Gluconeogenesis/Ketogenesis

Question 1

What is gluconeogenesis? precursors? where does it happen?

Answer 1

• synthesize glucose from non-carbohydrate precursors when glucose levels are low
• precursors:

pyruvate, lactate, propionate, glycerol, and amino acids

-tissues:

liver (major), kidneys and small intestine (minor)

• early stage of fasting, kidney provides 10% of glucose and during extended fasting, kidney provides 40%
• supports plasma glucose levels in brain, testes, RBCs, and kidney medulla
• insulin/glucagon low

Question 2

3 irreversible steps of glycolysis?

Answer 2

1- Glucokinase/hexokinase

3- PFK1

10-Pyruvate kinase -these barriers must be overcome in GNG

Question 3

What is the first barrier to overcome in GNG? (7)

Answer 3

barrier: pyruvate to PEP
1. Pyruvate to oxaloacetate by pyruvate carboxylase
- enzyme to overcome is pyruvate kinase
- uses 1 ATP
- Biotin as cofactor, covalently bound
- allosterically activated by acetyl CoA
2. OAA to PEP by PEP carboxykinase
- either by OAA to PEP directly, using 1 GTP in mitochondria
- or by OAA to Malate (in mitochondria and then transported to cytosol) to OAA to PEP by cytosolic PEP carboxykinase using 1 GTP
- Notes:
- pyruvate must go into the mitochondria and through several steps to bypass this step
- shuttle is used, bidirectional, malate or aspartate must move from mitochondria to cytosol
- H from NADH is moved from mitochondria to cytosol to be used for glycolysis later

Question 4

Glycolysis vs GNG in 1st barrier? (8)

Answer 4

Glycolysis last step:

-one enzyme (pyruvate kinase) generates 2 ATP

GNG 1st step:

• two enzymes (pyruvate carboxylase and PEP corboxykinase) use 2 ATP
• PEP is in cytosol and OAA is in mitochondria so transportation across mtmemebrane must take place

Question 5

What is the 2nd barrier to GNG? (9)

Answer 5

• F1,6bisP to F6P
• enzyme used is F1,6bisPase (overcomes PFK-1 in step 3 of glycolysis)

Question 6

What is the 3rd barrier to GNG? (9)

Answer 6

• G6P to glucose
• enzyme used is G-6-phosphatase (overcomes hexokinase in step 1 of glycolysis)

Question 7

Glycolysis vs GNG? enzymes? location? energy used?(10)

Answer 7

• enzymes are the same except:
• pyruvate to PEP (step 10)
• F1,6bisP to F6P (step 3)
• G6P to glucose (step 1)
• location:
• glycolysis in cytosol
• GNG in cytosol and mitochondria -glycolysis generates 2 ATP
• GNG consumes 6 ATP

Question 8

Precursors to GNG? (11)

Answer 8

• pyruvate (reverse glycolysis)
• lactate (turns into pyruvate)
• glycerol (glycerol 3 phosphate and DHAP)
• propionate
• amino acids (alanine can turn into pyruvate, 18 can go into TCA)

Question 9

How are lactate and alanine used for GNG? (12)

Answer 9

• lactate to pyruvate catalyzed by lactate dehydrogenase, using NAD to transfer H back to NADH, reversible
• alanine to pyruvate using aminotransferase (transaminase), reversible

Question 10

What is the Cori cycle? (13)

Answer 10

• glucose lactate cycle
  1. in RBC, no mitochondria, and high concentration of pyruvate dehydrogenase, so lactate is formed
  2. blood carries lactate to liver
  3. lactate turns into glucose by GNG
• in each cycle, 6 ATP are spent in the liver and 2 ATP are generated in RBC

Question 11

Glucose alanine cycle? (14)

Answer 11

• anaerobic exercise
  1. glycolysis in muscle generates pyruvate which turns into alanine
  2. NH2 (ammonia- toxic) is carried on alanine from muscle to liver where it is used to make urea
  3. alanine converts back to pyruvate to be used for GNG in liver
• input 6 ATP in liver to generate 2 ATP in muscle

Question 12

Glycerol in GNG? process of turning to glucose?(15)

Answer 12

• glycerol is 3C molecule
• backbone of triacylglycerol (fat) with 3 fatty acids
  1. glycerol leaves fat and enters blood to be carried to liver
  2. in liver, glycerol kinase turns glycerol to G3P using one ATP
• adipose tissue does not have glycerol kinase to it cannot use glycerol
  3. G3P dehydrogenase catalyzes G3P into DHAP transferring H from NAD to NADH
  4. DHAP is an intermediate in glycolysis so it can go in reverse to generate glucose

Question 13

Propionate in GNG? process of getting glucose? (16)

Answer 13

• 3C acid molecule comes through beta oxidation(cut 2C off each time), sometimes 3C are left
  1. propionate to propionyl CoA bio thiokinase, energy used, high energy
  2. carboxylation using biotin to methyl malonyl CoA
  3. mutase catalyzes the formation of succinyl CoA using Vit B12
  4. succinyl CoA goes through TCA cycle to reach OAA, go in reverse glycolysis to get glucose

Question 14

What amino acids are used for GNG? ketogensis? (17)

Answer 14

• GNG:
• 18 of 20 are used except lysine and leucine
• carbon skeleton of most amino acids can used to make glucose
• different entry points because of different structure

KG:

• tryptophan
• isoleucine
• phenylalanine
• tyrosine

Question 15

When do you need to conduct GNG?

Answer 15

plasma glucose levels are low

Question 16

where is the carbon backbone from in GNG?

Answer 16

proteins (amino acids) or glycerol

Question 17

where is the energy driving GNG?

Answer 17

fatty acid catabolism (acetyl CoA)

-regulation comes from fatty acid beta oxidation

Question 18

How to coordinate cell to cell communication in GNG?

Answer 18

hormones (insulin, glucagon)

Question 19

Glucose usage vs storage per day?

Answer 19

• use 160g/day (120g in brain, 40g in RBC)
• store 190g glycogen
• 20g free floating in fluid
• enough storage for about one day
• GNG starts before depletion of glycogen

Question 20

Regulation of GNG overall picture? (20)

Answer 20

1. decreased insulin/glucagon ratio drives the breakdown of TG into fatty acids
2. free fatty acids enter the mitochondria where they are converted to acetyl CoA by beta oxidation, forming NADH
3. NADH and acetyl CoA inhibit pyruvate dehdyrogrenase so that pyruvate is converted into OAA rather than more acetyl CoA
4. pyruvate carboxylase is activated by acetyl CoA
5. pyruvate is converted into OAA
6. OAA is converted directly into PEP by PEP carboxykinase (induced by PKA), transported out of mitochondria
   - this is dominant at beginning because there is plenty of NADH in cytosol to complete GNG
7. OAA is indirectly converted to malate, transported out of mitochondria with NAD and converted back to OAA, forming NADH
   - this is dominant when there is not enough NADH in cytosol to carry out GNG, NADH is transported to cytosol with Malate
8. OAA can also be converted to aspartate by aminotransferase and then transported out to cytosol by anti porter glutamate aspartic transporter, turns back to OAA
   - ammonia carried will be made into urea
9. pyruvate carboxykinase is induced by high glucagon to convert OAA into PEP
10. pyruvate kinase (PK) is inhibited by increased glucagon which activates cAMP to phosphorylate PK so that it does not form more pyruvate, but completes GNG
11. glucose is formed by GNG

Question 21

Explain the hormonal regulation of F2,6bisP? (22, 23, 24)

Answer 21

1. increased glucagon (PKA) phosphorylates F2,6Pase to convert more F2,6bisP to F6P
   - lack of F2,6bisP inhibits PFK-1 and does not inhibit F1,6Pase, so increased gluconeogenesis
2. increased insulin (phosphatase) dephosphorylates PFK-2 to convert more F6P to F2,6bisP
   - F2,6bisP stimulates PFK-1 to increase glycolysis and inhibits F1,6Pase to decrease gluconeogenesis

Question 22

What are F1,6Pase and G-6-phosphatase induced by? regulation of 2nd and 3rd barriers? (25)

Answer 22

• glucagon
• G-6-phosphatase is located in ER so G6P needs to translocated to ER by G6P translocase
• deficiency of either proteins (translocase or G6Pase) leads to glycogen storage disease (can synthesis but not use)
• glucokinase nuclear translocation prevents glucose phosphorylation

Question 23

Summary of regulation of GNG?

Answer 23

• hormonal:
• increased glucagon increases GNG
• decreased insulin
• allosteric:
• increased ATP from beta oxidation
• decreased AMP
• substrate availability:
• GNG precursors driven by glucagon from different sources

Question 24

What is going on during short term fasting? (27)

Answer 24

1. lower blood glucose
   - lower insulin levels
   - higher glucagon
2. phosphorylation of enzymes to turn glycogen into G6P which turns into glucose to be transported out into blood (brain, RBC)
3. brain uses glucose for energy
4. RBC convert glucose to lactate in Cori cycle and transport it to liver (11)
5. adipose breaks down triacylglycerol into glycerol and free fatty acids
   - glycerol goes to liver for GNG (12)
6. fatty acids go to liver or muscle to be turned into acetyl CoA
7. acetyl CoA goes to make ketone bodies
8. ketone bodies go to muscle where they are converted back to acetyl CoA, and ATP
9. amino acids broken down in muscle, sent to liver to be used in GNG (alanine)
10. ammonia from amino acids will be used to make urea

Question 25

Long term starvation? (28)

Answer 25

1. low glucose
   - low insulin
   - high glucagon
   - glycogen depleted
2. glucose from liver mainly goes to RBC to support cori cycle because RBC can only use glucose
3. amino acids are used sparingly
4. adipose tissue is broken down into glycerol for GNG and free fatty acids
   - fatty acids are converted to acetyl CoA in muscle and liver to make ATP and ketone bodies
5. ketone bodies go straight to brain to make ATP
   - brain prefers to use ketone bodies but usually use glucose because KBs are not available
   - in this case, brain uses KBs to save glucose for RBC which cannot use anything else
6. urea and urine is reduced

Question 26

summary graph of short term and long term fasting? (29)

Answer 26

graph

• ketone bodies increase exponentially
• fatty acids increase linearly
• how long you can last without food, depends on how much fat you have

Question 27

How are triacylglycerols mobilized in fat to liver during fasting state? hormones and enzymes?(30)

Answer 27

1. decreased insulin
2. increased glucagon, epinephrine, norepinephrine, AMPK (sensing levels of AMP, low energy means more AMP)
3. hormone sensitive lipase (HSL) is phosphorylated and is activated
4. lipase breaks down diester bond from triacylglycerol to form glycerol and 3 fatty acids
5. glycerol goes to liver which has glycerol kinase to produce DHAP for GNG
   - adipose lacks enzyme to re-use glycerol
6. fatty acid is carried by albumin in blood to muscle and liver for beta oxidation for energy (acetyl CoA in liver as well for ketone bodies)

Question 28

Pancreatic lipase function?

Answer 28

• active in digestion
• secreted by pancreas
• acts only on primary alcohols in TG

Question 29

Lipoprotein lipase function?

Answer 29

• extracellular in lumen of capillaries
• acts on TGs from VLDL and chylomicron
• fatty acid enter muscle to use as energy
• fatty acid enter adipose to be stored

Question 30

hormone sensitive lipase function?

Answer 30

• found inside adipose tissue
• mobilizes fatty acid and TG
• sensitive to glucagon and epinephrine (active)
• sensitive to insulin (inactive)

Question 31

What are ketone bodies?

Answer 31

• acetoacetate
• beta-hydroxybutyrate
• acetone

Question 32

What is the precursor for ketone bodies?

Answer 32

-acetyl CoA (derived from fatty acids through beta oxidation)

Question 33

Why bother to turn fatty acids into ketone bodies?

Answer 33

• fatty acids are fat soluble and cannot pass through blood brain barrier
• ketone bodies are water soluble and can be used by brain

Question 34

Process of synthesis of ketone bodies? (32)

Answer 34

1. 2 acetyl CoAs are combined by beta-ketothiolase to form acetoacetyl CoA
2. another acetyl CoA is added by HMG-CoA synthase to form HMG-CoA (rate limiting-irreversible)
3. HMG-CoA lyase removes one of the original acetyl CoAs to form acetoacetate
4. spontaneously loses CO2 to form acetone
5. the rest is reduced by beta hydroxybutarate dehydrogenase to form beta hydroxybutarate
6. these 3 molecules (beta-hydroxybutarate, acetone, and acetoacetate) are considered the ketone bodies
   - only can use two of them for energy (acetone is not usable form of energy, it is evaporated)

Question 35

Summary of glucagon action of TG and fate of fatty acid?

Answer 35

1. HSL is activated due to glucagon levels, epinephrine, nor, AMPK
2. active phosphorylated HSL cleaves fatty acid from TG
3. fatty acids are released from adipose travels in blood by albumin
4. in liver, FA synthesis turned off
   - acetyl CoA carboxylase inactive (decreased by fatty acid acetyl CoA), therefore decreased malonyl CoA
5. carnitine acyl transferase 1 (in mito membrane) is active to transport form outer to inner membrane

Question 36

Summary of ketone bodies synthesis?

Answer 36

1. increased acetyl CoA due to increased beta oxidation
2. idling of TCA cycle - a lot of NADH which inhibits TCA
3. HMG-CoA synthase is rate limiting (irreversible) is induced by glucagon
4. liver cannot use KBs because they lack beta-ketoacyl -CoA transferase
5. KBs used by muscle, kidney, brain

Question 37

How do certain tissues use Ketone bodies? (35)

Answer 37

• heart, muscle, brain use them
  1. beta-hydroxybutarate (more energy rich) carries two extra H’s compared to acetoacetate, which are transferred to NADH for energy
  2. the enzyme, beta-ketoacyl-CoA transferase is necessary for ketone bodies to be used
  3. this enzyme takes the CoA from succinyl CoA and adds it to acetoacetate to make acetoacetyl-CoA
  4. acetoacetyl CoA is turned into two acetyl CoAs by beta-ketothiolase
  5. acetyl CoA goes through TCA to form ATP

Question 38

Why doesnt the liver use ketone bodies for energy?

Answer 38

lacks the enzyme beta-ketoacyl-CoA transferase

Question 39

What does excess ketone bodies lead to?

Answer 39

• ketosis
• acetoacetate and hydroxybutarate are acids
• over production of KB leads to ketoacidosis
• diabetic acidosis- high blood glucose but tissues are glucose starved, similar to fasting
• alcohol induced ketoacidosis
• starvation induced ketoacidosis

Question 40

Alcohol induced acidosis?

Answer 40

1. ethanol is high energy like fatty acids KBs b/c two carbons
2. alcohol dehydrogenase converts ethanol into acetyldehyde (toxin), can be further oxidized to generated acetate (acetaldehyde dehydrogenase), this is not regulated
3. both NADPH and NADH are generated to feed the ETC
4. serves for energy purposes, a lot of NADH means there is not enough NAD (already used) to be used for beta oxidation
5. fatty acids are mobilized but you cannot use it, so there is an accumulation of fatty acids in liver
6. NAD is also not available for TCA cycle to continue
7. Pyruvate also turns into lactate which oxidizes NADH to NAD, this is due to excess NADH, this leads to acidosis
8. ketoacidosis
9. uric acid- Gout disease
   - this mimics fasting condition because people who drink a lot, don’t eat a lot

Question 41

Summary of everything? (37)

Answer 41

explain pic

Question 42

Beta oxidation of fatty acids with GNG?

Answer 42

• beta oxidation of fatty acids in mitochondria generates:
• increased NADH, which results in increased ATP
• increased acetyl CoA
• liver spares itself and converts acetyl CoA to ketone bodies (instead of TCA)
• beta oxidation drives GNG

Question 43

Clinical conditions of diabetic ketoacidosis?

Answer 43

• accompanies by insulin deficiency, hyperglycemia, dehydration
• type 1 diabetes (insulin not made), lack of insulin prevents glucose absorption
• lack of insulin causes unchecked ketone body production due to increased levels of glucagon which activates HSL

Question 44

Clinical conditions of alcoholic ketoacidosis?

Answer 44

• alcohol causes dehydration, resulting in osmosis movement of water into urine
• products of alcohol used for energy, but glucose may become low
• alcohol blocks first steps of GNG

Question 45

Ketogenic diet?

Answer 45

• 4x more fat than protein or CHO (80% from fat)
• side effects: dehydration and constipation

Question 46

Pyruvate carboxylase is an enzyme that

A. Catalyzes the formation of pyruvate from oxaloacetate

B. Catalyzes the formation of PEP from pyruvate

C. Allosterically inhibited by Acetyl CoA

D. Uses NADPH as its cofactor

E. Functions in the mitochondria

Answer 46

E

Question 47

Which of the following enzymes are more active when glucagon levels are high?

A. G-6-phosphatase and F-2,6-bisphosphatase

B. G-6-phosphatase and Glucokinase

C. F-1,6-bisphosphatase and Hexokinase

D. F-2,6-bisphosphatase and PFK-1

E. F-2,6-bisphosphotase and PFK-2

Answer 47

A

Question 48

During gluconeogenesis, which of the following enzymes are activated?

A. Pyruvate carboxylase and PEP carboxykinase

B. Pyruvate carboxylase and pyruvate dehydrogenase

C. Pyruvate dehydrogenase and pyruvate kinase

D. Pyruvate kinase and pyruvate carboxylase

E. Pyruvate kinase and PEP carboxykinase

Answer 48

A

Question 49

After a high carb meal and if citrate level is elevated:

A. ADP/ATP should be High

B. TCA cycle should be more active

C. PFK1 should be more active

D. Pyruvate kinase should be more active

E. Gluokinase should be more active

Answer 49

E