Amino Acid Degradation and the Urea Cycle PDF

Summary

This document provides a detailed overview of amino acid biosynthesis, catabolism, and the urea cycle. It highlights the processes involved and the different metabolic pathways. It also explores the use of amino acids as fuel sources and the role of the urea cycle in detoxification. The document is aimed at a postgraduate level.

Full Transcript

# Amino Acid Biosynthesis and Catabolism

## Amino Acid Biosynthesis

- **Glycolysis and the TCA cycle provide carbon skeletons for amino acid biosynthesis.**
- **Alanine, glutamate, and aspartate are synthesized by transamination of the corresponding α-keto acids.**

**Amino acids synthesized by humans:**

- **Cysteine**
- **Glycine**
- **Serine**
- **Asparagine**
- **Aspartate**
- **Proline**
- **Glutamate**
- **Alanine**
- **Threonine**
- **Cystathionine**
- **Lysine**
- **Methionine**
- **Isoleucine**
- **Leucine**
- **Valine**
- **Ornithine**
- **Glutamine**
- **Citrulline**
- **Histidine**
- **Arginine**
- **Tryptophan**
- **Tyrosine**
- **Phenylalanine**

## Overview of Amino Acid Catabolism

- **Once broken down to amino acid, all types of protein are treated the same way, dependent on the organism's energy needs.**

**Two main fates for amino acids:**

1. **Recycled into new proteins.**
2. **Oxidized for energy:**

- **Removal of amino group (urea cycle).**
- **Entry into central metabolism (glycolysis, citric acid cycle).**

## The Use of Amino Acids as Fuel Varies Greatly by Organism

- **About 90% of energy needs of carnivores can be met by amino acids immediately after a meal.**
- **Microorganisms scavenge amino acids from their environment for fuel when needed.**
- **Only a small fraction of energy needs of herbivores are met by amino acids.**
- **Plants do not use amino acids as a fuel source, but can degrade amino acids to form other metabolites.**

## Metabolic Circumstances of Amino Acid Oxidation

- **Leftover amino acids from normal protein turnover (e.g., proteolysis and regeneration of proteins).**
- **Dietary amino acids that exceed body's protein synthesis needs.**
- **Proteins in the body can be broken down to supply amino acids for energy when carbohydrates are scarce (starvation, diabetes mellitus).**

## You Are Not Protein Deficient

- The **National Academy of Medicine recommends that adults get about 0.8 grams of protein a day for every kilogram they weigh.**
- This is about **7 grams for every 20 pounds.**
- **Babies and children need a bit more**, ranging from 1.2 grams per kilogram for infants to 0.85 grams per kilogram for teens.

**Special Considerations:**

- **Vegans should eat grains and beans to get enough methionine and lysine.**

## Degradation of All Amino Acids Begins with Removal of the Amino Nitrogen by Transaminases or Direct Deamination

- **Alanine aminotransferase and aspartate aminotransferase transfer amino groups to glutamate.**
- **Pyruvate and oxaloacetate can enter metabolism directly - gluconeogenesis or TCA cycle.**

**Some amino acids can be directly deaminated:**

- **Serine → pyruvate + NH₄⁺**
- **Threonine → α-ketobutyrate + NH₄⁺**

## The Two Major Sites of Amino Acid Degradation Are Muscle and Liver

- **Muscle, especially during prolonged fasting, can use branched chain amino acids as a major energy source.**
- **However, muscle lacks the enzymes of the urea cycle so cannot process NH₄⁺ released by deamination of amino acids.**
- **Liver is the principal site of breakdown of other amino acids, and also for processing of NH₄⁺ by the urea cycle.**

## In Muscle, α-Ketoacid Dehydrogenase Processes Branched-Chain Amino Acids

- **The branched-chain amino acids - leucine, isoleucine, and valine are used as fuels by muscle tissue.**
- **They are converted into acetyl CoA, succinyl CoA, and acetoacetyl CoA using reactions similar to those of the citric acid cycle and fatty acid oxidation.**
- **The branched-chain α-ketoacid dehydrogenase complex, which is similar to the pyruvate dehydrogenase complex and the α-ketoglutarate dehydrogenase complex, processes these amino acids.**

- **Branched-chain α-keto acid + NAD⁺ + CoA → CoA derivative + CO₂ + NADH + H⁺**

## The Carbon Skeletons of the Amino Acids Are Metabolized to Seven Major Metabolic Intermediates

- **Acetoacetyl CoA, acetyl CoA, pyruvate, succinyl CoA, fumarate, α-ketoglutarate, oxaloacetate.**

- **When amino acids are metabolized to acetyl CoA and acetoacetyl CoA, they are called ketogenic amino acids, because they can form fats but not glucose.**

- **When amino acids are degraded to the remaining major intermediates, they are called gluconeogenic amino acids, because they can be used to synthesize glucose.**

- **Only leucine and lysine are solely ketogenic.**
- **Other amino acids can be glucogenic OR ketogenic.**

## Ammonia Is Safely Transported in the Bloodstream as Glutamine

- **Free ammonia is very toxic.**
- **Glutamine synthetase traps free ammonia (from serine and threonine for example) into glutamine.**
- **Excess glutamine is processed in the intestines, kidneys, and liver.**

## Muscle Lacks the Enzymes of the Urea Cycle

- **The nitrogen from branched-chain amino acid degradation is transported to the liver by the glucose-alanine cycle.**

- **Transamination of pyruvate produces alanine in the muscle.**
- **This is transported to the liver, and the amino group transferred to α-ketoglutarate to give glutamate.**
- **The resulting pyruvate is converted back to glucose, and released by the liver.**

## Ammonia Collected in Glutamine Is Liberated by Glutaminase

- **Ammonia collected in glutamate is liberated by Glutamate Dehydrogenase.**

- **Nitrogen enters the liver as:**

- **alanine (from muscle) - transaminated to generate pyruvate and glutamate**
- **glutamine (from muscle and other tissues) - NH₄⁺ is liberated in mitochondria by the enzyme glutaminase.**
- **or as dietary amino acids from ingested protein - undergo transamination to generate glutamate and the α-ketoacid.**

- **Glutamate then undergoes an oxidative deamination by glutamate dehydrogenase.**

- **Net result: high NH₄⁺ in mitochondria.**

## The Urea Cycle

- **The free NH₄⁺ generated by glutaminase and glutamate dehydrogenase must be transformed into a less toxic compound for excretion.**

**Nitrogen enters the cycle at two points:**

1. **Free NH₄⁺ is incorporated into carbamoyl phosphate by carbamoyl phosphate synthetase.**
2. **The carbamoyl group is transferred to ornithine by ornithine transcarbamolyase to form citrulline.**

- **Citrulline is transported out of the mitochondria into the cytoplasm in exchange for ornithine.**
- **Nitrogen from aspartate is incorporated by a transamination reaction to form argininosuccinate.**
- **Argininosuccinate is cleaved to form arginine and fumarate.**
- **Arginine is cleaved by arginase into urea, which is excreted, and ornithine, which is transported into the mitochondria to begin another cycle.**

## The Urea Cycle, Citric Acid Cycle, and the Transamination of Oxaloacetate Are Linked by Fumarate and Aspartate

- **The stoichiometry of the urea cycle is:**

**CO₂ + NH₄⁺ + 3 ATP + aspartate + 2 H₂O → urea + 2 ADP + 2 P_i + AMP + PP_i + fumarate**

- **Fumarate can be converted into oxaloacetate by the citric acid cycle and then into glucose by the gluconeogenic pathway.**

## Fates of Nitrogen in Various Organisms

- **Plants conserve almost all of their nitrogen.**
- **Many aquatic vertebrates release ammonia to their environment:**
- **Passive diffusion from epithelial cells.**
- **Active transport via gills.**
- **Many terrestrial vertebrates and sharks excrete nitrogen in the form of urea:**
- **Urea is far less toxic than ammonia.**
- **Urea has very high solubility.**
- **Some animals such as birds and reptiles excrete nitrogen as uric acid:**
- **Uric acid is least toxic, but has the disadvantage of requiring more energy for its synthesis.**
- **Uric acid is rather insoluble.**
- **Excretion as paste allows the animals to conserve water.**
- **Humans and great apes excrete both urea (from amino acids) and uric acid (from purines).**

## Phenylketonuria Is Caused by a Defect in the First Step of Phe Degradation

- **A buildup of phenylalanine and phenylpyruvate.**
- **Impairs neurological development leading to intellectual deficits.**
- **Controlled by limiting dietary intake of Phe.**

## Nitrogen from Pyrimidine Degradation Is Incorporated into Glutamate

- **Uridine → Dihydrouracil → β-Alanine → β-Ureidopropionate → β-Ureidoisobutyrate → Glutamate.**

## Nitrogen from Purine Degradation Is Excreted as Urate

- **AMP → Adenosine → Inosine → Hypoxanthine → Xanthine → Urate → Uric acid.**

## Disruptions in Nucleotide Metabolism Can Cause Pathological Conditions

- **Xanthine oxidase catalyzes the conversion of xanthine into uric acid, the final common pathway for the degradation of purine nucleotides.**
- **Uric acid ionizes to form urate.**
- **High blood levels of urate induce gout, a painful disease that results from the accumulation of urate crystal in the joints.**
- **Administration of allopurinol, a suicide inhibitor of the oxidase, relieves the symptoms of gout.**
- **Purines are then excreted as xanthine and hypoxanthine.**
- **Urate is a potent antioxidant, and urate in the blood may prevent oxidative damage.**

## What You Need to Know:

* **Amino acids from protein are an important energy source in carnivorous animals.**
* **Ammonia generated by amino acid catabolism in muscle tissues is transported to the liver as alanine (transamination of pyruvate generated by glycolysis).**
* **The first step of AA catabolism is transfer of the NH₃ via PLP-dependent aminotransferase usually to α-ketoglutarate to yield glutamate. Transferring a second NH₃ yields glutamine.**
* **In most mammals, toxic ammonia is quickly recaptured into carbamoyl phosphate and passed into the urea cycle.**
* **Amino acids are degraded to pyruvate, acetyl-CoA, α-ketoglutarate, succinyl-CoA, and/or oxaloacetate.**
* **Amino acids yielding acetyl-CoA are ketogenic.**
* **Amino acids yielding other end products are glucogenic.**
* **Genetic defects in amino degradation pathways result in a number of human diseases.**
* **Nitrogen from pyrimidine degradation is incorporated into glutamate.**
* **Nitrogen from purine degradation is excreted as uric acid.**
* **Excess uric acid production leads to gout.**