variations that can result in beneficial adaptations. Negative mutations will often be destroyed through natural selection, as weaker or less adaptable specimens are less likely to survive and pass on their detrimental genetics to another generation.

Depending on what type of cell is affected by mutation, results can be positive, negative, or neutral. Hereditary diseases, for instance, are a result of a mutated or damaged cell that passes on the mutation to each new cell it creates. Similarly, cancer is the result of malignant growth of mutated cells. However, one common mutation in humans, the CCR5 base pair, can give added resistance to some diseases including HIV.

The concept of mutation has inflamed imaginations for generations, as its potential power to change or harm humans is enormous. One popular comic book series, X-Men, takes the concept to an extreme, creating a parallel universe in which some of the population is granted super-powers due to extreme genetic mutation. While the limits of genetic mutation remain unexplored, it appears unlikely that anyone will begin sprouting horns or flying due to mutation any time soon.