Sum activity of peripheral deiodinases: Difference between revisions
From WikiMD's Wellness Encyclopedia
CSV import |
No edit summary |
||
| Line 8: | Line 8: | ||
* '''Type I Deiodinase (D1)''': | * '''Type I Deiodinase (D1)''': | ||
** Found primarily in the [[liver]], [[kidney]], and [[thyroid gland]]. | |||
** Converts [[thyroxine]] (T4) to the more active [[triiodothyronine]] (T3) by removing an iodine atom from the outer ring. | |||
** Also capable of converting reverse T3 (rT3) to diiodothyronine (T2). | |||
* '''Type II Deiodinase (D2)''': | * '''Type II Deiodinase (D2)''': | ||
** Predominantly located in the [[brain]], [[pituitary gland]], [[brown adipose tissue]], and [[skeletal muscle]]. | |||
** Converts T4 to T3, thus playing a critical role in maintaining local T3 levels in tissues. | |||
** Important for the feedback regulation of the [[hypothalamic-pituitary-thyroid axis]]. | |||
* '''Type III Deiodinase (D3)''': | * '''Type III Deiodinase (D3)''': | ||
** Expressed in the [[placenta]], [[central nervous system]], and [[skin]]. | |||
** Inactivates T4 and T3 by converting them to rT3 and T2, respectively. | |||
** Protects tissues from excessive thyroid hormone action. | |||
==Function and Importance== | ==Function and Importance== | ||
| Line 42: | Line 42: | ||
* [[Hypothyroidism]] | * [[Hypothyroidism]] | ||
* [[Hyperthyroidism]] | * [[Hyperthyroidism]] | ||
{{stub}} | |||
[[Category:Endocrinology]] | [[Category:Endocrinology]] | ||
[[Category:Enzymes]] | [[Category:Enzymes]] | ||
[[Category:Thyroid]] | [[Category:Thyroid]] | ||
Latest revision as of 23:42, 23 March 2025
Overview of the sum activity of peripheral deiodinases
Sum Activity of Peripheral Deiodinases[edit]
The sum activity of peripheral deiodinases refers to the collective function of enzymes known as deiodinases that are responsible for the activation and deactivation of thyroid hormones in peripheral tissues. These enzymes play a crucial role in the regulation of metabolism, growth, and development by modulating the levels of active thyroid hormones available to tissues.
Types of Deiodinases[edit]
There are three main types of deiodinases, each with distinct roles and tissue distributions:
- Type I Deiodinase (D1):
- Found primarily in the liver, kidney, and thyroid gland.
- Converts thyroxine (T4) to the more active triiodothyronine (T3) by removing an iodine atom from the outer ring.
- Also capable of converting reverse T3 (rT3) to diiodothyronine (T2).
- Type II Deiodinase (D2):
- Predominantly located in the brain, pituitary gland, brown adipose tissue, and skeletal muscle.
- Converts T4 to T3, thus playing a critical role in maintaining local T3 levels in tissues.
- Important for the feedback regulation of the hypothalamic-pituitary-thyroid axis.
- Type III Deiodinase (D3):
- Expressed in the placenta, central nervous system, and skin.
- Inactivates T4 and T3 by converting them to rT3 and T2, respectively.
- Protects tissues from excessive thyroid hormone action.
Function and Importance[edit]
The sum activity of peripheral deiodinases is essential for the fine-tuning of thyroid hormone action in various tissues. By converting T4 to T3, deiodinases ensure that tissues receive the appropriate amount of active hormone necessary for their specific metabolic needs. This local regulation is crucial for:
- Metabolic Rate Regulation: T3 is the active form of thyroid hormone that influences the basal metabolic rate.
- Development: Proper levels of T3 are vital for fetal development and neurodevelopment.
- Thermogenesis: In brown adipose tissue, D2-mediated conversion of T4 to T3 is important for heat production.
Clinical Significance[edit]
Alterations in the activity of deiodinases can lead to various clinical conditions:
- Hypothyroidism: Reduced deiodinase activity can lead to decreased T3 levels, contributing to symptoms of hypothyroidism.
- Hyperthyroidism: Increased deiodinase activity may result in excessive T3 production, exacerbating hyperthyroid conditions.
- Non-thyroidal Illness Syndrome: Changes in deiodinase activity are observed in critical illnesses, affecting thyroid hormone levels and metabolism.
