Carbohydrates account for a major portion of the human diet. These carbohydrates are composed of three principal monosaccharides: glucose, fructose and galactose; in addition glycogen is the storage form of carbohydrates in humans. The failure to effectively use these molecules accounts for the majority of the inborn errors of human carbohydrates metabolism.
Glycogen storage diseases are deficiencies of enzymes or transport proteins which impair glycogen synthesis, glycogen degradation or glycolysis. The two organs most commonly affected are the liver and the skeletal muscle. Glycogen storage diseases that affect the liver typically cause hepatomegaly and hypoglycemia; those that affect skeletal muscle cause exercise intolerance, progressive weakness and cramping.[1]
Lactose is a disaccharide sugar composed of galactose and glucose that is found in milk. Lactose can not be absorbed by the intestine and needs to be split in the small intestine into galactose and glucose by the enzyme called lactase; unabsorbed lactose can cause abdominal pain, bloating, diarrhea, gas, and nausea.[citation needed]
In most mammals, production of lactase diminishes after infants are weaned from maternal milk. However, 5% to 90% of the human population possess an advantageous autosomal mutation in which lactase production persists after infancy. The geographic distribution of lactase persistence is concordant with areas of high milk intake. Lactase non-persistence is common in tropical and subtropical countries. Individuals with lactase non-persistency may experience nausea, bloating and diarrhea after ingesting dairy.[citation needed]
Galactose
Galactosemia, the inability to metabolize galactose in liver cells, is the most common monogenic disorder of carbohydrate metabolism, affecting 1 in every 55,000 newborns.[2] When galactose in the body is not broken down, it accumulates in tissues. The most common signs are failure to thrive, hepatic insufficiency, cataracts and developmental delay. Long term disabilities include poor growth, mental retardation, and ovarian failure in females.[3]
Galactosemia is caused by mutations in the gene that makes the enzymegalactose-1-phosphate uridylyltransferase. Approximately 70% of galactosemia-causing alleles have a single missense mutation in exon 6. A milder form of galactosemia, called Galactokinase deficiency, is caused a lack of the enzyme uridine diphosphate galactose-4-epimerase which breaks down a byproduct of galactose. This type of is associated with cataracts, but does not cause growth failure, mental retardation, or hepatic disease. Dietary reduction of galactose is also the treatment but not as severe as in patients with classical galactosemia. This deficiency can be systemic or limited to red blood cells and leukocytes.[citation needed]
Screening is performed by measuring GAL-1-P urydil transferase activity. Early identification affords prompt treatment, which consists largely of eliminating dietary galactose.[citation needed]
Three autosomal recessive disorders impair fructose metabolism in liver cells. The most common is caused by mutations in the gene encoding hepatic fructokinase, an enzyme that catalyzes the first step in the metabolism of dietary fructose. Inactivation of the hepatic fructokinase results in asymptomatic fructosuria.[citation needed]
Hereditary fructose intolerance (HFI) results in poor feeding, failure to thrive, chronic liver disease and chronic kidney disease, and death. HFI is caused by a deficiency of fructose 1,6-biphosphate aldolase in the liver, kidney cortex and small intestine. Infants and adults are asymptomatic unless they ingest fructose or sucrose.[citation needed]
Deficiency of hepatic fructose 1,6-biphosphate (FBPase) causes impaired gluconeogenesis, hypoglycemia and severe metabolic acidemia. If patients are adequately supported beyond childhood, growth and development appear to be normal.[citation needed]
Essential fructosuria is a clinically benign condition characterized by the incomplete metabolism of fructose in the liver, leading to its excretion in urine.[citation needed]
The liver can also create glucose (gluconeogenesis, see below); during times of low carbohydrate supply from the digestive system, the liver creates glucose and supplies it to other organs.[4] Most enzymes of glycolysis also participate in gluconeogenesis, as it is mostly the reverse metabolic pathway of glycolysis; a deficiency of these liver enzymes will therefore impact both glycolysis and gluconeogenesis. (Note: gluconeogenesis is taking place only in the liver and not in other cells like e.g. muscle cells.)
Classic form: Symptoms usually appear in early childhood. Myopathy. Exercise-induced muscle cramps, weakness and sometimes rhabdomyolysis. Nausea and vomiting following strenuous exercise. Myoglobinuria, haemolytic anaemia, Hyperuricemia is common. High levels of bilirubin and jaundiced appearance possible. Late-onset form: Presents later in life. Myopathy, weakness and fatigue. Exercise intolerance (more than in GSD 5). Severe symptoms from classic type are absent. Infantile form: Rare. Often floppy infant syndrome (hypotonia), arthrogryposis, encephalopathy, cardiomyopathy and respiratory issues. Also central nervous system manifest possible, usually seizures. Hemolytic form: The defining characteristic is hemolytic anemia. Myopathy not as common. Rhabdomyolysis/myoglobinuria may cause acute renal failure.
Exercise test: Late about 3 times increase of lactate (higher than in GSD 5 and lower than in healthy). Increased rise of ammonia.[5]
No specific treatment. General advice is avoidance of vigorous exercise and of high-carbohydrate meals.
Muscle symptoms: Myopathy. Exercise intolerance, cramps. In some rhabdomyolysis and myoglobinuria. Liver symptoms: Hepatomegaly RBC symptoms: Hemolytic anemia. Rhabdomyolysis/myoglobinuria may cause acute renal failure.
Hemolytic anemia. Reticulocytosis and hyperbilirubinemia are common. Classical generalized form: Progressive neurologic dysfunction with dystonia, tremor, dyskinesia, pyramidal tract signs, cardiomyopathy and spinal motor neuron involvement with progressive neuromuscular impairment (severe weakness and muscle wasting).
Myopathic form: Progressive muscle weakness, pain, and cramping, particularly with exercise. Myoglobinuria possible. Myoglobinuria may cause acute renal failure. Hemolytic form: Hemolytic anemia. Neurologic form: In some central nervous system manifestation, including hemiplegic migraines, epilepsy, ataxia and tremor. Progressive neurologic impairment in some. Combinations of 1, 2 or all 3 forms have been reported.
Exercise test: ?
Regular blood transfusions for severe chronic anemia; splenectomy has been shown to be beneficial in some cases.
Myopathy. Exercise-induced myalgias, generalized muscle weakness and fatigability.
Exercise test: No rise of lactate. Biopsy: Focal sarcoplasmic accumulation of glycogen-beta particles. Immunohistochemistry and immunoblotting show reduced beta-enolase protein.
Transport proteins move substrates through cellular membranes. A glucose transporter (GLUT) protein is needed to assist glucose into (and in the liver and kidneys, also out of) the cell. De Vivo disease (GLUT1 deficiency) is a deficiency of GLUT1, which is needed to transport glucose across the blood-brain barrier. Fanconi-Bickel syndrome (GLUT2 deficiency, formally known as GSD-XI) is a deficiency of GLUT2, which is needed for the transport of glucose between liver and blood.
Mitochondrial pyruvate carrier deficiency (MPYCD) is a metabolic disorder, in which the transport of pyruvate from the cytosol to the mitochondria is affected (gene SLC54A1/BRP44L/MPC1[6]); the deficiency is characterized by delayed psychomotor development and lactic acidosis with a normal lactate/pyruvate ratio resulting from impaired mitochondrial pyruvate oxidation.[7] A similar disease is also seen in mutations of gene SLC54A2/BRP44/MPC2.[8]
PDHA1, DLD, PDHX, PDHB, DLAT, PDP1, LIAS Systemic/variousPyruvate dehydrogenase deficiency (PDHA deficiency, PDHAD, ataxia with lactic acidosis, intermittent ataxia with pyruvate dehydrogenase deficiency, pyruvate dehydrogenase complex deficiency, pyruvate decarboxylase deficiency, pyruvate dehydrogenase lipoic acid synthetase deficiency (PDHLD), some forms of Leigh Syndrome (genes PDHA1 and DLD))
2 major presentations: metabolic and neurologic. Between these 2 major presentations, there is a continuous spectrum of intermediate forms.[10] Those with predominantly neurological symptoms fit within the category of Leigh Syndrome.[10]
Broad clinical spectrum: From fatal lactic acidosis in the newborn to chronic neurologic dysfunction with structural abnormalities in the central nervous system without systemic acidosis. Most common cause of primary lactic acidosis in children.
Developmental delay and intellectual disability, delayed or absent speech, short stature, and congenital heart defects. Additional features reported.
Elevated plasma and urinary polyols (erythritol, arabitol, and ribitol) and urinary sugar-phosphates (ribose-5-phosphate and xylulose/ribulose-5-phosphate). Biopsy shows absent or low TKT.
Fasting hypoglycemia with lactic acidosis. Episodes of hyperventilation, apnea, and ketosis. Symptoms exacerbated by fructose, sucrose, and glycerol consumption.
G6PC: Liver SLC37A4 (G6PT1): Liver GSD type I (GSD 1, von Gierke's disease, hepatorenal glycogenosis, glucose-6-phosphate deficiency, glucose-6-phosphate transport defect)
Hypoglycemia and hepatomegaly. Growth retardation, delayed puberty, lactic acidemia, hyperlipidemia, hyperuricemia. In adults hepatic adenomas likely.
Exercise test: Normal lactate and ammonia rise.[11]
SCN4: A disorder of hematopoiesis. Maturation arrest of granulopoiesis at the level of promyelocytes. Neutropenia. Osteopenia, may lead to osteoporosis. Prone to recurrent infections. In some heart and genital abnormalities, cancerous conditions of the blood, seizures, developmental delay. Dursun syndrome: Pulmonary arterial hypertension, cardiac abnormalities (including secundum-type atrial septal defect), intermittent neutropenia, lymphopenia, monocytosis and anemia.
The enzyme glycogenin (GYG) is needed to create initial short glycogen chains, which are lengthened and branched by the other enzymes of glycogenesis.
Once eight glucose have been added to the glycogen chain, then glycogen synthase (GYS) can bind to the growing glycogen chain and add UDP-glucose to lengthen the glucogen chain.
Branches are made by glycogen branching enzyme (GBE), which transfers the end of the chain onto an earlier part, forming branches; these grow further grow by addition of more units.
Wide range of manifestations and severity. Commonly cleft lip and bifid uvula, hepatopathy, intermittent hypoglycemia, short stature, and exercise intolerance.
DNA Test: mutation on PGM1.
Walk test: Second Wind phenomenon in some,[12] but not all.[13] Observable with treadmill and heart rate monitor.
Muscle biopsy: shows glycogen accumulation. Blood test: Abnormal serum transferrin.
Non-ischemic forearm test: exercise-induced hyperammonemia with normal lactic acid rise.[14]
severe autosomal recessive neurodevelopmental disorder, presenting in early life with intractable seizures, absence of virtually all developmental milestones, visual impairment, progressive microcephaly and minor dysmorphic features[15]
Exercise test: ? Skeletal muscle biopsy: deficit of glycogen, predominance of slow-twitch, oxidative muscle fibers and mitochondrial proliferation. Endomyocardial biopsy: hypertrophic cardiomyocytes, enlarged nuclei and large centrally located vacuoles containing periodic acid Schiff (PAS)-positive material (but ultrastructurally different from glycogen). Glycogen depletion in the remainder of the cytoplasm.
GYS2: Liver GSD type 0a (GSD 0a, glycogen synthetase deficiency)
Infancy or in early childhood onset. Morning fatigue and fasting hypoglycemia, hyperketonemia. Without hepatomegaly, hyperalaninemia or hyperlactacidemia. After meals, major hyperglycemia associated with lactate and alanine increase and hyperlipidemia.
Neuropathy, affecting the central and peripheral nervous systems. Cognitive impairment, pyramidal tetraparesis, peripheral neuropathy, and neurogenic bladder. Peripheral neuropathy and progressive muscle weakness and stiffness (spasticity). Cerebellar dysfunction and extrapyramidal signs in some. Late-onset, slowly progressive.
An alternative to glycolysis is the Pentose phosphate pathway (PPP): Depending on cellular conditions the PPP can produce NADPH (another energy transport form in the cell) or synthesize riboses (important for substances based on ribose like e.g. RNA) - the PPP is for example important in red blood cells.
If glycogenolysis is taking place in the liver, G-6-P can be converted to glucose by the enzyme glucose 6-phosphatase (G6Pase); the glucose produced in the liver is then released to the bloodstream for use in other organs. Muscle cells in contrast do not have the enzyme glucose 6-phosphatase, so they cannot share their glycogen stores with the rest of the body.
In addition to glycogen breakdown with the glycogen debranching enzyme and the glycogen phosphorylase enzyme, cells also use the enzyme acid alpha-glucosidase in lysosomes to degrade glycogen.
A deficiency of an involved enzyme results in:
Accumulation of glycogen in the cells
Lack of cellular energy negatively affects the involved organs
Myophosphorylase (muscle glycogen phosphorylase) comes in two forms: form 'a' is phosphorylated by phosphorylase kinase, form 'b' is not phosphorylated. Form 'a' is de-phosphorylated into form 'b' by the enzyme phosphoprotein phosphatase, which is activated by elevated insulin.
Both forms 'a' and 'b' of myophosphorylase have two conformational states: active (R or relaxed) and inactive (T or tense). When either form 'a' or 'b' are in the active state, then the enzyme converts glycogen into glucose-1-phosphate.
Myophosphorylase-b is allosterically activated by elevated AMP within the cell, and allosterically inactivated by elevated ATP and/or glucose-6-phosphate. Myophosphorylase-a is active, unless allosterically inactivated by elevated glucose within the cell. In this way, myophosphorylase-a is the more active of the two forms as it will continue to convert glycogen into glucose-1-phosphate even with high levels of glycogen-6-phosphate and ATP. (See Glycogen phosphorylase§Regulation).
PYGL: Liver GSD type VI (GSD 6, Hers disease, hepatic glycogen phosphorylase deficiency, liver phosphorylase deficiency syndrome)
Hepatomegaly, failure to thrive, growth retardation. No other developmental delay, no muscle involvement. Hypoglycemia, lactic acidosis, hyperlipidemia and ketosis during prolonged fasting periods. Infancy or childhood onset, symptoms tend to improve with age.
PYGM: Muscle GSD type V (GSD 5, McArdle's disease, muscle phosphorylase deficiency, myophosphorylase deficiency, PYGM deficiency)
Myopathy: Exercise intolerance, symptoms tend to improve with rest. "Second wind" phenomenon in most. Some have hypertrophic calf muscles.[16] Rhabdomyolysis and myoglobinuria possible. Some have muscle weakness. Of those with muscle weakness, in two-thirds it worsens, however in some the muscle weakness is stable. Onset forms: infant, child, adult. Infant-form most severe (e.g. progressive respiratory failure), adult-onset can be very mild (e.g. mainly poor stamina).
Exercise test: Severely impaired rise of lactate. Normal or enhanced ammonia.[11][5][17] Exercise-induced inappropriate rapid heart rate and myogenic hyperuricemia.[18][19] "Second wind" observable with treadmill and heart rate monitor in a 12-minute walk test.[20][21]
GSD type IX (GSD 9, phosphorylase b kinase deficiency, PhK deficiency, liver glycogenosis) Formerly GSD type VIII (GSD 8)
GSD 9a: Liver form. Hepatomegaly, growth retardation, elevation of glutamate-pyruvate transaminase and glutamate-oxaloacetate transaminase, hypercholesterolemia, hypertriglyceridemia, and fasting hyperketosis. Improves with age, most adult patients are asymptomatic. GSD 9a1: PhK deficiency in erythrocytes. GSD 9a2: Normal PhK activity in erythrocytes. GSD 9b: Liver and muscle form. Additionally mild myopathy like GSD 9d. Rare. GSD 9c: Similar to GSD 9a, but tends to be more severe. In some hepatic fibrosis or cirrhosis.
PHKA1: Muscle GSD type IXd (GSD 9d, phosphorylase b kinase deficiency, PhK deficiency, muscle glycogenosis) Formerly GSD type VIII (GSD 8) Formerly GSD type Vb (GSD 5b)[22]
Myopathy. Exercise-induced muscle weakness or stiffness. Relative mild compared to other metabolic myopathies. Typically adult-onset, some asymptomatic in late adulthood. No liver involvement.
Exercise test: Both impaired and normal lactate observed; possible submaximal/maximal or aerobic/anaerobic discrepancy. Normal or exaggerated ammonia response.[23]
Symptoms of both GSD types IIa and IIb are very similar due to a defect in lysosomes. However, in type IIb, some show abnormal glycogen accumulation, but not all.
Classic infantile form (Pompe disease): Cardiomyopathy and muscular hypotonia. In some respiratory involvement. Juvenile and adult form: Myopathy of the skeletal muscles. Exercise intolerance. Some similarity to limb-girdle dystrophy. In some respiratory involvement. Non-classic infantile form: Less severe.
DNA test: Mutation in either GAA or LAMP2 gene. Pompe disease is autosomal recessive. Danon disease is X-linked dominant.
Muscle biopsy: Abnormal glycogen accumulation in lysosomes.
Mutations in the PRKAG2 gene have been traced to fatal congenital nonlysosomal cardiac glycogenosis; PRKAG2 is a noncatalytic gamma subunit of AMP-activated protein kinase (AMPK), which affects the release of G-1-P by phosphorylase kinase during nonlysosomal glycogenolysis.[24]
^Perenthaler, E., Nikoncuk, A., Yousefi, S. et al. Loss of UGP2 in brain leads to a severe epileptic encephalopathy, emphasizing that bi-allelic isoform-specific start-loss mutations of essential genes can cause genetic diseases. Acta Neuropathol 139, 415–442 (2020). https://doi.org/10.1007/s00401-019-02109-6
^Rodríguez-Gómez I, Santalla A, Díez-Bermejo J, Munguía-Izquierdo D, Alegre LM, Nogales-Gadea G, et al. (November 2018). "Non-osteogenic muscle hypertrophy in children with McArdle disease". Journal of Inherited Metabolic Disease. 41 (6): 1037–1042. doi:10.1007/s10545-018-0170-7. hdl:10578/19657. PMID29594644. S2CID4394513.
^Mineo I, Kono N, Hara N, Shimizu T, Yamada Y, Kawachi M, et al. (July 1987). "Myogenic hyperuricemia. A common pathophysiologic feature of glycogenosis types III, V, and VII". The New England Journal of Medicine. 317 (2): 75–80. doi:10.1056/NEJM198707093170203. PMID3473284.
^Pérez M, Ruiz JR, Fernández Del Valle M, Nogales-Gadea G, Andreu AL, Arenas J, Lucía A (June 2009). "The second wind phenomenon in very young McArdle's patients". Neuromuscular Disorders. 19 (6): 403–405. doi:10.1016/j.nmd.2009.04.010. PMID19477644. S2CID31541581.
