This section outlines the process of excretion, focusing on the removal of nitrogenous waste products from an organism's body. It explains how the type of waste product is a crucial adaptation related to the organism's habitat and water availability.
Metabolism, particularly the breakdown of proteins and nucleic acids, produces toxic nitrogen-containing compounds. The primary nitrogenous wastes in animals are ammonia, urea, and uric acid. The type of waste excreted is strongly correlated with the organism's habitat and the availability of water.
- Toxicity: Highly toxic. It can raise the pH of body fluids and interfere with membrane transport.
- Solubility and Water Requirement: Highly soluble in water. Requires a large volume of water to be diluted to a non-toxic level (approximately 500 mL of water per 1 g of nitrogen).
- Excretion Method: Diffuses rapidly across cell membranes and must be excreted quickly.
- Habitat: Primarily aquatic environments where water is abundant.
- Organisms (Ammonotelic): Animals that excrete ammonia as their major waste product.
- Examples: Most freshwater fish, protozoans, sponges, cnidarians, echinoderms, and crustaceans.
- Toxicity: Low toxicity (100,000 times less toxic than ammonia).
- Solubility and Water Requirement: Soluble in water, but requires significantly less water for dilution than ammonia (approximately 50 mL of water per 1 g of nitrogen).
- Excretion Method: Organisms expend energy to convert toxic ammonia into less harmful urea in the liver (Urea Cycle).
- Habitat: Terrestrial and some marine environments where water conservation is necessary.
- Organisms (Ureotelic): Animals that excrete urea as their major waste product.
- Examples: Mammals (including humans), many amphibians, sharks, and some marine fish.
- Toxicity: Very low toxicity. It is less toxic than urea.
- Solubility and Water Requirement: Poorly soluble in water and precipitates out of solution. Requires very little water for excretion (approximately 1 mL of water per 1 g of nitrogen).
- Excretion Method: Excreted as a semi-solid paste, which is a major adaptation for water conservation. It is an energetically expensive molecule to produce.
- Note for Humans: Humans excrete small amounts of uric acid, but it is derived from the breakdown of nucleic acids (purines), not proteins.
- Habitat: Terrestrial environments with significant water scarcity.
- Organisms (Uricotelic): Animals that excrete uric acid as their major waste product.
- Examples: Terrestrial invertebrates (e.g., land snails, insects), reptiles (e.g., snakes, lizards), and most birds.
| Feature | Ammonia | Urea | Uric Acid |
|---|
| Toxicity | Very High | Moderate | Low |
| Water Required | Very High (500 mL/g N) | Moderate (50 mL/g N) | Very Low (1 mL/g N) |
| Energy Cost | Low | High | Very High |
| Organism Type | Ammonotelic | Ureotelic | Uricotelic |
| Examples | Freshwater fish, protozoa | Mammals, amphibians, sharks | Birds, reptiles, insects |
Plants handle metabolic wastes differently than animals. They do not have a specialized excretory system. Instead, they use various strategies such as storage in vacuoles, or accumulating wastes in leaves that are eventually shed.
Q: Where do you think the carbon dioxide used in the formation of urea comes from?
A: The carbon dioxide used in the urea cycle (the metabolic pathway that forms urea from ammonia) is a product of cellular respiration, specifically from processes like the Krebs cycle occurring within the mitochondria of liver cells.
Q: Where does the remainder of excess carbon dioxide go to be excreted?
A: The vast majority of excess carbon dioxide produced by the body is transported via the bloodstream to the lungs, where it is excreted from the body through exhalation. See also Mechanism Of Ventilation Breathing→ for details on respiratory excretion.
The form of nitrogenous waste is a key evolutionary adaptation for maintaining water balance (osmoregulation) and surviving in different environments. See also Functions Of Kidney→ for details on how kidneys filter these wastes.