- 00:01Concepts
- 03:09Media Preparation
- 05:12Preparing Agar Plates
- 06:21Culturing Host Cells
- 07:30Phage Serial Dilution and Preparation of Bacteria and Phage Overlay
- 10:37Data Analysis and Results
- 11:35Results
斑块测定:确定病毒性皮石为斑块形成单位(PFU)的方法
English
Share
Overview
资料来源:蒂尔德·安徒森1号,罗尔夫·卢德1
1临床科学隆德系,感染医学系,生物医学中心,隆德大学,221 00 隆德,瑞典
感染原核生物的病毒,称为噬菌体或简称噬菌体,在20世纪初由Twort(1)和d’Hérelle(2)独立发现。自那时以来,噬菌体因其治疗价值(3)及其对人类(4)以及全球生态系统(5)的影响而得到广泛认可。目前的关切促使人们重新关注使用噬菌体作为现代抗生素替代治疗传染病的方法(6)。基本上,所有的噬菌体研究都依赖于纯化和量化病毒的能力,也称为病毒性小子。最初描述在1952年,这是斑块测定的目的(7)。几十年后,多项技术进步,斑块测定仍然是确定病毒性牙点(8)的最可靠的方法之一。
噬菌体通过将遗传物质注入宿主细胞,劫持机器来生产新的噬菌体颗粒,并最终导致宿主通过细胞解释释放许多后代病毒。由于其微小的大小,噬菌体不能只用光显微镜观察;因此,扫描电子显微镜是必需的(图1)。此外,噬菌体不能像细菌一样在营养琼脂板上培养,因为它们需要宿主细胞来捕食。
图1:噬菌体形态,这里以大肠杆菌噬菌体为例子,可以用扫描电子显微镜进行研究。大多数噬菌体属于考多病毒(尾噬菌体)。这种特殊的噬菌体有一个很短的尾巴结构和一个食道头,把它放在波多病毒家族。
斑块测定(图2)基于将宿主细胞(优先用于对数相生长)并入培养基。这创造了一个密集,浑浊的细菌层,能够维持病毒生长。分离的噬菌体随后可以感染、在一个细胞内复制和分莱。每个分莱细胞,多个相邻的细胞立即被感染。在几个周期中,在原本浑浊的板块中可以观察到一个清晰的区域(斑块),表明最初是单个噬菌体粒子的存在。因此,样品每体积(即PFU/mL)的斑块形成单位数量可以从产生的斑块数量中确定。
图2:检测斑块形成单元(PFU)是确定样品中噬菌体数量的常见方法。(A)无菌培养皿的基底覆盖着适当的固体营养介质,然后是软培养基、易感宿主细胞的混合物和原噬菌体样本的稀释。请注意,在某些情况下,噬菌体悬浮液也可以均匀地分布在已经凝固的软琼脂表面。(B)宿主细菌的生长在琼脂层形成细胞草坪。噬菌体复制产生由宿主细胞解致引起的透明区域或斑块。
图3:PFU测试结果显示,噬菌体产生的多斑块。由于易感宿主细胞的赖清,斑块可被视为细菌草坪上的清除区,要么具有(A)完全清除,要么(B)由产生耐药细菌(或可能是由耐温噬菌体)引起的部分再生致源循环)。
除了以前描述的溶血生长外,某些温带噬菌体可以采用所谓的溶源性生命周期。在地合体中,病毒通过将其遗传物质纳入宿主细胞(9)的基因组而假定为潜伏状态,这通常对进一步的噬菌体感染具有抵抗力。这有时通过斑块的轻微云彩(图3B)来揭示。然而,值得注意的是,斑块也可能显得模糊,由于细菌的再生长,已经进化了抵抗噬菌体,独立于以前的噬菌体感染。
病毒可以附着或吸附,只有有限的宿主细菌(10)。宿主范围受到细胞内抗病毒策略(如CRISPR-Cas系统(11)的进一步限制。细菌亚群对特定噬菌体表现出的抗药性/敏感性历来被用来将细菌菌株分类为不同的噬菌体类型(图4)。虽然这种方法的有效性现已被新的测序技术所超越,但噬菌体类型仍然可以提供有关细菌-噬菌体相互作用的宝贵信息,例如,促进为临床使用设计噬菌体鸡尾酒.
图4:不同细菌菌株的噬菌体敏感性。软琼脂板与可爱痤疮菌株(A)AD27和(B)AD35,被发现与21种不同的C.痤疮噬菌体。只有噬菌体11能够感染和杀死AD27,而AD35菌株对所有噬菌体表现出敏感性。这种技术,称为噬菌体类型,可用于根据噬菌体易感性将细菌种类和菌株分成不同的亚群。
Procedure
Applications and Summary
Despite multiple technological advances, plaque assays remain the gold standard for determination of viral titer (as PFU) and essential for isolation of pure bacteriophage populations. Susceptible host cells are cultivated in the top coat of a two layered agar-plate, forming a homogenous bed enabling viral replication. The initial event where an isolated bacteriophage in lytic lifecycle infects a cell, replicates within it, and eventually lyses it, is too small to observe. However, the virions released will infect adjacent cells, subsequently giving rise to a clearing zone, or plaque, denoting the presence of a single PFU.
References
- Twort, F. An investigation on the nature of ultra-microscopic viruses. Lancet. 186 (4814): 1241-1243. (1915)
- d'Hérelle, F. An invisible antagonist microbe of dysentery bacillus. Comptes Rendus Hebdomadaires Des Seances De L Academie Des Sciences. 165: 373-375. (1917)
- Cisek AA, Dąbrowska I, Gregorczyk KP, Wyżewski Z. Phage Therapy in Bacterial Infections Treatment: One Hundred Years After the Discovery of Bacteriophages. Current Microbiology. 74 (2):277-283. (2017)
- Mirzaei MK, Maurice CF. Ménage à trois in the human gut: interactions between host, bacteria and phages. Nature Reviews Microbiology. 15 (7):397. (2017)
- Breitbart M, Bonnain C, Malki K, Sawaya NA. Phage puppet masters of the marine microbial realm. Nature Microbiology. 3 (7):754-766. (2018)
- Leung CY, Weitz JS. Modeling the synergistic elimination of bacteria by phage and the innate immune system. Journal of Theoretical Biology. 429:241-252. (2017)
- Dulbecco R. Production of Plaques in Monolayer Tissue Cultures by Single Particles of an Animal Virus. Proceedings of the National Academy of Sciences of the United States of America. 38 (8):747-752. (1952)
- Juarez D, Long KC, Aguilar P, Kochel TJ, Halsey ES. Assessment of plaque assay methods for alphaviruses. J Virol Methods. 187 (1):185-9. (2013)
- Clokie MRJ, Millard AD, Letarov AV, Heaphy S. 2011. Phages in nature. Bacteriophage. 1 (1):31-45. (2011)
- Moldovan R, Chapman-McQuiston E, Wu XL. On kinetics of phage adsorption. Biophys J. 93 (1):303-15. (2007)
- Garneau JE, Dupuis M-È, Villion M, Romero DA, Barrangou R, Boyaval P, Fremaux C, Horvath P, Magadán AH, Moineau S.. The CRISPR/Cas bacterial immune system cleaves bacteriophage and plasmid DNA. Nature. 468 (7320):67. (2010)
Transcript
Bacteriophages, also called phages, are viruses that specifically infect bacteria and we can confirm their presence and quantify them using a tool called the plaque assay. Bacteriophages infect their susceptible hosts by first attaching to the bacterial cell wall and injecting their genetic material. Then, they hijack the cell’s biosynthetic machinery to replicate their DNA and produce numerous progeny phage particles, which they then release by lysing and killing the host cell.
This lytic activity is the basis of a widely used phage enumerating technique known as the plaque assay or double agar layer assay. Here, a bacteriophage mix is first prepared in a molten nutrient broth containing low concentration agar. All bacteria used in the mix should be alive and actively dividing in the log phase of their growth, which will ensure that a large percentage of the bacteria are viable and able to form a dense lawn around the plaques. Next, this molten bacterial-phage agar mix is spread over a more solid, concentrated agar nutrient medium which is already solidified on a Petri dish. On incubation at room temperature, the low concentration agar-phage-bacteria broth also solidifies to form a soft agar overlay.
Here, the bacterial cells can derive additional nutrients from the bottom layer and should rapidly multiply to produce a confluent lawn of bacteria. However, as phage particles are also present in the soft layer, these will infect and replicate their genetic material within the bacteria, culminating in cell lysis, which releases multiple progeny. These phage progeny then infect the neighboring cells, as the semi-solid state of the bacteria-phage layer restricts their movement to more distantly located host cells. This cycle of infection and lysis continues over multiple rounds, killing a large number of bacteria in a localized area. The effect of the neighboring cells being destroyed, is to produce a single circular clear zone, called a plaque, which can be seen by the naked eye, effectively amplifying the bacteria lytic activity of the phage and enabling their enumeration.
The number of plaques on a Petri dish are referred to as Plaque-Forming Units, or PFUs, and, providing the initial bacteriophage concentration was sufficiently dilute, should directly correspond to the number of infective phage particles in the original sample. This technique can also be used for characterization of plaque morphology, to aid in identification of phage types, or to isolate phage mutants. In this lab, you will learn how to perform the plaque assay for enumerating phages, using the T7 phage of E. coli as an example.
First, identify a suitable medium for the culturing of the host bacterial cells and the bacteriophage. Here lysogeny broth, or LB medium, was used to culture E. coli and the T7 phage. Next, take three clean glass bottles and label them with media, name, and then the first as LB-Broth, the second as LB-Bottom Agar, and the third as LB-Top Agar. Now, weigh out four grams of pre-formulated LB powder in three sets and then transfer one set of weighed dried media into each bottle. Add 200 milliliters of water to the first bottle. Mix the contents using a magnetic stir bar.
Then, using a pH meter and constant stirring, bring the final pH to 7.4 through the addition of sodium hydroxide or hydrochloric acid. Repeat the water addition and pH adjustment for the other two remaining bottles, as well. Now, weigh out three grams of agar powder and add it to the second bottle to make a 1.5 % bottom agar. Finally, weigh 1. 2 grams of agar and add it to the third bottle to make the .6 % LB top agar. The broth condition in bottle one does not need an agar addition. Cap the bottle semi-tightly and then, sterilize the media by autoclaving at 121 degrees Celsius for 20 minutes. Once complete, remove the media bottles from the autoclave and immediately twist the bottle caps to close them fully to prevent contamination. Keep the LB-Broth and LB-Top Agar media on the bench for later use. Place the LB-Bottom Agar to cool in a water bath that is preset to approximately 45 degrees Celsius.
When the LB-Bottom agar reaches approximately 45 degrees Celsius, transfer it to the work bench. Next, sterilize the workspace using 70 % ethenol. Next, add 450 microliters of sterile one molar calcium chloride to the molten bottom agar to make a final concentration of 2.25 millimolar. Gently swirl the bottle to mix. Then, set out seven clean Petri dishes. Label each dish on the bottom with the media name and preparation date. Then, pour 15 milliliters of the bottom agar into each of the seven Petri dishes. Allow the plates to set for a few hours or overnight at room temperature. Once set, the culture plates can be stored at four degrees Celsius for several days if needed, upside down to minimize condensation. Transfer the Petri dishes from the four degrees Celsius refrigerator to a 37 degrees Celsius incubator one hour before the assay.
The day before the assay is to be preformed, the E. coli should be cultured. Here, 10 microliters of E. coli culture was inoculated into 10 milliliters of LB-Broth. Place the bacteria to grow overnight in a shaking incubator set to 37 degrees Celsius at 160 RPM. Then, on the day of the assay, remove the bacterial culture from the incubator. Seed a fresh 10 milliliters of fresh LB broth with 0.5 milliliters of the overnight culture. Place these cells to grow into a shaking incubator set to 37 degrees Celsius at 160 RPM. Next, use a spectrophotometer to check when this culture reaches log phase growth, indicated by an optical density of 0.5 to 0.7. Once the OD reaches this level, stop the incubation by transferring the cell culture to the bench. They are now ready to be used for phage overlay assay.
Phage titers can vary exponentially across different phage types and samples. So in order to count them effectively, they should be diluted to generate a wide range of phage concentrations. On the day of the assay, generate a series of phage dilutions ranging from one tenth to one millionth concentrations, following a 10-fold dilution technique. To obtain statistically significant and accurate data, perform the serial dilution in triplicate.
Next, melt the solidified LB-top agar using a microwave. Then, place it in a water bath that is preset at 45 degrees Celsius for one hour. After one hour, collect the Petri dishes containing the bottom agar layer from the incubator. Label the plates with phage concentration and assay date. Then, set out seven clean test tubes. Label each test tube with the serial phage dilution number and designate one as control.
When the LB-top agar reaches 45 degrees Celsius, transfer it to the working bench. Now, add 450 microliters of one molar calcium chloride to the 200 milliliter agar to make a final concentration of 2.25 millimolar. Gently swirl the bottle to mix. Next, add 35 milliliters of LB-top agar and four milliliters of bacterial suspension to a sterile conical tube. Gently swirl to evenly distribute the cells but avoid shaking to prevent foaming.
Now, aliquot five milliliters of this bacteria- top agar mix to each of the seven test tubes. Then, transfer 100 microliters of the serially diluted bacteriophage samples and control media, which should be simply media with no bacteriophage, to the respectfully labeled test tubes. Swirl the mixture gently to ensure proper mixing. Gently transfer five milliliters of bacteriophage mix onto the respective Petri plate. Evenly spread the mix throughout the whole surface by gently swirling the Petri plate.
Once all of the Petri plates are layered with the mix, allow solidification of the top layer by incubating at room temperature for 15 minutes. After completion of these steps, repeat the process for the second and then the third sets of the Petri dishes using the remaining two sets of phage dilutions. Seal each dish with parafilm and incubate at room temperature for 15 minutes. Place the culture plate upside down at a suitable temperature for 24 hours or until plaques develop. Here, plates were placed in a 37 degrees Celsius incubator for one day, a stimulating growth condition for E. coli and the T7 phage.
Plaques will appear after one to five days of incubation, depending on the bacterial species, incubation conditions, and the choice of medium. Here, plaques were visible after one day of incubation at 37 degrees Celsius. Begin by checking the plates marked control and ensure that no plaques were formed in these plates, as this would indicate viral contamination. To determine the phage titer in the original sample, start with the plates containing the most diluted phage sample first and count the plaques without removing the lids, marking them to indicate which ones have already been counted. Repeat the counting for each plate in every set. Some plates might have too many or too few plaques to be counted. Consider 10 to 150 as an ideal plaque count.
Next, generate a table listing the plaque number values for the different dilutions and replicates. Then, calculate the mean plaque number values for the dilution plates that contained the ideal number of plaque counts. In this example, these were the average number of plaques formed in the 10 to the minus three and 10 to the minus four dilution plates. Now, adjust for phage dilution factor by dividing the obtained mean plaque values by the respective phage dilution factors. Here, the average number of plaques formed to the 10 to the minus three and 10 to the minus four dilution plates, were divided by their respective dilution factors to obtain the number of plaque forming units, or PFUs, in 100 microliters of phage mixture. To convert the value to PFU per milliliter, multiply the generated values by 10, as only 100 microliters of phage dilution mix was used during the bacteriophage overlay preparation step, producing an additional dilution factor of 10. Finally, calculate the average of the values obtained from the different dilution plates. This will give the average number of PFUs per milliliter. The number of PFUs corresponds to the number of infective phage particles in the original sample.