Please note, you must be an educator in higher ed or maybe high school to qualify to recieve the MCI
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|Oxygen has a tendency to form very reactive by-products (H2O2 and O2-(superoxide)) inside a cell. These by-products create havoc by reacting with protein and DNA, thus inactivating them. Cells that are able to live in the presence of oxygen have evolved enzymes to cope with H2O2 and O2- and thus are not inhibited by O2. Also many anaerobes have oxygen labile Fe-S centers and no cellular machinery to protect them from the oxidizing power of oxygen. Organisms that cannot deal with the problems presented by oxygen cannot survive in air and are killed.
On the basis of oxygen tolerance, microorganisms can be placed into four classes. Strict aerobes cannot survive in the absence of oxygen and produce energy only by oxidative phosphorylation. Strict anaerobes, in many cases, generate energy by fermentation or by anaerobic respiration and are killed in the presence of oxygen. Aerotolerant anaerobes generate ATP only by fermentation, but have mechanisms to protect themselves from oxygen. Facultative anaerobes prefer to grow in the presence of oxygen, using oxidative phosphorylation, but can grow in an anaerobic environment using fermentation.
Oxygen utilization is a primary diagnostic tool when identifying microorganisms. Special media has been developed for the purposes of determining the oxygen relationship and method of metabolism (fermentation vs. respiration) of microorganisms. One such medium, Thioglycollate Agar is useful for determining the oxygen relationship of a microorganism. The medium contains thioglycollic acid, cystine and 0.35% agar, among other things. The thioglycollic acid and agar prevent oxygen from entering the entire medium. A dye, resazurin, is used as an indicator of the amount of oxygen in the medium. Resazurin is red in the presence of oxygen and turns colorless under anaerobic conditions. The medium is steamed just before use, which removes all oxygen from the tubes. After inoculation and incubation, oxygen is able to diffuse into the top part of the medium and support growth aerobically, while the bottom half of the medium remains devoid of oxygen.
A second medium used to investigate the general type of metabolism used by a microorganism is glucose O/F medium. This is a rich medium that contains glucose as primary carbon source. A pH indicator dye, brom thymol blue, is added and is green/blue under alkaline-Oxidative conditions or yellow under acidic-Fermentative conditions. Each test organism is inoculated into two tubes of glucose O/F medium. One tube is overlaid with mineral oil and the other is not. The mineral oil serves as a barrier to oxygen, which helps to create an anaerobic environment.
In this experiment you will first investigate the reactions of several known microorganisms having different types of metabolism. You will determine the characteristic reactions of thioglycollate medium and glucose O/F medium. You will then use this information to determine the oxygen relationships and catabolism type of your two unknown isolates.
8 tubes of Glucose O/F Medium
4 tubes of sterile mineral oil
4 tubes of Thioglycollate Agar (melted, in 50 °C water bath)
Cultures of
Pseudomonas fluorescens
Clostridium sporogenes
Enterococcus faecalis
Escherichia coli
2 plates of Brain Heart Infusion Agar
Anaerobe jar
In this exercise we will be first testing the oxygen relationships of some known organisms in Glucose O/F medium and Thioglycollate Agar. This will give you a sense of inoculating test media and allow you to observe their characteristic reactions.
Figure 6.2. Uninoculated thioglycollate agar and Glucose O/F medium. Glucose O/F medium (left) is green and clear. Thioglycollate agar (right) is yellow and clear with no turbidity visible before inoculation with culture.
Figure 6.15 the catalase test
Figure 6.3. Reactions in thioglycollate agar. After preparation, Thioglycollate Agar will develop a stable oxygen gradient, with high concentrations of oxygen near the surface of the agar and no oxygen near the bottom. Microbes will display different growth patters depending upon their oxygen relationship. Strict aerobes will only grow near the surface of the agar (Af, Alcaligenes faecalis; Pf, Pseudomonas fluorescens). Aerotolerant anaerobes grow at the same rate in presence or absence of oxygen (Lp. Lactobacillus plantarum). Facultative anaerobes will grow throughout the tube, but will display more growth near the top of the tube (Se, Staphylococcus epidermidis; Ea, Enterobacter aerogenes). Strict aerobes will only grow in the presence of oxygen, at the top of the tube (Cb, Clostridium butryricum). Strict anaerobes will only grow in the bottom of the tube where oxygen is absent.
Figure 6.4. Reactions in Glucose O/F medium. Each organism is inoculated into two tubes of glucose O/F medium, one of which is covered with mineral oil to exclude oxygen. There are three types of reactions possible. Microbes that are incapable of utilizing glucose will have a alkaline reaction (blue color) at the top of the aerobic tube (the one not covered with mineral oil) and no reaction in the anaerobic tube (Af; Alcaligenes faecalis). Oxidative microbes, those only capable of respiration, will only grow significantly in the aerobic tube. Often there will be a small amount of acid produced, turning the top of the aerobic tube yellow (Pf; Pseudomonas fluorescens). Those capable of fermentative metabolism will grow in both tubes and turn the medium yellow due to the production of acid while growing anaerobically (Ea; Enterobacter aerogenes). The aerobic tube turns yellow for fermentative organisms because they use up any available oxygen and begin to ferment available glucose.
Figure 6.5. Growth of microbes on BHI plates. The left side plates were incubated anaerobically, while those on the right were incubated aerobically. Strict aerobes cannot grow in the absence of oxygen, while strict anaerobes cannot grow in the presence of oxygen. Note that Pf and Af grew slightly under anaerobic conditions due to residual oxygen present in the anaerobe jar. Cultures shown: Se, Staphylococcus epidermidis; Af, Alcaligenes faecalis; Cb, Clostridium butyricum; Lp, Lactobacillus plantarum; Ea, Enterobacter aerogenes; Pf, Pseudomonas fluorescens;