Lysosomal storage disorders: Pathology review

Last updated: November 01, 2022

Lysosomal storage disorders: Pathology review

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Bacterial structure and functions
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Schistosomes
Pediculus humanus and Phthirus pubis (Lice)
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Light microscopy and staining methods
Cardiac muscle histology
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Glycolysis
Citric acid cycle
Electron transport chain and oxidative phosphorylation
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Physiological changes during exercise
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Glycogen storage disease type I
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Leukodystrophy
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Krabbe disease
Gaucher disease (NORD)
Niemann-Pick disease types A and B (NORD)
Niemann-Pick disease type C
Fabry disease (NORD)
Tay-Sachs disease (NORD)
Mucopolysaccharide storage disease type 1 (Hurler syndrome) (NORD)
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Cystinosis
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Disorders of carbohydrate metabolism: Pathology review
Disorders of fatty acid metabolism: Pathology review
Dyslipidemias: Pathology review
Glycogen storage disorders: Pathology review
Lysosomal storage disorders: Pathology review
Disorders of amino acid metabolism: Pathology review
Carbohydrates and sugars
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Fat-soluble vitamin deficiency and toxicity: Pathology review
Zinc deficiency and protein-energy malnutrition: Pathology review
Water-soluble vitamin deficiency and toxicity: B1-B7: Pathology review
Human development days 1-4
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Questions

USMLE® Step 1 style questions USMLE

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A 3-year-old boy is being evaluated for developmental delay. He recently learned to sit up on his own; however, he is unable to stand up without support. His past medical history is significant for recurrent upper respiratory infections. His family is of Ashkenazi Jewish descent. Physical examination shows coarse facial features, kyphoscoliosis, and restricted joint mobility. Abdominal examination reveals hepatosplenomegaly. Ophthalmic examination reveals corneal clouding. A genetic condition is suspected. Which of the following intracellular processes are defective considering the most likely diagnosis? 

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At the pediatric clinic, Abigail, a 5-month-old girl of Ashkenazi Jewish descent, is brought in by her parents because of recurring episodes of seizures, which started about a month ago. Her parents have also noticed that Abigail startles easily at loud noises. Physical examination reveals a low muscle tone with exaggerated reflexes. Upon palpation of the abdomen, the liver and spleen are of normal size. On ophthalmologic examination, a cherry red spot is found on the maculae of both eyes. Next in the clinic, there’s 2-year-old Harry. According to his mother, he recently stopped walking and speaking in sentences, and instead started crawling and babbling again. On further questioning, his mother mentions that Harry seems to have a hard time sitting still and often shows aggressive behavior. Physical examination reveals a prominent forehead, a nose with a flattened bridge and flared nostrils, an enlarged tongue, and thickened lips. On ophthalmologic examination, no corneal clouding is observed.

Based on the initial presentation, both Abigail and Harry seem to have some form of lysosomal storage disorder. These are a group of inherited metabolic disorders that result in the inability to break down certain substances in lysosomes, causing them to build up, and ultimately leading to cell damage and death. Lysosomal storage disorders include sphingolipidoses, caused by the accumulation of a certain type of lipids called sphingolipids. Mucopolysaccharidoses are caused by the accumulation of a type of complex sugars called mucopolysaccharides or glycosaminoglycans. Finally, there’s also mucolipidoses, which are caused by the accumulation of both sphingolipids and mucopolysaccharides.

Okay, let’s start with sphingolipidoses! Gaucher disease is the most common lysosomal storage disorder. It is caused by a mutation in the GBA gene, which codes for the enzyme glucocerebrosidase, also known as beta-glucosidase. For your exams, remember that Gaucher disease is autosomal recessive, meaning that an individual needs to inherit two copies of the mutated gene, one from each parent, to develop the condition. Another thing to note is that Gaucher disease is more common in those of Ashkenazi Jewish heritage.

Now, glucocerebroside is a glycolipid that's included in the membrane of many different cells. When these cells become old or damaged, they are often engulfed by macrophages, and digested in their lysosomes. That’s where glucocerebrosidase breaks down glucocerebroside. In Gaucher disease, glucocerebroside can’t be broken down, so it accumulates inside the lysosomes of macrophages. These macrophages are called Gaucher cells and can build up in multiple organs and tissues, including the bone marrow, liver, and spleen. And that’s a high yield fact! Signs and symptoms vary depending on the tissue affected. So, if that's the bone marrow, there can be anemia with fatigue, and leukopenia with increased susceptibility to infections. Bone infarctions can also be caused by reduced blood flow to part of the bone, and can manifest as a painful “bone crisis” or result in physical deformity and avascular necrosis, or death of bone tissue, mostly involving the femur. These individuals may also be more susceptible to fractures due to osteoporosis. For your exams, another extremely high yield finding is hepatosplenomegaly, meaning that both the liver and spleen can become enlarged. And when platelets are sequestered, or trapped, within the enlarged spleen, this can cause thrombocytopenia or low platelet count, leading to bleeding and easy bruising. If glucocerebroside builds up in the brain, neurological symptoms can also appear, including loss of motor skills, hypotonia or decreased muscle tone, muscle spasms, seizures, and dysphagia or trouble swallowing. Over time, this can progress to severe breathing and feeding difficulties, which, if left untreated, can progress to death within the first few years of life.

Diagnosis of Gaucher disease relies on measuring glucocerebrosidase enzyme activity in white blood cells, as well as genetic testing, to look for mutations in the GBA gene. A high yield fact is that, on a tissue biopsy, Gaucher cells have a characteristic lipid-laden, or “fatty” appearance, similar to “crumpled tissue-paper.”

Treatment depends on the severity of the condition. Symptoms can be managed with supportive therapy. In addition, some individuals can get enzyme replacement therapy with a synthetic form of glucocerebrosidase, as well as substrate reduction therapy designed to block the production of glucocerebroside.

Another high yield sphingolipidosis is Tay-Sachs disease or TSD for short, which is an autosomal recessive disorder, caused by a mutation in the HEX-A gene. This results in hexosaminidase A, or HEX-A deficiency, which normally breaks down a GM2 ganglioside. GM2 is found mainly in neurons, so when it builds up inside lysosomes, it results in progressive neurodegeneration. For your exams, keep in mind that Tay-Sachs disease is also more common in those of Ashkenazi Jewish heritage. Symptoms typically begin between 2 and 6 months of age and include progressive loss of motor and cognitive skills, along with hypotonia or decreased muscle tone, hyperreflexia, or abnormally increased reflexes, seizures, hyperacusis, or increased sensitivity to normal sounds, as well as feeding problems and vision loss. What’s extremely important to remember is that GM2 can also build up in the retinal cells around the central macular area, causing a “cherry red spot” in the macula of the eye that can be seen with fundoscopy during an ophthalmologic examination. Diagnosis of TSD is done by determining the activity of HEX-A in serum, leukocytes, tears, or any other body tissue, as well as genetic testing to look for mutations in the HEX-A gene. On histologic exam, neurons are distended with cytoplasmic vacuoles due to lysosomes filled with GM2, which give a characteristic onion skin appearance. Treatment involves supportive care to manage symptoms.

Moving on to Fabry disease, this is caused by a mutation in the GLA gene that codes for alpha galactosidase A. For your exams, remember that this is an X-linked recessive disorder, which means that all carrier males develop the disease because they have only one X chromosome and thus one GLA gene available. On the other hand, females have two X chromosomes, so even if they have a defective GLA gene on one chromosome, they still have another functional one.

Now, alpha galactosidase A normally breaks down a sphingolipid called ceramide trihexoside, otherwise known as globotriaosylceramide or GL3 for short. Without alpha galactosidase A, GL3 builds up in the lysosomes of endothelial cells lining blood vessels, as well as cells of the peripheral nervous systems, kidney, and heart cells. Symptoms start in childhood and include a classic triad of peripheral neuropathy, hypohidrosis, and angiokeratomas. Peripheral neuropathy typically manifests as burning, tingling, prickling, and pain in the hands and feet, and is frequently triggered by exercise, fatigue, stress, or illness. Hypohidrosis means there’s a gradual decrease of sweating, which may progress to anhidrosis or an entire lack of sweating. And angiokeratomas are small reddish-purple rashes that usually appear around the lower abdomen and “bathing trunk” region of the body. In addition to this classic triad, individuals may present gastrointestinal symptoms like cramping, frequent bowel movements, constipation, or diarrhea. A slit lamp eye exam might also reveal a whorl-like pattern of brown or gray corneal opacities, called cornea verticillata, which results from GL3 buildup in the cornea, but remember that it doesn’t typically affect vision. Later on, individuals with Fabry disease can develop complications, such as kidney disease with progressive renal failure, cardiomyopathy with heart enlargement, and an increased risk of stroke.

Diagnosis of Fabry disease starts with blood tests showing low alpha galactosidase A levels, and is confirmed via genetic testing of the GLA gene.

Treatment options include enzyme replacement therapy with a synthetic alpha galactosidase A, or chaperone therapy with migalastat to help enhance residual enzyme activity.

Another sphingolipidoses is Krabbe disease, which originates from a mutation in the GALC gene, resulting in a deficiency of the enzyme galactocerebrosidase, also known as galactosylceramidase. Normally, galactocerebrosidase breaks down galactosylceramides, such as galactocerebroside and galactosylsphingosine, also known as psychosine. As a result, these molecules build up in the glial cells in the central and peripheral nervous system, resulting in demyelination and impaired nerve impulse transmission. The most important thing to remember for your exams is that demyelination occurs both in the central as well as the peripheral nervous system. Galactosylceramides can also accumulate inside macrophages, which become these gigantic, multinucleated macrophages called globoid cells that move in to clear out the damaged glial cells. And these globoid cells are a classic finding in Krabbe disease.

Symptoms typically begin before 6 months of age. Common symptoms of central nervous system demyelination include muscle stiffness, seizures, optic atrophy with visual disturbances, and developmental delay with difficulty in speaking, walking, or swallowing; while symptoms of peripheral nervous system demyelination may include loss of sensation in the extremities, along with hyporeflexia or diminished deep tendon reflexes. Unfortunately, most infants die by the age of two. Diagnosis is based on measuring the activity of galactocerebroside in leukocytes, along with genetic testing to look for mutations in the GALC gene. There’s no cure for Krabbe disease, so treatment is mainly supportive.

Next is metachromatic leukodystrophy or MLD, which is an autosomal recessive disorder caused by a mutation in the ARSA gene, which codes for arylsulfatase A. This enzyme normally breaks down cerebroside sulfate, so without it, sulfatide accumulates in neurons and myelin-producing cells of the central and peripheral nervous system, resulting in demyelination. What’s important to remember here is that symptoms vary by the age of onset. So, there’s a late infantile form, where symptoms develop within the first three years of life, and include severe muscle weakness, difficulty walking, irritability, and developmental delay, meaning a delay in reaching certain developmental milestones. In the juvenile form, symptoms usually develop between the age of 4 and adolescence, which is around 12 and 14 years of age, and include behavioral changes and decreased ability in school. In the adult form, symptoms usually develop after the age of 16 and include memory loss and psychosis. As the symptoms progress, all forms of MLD can result in blindness, paralysis, unresponsiveness, dementia, and psychosis.

Diagnosis is based on measuring arylsulfatase A enzyme activity in white blood cells, measuring the sulfatide levels in the urine, as well as genetic testing to confirm the ARSA gene mutation. A brain MRI might also show areas of hyperintensity in the white matter regions, which indicate the loss of myelin. And again, there’s no cure, so treatment involves supportive care to manage symptoms.

Okay, the last sphingolipidoses is Niemann-Pick disease, which is an autosomal recessive disorder, more common in those of Ashkenazi Jewish descent. There are three types of Niemann-Pick disease. So, in types A and B, there’s a mutation in the SMPD1 gene that causes a defect in the production of sphingomyelinase. This leads to an inability to break down sphingomyelin, which ends up accumulating in the lysosomes. In contrast, Niemann-Pick disease type C, or NPC, is caused by mutations in either the NPC1 or NPC2 genes. Normally, cholesterol is processed by lysosomes, then carried up to the lysosomal membrane by the NPC2 protein, and finally transported out of the lysosome and into the cytoplasm with the help of NPC1 protein, so that it can be incorporated into the cell membrane. So with NPC1 or NPC2 mutations, intracellular cholesterol transport is impaired, and instead, cholesterol ends up accumulating inside lysosomes.

Now, the accumulated sphingomyelin and cholesterol can affect many different kinds of cells, causing a variety of symptoms. The most common ones are progressive neurologic symptoms, but remember that these typically only appear in types A and C and can include a delay in reaching developmental motor milestones, like lifting the head or crawling, as well as a developmental regression, meaning that a child may lose certain developmental skills that they had previously acquired. In all three types, ophthalmologic examination may show a “cherry red spot” in the macula of the eye, resulting from the buildup of material in the retinal cells around the central macular area. Another high-yield symptom is hepatosplenomegaly, which is often accompanied by jaundice and thrombocytopenia, which causes easy bruising and bleeding issues. In a test question, you should compare Niemann-Pick disease to Tay-Sachs, which also has that cherry red macular spot and is more common in Ashkenazi Jews, but a key difference is that Tay-Sachs doesn’t cause hepatosplenomegaly.

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