Galactose To Glucose 1 example essay topic
Galactose, the enzyme in the liver that is required to break down galactose, is deficient in galactose mia patients ("Galactosemia" 1995 and Wohl ers, Chris tacos, and Harriman 1999). This enzyme works as a catalyst to speed up the breakdown of galactose. When there is a deficiency of this enzyme, the body cannot metabolize galactose as quickly as needed, causing a toxic buildup (Olendore, Jenyan, and Bayden 1999). This disease is inherited in an recessive manner, this means that galactose mia is only present in individuals with two defective copies of any one of the three genes that causes it (Chung 1997).
These genes are the genes that code for the three enzymes, galactose mia-1-phosphate- transferase (GALT), (GALK), and -4- (Olendore, Jenyan, and Bayden 1999). Although carriers have less than normal enzyme activity, carriers of the disease are unaware that they are carrying a defective gene since no symptoms are evident (Chung 1997). If two carriers of the same defective gene have children, the chance of their child getting galactose mia by having two copies of the same defective gene is 25% for each pregnancy (Elsas 1999). Every cell nucleus has two copies of each gene, therefore, if only one of the two copies is defective, enough of the enzyme is made and the pathway of galactose metabolism is not blocked (Olendore, Jenyan, and Bayden 1999). Most states have now included testing for galactose mia in newborn screening programs ("Galactosemia" 1995).
However, if galactose mia is not found in a screening program, some symptoms appear within the first couple of days of the newborn's life (Elsas 1999). Symptoms usually begin to appear quickly in newborns because their entire diet is made up of milk, which is made of 20% galactose (Olendore, Jenyan, and Bayden 1999). High levels of galactose cause vomiting diarrhea, lethargy, low blood sugar, brain damage, jaundice, liver enlargement, cataracts, malnutrition, rapid organ damage, susceptibility to infection especially to gram negative bacteria, and even death (Olendore, Jenyan, and Bayden 1999 and Chung 1997). Infants may also exhibit poor growth, feeding difficulties, encephalopathy, and renal tubular dysfunction (Berry et al.
1995). The Human Genome Project has had a great impact on what is known about galactose mia. They have identified what causes the disease and on which chromosome the mutation occurs. Three enzymes are required to completely convert galactose to glucose-1-phosphate, which is able to enter the metabolic pathway and turn into energy.
A separate gene encodes each of these three enzymes. If any of these enzymes fail to function galactose builds up and galactose mia result (Olendore, Jenyan, and Bayden 1999). The first type of galactose mia is called galactose mia I or classic galactose mia. This form has been discovered to be caused by defects in both copies of the gene that codes the enzyme galactose mia-1-phosphate- transferase (GALT) (Olendore, Jenyan, and Bayden 1999). This enzyme is responsible for the second phase of galactose metabolism. Without this enzyme, the body cannot convert galactose to UDP galactose, which eventually leads to glucose formation causing hypoglycemia.
Since this cannot occur, the galactose metabolite, galactose-1-phosphate remains unconverted and accumulates causing rapid damage to vital organs (Chung 1997). There are thirty known mutations in this gene that cause GALT to malfunction. The frequency of this form is relatively high, occurring in 1 in 50,000 to 70,000 births (Olendore, Jenyan, and Bayden 1999). The second type of galactose mia is called galactose mia II. This form is caused by defect in the gene that codes for the enzyme (GALK). Galactokinase normally acts as a catalyst that converts galactose-1-phosphate to glucose-1-phosphate using a series of reactions requiring uri dine tri phosphate (UTP) as a coenzyme.
Without, the reaction occurs too slowly and galactose-1-phosphate is not converted to glucose-1-phosphate (Oldendore, Jenyan, and Bayden 1999). A deficiency in causes some physical problems such as nuclear cataracts before or shortly after birth. It also causes mental retardation in some. Biochemically, it results in the increased secretion of galactose and corresponding sugar alcohol, , following galactose.
This results in the elevation of blood galactose levels (Galactokinase Deficiency 1996). Galactosemia II is less harmful than galactose mia I and only occurs in about 1 in every 100,000-150,000 births (Oldendore, Jenyan, and Bayden 1999). The third form is galactose mia. It is a benign form, usually asymptomatic, and does not require a special diet. This form is caused by defects on the gene that codes for the enzyme -4- (GALE). Uridyl -4- assists in the conversion of galactose-1-phosphate by catalyzing the conversion of UDP-glucose to UDP-galactose.
In the benign form, the enzyme deficiency is only found in the blood cells (leukocytes, lymphocytes, and erythrocytes). However, in the severe form, the enzyme deficiency is in the blood cells and in the fibroblasts and is usually less than 10% of normal (Galactosemia 1994). This very rare, severe form of galactose mia has been found to have similar symptoms to galactose mia I but with more severe neurological problems (Oldendore, Jenyan, and Bayden 1999). For example, Fan coni Syndrome appears which causes episodes of vomiting, dehydration, weakness, anorexia, constipation, polydipsia, , and rickets (Galactosemia 1994).
A number of different types of mutations on these genes have been found in galactose mia patients. These include nucleotide substitutions, small deletions, small insertions, small indies, gross deletions, gross insertions and duplications, and repeat variations ("Galactose-1-phosphate... ". 1990). In fact, over 172 different mutations are known to cause galactose mia (Elsas 1999). Although galactose mia can lead to death if not found immediately after birth, many precautions can be taken to lessen the chances of this occurring.
First of all, adults who want to start a family can be tested for having a defective gene. If a defective gene is found in both parents, the child should be tested immediately after birth for galactose mia (Olendore, Jenyan, and Bayden 1999). Also, most states have added tests for galactose mia in with their newborn screening process to eliminate the potential of death ("Galactosemia" 1995). Unfortunately, many children are born each year with galactose mia and there is no medication that can treat it (Chung 1997). However, galactose mia is manageable and the symptoms can be greatly reduced by taking a few precautions. First of all, babies whose GALT activity is less than 10% need to have all their milk products replaced by formula such as Isom il or Prosobee, which are free of lactose.
Soy products contain other sugars such as sucrose, fructose, and non-galactose poly carbohydrates, which supply the needed energy to the baby. All lactose containing foods such as dairy products, tomato sauces, candies, and medicines should be avoided fro the remainder of the patients life (Elsas 1999). Finally, legumes, organ meats, and processed meats also contain galactose and should be avoided (Olendore, Jenyan, and Bayden 1999). Management of the diet becomes less important after infancy and early childhood because milk products are no longer the primary source of energy (Elsas 1999). So, although galactose mia can be fatal, it is highly treatable and a patient can live a normal life with only a few changes in their diet.