Genetic Disorders: Cat Eye Syndrome

This syndrome is tested at birth with fluorescent in situ hybridization or FISH. With blood samples, they test the blood for the deletion of chromosome 7. FISH checks if many as of 22-26 genes are deleted. Because there is no cure for this syndrome, you will most likely have physical therapy and early education to help early development symptoms like speech delays and heart problems. This syndrome is not caused by environmental factors, it is completely genetic and NOT the parents fault.

INTRODUCTION. Idiopathic congenital nystagmus, or idiopathic infantile nystagmus is a disease characterized by the rapid, involuntary eye movement. This movement is typically in the horizontal direction, however, movement in other directions have been observed. One way to get nystagmus is through genetic mutations. Nystagmus caused by genetic mutation is seen at a relatively young age but cannot yet be treated. The disease is not understood well, it is believed that the cause is a developmental defect. The linkage, and inheritance has not been identified, the patterns suggest that multiple genes are involved in the disease and that there are loci on different chromosomes with three of the five loci located on the X chromosome. Mutations have been linked to the FRMD7 gene, a gene that consists of 12 exons, of the FERM family. The function of FRMD7 have yet to be determined however an abundance of the protein in the brain in areas associated with the eye. Mutations within this region consist of missense, deletion, tranversion and nonsense mutations. Over forty-four mutations that lead to ICN have been found in the FRMD7 gene. Learning more about the mutation of FRMD7 in ICN is important because these mutations may prevent elongation of neurite processes during differentiation preventing axons from responding to stimuli (Watkins et al. 2012).

About 10% of those who encounter it experience it from a pattern through their family(Duane’s Syndrome). When the syndrome does transmit through family patterns there have been cases in which duane’s syndrome has skipped generations and different family members have encountered individual levels of asperity. These genes can be found as both recessive and dominant although dominant is the most common form of the syndrome. While experiencing this disorder you can experience 3 types of symptoms all varying in the eyes ability to move inward or outward, also including the eyes retraction, closing of the eye opening, and downshoot or upshoot when looking inward (Duane’s

Usher syndrome is a genetic disorder that causes its victims to get retnis pigmentosa (RP), or a disease that affects someone’s retinas resulting in tunnel vision, and hearing loss. The most common gene that becomes mutated is gene USH2A, this is a protein producing gene. It is a mutated recessive gene, meaning that in order to inherit Usher syndrome both parents have to be carriers of it. Once the child gets Usher syndrome, they will experience loss of eyesight and hearing.

Furthermore, people born with this unique genetic defect share some similar characteristic traits and features that are both physical

This syndrome is from a mutation of a gene on chromosome 15 and this causes problems in the production of fibrillin-1 which is a protein that is an important part of connective tissue. The name for the gene is FBN1. Basically, it is the “glue” that helps to support the tissues in the human body. A child born to a parent with this syndrome has a 50% of having it. However, in the remaining 25%, neither parent has the disease which gives them a 1 in 10,000 chance of having a child with this disorder. When a child of two unaffected parents is born with it then the genetic mutation occurs in either the egg or sperm cell at the time of conception.

The purpose of this paper is to discuss the effects of the disorder and how genetics and biochemistry work together to create this

The P1 cross was between four wmf females and nine wild-type males. The F1 progeny consisted of 12 wild-type females, and four triple-mutant males. The P2 cross resulted in 13 females, and 3 males, all with the wild-type phenotype (Table 1). The two parental crosses identify that the mutations are X-link recessive. The triple-mutant females of the P1 cross produce mutant male offspring, but wild-type females. The F1 females would be heterozygous for the mutations, but don’t express the mutations because they still have a wild-type X chromosome. However, the F1 males only have one X chromosome that comes from a mutant mother. The offspring for P1 were crossed again to make and F1 cross. The F1 cross would be X+/Y and X+/X. The F1 cross resulted in 100 F2 progenies over the course of 7 days.

Muscular dystrophy (MD) is a genetic disorder caused by incorrect or missing genetic information that leads to the gradual weakening of the muscle cells. Various causes lead to weak and deteriorating muscles depending on the type of muscular dystrophy the patient was affected by. However, there are many causes for muscular dystrophy due to the fact that there are thirty forms of muscular dystrophy, which are categorized under several categories. All are ultimately caused by autosomal recessive, autosomal dominant, sex-linked, and random mutations in very rare cases.

Cri-du-Chat (cat’s cry) Syndrome is a rare chromosomal disorder that is caused by the deletion of genetic material on chromosome 5. Due to this, this syndrome has an alternative name, known as 5p-, or 5p minus syndrome. Although this genetic defect is able to be diagnosed, the cause of the deletion on the chromosome is unknown. Almost all cases of the Cri-du-Chat Syndrome are found to have no relation with family members or previous generations. This syndrome is generally not inherited, as the deletion occurs randomly during meiosis (the formation of the gametes). In about 90% of people who have this condition, the deletion is completely random and is not inherited. The remaining 10% of affected people inherit a chromosome with a deleted section from an unaffected parent. This is because the parents’ balanced

Genetic disorders come in various forms. Some can be caused by mutations of the genes or chromosomes while others can be caused by a process called nondisjunction. Nondisjunction occurs when chromosomes during meiosis do not separate correctly and the daughter cells receive too much or too little genetic information. Klinefelter's is caused by nondisjunction which results in an extra X chromosome being present in a male.

This condition is often overlooked and treatment delayed because there are no visible signs or abnormalities and children are seldom aware that anything is wrong with their vision.

The cat like cry is the most prominent feature and is usually one of the key factors in diagnosing it. The chromosomes can also be analyzed and they can find the missing or misplaced chromosome. In this case they would find that the fifth chromosome is missing. They can also do a more detailed test called the “FISH” test. FISH stands for Fluorescent in Situ Hybridization, it can detect the deletion.

scoliosis, cataracts , scars, overweight, Chrohn diseasChromosome Patterns The normal female has 46 chromosomes, of

The gene carrying the defect that produces albinism is recessive, which means that both parents must carry this recessive gene in order to produce a child with the condition. When both parents carry the gene (and neither has albinism), there is a one in four chance with each pregnancy that their child will have albinism. The inheritance pattern of ocular albinism is alittle different. This condition is X-linked, meaning that the recessive gene for ocular albinism is located on the X chromosome. X-linked ocular albinism appears just about only in males who inherit the condition from their mothers.