Laboratories for Measuring Physiological
Processes in Plants and Animals

Measurement of the Light Dependence of Photosynthesis

Photosynthesis is the most important energy-capturing process in both aquatic and terrestrial ecosystems. As the name suggests, photosynthesis is a process by which light is converted to chemical energy and is used to synthesize compounds within the organism. The green pigment chlorophyll is the central light-absorbing pigment that makes this energy capture possible. Chlorophyll, along with various other accessory pigments, is located in chloroplasts within the cells of the green portions of a plant. The leaves are the main organs of the plant housing chloroplasts and they are very well designed to capture the maximum amount of light, as you will see when you examine their structure in detail. The light energy captured by the chloroplast pigments is converted into chemical energy in the form of ATP and NADPH₂. These compounds can then be used to convert CO₂ molecules into sugar molecules, which are used to feed the plant and us. In the overall process of photosynthesis CO₂ molecules are absorbed by the leaf and O₂ molecules are released as a waste product of the process, as seen in the equation below:

6 CO₂ + 12 H₂O → C₆H₁₂O₆ + 6 O₂ + 6 H₂O

Thus the rate of photosynthesis can be determined by measuring the rate of either O₂ production or CO₂ uptake.

The purpose of this experiment is to demonstrate that leaves produce O₂ during photosynthesis and to measure photosynthetic rate by measuring the rate at which O₂ is evolved from a leaf at various light intensities or wavelengths. In addition the results will show that the rate of photosynthesis increases with light intensity until a light saturation point is reached. At that point, photosynthetic rate is limited either by the ability of the leaf to convert the light energy it absorbs to chemical energy, or by the supply of some other factor required for photosynthesis, such as CO₂. In addition, you will determine the effect of altering the wavelength of light available to the leaves.

You must read the file "Measurement of Photosynthetic Rate" in the Photosynthesis Pack Folder or on the Web at www.grinnell.edu/courses/bio/qubitmanual/ before proceeding with the experiment.

Materials

Leaves of a higher plant
Qubit Systems photosynthesis laboratory package with oxygen sensor

Procedure

1. The computer screen will show two graphs, the upper graph displaying percentage O₂ plotted against time, and the lower graph showing photon flux (µmol quanta/m²/s) plotted against time. Adjust the time axis on both graphs to 60 min by using the mouse to highlight the maximum value present and typing in 60, then Press Enter.
   
   
2. With the light off, seal the leaf inside the leaf chamber so that no part of the leaf is shaded by the O₂ sensor or the gas inlet and outlet ports. It does not matter if the leaf is too large to be fully sealed within the chamber, and the "excess" may protrude out of the chamber without influencing your results. When closing the chamber turn the thumb-screws finger tight only.
3. Place a beaker with 200 ml of water on top of the chamber so that it covers the major part of the leaf area. This serves as a heat filter; thus the water should be changed every 10-15 min to prevent heating of the leaf. Position the light above the beaker so that its bottom edge is 11 cm from the top of the leaf chamber. Turn on the light to full intensity and record the irradiance reading at the bottom of the screen.
4. Using a drinking straw, inflate a plastic gas bag with your breath being careful not to put pressure on the seams by over-inflating the bag. Seal the bag with the clip provided. Depending on your metabolic condition, your exhaled breath should contain between 16 and 18% O₂, and 3 to 5% CO₂.
5. Click on the Start button on the bottom left hand side of the computer screen. The button will change to a Stop button and data will begin to appear on the two graphs on the screen and as numerals on the bottom of the screen. The initial O₂ concentration should be close to 20.7% O₂, and the initial photon flux should reflect the maximum output of the lamp.
6. Unseal the gas bag and attach its tubing to one of the gas ports on the upper surface of the leaf chamber. Unplug the other gas port. Press the bag gently so that your breath is flushed through the chamber. Observe the decline in the O₂ reading on the computer screen until this reaches a stable value. After approximately 30-45 seconds of flushing, remove the bag from the inlet port, seal the bag and seal both ports of the leaf chamber with the plugs provided.
7. Adjust the illumination of the leaf by sliding the dimmer control to an intensity equal to 5% of the maximum output and observer the changes in the O₂ concentration within the chamber. If the leaf has been maintained in near darkness (e.g. room light) prior to the experiment, there will be little change in the O₂ reading during the first 5-10 minutes of illumination. This corresponds to the "induction period" of photosynthesis during which photosynthetic metabolites are synthesized until they reach the critical pool sizes required for photosynthesis to occur. Once this had been achieved, the partial pressure of O₂ in the chamber will increase as O₂ is released in photosynthesis. After the photosynthetic induction period, the pO₂ in the chamber will rise slowly at first and then will increase linearly.
8. After observing the linear part of the rise for approx. 5 minutes switch off the light and flush the chamber with gas from your gas bag for at least 30 seconds. Reseal the chamber and the gas bag. DO NOT stop the program at any time during this experiment.
9. Switch on the light again, and increase its output to approximately 10% of the initial intensity. This can be achieved by observing the response of the light sensor display as the dimmer control is adjusted.
10. After switching on the light, photosynthesis should begin almost immediately, since the leaf is already photsynthetically induced. Measure the increase in pO₂ of the chamber for 5-10 min. and then repeat step 8.
11. Increase the output of the lamp to 20% of initial, and repeat steps 8 and 9 until you have measured photosynthetic rate at a number of light intensities equal to 5, 10, 20, 40, 60 and 80% of the initial light output.
12. If you are altering the wavelength (color) of light the leaf is receiving, start with full intensity white light for your initial measurement. Then alter the wavelength at maximum intensity by placing different colored filters over the leaf chamber (under the beaker of water). Allow each reading to proceed until a uniform rate is established, usually about 5 minutes. Then turn off the light, replenish the water in the beaker if necessary, and repeat steps 8 and 9 with each colored filter.
13. After you have made all your measurements, stop the experiment by clicking on the Stop button.
14. Save your data by selecting Save as . . in the File menu. Give your data an appropriate file name and save it to your data folder.
15. Remove the beaker of water, detach the leaf from the plant, and detach the leaf chamber from its mounting bracket with the leaf enclosed. Be careful not to touch any hot surface of the lamp or its fitting while doing this. Place the acetate grid on the surface of the chamber so that it covers the leaf. Count the number of interstices completely enclosed by the area of the leaf. Any interstices falling exactly on the leaf margin should be given a value of 0.5. Sum the results and divide the total by 4. The value you obtain is equal to the area of the leaf in cm².

Data Analysis

The O₂ sensor measures only the partial pressure of O₂ present in the leaf chamber; it does not measure the rate at which this O₂ is produced. To measure the rate of photosynthesis in your experiment, you will need to measure the increase in pO₂ within the leaf chamber as a function of time. This is achieved by measuring the rate of the O₂ response which, when the x axis of your graphs is presented in minutes, will give a rate in %O₂ per min. The procedure for analyzing your data is as follows:

1. Open the file containing data from one of your experiments. A command box will appear asking you whether or not you wish to load the calibration stored with your data file. Answer Yes. Your data will appear on the screen exactly as it appeared when you saved it at the end of the experiment.
2. Select Examine from the Analyze menu at the top of the screen. A vertical line will appear on your graphs which can be moved along the data points on the graphs by moving the mouse. Note that as you move the vertical line, the numerical display in the box on the screen will change to show you the exact O₂ concentration and time value at the point on the graph where the line is situated.
3. Measure photosynthetic rate during the linear part of the increase in chamber O₂ concentration. To do this, move the vertical line to the point on your O₂ data where you wish to start the measurement, click on the mouse button and hold it down. Move the mouse over the part of the data you wish to analyze, and then release the mouse button capturing the portion to be analyzed inside the box that appears.
4. Select Linear Fit from the Analyze menu. In the command box that is on the screen you will see the equation for a straight line, y= mx + b, along with the values for m and b. The value for m is the slope of the line, which is the rate of O₂ production. Record this in your data table. Close the box on the screen by clicking in the upper right hand corner.
5. Measure photosynthetic rate at the next light intensity by moving the vertical line to the linear part of the next set of data. Select the next area of data to be analyzed by clicking and dragging with the mouse. Again select Linear Fit from the Analyze menu. The equation screen will reflect the new m value for the range of data that you have selected. Record the new value for m in the Results section.
6. Repeat this procedure for all of the light intensities and wavelengths that you tested.

Calculations

Each m value from each regression that you performed represents the rate of increase of O₂ concentration in the chamber with time. As such, each of these m values are rates of photosynthesis expressed as %O₂ per min. However, photosynthesis is usually expressed in terms of µl O₂/ m²/sec. To make this conversion the following procedure is required:

Let us assume that the m value was x, i.e. the O₂ concentration of the chamber increased by x %O₂/min. x %O₂ is equivalent to 10,000x parts per million (ppm) O₂ which, in turn, is equivalent to 10,000x µl of O₂ per liter of gas in the chamber.

x %O₂/min = 10,000x µl O₂/min/liter of gas in the chamber

At STP 1 mmole of any gas occupies 22.413 ml, so at the temperature T of the laboratory, 10,000 x µl of O₂ contains:

µl O₂/min/liter /{ [(273+T)/273] X 22.413} = µmoles of O₂ /min/liter

To obtain the photosynthetic rate we must now multiply by the volume of the chamber expressed in liters. The chamber is designed so that when closed it has a fixed internal volume of 0.047 liters.

µmoles of O₂/min/liter X 0.047 liter = µmoles of O₂/min

However we would like to express the photosynthetic rate in µmoles O₂/m²/min. To do this we must perform the following calculations:

µmoles of O₂ /min ÷ area of leaf in m² = µmoles of O₂ /m²/min

In order to convert these units to µmoles of O₂ /m²/sec, the preferred units of photosynthetic rate used in the literature, divide by 60:

µmoles of O₂ /m²/min ÷ 60 sec/min = µmoles of O₂ /m²/sec

Results and Discussion

Photon Flux (µmol quanta/m2/s)	m %O2/min	Photosynthetic Rate (µmol O2 /m2/s)
5%
10%
20%
40%
60%
80%

When you have calculated rates of photosynthesis at each light intensity used in your experiment, present your data as a graph with photosynthetic rate (µmol O₂/m²/sec) plotted on the y axis and light intensity (µmol quanta/m²/s) on the x axis. This will produce a photosynthetic light response curve. The light intensity beyond which the light response curve plateaus is called the light saturation point of photosynthesis. At this point increases in light intensity do not cause increases in photosynthetic rate, so other factors apart from the supply of light must be limiting the photosynthetic process.

1) What might these factors be?

2) Did you measure the light saturation point in your experiment? If not, why do you think the light saturation point was not reached?

If the light saturation point was reached, do you think that CO₂ supply was the major factor limiting photosynthesis at this point? How would you test this? Remember that your breath contains approximately 100 times the concentration of CO₂ in the atmosphere.

Color of Filter	m % O2/min	Photosynthetic Rate (µmol O2 /m2/s)
White
Red
Blue
Green

1. How did photosynthetic rate differ in each light color? Relate your results to the absorption spectra of photosynthetic pigments.
2. What characteristics regarding the amount of light transmitted by the filters would be important in order to make valid comparisons of the effect of various wavelengths of light?