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ULTRAVIOLET/VISIBLE SPECTROSCOPY PURDUE UNIVERSITY INSTRUMENT VAN PROJECT ANALYSIS OF PLANT PIGMENTS USING PAPER CHROMATOGRAPHY AND VISIBLE AND/OR UV SPECTROSCOPY (1-31-96) INTRODUCTION We have seen that all cells must constantly consume fuel molecules to maintain themselves, grow, and reproduce. Fuel molecules such as glucose constitute an immediate source of energy for biological work that can be released by catabolic cell processes. However it is necessary that life on earth have a constant source of energy that can be harvested and used to generate complex fuel molecules from simple starting materials. The ultimate energy source upon which all life forms depend is visible light from the sun. Light energy must first be transformed into chemical(bond) energy before it can be utilized by the living cell. This transformation is achieved only in the cells of green plants and certain bacteria. In green plants it is coupled with a transformation of matter in which relatively low-energy compounds, carbon dioxide and water, are converted into high energy chemical molecules that become subunits of carbohydrates. There are four different pigment groups present in leaves of photosynthesizing plants. Studies indicate that only the chlorophyll IS involved in the actual absorption of light energy and later conversion to chemical energy of living cells. The other pigments also absorb light energy, but it is transferred to the chlorophyll for conversion to chemical energy. Biochemists have developed a variety of methods for the purification and analysis of biomolecules. Several of these techniques will be used in this laboratory exercise in order to isolate and study the photosynthetic pigments, chlorophyll a, chlorophyll b, and carotenoids. These include paper chromatography and spectrophotometry. Paper chromatography separates compounds on paper as solvent carries the mixture up (or down) the paper by capillary action. Compounds which are very soluble in the solvent move along with the advancing solvent front, while less soluble compounds travel slowly through the paper, well behind the solvent front. As a result, the different compounds are separated on the basis of their solubilities in the chosen solvent. Chlorophyll a is slightly soluble in a 3:1:1 mixture of petroleum ether, acetone, and water. Carotenoids are very soluble in this solvent system. These solubility differences will allow the separation of chlorophyll a from the carotenoids and chlorophyll b on a paper chromatogram. Having purified chlorophyll a, chlorophyll b, and the carotenoids, you will examine the light absorption characteristics of the molecules using a spectrophotometer, an instrument which

ULTRAVIOLET/VISIBLE SPECTROSCOPY PURDUE UNIVERSITY INSTRUMENT VAN PROJECT measures the absorption of light by a solution at any wavelength(s) selected by the experimenter. Light visible to the human eye occupies only a small portion of the electromagnetic spectrum, namely from about 350 to 750 nanometers, or from violet to red. The color of light is also related to the energy of the light as shown below. color: UV violet blue green yellow red IR 300 400 500 600 700 800 high energy light low energy light Spectrophotometers and related devices can "sense" not only visible light but other wavelengths such as ultraviolet as well. The instrument is set to read a certain wavelength and the instrument reports the amount of light absorbed by the solution at the set wavelength. Obviously by changing the wavelength setting over the entire range, we can obtain the visible or visibleultraviolet light absorption spectrum for any solution or compound. PURPOSE To separate pigments from leaves of a green plant using paper chromatography and to determine the wavelength at which energy is absorbed by the individual pigments using spectrophotometry. SAFETY Goggles and aprons to be worn Petroleum ether, acetone and alcohol are volatile and flammable Avoid breathing vapors of the reagents Handle microcuvets by grooved sides only PRE-LAB QUESTIONS 1. Why is energy required for life? 2. How does energy enter the living world? 3. Visible white light is composed of what? 2

ULTRAVIOLET/VISIBLE SPECTROSCOPY PURDUE UNIVERSITY INSTRUMENT VAN PROJECT

4. Which wavelength of visible light possesses the greatest energy value, and what is its color? 5. Which wavelength possesses the least energy value, and what is its color? 6. Which pigment(s), chlorophyll a, chlorophyll b, and/or carotenoids, will travel the farthest on the chromatography paper? 7. Which pigment(s) is least soluble in the solvent? 8. If the transmittance is 100% what would be the absorbance? 9. If the absorbance is 2 what would be the % transmittance? EQUIPMENT AND MATERIALS NEEDED 2 or 3 fresh spinach leaves wooden ruler 600 mL beaker plastic wrap chromatography paper or filter paper pencil copper penny coin 100 mL graduated cylinder 5 test tubes scissors stapler 3 spectrophotometer cuvets graph paper optical wipes isopropyl alcohol petroleum ether acetone distilled water visible spectrophotometer (400-900 nm) Optional: Beckmann DU64 spectrophotometer/4 microcuvets (polystyrene)

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ULTRAVIOLET/VISIBLE SPECTROSCOPY PURDUE UNIVERSITY INSTRUMENT VAN PROJECT PROCEDURE DAY ONE Work in teams of two for this activity Make sure work area is clean and dry. Preparation of the sample: Note: Since oils from skin affect the separation, it is desirable to handle paper as little as possible. 1. Cut a piece of Whatman #1 filter paper or chromatography paper to the dimensions of 12 cm X 14 cm. Edges must be straight. 2. With a pencil lightly make a line 1.5 - 2 cm from the bottom edge of the paper which measures 14 cm. 3. Select 2 large dark green spinach leaves and blot dry with paper towels. Place a leaf over the pencil line leaving 3 mm on each end to align the ruler. 4. Place the widest side of a wooden ruler (without metal edge) over the leaf so that it covers the pencil line on either end. 5. Using a penny coin, press down firmly and roll along the ruler edge several times to form a definite green line. 6. Allow the green line to dry 7. Move leaf down and repeat several times until the pencil line is covered completely with a narrow green band. Be careful not to smear this green line.

Separation of pigments: 1. Roll 12 cm edges together to form a cylinder with the green line on the outside - do not 4

ULTRAVIOLET/VISIBLE SPECTROSCOPY PURDUE UNIVERSITY INSTRUMENT VAN PROJECT overlap edges. 2. Staple top and bottom to form a cylinder. 3. Obtain 20 mL of the separation solvent and pour into a 600 mL beaker. 4. Place paper cylinder in beaker with the green band down. The solvent should not touch the green line. 5. Cover the beaker tightly with a piece of plastic wrap being careful not to slosh solvent. 6. Allow to stand undisturbed for 5 minutes. 7. After five minutes lift up corner of wrap and reseal. This will reduce the vapor pressure inside the beaker. 8. Observe the solvent movement and band separation. 9. When the solvent front is within 1 cm of the upper edge of the paper, remove the cylinder from the beaker. Mark the edge of the solvent front with a pencil. 10. Allow the cylinder to dry completely in a darkened area. 11. Discard the solvent from the 600 mL beaker into the waste container in the fume hood followed by three volumes of water. Extraction of pigments: 1. Open the dried cylinder by removing the staples. 2. Measure distance from the first pencil line to the solvent front. Then measure the distance from the pencil line to the highest point of each color band and the original pencil line band. Record your results. 3. Ideally there should be three distinct colored bands. Cut the bands apart carefully and trim off excess paper being careful not to cut colored band. 4. Cut each strip into pieces small enough to fit into a large test tube. Label each tube and 5

ULTRAVIOLET/VISIBLE SPECTROSCOPY PURDUE UNIVERSITY INSTRUMENT VAN PROJECT record the color and order of pigment. Place paper pieces in the appropriate test tubes. 5. Add 5 mL of isopropyl alcohol to each tube and seal with small piece of plastic wrap. Allow to stand until color is completely eluted from the paper. STOPPING POINT! 6. Calculate rf values for each pigment. The rf values should be written on the chalkboard. rf = DAY TWO UPON ENTERING LAB TURN THE POWER CONTROL KNOB ON THE SPECTROPHOTOMETER TO THE "ON" POSITION Preparation of samples for spectrophotometric analysis 1. Fill to 1/3 a spectrophotometer cuvet with isopropyl alcohol. Label "bl" using a marking pen. This is the blank used to standardize the spectrophotometer. 2. Transfer solution from test tube containing chlorophyll a pigment to a second spectrophotometer cuvet. Label "a". 3. Transfer solution from test tube containing chlorophyll b pigments to a third cuvet. Label "b". 4. Transfer solution from test tube containing carotene pigments to a fourth cuvet. Label "c". 5. Wipe sides of cuvet with Accuwipe and avoid touching surfaces with fingers. Be sure that the label does not interfere with the path of the light beam. Measuring absorbance of pigments 1. Turn wavelength control knob to 360 nm. If using Flinn spectrophotometer, turn dial on lower front of case to the blue filter. 2. With the sample chamber lid closed set the 0 % transmittance to 0. 3. Insert cuvet labeled "bl" into the sample chamber and close lid. Set the 100% transmittance to 100% and remove cuvet. distance color travels distance solvent front travels

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ULTRAVIOLET/VISIBLE SPECTROSCOPY PURDUE UNIVERSITY INSTRUMENT VAN PROJECT 4. Insert cuvet "a" into sample chamber, close lid and read the ABSORBANCE shown. Record results. Remove cuvet. 5. Insert cuvet "b" into sample chamber, close lid and read the ABSORBANCE shown. Record results. Remove cuvet. 6. Insert cuvet "c" into sample chamber, close lid and read the ABSORBANCE shown. Record results. Remove cuvet. 7. Turn wavelength control knob to 380 nm. 8. Continue to record results for wavelengths at 20 nm increments, remember to repeat steps #26 for each new wavelength. The final reading is 720 nm. If using the Flinn spectrophotometer, change to the yellow filter at 520 nm. Optional 1. If directed by teacher, obtain four polystyrene cuvets. Handle by grooved edge only. 2. Transfer samples from each of the cuvets into three microcuvets, filling each cuvet almost to the top. Transfer chlorophyll b sample to a fourth microcuvet. 3. Label each cuvet near the top with a marking pen. 4. Place all four microcuvets into the cell carrier of the Beckmann DU64 spectrophotometer. 5. Program the spectrophotometer according to the direction supplied with the instrument for a range of 720 nm to 360 nm and scan the absorbance for the four samples. 6. Remove samples and print out the data obtained. 7. Rinse microcuvets well with water and return to container.

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ULTRAVIOLET/VISIBLE SPECTROSCOPY PURDUE UNIVERSITY INSTRUMENT VAN PROJECT Data Table WAVELENGTH (nm) Chlorophyll a 360 380 400 420 440 460 480 500 520 540 560 580 600 620 640 660 680 700 720 8 ABSORBANCE Chlorophyll b Carotenoids

ULTRAVIOLET/VISIBLE SPECTROSCOPY PURDUE UNIVERSITY INSTRUMENT VAN PROJECT

DATA ANALYSIS Graph the results from the above data with ABSORBANCE on the Y-axis and WAVELENGTH (nm) on the X-axis. Use different symbols for the two pigments. Make sure the graph has a title and legends. CONCLUSIONS 1. At what wavelengths and colors did chlorophyll a absorb energy? 2. At what wavelengths and colors did carotenoids absorb energy? 3. At what wavelengths and colors did chlorophyll b absorb energy? 4. Why do green plants appear green? 5. Would you expect a plant to grow well in only green light? Explain. 6. In which colors of light would you expect a plant to obtain maximum photosynthetic activity? Explain. 7. What role do the carotenoids play in photosynthesis? 8. Why was isopropyl alcohol used to ZERO the spectrophotometer? (to get the 100 % T setting) 9. What is the significance of the rf values? FOLLOW-UP QUESTIONS 1. How do you think the results would differ if you had used spinach leaves which had been stored in a dark room for five days before the experiment? Explain your answer.

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ULTRAVIOLET/VISIBLE SPECTROSCOPY PURDUE UNIVERSITY INSTRUMENT VAN PROJECT

TEACHERS' GUIDE ANALYSIS OF PLANT PIGMENTS USING PAPER CHROMATOGRAPHY AND VISIBLE AND/OR UV SPECTROSCOPY (1-31-96) CLASSROOM USAGE First or second year high school biology First or second year chemistry Biochemistry Physical science Physics CONCEPT MAP Suggested terms: energy photosynthesis color carotenoids light chlorophyll separation absorption solubility transmission absorbance rf paper chromatography spectrophotometer CURRICULUM INTEGRATION Photosynthesis unit in biology Biochemistry unit in first or second year chemistry Solutions unit in first year chemistry Separation of mixtures in first year chemistry Light unit in physics or physical science Environmental science Ecology

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ULTRAVIOLET/VISIBLE SPECTROSCOPY PURDUE UNIVERSITY INSTRUMENT VAN PROJECT

INDIANA STATE SCIENCE PROFICIENCIES 1, 2, 3, 4, 5a, 5b, 5e, 5f, 6a, 6d, 8, 11 KEY UNDERSTANDINGS Use of paper chromatography Use of spectrophotometer Interpreting results of spectrophotometer Graphing skills Photosynthesis Light Absorbance/transmittance of color Practical applications of separation PREPARATION Teacher secure fresh, dark green spinach from local sources immediately before doing this activity and refrigerate until time of usage. Teacher may desire to prepare a sample graph to demonstrate form to be used and uniform scales on each axis. Teacher may desire to take a sample Beckmann DU64 printout of absorbance and interpret the graph SOLVENT PREPARATION 1. 180 mL petroleum ether, 60 mL acetone, 60 mL distilled water per class of 12 lab groups. 2. Isopropyl alcohol for extraction is used full strength and must be freshly opened. 3. Polystyrene microcuvets must be used in the UV/VIS spectrophotometer to avoid being clouded by solvent. TIME Teacher preparation: approximately 30 minutes to gather materials. 11

ULTRAVIOLET/VISIBLE SPECTROSCOPY PURDUE UNIVERSITY INSTRUMENT VAN PROJECT

Stopping points:

Day One devoted to chromatography - 45 minutes minimum Day Two devoted to spectrophotometry - 45 minutes minimum Doing the activity: approximately 20 minutes for pre-lab and 30 minutes for data analysis at the end in addition to the two days devoted to the laboratory activity. Student analysis may be done as homework assignment depending upon student abilities. SAFETY AND DISPOSAL No unusual safety or disposal problems. Goggles and aprons to be worn at all times. Petroleum ether, acetone and alcohol are volatile and flammable. Avoid breathing vapors of the reagents Handle microcuvets by grooved sides only Make sure solvents are disposed of in a labeled waste container in the fume hood. VARIATIONS/EXTENSIONS Day One chromatography activity could be done as complete activity. Additional plant pigments from leaves or colored petals could be investigated. ASSESSMENT Behavioral check list accuracy of recording data, competency in use of instrument preparation of solutions ability to follow written procedures Accuracy in presentation of data and format of graphing Portfolio Data interpretation Narrative questions V-diagrams Concept maps

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ULTRAVIOLET/VISIBLE SPECTROSCOPY PURDUE UNIVERSITY INSTRUMENT VAN PROJECT

REFERENCES Bowen, W. R. and Baxter, W. D., Experimental Cell Biology, An Integrated Laboratory Guide and Text, Macmillan Publishing Co, Inc.,New York, 1980. Van Bell, Craig, et al, Principles of Biology Laboratory Manual, Morehead State University, Morehead, Ky. LAB WRITTEN BY: Dee Ann Kalb and G. W. Howard

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Biology Introduction

...including their structure, function, growth, evolution, distribution, and taxonomy.[1] Modern biology is a vast and eclectic field, composed of manybranches and subdisciplines. However, despite the broad scope of biology, there are certain general and unifying concepts within it that govern all study and research, consolidating it into single, coherent fields. In general, biology recognizes the cell as the basic unit of life, genes as the basic unit of heredity, and evolution as the engine that propels the synthesis and creation of new species. It is also understood today that all organisms survive by consuming and transforming energy and by regulating their internal environment to maintain a stable and vital condition. Subdisciplines of biology are defined by the scale at which organisms are studied, the kinds of organisms studied, and the methods used to study them: biochemistry examines the rudimentary chemistry of life; molecular biologystudies the complex interactions among biological molecules; botany studies the biology of plants; cellular biologyexamines the basic building-block of all life, the cell; physiology examines the physical and chemical functions oftissues, organs, and organ systems of an organism; evolutionary biology examines the processes that produced the diversity of life; and ecology examines how organisms interact in their environment.[2] HistoryThe term biology is derived from the Greek word βίος, bios, "life" and the suffix -λογία, -logia, "study of."[3][4] The...

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