yeast population dynamics

Procedure

1. Work in pairs on this lab, so 12 tubes per pair of students. And share a tube rack with one other pair of students

2. Turn on your spectrophotometer. It needs at least 15 minutes to warm up to give you good readings.

3. Add 5 mL of yeast extract solution (YECM) to each of 12 tubes. (The yeast extract provides vitamins and amino acids for yeast growth and will be the same for all cultures). The tubes should be labeled with your initials, treatment, and tube number. Tape or Parafilm down the lids of 3 tubes, and label them “CONTROL”.

Do not touch the insides of the tubes or lids! Try to keep these as sterile as possible!!

4. Add 50 mL live yeast culture to each of the remaining 9 tubes.

5. Add the varying volumes of sugar and/or ethanol using Table 1 below.

6. Use Parafilm to close the tops of each tube, making sure the Parafilm is tight and no air can get in, and label each tube with the following:

Amount of sugar added (mL) Amount of ethanol added (mL)

Name of your group Tube number

Table 1: setup yeast tubes (remember, 1 mL = 1000 mL)
Tube number	Yeast culture medium? (5 mL)	Live yeast culture? (50 mL)	Sugar added (mL)	Ethanol added (mL)
1 – control	YES	NO	0	0
2 – control	YES	NO	0	0
3 - control	YES	NO	0	0
4	YES	YES	0	0
5	YES	YES	0.25	0
6	YES	YES	0.5	0
7	YES	YES	0	0.25
8	YES	YES	0.25	0.25
9	YES	YES	0.5	0.25
10	YES	YES	0	0.5
11	YES	YES	0.25	0.5
12	YES	YES	0.5	0.5

Procedure for measuring absorbance (in absorbance units, or AU)

7. Calibrate the spectrophotometer:

Turn on the spectrophotometer and let it warm up for 15 minutes. You will get erroneous results if you don’t let it warm up first.

Be sure the spectrophotometer is set to read at the wavelength of 550 nm

With no tube in the spectrophotometer and the lid closed, use the left-hand knob to adjust the reading to 0% Transmittance/push zero button to calibrate

Insert a CONTROL tube (making sure it is clear, without bacterial contamination which would make it cloudy), and use the right-hand knob to readjust the spectrophotometer to 100% Transmittance.

When reading the absorbance, be sure to line up the needle on the spec with its reflection.

8. Immediately before reading any tube, vortex the tube so that the spinning column reaches the bottom of the tube for several seconds. This is critical! The yeast cells are heavy and will tend to sink to the bottom of the tube, so you must vortex the tubes to resuspend them: otherwise, your spectrophotometer readings will be erroneously low. If the vortex is not enough to suspend the pellet of yeast cells at the base of the tube, take a piece of Parafilm and cover the top of the tube, then cover this with your thumb and shake the tube vigorously. The pellet should dislodge and the yeast cells should be easily resuspended after doing this. Use a Kimwipe to wipe down the outside of each tube, to remove fingerprints and other smudges that could affect the absorbance reading. (COULD BE A POTENTIAL ERROR)

9. Record the absorbance (in absorbance units, AU) for the tube on your data sheet.

10. Repeat steps 5 and 6 for every tube.

11. Leave the spectrophotometer turned on for the next user.

Figures you should include are:

Average absorbance vs. time for the no ethanol (0 mL) treatment

Average absorbance vs. time for the 0.25 mL ethanol treatment

Average absorbance vs. time for the 0.50 mL ethanol treatment

Sugar added vs. average carrying capacity (K). Use different symbols to denote each of the three alcohol concentrations

A. After a limit, the increasing concentration of sugar decreases the carrying capacity and growth rate. This is because at higher sugar concentrations, the medium becomes hypertonic and the yeast cells loss water towards the medium.With increasing concentration of the ethanol, the carrying capacity and the growth rate decreases. Why does this happen?

B. Is there any interaction between the effects of adding sugar and alcohol on yeast?

C. why do some cultures not reach K?

D. What are the potential sources of error and assumptions made in this experiment?

E. What do these results mean in a more general (non-yeast) context?

Experiment 1 Fermentation by Yeast Experiment Inventory Labware (4) 250 mL Beakers (1) 100 mL Graduated Cylinder (1) Test Tube Rack (5) Fermentation Tubes = (10) Test Tubes (5 plastic and 5 glass; see Figure 4) (1) Measuring Spoon (4) Pipettes (1) Ruler Note: You must provide the materials listed in *red. EXPERIMENT 1: FERMENTATION BY YEAST Yeast cells produce ethanol, C2 H6 O, and carbon dioxide, CO2 , during alcoholic fermentation. In this experiment, you will measure the production of CO2 to determine the rate of fermentation in the presence of different carbohydrates with fermentation tubes. Note: Regular table sugar is sucrose, a disaccharide, which is made up of glucose and fructose. Glucose is a monosaccharide. Figure 4: Fermentation tubes. Note how the smaller, plastic test tube is inverted into the larger glass tube. You will create five fermentation tubes in this experiment. PROCEDURE 1. In this experiment, you will mix yeast with sugar, Equal®, and Splenda®. Before you begin, develop a hypothesis predicting what will happen when the sugar/sweeteners are mixed with yeast. Will fermentation occur? Why or why not? Record your hypothesis in the post-lab questions. 2. Use the permanent marker to label three 250 mL beakers as Equal®, Splenda®, and Sugar. 3. Empty the Equal®, Splenda®, and Sugar packets into the corresponding beakers. 4. Fill the Equal® and Splenda® beakers to the 100 mL mark with warm tap water. 5. Fill the Sugar beaker to the 200 mL mark with warm tap water. 6. Mix each beaker thoroughly by pipetting the solution up and down several times. Use a new pipette to mix each solution. Each beaker now contains a 1% solution. Set these aside for later use. 7. Completely fill one of the smaller plastic tubes with tap water and invert the larger glass tube over it. Push the small tube up into the larger tube until the top connects with the bottom of the inverted tube. Invert the fermentation tube (Figure 4) so that the larger tube is upright (there should be a small bubble at the top of the internal tube). Note: Repeat Step 7 several times as practice. Strive for the smallest bubble possible. When you feel comfortable with this technique, empty the test tube(s) and proceed to Step 8. CAUTION: Do not try to force the plastic test tube into the glass test tube. This might cause your glass test tube to break, causing you injury. If your plastic test tubes do not fit easily, please call eScience Labs for replacement glass tubes. If you are able to set up at least two fermentation tubes, continue with the experiment, but know that you will have to perform steps 12-15 in multiple steps. 8. Use the permanent marker to label the fourth 250 mL beaker as Yeast. 9. Fill this beaker with 175 mL of warm tap water. It should be between 30 and 40o C (warm to the touch). 10.Open the yeast package, and use the measuring spoon to measure and pour 1 tsp. yeast into the beaker. Pipette the solution up and down until all of the yeast is mixed homogenously into the solution. Note: Make sure the yeast solution remains homogenous before each test tube is filled in the proceeding steps. The yeast density is fairly high, and the yeast may settle to the bottom of the beaker if it rests for an extended period of time. 11. Use the permanent marker to label the big glass and small plastic test tubes as 1, 2, 3, 4, and 5. 12.Use the 100 mL graduated cylinder to measure and pour 15 mL of the following solutions into the corresponding small plastic test tubes: Tube 1: 1% Glucose Solution Tube 2: 1% Sucrose Solution Tube 3: 1% Equal® Solution Tube 4: 1% Splenda® Solution Tube 5: 1% Sugar Solution Note: Thoroughly rinse the graduated cylinder between each measurement. 13.Fill the remaining volume in each small tube to the top with the yeast solution. 14.Slide the corresponding larger tube over the small tube and invert it as practiced in Step 7. This will mix the yeast and sugar/sweetener solutions. 15.Place the fermentation tubes in the test tube rack, and use a ruler to measure (in millimeters) the initial air space in the rounded bottom of the internal tube. Record these values in the Table 1. 16.Allow the test tubes to sit in a warm place (approximately 30 °C) for two hours. Placement suggestions include: a sunny window sill, atop (not in!) a warm oven heated to approximately 85 °C (185 °F on an oven setting), or under a very bright (warm) light. 17.At the end of the fermentation period, use your ruler to measure (in millimeters) the final gas height (total air space) in each tube. Record this data in Table 1. 18.Calculate the difference between the initial and final gas height in each tube. Record this data in Table 1.

EXPERIMENT 1: FERMENTATION BY YEAST

Result Tables

Table 1: Yeast Fermentation Data

Post-Lab Questions

Include your hypothesis from Step 1 here. Be sure to include at least one piece of scientific reasoning in your hypothesis to support your predictions.

Did you notice a difference in the rate of respiration between the various sugars? Did the artificial sugar provide a good starting material for fermentation?

Was anaerobic fermentation occurring? How do you know (use scientific reasoning)?

If you observed respiration, identify the gas that was produced. Suggest two methods you could use for positively identifying this gas.

Hypothesize why some of the sugar or sweetener solutions were not metabolized, while others were. Research the chemical formula of Equal^® and Splenda^® and explain how it would affect yeast respiration.

How do the results of this experiment relate to the role yeast plays in baking?

What would you expect to see if the yeast cell metabolism slowed down? How could this be done?

Indicate sources of error and suggest improvement (for example, what types of controls could be added?).