Pyruvate Carboxylase Deficiency Disease
Pyruvate Carboxylase
Multiple Carboxylase Deficiency
Mannosidase Deficiency Diseases
Carbon-Carbon Ligases
Methylmalonyl-CoA Decarboxylase
Biotin
Carbamoyl-Phosphate Synthase I Deficiency Disease
Holocarboxylase Synthetase Deficiency
Carbon-Nitrogen Ligases
Immunologic Deficiency Syndromes
Biotinidase Deficiency
Multiple Sulfatase Deficiency Disease
Biotinidase
Amino Acid Metabolism, Inborn Errors
Carboxy-Lyases
Acetyl-CoA Carboxylase
Biotin-response organicaciduria. Multiple carboxylase defects and complementation studies with propionicacidemia in cultured fibroblasts. (1/12)
Fibroblast cultures from two individuals with biotin-responsive organicacidemia were found to have a pleiotropic deficiency of propionyl-CoA carboxylase, beta-methylcrotonyl-CoA carboxylase, and pyruvate carboxylase activities after growth in biotin limited culture medium, conditions which do not affect the carboxylase activities of normal cells. All three enzyme activities were restored to normal levels after transferring the mutant strains to biotin-rich medium. Both patients excreted abnormal levels of an array of metabolic intermediates, including beta-methylcrotonate, beta-hydroxyisovalerate, beta-hydroxypropionate, and lactate, which reflect metabolic blocks at all three carboxylase sites.14 mutants deficient in only propionyl-CoA carboxylase activity from patients with propionicacidemia and the two biotin-responsive strains were examined for complementation with seven previously mapped pcc mutants. No new pcc complementation groups were identified. Nine of the mutants were mapped to group pccA. The remaining 12 mutants mapped to pccBC or its B or C subgroups, confirming the complex nature of this group. The biotin-responsive mutants failed to complement each other but did complement mutants from all the pcc groups. Thus biotin-responsive organicacidemia is defined by a new complementation group, bio. The results obtained in this study suggest that the bio mutants have a defect of either biotin transport or a common holocarboxylase synthetase required for the biotin activation of all three mitochondrial carboxylases. (+info)The molecular basis of pyruvate carboxylase deficiency: mosaicism correlates with prolonged survival. (2/12)
(+info)The French and North American phenotypes of pyruvate carboxylase deficiency, correlation with biotin containing protein by 3H-biotin incorporation, 35S-streptavidin labeling, and Northern blotting with a cloned cDNA probe. (3/12)
Cultured skin fibroblasts from 16 patients with either French or American pyruvate carboxylase (PC) deficiency were examined for their ability to incorporate 3H-biotin into proteins. Cell extracts were also examined for the presence of biotin-containing proteins with 35S-streptavidin, immunoreactive protein with anti-PC antibody, and PC mRNA by Northern blotting with a PC cDNA probe. All the North American presentation patients showed a 3H-biotin protein, a streptavidin protein, and an anti-PC precipitable protein at 125 kilodaltons on sodium dodecyl sulfate-polyacrylamide gel electrophoresis of cellular proteins. They also showed a detectable mRNA species for PC on Northern blotting. Of the French presentation patients, five showed very low or absent 3H-biotin protein, streptavidin protein, and anti-PC precipitable protein at 125 kilodaltons. Three French presentation patients showed PC protein to be present on the basis of these techniques. Similarly, five showed either very low or absent mRNA for PC on Northern blotting whereas three gave evidence of the presence of PC-specific mRNA. Thus, whereas the North American presentation of PC deficiency is associated with the presence of a mature biotin containing protein of the correct molecular weight, the French presentation may, in some (but not in all) cases, have both absent PC protein and absent PC mRNA. (+info)Heterogeneity of holocarboxylase synthetase in patients with biotin-responsive multiple carboxylase deficiency. (4/12)
Holocarboxylase synthetase activity has been determined in fibroblasts of seven patients with the neonatal form of biotin-responsive multiple carboxylase deficiency. The normal Km for biotin was 15 +/- 3 nmol/l, while in the patients the values ranged from 48 to 1,062 nmol/l. The mean maximum velocity was 27% of normal. Differences among the values obtained for the Km for biotin and the heat stability of holocarboxylase synthetase suggested that the patients studied represented at least four distinct variants at the holocarboxylase synthetase locus. (+info)Inborn errors of metabolism. Vitamin-responsive genetic disease. (5/12)
The several ways in which vitamin administration may bring about a biochemical response in genetic abnormalities have been discussed. Two major interrelated lessons emerge from what we now know about vitamin-responsive genetic disease. First, it is possible to enhance metabolite flow through partially deficient reactions by suitable manipulation of the environment in which a fixed amount of enzyme functions or by changing the concentration of the enzyme itself. The latter approach may be the most versatile in the long run since there may be agents other than vitamins which increase enzyme concentrations. A striking example of such an effect in mammals is furnished by the work of Pitot and his collaborators, who by administration of casein hydrolysate to rats, increased threonine dehydratase activity several hundred-fold (Peraino and Pitot, 1964) by increasing the rate of enzyme synthesis (Jost, Khairallah, and Pitot, 1968). Other means of enhancing enzyme activities, ranging from tissue transplantation to transfer of genetic material, have been discussed elsewhere (for example, see Brady, 1973). These procedures will not be discussed here, other than to mention a recent report (Mukherjee and Krasner, 1973) who transferred several small plugs of liver tissue (approximately 5% of the liver) from normal rats to the livers of rats genetically deficient in bilirubin uridine diphosphate glucuronyltransferase activity. Twelve weeks later the specific activity of glucuronyltransferase had risen in the livers of the recipient rats to 6-23% of normal, and the serum bilirubin of these rats, which had initially been elevated, had fallen to close to, or within, the normal range. Thus liver grafts between suitably matched individuals, may in the near future, become a means of increasing hepatic activities of deficient enzymes to extents which are therapeutically meaningful. The second lesson to be learned from the review presented here is that enhancement of enzyme activity may be therapeutically beneficial even though the increase is small and the activity attained is still reduced relative to normal. It will be well to bear this in mind in any attempts to treat inborn errors of metabolism. (+info)Biotin in clinical medicine--a review. (6/12)
The recent developments in cofactor therapy of inherited biochemical disease has awakened interest in biotin as a therapeutic agent. This review briefly details the physiological and biochemical aspects of human biotin metabolism. The role of biotin in therapy of human disease is critically examined and the relevant literature extensively reviewed. It is our hope that this review will stimulate further clinical interest in the treatment of biotin-responsive human disorders. (+info)[3H]biotin-labeled proteins in cultured human skin fibroblasts from patients with pyruvate carboxylase deficiency. (7/12)
Biotin containing carboxylases in cultured human skin fibroblasts were radioactively labeled by addition of [8,9-3H]biotin to biotin-depleted cell cultures. Three major bands were visualized by fluorography after sodium dodecyl sulfate-polyacrylamide gel electrophoresis of the fibroblast proteins. These bands corresponded to pyruvate carboxylase (Mr = 125,000), the biotin-containing subunit of methyl crotonyl-CoA carboxylase (Mr = 75,000) and the biotin-containing subunit of propionyl-CoA carboxylase (Mr = 73,000) as judged by molecular weight markers, purified carboxylase protein standards, and interaction with monospecific antisera. Four out of 5 cell lines from patients with classical pyruvate carboxylase deficiency (less than 5% of normal activity) labeled with this technique displayed a normal band in the position of pyruvate carboxylase while one cell line showed complete absence of any labeled protein in this area. These results demonstrate heterogeneity in the etiology of pyruvate carboxylase deficiency. (+info)The molecular basis for the two different clinical presentations of classical pyruvate carboxylase deficiency. (8/12)
Eight cases of isolated human pyruvate carboxylase deficiency were examined from seven families. Although all patients presented with a chronic lacticacidemia, two particular patients presented with the added features of hyperammonemia, citrullinemia, and hyperlysinemia. When cultured skin fibroblasts from these patients were examined for their ability to synthesize [3H]biotin-containing proteins, it was found that the two patients who presented with hyperammonemia, citrullinemia, and hyperlysinemia did not synthesise a protein of the correct subunit molecular weight (Mr = 125 K daltons) corresponding to pyruvate carboxylase. In addition, when skin fibroblast proteins were labeled with [35S]methionine, cross-reacting material (CRM) corresponding to pyruvate carboxylase was immunoprecipitated by antipyruvate carboxylase antiserum in most patients, but again the two patients with the atypical presentation showed no CRM. We propose that the different clinical presentation of human pyruvate carboxylase deficiency is a manifestation of two different mutations in the pyruvate carboxylase gene, one that results in the synthesis of a relatively inactive pyruvate carboxylase protein CRM(+ve) and one that results in the lack of expression of the gene in the form of a recognizable protein CRM(-ve). (+info)Pyruvate carboxylase deficiency disease is a rare inherited metabolic disorder that affects the body's ability to break down proteins, fats, and carbohydrates for energy. It is caused by mutations in the Pyruvate Carboxylase (PC) gene, which provides instructions for making an enzyme called pyruvate carboxylase. This enzyme plays a critical role in gluconeogenesis, a process that takes place in the liver and kidneys to produce glucose, a simple sugar that is a primary source of energy for the body.
In pyruvate carboxylase deficiency disease, the enzyme's activity is significantly reduced or absent, leading to an accumulation of toxic levels of certain metabolic intermediates, such as lactic acid and pyruvic acid, in the blood and other tissues. This accumulation can cause a range of symptoms, including developmental delay, seizures, poor muscle tone, difficulty breathing, and feeding problems.
The severity of pyruvate carboxylase deficiency disease varies widely, depending on the degree of enzyme activity that is affected. Some individuals may have mild symptoms, while others may experience severe, life-threatening complications. Treatment typically involves managing symptoms and providing supportive care to help prevent complications. In some cases, a low-protein diet or supplementation with certain vitamins and minerals may be recommended to help reduce the accumulation of toxic metabolites.
Pyruvate carboxylase is a biotin-containing enzyme that plays a crucial role in gluconeogenesis, the process of generating new glucose molecules from non-carbohydrate sources. The enzyme catalyzes the conversion of pyruvate to oxaloacetate, an important intermediate in several metabolic pathways, particularly in the liver, kidneys, and brain.
The reaction catalyzed by pyruvate carboxylase is as follows:
Pyruvate + CO2 + ATP + H2O → Oxaloacetate + ADP + Pi + 2H+
In this reaction, pyruvate reacts with bicarbonate (HCO3-) to form oxaloacetate, consuming one molecule of ATP in the process. The generation of oxaloacetate provides a key entry point for non-carbohydrate precursors, such as lactate and certain amino acids, to enter the gluconeogenic pathway.
Pyruvate carboxylase deficiency is a rare but severe genetic disorder that can lead to neurological impairment and developmental delays due to the disruption of energy metabolism in the brain.
Multiple carboxylase deficiency (MCD) is a rare genetic disorder that affects the body's ability to metabolize certain amino acids, particularly those that contain sulfur. It is caused by mutations in the genes responsible for producing enzymes involved in the biotin-dependent carboxylation reactions, which are critical for various metabolic processes in the body.
There are two major types of MCD:
1. Profound multiple carboxylase deficiency (also known as Type II biotinidase deficiency): This form is more severe and is caused by a defect in the holocarboxylase synthetase enzyme, which is responsible for attaching biotin to several carboxylases.
2. Biotin-responsive multiple carboxylase deficiency (also known as Type I biotinidase deficiency): This form is milder and is caused by a defect in the biotinidase enzyme, which recycles biotin in the body. However, it can be treated with biotin supplementation.
Symptoms of MCD may include:
* Developmental delay
* Seizures
* Hypotonia (low muscle tone)
* Ataxia (lack of coordination)
* Rash
* Hair loss
* Acidosis (high levels of acid in the body)
* Coma and even death, if left untreated
Early diagnosis and treatment with biotin supplementation can significantly improve outcomes for individuals with MCD.
Mannosidosis is a rare inherited metabolic disorder caused by a deficiency of the enzyme alpha-mannosidase, which is responsible for breaking down complex sugar molecules called mannose-rich oligosaccharides. When the enzyme is not functioning properly, these sugar molecules accumulate in various tissues and organs, leading to progressive damage.
There are two main types of Mannosidosis: type I (also known as classic Mannosidosis) and type II (also known as mild or attenuated Mannosidosis). The symptoms and severity of the disease can vary widely between individuals and between the two types, but may include developmental delays, intellectual disability, coarse facial features, skeletal abnormalities, hearing loss, recurrent respiratory infections, and vision problems.
The diagnosis of Mannosidosis is typically made through enzyme assay and genetic testing. Treatment is primarily supportive and may include physical therapy, speech therapy, hearing aids, and management of respiratory and other medical issues as they arise. In some cases, bone marrow transplantation may be considered as a treatment option.
Carbon-carbon ligases are a type of enzyme that catalyze the formation of carbon-carbon bonds between two molecules. These enzymes play important roles in various biological processes, including the biosynthesis of natural products and the metabolism of carbohydrates and lipids.
Carbon-carbon ligases can be classified into several categories based on the type of reaction they catalyze. For example, aldolases catalyze the condensation of an aldehyde or ketone with another molecule to form a new carbon-carbon bond and a new carbonyl group. Other examples include the polyketide synthases (PKSs) and nonribosomal peptide synthetases (NRPSs), which are large multienzyme complexes that catalyze the sequential addition of activated carbon units to form complex natural products.
Carbon-carbon ligases are important targets for drug discovery and development, as they play critical roles in the biosynthesis of many disease-relevant molecules. Inhibitors of these enzymes have shown promise as potential therapeutic agents for a variety of diseases, including cancer, infectious diseases, and metabolic disorders.
Methylmalonyl-CoA decarboxylase is a mitochondrial enzyme that plays a crucial role in the metabolism of certain amino acids and fatty acids. Specifically, it catalyzes the conversion of methylmalonyl-CoA to propionyl-CoA through the decarboxylation of the thioester bond.
The reaction is as follows:
Methylmalonyl-CoA → Propionyl-CoA + CO2
This enzyme requires biotin as a cofactor, and its activity is reduced in individuals with methylmalonic acidemia, a rare inherited metabolic disorder caused by mutations in the MMAB or MCEE genes that encode subunits of the methylmalonyl-CoA decarboxylase enzyme complex.
Deficiency of this enzyme leads to an accumulation of methylmalonic acid and methylmalonyl-CoA, which can cause metabolic acidosis, hyperammonemia, and other symptoms associated with the disorder.
Biotin is a water-soluble vitamin, also known as Vitamin B7 or Vitamin H. It is a cofactor for several enzymes involved in metabolism, particularly in the synthesis and breakdown of fatty acids, amino acids, and carbohydrates. Biotin plays a crucial role in maintaining healthy skin, hair, nails, nerves, and liver function. It is found in various foods such as nuts, seeds, whole grains, milk, and vegetables. Biotin deficiency is rare but can occur in people with malnutrition, alcoholism, pregnancy, or certain genetic disorders.
Carbamoyl-phosphate synthase I (CPS1) deficiency disease is a rare inherited disorder of urea synthesis, which can lead to hyperammonemia (elevated blood ammonia levels) and life-threatening neurological symptoms. CPS1 is an enzyme that plays a crucial role in the first step of the urea cycle, where it catalyzes the conversion of ammonia and bicarbonate into carbamoyl phosphate.
In CPS1 deficiency disease, mutations in the CPS1 gene lead to reduced or absent enzyme activity, impairing the body's ability to detoxify ammonia. As a result, toxic levels of ammonia accumulate in the blood and can cause irreversible brain damage, intellectual disability, coma, or even death if not treated promptly and effectively.
Symptoms of CPS1 deficiency disease may include poor feeding, vomiting, lethargy, hypotonia (low muscle tone), seizures, and developmental delays. The severity of the disorder can vary widely, from a severe neonatal-onset form with early symptoms appearing within the first few days of life to a milder late-onset form that may not become apparent until later in infancy or childhood.
Treatment typically involves a combination of dietary restrictions, medications to lower ammonia levels and support liver function, and, in some cases, liver transplantation. Early diagnosis and intervention are critical for improving outcomes and minimizing the risk of long-term neurological complications.
Holocarboxylase Synthetase Deficiency (HCD) is a rare genetic disorder of biotin metabolism, characterized by the body's inability to properly utilize the vitamin biotin. Biotin plays a crucial role in various essential functions, such as the breakdown of fats, proteins, and carbohydrates, as well as the regulation of gene expression.
Holocarboxylase synthetase is an enzyme responsible for attaching biotin to four different carboxylases, which are necessary for these vital processes. In Holocarboxylase Synthetase Deficiency, this enzyme is either partially or completely nonfunctional due to mutations in the HLCS gene.
The symptoms of HCD can vary widely but often include:
1. Feeding difficulties and poor growth in infancy
2. Severe metabolic acidosis
3. Ketoacidosis
4. Delayed development
5. Hypotonia (low muscle tone)
6. Skin rashes
7. Hair loss
8. Neurological symptoms, such as seizures and ataxia (loss of coordination and balance)
If left untreated, Holocarboxylase Synthetase Deficiency can lead to severe complications, including developmental delays, neurological damage, and even death. However, with early diagnosis and proper treatment involving biotin supplementation, many of these symptoms can be managed, and the progression of the disorder can be slowed or stopped.
Carbon-Nitrogen (C-N) ligases are a class of enzymes that catalyze the joining of a carbon atom from a donor molecule to a nitrogen atom in an acceptor molecule through a process called ligase reaction. This type of enzyme plays a crucial role in various biological processes, including the biosynthesis of amino acids, nucleotides, and other biomolecules that contain both carbon and nitrogen atoms.
C-N ligases typically require ATP or another energy source to drive the reaction forward, as well as cofactors such as metal ions or vitamins to facilitate the chemical bond formation between the carbon and nitrogen atoms. The specificity of C-N ligases varies depending on the enzyme, with some acting only on specific donor and acceptor molecules while others have broader substrate ranges.
Examples of C-N ligases include glutamine synthetase, which catalyzes the formation of glutamine from glutamate and ammonia, and asparagine synthetase, which catalyzes the formation of asparagine from aspartate and ammonia. Understanding the function and regulation of C-N ligases is important for understanding various biological processes and developing strategies to modulate them in disease states.
Immunologic deficiency syndromes refer to a group of disorders characterized by defective functioning of the immune system, leading to increased susceptibility to infections and malignancies. These deficiencies can be primary (genetic or congenital) or secondary (acquired due to environmental factors, medications, or diseases).
Primary immunodeficiency syndromes (PIDS) are caused by inherited genetic mutations that affect the development and function of immune cells, such as T cells, B cells, and phagocytes. Examples include severe combined immunodeficiency (SCID), common variable immunodeficiency (CVID), Wiskott-Aldrich syndrome, and X-linked agammaglobulinemia.
Secondary immunodeficiency syndromes can result from various factors, including:
1. HIV/AIDS: Human Immunodeficiency Virus infection leads to the depletion of CD4+ T cells, causing profound immune dysfunction and increased vulnerability to opportunistic infections and malignancies.
2. Medications: Certain medications, such as chemotherapy, immunosuppressive drugs, and long-term corticosteroid use, can impair immune function and increase infection risk.
3. Malnutrition: Deficiencies in essential nutrients like protein, vitamins, and minerals can weaken the immune system and make individuals more susceptible to infections.
4. Aging: The immune system naturally declines with age, leading to an increased incidence of infections and poorer vaccine responses in older adults.
5. Other medical conditions: Chronic diseases such as diabetes, cancer, and chronic kidney or liver disease can also compromise the immune system and contribute to immunodeficiency syndromes.
Immunologic deficiency syndromes require appropriate diagnosis and management strategies, which may include antimicrobial therapy, immunoglobulin replacement, hematopoietic stem cell transplantation, or targeted treatments for the underlying cause.
Biotinidase deficiency is a genetic disorder that affects the body's ability to recycle and reuse biotin, a type of B vitamin. Biotinidase is an enzyme that helps release biotin from proteins in the food we eat and recycle it for use by the body.
In people with biotinidase deficiency, the biotinidase enzyme is either partially or completely missing, leading to a decrease in available biotin. This can result in a variety of symptoms, including seizures, developmental delays, hearing and vision loss, skin rashes, hair loss, and muscle weakness.
There are two main types of biotinidase deficiency: partial deficiency and profound deficiency. Partial deficiency means that some biotinidase activity is present, but not enough to prevent symptoms. Profound deficiency means that there is little or no biotinidase activity, resulting in more severe symptoms.
Biotinidase deficiency can be diagnosed through a blood test that measures the level of biotinidase enzyme activity. Treatment typically involves taking biotin supplements to replace the missing biotin and prevent symptoms from developing or worsening. With early diagnosis and treatment, people with biotinidase deficiency can often lead normal lives.
Multiple sulfatase deficiency (MSD) is a rare inherited metabolic disorder that affects multiple organ systems in the body. It is caused by mutations in the SUMF1 gene, which provides instructions for making an enzyme called formylglycine-generating enzyme (FGE). FGE is essential for the function of several sulfatase enzymes, which are responsible for removing sulfate groups from certain sugar molecules attached to proteins and lipids.
In MSD, the activity of all or most of these sulfatase enzymes is reduced or absent, leading to the accumulation of sulfated molecules in various tissues and organs. This can result in a wide range of symptoms that typically appear in infancy or early childhood, including developmental delay, intellectual disability, coarse facial features, skeletal abnormalities, vision and hearing loss, and problems with mobility and coordination.
MSD is an autosomal recessive disorder, which means that an individual must inherit two copies of the mutated gene (one from each parent) in order to develop the disease. The incidence of MSD is estimated to be less than 1 in 1 million people worldwide. Currently, there is no cure for MSD and treatment is focused on managing symptoms and improving quality of life.
Biotinidase is an enzyme that is responsible for the release of biotin, a vital nutrient, from proteins in the body. Biotin is essential for various metabolic processes, including the synthesis of fatty acids and glucose. Biotinidase deficiency can lead to serious health problems, such as seizures, developmental delays, and hearing and vision loss. Therefore, biotinidase levels are often measured in newborn screening tests to identify babies who may be at risk for this rare but treatable condition.
Inborn errors of amino acid metabolism refer to genetic disorders that affect the body's ability to properly break down and process individual amino acids, which are the building blocks of proteins. These disorders can result in an accumulation of toxic levels of certain amino acids or their byproducts in the body, leading to a variety of symptoms and health complications.
There are many different types of inborn errors of amino acid metabolism, each affecting a specific amino acid or group of amino acids. Some examples include:
* Phenylketonuria (PKU): This disorder affects the breakdown of the amino acid phenylalanine, leading to its accumulation in the body and causing brain damage if left untreated.
* Maple syrup urine disease: This disorder affects the breakdown of the branched-chain amino acids leucine, isoleucine, and valine, leading to their accumulation in the body and causing neurological problems.
* Homocystinuria: This disorder affects the breakdown of the amino acid methionine, leading to its accumulation in the body and causing a range of symptoms including developmental delay, intellectual disability, and cardiovascular problems.
Treatment for inborn errors of amino acid metabolism typically involves dietary restrictions or supplementation to manage the levels of affected amino acids in the body. In some cases, medication or other therapies may also be necessary. Early diagnosis and treatment can help prevent or minimize the severity of symptoms and health complications associated with these disorders.
Carboxy-lyases are a class of enzymes that catalyze the removal of a carboxyl group from a substrate, often releasing carbon dioxide in the process. These enzymes play important roles in various metabolic pathways, such as the biosynthesis and degradation of amino acids, sugars, and other organic compounds.
Carboxy-lyases are classified under EC number 4.2 in the Enzyme Commission (EC) system. They can be further divided into several subclasses based on their specific mechanisms and substrates. For example, some carboxy-lyases require a cofactor such as biotin or thiamine pyrophosphate to facilitate the decarboxylation reaction, while others do not.
Examples of carboxy-lyases include:
1. Pyruvate decarboxylase: This enzyme catalyzes the conversion of pyruvate to acetaldehyde and carbon dioxide during fermentation in yeast and other organisms.
2. Ribulose-1,5-bisphosphate carboxylase/oxygenase (RuBisCO): This enzyme is essential for photosynthesis in plants and some bacteria, as it catalyzes the fixation of carbon dioxide into an organic molecule during the Calvin cycle.
3. Phosphoenolpyruvate carboxylase: Found in plants, algae, and some bacteria, this enzyme plays a role in anaplerotic reactions that replenish intermediates in the citric acid cycle. It catalyzes the conversion of phosphoenolpyruvate to oxaloacetate and inorganic phosphate.
4. Aspartate transcarbamylase: This enzyme is involved in the biosynthesis of pyrimidines, a class of nucleotides. It catalyzes the transfer of a carboxyl group from carbamoyl aspartate to carbamoyl phosphate, forming cytidine triphosphate (CTP) and fumarate.
5. Urocanase: Found in animals, this enzyme is involved in histidine catabolism. It catalyzes the conversion of urocanate to formiminoglutamate and ammonia.
Acetyl-CoA carboxylase (ACCA) is a biotin-dependent enzyme that plays a crucial role in fatty acid synthesis. It catalyzes the conversion of acetyl-CoA to malonyl-CoA, which is the first and rate-limiting step in the synthesis of long-chain fatty acids. The reaction catalyzed by ACCA is as follows:
acetyl-CoA + HCO3- + ATP + 2H+ --> malonyl-CoA + CoA + ADP + Pi + 2H2O
ACCA exists in two isoforms, a cytosolic form (ACC1) and a mitochondrial form (ACC2). ACC1 is primarily involved in fatty acid synthesis, while ACC2 is responsible for the regulation of fatty acid oxidation. The activity of ACCA is regulated by several factors, including phosphorylation/dephosphorylation, allosteric regulation, and transcriptional regulation. Dysregulation of ACCA has been implicated in various metabolic disorders, such as obesity, insulin resistance, and non-alcoholic fatty liver disease.
Ligases are a group of enzymes that catalyze the formation of a covalent bond between two molecules, usually involving the joining of two nucleotides in a DNA or RNA strand. They play a crucial role in various biological processes such as DNA replication, repair, and recombination. In DNA ligases, the enzyme seals nicks or breaks in the phosphodiester backbone of the DNA molecule by catalyzing the formation of an ester bond between the 3'-hydroxyl group and the 5'-phosphate group of adjacent nucleotides. This process is essential for maintaining genomic integrity and stability.