Please note, you must be an educator in higher ed or maybe high school to qualify to recieve the MCI
The growth of any microorganism, whether in its natural niche or in a laboratory, is dependent upon the presence of certain essential compounds in its environment. In the lab all these components must be provided for in the culture medium for the organisms to grow. The potential composition of media is as diverse as the number of microorganisms under study. This section discusses the basic requirements for all organisms and the components of culture media. If you want to know more about microbial requirements for growth, read the chapter on bacterial nutrition in your microbiology textbook
A fundamental and often ignored ingredient in all growth media is water. Water is an amazing compound. It is the only natural substance found in all three states; liquid, solid and gas at temperatures commonly found on earth. Water has a high specific heat index and can hold a large amount of heat. Water is the universal solvent, dissolving many more substances than any other liquid. All biological reactions take place in water. Its unique properties allowed the development of life on this planet. When humans discover life on other planets, life forms will likely be water-based. Besides being the solvent of choice, water can also donate H or O to certain reactions, but this contribution is minimal. In the preparation of most culture media, the first ingredient added is water.
The second most important ingredient added to media is the carbon source. For many of the media we will use in this course, an organic compound, such as glucose, will serve as the carbon source. However, this is not always the case. Autotrophs will utilize CO2 for cell carbon and the medium used for the growth of some autotrophs consists of just a few salts. In many cases the carbon source will also serve as the source of energy. E. coli, growing in a minimal glucose medium utilizes the glucose both as carbon and energy source. In other cases, another source will be used to generate energy, including inorganic compounds and light.
Carbon is not the only element needed in relatively large amounts by microorganisms. Hydrogen, oxygen, nitrogen, phosphorous, sulfur, and potassium are usually provided in a culture medium. Some microbes can assimilate these elements in their most simple form (i.e. O2, H2,or N2), while in other cases they have to be provided as a part of a larger molecule (KNO3, amino acids, MgSO4). Other elements that are also essential, but are not added in as large a quantity include, magnesium, iron, calcium, and potassium. Whatever the source, all these elements must be provided to support growth.
Since the list of growth requirements is quite extensive, providing all of them to a microorganism in a culture medium would seem complicated. In practice, most media is easy to make, but some formulations can be tremendously difficult. The ingredients added to culture media can range from pure chemical compounds to extracts and digests of plant or animal tissues. If all the components of a medium are known both qualitatively and quantitatively, it is referred to as chemically defined medium. This type of medium is often used to study the nutritional requirements of an organism or is necessary when elucidating various metabolic processes. Complex medium contains components that are extracts or digests whose exact chemical composition is impossible to determine and often varies from lot to lot. Therefore the exact amount of ingredients in complex medium is generally unknown. Common extracts and digests used in the preparation of microbial medium include; brain heart infusion (boiled, concentrated cow brains and hearts), yeast extract (killed and purified, dehydrated yeast) and various peptones (a digest of certain plant and animal proteins). These complex materials can provide carbon and energy sources, all necessary minerals, and growth factors (known and unknown) to an organism. Complex medium is often used in diagnostic tests, since they often provide all necessary components for growth of many different microorganisms.
Media used in the cultivation of microorganisms can also be classified according to the way in which it is used.
If a solid medium is necessary, agar is usually added as the solidifying agent. For plates or slants, a 1.5% concentration of agar is typical. For semi-solid medium < 0.5% agar is employed. Agar is a complex, long chain polysaccharide derived from certain marine algae and has several useful properties. When added to a solution, it melts at 100 °C forming a slightly viscous liquid that solidifies at ~43 °C. After solidification, the agar will not melt unless the temperature is again raised to 100 °C. This is a tremendously useful property as you will discover later in the semester. Some other useful properties of agar include its resistance to microbial degradation and its translucence for easy viewing of colonies embedded in the agar. One important disadvantage of agar is its tendency to harbor impurities, which are virtually impossible to completely extract. With certain organisms, these impurities can sometimes interfere with nutritional studies, and even inhibit growth. Chemically defined medium that contains agar must technically be considered complex. If agar presents a problem in certain studies, silica based solidifying agents are usually used as a substitute.
We owe the adoption of agar as a solidifying agent in microbiology to Fanny Eilshemius Hesse. Robert Koch and her husband Walter Hesse were searching for a method of culturing microorganisms on solid surfaces. Walter had tried using potato slices and solidified gelatin, both with unsatisfactory results. In 1881, Fanny suggested he try agar (a thickener she often used in cooking). With this new solid medium, Walter was able to develop pure culture techniques and discover the causes of many diseases, including tuberculosis.
In almost all cases, once a medium is made, it must be treated to eliminate any microorganisms contaminating containers, media ingredients, weighing papers, or other surfaces that come in contact with the medium. If this is not performed correctly, contaminates arise during incubation, making microbiological investigations impossible. Sterilization is defined as the inactivation (or removal) of all life forms (including the pseudo-life forms, viruses) in a specific area. Culture media must be made sterile without inactivating nutrients necessary for growth of the microorganism. Equipment and media used in the microbiology laboratory are most often sterilized using one of the methods listed in Figure 5-14.
Figure 5.14. Sterilization of media. Some common methods for the sterilization of media and instruments. The methods used depends upon the material and its intended use.
13 tubes of Nutrient Broth
2 250 ml flasks
1 graduated cylinder (100 ml)
magnetic stirrer and stir bar
scales and weighing paper
8 empty sterile Petri plates
1 tube of 50% glucose (2 ml)
1 bottle of 3% Agar + MgSO4 (50 ml, melted in 50 °C water bath)
Media ingredients (as listed below)
Minimal Medium - Part A | g/L | Nutrient Agar | g/L | |
---|---|---|---|---|
Ammonium Sulfate | 7.0 | Beef Extract | 5.0 | |
Dipotassium Phosphate | 7.0 | Peptone | 3.0 | |
Monopotassium Phosphate | 3.0 | Agar | 15.0 |
Minimal Medium -Part B | g/100 ml |
---|---|
Agar | 3.0 |
Magnesium Sulfate | 0.02 |
Minimal Medium Part C | g/100 ml |
---|---|
Glucose | 50 |
To become familiar with what goes into mixing up a batch of medium, 4 plates of a minimal medium and 4 plates of a complex medium will be prepared.
2 plates of Minimal Medium (MM)*
2 plates of Nutrient Agar (NA)*
Cultures for streaking
Figure 5.1. A picture of plates prepared plates. The appearance of plates after they are made. The minimal medium is colorless (left), while the nutrient agar is tan (right).
*Prepared last period by students
Media Making
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 5.15 the catalase test
Figure 5.3. Motility of a gliding bacteria. The gliding motion of a Paenibacillus species on a solid surface. Note the gliding motion of the cells across the screen.
Streptomyces are gram positive, spore-forming bacteria found in soil. They are characterized by their tough, leathery, frequently pigmented colonies and their filamentous growth. When first discovered, these organisms were thought to be fungi, but closer examination revealed a lack of a nuclear membrane and the presence of peptidoglycan, demonstrating their prokaryotic origin. Streptomyces are chemoheteroorganotrophs, growing best at 25°C and pH 8-9. They are capable of using complex organic materials as carbon and energy sources and are involved in the breakdown of these products in the soil. This degradative ability makes these bacteria pivotal in the production of fertile soil for agriculture. They also give soil its characteristic smell by the production of a class of volatile low molecular weight compounds called geosmins.
In the laboratory, different isolates were found to produce numerous compounds capable of inhibiting or killing other microorganisms. Many of these Figure 10-3 shows some examples of streptomycetes
Figure 10.3. An example of streptomycetes. A photomicrograph of Streptomyces vegetative cells and spores.
In this section, we describe the enrichment of this group of organisms and test several isolates for their antibiotic producing ability. Dried soil, a great source of inoculum for Streptomyces, will be plated directly onto Actinomycete Isolation Agar (AIA). Since an enrichment step is not necessary, what does that tell you about the population of Streptomyces in the soil? AIA contains starch and sodium caseinate as sole carbon and energy sources. Only organisms capable of degrading these complex polymers (mostly molds and streptomycetes) are able to grow. Sodium propionate (a preservative sometimes present in commercial bread) is added to inhibit the growth of molds. Incubation at 30°C for more than five days results in the formation of Streptomyces colonies that are recognized by their characteristic appearance.
Soil sample
3 0.85% NaCl dilution blanks (9 ml)
3 plates Actinomycete Isolation Agar (AIA)
Below is shown the appearance of a Streptomyces isolation plate after 5 days of incubation
5 AIA plates
Figure 10.4. AIA after incubation. This AIA plate was inoculated with soil from near Hayward Wisconsin. The plate was incubated at 30°C for one week. Streptomyces species are the white and colorful chalky looking colonies.
Figure 10.5. A closeup of a typical streptomyces colony. Note the colorful chalky/dusty appearance. The colony is hard, not gummy, and does not easily lift from the agar.
Figure 10.6. A wet mount of a Streptomyces colony. A Streptomyces colony under the phase microscope. Notice the long branched hyphae in the picture. This picture was taken at 1000x and enlarged 2 fold.
6 plates of Penassay Agar
Culture of Streptomyces griseus, an active antibiotic producer
Figure 10.7. Streaking pattern for the antibiotic test. Diagram of the appropriate streaking technique for the Penassay plates. (A) The placement of the Streptomyces colonies. (B) The placement of the test cultures. Note that there is a 5-7 day incubation between streak A and streak B.
Figure 10.8. Streaks for isolated colonies on penassay agar. The appearance of penassay agar after streaking for isolated colonies of Actinomycetes.
Broth cultures of 5 test organisms
Figure 10.9. An appropriately grown test plate. Example plates after growth of the Streptomyces test strains. Note the full growth completely along the streak line. There is a minor contaminant in the left sample, but it should not interfere with analysis.
Figure 10.10. Antimicrobial production by isolates. Examples of microbes that have been isolated and their inhibition of test microbes. Isolate 3 is secreting a brown metabolite into the medium. Isolate 4 is secreting an antimicrobial into the medium that is inhibiting S. epidermidis, E. faecalis, and B. subtilis. Ec - E. coli, Pf - P. flourescens, Bs - B. subtilis, Se - S. epidermidis, and Ef - E. faecalis.
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Motility in bacteria is achieved by any of several mechanisms. The most widespread mechanism is flagellar movement which allows travel in a liquid medium and is mediated by special threadlike organelles extending from the cell surface called flagella. Most rods and spirilla are motile by means of flagella; cocci are usually non-motile. A somewhat modified version of the bacterial flagellum is responsible for the movement of the bacteria known as spirochetes. These organisms possess an axial filament, consisting of two sets of flagella-like fibrils anchored at the two poles of the cell. Another type of movement observed for bacteria is known as gliding motility. It is the sole method of move-ment for certain of the cyanobacteria and myxobacteria. These organisms can move slowly over solid surfaces. Motility seen for any organism in this course will be due to flagella, the main focus of this experiment.
Virtually all bacteria which possess flagella are motile. Flagellation is a genetically-stable morphological trait of these cells. Certain environmental and nutritional conditions favor flagellar movement which can cease with increasing age (of the culture), temperature and concentration of waste products. Thus, optimal conditions for growth of the organism should be provided when one wishes to detect motility. The presence of flagella, as well as their number and distribution on the cell, are important characteristics for purposes of identification and classification of bacteria. When one or more flagella arise only from one or both ends of a rod or spiral-shaped cell, the arrangement is termed polar. When flagella arise randomly over the entire surface of the cell, the arrangement is termed peritrichous.
Motility is important in that an organism can swim toward optimal concentrations of nutrients and away from toxic substances. As an organism moves (runs), stops (twiddles), moves off in another direction, stops, etc. - in what superficially looks like a random fashion - one finds that the longest runs are in the direction toward the nutrient or away from the toxic substance. This type of purposeful movement is called chemotaxis. Other forms of tactic response include phototaxis (movement toward optimal light concentration or wavelength) and magnetotaxis (orientation and movement along lines of magnetic force). For more information of motility, see the chapter in the microtextbook on surface structures
Unlike flagella of eucaryotic cells (protozoa, algae, etc.), bacterial flagella are beyond the resolving capability of our lab microscopes. Flagella stains have been developed which coat the flagella to make them visible with the microscope and much practice is necessary to get consistently good results. Were we to have access to an electron microscope, we would be able to see the flagella (if present) and their arrangement for the organisms in this and other experiments in this course.
In our lab, determining the presence or absence of flagella is done by indirect methods, as we detect whether or not motility is evident under growth conditions made as favorable as possible for the organisms. With the wet mount, an actively-growing, young culture is required for observation. Motile organisms are usually easily seen as they move among each other in separate directions. One must, of course, discount Brownian motion, the movement due to bombardment of submicrosopic particles in the liquid, where the cells (alive or dead) appear to remain in one position but shake somewhat. One must also not confuse true motility with movement in a current of liquid where all cells (again, alive or dead) appear to be swept in one direction. We will also utilize tubes of Motility Medium wherein only motile bacteria can move away from the line of inoculation in the low (0.5% or less) concentration of agar; descendants of cells which have migrated throughout the medium show up as evidenced by turbidity (cloudiness) in the medium. One advantage of using Motility Medium is that a culture of any age can be used for inoculation - as long as it is pure and viable! In observing the tubes, one must always ignore growth at the surface of the medium and also between the medium and the wall of the tube. Such growth is not necessarily evidence of actual motility. Certain motile organisms, such as many which are strict aerobes, may grow with difficulty in the depths of the medium and ultimately give a false-negative reaction. Generally, one seeks to confirm microscopically any negative reaction seen in the tube.
Growth in the bacterial context is normally described as an increase in cell number. Microorganisms, depending upon the specific species, increase their numbers by binary fission, budding or by filamentous growth. Binary fission is the separation of the initial cell, the mother cell, into two daughter cells of approximately equal size. This is a very common method of multiplication and most of the organisms we will investigate divide in this manner.
Figure 5.8. The various forms of division. Cells can increase in number by binary fission, budding or filamentous growth. This animation demonstrates each of these processes.
Budding division involves the asymmetric creation of a growing bud, on the mother cell. The bud increases in size and eventually is severed from the parental cell. After division is complete, the mother cell reinitiates the process by growing another bud. Yeast and some bacteria (Caulobacter is one example) use this form of division.
Figure 5.9. Budding cells. A picture of Histoplasma capsulatum var. duboisii cells, a yeast that causes histoplasmosis, in the process of budding. Picture courtesy of Dr. Libero Ajello and the Centers for Disease Control and Prevention.
Filamentous growth is characterized by the formation of long, branching, non-divided filaments, containing multiple chromosomes. Sometimes the filaments will have cross walls separating chromosomes. As growth proceeds, the filaments increase in length and number. Under nutrient limiting conditions, some filamentous microorganisms will go through developmental changes, with a fraction of the filaments differentiating to form spores. The structures and mechanisms used to form these spores can be spectacular. Streptomyces species and many molds grow in this manner.
Figure 5.10. Filamentous growth. The bacteria Nocardia asteroides. Note the long branching cells and the circular spores in the picture.
The best characterized type of growth is binary fission and this is what we will focus on in this experiment. When grown in liquid medium, bacterial cultures progress through several distinguishable phases, which can be characterized by plotting the log of the cell number vs. time. Figure 5-12 shows an example of a typical growth curve with the 4 phases of growth, lag phase, exponential growth phase (also termed balanced growth), stationary phase and death phase.
Figure 5.11. Binary fission. As a cell divides by binary fission, a cross-wall is formed to separate the daughter cells. In this EM of Staphylococcus aureus, the cross-wall is already formed to divide the cells.
Figure 5.12. A bacterial growth curve. A bacterial growth curve generated from actual data obtained in the teaching laboratories at the University of Wisconsin-Madison. The four phases of growth (lag (1), exponential (2), stationary (3) and death phase(4)) are labeled.
When an organism is inoculated into a fresh medium, it needs to adapt to the new nutrients available, synthesize RNA, protein and finally replicate its DNA before starting division. These processes take time and there is no net increase in cell numbers, thus a lag phase is observed.
In the subsequent discussion, the numbers refer to the figure above. Once the appropriate enzymes for growth in a particular medium have been expressed cells begin to multiply. This period of maximal division can last for several hours or days, depending upon the organism, and is called the log or exponential growth phase (2).
Eventually the increase in cell number ceases, either because cells stop dividing or the rate of division equals the rate of cell death, resulting in a stationary phase (3). This is usually caused by limitation of a nutrient or the accumulation of a toxic waste product. Depending on the bacterium, stationary phase can last for several hours to many days.
The final chapter of a growth curve is the death phase (4). An exponential decrease in the number of organisms due to cell death occurs during this phase. Some microorganisms never experience a death phase or it is greatly delayed due to their ability to survive for long periods without nutrients.
Growth of microorganisms can be measured by following the increase in cell number or the increase in a cellular macromolecule such as DNA or protein. In most cases, the increase in cell number is determined. Cell numbers can be measured in a variety of ways. For this experiment we will use the viable plate count, which you are familiar with, and turbidometric measurement, which is was explained in the chapter on quantification of microorganisms.
So which wavelength of light do we use to measure cell numbers? Typically the shorter the wavelength the greater the sensitivity of the measurement. Some wavelengths cannot be used, however, because cellular constituents absorb light, not scatter them. For example proteins absorb light at 280 nm. Likewise the color of the medium affects absorbance. For this experiment we will be measuring the growth of E. coli in either a yellow or a clear medium, 600 nm works well. Beware, however, that the choice of wavelength must be considered for each experimental condition.
The sample is placed in a sample chamber. The chamber will contain a holder, an entrance for the selected wavelength, and an exit, leading to the detector. A critical piece of equipment used in the sample chamber is the cuvette. A cuvette is a special test tube that holds the sample. Cuvettes must be clean and free of aberrations, both of which could scatter light, resulting in inaccurate readings. Most good cuvettes are expensive and must be treated with care!
The actual operation of a spectrophotometer is much simpler than understanding its parts. There are a few general, rules of thumb, when using any spectrophotometer.
In this experiment, the classic bacterial growth curve will be demonstrated. A culture of Escherichia coli will be sampled at hourly or half-hourly intervals from the time of inoculation of the culture (0-time) through a 7 to 9-hour incubation period. The periodic samplings will be plated to determine viable counts (as colony-forming units per ml of culture) over the incubation period such that a growth curve may be plotted. From the graph, we may note the stages in the growth of the culture as it grows into the stationary phase. Additionally we will be able to determine the growth rate and generation time of E. coli under our experimental conditions from two points in the exponential phase of the graph.
Figure 5.16. Bacterial Growth. Graphing of bacterial growth on a linear scale
By definition, bacterial growth is cell replication - i.e., growth of the culture. Most species of bacteria replicate by binary fission, where one cell divides into 2 cells, the 2 cells into 4, the 4 into 8, etc. If this cell division occurs at a steady rate - such as when the cells have adequate nutrients and compatible growing conditions - we can plot numbers of cells vs. time such as on the graph at right. Before too long, we will need to extend the paper vertically as the population continues to double. For a culture where cells divide every 20 minutes, one cell can result in 16,777,216 (i.e., 224) cells after just 8 hours - barring nutrient depletion or other growth-altering conditions.
Figure 5.17. Bacterial Growth. Graphing of bacterial growth with cell number on a log scale.
If we were to convert our vertical axis to a logarithmic scale - as on the graph at right - we will not need as many sheets of graph paper, and we will find that a steady rate of growth is reflected as a straight line. (On the vertical axis, the same distance on the paper is covered with each doubling.) This type of graph paper is called semilogarithmic graph paper on which we will be plotting our class results. The numbers we plot will fall on the graph at the same place the logarithms of these numbers would fall when plotted on conventional graph paper.
The example below shows the type of graph we may obtain from our class data. We can plot both colony-forming units (CFUs) per ml and absorbance on the same graph, remembering that the absorbance units should also be on a logarithmic scale. Rather than "connecting the dots," we draw the best straight line among our CFU/ml plots to represent the phases of growth - lag, exponential, and the start of the maximum stationary phase.
Figure 5.18. Two measurements of growth. Example data showing a plot of cell number by VPC and by turbidity.
For the growth rate formula we are about to use, we need to choose two points on the straight line drawn through the exponential phase, also making note of the time interval between them. As we will be converting our numbers to logarithms for the formula, why not choose two points for which the logs are easy to obtain? (For example, the log of 1X1010 is simply 10.)
Higher CFU/ml = Xt = 1X1010 (at 5.75 hours)
Lower CFU/ml = X0 = 1X108 (at 2.75 hours)
Time interval (in hours) between the 2 points = t = 3
Using the first formula, we find the growth rate which is the number of generations (doublings) per hour:
Figure 5.19. Caluclating the growth rate. Use this formula to determine the growth rate k
With the second formula, we find the generation time which is the time it takes for the population to double:
Figure 5.20. Generation time. The generation time is the reciprocal of the growth rate.
With a clear graph, one should be able to determine the generation time without the use of formulas. Just look for a doubling of the population and the time it takes for that to happen. For example - in the above graph - the time it takes to go from 3 X 109 to 6 X 109 appears to be approximately 30 minutes, which is close to the generation time determined above.
In preparation for this exercise, be sure to read the relevant material in your textbook, and look over the procedure below.
Precautions regarding observance of aseptic technique:
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Period 1
Materials
Samples (5-6 ml) which were taken at hourly or half-hourly intervals from a culture of E. coli growing in Nutrient Broth+0.2% yeast extract, incubated at 37°C on a shaker. These samples have been kept on ice for use in this experiment, and each pair will use one sample.
The following are provided for each pair of students:
7-9 nine ml dilution blanks
8 tubes of melted Plate Count Agar (PCA) in test tubes (15-20 ml/tube) - in 50°C water bath
8 empty, sterile petri dishes
Pipettors (P1000) and sterile tips
Spectrophotometer tube and spectrophotometer
Each pair will pick up one culture from the ice-water bath on the front table. Record the number on the tube. It represents the age of the culture at which time the sample was taken.
With the P1000 (blue) pipettor set at 1.0 ml, transfer 1 ml of the culture to the first nine ml dilution blank (for the first 1/10 dilution to work with in Step 5).
Aseptically dump the remainder of the culture into the small spectrophotometer tube (to work with in step 4).
With the culture in the spectrophotometer tube, one person in the pair will obtain and record the absorbance reading of the culture while the other begins the next step.
With additional dilution blanks, make dilutions as specified below. Inoculate 1 ml from each of the four specified dilutions into each of two petri plates; plate inoculations can be made concurrently with preparation of the dilutions.
The dilutions to be plated are as follows:
For 0-hour through 2-hour sampling times: | 10-4, 10-5, 10-6, 10-7 |
For 2.5-hour through 4.5-hour sampling times: | 10-5, 10-6, 10-7, 10-8 |
For 5-hour through 9-hour sampling times: | 10-6, 10-7, 10-8, 10-9 |
For each plate, obtain a tube of melted PCA from the water bath and pour the contents into the plate. Mix the medium and inoculum by carefully swirling and allow the plates to solidify.
Incubate the plates inverted at 30°C until the next period.
Period 2
Each pair will determine the total plate count (no. of colony-forming units/ml of culture). Be sure you are counting colonies of all sizes. (E. coli typically produces small, lens-shaped colonies when growing below the surface.) Turn your result in to the instructor along with the absorbance reading. Be sure you have indicated the sampling time! Results will be compiled and presented next period.
Plot the plate count data on semi-logarithmic graph paper. Rather than generating a growth curve by connecting the dots, draw the best straight lines through the lag and exponential phases. (Transitions between the growth phases can be rounded out.)
Determine the growth rate and generation time for the particular strain and cultural conditions in our experiment. Remember that the points you need to calculate these values are to be taken from the best straight line drawn through the exponential phase. Do not use individual data points from the class data. Also, be sure to indicate the proper units (gen/hr or hr/gen). Show your calculations!
Plot the absorbance readings on semi-logarithmic graph paper. Note any similarities in the graph generated and that for the plate count data. Both the absorbance and plate count plots can be made on the same graph. Do not use the absorbance readings for any calculations of growth rate or generation time.
One important limitation to metabolic tests is that they almost always require the growth of the microbe in some medium and this takes at least 12-24 hours before a clear result is obtained. Faster results would speed diagnosis. A second limitation to metabolic tests is that a specific isolate under testing may have a mutation such that it is incapable of performing a metabolic conversion where the normal isolate of that species is proficient. For example, most strains of E. coli are capable of using lactose as a carbon source, but isolates of E. coli have been found that cannot utilize lactose. Finally, to clearly identify an isolate, it is often necessary to perform numerous tests. The preparation and use of all this media is time consuming and expensive.
Because of the limitations of metabolic tests, considerable effort has been made to find accurate, simple, and rapid alternatives. This research is starting to bear fruit, with the most popular methods being antibody tests and DNA methods, especially Figure 6-13 shows the steps of the TECRA reaction.
Here we present the TECRA reaction, explaining the theory behind how it works and a typical protocol for its use. The protocol was adapted from the technical material provided by BioTrace International.
This kit will be used for various experiments depending upon time and funding. The protocol is the same for both after the initial enrichment steps. These initial enrichment steps will be done according the FDA approved BAM. The majority of this section is modified from the instructions included with the TECRA kit.
Figure 7.13. The basis of TECRA.
TECRA reactions are a four step process that uses antibodies to detect various strains. Here is what is happening in each step
The TECRA® Visual Immunoassay (VIA) is a rapid and specific screening test for the in vitro detection of the species of interest in food, food-related and environmental samples after enrichment.
Following enrichment, at least 1 CFU of the species of interest in 25 grams of sample can be detected. Presumptive positives should be confirmed by standard methods. This is especially important in situations such as product recalls.
The TECRA® VIA utilizes antibodies which recognize all tested strains of the species of interest. This method has been shown to be at least as sensitive as standard culture and plating techniques and has virtually no cross-reactivity with other types of organisms.
The TECRA® VIA is an Enzyme-linked Immunosorbent Assay (ELISA) performed in a "sandwich" configuration.
Figure 7.14. Example of a TECRA reaction. A positive (left) and negative (right) TECRA reaction. The results can be observed qualitatively using a card or quantitatively using a plate reader. The card that comes with the TECRA kit is shown for reference.
What metabolic tests are really sensing is the absence or presence of a set of enzymes inside the microbe that carry out a specific function. All enzymes are encoded in the genome (the DNA) of the microbe. It is therefore possible to detect the presence of the genes that codes for specific enzymes instead of detecting the metabolic products of that enzyme activity. DNA detection methods depend upon the hybridization of a short piece or pieces of synthesized DNA to the genome of the test species. These short pieces of DNA are called probes or primers depending upon the method. The DNA genome of the test species is extracted, often by simply boiling a small bit of culture of the microbe, and then exposed to the primer. Once bound, the primer is detected in some fashion, the most common method being by PCR. DNA detection has several advantages.
Until a few years ago, detecting the presence of specific DNA sequences was much more difficult than performing metabolic tests. Even though there are advantages to using DNA tests, they remained something done in research labs for very different purposes. The emergence of PCR and specifically Real Time PCR (RT-PCR) is beginning to break down that barrier. Using RT-PCR, it is possible to detect the presence of a microbe in a sample in minutes to hours. Microbes can be detected at very low levels, sometimes just a few cells per gram of sample are detectable.
Real time PCR is a modification of the PCR protocol such that PCR fragments are rendered detectable by fluorescence, thus it become unnecessary to run an agarose gel to determine the absence or presence of a DNA fragment. Many kits are available to detect pathogens in food. However, UW-Madison uses a modified protocol that simulates the results one would obtain from a kit. Why are we not using a kit? Two reasons. First, they are expensive, costing $300-400 for 100 samples. Second, they have very high specificity. For example, the kit for hemorrhagic E. coli detects the labile toxin, which is responsible for many of the symptoms of the disease. Therefore, only the bona fide pathogen will work in the assay. While this is a good thing in the field, in a teaching laboratory it would require that you be given the real pathogen; probably not a good idea. Especially with hemorrhagic E. coli as it is believed that the infectious dose can be as low as 10 microorganisms.
In our assay, fluorescence is generated by the binding of SYBR green, a dye developed by Invitrogen. SYBR green is excited by light at 498 nm and emits light at 522 nm when returning to the ground state. The dye is highly specific for double stranded DNA, and has a much higher fluorescence when bound to it.
In RT-PCR, a PCR reaction is run in the presence of SYBR green. If a positive template is present, the PCR primers bind to it and create double stranded DNA (dsDNA). The SYBR green dye binds to this dsDNA. As the amplification proceeds, the concentration of dsDNA:SYBR green complex increases with the concentration of dsDNA. Specialized machines, RT-PCR thermocyclers, have been developed to measure the fluoresce coming out of PCR reactions after each cycle. If a positive template is present, a strong SYBR green fluorescence will be observed in the tube. Conversely, samples without a positive template will have a lower fluorescence. One caveat, SYBR green is non-specific and will bind to any dsDNA fragment present in solution. It is therefore important to perform a melting curve after the amplification to verify that the fragment obtained is the correct sequence. DNA sequences will have a unique temperature at which they melt, with the melting temperature dependent upon the specific primary sequence of the fragment. In most RT-PCR reactions, the correct fragment will have a unique melting temperature compared to any false positives that may have arisen in the tube. With a carefully designed experiment and given the right primers, it is possible to test for the presence or absence of any DNA sequence and therefore any desired microbe or set of microbes. Below is given a general protocol for extracting DNA and testing for various bacteria using RT-PCR. This protocol was adapted from the references listed at the end of this page.
Once processed continue from here
Master mix is purchased from Promega corporation. It comes as a 2x concentration. The SYBR green dye is purchased from invitrogen. (the material for gel staining) and comes in a 10,000x concentration. It is used in PCR assays at 100,000 x dilution. A 10x solution is a 10,000-fold dilution of the SYBR green. The primers are used as a concentration of primer is 0.25 µm. We obtained the primers from genosys.
PCR test for | Tm (°C) | primer forward (µl) | primer reverse (µl) | master mix | template DNA (µl) | SYBR green dye (10x) (µl) | double distilled water | Melt temp |
---|---|---|---|---|---|---|---|---|
E. coli | 60 | 1.7 | 1.6 | 25 | 10 | 5 | to 50 µl | 87.5 |
Salmonella | 55 | 2.4 | 2.9 | 25 | 10 | 5 | to 50 µl | 86 |
Listeria | 2 | 1.8 | 25 | 10 | 5 | to 50 µl | 80 |
Below are the sequences of the primers used to detect each species, along with their expected length of the fragment that should be generated if amplification is successful.
E. coli Primers (340 bp) |
---|
F: 5'-GTTAA TACCT TTGCT CATTG A-3' |
R: 5'-ACCAG GGTAT CTAAT CCTGT T-3' |
Salmonella primers (85 bp) |
---|
F: 5'-CCTTT CTCCA TCGTC CTGAA-3' |
R: 5'-TGGTG TTATC TGCCT GACC-3' |
Listeria monocytogenes primers (98 bp) |
---|
F: 5'- TCCGC AAAAG ATGAA GTTC-3' |
R: 5'-ACTCC TGGTG TTTCT CGATT-3' |
Figure 7.15. Running RT-PCR experiment. Samples are processed as described in the protocol and then mixed with template DNA, taq polymerase, dNTPs and primers. Each complete reaction is pipetted into in a 96-well rack (a) and placed into a RT-PCR system. The University of Wisconsin-Madison Bacteriology Department uses the Applied Biosystems 7500 Real-Time PCR System (b). The system is programmed using their software. Runs typically take about 1-2 hours to complete. Results consist of Amplification plots (c) and Melting Temperature curves (d). Final analysis consists of looking at what cycle fluorescence appeared and what the melting curve of each test looks like in comparison to the positive and negative control.
Figure 7.16. Interpreting RT-PCR. The table was generated by adding PCR primers specific for E. coli and running a RT-PCR reaction. Cycle threshold indicates the cycle at which the fluorescence detectedby the instrument passed a predetermined threshold, indicating the presence of a PCR product. Melting temperature is the temperature at which the amplified DNA double helix denatured into single strands. This is sequence specific. Any test PCR reaction should have approximately the same melting point as the positive control. Given this table of results, determine which of the 14 samples actually contained E. coli.
For more information on identifying and classifying bacteria, read the chapter on bacterial classification.
The data shown here was generated by growing E. coli in four different media and then comparing the results. Before you do anything, think about the various media and hypothesize about which condition would have the fastest growth rate. Then, use this data to prepare graphs of the four conditions. Once created, choose appropriate points and determine the growth rate and generation time of each culture.
Growth of E. coli in minimal medium + lactose at 37 °C.
Time (hours) | VPC1 | VPC2 |
7.80 x 106 | ||
1.0 | 1.08 x 107 | |
2.0 | 3.20 x 107 | |
2.5 | 6.40 x 107 | |
3.0 | 2.02 x 108 | |
3.5 | 3.56 x 108 | |
4.0 | 9.60 x 108 | 4.1 x 108 |
4.5 | 3.60 x 108 | |
5.0 | 9.50 x 108 | 2.50 x 108 |
5.5 | 1.83 x 109 | 1.07 x 109 |
6.0 | 1.05 x 109 | |
6.5 | 1.41 x 109 | |
7.0 | 1.03 x 10100 | |
7.5 | 1.00 x 109 | |
24.5 | 4.20 x 108 | |
25.5 | 1.00 x 108 | |
26.5 | 7.00 x 108 |
E. coli grown in Minimal medium + glucose
Time | VPC1 | VPC2 |
0.0 | 1.20 x 107 | |
0.5 | 1.13 x 107 | |
1.0 | 1.03 x 107 | 1.40 x 107 |
1.5 | 2.48 x 107 | 2.10 x 107 |
2.0 | 6.00 x 107 | |
2.5 | 8.40 x 107 | |
3.0 | 1.66 x 108 | |
3.5 | 3.30 x 108 | |
4.0 | 2.90 x 109 | 1.80 x 109 |
4.5 | 6.20 x 108 | 9.40 x 108 |
5.0 | 7.50 x 108 | 1.09 x 109 |
5.5 | 2.00 x 109 | 1.60 x 109 |
6.0 | 1.70 x 109 | 2.42 x 109 |
6.5 | 2.00 x 109 | 1.48 x 109 |
7.5 | 3.48 x 109 | |
8.0 | 4.00 x 109 | |
12.0 | 4.10 x 109 | |
16.0 | 3.70 x 109 | |
20.0 | 8.00 x 108 | |
24.5 | 1.25 x 108 | |
26.5 | 1.23 x 108 |
E. coli grown in Minimal medium + glycerol
Time | VPC1 | VPC2 |
0.0 | 2.52 x 107 | |
0.5 | 1.11 x 107 | |
1.0 | 9.80 x 106 | |
1.5 | 1.96 x 107 | |
2.0 | 1.65 x 107 | |
2.5 | 3.80 x 107 | |
3.0 | 4.10 x 107 | |
3.5 | 9.10 x 107 | |
4.0 | 5.80 x 107 | 1.50 x 108 |
4.5 | 2.23 x 107 | |
5.0 | 2.23 x 107 | 4.10 x 108 |
5.5 | 6.20 x 108 | 5.10 x 108 |
6.0 | 5.00 x 108 | 7.10 x 108 |
6.5 | 1.16 x 108 | 2.48 x 108 |
7.5 | 1.90 x 108 | |
24.5 | 3.56 x 108 | |
25.5 | 8.60 x 108 | 4.10 x 108 |
26.5 | 6.30 x 108 | 6.20 x 108 |
E. coli grown in Rich medium (Nutritent Broth + Glucose + Yeast Extract)
Time (hours) | VPC1 | VPC2 |
0.0 | ||
0.5 | 5.01 x 106 | |
1.0 | 4.90 x 106 | |
1.5 | 5.20 x 106 | |
2.0 | 1.46 x 108 | |
2.5 | 8.35 x 107 | |
3.0 | 3.85 x 108 | |
3.5 | 5.50 x 108 | |
4.0 | 5.55 x 108 | |
4.5 | 9.10 x 108 | |
5.0 | 8.40 x 108 | |
5.5 | 9.10 x 108 | |
6.0 | 1.10 x 109 | |
6.5 | 3.90 x 109 | 7.00 x 108 |
7.0 | 7.40 x 108 | |
7.5 | 7.70 x 108 | |
25.5 | 5.00 x 108 | |
26.5 | 7.70 x 108 |
After looking at the data and determining your growth rates, did your actual results match your hypothesis? In either case explain your reasoning.
Proper care and maintenance of microorganisms is essential for any successful experiments, be they in academic research, industry or the health field. If you do not understand what a microbe requires for growth it is very difficult to study its properties. Even in the field of environmental microbiology, where unculturable microbes are sometimes studied, the ultimate goal will be to bring strains into the laboratory where they can be examined in detail. Microbes, despite their great metabolic diversity, have the same basic requirements for growth; a carbon source, an energy source and a source of reducing power. Carbon can come from CO2 or organic molecules, energy will come from light or chemicals and reducing power is obtained from organic or inorganic chemicals.
A successful medium for a target microbe must contain all the nutrients it needs for growth in a form that the microbe can utilize. These are mixed in an aqueous solution and then sterilized, most often by autoclaving. Ingredients that cannot stand the heat of the autoclave are often filter sterilized. Once sterilized, all the components of a medium are mixed together and the medium is then inoculated with a source of bacteria.
One of the more important properties for a microbe is the relationship of the microbe toward oxygen. Organisms capable of utilizing oxygen in their metabolism are aerobes, those that cannot are called anaerobes. Microbes can be separated into 5 categories based upon their use of oxygen. Strict aerobes require oxygen for their growth, while strict anaerobes cannot survive in the presence of oxygen. Facultative anaerobes can grow in the absence of oxygen, but grow better in its presence. Aerotolerant anaerobes have mechanisms to protect themselves from oxygen, thus being able to grow in its presence or absence, but do not use oxygen in their metabolism. Finally microaerophiles require oxygen for their metabolism, but cannot survive at atmospheric levels of oxygen (21% O2). Microaerophiles are restricted to narrow bands in between aerobic and anaerobic habitats, where the oxygen gradient is within an acceptable range. Some examples would be in a lake or pond, or wet soil.
For unicellular orgnaisms, growth is normally thought of as an increase in number. Microbes can growth very rapidly and the most heavily studied microbes grow by binary fission. A characteristic growth pattern is found when microbes are growth in a closed vessel. Initially, the microbe adapts to a fresh medium and no growth is observed. This is called lag phase. The microbe then begins dividing and the increase in population occurs by a geometric progression, resulting in explosive growth until nutrients are used up or toxic end products accumulate. This is termed exponential growth phase. At this stage growth stops and stationary phase begins. The population remains constant, sometimes for long periods of time. Eventually, cells accumulate damage and begin to die. The decrease in population, called death phase, occurs exponentially.
The rate of growth can be calculated by determining the cell number at different times. The growth rate (k) is a measure of how rapidly the cells are dividing, the faster cells are growing, the higher the growth rate will be.