Photosynthetic Conversion of Light

1. Photosynthetic Conversion of Light Biogradska gora by Snežana Trifunović (2007) http://en.wikipedia.org/wiki/File:Biogradska_suma.jpg ldh

2. Lesson Objective The student will describe the process of photosynthesis. Subobjective 1: The student will describe light-dependent reactions. Subobjective 2: The student will describe light-independent reactions.

3. Let's discuss photosynthesis. Pull out the tabs to learn more about what we will be 
discussing in this lesson. Photosynthesis uses the energy of sunlight to convert 
carbon dioxide and water into high energy sugars and 
oxygen. Chemically, this is written: 6CO2 + 6H2O + energy C6H12O6 + 6O2 (Carbon Dioxide + Water + light energy --> sugar + oxygen) Sugar is the end product of photosynthesis and 
oxygen is the byproduct. Organisms that use energy 
to produce or synthesize complex organic molecules 
(such as sugar) from inorganic molecules (such as 
CO2) are called autotrophs. Those that use light as their energy source are called photoautotrophs. There are two sets of reactions involved in 
photosynthesis: 1) Light-dependent reactions (or 
light reactions) and 2) Light-independent 
reactions (or dark reactions).

4. The diagram below shows the process of photosynthesis. A simplified diagram of photosynthesis by Daniel Mayer (2008) http://en.wikipedia.org/wiki/File:Simple_photosynthesis_overview.svg Light reactions (or 
photophosphorylation) 
produce oxygen, ATP 
and NADPH. Dark reactions (or 
the Calvin Cycle) 
produce sugar, ADP 
and NADP+.

5. Photosynthesis occurs in chloroplasts. Let's look 
at the structure of a chloroplast. Click on each number to see the parts of the chloroplast. A diagram showing the simple structure of a chloroplast by Ollin (2009) http://en.wikipedia.org/wiki/File:Chloroplast_diagram.svg

6. Let's discuss the light-dependent reactions. This is the first stage of photosynthesis. Click on the 
picture of chloroplasts below to learn more. Chloroplasts are organelles within plant cells. A typical 
plant cell contains 10 to 100 chloroplasts. Chloroplasts are flat discs. They range from 2 to 10 μm in diameter and 1 to 2 μm thick. Chloroplasts contain stacks (grana) of thylakoids. Thylakoids are flat membrane bound discs. 
Photosynthesis occurs on the thylakoid membrane. Photosynthesis occurs as a series of chemical reactions.

7. Let's look at the chemical reactions involved in the 
light reactions. Click on the numbers below to learn more. Photosynthesis begins with the 
sunlight exciting chlorophyll 680 
to a higher energy state. It 
loses an electron to a 
pheophytin. Chlorophyll 680 
gets a replacement electron by 
splitting water. The electron passed to a pheophytin is then 
passed to a quinone molecule precipitating the 
beginning of an electron transport chain. This 
chain creates the energy used to transform 
ADP and an inorganic phosphate into ATP. 1 2 The ferredoxin carries the 
electrons to the enzyme 
ferredoxin NADP+ which then 
reduces NADP+ to NADPH. 
ATP and NADPH are both 
energy storing molecules which 
fuel the light-independent (or 
dark) reactions. The end of this electron transport chain is 
plastocyanin which transfers the electrons 
to chlorophyll inside photosystem I (PSI). 
The chlorophyll is excited to a higher 
energy state by light where the electrons 
are removed and transferred through an 
intermediary to ferredoxin. 3 4 Z-scheme by Bensaccount (2005) http://en.wikipedia.org/wiki/File:Z-scheme.png

8. Let's discuss light-independent reactions. Click on the boxes to learn more. Light-independent reactions occur in the 
stroma of the chloroplasts. Light-independent reactions are also known as carbon-fixing 
reactions, dark reactions, and the Calvin cycle. There are three phases to the Calvin cycle: carbon fixation, 
reduction reactions, and RuBP regeneration. These reactions occur only in the presence of 
light but do not require light's energy to occur.

9. The Calvin cycle is pictured below. Click on each number below to see an explanation of the step depicted 
in that portion of the cycle. After reading the explanation, click the 
"Return to Home page" button to return to this page. 1 6 2 5 The colored dots 
represent the following 
atoms: Black - Carbon Red - Oxygen White - Hydrogen Pink - Phosphorus 4 3 Go to 
Summary 
page Overview of the Calvin Cycle pathway by Mike Jones (2010) http://en.wikipedia.org/wiki/File:Calvin-cycle4.svg

10. Carbon dioxide is attached to ribulase-1-5-bisphosphate (RuBP), 
a five carbon sugar compound, by the enzyme RuBisCO to form 
an unstable intermediary six carbon compound. 1 For simplicity, we will 
assume that three CO2 molecules begin the 
reaction with three RuBP 
molecules. 1 6 2 5 4 3 We start with 18 
carbon atoms (3 x 5 
RuBP and 3 x 1 
CO2). Return to 
Home 
page Overview of the Calvin Cycle pathway by Mike Jones (2010) http://en.wikipedia.org/wiki/File:Calvin-cycle4.svg

11. Because this intermediary six carbon compound is unstable, it 
breaks into two molecules of 3-phosphoglycerate (PGA). 2 For simplicity, we will 
assume that three CO2 molecules begin the 
reaction with three RuBP 
molecules. 1 6 2 5 4 3 We now have three 
six-carbon molecules 
for 18 carbon atoms. Return to 
Home 
page Overview of the Calvin Cycle pathway by Mike Jones (2010) http://en.wikipedia.org/wiki/File:Calvin-cycle4.svg

12. One ATP and one NADPH are required to convert one molecule of 
PGA to glyceraldehyde 3-phosphate (G3P), an energy rich 
molecule. The ATP is reduced to ADP and the NADPH to NADP+. These are then used by the light-dependent reactions to create 
more ATP and NADPH. 3 For simplicity, we will 
assume that three CO2 molecules begin the 
reaction with three RuBP 
molecules. 1 6 2 5 4 3 We still have three 
six-carbon molecules 
for 18 carbon atoms. Return to 
Home 
page Overview of the Calvin Cycle pathway by Mike Jones (2010) http://en.wikipedia.org/wiki/File:Calvin-cycle4.svg

13. One of the G3P molecules leave the cycle. It may combine 
with another G3P molecule to form a sugar molecule or it 
may also be used to form starch, cellulose, or other 
molecules needed by the plant. 4 For simplicity, we will 
assume that three CO2 molecules begin the 
reaction with three RuBP 
molecules. 1 6 2 5 4 3 One G3P molecule 
leaves the cycle 
leaving five three-
carbon molecules in 
the cycle or 15 carbon 
atoms. Return to 
Home 
page Overview of the Calvin Cycle pathway by Mike Jones (2010) http://en.wikipedia.org/wiki/File:Calvin-cycle4.svg

14. The remaining G3P molecules are recycled through various 
intermediate steps back into Ribulose 5-phosphate. 5 For simplicity, we will 
assume that three CO2 molecules begin the 
reaction with three RuBP 
molecules. 1 6 2 5 4 3 We now have three 
five-carbon 
molecules or 15 
carbon atoms. Return to 
Home 
page Overview of the Calvin Cycle pathway by Mike Jones (2010) http://en.wikipedia.org/wiki/File:Calvin-cycle4.svg

15. One ATP is used per molecule to convert this back into 
RuBP. This RuBP is now ready to accept another CO2 molecule and continue the cycle. 6 For simplicity, we will 
assume that three CO2 molecules begin the 
reaction with three RuBP 
molecules. 1 6 2 5 4 3 We still have three 
five-carbon 
molecules or 15 
carbon atoms. Return to 
Home 
page Overview of the Calvin Cycle pathway by Mike Jones (2010) http://en.wikipedia.org/wiki/File:Calvin-cycle4.svg

16. Let's summarize the light-independent reactions. Click on the boxes below. The light-independent reactions fix inorganic carbon from 
CO2 into organic molecules used by the plant. The light-independent reactions consume ATP and 
NADPH, which are produced by the light-dependent 
reactions. The light-independent reactions produce ADP and 
NADP+, which are consumed in the light-dependent reactions. The light-independent reactions consume RuBP and 
then regenerate more RuBP so that the cycle can 
continue.

17. The following website shows step-by-step, the 
processes of both the light-dependent and light-
independent reactions. http://www.botany.uwc.ac.za/ecotree/photosynthesis/photosynthesis1.htm