Post on 22-Dec-2015
Endo 1.08 The thyroid gland
• Gross anatomy and histology of the thyroid gland
• Thyroid hormone synthesis
• Thyroid hormone secretion, peripheral conversion and metabolism
• Measurement of free T4 and TSH
• Actions of thyroid hormones, hyper-and hypothyroidism
Blood supply
Superior and inferior thyroid arteries from external carotids and subclavian arteries respectively
Superior, middle and inferior thyroid veins
More blood per unit weight than kidney - goitre bruit
20 grams
4 cm
Histology of the thyroid gland
Thyroid hormones derived from two iodinated tyrosine molecules
Synthesis of thyroid hormones
• Active uptake of iodide into follicular cell
• Iodide iodine - H2O 2 (catalysed by TPO)
• Active uptake of iodine at follicular/ colloid interface
• Incorporation of iodine onto tyrosine residues of thyroglobulin
• Coupling of iodinated tyrosines
• Storeage of T3 and T4
Active transport of iodine (ATPase dependent) against electrical and chemical gradient - concentration of
iodine 30-50 times that of the circulation
• Active uptake of iodine by a sodium iodide symporter
• Oxidation of iodide to iodine
• Iodination of tyrosine residues at apical/colloid interface to form MIT and DIT
• Uptake of thyroglobulin into the lumen of the follicle
Incorporation of iodine onto tyrosine residues on the thyroglobulin molecule
4) Release of T4 and T3 into circulation -
100g T4 & 10g T3/day
3) ~ 10% T4 undergoes mono-deiodination to T3 before secretion
2) Fusion of colloid droplets with lysosomes --> hydrolysis and release of thyroid hormones
1) Stimulated by TSH colloid droplets with the bound thyroid hormones are taken back into follicular cells by pinocytosis
Daily production of thyroid hormone
secretion and serum
concentrations
5’ 5
3’ 3
5’
5Thyroid hormone
metabolism
Metabolism of thyroid hormones
Series of deiodinations by deiodinasesType 1 - liver, kidney, thyroid, pituitary gland,
CNS: 5’ and 5 positions
Type 2 - brain, brown fat, placenta, pituitary gland: 5’ position only: T4 T3 only: intracellular concentrations of T3
Type 3 - brain, placenta: 5 position only
T4 T3
Other metabolic pathways: sulphation, decarboxylation, conjugated with glucuronide
Thyroxine (T4)
T3rT3
T3 S
TRIAC
T2T2
other pathways
T1 T1
thyronine
1 & 2 1 & 3
3,5,3’ 3,5’,3’
Type 1 - 5’ and 5
Type 2 - 5’ only
Type 3 - 5 only
Control of thyroid hormone synthesis
and release and feedback control
TSH Receptors
TSH
G protein linked receptor
cAMP IP3 + DAG
Protein Ca2+ Protein Kinase A CM Kinase
C(high concentrations)
Actions of TSH
• Active uptake of iodine*
• Stimulates other reactions involved in thyroid hormone synthesis
• Stimulates the uptake of colloid
• Induces growth of the thyroid gland
Thyroid hormone receptors
Thyroid hormone receptors
• Type 2 receptors in nucleus - high affinity for T3
• Dimerize with another T3 receptor (homodimer) or retinoic acid receptor (heterodimer)
• Dimerized receptor + other transcription factors gene transcription
• Membrane receptors? Ion movements
Isoforms of the thyroid hormone receptor
DBD
DBD
DBD
DBD
T3
Dimerization of thyroid hormone receptors and gene activation/inactivation
Functions of thyroid hormonesStimulate metabolic rate: increasing number and
size of mitochondria, increasing enzymes in the
metabolic chain, increasing Na+/K+ ATPase activity.
Resting metabolic rate may increase 100% with
excess thyroid hormones or decrease by 50% with a
deficiency
Positive inotropic and chronotropic effects on
the heartImportant in growth and development -
particularly skeleton and nervous system
Feedback control of
thyroid hormone
synthesis and secretion
Radioisotopic (technetium) scanning of the thyroid gland - regional function of the gland
No left lobe hyperthyroidism
hypothyroidism
Hot noduleCold nodule
Measuring ‘free’ T4
1) Add serum sample or standard (T4 ) to latex beads coated with Abs
2) Add T4 labelled with alkaline phosphatase. This will bind to any unoccupied Ab binding sites
3) Add a substrate that will fluoresce when the alkaline phosphatase removes a phosphate group
4) Fluorescent intensity will be inversely proportional to the concentration of T4
Phosphate
Assay of antibodies to the human TSH receptors
Patients serum Add Precipitate Count + TSH 125I-TSH
receptors (bovine) (porcine)
Circulating concentrations of TSH and pituitary function test in normal and primary hyperthyroidism
Saggital MR scans of a) normal and b) a patient with a craniopharyngioma causing bitemporal hemianopia and
hypopituitarism
Primary hyperthyroidism Hypothyroidism
Grave’s disease (10)
• Autoimmune - activating AB’s to TSH receptor
• High concentrations of circulating thyroid hormones, low TSH
• Weight loss, tachycardia, tiredness
• Diffuse goitre - TSH stimulating growth
• Opthalmompathy and dermopathy
Symptoms and signs of hyperthyroidism
Hashimoto’s (1o)
• Autoimmune - AB’s destruction of thyroid gland
• Low concentrations of thyroid hormones, high TSH
• Lethargy, intolerance to cold
• Lack of growth and development
• Diffuse goitre - lymphocytic infiltration of gland + TSH stimulated growth
Symptoms and signs of hypothyroidism