Glycolysis and Fermentation

Chapter 8

Cellular Respiration and Photosynthesis

0 Things to know in these chapters

0 Names and order of the processes

0 Reactants and products of each process

0 How do they relate to the overall equations?

0 What environmental factors are needed to run the process?

0 Where will these processes occur? (organisms and organelles)

0 The occasional important “step” within the process

Cellular Respiration 0 Cellular respiration is the process of breaking down sugars to

provide cells with energy

0 Cellular Respiration Equation:

0 C6H12O6 + 6 O2 6 CO2 + 6 H2O + Energy

0 Cellular respiration allows for a molecule of glucose to be broken down as slowly as possible

0 If glucose was broken down quickly, much of the energy it holds would be lost as heat

0 Cellular respiration is able to harness 39% of the energy available in a glucose molecule

0 Photosynthesis is 55% efficient

0 The average gasoline automobile is 25% efficient

Cellular Respiration 0 Cellular respiration is 3 separate processes that combine to

maximize the energy output in various conditions

0 1. Glycolysis.

0 Slowly convert glucose into pyruvic acid.

0 Obtain small quantity of energy; very little wasted though

0 Designed to maximize energy production later

0 2. Aerobic Respiration

0 Takes place when cell has access to oxygen

0 Citric Acid Cycle and Electron Transport Chain

0 Large amounts of ATP produced

0 3. Anaerobic Respiration (Fermentation)

0 Takes place when cell has no access to oxygen

0 Alcohol or lactic acid produced

0 Maintains life temporarily until oxygen can be maintained

Glycolysis Summary 0 Each process in photosynthesis and respiration is a machine.

0 The machine takes a reactant and, throughout a series of steps, builds products.

0 Like man-made machines, each of these steps creates waste material

0 Unlike man-made machines, the waste materials just happen to be molecules the cell needs

0 Sometimes, the products also are needed. Sometimes they aren’t.

0 As long as the cell keeps these machines working, the machines will keep churning out these “waste” products

Glycolysis Summary 0 Glycolysis takes place in the cytoplasm

0 Glycolysis is ten steps long

0 Glycolysis requires an input of energy

0 “Glyco” = glucose; “lysis” = “to split”

0 For the processes in these chapters, I will provide all the information so you know what is happening. The essential info for memorizing will be underlined

Glycolysis 0 Step 1

0 Begins with a molecule of glucose

0 Energy from an ATP is consumed

0 At this point, the cell has used energy and hasn’t harnessed any. It’s in debt.

0 By spending energy now, it can invest the energy and get MUCH more energy later.

0 The cell forms a molecule of glucose-6-phosphate

Glycolysis 0 Step 2

0 Glucose-6-phosphate is rearranged to form a molecule of fructose-6-phosphate

Glycolysis 0 Step 3

0 Another input of ATP is required

0 At this point the cell has spent two high-energy molecules and has made none.

0 The cell is even more in debt now.

0 Fructose-6-Phosphate is rearranged to form Fructose-1,6-Bisphosphate

Glycolysis 0 Step 4 and Step 5

0 The glucose molecule is split from one 6-carbon molecule into two 3-carbon molecules

0 The amount of carbon, hydrogen, oxygen and phosphorus hasn’t changed. But now there’s two molecules instead of one.

0 One molecule immediately forms a glyceraldehyde-3-phosphate (PGAL, or G3P)

0 The other forms a different molecule temporarily, then immediately forms a second PGAL

0 From this point on, there are two identical molecules that enter each step of cell respiration, which means we will double the products we make from here on out.

0 Without the input of energy at the beginning, we couldn’t have done this.

Glycolysis 0 Step 6

0 The PGAL is phosphorylated (a free-floating phosphate is attached)

0 This phosphate will eventually be attached to an ADP to form an ATP

0 PGAL also donates a Hydrogen to an NAD+ to become an NADH

0 NADH is a waste product in glycolysis, but NADH will be used later in the electron transport chain as a reactant

0 The PGAL rearranges to form a molecule of 1,3-bisphosphoglycerate (PGAP)

Glycolysis 0 Step 7

0 The PGAP donates one of it’s phosphates to an ADP to form ATP

0 The ATP is a “waste” product in glycolysis—but the cell can use it somewhere else

0 *Remember: we’ve actually made TWO ATP’s (one for each PGAL we made earlier)

0 PGAP is rearranged to form a 3-phosphoglycerate (PGA)

Glycolysis 0 Step 8

0 PGA is rearranged to form a 2-phosphoglycerate

Glycolysis 0 Step 9

0 2-phosphoglycerate loses a water molecule

0 2-phosphoglycerate is rearranged to form Phosphoenolpyruvate (PEP)

Glycolysis 0 Step 10

0 PEP donates a phosphate to form an ATP

0 The final molecule of glycolysis is a 3-carbon pyruvate.

Glycolysis Summary 0 Inputs

0 1 glucose molecule

0 2 ATP

0 Outputs

0 2 pyruvate molecules

0 2 NADH

0 4 ATP

0 Net Gain

0 2 pyruvate molecules

0 2 NADH

0 2 ATP

Fermentation 0 After glycolysis, the pyruvic acid will enter either aerobic or

anaerobic respiration

0 Aerobic respiration: if oxygen is available

0 Anaerobic respiration: if oxygen is not available

0 Anaerobic respiration, or fermentation, comes in two forms

0 Alcoholic fermentation: Yeasts and other microorganisms

0 Pyruvic acid + NADH Alcohol + CO2 + NAD+

0 Lactic Acid fermentation: muscle cells

0 Pyruvic acid + NADH Lactic Acid + NAD +

Fermentation 0 Fermentation for humans is not ideal at all. It’s a life-support

system.

0 Without oxygen, the only process for cells to obtain energy from is glycolysis.

0 In order for glycolysis to occur, it needs three reactants

0 Glucose, which is obtained from food. This is not a problem

0 ADP, to form ATP. This is not a problem

0 NAD+ to form NADH. NADH is consumed and transformed back to NAD+ during aerobic respiration

0 But…we can’t go through aerobic respiration right now. So we can’t turn the NADH back to NAD+. So we don’t have any NAD+ to use in glycolysis. So we can’t run glycolysis.

0 THIS is the problem.

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Fermentation 0 The sole purpose of fermentation is to remove the “H” off of

the NADH and turn it back to NAD+.

0 The NAD+ can then re-enter glycolysis, and the cell can get another net gain of 2 ATP.

0 2 ATP is pathetic, but it is something. So why do we do it?

0 Fermentation gives the organism a few extra precious minutes to find some oxygen again

0 Without it, organisms would die the instant their cells are without oxygen.

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Cell Respiration Summary 0C6H12O6 + 6 O2 6 CO2 + 6 H2O + Energy

0C6H12O6 : For glycolysis

06 O2 : To collect the electron in the ETC

06 CO2 : Given off in intermediate step and Citric Acid Cycle

06 H2O : Given off in the ETC

0Energy : In the form of ATP