Lecture 10

1. Lecture 10 Glucose Disposal: Liver and Molecular Mechanisms

2. Hexose Metabolism P hexokinase Using UTP Releases PP PP hydrolysis pulls reaction to completion P Using ATP glucose glucose 1-phosphate glucose 6-phosphate P P P U UDP glucose fructose 6-phosphate “Activated Glucose” P P PFK Pyrophosphate hydrolyses to two phosphates Pulls UDP-glucose conversion over fructose 1,6-bisphosphate

3. Splitting F16BP Triose phosphate Isomerase P P aldolase CH2OP CH2OP CHOH C=O fructose 1,6-bisphosphate CHO CH2OH Glyceraldehyde 3- phosphate Dihydroxyactone phosphate Rest of Glycolysis to pyruvate Involves oxidation of G3P and generation of ATP

4. Glycogen Synthesis P P Glycogen U UDP glucose P P Glycogen with one more glucose U Note synthesis is C1 C4 C1 end of glycogen attached to glycogenin UDP UDP needs to be made back into UTP Use ATP for this UDP + ATP  UTP + ADP

5. Liver Glucose Uptake • GLUT-2 used to take up glucose from bloodstream • Very high activity and very abundant • [Glucose] blood = [Glucose] liver • Glucokinase • Rapidly converts GG6P • Not inhibited by build up of G6P • High Km (10 mM) for glucose – not saturated by high levels of liver glucose • So [G6P] rapidly increases as blood [glucose] rises • G6P can stimulate inactive GS • Even phosphorylated GS • Glucose itself also stimulates the dephosphorylation of GS • Via a slightly complex process that involves other kinases and phosphatases which we needn’t go into right now 

6. Glycogenesis • In liver • The “push” mechanism • Glycogenesis responds to blood glucose without the need of insulin • Although insulin WILL stimulate glycogenesis further • In muscle • [G6P] never gets high enough to stimulate GS • “Push” method doesn’t happen in muscle • More of a “pull’ as insulin stimulates GS • In both cases • 2 ATPs required for the incorporation of a glucose into glycogen chain • GG6P and UDPUTP • Branching enzyme needed to introduce a16 branch points • Transfers a segment from one chain to another • Limit to the size of glycogen molecule • Branches become too crowded, even if they become progressively shorter • Glycogen synthase may need to interact with glycogenin to be fully active

7. A Tale of Two Kinases • Glucokinase (GK) • Only works on glucose • High Km for glucose (~10mM) • Not inhibited by G6P • Only presents in liver, beta-cells • Responsive to changes in [glucose] blood • Hexokinase (HK) • Works on any 6C sugar • Km for glucose ~0.1mM • Strongly inhibited by its product G6P • Present in all other tissues • If G6P is not used immediately, its build up and inhibits hexokinase • Easily saturated with glucose

8. Fructose Metabolism Glyceraldehyde 3-phosphate Glyceraldehyde fructokinase P CH2OH CH2OP Aldolase B CHOH CHOH fructose Using ATP Triose Kinase fructose 1-phosphate CHO CHO hexokinase CH2OP P C=O CH2OH fructose 6-phosphate Dihydroxyactone phosphate PFK ‘normal glycolysis’ ‘normal glycolysis’

9. Fructose Metabolism • Fructose entry into cells does not require insulin • In muscle, fructose just enters glycolysis • Or could be made into glycogen if insulin stimulus available! • F6P  G6P  G1P  UDP-glucose  Glycogen • In liver, fructokinase traps fructose • FK produces F1P • FK is quite fast in comparison to the aldolase B that uses the F1P • F1P can build up • But more seriously producing ‘dead’ F1P traps phoshpate • FK reaction consumes ATP • Lack of phosphate akes new ATP synthesis difficult • ATP levels in liver fall • Even more serious in people with a deficiency in Aldolase B