Glycogen And Fat Flashcards
Glycogen Stores
Muscle glycogen
- as intra- and intermyofibrillar glycogen granules
- only converted back to glucose-6-phosphate - used by muscle for local energy production
Liver glycogen (up to 10% liver mass)
- glycogen storage granules within hepatocytes
- converted back to glucose and released into the blood for use in other tissues
Glycogen structure
Branched - can be broken down and utilised quickly
- alpha 1,6 glycosidic bonds form branch points (branching enzyme)
- alpha 1,4 glycosidic bonds join chains (glycogen synthase)
Has minimal osmotic effect on the cell
Glycogenesis
Glucose + ATP —> glucose-6-phosphate + ADP
With hexokinase in the liver
Phosphoglucomutase moves the phosphate from G-6-P to G-1-P
G-1-P + UTP + H2O –> glycogen + UDP
Regulation of liver glycogen metabolism
Glycogen synthesis is limited by glycogen synthase
- inhibited by glucagon and adrenaline
- activated by insulin
Glycogen degradation is limited by glycogen phosphorylase
- inhibited by insulin
- activated by glucagon, adrenaline
Glucagon has no effect on muscle glycogen
AMP is an allosteric activator of muscle glycogen phosphorylase
Glycogen storage disease
- inherited metabolism disease
- deficiency or dysfunction of enzymes of glycogen metabolise
- 11 distinct types of varying frequency
Liver and/or muscle can be affected
Excess glycogen storage can lead to tissue damage
Diminished glycogen stored can lead to hypoglycaemia and poor exercise tolerance
e.g. Vonnegut Gierke’s disease - Glucose-6-P deficiency and McArdie disease - muscle glycogen phosphorylase deficiency (storage)
Gluconeogenesis
- happens after >8hrs after eating
- in the liver and to a lesser extent the kidney cortex
Precursors - lactate - from anaerobic glycolysis in exercising muscle and RBC
- glycerol - released from TAC breakdown in adipose
- amino acids - mainly alanine
NO NET SYNTHESIS OF GLUCOSE FROM ACETYL-COA
Key enzymes - PEPCK (oxaloacetate –> phosphophenolpyruvate)
- fructose 1,6-bisphosphate (fructose 1,6-bisphosphate –> fructose-6-phosphate)
- glucose-6-phosphatase (glucose 6-phosphate –> glucose)
Regulation of gluconeogenesis
PEPCK and Fructose 1,6-bisphosphatase
- inhibited by insulin
- activated by glucagon and cortisol
Glucose utilisation
Glucose from food ~ 2 hours
Glycogenolysis ~ 1 to 10 hours
Gluconeogenesis ~ 8 to 10 hours onwards (with water this can sustain life for up to 40 days)
Glucose as the preferred fuel
Some tissues have an absolute requirement for glucose
- erythrocytes (RBC), leukocytes (WBC)
- testes
- kidney medulla
- lens and cornea of the eye
Stable blood glucose is essential for normal brain function. To achieve this a store of glucose - glycogen - is required
TAGs utilisation and storage
Hydrophobic - stored in anhydrous form in adipose tissue
Highly efficient energy stores (energy content per gram twice that of carbohydrate or protein)
Used I’m prolonged exercise, stress, starvation and during pregnancy
The storage and utilisation is under hormonal control
Adipocytes
Cytoplasm and organelles pushed to the edge of the cells by a large lipid droplet that is mainly composed of TAG and cholesterol esters
~ 0.1 mm in diameter
Can increase in size (hypertrophy) fourfold before dividing and increasing cell number (hyperplasia)
TAG metabolism
Pancreas - TAG broken down by pancreatic lipase to fatty acids and glycerol
Transported in blood as a chylomicron
Fatty acid oxidation can only take place in cells with mitochondria and not in the brain since FA do not easily pass the blood-brain barrier
Fatty acid synthesis
- mainly occurs in the liver and adipose tissue
- glycolysis in the cytoplasm
- pyruvate enters the mitochondria and forms acetyl-CoA & oxaloacetate
- acetyl-CoA carboxylate produces malonyl-CoA from acetyl-CoA
- fatty acid synthesis complex builds fatty acids by malonyl-CoA (3C - CO2 = 2C addition steps) requires ATP and NADPH
Liver lipogenesis
Acetyl-CoA carboxylase
- inhibited by glucagon/adrenaline and AMP
- activated by insulin and citrate
Fat mobilisation
lipolysis
Hormone sensitive lipase breaks down TAGs to FA (travels with albumin to muscle and other tissues for beta oxidation) and glycerol (liver source of carbon for gluconeogenesis)
- inhibited by insulin
- stimulated by - glucagon and adrenaline
