Prokaryotes
Introduction
Prokaryotes include the domains Bacteria and Archaea. All of the organisms that we study in this lab will be in the domain Bacteria.
This exercise is designed to familiarize students with some basic equipment and techniques used in the study of microorganisms. In addition, students will learn some basic techniques used in identifying procaryotes and make and view microscope slides of some common procaryotes.
Microbiology Laboratory Equipment
Sterilization
It is important that all instruments and media discussed below be sterile, that is, free of any living organisms. The use of sterile equipment, media, and techniques prevents unwanted microorganisms from contaminating your cultures.
Media
Culture media containing the necessary nutrients are used to grow microorganisms in a laboratory. Four kinds of commonly-used culture media are shown below.
Broth
Broth is a liquid that contains nutrients for bacteria to grow. It is kept in glass tubes and capped with a metal or plastic sleeve.
Agar
Agar is solid or semisolid. It liquefies at 100 C and solidifies at 40 C.
Agar plates are Petri dishes that contain agar for growing microorganisms. They have a large surface area and are useful for isolating and studying microorganisms. After they are inoculated, they are incubated in an inverted position. This prevents condensation from dripping from the cover onto the agar.
Agar slants are useful for maintaining cultures. Microorganisms grow on the surface of agar plates and slants.
Agar deep tubes are useful for studying gas requirements of microbes. A needle (see below) is used to inoculate a deep tube by pushing cells underneath the agar.
Transfer Instruments
Subculturing refers to transferring microorganisms from one medium to another. For example, bacteria growing in broth may be transferred to an agar plate.
Wire loops are used to transfer microorganisms from liquid media to liquid or solid media.
Needles are used for transferring microorganisms to deep tubes.
Pipettes are used to transfer liquids. A mechanical device must be used with pipettes to create a vacuum.
Incubation
Bacterial cells on the agar or in the broth will reproduce rapidly if other environmental conditions such as temperature are favorable. A single cell on the agar will shortly produce a colony of cells that is easily visible to the naked eye. Such a colony is a pure culture because it is a single species.
An incubator is a chamber that maintains a constant temperature. After microorganisms are transferred to broth or agar, they are placed in an incubator (incubated) for a period of time while the cells reproduce.
Refrigerators are useful for maintaining stock cultures for long periods of time because microorganisms grow (reproduce) very slowly at low temperatures. They can also be used to store subcultures after they have been incubated.
Culture Transfer Techniques
Techniques
The procedure listed below can be used to transfer microorganisms from a tube of broth to another culture tube.
Microorganisms are often transferred from one medium to another with a wire loop or needle. Before the loop or needle is used to remove a sample of microorganisms, it must first be sterilized.
The wire should be heated until it glows red. The blue part of the flame is the hottest part and will heat the wire the fastest..
The upper part of handle should also be passed through flame.
The loop should be cooled in the air for 10 to 20 sec. Care should be taken not to put it down in order to avoid contamination.
Hold the source tube and also the tube to be inoculated in one hand as shown above. The loop or needle is held in the other hand.
The two tubes are uncapped by using the hand that holds the loop. The likelihood of contamination can be minimized by keeping the caps in your hand as shown below.
Pass the mouths of the tubes through the flame.
Remove a sample from a broth culture by using a sterile wire loop.
A loop or needle are used to remove a sample from an agar slant. Touch the colony to be subcultured with the wire but do not break the surface of the agar.
Reflame the mouths of the tubes and replace the caps.
Reflame the loop or needle before putting it down.
Notes on Transferring Samples
Transferring to broth – Put the loop in the broth and then swirl it.
Agar slant or plate – When inoculating an agar slant or plate, draw the loop very lightly over the surface while being careful not to break the surface. A straight or a zig-zag motion can be used.
Deep Agar Tube – Push needle directly into the agar to the bottom of the tube, then remove it.
Laboratory Procedure
1) Transfer S. marcescens: from broth to a sterile agar slant using a wire loop.
2) Transfer S. marcescens: from broth to a sterile deep tube using a needle.
3) Transfer S. marcescens: from broth to a sterile broth using a wire loop.
4) Transfer S. marcescens: from a slant to a sterile broth.
5) Transfer S. marcescens: from a slant to sterile slant.
6) Transfer S. marcescens: from a slant to a sterile agar deep tube.
Put your name on each tube and place them in a 37 degree incubator for 48 hours.
Sampling the Environment
The procedure below will demonstrate that bacteria are commonly found throughout our environment.
Use a cotton swab to sample bacteria on a surface such as a desktop, the floor, or a stair handrail. After rubbing the swab on the surface, rub it lightly on the surface of an agar plate.
Your instructor will place the plates in an incubator for 48 hours. They can be examined during the next lab period.
Staining
Procaryotes are typically stained to make them easier for viewing. We will use a basic staining procedure called gram staining. This staining method separates bacteria into two groups based on the thickness of their cell wall. Gram positive bacteria have a thick cell wall and will appear dark purple after a gram stain. Gram negative bacteria have a thinner cell wall and will appear lighter in color.
Preparing a Smear
The gram staining technique involves making a smear of bacteria on a slide and then adding the stain.
Use a wire loop to place a sample of Staphlococcus xylosus on the center of a slide. Place a sample of Escherichia coli on the center of a second slide.
Use a wire loop or a dropper to add a small amount of distilled water to the sample and use a wire loop to spread the culture evenly over an area the size of a dime or smaller.
Allow the slides to air-dry.
After they are dry, pass the slides over the flame of a bunsen burner two or three times to fix it. This process causes the bacteria to become attached to the slide and prevents them from washing off during the staining process.
Gram Staining
Place a wire test tube rack in a plastic tray and place the slides on the test tube rack. as shown below.
Flood the slides with crystal violet for 1 minute. This should be done over the sink or a tray to prevent stain from spilling on the laboratory bench top.
Wash the slides with tap water.
Stain with Gram's iodine (a mordant) for 1 minute.
Wash again with tap water.
Flood the slides with 95% ethyl alcohol. This decolorizes bacteria that have thin cell walls.
Wash with tap water.
Counterstain with safranin for 45 seconds.
Wash with tap water.
Blot dry. The slide is ready for viewing; cover slips are not necessary. View the slide using high power. You may wish to also view the slide using the oil immersion lens. Click here for instructions on oil immersion microscopy.
1. Draw and describe each slide.
Prepared Slides of Typical Bacteria
You will be asked to observe different procaryotic cells below. It is suggested that you begin at 100X and then switch to 430X after focusing. It is not necessary to use 1000X. If you would like to try 1000X, you must put a drop of immersion oil between the slide and the objective.
2. The slides that you stained and viewed (above) are typical cocci (Staphlococcus xylosus) and bacilli (Escherichia coli). Observe and draw a prepared slide of typical spirilla.
Click here for more information about these three shapes.
Typical Bacillus X 400 Typical Bacillus X 1000 Typical Coccus X 400 Typical Spirillum X 400
Cyanobacteria
3. Observe and draw Oscillatoria, Anabaena, and Gloeocapsa. Be sure to indicate the magnification used in your drawing.
The photographs below show prepared slides of several kinds of cyanobacteria.
Gloeocapsa X 400 Oscillatoria X 400 Anabaena X 400 Anabaena showing a heterocyst. Heterocysts function in nitrogen fixation.
