PHOTOSYNTHESIS REVIEW AND CELLULAR RESPIRATION OVERVIEW

ENERGY AND LIFE

Plants and some other organisms are able to use the light energy from the sun to produce food.

The basic energy source for all cells is ATP, but it is not a good energy storage molecule.

Glucose can hold 90 times more energy than ATP.

PHOTOSYNTHESIS: AN OVERVIEW

Photosynthesis uses the energy of sunlight to convert water and carbon dioxide into high-energy sugars (glucose) and oxygen.

Photosynthesis requires water, carbon dioxide, light and the pigment chlorophyll to make glucose and oxygen.

PHOTOSYNTHESIS: EQUATION

Photosynthesis:

6CO2 + 6H2O C6H12O6 + 6O2glucose

SUNphotons

REACTIONS OF PHOTOSYNTHESIS

2 Reactions: Light-dependent and Calvin Cycle (light-independent)

Light-dependent: produce oxygen, convert ADP and NADP+ into ATP and NADPH, occur in the thylakoid membrane

Calvin Cycle: uses ATP and NADPH from the light-dependent reactions to produce glucose

CELLULAR RESPIRATION

Cellular respiration: releases energy by breaking down glucose and other food molecules in the presence of oxygen.

GLYCOLYSIS

Glycolysis: breaks one molecule of glucose in half to make 2 pyruvic acid molecules

Captures two pairs of high-energy electrons with the carrier NAD+

Does not require energy, supplies chemical energy to cells when oxygen is not available

CHEMICAL ENERGY AND FOOD

Food = ENERGY!

Energy in food is measured in Calories

1 Calorie = 1000 calories

1 calorie = energy needed to raise the temp. of 1 gram of water by 1⁰ Celsius

One molecule of glucose = 3811 calories

OVERVIEW OF CELLULAR RESPIRATION

EQUATION:

C6H12O6 + 6O2 -----> 6CO2 + 6H20 + energy

Glucose + Oxygen Carbon Dioxide + Water + ATP & Heat

Controlled release of energy

The energy in one glucose molecule may be used to produce 36 ATP

Involves a series of 3 reactions --- Glycolysis, Kreb's Cycle, & Electron Transport Chain

GLYCOLYSIS REACTIONS

Occurs in the cytoplasm

Summary of the steps of Glycolysis: a. 2 ATP added to glucose (6C) to energize it.

b. Glucose split to 2 PGAL (3C). (PGAL = phosphoglyceraldehyde)

c. H+ and e- taken from each PGAL & given to make 2 NADH.

d. NADH is energy and e- carrier.

e. Each PGAL rearranged into pyruvate (3C), with energy transferred to make 4 ATP

GLYCOLYSIS REACTIONS

Although glycolysis makes 4 ATP, the net ATP production by this step is 2 ATP (because 2 ATP were used to start glycolysis).

WHAT HAPPENS NEXT?

If oxygen is available to the cell, the pyruvate will move into the mitochondria & aerobic respiration will begin.

Aerobic = with oxygen (true cell respiration)

If no oxygen is available to the cell (anaerobic), the pyruvate will be fermented

Anaerobic = no oxygen (called fermentation)

AEROBIC RESPIRATION

Occurs in the mitochondria

Includes the Krebs Cycle & the Electron Transport Chain

Pyruvic acid from glycolysis diffuses into matrix of mitochondria & reacts with coenzyme A to form acetyl-CoA (2-carbon compound)

CO2 and NADH are also produced

MITOCHONDRIA

Has smooth outer membrane & folded inner membrane

Folds are called cristae

Space inside cristae is called the matrix & contains DNA & ribosomes

Site of aerobic respiration

Krebs cycle takes place in matrix

Electron Transport Chain takes place in cristae

MITOCHONDRIA STRUCTURE

KREB’S CYCLE

Named for biochemist Hans Krebs

Also known as the Citric acid Cycle

Requires 2 cycles to metabolize glucose

Pyruvic acid is broken down into CO2 in a series of energy extracting reactions

KREB’S CYCLE

Steps of Kreb’s Cycle

Pyruvic acid (3C) enters mitochondria

One carbon is removed, forming CO2 and e- are removed, changing NAD+ into NADH.

Coenzyme-A joins the 2C molecule, forming acetyl-CoA.

Acetyl-CoA then adds the 2-carbon acetyl group to a 4-carbon compound, forming citric acid.

KREB’S CYCLE

Citric acid is broken down into a 5-C compound, then into a 4-C compound

2 more CO2 get released, and electrons join NAD+ and FAD, forming NADH and FADH2.

One molecule of ATP is made

TOTAL: 4 NADH, 1 FADH2 and 1 ATP

ELECTRON TRANSPORT CHAIN

Follows Krebs Cycle in aerobic respiration

Uses the high-energy electrons from the Krebs cycle to convert ADP into ATP

ELECTRON TRANSPORT CHAIN

Steps of Electron Transport Chain:

High-energy electrons from NADH and FADH2 are passed along the electron transport chain

Electrons join with H+ and oxygen at the end to form water

As electrons move through chain, H+ are pumped across the membrane creating a gradient

H+ move through ATP synthase which combines an ADP and a P to make ATP

Each pair of electrons provides enough energy to make 3 ATP

THE TOTALS

How much do we get from one glucose?

Glycolysis = 2 ATP

Krebs cycle and Electron Transport = 34 ATP

For a total of 36 ATP

ANAEROBIC RESPIRATION

Also known as fermentation

Releases energy from food molecules by producing ATP in the absence of oxygen

NADH converts back to NAD+ by passing electrons back to pyruvic acid (pyruvate)

FERMENTATION

2 main types Alcoholic fermentation and lactic acid

fermentation

In the absence of oxygen, yeast and few other microorganisms use alcoholic fermentation, forming ethyl alcohol and carbon dioxide as wastes

Animals cannot perform alcoholic fermentation, but some cells, such as human muscle cells, can convert glucose into lactic acid

ALCOHOLIC FERMENTATION

Pyruvic acid + NADH alcohol + CO2 + NAD+

Produces CO2 and alcohol

Used to make bread, wine, beer, root beer, etc…

LACTIC ACID FERMENTATION

Pyruvic acid + NADH lactic acid + NAD+

Produced in muscle cells during rapid exercise when the body cannot supply enough oxygen to the tissues

Buildup of lactic acid causes a painful, burning sensation

Used to make a variety of foods and beverages: cheese, yogurt, buttermilk, pickles, sauerkraut, etc…

OVERALL

The products of photosynthesis are similar to the reactants of cellular respiration.

The products of cellular respiration are the reactants of photosynthesis.