The thyroid gland: control of secretion, effects of the thyroid hormones

Question 1

What is the Thyroid Gland (TG)?

Answer 1

• One of the largest endocrine glands, normally 15 to 20g in adults
• Bilobular, located immediately below the larynx of each side of and anterior to the trachea
• Secretes two major metabolic hormones; thyroxine (T4) and triiodothyronine (T3)
• Thyroid secretion is controlled primary by the thyroid-stimulating hormone (TSH) secreted by the anterior pituitary gland
• The thyroid gland also secretes calcitonin, a hormone involved in calcium metabolism
• Thyroglobulin is secreted into the follicular sacs within the gland
• Usually TG produces and stores hormones (unusual for a gland to both secrete and store!)

Question 2

What are the important cells, compartments and secretions of the Thyroid Gland ?

Answer 2

• Thyroid Gland has many closed follies (100 - 300 microns in diameter)
• Cuboidal epithelial cells secrete colloid into follies
• Main component of colloid is thyroglobulin which contains the thyroid hormones
• Secretions must be reabsorbed through epithelial cells and enter into the blood stream before it can function in the body (blood flow 5x weight of the gland/minute)
• C cells secrete calcitonin (role in calcium regulation - especially in other mammals)

Question 3

So what is T3 and T4?

Answer 3

• Approx 93% of metabolically active hormones secreted by the thyroid gland is Thyroxine (T4) and 7% is Triiodothyronine (T3)
• Almost all T4 is eventually converted to T3 in tissues (as T3 is more potent)
• T3 is approximately 4 times as potent as T4, but it is present in the blood in much smaller quantities and persists for a much shorter time compared with Thyroxine
• T4 and T3 increase metabolic rate

Question 4

What does a lack of thyroid secretion cause?

Answer 4

• Lack of thyroid secretion usually causes basal metabolic rate to fall 40% to 50% below normal

Question 5

What does an excess of thyroid secretion cause?

Answer 5

• Excesses of thyroid secretion can increase the basal metabolic rate to 60% to 100% above normal

Question 6

Why do we need Iodine?

Answer 6

• Iodine is required to form Thyroxine (T4)
• Require approx. 50mg / year (about 1mg/week)
• Table salt is iodised to prevent deficiencies of this in our diet
• Iodide is sequestered by the Thyroid gland (Thyroid can concentrate iodide), excess usually excreted by kidneys

Question 7

How do we trap Iodine in the Thyroid Gland?

Answer 7

• Concentrating iodine within thyroid gland cells
• First stage of thyroid hormone formation - transport of iodide from blood to thyroid gland cells and follicles
• Basolateral membrane of thyroid cell actively pumps iodide into the cells via the sodium-iodide symporter (NIS) (2Na+: 1 iodide) (using energy from the sodium pump)
• Iodide concentrated in the cell (30x more than plasma). Concentration can increase to 250x plasma concentration
• Rate is controlled mostly by TSH (thyroid stimulating hormone) - “The main controller”
• Iodide transported through apical membrane into follicle by “pendrin-chloride-iodide anti-porter”

Question 8

What are the different steps involved in transporting and making T3 + T4?

Answer 8

1). Iodide trapping
2). Oxidising iodide = Iodine
3). Oragnification of Thyroglobulin
4). Coupling
5). Storage
6). Release

Question 9

What is thyroglobulin and how does it help produce T3 and T4?

Answer 9

• Thyroglobulin - large glycoprotein molecule
• MW 335,000 synthesised and secreted into follicles by ER and Golgi apparatus
• Contains approx 70 tyrosine AAs
• Tyrosine + iodine = T3 + T4
• This happens within the thyroglobulin
• T3 and T4 also stored as part of thyroglobulin

Question 10

What happens to the iodine inside the cell ?

Answer 10

• Iodide ions are converted to oxidised form of iodine - either I (0) or I (3-) which can combine with tyrosine
• Enzyme peroxidase, located in or attached to apical membrane, is used to produce peroxide and this oxidises the iodide ions to iodine
• Blockage or absence of peroxidase system stops formation of thyroid hormones

Question 11

What happens in the Organification of Thyroglobulin step?

Answer 11

This is the binding of the oxidised iodine to thyroglobulin

• It will occur spontaneously but slowly
• In thyroid cells, oxidised iodine is associated with thyroid peroxidase (acts as a catalyst)
• It speeds the reaction up and iodide binds to tyrosine almost as soon as they come into contact with the thyroglobulin

Question 12

How do we form T3 and T4?

Answer 12

Stages of iodination and coupling;

1). Tyrosine is iodised to monoiodotyrosine and then to diiodotyrosine

2). Next few minutes/hours/days, mono and/or diodo iodotyrosine residues become coupled with one another
- Major product is Thyroxine (T4) = 2x diiodotyrosine
- Approx 1/15th of product is trioiodothyranine (T3) = mono + diodo tyrosine
- Small amount of reverse T3 = diodo + monoiodotyrosine (not important physiologically?)

See image

Question 13

How do we store T3 + T4?

Answer 13

Storage;
- When synthesis / coupling has finished, each thyroglobulin molecule contains up to 30 T4’s and a few T3’s
- thyroglobulin stores in follicles until needed
- Supply lasts for 2-3 months
- Deficiency / pathophysiology of process may be undetected for a few months
- Hence if something goes wrong find 2/3 month down line since stopped working

Question 14

How is T3 an T4 cleaved + released ?

Answer 14

• T3 an T4 are cleaved from thyroglobulin
• T3 and T4 then released as free hormones
• Colloid (containing thyroglobulin with its T3 and T4) brought into the cell at the apex by pinococytosis
• Pinocytotic vesicles in the thyroid cell fuse with lysosomes which contain digestive enzymes (e.g proteases)

Question 15

What are the actions of proteases (release phase?) ?

Answer 15

• Proteases digest thyroglobulin and release T3 and T4
• T3 and T4 diffuse through basolateral membrane into capillaries and bloodstream
• Approx 93% thyroxine (T4), 7% T3 initially
• Approx half of T4 is de-iodinated to T3 over the next few days
• Most of the hormone is delivered tissues is T3

Truncate larger structure and cleave off some amino acids making smaller so can be transported through basolateral membrane into blood stream so it can act where it needs to

Question 16

How is T3 and T4 transported to cells?

Answer 16

• > 99% of T3 and T4 are in the blood bound to plasma proteins (synthesised by the liver)
• Proteins mainly thyroxine-binding globulin, thyroxine-binding prealbumin and albumin
• Proteins have high affinity for T3 and T4 so release them only slowly at the tissues (T3 released more quickly than T4)

Question 17

How do T3 and T4 act done in the target cells?

Answer 17

• In target cells, T3 and T4 bind with intracellular proteins for storage again
• T4 is more strongly bound than T3
• Used over days/weeks
• Can observe indirectly by looking at the effects

Question 18

How quickly would an injection of Thyroxine show up in the blood and why?

Answer 18

• 2 or 3 day latent period
• Increase in activity over about 10-12 days
• Diminishes over several weeks/months (Half life approx. 15 days)
• T3 more rapid response - latent period of 6-12 hours, max activity in 2-3 days
• Latency is due to binding to proteins but also due to how T3 and T4 mediate reactions downstream

Question 19

How do T4 and T3 affect transcription genes?

Answer 19

• T4 and T3 enter the cell membrane by carrier-mediated active transport
• Most T4 deiodinated to form T3
• T3 interacts with the thyroid hormone receptor
• Leads to increase or decreases in transcription of genes that lead to the formation of proteins
• Thyroid hormone response of the cell is generated

Thyroid Hormones act on many cells/systems;
- Growth
- CNS development
- Cardiovascular
- Metabolism

Hence why wont see an instant response as this can take days to show up !

Question 20

What are some Non-genomic cellular effects that T3 and T4 can have?

Answer 20

• Quick response in some tissues, e.g, heart, pituitary, adipose (Because these aren’t working through the transcription mechanism)
• Not enough time for transcription and protein synthesis t occur so must work another way
• Sites of action are probably plasma membrane, cytoplasm, mitochondria, other organelles
• Probably work via activation of intracellular 2nd messengers (e.g cAMP and protein kinase signalling cascades)

Question 21

What are the Major Physiological effects of the Thyroid hormones?

Answer 21

1). Mobilisation of Carbohydrate, fat and protein stores (direct and indirection actions)
- Increase glucose uptake from GI tract
- Increase glucose utilisation (esp muscle and tissue)
- Increase liver glycogenolysis and gluconeogensis
- Increase Lipolysis in adipose tissue (increase plasma Free Fatty acids)
- Increase tissue oxidation of Free Fatty Acids
- General increase in protein turnover with net increase in anabolism
- Increase in specific enzymes / membrane proteins / hormone receptors
- Permissive actions for other hormones (GH, prolactin, gonadal and adrenal steroids)
- Essential for normal development and function of CNS and PNS

2). Increased Basal Metabolic Rate (BMR);
- Increase secretion = Weight loss
- Decreased secretion = Weight gain

3). Increases in almost every system;
- Blood flow and cardiac output
- Respiration
- GI motility
- Excitatory effects on CNS (Anxiety, worry, nervousness etc)
- Muscle vigour but will cause decrease at high hormone concentration due to excess protein catabolism, often muscle tremor
- Rates of secretion of other hormones
- Sexual disfunction - various effects, complex and not well understood

Question 22

How would thyroid hormones affect the Basal metabolic rate (BMR) / temperature regulation ?

Answer 22

Basal metabolic rate (BMR) / temperature regulation;

Normal;
- Promotes normal oxygen use and BMR
- Calorigenesis
- Enhances effects of sympathetic nervous system

Hypo;
- BMR below normal
- Decreased body temperature and cold intolerance
- Decreased appetite
- Weight gain
- Reduced sensitivity to catecholamines

Hyper;
- BMR above normal
- Increased body temperature and heat intolerance
- Increased appetite
- Weight loss

Question 23

How would thyroid hormones affect the Carbohydrate/lipid/protein metabolism ?

Answer 23

Carbohydrate/lipid/protein metabolism;

Normal;
- Promotes glucose catabolism
- Mobilises fats
- Essential for protein synthesis
- Enhances liver’s synthesis of cholesterol

Hypo;
- Decreased glucose metabolism
- Elevated cholesterol / triglyceride levels in the blood
- Decreased protein synthesis
- Oedema

Hyper;
- Enhanced catabolism of glucose, proteins and fats
- Weight loss
- Loss of muscle mass

Question 24

How would thyroid hormones affect the Nervous System ?

Answer 24

Nervous System;

Normal;
- Promotes normal development of nervous system in foetus and infant
- Promotes normal adult nervous system function

Hypo;
In infant
- Slowed/deficient brain development
- Retardation

In adult;
- Mental dulling
- Depression
- Paresthesias
- Memory impairment
- Hypoactive reflexes

Hyper;
- Irritability
- Restlessness
- Insomnia
- Personality changes
- Exophthalmos (In graves disease)

Question 25

How would thyroid hormones affect the Cardiovascular system ?

Answer 25

Cardiovascular system;

Normal;
- Promotes normal functioning of the heart

Hypo;
- Decreased efficiency of pumping action of heart; low heart rate and blood pressure

Hyper;
- Increased sensitivity to catecholamines leads to rapid heart rate and possible palpitations
- High blood pressure
- If prolonged heart failure

Question 26

How would thyroid hormones affect the Muscular System ?

Answer 26

Muscular System;

Normal;
- Promotes normal muscular development and function

Hypo;
- Sluggish muscle action; muscle cramps; myalgia

Hyper;
- Muscle atrophy and weakness

Question 27

How would thyroid hormones affect the Skeletal System ?

Answer 27

Skeletal System;

Normal;
- Promotes normal growth and maturation of skeleton

Hypo;
- In child, growth retardation, skeletal stunting, retention of childs body proportions
- In adult, joint pain

Hyper;
- In child, excessive skeletal growth initially, followed by early epiphyseal closure and short stature
- In adult demineralisation of skeleton

Question 28

How would thyroid hormones affect the Reproductive system?

Answer 28

Reproductive system;

Normal;
- Promotes normal female reproductive ability and lactation

Hypo;
- Depressed ovarian function
- Sterility
- Depressed lactation

Hyper;
- In females, depressed ovarian function
- In males, impotence

Question 29

How would thyroid hormones affect the GI system ?

Answer 29

GI System;

Normal;
- Promotes normal GI motility and tone
- Increases secretion of digestive juices

Hypo;
- Depressed GI motility, tone, and secretary activity
- Constipation

Hyper;
- Excessive GI motility, diarrhoea
- Loss apetite

Question 30

How would thyroid hormones affect the Integumatnary system ?

Answer 30

Normal;
- Promotes normal hydration and secretory activity of skin

Hypo;
- Skin pale, thick and dry
- Facial oedema
- Hair coarse and thick

Hyper;
- Skin flushed, thin and moist
- Hair fine and soft
- Nails soft and thin

Question 31

How is T3 and T4 secretion regulated ?

Answer 31

Complex - Narrow homeostatic range required to maintain appropriate metabolised (needs monitored closely)

TSH (thyrotropin);
- an anterior pituitary hormone increases T3 and T4 secretion (and all known secretions from the thyroid gland).
- Also has a stimulatory effect of TSH mediated by cAMP as a secondary messenger

Anterior pituitary;
- secretion of TSH is controlled by a hypothalamic hormone, thyrotropin releasing hormone (TRH)

Thyrotropin releasing hormone (TRH);
- TRH binds to TRH receptors in the pituitary cell membrane - this binding activates phospholipase second messenger system inside the pituitary cells to produce large amounts of phospholipase C then secondary messenger cascade leading to TSH release

Cold (probably);
- causes excitation of hypothalamic centres for body temperature increasing TRH and TSH

Feedback from thyroid T3 and T4

Question 32

How is T3 and T4 regulated by Negative feedback?

Answer 32

• Increased T3 and T4 strongly inhibits the Anterior pituitary to stop producing Thyroid Stimulating Hormone (TSH)
• Increased T3 and T4 inhibits the hypothalamus to stop the production of Thyrotropin-releasing hormone (TRH)
• Iodine coming in affects it, increases total collection of iodine in thyroid, increase T3 + T4 and increase neg feedback

Question 33

How does Thiocyanate regulate T3 and T4 ?

Answer 33

• Thiocyanate ions decrease iodide trapping
• The same active pump that transports iodide ions into the thyroid cells can also pump thocyanate ions
• Thiocyanate competitively inhibit iodide transport into the cell
• Thyroglobulin still formed but isn’t iodinated and therefore cannot form thyroid hormones
• Low Thyroid hormones increases the secretion of TSH
• Overgrowth of the thyroid gland caused even though no Thyroid hormones
• Enlarged thyroid gland = goitre

Question 34

How does Propylthiroacil regulate T3 and T4 ?

Answer 34

• Propylthiroacil (e.g Carbimazole / Methimazole) prevents formation of thyroid hormones from iodides and tyrosine
• Block the peroxidase enzyme that is required for iodination of tyrosine and blocks the coupling that forms T3 and T4
• (Like Thiocyanate) does not prevent formation of thyroglobulin
• Absence of T3 and T4 leads to feedback enhancement of TSH secretion by the anterior pituitary gland = growth of glandular tissue = goitre

Question 35

How does and increased Plasma Iodide affect the regulation of T3 and T4?

Answer 35

When plasma Iodide is x100 normal, most activity decreases

Short term - only lasts a few weeks;
- iodide trapping rate is reduced
- iodination of tyrosine to form T3 and T4 also decreased
- Endocytosis of colloid from follicles stops
- rapid shutdown of T3 and T4 secretion into the blood

• Gland size and blood supply decreases
• We administer iodides for 2-3 weeks before surgical removal of the thyroid gland to decrease the amount of surgery and bleeding

Question 36

What are the features of Hyperthyroidism?

Answer 36

Hyperthyroidism;
- E.g Toxic Goitre, Thyrotoxicosis, Graves Disease
- Thyroid Gland increases size and number of cells (x2-3)
- Secretion rate increases

Question 37

What is happening in Graves disease?

Answer 37

Graves Disease - Most common of Hyperthyroidism;
- Autoimmune disease
- Thyroid-stimulating immunoglobulins (TSI’s) antibodies form against the thyroid stimulating hormone (TSH) receptor in the Thyroid Gland
- Antibodies bind with the same membrane receptors that bind TSH
- Get continual activation of the cAMP system of cells which leads to Hyperthyroidism
- TSI’s stimulate thyroid hormone production more than TSH does normally
- High levels of thyroid hormone suppresses TSH production
- So people with Graves disease usually have a low/zero TSH

Question 38

What are the symptoms of Grave’s Disease ?

Answer 38

• Excitability
• Intolerance to heat increased sweating, weight loss
• Diarrhoea
• Muscle weakness (due to muscle atrophy)
• Nervousness or other psychic disorders
• Extreme fatigue but inability to sleep
• Tremor of the hands
• Exophthalmos

Question 39

What are the features of Hypothyroidism ?

Answer 39

• Generally effects are opposite to those of hyperthyroidism, a few differences too
• Both often initiated by autoimmunity against thyroid gland
• E.g Hasimoto’s disease

Question 40

What is happening in Hashimoto’s disease ?

Answer 40

Hashimoto’s disease;
- Autoimmunity destroys the gland rather than stimulates it (unlike in Graves)
- Usually thyroiditis occurs (thyroid inflammation)
- Thyroiditis = Thyroid gland fibrosis
- Get a decreased / zero secretion of thyroid hormone
- Other types of hypothyroidism also occur that are often associated with development of enlarged thyroid glands, called thyroid goitre (various ways these are formed)

Question 41

What are the symptoms of Hypothyroidism ?

Answer 41

Hypothyroidism symptoms;
- Fatigue
- Extreme somnolence (drowsiness or strong desire to fall asleep)
- Extreme muscular sluggishness
- Slowed heart rate, decreased cardiac output, decreased blood volume
- Sometimes increased body weight, contraption
- Mental sluggishness
- Failure of many trophic functions (e.g depressed growth of hai and scaliness of skin)
- Development of a froglike, husky voice
- Development myxedeme (bagginess under the eyes and swelling of the face)
- Atherosclerosis leads to peripheral vascular diseases, deafness and coronary artery disease = early death