3. Glycolysis
• Occurs in cytoplasm when glucose a hexose (6C) sugar is broken
down into two molecules of pyruvate (3C)
• Glycolysis involves ten individual steps, each catalysed by an
enzyme.
• Energy is released and there is a net production of 2 ATP
molecules.
• Reduced NAD is formed, which has the potential to produce
more ATP.
Glycolysis takes place in the cytosol of cells.
Glucose enters the Glycolysis pathway by conversion to
glucose-6-phosphate.
H O
OH
H
OH
H
OH
CH2OPO3
2
H
OH
H
1
6
5
4
3 2
glucose-6-phosphate
4. GLYCOLISIS
• Glycolisis oxidation of glucose energy
• It can function either aerobically or anaerobically
pyruvate lactate
• Occurs in the cytosol of all cell
• AEROBICALLY GLYCOLYSIS :
Pyruvate Mitochondria oxidized to
Asetil CoA Kreb’s Cycle
CO2 + H2O + ATP
11. • NADH + H+ and FADH2 enter ETC and produce;
NADH + H+ 3 ATP
FADH2 2 ATP
c
c
Glycolysis complete Reaction (Energetic)
Glucose 2Pyruvate + 2NADH+ 2ATP
2 NADH produce = 6 ATP
ATP produce = 2 ATP x 2 = 4 Atp
2 ATP Used = - 2 ATP
Total = 8 ATP
12. Regulation of Glycolysis:
Two types controls for metabolic reactions:
a) Substrate limited : When concentrations of reactant and products in the cell
are near equilibrium, then it is the availability of substrate which decides
the rate of reaction.
b) Enzyme-limited: When concentration of substrate and products are far away
from the equilibrium, then it is activity of enzyme that decides the rate of
reaction. These reactions are the one which control the flux of the overall
pathway.
There are three steps in glycolysis that have enzymes which regulate the flux of
glycolysis.
I. The hexokinase (HK)
II. The phoshofructokinase (PFK)
III. The pyruvate kinase
13.
14.
15. Pyruvate is first transported into
mitochondria via a specific transporter on
the inner membrane and then oxidized to
acetyl-CoA by the catalysis of pyruvate
dehydrogenase complex.
18. 3
An overview of
the citric acid cycle
None of the intermediates
are phosphorylated.
None of the intermediates
are phosphorylated
All are either di- or
tricarboxylic acids.
To regenerate
oxaloacetate.
all are either di- or
tricarboxylic acids.
21. TCA cycle (Energetics):
Acetyl CoA 2CO2 + 3NADH+ FADH2+ GTP
3 NADH produce = 9 ATP
1FADH2 produce = 2 ATP
1 GTP produce = 1 ATP
12 ATPs
But 2 acetyl Con A take part in reaction so,
2 x 12ATPs = Toatal =
24 ATP formed
22. Total yield of high energy ATP in
the aerobic catabolism of glucose?
Glycolysis:
glucose 2pyruvate + 2NADH+2ATP 8 ATPs
Pyruvate Dehydrogenase:
2pyruvate 2acetyl CoA + 2NADH 6 ATPs
TCA cycle:
acetyl CoA2CO2+3NADH+FADH2+GTP 2x12ATPs
OVERALL yield from glucose 38 ATPs
23. ENERGY RELATIONSHIPS
G° for oxidation of glucose to CO2 is 2,840 kJ/mole
Much of this energy conserved as ATP
38 ATP X 30.5 kJ/mole ATP
=1,160 kJ/mole glucose
This represents 41% conservation of the potential
energy available in glucose as ATP.
