Summary

Plaquing of Herpes Simplex Viruses

Published: November 05, 2021
doi:

Summary

Plaquing is a routine method used to quantify live viruses in a population. Though plaquing is frequently taught in various microbiology curricula with bacteria and bacteriophages, plaquing of mammalian viruses is more complex and time-consuming. This protocol describes the procedures that function reliably for regular work with herpes simplex viruses.

Abstract

There are numerous published protocols for plaquing viruses, including references within primary literature for methodology. However, plaquing viruses can be difficult to perform, requiring focus on its specifications and refinement. It is an incredibly challenging method for new students to master, mainly because it requires meticulous attention to the most minute details. This demonstration of plaquing herpes simplex viruses should help those who have struggled with visualizing the method, especially its nuances, over the years. While this manuscript is based on the same principles of standard plaquing methodology, it differs in that it contains a detailed description of (1) how best to handle host cells to avoid disruption during the process, (2) a more useful viscous medium than agarose to limit the diffusion of virions, and (3) a simple fixation and staining procedure that produces reliably reproducible results. Furthermore, the accompanying video helps demonstrate the finer distinctions in the process, which are frequently missed when instructing others on conducting plaque assays.

Introduction

The beginnings of virus plaque assays go back to the first discoveries of viruses in the 1890s1. Tobacco mosaic virus was first isolated and passed on tobacco leaves, where individual spots of infection could be recognized and quantified as originating from a single, live virus entity2, later identified as a virion2. Later seminal studies with bacteria and bacteriophages perfected the techniques used to plaque these viruses, including bacteria at the mid-log phase of growth, serial dilution of bacteriophage samples, and top agar with subsequent visualization of literal holes (named plaques) in the bacterial lawn3.

Plaquing of animal viruses lagged the exciting research being conducted with bacteriophages, mainly because the methods required for growing mammalian cells in culture were not developed until the 1940s4. However, the advent of growing murine cells in the absence of the entire host organism4 spawned a new era in the ability to culture and count viruses. Such work was extended for the propagation and quantitation of Western Equine Encephalomyelitis virus in chicken cells and poliovirus in human cells5,6. As the realm of culturable mammalian cells expanded, the bevy of different host cells for various viral infections gave the world a cornucopia of possibilities to study all manner of viruses7. This included the propagation and quantification of human herpesviruses, particularly herpes simplex virus-1 (HSV-1) and -2 (HSV-2), which cause mucocutaneous lesions8. Importantly, all plaque assays are dependent on the existence of live virions, which can enter host cells in a receptor-mediated fashion in a sample9. Regardless of the ubiquity and multitude of publications on the execution of plaque assays5,10,11,12,13,14,15,16, these methods for HSV-1/-2 are a mixture of both art and science; one cannot conduct the assay without proper attention to every detail in the protocol, nor can one execute a successful assay without a crticial eye for subtlety in the process. This manuscript depicts one of the most consistently reproducible methods for HSV-1/-2 plaque assays, with precise details towards the art of the assay that are seldom discussed.

This current protocol obtains live plaque-forming units (PFU) counts for HSV-1 and -2 reliably. Best results are obtained using Vero cells (transformed African green monkey kidney epithelial cells) at low passage (below passage number 155) and routinely grown in alpha-MEM17 supplemented with 10% fetal calf serum (FCS), L-alanyl-L-glutamine, and an antibiotic/antimycotic mixture18. Vero cells are standardly propagated in this medium two to three times per week at a 1/5 dilution each time.

Protocol

All procedures with the Vero cells and live herpesviruses have been approved by the Towson University Institutional Biosafety Committee. A generalized scheme of these procedures is represented in Figure 1.

1. Seeding of the Vero cells

  1. The day before initiating the plaque assay, trypsinize Vero cells and resuspend them in regular Dulbecco's Modified Eagles Medium (DMEM) and supplement as per standard cell culture methodology19. Resuspend the trypsinized cells in 10 mL of DMEM per T-75 flask of the confluent Vero cells (~107 cells).
    NOTE: DMEM is used for plaque assays instead of alpha-MEM because it slightly slows the cell growth rate and favors better plaque assay results.
  2. Count the cells by one's preferred method (e.g., a standard hemocytometer with Trypan Blue exclusion)19.
  3. Seed the cells at 4 x 106 cells/plate; for HSV-2, use 6-well plates with 2.5 mL of DMEM (with supplements) per well; and for HSV-1, use 12-well plates with 1.25 mL of DMEM (with supplements) per well.
    NOTE: The number of cells should be constant regardless of the plate used, though the size of the wells matters concerning accuracy in the plaque assay. It is essential to get cells evenly distributed, which can be most effectively accomplished by moving the plate back and forth, not in a circular fashion.
  4. Allow the cells to grow overnight at 37 °C/5% CO2 in a humidified incubator.
    ​NOTE: Humidity is maintained with a pan of distilled water containing an algicide in the bottom of the incubator.

2. Sample dilution

  1. Complete the sample dilution and the addition of virus to cells in one lab session.
    CAUTION: HSV-1 and -2 are infectious for humans and must be handled under proper biosafety containment (BSL-2). Keep all materials that come into contact with the virus separate and disinfect with a quaternary agent at 1/256 dilution (see Table of Materials), iodophor, bleach, or strong ionic detergent (e.g., SDS) before removing them from the biosafety cabinet.
  2. The day after seeding of the Vero cells, serially dilute each virus sample to be plaqued in 1x PBS; typically use 10-fold dilutions for most precise tracking.
  3. Make these dilutions through 10-4 (for low concentrations of viruses) or through 10-9 (for expectations of higher titer samples) with at least 1 mL of each sample remaining for the plaque assay itself.
  4. Keep all the viral dilutions on ice (no longer than 1 h) until ready to add these diluted virus samples to the cells.

3. Addition of virus to the cells

  1. Remove the cell culture medium from one or two wells by pipette.
    NOTE: Do not use an aspirator because it removes too much liquid from the cell monolayer and dries the cells out. One crucial consideration is ensuring that the cell monolayer remains hydrated throughout the entire course of the experiment. If the cells dry out, they will wash off the plate in the final step and generate unusable data. Therefore, process only one or two wells at a time to reduce this possibility.
  2. Carefully add the diluted virus sample (100-400 µL and 50-200 µL of virus sample are used for 6-well and 12-well plates, respectively) dropwise to each monolayer, adding the drops down the side of each well. Repeat the process for every one or two wells until the entire plate is filled with the virus samples being plaqued.
    NOTE: Adding the drops to the center of the well may inadvertently slough cells off the substrate.
  3. Gently rock the entire plate by hand to ensure the PBS that contains the virus covers the entire monolayer of cells in each well, then place the plate in a CO2 incubator at 37 °C to allow the virus to adsorb.
  4. Every 10 min within 1 h, remove the plate from the incubator, gently rock it again to spread the virus more evenly across each well, and then place it back in the incubator.
    NOTE: Each experiment will dictate the number of replicates and which dilutions are used; the reader's preference dictates that decision.
  5. To diminish the possibility of inadvertently counting unabsorbed inoculum, remove the virus sample from the wells with 1000 µL pipette tips and place it in a waste beaker.
    NOTE: Again, this procedure is conducted with only one or two wells at a time to maintain hydration of the cell monolayer.
  6. Place 2.5 mL of a methylcellulose overlay (dissolve 5% methylcellulose w/w in 100 mL of PBS, autoclave for 15 min at 121 °C and 15 psi on a liquid cycle, then add 375 mL of DMEM plus 25 mL of FBS).
  7. Once an entire plate contains overlay, place the plate back in the incubator to allow growth for two days.
    NOTE: If the virus and cells are allowed to grow for three days, even in DMEM plus supplements, a substantial loss of cells in the monolayer may result, thereby compromising the final data.
  8. Disinfect the waste beaker, typically with the addition of bleach, an iodophor, or a similar virucide, before removing it from the biosafety cabinet.

4. Staining for plaques

  1. After the two-day incubation, remove the methylcellulose overlay by a pipette, again one or two wells at a time, and place it in a waste beaker.
  2. Add ~2 mL of 1% crystal violet (see Table of Materials) in 50% ethanol to each well to stain the plaques.
    NOTE: It is not essential to remove every last drop of the overlay.
  3. Incubate the plate with all wells filled with the stain for 30 min at 37 °C. At this point, disinfect the waste beaker as above in step 3.8.
  4. Wash the plates vigorously with tap water until the runoff is clear.
    NOTE: A gentle stream of water is not vigorous enough; full pressure from a lab sink fixture is required.
  5. At this point, ensure that there are approximately 10-fold differences in the number of plaques across each dilution series.
  6. Allow the plates to dry overnight upside down, after which the individual plaques may be counted.

5. Counting plaques and determining virus titer

  1. Regardless of the approach (see NOTE below), multiply the number of plaques by the dilution factor (e.g., if the plaques were counted in the 10-4 well, then the number of plaques would be multiplied by 104).
    NOTE: Although counting within a range of 10-100 plaques is useful5, counting wells with 30-300 plaques is somewhat more reliable and takes into account approximately ½-log dilutions instead of full-log dilutions.
  2. Divide this number by the volume of inoculum (as above in step 3.2), and average all wells that have plaques within the stated range to get the most accurate titer of HSV in the original sample.
  3. Perform the calculations in steps 5.3.1 to 5.3.5, considering the use of mock data in Table 1.
    1. Consider only wells with 30-300 plaques (step 5.1). Hence, in Table 1, use only the 10-5 column for replicates 1, 2, and 3.
    2. Take the number of plaques at the given dilution and multiply by the reciprocal of the dilution factor. Hence, the 10-5 column of sample 1 goes from 81 plaques at the 10-5 dilution to 81 plaques times 105.
    3. Then divide that number by the volume (in mL) of the virus dilution added to the cells in that well. Assuming the data on HSV-1 in Table 1 are from a 12-well plate, 0.2 mL would be the most appropriate measurement. Hence the calculation from step 5.3.2 becomes 81 x 105 divided by 0.2 mL, or 4.0 x 107 PFU/mL of HSV-1.
    4. Repeat this process for all useful data and average. Hence conduct the calculation in 5.3.2-5.3.3 on all samples in the 10-5 column, assuming they originated from the same virus sample and the biological replicates were conducted to obtain the most accurate titer measurement. In the case of Table 1, average 4.0 x 107, 2.1 x 107, and 2.6 x 107 PFU/mL to obtain a final average titer of 2.9 x 107 ± 0.98 x 107 PFU/mL for this sample.

Representative Results

Table 1 shows an experiment that has optimal results. All 10-fold dilutions follow an approximately 10-fold decrease in plaque counts. These kinds of data can also be seen in Figure 2, an actual plaque assay where the countable number of plaques fell in the 10-4 range for all three replicates. The same can be seen in Figure 3, the top row, where the countable number of plaques was in the 10-3 dilution.

However, Figure 3, bottom row, shows an entirely different result when a plaque assay is not conducted well. First, there are very few plaques visible from any dilution; hence, the data are unusable. Second, there are visible areas around the top where the Vero cells have entirely lifted from the substrate, evidence either of allowing the cells to dry out in the process or of pipetting too vigorously in that region of the well.

Table 2 also shows a set of potentially aberrant outcomes in plaque counts and requires cautions along the way. Of note, neither the top row nor the bottom row of replicates follows a regular 10-fold difference in plaque counts as one moves from one dilution to the next; these data indicate user error during the virus dilution process. Furthermore, it is not likely that a user would accurately count over 15,000 plaques, so one must call those data into question. Finally, one may note that in replicate 1, 10-6 dilution, there is a plaque count in the 30-300 range; nonetheless, given the poor nature of the rest of the data in this replicate, it is unlikely that the 42 plaque count is an accurate number. Hence, the only believable data in Table 2 are in replicate 2.

Figure 4 shows the same problems with cells drying out or being mishandled during the plaque assay. However, Figure 4 critically shows poor Vero cell seeding; every well shows darker purple spots, indicative of cells not spread well across the well and piled on top of one another in clusters.

Figure 1
Figure 1: Overall plaque assay scheme. Adapted from Biorender template, "Viral Plaque Assay Protocol," by BioRender.com. Please click here to view a larger version of this figure.

Figure 2
Figure 2: Plaque assay for HSV-1 in twelve-well plates. Biological replicates were conducted as outlined in Figure 1 on one sample of HSV-1. Serial 10-fold dilutions of an HSV-1 sample (starting at the 10-2 dilution) were added to the Vero cells, incubated, then stained with crystal violet. Please click here to view a larger version of this figure.

Figure 3
Figure 3: Plaque assay for HSV-2 in six-well plates. Biological replicates were conducted as outlined in Figure 1 on one sample of HSV-2. Serial 10-fold dilutions of an HSV-2 sample (starting at the 10-2 dilution) were added to Vero cells, incubated, then stained with crystal violet. Please click here to view a larger version of this figure.

Figure 4
Figure 4: Plaque assay for HSV-1 in twelve-well plates. Biological replicates were conducted as outlined in Figure 1 on one sample of HSV-1. Serial 10-fold dilutions of an HSV-1 sample (starting at the 10-2 dilution) were added to Vero cells, incubated, then stained with crystal violet. Please click here to view a larger version of this figure.

Dilution factor
Replicate 10-3 10-4 10-5 10-6
1 5721 635 81 5
2 4592 365 42 0
3 5,519 521 53 1

Table 1: Representative plaque counts from one successful assay. Serial dilutions from each biological replicate were conducted; representative plaque counts (starting at the 10-3 dilution) are shown for each dilution.

Dilution factor
Replicate 10-3 10-4 10-5 10-6
1 15225 635 450 42
2 4592 365 42 0
3 5519 5400 53 1

Table 2: Representative plaque counts from one unsuccessful assay. Serial dilutions from each biological replicate were conducted; representative plaque counts (starting at the 10-3 dilution) are shown for each dilution.

Discussion

While plaque assays are almost as old as mammalian cell culture itself, it seems that each lab has its own set of protocols to execute this basic assay5,6,10,11,12,13,14,15,16,20. Although the instructions in each published version of a plaque assay differ ever so slightly, few of these manuscripts elucidate the critical nuances involved in obtaining consistent results.

Hence, there are some parts of this protocol that are more art than science. When Vero cells are seeded in wells for the assay, they must be spread evenly throughout the well (Figure 4). All steps involving a liquid transfer (e.g., steps 3.1, 3.2, 3.5, 3.6, 4.1, and 4.2) must be done carefully to keep the Vero cell monolayer hydrated (Figure 3 and Figure 4). It is also crucial not to touch the bottom of the well with any pipette, or the cells may scrape off, further compromising the final data (Figure 4).

While methylcellulose is advantageous as an overlay material to prevent diffusion of virions across the entire well, alternatives may be used. For example, one may use microcrystalline cellulose21,22 or carboxymethyl cellulose21. Regardless, methylcellulose is one of the easiest and least expensive liquid overlay media to use, though. One may also use a different dye21 or fixing solution (e.g., paraformaldehyde)21 for the staining part of the protocol (step 4), but crystal violet in 50% ethanol is the easiest and least expensive among the options.

While it may be overtly straightforward to conduct these assays, they do require training and practice. It is well worth using samples that are not irreplaceable for learning this method so that one has mastered the technique when it matters most.

Plaque assays themselves should only be used, though, when one needs to count bona fide live virions. Plaquing is a much older methodology to measure virus particles5,10 compared to newer quantitative methods like fluorescence microscopy23, ELISA24, enzymatic activity25,26, or qPCR27. However, these latter methods generate surrogate data that suggest the presence of whole virions, yet may lead to a gross overestimate in viable particles because the user would be quantifying an indicator of infection, not real virions. Fluorescence microscopy measures infectious virions by how many cells exhibit the presence of a protein expressed by the virus but does not necessarily detect complete, replication-competent virions. ELISA similarly detects the presence of virus proteins that may exist without an utterly infectious virion. Assaying enzymatic activity, while suggestive of an intact virion, only shows that a single active enzyme is present and does not reflect the true contagious nature of a whole virion. And qPCR merely quantifies copies of a virus' genome, whether that genome is defective or not. The only method comparable to a plaque assay to quantify live viruses is an endpoint dilution assay28, which still requires a statistical estimation via the Reed-Muench or Spearman-Kärber methods29,30,31 to determine virion concentration.

While plaque assays are a routine method used throughout virology, there are particular cases where they are not the quantitative assay of choice. For example, plaque assays require host cells to attach to a substrate; if the best host cell for infection is non-adherent, plaques will never form32. Some viruses grow more slowly than the typical cell cycle of their hosts, and therefore any burgeoning plaques would be overgrown by the host cells themselves21. Plaques may sometimes not form well, just by the nature of the cytopathic effect, making the determination of bona fide plaques a limitation21.

The approach to plaquing herpesviruses presented here is not necessarily unique. However, this in-depth description of the minor caveats associated with a successful HSV plaque assay may diminish the difficulties experienced by many users, especially novices. Regardless, the methodology described is also broadly applicable to plaque assays with many other viruses, including but not limited to picornaviruses33, orthomyxoviruses34, flaviruses35, coronaviruses36, and many other systems in which a quantifiable amount of infectious animal viruses are required.

Disclosures

The authors have nothing to disclose.

Acknowledgements

We thank countless students in our labs (PJD and BJM) who have worked with us over the years refining these methods. A special thanks to Stan Person, under whose tutelage this methodology was first developed. This work was partially supported by the Towson University Fisher College of Science and Math Undergraduate Research Support fund and NIGMS Bridges to the Baccalaureate grant 5R25GM058264. This content is solely the authors' responsibility and does not necessarily represent the official views of the National Institutes of Health's National Institute of General Medical Sciences.

Materials

12-well plates Corning 3512
6-well plates Corning 3516
Alpha-MEM Lonza 12169F
Antibiotic/antimycotic Gibco 15240096
Crystal violet Alfa Aesar B2193214
DMEM Gibco 11965092
Dulbecco's PBS (no Mg++ or Ca++) Gibco 14190144
Fetal calf serum Millipore-Sigma TMS-013-B
L-alanyl-L-glutamine (Glutamax) Gibco GS07F161BA
Hemacytometer Thermo Fisher 02-671-54
Methylcellulose Millipore-Sigma 27-441-0
Quaternary agent (Lysol I.C.) Thermo Fisher NC9645698
Trypan Blue Corning 25900CI
Trypsin Cytiva SH30042.01
Vero cells ATCC CCL-81

References

  1. Dimmock, N., Easton, A., Leppard, K. . Introduction to Moden Virology. 6th end. , (2007).
  2. Mahy, B., Collier, L. . Topley and Wilson’s Microbiology and Microbial Infections. 9th edn. 1, (1998).
  3. Anderson, B., et al. Enumeration of bacteriophage particles: Comparative analysis of the traditional plaque assay and real-time QPCR- and nanosight-based assays. Bacteriophage. 1 (2), 86-93 (2011).
  4. Earle, W. R., et al. Production of malignancy in vitro; IV. The mouse fibroblast cultures and changes seen in the living cells. Journal of the National Cancer Institute. 4 (2), 165-212 (1943).
  5. Dulbecco, R., Vogt, M. Some problems of animal virology as studied by the plaque technique. Cold Spring Harbor Symposia on Quantitative Biology. 18, 273-279 (1953).
  6. Enders, J. F., Weller, T. H., Robbins, F. C. Cultivation of the lansing strain of poliomyelitis virus in cultures of various human embryonic tissues. Science. 109 (2822), 85-87 (1949).
  7. Enders, J. F. Cytopathology of virus infections: particular reference to tissue culture studies. Annual Review of Microbiology. 8, 473-502 (1954).
  8. Roizman, B., Knipe, D. M., Whitley, R. J., Knipe, D. M., et al. . Fields Virology. 1, 1823-1897 (2013).
  9. Madavaraju, K., Koganti, R., Volety, I., Yadavalli, T., Shukla, D. Herpes simplex virus cell entry mechanisms: An update. Frontiers in Cellular and Infection Microbiology. 10, 617578 (2020).
  10. Cooper, P. D. The plaque assay of animal viruses. Advances in Virus Research. 8, 319-378 (1961).
  11. Farnham, A. E. The formation of microscopic plaques by herpes simplex virus in HeLa cells. Virology. 6 (2), 317-327 (1958).
  12. Garabedian, G. A., Scott, L. V. Plaque assay for herpes simplex virus in L-929 (Earle) mouse fibroblasts. Proceedings of the Society for Experimental Biology and Medicine. 126 (2), 568-571 (1967).
  13. Lancz, G. J. Herpes simplex viruses types 1 and 2. Type and strain specific characteristics affecting virus plaque formation. Arch Gesamte Virusforsch. 46 (1-2), 36-43 (1974).
  14. Muratore, O., Tonoli, E. L., Pesce Schito, A. A short-term plaque assay for antiviral drug research on herpes simplex virus type 2. New Microbiologica. 19 (3), 257-261 (1996).
  15. Sato, S., Kaneki, H., Shirai, J., Takahashi, K., Kawana, R. Differentiation of herpes simplex virus types 1 and 2 by plaque appearances on semicontinuous rabbit lens epithelial cells in the clinical laboratory. Kansenshogaku Zasshi. 67 (6), 561-573 (1993).
  16. Yazaki, S., Taniguchi, S., Yoshino, K. Improvement of the plaque assay of herpes simplex virus in HeLa cells. Japanese Jouranl of Microbiology. 10 (3), 133-139 (1966).
  17. Stanners, C. P., Eliceiri, G. L., Green, H. Two types of ribosome in mouse-hamster hybrid cells. Nature New Biology. 230 (10), 52-54 (1971).
  18. Giannasca, N. J., Suon, J. S., Evans, A. C., Margulies, B. J. Matrix-based controlled release delivery of acyclovir from poly-(ethylene co-vinyl acetate) rings. Journal of Drug Delivery Science and Technology. 55, 101391 (2020).
  19. Freshney, R. I. . Culture of Animal Cells: A Manual of Basic Technique and Specialized Applications. 7th edn. , (2016).
  20. Dulbecco, R. Production of plaques in monolayer tissue cultures by single particles of an animal virus. Proceedings of the National Academy of Science, USA. 38 (8), 747-752 (1952).
  21. Baer, A., Kehn-Hall, K. Viral concentration determination through plaque assays: using traditional and novel overlay systems. Journal of Visualized Experiments. (93), e52065 (2014).
  22. Matrosovich, M., Matrosovich, T., Garten, W., Klenk, H. D. New low-viscosity overlay medium for viral plaque assays. Virology Journal. 3, 63 (2006).
  23. Culley, S., Towers, G. J., Selwood, D. L., Henriques, R., Grove, J. Infection counter: Automated quantification of in vitro virus replication by fluorescence microscopy. Viruses. 8 (7), 201 (2016).
  24. Hudu, S. A., et al. Quantitative Hepatitis B e antigen: A better predictor of Hepatitis B virus DNA than quantitative Hepatitis B surface antigen. Clinical Laboratory. 64 (4), 443-449 (2018).
  25. Baltimore, D. RNA-dependent DNA polymerase in virions of RNA tumour viruses. Nature. 226 (5252), 1209-1211 (1970).
  26. Scolnick, E. M., Aaronson, S. A., Todaro, G. J., Parks, W. P. RNA dependent DNA polymerase activity in mammalian cells. Nature. 229 (5283), 318-321 (1971).
  27. Strick, L. B., Wald, A. Diagnostics for herpes simplex virus: is PCR the new gold standard. Molecular Diagnosis and Therapy. 10 (1), 17-28 (2006).
  28. Ramakrishnan, M. A. Determination of 50% endpoint titer using a simple formula. World Jouranl of Virology. 5 (2), 85-86 (2016).
  29. Kärber, G. Beitrag zue kollektiven Behandlung pharmakologischer pharmakologischer Reihenversuche. Archiv for Experimentelle Pathologie und Pharmakologie. 162 (4), 480-487 (1931).
  30. Reed, L. J., Muench, H. A simple method of estimating fifty percent endpoints. American Journal of Hygiene. 27 (3), 493-497 (1938).
  31. Spearman, C. The Method of ‘Right and Wrong Cases’ (Constant Stimuli) without Gauss’s formula. British Journal of Psychology. 2 (3), 227-242 (1908).
  32. Ryu, W. -. S. . Molecular Virology of Human Pathogenic Viruses. 1st edn. , (2017).
  33. Burrill, C. P., Strings, V. R., Andino, R. Poliovirus: generation, quantification, propagation, purification, and storage. Current Protocols in Microbiology. , (2013).
  34. Karakus, U., Crameri, M., Lanz, C., Yanguez, E. Propagation and titration of influenza viruses. Methods in Molecular Biology. 1836, 59-88 (2018).
  35. Baz, M. Zika virus isolation, purification, and titration. Methods in Molecular Biology. 2142, 9-22 (2020).
  36. Coleman, C. M., Frieman, M. B. Growth and quantification of MERS-CoV infection. Current Protocols in Microbiology. 37 (1), 1-9 (2015).

Play Video

Cite This Article
Sadowski, L. A., Lesko, G. M., Suissa, C., Upadhyay, R., Desai, P. J., Margulies, B. J. Plaquing of Herpes Simplex Viruses. J. Vis. Exp. (177), e62962, doi:10.3791/62962 (2021).

View Video