Gluconeogenesis And Pentose Phosphate Pathway PDF

Summary

This document describes gluconeogenesis and the pentose phosphate pathway. It details learning goals, important considerations for studying metabolic pathways, key steps in metabolic pathways, and the central importance of glucose. The document also covers the four major pathways of glucose utilization, glycolysis, and various regulatory aspects. It also provides a summary of glycolysis regulation, hexokinase affinity, glucose transporters, and fructose 2-6 bisphosphate regulation, along with the fates of pyruvate and other relevant information.

Full Transcript

Gluconeogenesis and
Pentose Phosphate Pathway
 Gluconeogenesis, and the Pentose
Phosphate Pathway

Learning goals:
Review glycolysis and fates of pyruvate
Synthesis of glucose from simpler compounds:
gluconeogenesis
Oxidation of glucose in pentose phosphate pathway
What are the important things to note in
studying metabolic pathways?
Function of the pathway
Reactants, products, and overall reaction
Cells involved
Specific sites in the cell
o Transport mechanism involved if needs to be transported to
another site
Energy balance (energy metabolism)
o ATP, GTP, NADH, FADH
Regulation
Diseases involved
Drug mode of action
 Identify Key Steps

How to identify key steps?
- Rate limiting steps
- Irreversible reactions
- Connections with other pathways

What are important to know?
- Reactants and products
- Enzyme involved and regulation
REVIEW OF GLYCOLYSIS
 Central Importance of Glucose
Glucose is an excellent fuel.
– yields good amount of energy upon oxidation
−2840 kJ/mol glucose
– can be efficiently stored in the polymeric form
– Many organisms and tissues can meet their energy
needs on glucose only.

Glucose is a versatile biochemical precursor.
– Many organisms can use glucose to generate:
all the amino acids
membrane lipids
nucleotides in DNA and RNA
cofactors needed for the metabolism
 Four Major Pathways
of Glucose Utilization
Storage
– can be stored in the polymeric form (starch, glycogen)
– used for later energy needs
Energy production
– generates energy via oxidation of glucose
– short-term energy needs
Production of NADPH and pentoses
– generates NADPH for use in relieving oxidative stress and
synthesizing fatty acids
– generates pentose phosphates for use in DNA/RNA biosynthesis
Structural carbohydrate production
– used for generation of alternate carbohydrates used in cell walls
of bacteria, fungi, and plants
Four Major Pathways
of Glucose Utilization
Glycolysis
 Summary of Glycolysis
Glucose + 2 NAD+ + 2 ADP + 2 Pi  2 Pyruvate + 2 NADH + 2 H+ + 2 ATP

Used:
– 1 glucose; 2 ATP; 2 NAD+
Made:
– 2 pyruvate
various different fates
– 4 ATP
used for energy-requiring processes within the cell
– 2 NADH
must be reoxidized to NAD+ in order for glycolysis to
continue
Glycolysis is heavily regulated
– ensure proper use of nutrients
– ensure production of ATP only when needed
Summary of Glycolysis
Summary of Glycolysis Regulation
Hexokinase Affinity
Glucose Transporters
Glucose Transporters
Fructose 2-6 bisphosphate Regulation
Phosphofructokinase 1
Regulation by Reactants and Products

Increase in reactants  activation leading
to increase formation of products
Increase in products  inhibition leading to
decrease formation of products
FATES OF PYRUVATE
Fates of Pyruvate
GLUCONEOGENESIS
 Gluconeogenesis:
Making “New” Glucose

Gluconeogenesis is the
synthesis of glucose from
small sugars and non-
carbohydrate compounds.

Function: supply glucose-dependent cells; bridge
periods of prolonged fasting
 Precursors for Gluconeogenesis
Animals can produce glucose from sugars or
proteins.
– sugars: pyruvate, lactate, or oxaloacetate
– protein: from amino acids that can be converted to citric
acid cycle intermediates (or glucogenic amino acids)

Animals cannot produce glucose from fatty acids.
– product of fatty acid degradation is acetyl-CoA
– cannot have a net converstion of acetyl-CoA to
oxaloacetate
Plants, yeast, and many bacteria can do this, thus
producing glucose from fatty acids.
 Glycolysis versus Gluconeogenesis

Glycolysis occurs mainly Gluconeogenesis occurs
in the muscle and brain. mainly in the liver.
 Glycolysis versus Gluconeogenesis
Opposing pathways that are both thermodynamically
favorable
– operate in opposite direction
end product of one is the starting compound of the other
Glycolysis reactions are essentially irreversible in vivo
and cannot be used in gluconeogenesis
– must be bypassed with exergonic reactions
– no ATP generated during gluconeogenesis
– different enzymes in the different pathways
– differentially regulated to prevent a futile cycle
 Gluconeogenesis Is Expensive
2 Pyruvate + 4 ATP + 2 GTP + 2 NADH + 2 H+ + 4 H2O 
Glucose + 4 ADP + 2 GDP + 6 Pi + 2 NAD+

Costs 4 ATP, 2 GTP, and 2 NADH
Physiologically necessary: Brain, nervous system, and
red blood cells generate ATP ONLY from glucose.
Allows generation of glucose when glycogen stores
are depleted:
– during starvation
– during vigorous exercise
– can generate glucose from amino acids, but not fatty acids
Gluconeogenesis
Gluconeogenesis
 Conversion of pyruvate to
phosphoenol pyruvate

Takes place in two steps pyruvate
carboxylase is a biotin dependent
mitochondrial enzyme that converts
pyruvate to oxaloacetate in presence of
ATP & CO2
This enzyme regulates gluconeogenesis
& requires acetyl COA for its activity.
 Oxaloacetate is synthesized in the
mitochondrial matrix.
It has to be transported to the cytosol.
Due to membrane impermeability,
oxaloacetate cannot diffuse out of the
mitochondria.
It is converted to malate & transported to
cytosol.
In the cytosol, oxaloacetate is regenerated.
 The reversible conversion of oxaloacetate to
malate is catalysed by MDH, present in
mitochondria & cytosol
In the cytosol, phosphoenolpyruvate
carboxykinase converts oxaloacetate to
phosphoenol pyruvate.
 GTP (not ATP) is used in this reaction and the
CO2 is liberated.
For the conversion of pyruvate to
phosphoenol pyruvate, 2ATP equivalents are
utilized.
Gluconeogenesis
 Conversion of Fructose 1,6-bisphosphate to
fructose 6-phosphate

Phosphoenolpyruvate undergoes the reversal of
glycolysis until Fructose
1,6-bisphosphate is produced.
The enzyme Fructose 1,6-bisphosphatase
converts Fructose 1,6-bisphosphate to Fructose
6-phosphate and it requires Mg2+ ions.
This is also a regulatory enzyme.
 Conversion of glucose 6-phosphate
to glucose

Glucose 6-phosphatase catalyses the
conversion of glucose 6-phosphate to glucose.
It is present in liver & kidney but absent in
muscle, brain and adipose tissue.
Liver can replenish blood sugar through
gluconeogenesis, glucose 6- phosphatase is
present mainly in liver.
Gluconeogenesis Regulation
 Gluconeogenesis Regulation

*Reciprocal Regulation
 Gluconeogenesis from amino acids

The carbon skeleton of glucogenic amino
acids (all except leucine & lysine) results
in the formation of pyruvate or the
intermediates of citric acid cycle.
Which, ultimately, result in the synthesis
of glucose.
 Glucogenic Amino Acids
Glucogenic amino acids = able to undergo net conversion
to glucose
Intermediates of the citric acid cycle can also undergo
oxidation to oxaloacetate

Glucogenic Amino Acids, Grouped by Site of Entry
Pyruvate α-Ketoglutarate Succinyl-CoA Fumarate Oxaloacetate
Alanine Arginine Isoleucine Phenylalanine Asparagine
Cysteine Glutamate Methionine Tyrosine Asparate
Glycine Glutamine Threonine
Serine Histidine Valine
Threonine Proline
Tryptophan
 Gluconeogenesis from glycerol

Glycerol is liberated in the adipose tissue by the
hydrolysis of fats (triacylglycerols).
The enzyme glycerokinase (found in liver and
kidney, absent in adipose tissue)
activates glycerol to glycerol 3-phosphate.
It is converted to DHAP by glycerol
3-phosphate dehydrogenase.
DHAP is an intermediate in glycolysis.
 Gluconeogenesis from propionate

Oxidation of odd chain fatty acids & the
breakdown of some amino acids (methionine,
isoleucine) yields a three carbon propionyl COA.
Propionyl COA carboxylase acts on this in the
presence of ATP & biotin & converts to methyl
melonyl COA
 Which is then converted to succinyl CoA in the
presence of B12.
Succinyl CoA formed from propionyl CoA
enters gluconeogenesis.
 Gluconeogenesis from lactate (CORI cycle)

It is a process in which glucose is converted to
Lactate in the muscle and in the liver this lactate
is re-converted to glucose.
In an actively contracting muscle, pyruvate is
reduced to lactic acid which may tend to
accumulate in the muscle.
To prevent lactate accumulation, body utilizes
cori cycle.
ANAEROBIC RESPIRATION
Fates of Pyruvate
 Anaerobic Glycolysis:
Fermentation
Generation of energy (ATP) without consuming
oxygen or NAD+
No net change in oxidation state of the sugars
Reduction of pyruvate to another product
Regenerates NAD+ for further glycolysis under
anaerobic conditions
The process is used in the production of food from
beer to yogurt to soy sauce.
 Animals Undergo
Lactic Acid Fermentation
Reduction of pyruvate to lactate, reversible
During strenuous exercise, lactate builds up in the
muscle.
– generally, less than 1 minute
The acidification of muscle prevents its continuous
strenuous work.
The lactate can be transported to the liver and
converted to glucose there.
Requires a recovery time
– high amount of oxygen consumption to fuel gluconeogenesis
– restores muscle glycogen stores
Lactic Acid Fermentation
Lactic Acid Fermentation
Lactic Acid Fermentation
The Cori Cycle
The Cori Cycle
PENTOSE PHOSPHATE PATHWAY
Four Major Pathways
of Glucose Utilization
 Two Phases of the Pentose Phosphate
Pathway Simplified
AKA Hexose
Monophosphate
Shunt
Occurs in all cell
types but primarily
in the liver
– Generally, 10% of
glucose in
metabolized thru
the PPP
– In the liver 30%
 Pentose Phosphate Pathway
The main products are NADPH and ribose 5-phosphate.
NADPH is an electron donor.
– reductive biosynthesis of fatty acids and steroids (50%)
– repair of oxidative damage
– Important in cytochrome P450 enzyme
Ribose-5-phosphate is a biosynthetic precursor of
nucleotides.
– used in DNA and RNA synthesis
– or synthesis of some coenzymes
Also interconverts sugars
– to produce trioses, hexoses and pentoses
 Oxidative Phase
Generates NADPH
and a Pentose
 Oxidative Phase Generates NADPH
and a Pentose
Ribulose-5-phosphate can be used to generate ribose-5-phosphate for
DNA/RNA.
Ribulose-5-phosphate can also be used to generate xylulose-5-phosphate for
nonoxidative PPP.
NADPH and Oxidative Stress
 Nonoxidative Phase
Regenerates G-6-P from R-5-P
Used in tissues requiring more NADPH than R-5-P
– such as the liver and adipose tissue
 PPP Clinical Correlates:
Glucose-6-Phosphate Dehydrogenase Deficiency
Deficiency of G6PD
– 7.5% of world population deficient
– 35% prevalence in certain areas of Africa
– X-linked recessive inheritance
May cause:
– Hemolytic Anemia
Oxidative triggers:
– Infections: Typhoid fever, pneumonia
– Drugs: Antimalarial, sulfonamides, nitrofurantoin,
analgesics
– Certain food: fava beans
 Summary
Glycolysis, a process by which cells can extract a limited amount
of energy from glucose
Fermentation, a process by which cells can continue using
glycolysis to extract energy in anaerobic conditions
Gluconeogenesis, a process by which cells can use a variety of
metabolites for the synthesis of glucose
The differences between glycolysis and gluconeogenesis
– how they are both made thermodynamically favorable
– how they are differentially regulated to avoid a futile cycle
The pentose phosphate pathway, a process by which cells can
generate pentose phosphates and NADPH. The pentose
phosphates can be regenerated into glucose-6-phosphate,
which requires no ATP.