What Cause Mutation and What Are Some of the Possible Results of Genetic Mutation?
By: Fonta • Research Paper • 1,835 Words • January 30, 2010 • 1,271 Views
Join now to read essay What Cause Mutation and What Are Some of the Possible Results of Genetic Mutation?
What cause mutation and what are some of the possible results of genetic mutation?
In biology, term- mutation has been described as changes to the base pair sequence of the genetic material of an organism. Mutations can be caused by: copying errors in the genetic material during cell division, by exposure to ultraviolet or ionizing radiation, chemical mutagens, or viruses, or can occur deliberately under cellular control during processes such as hypermutation. In multicellular organisms, mutations can be subdivided into germ line mutations, which can be passed on to descendants, and somatic mutations, which cannot be transmitted to descendants in animals. Plants sometimes can transmit somatic mutations to their descendants asexually or sexually (in case when flower buds develop in somatically mutated part of plant). A new mutation that was not inherited from either parent is called a de novo mutation. For example, a butterfly may produce offspring with a new mutation. Many times new mutations are harmful; a new mutation might change the color of one of the butterfly's offspring, making it harder (or easier) for predators to see. If this color change is an advantage, the chances of this butterfly surviving and producing its own offspring are a little better, and over time the number of butterflies with this mutation may form a larger percentage of the population.
Alterations in human chromosomes or the deletion of an important gene product are often due to a mutation, which can spring an abundant strand of genetic mutations and improper coding. Mutations can spring from deletion, duplication or inversion of a chromosome. This improper deletion is the factor that leads to complications and ultimately genetic disorders. Turner Syndrome and Cat-cry Syndrome are both alterations of chromosome structure due to deletion. In Turner Syndrome, there is a missing X chromosome and in the Cat-cry Syndrome chromosome-18 has been lost or deleted. Other genetic disorders that give rise to discussion are point mutations which include Sickle cell anemia, Maternal PKU and the genetic disorder of The D1 Trisomy syndrome.
Turner Syndrome was described first by Turner in 1938 and it was established that this disorder was due to the deletion of an X chromosome in 1959 by Ford, Jones, Polani, de Ameida and Briggs. The most predominant traits of those who have this disorder consist of being short, having neck webbing with a low hairline and having a widely spaced chest. Turner Syndrome disease is not a fatal disease as long as there is management of possible heart problems and ovarian dysfunction. Early support and counseling are the key in dealing with psychological problems that may arise such as infertility and potential hearing loss.
Cat-cry Syndrome is another deletion disorder in which inhibitor survives quite well. Lejeune recognized this disorder in 1964 and he gave it the official name of La Maladie du Cri-du-Chat. The physical characteristics are evident in this disorder. There is a round moon-face, a low birth weight and a transverse palmar crease. When infants are born, it is their cry that stands out the most. It embodies a plaintive high-pitched wail, weak, and with a hint of stridor that sounds like that of a cat. This cry is the result of small vocal cords and a curved epiglottis. As these infants grow older their voice will eventually deepen and become more normal. The chromosome deletion is part of the short arm of a B group chromosome. It seems that the deletion comes about as a chance mishap, a break and then a loss at anaphase.
Sickle cell disease is another disorder but is not caused by the deletion of a chromosome. Instead there is an abnormal type of hemoglobin S that is inherited as an autosomal inherited trait. This disease produces chronic anemia, which may become life threatening when hemolytic crises (the breakdown of redblood cells) or aplastic crises (bone marrow fails to produce blood cells) occur. The incidence of this disorder is 1/400 African Americans and 8/100,000 people. The manifestations of this disease are a result of the fragility and inflexibility of the sickle red bloodcells. When exposed to a lack of water, infection, and low oxygen supply, these delicate red blood cells take the shape of a crescent. This then causes blood cell devastation and thickening of the blood. Sickle cell anemia has the potential to be life threatening and can affect other body systems and parts of the body. Those included are the nervous system, bones, the kidneys and the liver.
Maternal PKU is a genetic disorder that stems from