1. Overview of Cellular Respiration
Electrons carried via NADH
Electrons carried via NADH & FADH2
MITOCHONDRION
KREBS CYCLE
ELECTRON TRANSPORT CHAIN & OXIDATIVE PHOSPHORYLATION
GLYCOLYSIS
GLUCOSE PYRUVATE
CYTOSOL
ATP
ATP
ATP
(substrate level (substrate level (oxidative
phosphorylation) phosphorylation) phosphorylation)

2. Task Read the learning outcomes on Glycolysis on the next slide
How do you feel?
Where are your gaps?

3. Learning outcomes:
State that glycolysis occurs in the cytoplasm of cells.
Outline the process of glycolysis beginning with the phosphorylation of glucose to hexose bisphosphate, splitting of hexose bisphosphate into two triose phosphate molecules and further oxidation to pyruvate, producing a small yield of ATP and reduced NAD;
State that, during aerobic respiration in animals, pyruvate is actively transported into mitochondria;

4. Stage 1: Respiration: Glycolysis
Split into 4 stages:
Phosphorylation
Splitting of the hexose 1,6 bisphosphate
Oxidation of triose phosphate
Conversion to pyruvate

5. Cellular Respiration Watch.... Good link

6. Glycolysis – an introduction
Glycolysis means splitting of sugar
Occurs in cytoplasm of all living cells (sarcoplasm of muscle cells)
Stores of glycogen in muscle/liver (SYNOPTIC) a polymer of glucose must first be converted to glucose
GLUCOSE is the main respiratory substrate.
Good fuel but is unstable and unreactive
Glucose, a six carbon sugar is split into two three-carbon sugars – These smaller sugars are then oxidised, and their remaining atoms are rearranged to form two molecules of pyruvate

7. Stage 1 Phosphorylation
Because glucose is stable and unreactive it needs an input of energy to get the reaction started
1 ATP molecule is hydrolysed to provide the energy to phosphorylate the glucose molecule at carbon 6 to form glucose 6-phosphate
This is changed to fructose 6-phosphate
1 ATP is hydrolysed and attaches to fructose 6-phosphate at C1
This is now fructose 1,6-bisphosphate

8. Stage 1 Phosphorylation
The hexose sugar is activated
This prevents it from leaving the cell
Referred to as hexose 1,6-bisphosphate
Each stage is catalysed by a different enzyme
2 ATP molecules have been used!

9. Stage 2:Splitting Hexose 1,6-bisphosphate
Split into 2x triose phosphate

10. Stage 3:Oxidation 2x triose phosphate
Anaerobic BUT 2 hydrogen atoms (with their electrons) are removed from each TP molecule
Dehydrogenase enzymes are involved
Aided by coenzyme NAD
NAD combines with hydrogen atoms and becomes reduced NAD
Produced per glucose molecule : 2 molecules reduced NAD and 2 ATP by substrate level phosphorylation
2 x intermediate 3C compounds

11. Substrate level phosphorylation
The ATP is produced by substrate level phosphorylation
Glucose is at a higher energy level than pyruvate: so energy is used to produce ATP (phosphate from intermediate compounds transferred to ADP)

12. Stage 4: Conversion to pyruvate
2 x intermediate 3C compounds
4 enzyme-catalysed reactions convert each TP molecule to a molecule of pyruvate (3C)
In this process 2x ADP phosphorylated to produce 2 ATP in substrate level phosphorylation.

13. The end products of glycolysis…
Over this series of reactions 2 ATP are used up
However 4 ATP molecules are created
Therefore there is a net gain of 2 ATP (substrate level phosphorylation)
2 reduced NAD are also made which will go to the respiratory chain on the inner membrane of the mitochondria and used to generate more ATP during oxidative phosphorylation.
2 molecules of 3C pyruvate: actively transported into the mitochondrial matrix for the next stage of aerobic respiration

14. Pyruvate is actively transported into the matrix of the mitochondria where the Krebs cycle begins…

15. TASKS
Using the next slide, ensure you can outline the process of glycolysis
Complete the Glycolysis sort (answer on slide 2)
What detail can you add?
Complete the exam questions in pack:
Figure 2.1 represents the first stage of respiration (4 marks)
Glycolysis is the initial stage of cellular respiration (i) and (ii) (5 marks)

17. 1.An ATP molecule is hydrolysed and the phosphate attached to the glucose molecule at C-6 (forms Glucose 6-phosphate) 2. Glucose 6-phosphate is turned into fructose 6 phosphate 3. Another ATP is hydrolysed, and the phosphate attached to C-1 4. The hexose sugar is activated by the energy release from the hydrolysed ATP molecules. It now cannot leave the cell and is known as Hexose-1,6-biphosphate 5. It is split into two molecules of Triose phosphate 6. Two hydrogen atoms are removed from each Triose Phosphate, which involved dehydrogenase enzymes. 7. NAD combines with the Hydrogen atoms to form reduce NAD 8. Two molecules of ATP are formed- substrate level phosphorylation 9. Four enzyme-catalysed reactions convert each triose phosphate molecule into a molecule of pyruvate. 10. Two more molecules of ATP are formed, so there is a net gain of two ATP

18. The following figure is an outline of the glycolytic pathway.
With reference to the figure, state the letter, A, B or C, in the glycolytic pathway where the following processes occur.
phosphorylation using ATP ………………………………..
dehydrogenation ………………………………..
formation of ATP ………………………………..
splitting of a hexose ………………………………..
[Total 4 marks]

19. A ;
C ;
B ;