Browsing Pathways

Congenital sucrase-isomaltase deficiency is a rare inborn error of metabolism (IEM) and autosomal recessive disorder caused by mutatins in the SI gene which encodes for the enzyme sucrase-isomaltase. Sucrase-isomaltase catalyzes the breakdown of sucrose, maltose and larger carbohydrates. Sucrose and maltose are disaccharides, and are broken down into simple sugars during digestion. Sucrose is broken down into glucose and fructose, while maltose is broken down into two glucose molecules. This disorder is characterized by stomach cramps, bloating, excess gas production, and diarrhea after ingestion of sucrose and maltose. These digestive problems can lead to failure to thrive and malnutrition. There is no cure for Sucrase-Isomaltase Deficiency, however orally administrated Sacrosidase can help relieve symptoms. Similarly, restricting high sugar diets can also help. Most affected children are better able to tolerate sucrose and maltose as they get older. Frequency of Sucrase-Isomaltase Deficiency is about 1 in 5,000 with European descent. 

Pyruvate carboxylase deficiency is caused by mutation in the pyruvate carboxylase gene. Serine—pyruvate aminotransferase catalyzes the reaction of serine and pyruvate to produce 3-hydroxypyruvate and L-alanine, as well as the reaction from L-alanine and glyodxylate to pyruvate and glycine. A defect in this results in accumulation of ammonia, glucose and pyruvate in blood; proline, lysine, citrulline, and alanine in plasma; and 2-oxoglutaric acid, fumaric acid, ketone bodies and succinate in urine. Symptoms include ataxia, lactic acidosis, mental retardation, metabolic acidosis, siezures, and dyspnea.

Adrenoleukodystrophy (ALD) is an X-linked recessive transmission disease. Central nervous system signs and symptoms have been consistently more prominent than signs of adrenal involvement. Behavioral changes are the most common initial finding and range from aggressive outbursts to withdrawal. Such behavior is generally accompanied by a gradually failing memory and poor school performance. Loss of vision is an early finding in some patients and is a prominent feature at some stage in most affected individuals. The initial visual loss appears as homonomous hemianopsia in some individuals and is usually associated with intact pupillary reflexes. Optic atrophy is less common as an initial finding but eventually develops in almost all cases. Gait disturbance is also an early finding and as is stiff-legged, unsteady and accompanied by hyperreflexia. In almost all cases there is spastic quadraplegia and a variable degree of decorticate posturing. Hearing loss, dysarthria and dysphagia develop at about the same time as gait disturbance. Seizures are a typical symptom in many affected individuals in the the end stages of the disease progression.

The normal response to a bacterial infection involves bacteria activateing the Toll-like receptor TLR4 on the membranes of macrophages, T-cells and dendritic cells. TLR4 activates the production of interferon regulatory factor 3 (IRF3), TIR-domain-containing adapter-inducing interferon-β (TRIF), signal transducer and activator of transcription 1 (STAT1) and nuclear factor kappa B (NF-kB) in the cytoplasm [1]. The NF-kB protein then goes to nucleus and activates expression of nitric oxide synthase (iNOS) which generates nitric oxide (NO). It also activates aconitate decarboxylase (Irg1), tumor necrosis factor (TNF), interleukin 6 (IL-6) and interleukin 1 beta (IL-1β). These are the pro-inflammatory proteins while nitric oxide (NO) is also a pro-inflammatory molecule that can lead to the production of oxidized tyrosines (i.e., nitrotyrosine). Similarly, the newly expressed IRF3 goes to the nucleus and activates the production of interferon beta (IFN- β), which is another pro-inflammatory cytokine. The whole collection of cytokines, TNF, IL-6, IL-1β and IFN-β move into the bloodstream and head to the brain and into the hypothalamus, leading to release of the hypothalamic corticotropin releasing hormone (CRH) [2]. CRH, in turn, activates the release of pituitary adrenocorticotropic hormone (ACTH), which then moves down through the blood stream towards the adrenal glands (located at the top of the kidneys) to produce cortisol and epinephrine. Cortisol and epinephrine stimulate the ”flight or fight” response, leading to the increased production of glucose from the liver (via glycogen breakdown) and the release of short-chain acylcarnitines (also from the liver) to help support beta-oxidation of fatty acids. These compounds support cell synthesis and growth of the macrophages and neutrophils used in the innate immune response. The liver also produces more IL-6, more TNF and more NO to further stimulate the innate immune response. Higher nitric oxide (NO) levels lead to blood vessel dilation and reduced blood pressure, which in its most extreme form, can be a major problem in sepsis. Higher iNOS expression in macrophages, neutrophils and dendritic cells consumes the amino acid arginine to produce more NO which disrupts the mitochondrial TCA cycle leading to the accumulation of citrate and the production of fatty acids and acylcarnitines (needed for lipid synthesis). Increased Irg1 (actonitate decarboxylase) expression leads to accumulation of succinate, which results in the succinylation of phosphofructokinase M2 (PKM2) [3]. Succinate also leads to the release of hypoxia inducible factor 1-alpha (HIF-1α) from its PHD-mediated inhibition. HIF-1α interacts with succinylated PKM2 and induces the expression of glycolytic genes such as Glut1 (the glucose transporter) and the pro-inflammatory cytokine IL-1β [3]. As a result of these metabolic changes and the deactivation of the oxidative phosphorylation pathway in their mitochondria, macrophages, neutrophils, T-cells and dendritic cells shift to aerobic glycolysis [4]. This leads to the production of more reactive oxygen species (ROS) which results in the oxidation of certain amino acids, such as methionine. This leads to the increased production of methionine sulfoxide (Met-SO). As the inflammatory response continues, more glucose and arginine in the bloodstream are consumed by dividing white blood cells to produce more lactate and more NO to further push the aerobic glycolytic pathway [4]. This aerobic glycolysis occurs primarily in white blood cells leading to active cell division and rapid white cell propagation (growing by a factor of three to four in a few hours). Hexokinase (HK) along with increased levels of lactate from aerobic glycolysis activate the inflammasome inside macrophages and dendritic cells, leading to the secretion of IL-1β. This cytokine further drives the aerobic glycolysis pathway for these white blood cells. All these signals and effects combine to lead to the rapid and sustained production of large numbers of macrophages, neutrophils, dendritic cells and T-cells to fight the bacterial infection. This often leads to a reduction in essential amino acids (threonine, lysine, tryptophan, leucine, isoleucine, valine, arginine) and a mild reduction in gluconeogenic acids (glycine, serine) in the bloodstram. The reduction in essential amino acids is intended to “starve” the invading bacteria (and other pathogens) of the amino acids they need to reproduce [4]. Some of the reduction in amino acid levels is moderated by the proteolysis of myosin in the muscle and the proteolysis of serum albumin in the blood (the most abundant protein in the blood, which is produced by the liver). These proteins act as amino acid reservoirs to help support rapid immune cell production. The loss of serum albumin in the blood to help support amino acid synthesis elsewhere can lead to hypoalbuminemia, a common feature of infections and inflammation. As the bacteria are cleared, the body goes into the anti-inflammatory response.

Kynurenine is a uremic toxin that is produced when a person has uremia or renal failure. Kynurenine is naturally synthesized in the body from tryptophan. Tryptophan is consumed through foods such as milk, eggs, chicken, turkey, and oats. Tryptophan is then transported from the small intestine into the blood by an amino acid transport. In the blood it travels to the liver and is transported into a hepatocyte by an amino acid transporter. The kynurenine pathway becomes dysregulated, potentially through over-stimulation by interferon gamma (IFNG). This hyperstimulation leads to large reductions in tryptophan levels as the indole dioxygenase (IDO) enzyme becomes more active. IDO activation results in the generation (from tryptophan) of large amounts of kynurenine (and its other metabolites) through a self-stimulating autocrine process. Kynurenine binds to the arylhydrocarbon receptor (AhR) found in most immune cells [5-7]. In addition to increased kynurenine production via IDO mediated synthesis, hyopalbuminemia can also lead to the release of bound kynurenine (and other immunosuppressive LysoPCs) into the bloodstream to fuel this kynurenine-mediated process. Regardless of the source of kynurenine, the kynurenine-bound AhR will migrate to the nucleus to bind to NF-kB which leads to more production of the IDO enzyme, which leads to more production of kynureneine and more loss of tryptophan. Kynurenine then enters the blood via a liver organic anion transporter such as solute carrier family 22 member 9. Kynurenine is shown to activate aryl hydrocarbon receptors that can lead to renal impairment, apoptosis, and kynurenine has also been found to disrupt the electron transport chain and oxidative phosphorylation causing muscle atrophy.

Molybdenium cofactor deficiency (Sulfite oxidase deficiency) is caused by mutations in the genes MOCS1 and MOCS2 in the formation of molybdenum cofactor. A molybdenum-containing cofactor is essential to the function of 3 enzymes: sulfite oxidase, xanthine dehydrogenase, and aldehyde oxidase. Xanthine dehydrogenase is a molybdenum-containing hydroxylase involved in the oxidative metabolism of purines. Defects in this enzyme cause accumulation of hypoxanthine,, s-s-sulfocysteine, taurine, and xanthine in the urine. Symptoms include hemorrhage, cerebral atrophy, encephalopathy, lactic acidosis, nystagmus, spastic diplegia/quadriplegia, and vomiting.

Familial Hypercholanemia can be caused by mutations in the TJP2, BAAT or EPHX1 genes which code for bile acid-CoA:amino acid N-acyltransferase, which plays a part in the metabolism of in bile acids. This enzyme plays a particularly important role in the hepatocytes of the liver. In this region the said enzyme is in part responsible for the catalysis of C24 bile acids (also known as choloneates) at a point preceding excretion into bile canaliculi. Bile is made up of many components, though two major ones are chenodeoxycholic acid and cholic acid. First, the bile acids undergo a process of conversion into acyl-CoA thioester. This occurs in two regions: in peroxisomes or endoplasmic reticulum (the latter are known as the secondary bile acids). Second, the bile acids undergo a process of conjugation which increases the detergent property, in particular in the intestine. In turn, the absorption of vitamins which are lipid soluble is faciliatated. In later steps, the deconjugation of bile acids is performed by bacteria and at this stage the bile acids are then returned to the liver to once again undergo the process of reconjugation. Familial hypercholanemia is characterized by increased bile acids in plasma. Symptoms include rickets and steatorrhea.

2-Methyl-3-hydroxybutyryl CoA dehydrogenase deficiency (Hydroxyl-CoA dehydrogenase deficiency; MHBD) is a rare inborn disease of metabolism caused by a mutation in the HSD17B10 gene which codes for 3-hydroxyacyl-CoA dehydrogenase type-2. A deficiency in this enzyme results in accumulation of L-lactic acid in blood, spinal fluid, and urine; 2-ethylhydracrylic acid, 2-methyl-3-hydroxybutyric acid, and tiglylglycine in urine. Symptoms include cerebal atrophy, motor and mental retardation, overactivity and behavior issues, seizures and progressive neurological defects leading to early death. Treatment includes a high carbohydrate and low protein diet.

Methylmalonic acidemia cause defects (Methylmalonaciduria due to methylmalonic CoA mutase; Acidemia, methylmalonic; MMA) in the metabolic pathway where methylmalonyl-coenzyme A (CoA) is converted into succinyl-CoA by the enzyme methylmalonyl-CoA mutase. Defects in the enzyme Methylmalonyl-CoA mutase causes accumulation of ammonia in blood; methylmalonic acid in plasma; creatinine and uric acid in serum; 3-Aminoisobutyric acid, 3-Hydroxypropionic acid, 3-Hydroxyvaleric acid, glycine, methylcitric acid and methylmalonic acid in urine; and methylmalonic acid in spinal fluid. Symptoms include anemia, dehydration, growth retardation, nephrosis, respiratory distress and metabolic acidosis.

Methylenetetrahydrofolate reductase deficiency (MTHFRD; Homocystinuria due to defect of n(5,10)-methylene THF deficiency) is caused by a defect in the MTHFR gene which codes for methylenetetrahydrofolate reductase. Methylenetetrahydrofolate reductase catalyzes the conversion of 5,10-methylenetetrahydrofolate to 5-methyltetrahydrofolate, a co-substrate for homocysteine remethylation to methionine. A defect in this enzyme results in accumulation of homocysteine and methionine in both plasma and urine. Some of the symptoms and signs include mental retardation, withdrawal, hallucinations, delusions, muscle weakness. Some patients remain asymptomatic until adulthood.