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Bacterial samples are critical for research, diagnostic, and teaching purposes. Although there are many ways to store bacteria, the ideal method is a function of bacterial compatibility, experimental purpose, and cell viability. As a general rule, the viable storage period of bacteria increases as the storage temperature decreases. Once the temperature is below the freezing point, however, cryoprotectants are essential to reduce cell damage caused by the freezing process.
The specific length of time that a culture will remain viable in a given storage condition is dependent upon the bacterial strain. Cell death during storage is inevitable but should be minimized as much as possible, which can sacrifice ease of use. Bacterial cultures that are used regularly (i.e., daily/weekly) can be stored on agar plates or in stab cultures in a standard refrigerator at 4°C. If cultures will not be used for more than a few weeks, though, more long-term storage methods should be considered for maximum bacterial viability (Table 1).
Working bacterial stocks can be streaked onto agar plates and stored at 4°C for daily or weekly use. Culture dishes should be wrapped with laboratory sealing film (plastic or paraffin) and stored upside down (agar side up) to minimize contamination and to keep both the culture and agar properly hydrated. Some bacterial strains can be stored for up to 1 year at 4°C in agar stab cultures, which are especially useful for transporting samples to other research facilities. Stab cultures are prepared by first sterilizing strain-compatible agar (e.g., lysogeny broth [LB] agar for E. coli) and then transferring the warm liquid agar to screw-cap vials using the appropriate aseptic technique. After the agar has solidified, a single colony is picked from an actively growing culture using a sterile, straight wire. The wire with the bacteria is then plunged deep into the soft agar several times, and the vial is incubated at 37°C for 8–12 hours with the cap slightly loose. The vial is then sealed tightly and stored in the dark at 4°C.
Table 1. Approximate time bacterial cultures remain viable in different storage conditions. | ||
Condition | Temp (°C) | Time (approx.) |
Agar plates | 4 | 4 - 6 weeks |
Stab cultures | 4 | 3 weeks - 1 year |
Standard freezer | -20 | 1 - 3 years |
Super-cooled freezer | -80 | 1 - 10 years |
Freeze dried | ≤4 | 15 years+ |
As mentioned above, the temperature at which frozen bacteria are stored affects how long they can be stored while remaining viable. Freezing and thawing cells at an appropriate rate and maintaining the frozen stocks at the proper storage temperature help to minimize damage from the freezing process. Also, the greater the cell density, the better the recovery is after thawing the cells. For most bacteria, a density of 107 cells/mL will result in adequate recovery if all conditions are properly maintained.1-2
Cryoprotectants: As water in cells is converted to ice, solutes accumulate in the residual free water. This localized increase in salt concentration can denature biomolecules.3 Furthermore, ice crystal formation can damage cell membranes. Additives that are mixed with the bacterial suspension before freezing lower the freezing point and protect cells during freezing to minimize the detrimental effects of increased solute concentration and ice crystal formation. The most commonly used cryoprotectants are dimethylsulfoxide (DMSO) and glycerol, which are typically used at 5–15% (v/v). Non-permeable additives used as cryopreservants, such as polysaccharides, proteins, and dextrans, adsorb to the surface of microorganisms and form a viscous layer that protects membranes, making these agents particularly useful for cryopreservation. Other commonly used additives include blood serum, ethylene glycol, methanol, skim milk, yeast extracts, and tripticase soy.4
Freezing samples: To prepare glycerol stocks, the glycerol is first autoclaved and allowed to cool. The appropriate volume of glycerol is added to a suspension of log-phase bacteria and vortexed to dissociate the cells and ensure even mixing of the bacteria with the glycerol. After aliquoting the suspension into cryogenic screw-cap vials, the cells are snap-frozen by immersing the tubes in either ethanol-dry ice or liquid nitrogen and then stored in freezers (‑20 to -80°C) or liquid nitrogen (-150°C).5 Repeated thawing and refreezing of the bacterial stocks will reduce cell viability and should be avoided. When recovering strains with antibiotic selection markers, culturing them on selective media will ensure that the bacterial stocks were not contaminated.
Freeze-drying: Bacteria can be freeze-dried by suspending log-phase cells in a lyophilization medium and then freeze- drying the suspension. Not all bacteria can be successfully freeze-dried.6-8 Certain strains might not survive the process or die rapidly once freeze-dried. The best way to determine if a strain is amenable to freeze-drying is to empirically evaluate its stability post–freeze-drying while maintaining a live culture as a backup. Once freeze-dried, it is best to store the bacteria at or below 4°C.
Bacterial samples are critical for research, diagnostic, and teaching purposes. Although there are many ways to store bacteria, the ideal method is a function of bacterial compatibility, experimental purpose, and cell viability. As a general rule, the viable storage period of bacteria increases as the storage temperature decreases. Once the temperature is below the freezing point, however, cryoprotectants are essential to reduce cell damage caused by the freezing process. The specific length of time that a culture will remain viable in a given storage condition is dependent upon the bacterial strain. Cell death during storage is inevitable but should be minimized as much as possible, which can sacrifice ease of use. Bacterial cultures that are used regularly (i.e., daily/weekly) can be stored on agar plates or in stab cultures in a standard refrigerator at 4°C. If cultures will not be used for more than a few weeks, though, more long-term storage methods should be considered for maximum bacterial viability (Table 1).
1. Simione, F.P. and Brown, E.M. (1991). ATCC Preservation Methods: Freezing and Freeze Drying. American Type Culture Collection, Rockville, Maryland.
2. Simione, F.P. (1992). Key issues relating to the genetic stability and preservation of cells and cell banks. J Parenter Sci Technol 46:226-32.
3. De Paoli, P. (2005). Biobanking in microbiology: From sample collection to epidemiology, diagnosis and research. FEMS Microbiology Reviews 29:897-910
4. Huba'lek, Z. (2003). Protectants used in the cryopreservation of microorganisms. Cryobiology 46: 205-29.
5. Moore, L.W. and Rene, V. (1975). Liquid nitrogen storage of phytopathogenic bacteria. Phytophathology 65:246-50.
6. Miyamoto-Shinohara, Y., et al. (2008). Survival of freeze-dried bacteria. J Gen Appl Microbiol 54(1):9-24.
7. Miyamoto-Shinohara, Y., et al. (2006). Survival curves for microbial species stored by freeze-drying. Cryobiology. 52(1):27-32.
8. Miyamoto-Shinohara, Y., et al. (2000). Survival rate of microbes after freeze-drying and long-term storage. Cryobiology. 41(3):251-5.
9. Su, S.C., et al. (1996). Temperature variations in upright mechanical freezers. Cancer Epidemiol Biomarkers 5(2):139-40.