РефератыИностранный языкSiSickle Cell Anemia Essay Research Paper We

Sickle Cell Anemia Essay Research Paper We

Sickle Cell Anemia Essay, Research Paper


We feel that this report looks a lot better single-spaced. A Brief History of


Sickle Cell Disease Sickle Cell Disease in African Tradition Sickle cell disease


has been known to the peoples of Africa for hundreds, and perhaps thousands, of


years. In West Africa various ethnic groups gave the condition different names:


Ga tribe: Chwechweechwe Faute tribe: Nwiiwii Ewe tribe: Nuidudui Twi tribe:


Ahotutuo Sickle Cell Disease in the Western Literature Description of Sickle


Cell Disease In the western literature, the first description of sickle cell


disease was by a Chicago physician, James B. Herrick, who noted in 1910 that a


patient of his from the West Indies had an anemia characterized by unusual red


cells that were "sickle shaped". Relationship of Red Cell Sickling to


Oxygen In 1927, Hahn and Gillespie showed that sickling of the red cells was


related to low oxygen. Deoxygenation and Hemoglobin In 1940, Sherman (a medical


student at Johns Hopkins) noted a birefringence of deoxygenated red cells,


suggesting that low oxygen altered the structure of the hemoglobin in the


molecule. Protective Role of Fetal Hemoglobin in Sickle Cell Disease Janet


Watson, a pediatric hematolist in New York, suggested in 1948 that the paucity


of sickle cells in the peripheral blood of newborns was due to the presence of


fetal hemoglobin in the red cells, which consequently did not have the abnormal


sickle hemoglobin seen in adults. Abnormal Hemoglobin in Sickle Cell Disease


Using the new technique of protein electrophoresis, Linus Pauling and colleagues


showed in 1949 that the hemoglobin from patients with sickle cell disease is


different than that of normals. This made sickle cell disease the first disorder


in which an abnormality in a protein was known to be at fault. Amino Acid


Substitution in Sickle Hemoglobin In 1956, Vernon Ingram, then at the MRC in


England, and J.A. Hunt sequenced sickle hemoglobin and showed that a glutamic


acid at position 6 was replaced by a valine in sickle cell disease. Using the


known information about amino acids and the codons that coded for them, he was


able to predict the mutation in sickle cell disease. This made sickle cell


disease the first known genetic disorder. Preventive Treatment for Sickle Cell


Disease Hydroxyurea became the first (and only) drug proven to prevent


complications of sickle cell disease in the Multicenter Study of Hydroxyurea in


Sickle Cell Anemia, which was completed in 1995. How Does Sickle Cell Cause


Disease? The Mutation in Hemoglobin Sickle cell disease is a blood condition


primarily affecting people of African ancestry. The disorder is caused by a


single change in the amino acid building blocks of the oxygen-transport protein,


hemoglobin. This protein, which is the component that makes red cells


"red", has two subunits. The alpha subunit is normal in people with


sickle cell disease. The ?-subunit has the amino acid valine at position 6


instead of the glutamic acid that is there normally. The alteration is the basis


of all the problems that occur in people with sickle cell disease. The schematic


diagram shows the first eight-of the 146 amino acids in the ?-globin subunit of


the hemoglobin molecule. The amino acids of the hemoglobin protein are


represented as a series of linked, colored boxes. The lavender box represents


the normal glutamic acid at position 6. The dark green box represents the valine


in sickle cell hemoglobin. The other amino acids in sickle and normal hemoglobin


are identical. The molecule, DNA (deoxyribonucleic acid), is the fundamental


genetic material that determines the arrangement of the amino acid building


blocks in all proteins. Segments of DNA that code for particular proteins are


called genes. The gene that controls the production of the ?-subunit of


hemoglobin is located on one of the 46 human chromosomes (chromosome #11).


People have twenty-two identical chromosome pairs (the twenty-third pair is the


unlike X and Y-chromosomes that determine a person’s sex). One of each pair is


inherited from the father, and one from the mother. Occasionally, a gene is


altered in the exchange between parent and offspring. This event, called


mutation, occurs extremely infrequently. Therefore, the inheritance of sickle


cell disease depends totally on the genes of the parents. If only one of the ?-globin


genes is the "sickle" gene and the other is normal, the person is a


carrier. The condition is called sickle cell trait. With a few rare exceptions,


people with sickle cell trait are completely normal. If both ?-globin genes


code for the sickle protein, the person has sickle cell disease. Sickle cell


disease is determined at conception, when a person acquires his/her genes from


the parents. Sickle cell disease cannot be caught, acquired, or otherwise


transmitted. The hemoglobin molecule (made of alpha and ?-globin subunits)


picks up oxygen in the lungs and releases it when the red cells reach peripheral


tissues, such as the muscles. Ordinarily, the hemoglobin molecules exist as


single, isolated units in the red cell, whether they have oxygen bound or not.


Normal red cells maintain a basic disc shape, whether they are transporting


oxygen or not. The picture is different with sickle hemoglobin. Sickle


hemoglobin exists as isolated units in the red cells when they have oxygen


bound. When sickle hemoglobin releases oxygen in the peripheral tissues,


however, the molecules tend to stick together and form long chains or polymers.


These polymers distort the cell and cause it to bend out of shape. When the red


cells return to the lungs and pick up oxygen again, the hemoglobin molecules


resume their solitary existence (the left of the diagram). A single red cell may


traverse the circulation four times in one minute. Sickle hemoglobin undergoes


repeated episodes of polymerization and depolymerization. This


"Ping-Pong" alteration in the state of the molecules damages the


hemoglobin and ultimately the red cell itself. Polymerized sickle hemoglobin


does not form single strands. Instead, the molecules group in long bundles of 14


strands each that twist in a regular fashion, much like a braid. These bundles


self-associate into even larger structures that stretch and distort the cell. An


analogy would be a water ballon that formed ice sickles that extended and


stretched the ballon. The stretching of the rubber of the ballon is similar to


what happens to the membrane of the red cell. Despite their imposing appearance,


the forces that hold these sickle hemoglobin polymers together are very weak.


The abnormal valine amino acid at position 6 in the ?-globin chain interacts


weakly with the ? globin chain in an adjacent sickle hemoglobin molecule. The


complex twisting, 14-strand structure of the bundles produces multiple


interactions and cross-interactions between molecules. On the other hand, the


weak nature of the interaction opens one strategy to treat sickle cell disease.


Some types of hemoglobin molecules, such as that found before birth (fetal


hemoglobin), block the interactions between the hemoglobin S molecules. All


people have fetal hemoglobin in their circulation before birth. Fetal hemoglobin


protects the unborn and newborns from the effects of sickle cell hemoglobin.


Unfortunately, this hemoglobin disappears within the first year after birth. One


approach to treating sickle cell disease is to rekindle production of fetal


hemoglobin. The drug, Hydroxyurea induces fetal hemoglobin production in some


patients with sickle cell disease and improves the clinical condition of some


patients. The Sickle Red Cell The schematic diagram shows the changes that occur


as sickle or normal red cells release oxygen in the microcirculation. The upper


panel shows that normal red cells retain their biconcave shape and move through


the microcirculation (capillaries) without problem. In contrast, the hemoglobin


polymerizes in sickle red cells when they release oxygen, as shown in the lower


panel. The polymerization of hemoglobin deforms the red cells. The problem,


however, is not simply one of abnormal shape. The membranes of the cells are


rigid due in part to repeated episodes of hemoglobin polymerization/depolymerization


as the cells pick up and release oxygen in the circulation. These rigid cells


fail to move through the microcirculation, blocking local blood flow to a


microscopic region of tissue. Amplified many times, these episodes produce


tissue hypoxia (low oxygen supply). The result is pain, and often damage to


organs. The damage to red cell membranes plays an important role in the


development of complications in sickle cell disease. Robert Hebbel at the


University of Minnesota and colleagues were among the first workers to show that


the heme component of hemoglobin tends to be released from the protein with


repeated episodes of sickle hemoglobin polymerization. Some of this free heme


lodges in the red cell membrane. The iron in the center of the heme molecule


promotes formation of very dangerous compounds, called oxygen radicals. These


molecules damage both the lipid and protein components of the red cell membrane.


As a consequence, the membranes become stiff. Also, the damaged proteins tend to


clump together to form abnormal clusters in the red cell membrane. Antibodies


develop to these protein clusters, leading to even more red cell destruction (hemolysis).


Red cell destruction or hemolysis causes the anemia in sickle cell disease. The


production of red cells by the bone marrow increases dramatically, but is unable


to keep pace with the destruction. Red cell production increases by five to


ten-fold in most patients with sickle cell disease. The average half-life of


normal red cells is about 40 days. In-patients with sickle cell disease, this


value can fall to as low as four days. The volume of "active" bone


marrow is much expanded in-patients with sickle cell disease relative to nomal


in response to demands for higher red cell production. The degree of anemia


varies widely between patients. In general, patients with sickle cell disease


have hematocrits that are roughly half the normal value (e.g., about 25%


compared to about 40-45% normally). Patients with hemoglobin SC disease (where


one of the ?-globin genes codes for hemoglobin S and the other for the variant,


hemoglobin C) have higher hematocrits than do those with homozygous Hb SS


disease. The hematocrits of patients with Hb SC disease run in low- to


mid-thirties. The hematocrit is normal for people with sickle cell trait. How Do


People Get Sickle Cell Disease? Sickle cell disease is an inherited condition.


The genes received from one’s parents before birth determine whether a person


will have sickle cell disease. Sickle cell disease cannot be caught or passed on


to another person. The severity of sickle cell disease varies tremendously. Some


people with sickle cell disease lead lives that are nearly normal. Others are


less fortunate, and can suffer from a variety of complications. How Are Genes


Inherited? At the time of conception, a person receives one set of genes from


the mother (egg) and a corresponding set of genes from the father (sperm). The


combined effects of many genes determine some traits (hair color and height, for


instance). One gene pair determines other characteristics. Sickle cell disease


is a condition that is determined by a single pair of genes (one from each


parent). Inheritance of Sickle Cell Disease The genes are those which control


the production of a protein in red cells called hemoglobin. Hemoglobin binds


oxygen in the lungs and delivers it to the peripheral tissues, such as the


liver. Most people have two normal genes for hemoglobin. Some people carry one


normal gene and one gene for sickle hemoglobin. This is called "sickle cell


trait". These people are normal in almost all respects. Problems from the


single sickle cell gene develop only under very unusual conditions. People who


inherit two genes for sickle hemoglobin (one from each parent) have sickle cell


disease. With a few exceptions, a child can inherit sickle cell disease only if


both parents have one gene for sickle cell hemoglobin. The most common situation


in which this occurs is when each parent has one sickle cell gene. In other


words, each parent has sickle cell trait. Figure 1 shows the possible


combination of genes that can occur for parents each of whom has sickle cell


trait. Figure 1. (ABOVE) Inheritance of sickle genes from parents with sickle


cell trait. As shown in the graphic, the couple has one chance in four that the


child will be normal, one chance in four that the child will have sickle cell


disease, and one chance in two that the child will have sickle cell trait. A


one-in-four chance exists that a child will inherit two normal genes from the


parents. A one-in-four chance also exists that a child will inherit two sickle


cell genes, and have sickle cell disease. A one-in-two chance exists that the


child will inherit a normal gene from one parent and a sickle gene from the


other. This would produce sickle trait. These probabilities exist for each child


independently of what happened with prior children the couple may have had. In


other words, each new child has a one-in-four chance of having sickle cell


disease. A couple with sickle cell trait can have eight children, none of whom


have two sickle genes. Another couple with sickle trait can have two children


each with sickle cell disease. The inheritance of sickle cell genes is purely a


matter of chance and cannot be altered. Do Factors Other Than Genes Influence


Sickle Cell Disease? Sickle cell disease is quite variable in itself. Other


blood conditions can influence sickle cell disease, however. One of the most


important is thalassemia. One form of thalassemia, called ?-thalassemia,


reduces the production of normal hemoglobin. A person with one normal hemoglobin


gene and one thalassemia gene has thalassemia trait (also called thalassemia


minor). Parents who have sickle cell trait and thalassemia trait have one chance


in four of having a child with one gene for sickle cell disease and one gene for


?-thalassemia (Figure 2). This condition is sickle ?-thalassemia. The severity


varies. Some patients with sickle ?-thalassemia have a condition as severe as


sickle cell disease itself. People of Mediterranean origin who have a sickle


condition most often have sickle ?-thalassemia. Figure 2. (BELOW ON LAST PA

GE)


Inheritance of hemoglobin genes from parents with sickle cell trait and


thalassemia trait. As illustrated, the couple has one chance in four that the


child will have the genes both for sickle hemoglobin and for thalassemia. The


child would have sickle ?-thalassemia. The severity of this condition is quite


variable. The nature of the thalassemia gene (?o or ?+) greatly influences the


clinical course of the disorder. Another disorder that interacts with sickle


cell disease is "hemoglobin SC disease". The abnormal hemoglobin C


gene is relatively harmless. Even people with two hemoglobin C genes have a


relatively mild clinical condition. When hemoglobin C combines with hemoglobin


S, the result is "hemoglobin SC disease". On average, hemoglobin SC


disease is milder than sickle cell disease. However, some patients with


hemoglobin SC disease have a clinical condition as severe as any with sickle


cell disease. The reason for the marked variability in the clinical course of


hemoglobin SC disease is unknown. We do know that the tendency of hemoglobin C


to produce red cell dehydration is a major reason that the combination of


hemoglobins S and C is so problematic. Figure 3. (ABOVE) Inheritance of


hemoglobin genes from parents with sickle cell trait and hemoglobin C trait. As


illustrated, the couple has one chance in four that the child will have the


genes both for sickle hemoglobin and for hemoglobin C. The child would have


hemoglobin SC disease. Most patients with hemoglobin SC disease have a milder


condition than occurs with sickle cell disease (two sickle genes).


Unfortunately, some patients run a clinical course that is undistinguishable


from sickle cell disease. Are There Tests That Can Tell Me Whether I Have Sickle


Cell Trait? The answer is yes. Routine "blood counts" commonly


performed in doctors’ offices do not give hints about the presence of sickle


cell trait. The blood counts of most people with sickle cell trait are normal.


Only a special test, called a "hemoglobin electrophoresis" indicates


reliably whether a person has sickle trait. In addition, the hemoglobin


electrophoresis will detect hemoglobin C and ?-thalassemia. How Can I Be Tested


for Sickle Cell Trait? Most large hospitals and clinics can perform routine


hemoglobin electrophoresis. Smaller laboratories send the test to commercial


firms for testing. If you are concerned about the possibility of having sickle


cell trait, you should speak with your doctor. Overview Everyone with sickle


cell disease shares the same gene mutation. A thymine replaces an adenine in the


DNA encoding the ?-globin gene. Consequently, the amino acid valine replaces


glutamic acid at the sixth position in the ?-globin protein product. The change


produces a phenotypically recessive characteristic. Most commonly sickle cell


disease reflects the inheritance of two mutant alleles, one from each parent.


The final product of this mutation, hemoglobin S is a protein whose quaternary


structure is a tetramer made up of two normal alpha-polypeptide chains and two


aberrant ?s-polypeptide chains. The primary pathological process leading


ultimately to sickle shaped red blood cells involves this molecule. After


deoxygenation of hemoglobin S molecules, long helical polymers of HbS form


through hydrophobic interactions between the ?s-6 valine of one tetramer and


the ?-85 phenylalanine and ?-88 leucine of an adjacent tetramer. Deformed,


sickled red cells can occlude the microvascular circulation, producing vascular


damage, organ infarcts, painful crises and other such symptoms associated with


sickle cell disease. Although everyone with sickle cell disease shares a


specific, invariant genotypic mutation, the clinical variability in the pattern


and severity of disease manifestations is astounding. In other genetic disorders


such as cystic fibrosis, phenotypic variability between patients can be traced


genotypic variability. Such is not the case, however, with sickle cell disease.


Physicians and researchers have sought explanations of the variability


associated with the clinical expression of this disease. The most likely causes


of this inconstancy are disease-modifying factors. I have reviewed the role of


some of these factors, and tried to ascertain the clinical importance of each.


Fetal Hemoglobin Augmented post-natal expression of fetal hemoglobin is perhaps


the most widely recognized modulator of sickle cell disease severity. Fetal


hemoglobin, as its name implies is the primary hemoglobin present in the fetus


from mid to late gestation. The protein is composed of two alpha-subunits and


two gamma-subunits. The gamma-subunit is a protein product of the ?-gene


cluster. Duplicate genes duplicate upstream of the ?-globin gene encodes fetal


globin. Fetal hemoglobin binds oxygen more tightly than does adult hemoglobin A.


The characteristic allows the developing fetus to extract oxygen from the


mother’s blood supply. After birth, this trait is no longer necessary and the


production of the gamma-subunit decreases as the production of the ?-globin


subunit increases. The ?-globin subunit replaces the gamma-globin subunit in


the hemoglobin tetramer so that eventually adult hemoglobin replaces fetal


hemoglobin as the primary component red cells. HbF levels stabilize during the


first year of life, at less than 1% of the total hemoglobin. In cases of


hereditary persistence of fetal hemoglobin, that percentage is much higher. This


persistence substantially ameliorates sickle cell disease severity. Mechanism of


Protection Two properties of fetal hemoglobin help moderate the severity of


sickle cell disease. First, HbF molecules do not participate in the


polymerization that occurs between molecules of deoxyHbS. The gamma-chain lacks


the valine at the sixth residue to interact hydrophobically with HbS molecules.


HbF has other sequence differences from HbS that impede polymerization of


deoxyHbS. Second, higher concentrations of HbF in a cell infer lower


concentrations of HbS. Polymer formation depends exponentially on the


concentration of deoxyHbS. Each of these effects reduces the number of


irreversibly sickle cells (ISC). Hemoglobin F Levels and Amelioration of Sickle


Cell Disease The level of HbF needed to benefit people with sickle cell disease


is a key question to which different studies supply varying answers. Bailey


examined the correlation between early manifestation of sickle cell disease and


fetal hemoglobin level in Jamaicans. They concluded that moderate to high levels


of fetal hemoglobin (5.4-9.7% to 39.8%) reduced the risk for early onset of


dactylics, painful crises, acute chest syndrome, and acute splenic


sequestration. Platt examined predictive factors for life expectancy and risk


factors for early death (among Black Americans). In their study, a high level of


fetal hemoglobin (*8.6%) augured improved survival. Koshy et al. reported that


fetal hemoglobin levels above 10% were associated with fewer chronic leg ulcers


in American children with sickle cell disease. Other studies, however, suggest


that protection from the ravages of sickle cell disease occur only with higher


levels of HbF. In a comparison of data from Saudi Arabs and information from


Jamaicans and Black Americans, Perrine et al. found that serious complications


occurred only 6% to 25% as frequently in Saudi Arabs as North American Blacks.


In addition mortality under the age of 15 was 10% as great among Saudi Arabs.


Further, these patients experienced no leg ulcers, reticulocyte counts were


lower and hemoglobin levels were higher on average. The average a fetal


hemoglobin level in the Saudi patients ranged between 22-26.8%. This is more


than twice that reported in studies mentioned above. Kar et al. compared


patients from Orissa State, India to Jamaican patients with sickle cell. These


patients also had a more benign course when compared with Jamaican patients. The


reported protective level of fetal hemoglobin in this study was on average


16.64%, with a range of 4.6% to 31.5%. Interestingly, ?-globin locus haplotype


analysis shows that the Saudi HbS gene and that in India have a common origin


(see below). These studies suggest that the level of fetal hemoglobin that


protects against the complications of sickle cell disease depend strongly on the


population group in question. Among North American blacks, fetal hemoglobin


levels in the 10% range ameliorate disease severity. The higher average level of


fetal hemoglobin could contribute to the generally less severe disease in


Indians and Arabs. Another study that suggests only a small role at best for


fetal hemoglobin as a modifier of sickle cell disease severity was reported by


El-Hazmi. The subjects were Saudi Arabs in whom a variety of symptoms associated


with sickle cell disease were assessed to form a "severity" index. The


author concluded that among his patients, no correlation existed between HbF and


the severity index. However, his analysis has a fundamental flaw. El-Hazmi


failed to examine the effect of HbF on each of these symptoms individually.


Their important information and an association between fetal hemoglobin levels


specific disease manifestations could be concealed in his data. However, the


study reinforces the conclusion that fetal hemoglobin levels most likely work in


conjunction with other moderating factors to determine clinical severity


in-patients with sickle cell disease. Alpha-Thalassemia Concurrent alpha-thalassemia


has also been examined as a modifier of sickle cell disease severity. Alpha-thalassemia,


like sickle cell disease, is a genetically inherited condition. The loss of one


or more of the four genes encoding the alpha globin chain (two each on


chromosome 16) produces alpha-thalassemia. A gene deletion most commonly is at


fault. The deletion results from unequal crossover between adjacent alpha-globin


genes during the prophase I of meiosis I. Such a crossover leaves one gamete


with one alpha-gene and the other gamete with three alpha genes. Upon


fertilization the zygote can have 2, 3, 4, or 5 alpha genes depending on the


make up of the other parental gamete. In people of African descent, the most


common haploid gamete of this type is alpha-thal-2 in which there is one


deletion on each of the number 16 chromosomes in the patient. Heterozygotes for


this allele, therefore, have three alpha genes (one alpha gene on one of the


number 16 chromosomes, two alpha genes on the other). Embury et al. (1984)


examined the effect of concurrent alpha-thalassemia and sickle cell disease.


Based on prior studies, they proposed that alpha-thalassemia reduces


intraerythrocyte HbS concentration, with a consequent reduction in


polymerization of deoxyHbS and hemolysis. They investigated the effect of alpha


gene number on properties of sickle erythrocytes important to the hemolytic and


rheological consequences of sickle cell disease. Specifically they looked for


correlations between the alpha gene number and irreversibly sickled cells, the


fraction of red cells with a high hemoglobin concentration (dense cells), and


red cells with reduced deformabilty. The investigators found a direct


correlation between the number of alpha-globin genes and each of these indices.


A primary effect of alpha-thalassemia was reduction in the fraction of red blood


cells that attained a high hemoglobin concentration. These dense cells result


from potassium loss due to acquired membrane leaks. The overall deformability of


dense RBCs is substantially lower than normal. This property of alpha-thalassemia


was confirmed by comparison of red cells in people with or without 2-gene


deletion alpha-thalassemia (and no sickle cell genes). The cells in the


nonthalassemic individuals were denser than those from people with 2-gene


deletion alpha-thalassemia. The difference in median red cell density produced


by alpha-thalassemia was much greater in-patients sickle cell disease. Reduction


in overall hemoglobin concentration due to absent alpha genes is not the only


mechanism by which alpha-thalassemia reduces the formation of dense and


irreversibly sickled cells. In reviewing the available literature, Embry and


Steinburg suggested that alpha-thalassemia moderate’s red cell damage by


increasing cell membrane redundancy. This protects against sickling-induced


stretching of the cell membrane. Potassium leakage and cell dehydration would be


minimized. These two papers by Embury et al. give some insight into the


moderation of sickle cell disease severity by alpha thalassemia. Some


deficiencies exist, nonetheless. The first paper makes no mention of the patient


pool. Unspecified are the number of patients used, their ethnicity, or their


state of health when blood samples were taken. This information would help


establish the statistical reliability of the data, and its applicability across


patient groups. Despite these limitation, the work provides important insight


into the mechanisms by which alpha-thalassemia ameliorates sickle cell disease


severity. Ballas et al reached different conclusions regarding alpha thalassemia


and sickle cell disease than did Embury et al . They reported that decreased red


blood cell deformability was associated with reduced clinical severity of sickle


cell disease. Patients with more highly deformabile red cells had more frequent


crises. They also found that fewer dense cells and irreversible sickle cells


correlated inversely with the severity of painful crises. Like Embury et al.,


Ballas and colleagues found alpha thalassemia was associated with fewer dense


red cells. In addition, Ballas’ group found that alpha thalassemia was


associated with less severe hemolysis. However they reached no clear conclusion


concerning alpha gene number and deformability of RBC except to note that the


alpha thalassemia was associated with less red cell dehydration. The two studies


are not completely at odds. Both state that concurrent alpha-thalassemia reduces


hemolytic anemia. They agree that this occurs through reduction in the number of


dense cells, a number directly related to the fraction of irreversibly sickled


cells. Embury et al. concludes that through this mechanism red blood cell


deformability is increased. The investigators diverge, however, on the


relationship to clinical severity of dense cells and rigid cells. Ballas et al.


asserts that both the reduction of dense cells and rigid cells contribute to


disease severity.


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