Hunter syndrome | |
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Patient with Hunter syndrome | |
Specialty | Endocrinology |
Symptoms | Skeletal abnormalities, hearing loss, retinal degeneration, enlarged liver and spleen |
Complications | Upper airway disease; cardiovascular failure |
Causes | Defiency of the enzyme iduronate-2-sulfatase |
Differential diagnosis | Mucopolysaccharidosis type I; other mucopolysaccharidoses |
Prognosis | In severe cases, death usually occurs by age 15. In attenuated cases, patients may survive into their 50s |
Frequency | 1 in 100,000 to 150,000 male births [1] |
Hunter syndrome, or mucopolysaccharidosis type II (MPS II), is a rare genetic disorder in which large sugar molecules called glycosaminoglycans (or GAGs or mucopolysaccharides) build up in body tissues. It is a form of lysosomal storage disease. Hunter syndrome is caused by a deficiency of the lysosomal enzyme iduronate-2-sulfatase (I2S). [2] [3] The lack of this enzyme causes heparan sulfate and dermatan sulfate to accumulate in all body tissues. [4] Hunter syndrome is the only MPS syndrome to exhibit X-linked recessive inheritance. [4]
The symptoms of Hunter syndrome are comparable to those of MPS I. It causes abnormalities in many organs, including the skeleton, heart, and respiratory system. In severe cases, this leads to death during the teenaged years. Unlike MPS I, corneal clouding is not associated with this disease. [1]
Hunter syndrome may present with a wide variety of phenotypes. It has traditionally been categorized as either "mild" or "severe" depending on the presence of central nervous system symptoms, but this is an oversimplification. Patients with "attenuated" or "mild" forms of the disease may still have significant health issues. For severely affected patients, the clinical course is relatively predictable; patients will normally die at an early age. For those with milder forms of the disease, a wider variety of outcomes exist. Many live into their 20s and 30s, but some may have near-normal life expectancies. Cardiac and respiratory abnormalities are the usual cause of death for patients with milder forms of the disease. [2]
The symptoms of Hunter syndrome (MPS II) are generally not apparent at birth. Often, the first symptoms may include abdominal hernias, ear infections, runny noses, and colds. As the buildup of GAGs continues throughout the cells of the body, signs of MPS II become more visible. The physical appearance of many children with the syndrome include a distinctive coarseness in their facial features, including a prominent forehead, a nose with a flattened bridge, and an enlarged tongue. They may also have a large head, as well as an enlarged abdomen. For severe cases of MPS II, a diagnosis is often made between the ages of 18 and 36 months. In milder cases, patients present similarly to children with Hurler–Scheie syndrome, and a diagnosis is usually made between the ages of 4 and 8 years. [2]
The continued storage of GAGs leads to abnormalities in multiple organ systems. After 18 months, children with severe MPS II may experience developmental decline and progressive loss of skills. [1] The thickening of the heart valves and walls of the heart can result in progressive decline in cardiac function. The walls of the airway may become thickened, as well, leading to obstructive airway disease. As the liver and spleen grow larger with time, the abdomen may become distended, making hernias more noticeable. All major joints may be affected by MPS II, leading to joint stiffness and limited motion. Progressive involvement of the finger and thumb joints results in decreased ability to pick up small objects. The effects on other joints, such as hips and knees, can make walking normally increasingly difficult. If carpal tunnel syndrome develops, a further decrease in hand function can occur. The bones themselves may be affected, resulting in short stature. In addition, pebbly, ivory-colored skin lesions may be found on the upper arms, legs, and upper back of some people with it. These skin lesions are considered pathognomonic for the disease. Finally, the storage of GAGs in the brain can lead to delayed development with subsequent intellectual disability and progressive loss of function.[ citation needed ]
The age at onset of symptoms and the presence or absence of behavioral disturbances are predictive factors of ultimate disease severity in very young patients. Behavioral disturbances can often mimic combinations of symptoms of attention deficit hyperactivity disorder, autism, obsessive compulsive disorder, and/or sensory processing disorder, although the existence and level of symptoms differ in each affected child. They often also include a lack of an appropriate sense of danger, and aggression. The behavioral symptoms of MPS II generally precede neurodegeneration and often increase in severity until the mental handicaps become more pronounced. [5] By the time of death, most children with severe MPS II have severe mental disabilities and are completely dependent on their caretakers. [2]
Since Hunter syndrome is an X-linked recessive disorder, it preferentially affects male patients. The IDS gene is located on the X chromosome. The IDS gene encodes for an enzyme called iduronate-2-sulfatase (I2S). A lack of this enzyme leads to a buildup of GAGs, which cause the symptoms of MPS II. [6]
If a female inherits one copy of the mutant allele for MPS II, she will usually have a normal copy of the IDS gene which can compensate for the mutant allele. This is known as being a genetic carrier. A male who inherits a defective X chromosome, though, usually does not have another X chromosome to compensate for the mutant gene. Thus, a female would need to inherit two mutant genes to develop MPS II, while a male patient only needs to inherit one mutant gene. A female carrier can be affected due to X-inactivation, which is a random process.[ citation needed ]
The human body depends on a vast array of biochemical reactions to support critical functions. One of these functions is the breakdown of large biomolecules. The failure of this process is the underlying problem in Hunter syndrome and related storage disorders.[ citation needed ]
The biochemistry of Hunter syndrome is related to a problem in a part of the connective tissue known as the extracellular matrix, which is made up of a variety of sugars and proteins. It helps to form the architectural framework of the body. The matrix surrounds the cells of the body in an organized meshwork and functions as the glue that holds the cells of the body together. One of the parts of the extracellular matrix is a molecule called a proteoglycan. Like many components of the body, proteoglycans need to be broken down and replaced. When the body breaks down proteoglycans, one of the resulting products is mucopolysaccharides (GAGs).[ citation needed ]
In MPS II, the problem concerns the breakdown of two GAGs: dermatan sulfate and heparan sulfate. The first step in the breakdown of dermatan sulfate and heparan sulfate requires the lysosomal enzyme iduronate-2-sulfatase, or I2S. In people with MPS II, this enzyme is either partially or completely inactive. As a result, GAGs build up in cells throughout the body, particularly in tissues that contain large amounts of dermatan sulfate and heparan sulfate. The rate of GAGs buildup is not the same for all people with MPS II, resulting in a wide spectrum of medical problems.[ citation needed ]
The first laboratory screening test for an MPS disorder is a urine test for GAGs. Abnormal values indicate that an MPS disorder is likely. The urine test can occasionally be normal even if the child actually has an MPS disorder. A definitive diagnosis of MPS II is made by measuring I2S activity in serum, white blood cells, or fibroblasts from skin biopsy. In some people with MPS II, analysis of the I2S gene can determine clinical severity.[ citation needed ]
Prenatal diagnosis is routinely available by measuring I2S enzymatic activity in amniotic fluid or in chorionic villus tissue. If a specific mutation is known to run in the family, prenatal molecular genetic testing can be performed. DNA sequencing can reveal if someone is a carrier for the disease. [2]
Because of the wide variety of phenotypes, the treatment for this disorder is specifically determined for each patient. Until recently, no effective therapy for MPS II was available, so palliative care was used. Recent advances, though, have led to medications that can improve survival and well-being in people with MPS II.[ citation needed ]
Idursulfase, a purified form of the missing lysosomal enzyme, underwent clinical trial in 2006 [6] and was subsequently approved by the United States Food and Drug Administration as an enzyme replacement treatment for MPS II. Idursulfase beta, another enzyme replacement treatment, was approved in Korea by the Ministry of Food and Drug Safety.
Recent advances in enzyme replacement therapy (ERT) with idursulfase have been proven to improve many signs and symptoms of MPS II, especially if started early in the disease. After administration, it can be transported into cells to break down GAGs, but as the medication cannot cross the blood–brain barrier, it is not expected to lead to cognitive improvement in patients with severe central nervous system symptoms. Even with ERT, treatment of various organ problems from a wide variety of medical specialists is necessary. [2]
Bone marrow transplantation and hematopoietic stem cell transplantation (HSCT) have been used as treatments in some studies. [7] [8] While transplantation has provided benefits for many organ systems, it has not been shown to improve the neurological symptoms of the disease. Although HSCT has shown promise in the treatment of other MPS disorders, its results have been unsatisfactory so far in the treatment of MPS II. ERT has been shown to lead to better outcomes in MPS II patients. [2]
In February 2019, medical scientists working with Sangamo Therapeutics, headquartered in Richmond, California, announced the first "in body" human gene editing therapy to permanently alter DNA – in a patient with MPS II. [9] Clinical trials by Sangamo involving gene editing using zinc finger nuclease are ongoing as of February 2019. [10]
Earlier onset of symptoms is linked to a worse prognosis. For children who exhibit symptoms between the ages of 2 and 4, death usually occurs by the age of 15 to 20 years. The cause of death is usually due to neurological complications, obstructive airway disease, and cardiac failure. If patients have minimal neurologic involvement, they may survive into their 50s or beyond. [1] [6]
An estimated 2,000 people have MPS II worldwide, 500 of whom live in the United States. [11]
A study in the United Kingdom indicated an incidence among males around one in 130,000 male live births. [12]
The syndrome is named after physician Charles A. Hunter (1873–1955), who first described it in 1917. [13] [14]
Beginning in 2010, a phase I/II clinical trial evaluated intrathecal injections of a more concentrated dose of idursulfase than the intravenous formulation used in enzyme replacement therapy infusions, in hopes of preventing the cognitive decline associated with the severe form of the condition. [15] Results were reported in October 2013. [16] A phase II/III clinical trial began in 2014. [17]
In 2017, a 44-year-old [18] patient with MPS II was treated with gene therapy in an attempt to prevent further damage by the disease. This is the first case of gene editing being used in vivo in humans. [19] The study was extended to six patients in 2018. [20]
On 24 July 2004, Andrew Wragg, 38, of Worthing, West Sussex, England, suffocated his 10-year-old son Jacob with a pillow, because of the boy's disabilities related to MPS II. A military security specialist, Wragg also claimed that he was under stress after returning from the Iraq War. He denied murdering Jacob, but pleaded guilty to manslaughter by reason of diminished capacity. Mrs Justice Anne Rafferty called the case "exceptional", gave Wragg a two-year prison sentence for manslaughter, then suspended his sentence for two years. Rafferty said "nothing [was] to be gained" from sending Wragg to prison for the crime. [21] [22] [23]
Sly syndrome, also called mucopolysaccharidosis type VII (MPS-VII), is an autosomal recessive lysosomal storage disease caused by a deficiency of the enzyme β-glucuronidase. This enzyme is responsible for breaking down large sugar molecules called glycosaminoglycans. The inability to break down GAGs leads to a buildup in many tissues and organs of the body. The severity of the disease can vary widely.
Mucopolysaccharidoses are a group of metabolic disorders caused by the absence or malfunctioning of lysosomal enzymes needed to break down molecules called glycosaminoglycans (GAGs). These long chains of sugar carbohydrates occur within the cells that help build bone, cartilage, tendons, corneas, skin and connective tissue. GAGs are also found in the fluids that lubricate joints.
Lysosomal storage diseases are a group of over 70 rare inherited metabolic disorders that result from defects in lysosomal function. Lysosomes are sacs of enzymes within cells that digest large molecules and pass the fragments on to other parts of the cell for recycling. This process requires several critical enzymes. If one of these enzymes is defective due to a mutation, the large molecules accumulate within the cell, eventually killing it.
Sanfilippo syndrome, also known as mucopolysaccharidosis type III (MPS III), is a rare genetic disease that mainly affects the brain and spinal cord. It is caused by a problem with how the body breaks down certain large sugar molecules called glycosaminoglycans (also known as GAGs or mucopolysaccharides). In children with this condition, these sugar molecules build up in the body and eventually lead to damage of the central nervous system and other organ systems.
Hurler syndrome, also known as mucopolysaccharidosis Type IH (MPS-IH), Hurler's disease, and formerly gargoylism, is a genetic disorder that results in the buildup of large sugar molecules called glycosaminoglycans (GAGs) in lysosomes. The inability to break down these molecules results in a wide variety of symptoms caused by damage to several different organ systems, including but not limited to the nervous system, skeletal system, eyes, and heart.
Metachromatic leukodystrophy (MLD) is a lysosomal storage disease which is commonly listed in the family of leukodystrophies as well as among the sphingolipidoses as it affects the metabolism of sphingolipids. Leukodystrophies affect the growth and/or development of myelin, the fatty covering which acts as an insulator around nerve fibers throughout the central and peripheral nervous systems. MLD involves cerebroside sulfate accumulation. Metachromatic leukodystrophy, like most enzyme deficiencies, has an autosomal recessive inheritance pattern.
Morquio syndrome, also known as mucopolysaccharidosis type IV (MPS IV), is a rare metabolic disorder in which the body cannot process certain types of sugar molecules called glycosaminoglycans (AKA GAGs, or mucopolysaccharides). In Morquio syndrome, the specific GAG which builds up in the body is called keratan sulfate. This birth defect, which is autosomal recessive, is a type of lysosomal storage disorder. The buildup of GAGs in different parts of the body causes symptoms in many different organ systems. In the US, the incidence rate for Morquio syndrome is estimated at between 1 in 200,000 and 1 in 300,000 live births.
Enzyme replacement therapy (ERT) is a medical treatment which replaces an enzyme that is deficient or absent in the body. Usually, this is done by giving the patient an intravenous (IV) infusion of a solution containing the enzyme.
Pseudo-Hurler polydystrophy, also referred to as mucolipidosis III, is a lysosomal storage disease closely related to I-cell disease. This disorder is called Pseudo-Hurler because it resembles a mild form of Hurler syndrome, one of the mucopolysaccharide (MPS) diseases.
Inclusion-cell (I-cell) disease, also referred to as mucolipidosis II, is part of the lysosomal storage disease family and results from a defective phosphotransferase. This enzyme transfers phosphate to mannose residues on specific proteins. Mannose-6-phosphate serves as a marker for proteins to be targeted to lysosomes within the cell. Without this marker, proteins are instead secreted outside the cell, which is the default pathway for proteins moving through the Golgi apparatus. Lysosomes cannot function without these proteins, which function as catabolic enzymes for the normal breakdown of substances in various tissues throughout the body. As a result, a buildup of these substances occurs within lysosomes because they cannot be degraded, resulting in the characteristic I-cells, or "inclusion cells" seen microscopically. In addition, the defective lysosomal enzymes normally found only within lysosomes are instead found in high concentrations in the blood, but they remain inactive at blood pH because they require the low lysosomal pH 5 to function.
An osteochondrodysplasia, or skeletal dysplasia, is a disorder of the development of bone and cartilage. Osteochondrodysplasias are rare diseases. About 1 in 5,000 babies are born with some type of skeletal dysplasia. Nonetheless, if taken collectively, genetic skeletal dysplasias or osteochondrodysplasias comprise a recognizable group of genetically determined disorders with generalized skeletal affection. These disorders lead to disproportionate short stature and bone abnormalities, particularly in the arms, legs, and spine. Skeletal dysplasia can result in marked functional limitation and even mortality.
Iduronidase, sold as Aldurazyme, is an enzyme with the systematic name glycosaminoglycan α-L-iduronohydrolase. It catalyses the hydrolysis of unsulfated α-L-iduronosidic linkages in dermatan sulfate.
In biochemistry, sulfatases EC 3.1.6.- are a class of enzymes of the esterase class that catalyze the hydrolysis of sulfate esters into an alcohol and a bisulfate:
Maroteaux–Lamy syndrome, or Mucopolysaccharidosis Type VI (MPS-VI), is an inherited disease caused by a deficiency in the enzyme arylsulfatase B (ARSB). ASRB is responsible for the breakdown of large sugar molecules called glycosaminoglycans. In particular, ARSB breaks down dermatan sulfate and chondroitin sulfate. Because people with MPS-VI lack the ability to break down these GAGs, these chemicals build up in the lysosomes of cells. MPS-VI is therefore a type of lysosomal storage disease.
Iduronate 2-sulfatase is a sulfatase enzyme associated with Hunter syndrome. It catalyses hydrolysis of the 2-sulfate groups of the L-iduronate 2-sulfate units of dermatan sulfate, heparan sulfate and heparin.
N-acetylglucosamine-6-sulfatase (EC 3.1.6.14, glucosamine (N-acetyl)-6-sulfatase, systematic name N-acetyl-D-glucosamine-6-sulfate 6-sulfohydrolase) is an enzyme that in humans is encoded by the GNS gene. It is deficient in Sanfilippo Syndrome type IIId. It catalyses the hydrolysis of the 6-sulfate groups of the N-acetyl-D-glucosamine 6-sulfate units of heparan sulfate and keratan sulfate
Scheie syndrome is a disease caused by a deficiency in the enzyme iduronidase, leading to the buildup of glycosaminoglycans (GAGs) in the body. It is the most mild subtype of mucopolysaccharidosis type I; the most severe subtype of this disease is called Hurler Syndrome.
Mucopolysaccharidosis type I is a spectrum of diseases in the mucopolysaccharidosis family. It results in the buildup of glycosaminoglycans due to a deficiency of alpha-L iduronidase, an enzyme responsible for the degradation of GAGs in lysosomes. Without this enzyme, a buildup of dermatan sulfate and heparan sulfate occurs in the body.
Emil Kakkis is an American medical geneticist known for his work to develop treatments for ultra rare disorders. He is the Founder of the Everylife Foundation for Rare Disease and Founder, CEO and President of Ultragenyx Pharmaceutical Inc.
Sangamo Therapeutics, Inc. is an American biotechnology company based in Brisbane, California. It applies cell and gene therapy to combat haemophilia and other genetic diseases.