Calcium homeostasis
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Transcript of Calcium homeostasis
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Calcium homeostasis
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Bone remodeling and repair
• Continuous remodeling– 5 to 7 % of total bone mass per week– Critical for maintenance of proper structure
• Removal of calcium
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Bone remodeling
• Location– Periosteum– Endosteum
• Remodeling units– Osteoblasts– Osteoclasts
• Does not occur uniformly– Different bones/different rates
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Bone remodeling
• Deposit– Site of injury– Strength re-enforcement– Nutrients
• Proteins• Vitamins (A and D)• Minerals
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Bone remodeling
• Deposit– Osteroid seam
• New matrix deposit– Unmineralized bone
• Calcification front• Rate of calcification
– Local concentrations of mineral products– Matrix proteins– Alkaline phosphatase
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Bone remodeling
• Resorption– Break down of bone matrix
• Formation of resorption bay
– Osteoclasts• Lysosomal enzymes• HCL• Phagocytosis of dead osteocytes• Activation triggered by T-lymphocytes
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• Regulation– Feedback loops
(Whether and when)• Calcium homeostasis in
the blood• Parathyroid hormone
(PTH)– Elevates blood calcium
concentration by increasing resorption
• Calcitonin– Increase calcium
deposition by osteoblasts
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Parathyroid gland
• Embedded on the thyroid surface– Four in humans
• Located in the back of thyroid glands
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• Removal of thyroid gland– Lethal
• Removal of parathyroid glands
– Decrease in blood calcium level
• Tetanic convulsion and death
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• Cell composition– Chief cells
• Secretes parathyroid hormone
– Oxyphil cells• Unknown functions
Oxyphil cells
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Parathyroid hormone
• Essential for life
• Chemistry– 84 AA
• Preprohormone (115 AA)– Synthesized and converted within the Golgi zone of the
chief cells– Proteolytic cleavage yields 90 AA prohormone
• prohormone– Removal of 6 AA to yield mature peptide
• Released into the bloodstream via exocytosis
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• Highly conserved hormone
• Short half-life– 3-4 min– Cleaved into two fragments
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Regulation of secretion• Blood calcium level
– Ca receptors on the parathyroid cells• Seven-transmembrane domain receptor
– Coupled with G-protein complex
• Highly conserved– 93 % AA homology between human and bovine
receptors
• Interaction of receptor with Ca– Concentration- dependent conformation alteration– Decreased cAMP production when high Ca
concentrations– Increased cAMP production when low Ca concentrations
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• Vitamin D– Inhibition of PTH secretion
• Genomic level• Slow effects
– No changes in release of PTH immediately after vitamin D treatment
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Function of PTH
• Elevation of blood calcium level– Decreased phosphate ion concentrations– Acts on kidneys, intestines, and bones
• Effects on mineral metabolism– Increased osteoclast activity
• Secretion of cytokines by stromal osteoblast in response to PTH
• Demineralization of bones
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• Renal excretion and reabsorption– Increased calcium reabsporption
• Renal tubular reabsorption
– Increased phosphate excretion (phosphaturia)
• Increased ionization of calcium– Prevention of CaPO4 formation
– Increased Mg reabsorption– Inhibition of Na-H exchange
• Decreased blood pH – Inhibition of Ca binding to plasma proteins
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• Absorption of calcium– Intestine
• Increased uptake (direct)• Effects on vitamin D metabolism (indirect)
• Control of vitamin D synthesis– Increased 1,25-dihydrovitamin D synthesis
from vitamin D• Kidney
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• Other actions– Increased reticulocyte and lymphocyte
mitosis– Vasodilation
• Direct action involving specific receptor
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Mechanism of action• Interaction between
PTH and its receptor– Increased cAMP
production• Gs
– Activation of phospholipase C
• Production of IP3 and DG– Activated by Gq
– Vitamin D-dependent• Mobilization of Ca from
bones
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• Role of vitamin D on PTH action– Not on cAMP production
• Normal cAMP production by the bones from vitamin D deficient mice
– Later parts of biochemical reactions
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Calcitonin• Maintenance of blood
Ca level– Critical– Acute elevation
• Meal– Return to normal
shortly after elevation
• Role of thyroid gland– Secretion of calcitonin
• C (clear) cells
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Synthesis and metabolism• 32 AA
– Derived from larger prohormone
– Ring structure• Disulfide bridge
between AA 1 and AA 7
• Isoforms– Two
• I in combination with II or III
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• High structural similarity– Low AA homology– Fish calcitonin is more potent in humans
• Resists proteolytic digestion• Higher receptor affinity