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Go go gadget glycoprotein!: HSV-1 draws on its sizeable glycoprotein tool kit to customize its diverse entry routes

Introduction: Viruses deploy diverse entry strategies

All viruses must enter cells to replicate [1]. Entry is thus the first hurdle a virus must overcome for a successful infection. Given the astonishing diversity of viruses that infect mammals alone—hundreds of thousands of different viruses according to some estimates [2]—it is unsurprising that their entry routes into cells are just as diverse. A major structural distinction that dictates the entry mode is the presence or absence of a lipid bilayer surrounding the viral nucleocapsid, which defines a virus as enveloped or nonenveloped, respectively. Nonenveloped viruses enter cells by endocytosis and subsequently penetrate the endosomal membrane by a variety of mechanisms including pore formation and endosomal fragmentation due to disruptive changes in membrane curvature [3], whereas all enveloped viruses must fuse their envelope with a host cell membrane: either the plasma membrane or the membrane of the endosomal vesicle following cellular uptake [4].

Regardless of the entry route, all viruses initially attach to the surface of the host cell by binding a cellular receptor. After attachment, enveloped viruses must employ fusogens—specialized viral surface glycoproteins that mediate the merger of the viral and host membranes by bringing them together as they undergo large, energetically favorable conformational changes. To do this, a spring-loaded fusogen must be triggered once the virus arrives at the right cell and/or the right intracellular compartment (such as an endosome, for example), either by binding a receptor (or a coreceptor) or by sensing the acidic pH of the endosome [4]. In many enveloped viruses, the receptor-binding and the fusogenic functions are mediated by different domains of a single glycoprotein. For example, the human immunodeficiency virus (HIV) envelope protein, Env, the sole glycoprotein encoded by HIV, binds the cellular glycoprotein cluster of differentiation 4 (CD4) and a coreceptor, C-X-C chemokine receptor 4 (CXCR4) or C-C chemokine receptor 5 (CCR5), on the surface of CD4+ T cells and also serves as the fusogen [5]. The influenza virus glycoprotein hemagglutinin binds an attachment receptor, sialic acid, and undergoes low-pH-triggered fusogenic conformational changes upon endocytosis [6]. In some cases, for example, in paramyxoviruses, the receptor-binding and the fusogenic functions are mediated by separate glycoproteins, and the fusogen receives the triggering signal from the receptor-binding viral protein [7]. Most enveloped viruses thus contain multiple copies of only one or two glycoproteins, which mediate viral attachment and entry into target cells [515].

Yet, entry of herpesviruses—large enveloped viruses that infect a wide variety of cells—is more complex, as it requires multiple viral glycoproteins (typically, at least three) and diverse host receptors [16]. Moreover, the coordinated activity of these multiple viral glycoproteins permits entry into different cell types by different routes. Whereas in some herpesviruses, such as human cytomegalovirus (HCMV) or Epstein–Barr virus (EBV), the use of particular entry routes correlates with the involvement of specific viral glycoprotein complexes [17, 18], in other herpesviruses, notably, herpes simplex virus type 1 (HSV-1), the picture is less clear [19]. Nonetheless, the entry mechanisms of all herpesviruses into a given cell, and particularly, the selection of the entry route, are complex and incompletely understood.

The HSV-1 replication cycle in humans necessitates the infection of different cell types, chiefly, epithelial and neuronal cells. Although it is known that HSV-1 enters these cells by different mechanisms—endocytosis (epithelial cells) and fusion at the plasma membrane (neurons) [20, 21]—knowledge regarding HSV-1 glycoprotein involvement in the entry route–selection process is minimal. This raises the following question: How does HSV-1 select a particular route to enter different cell types? Although the answer remains elusive, this Pearl will summarize the current understanding of HSV-1 entry strategies and the players involved.

The HSV-1 envelope contains over a dozen proteins, but only four are required for entry

HSV-1 contains 15 viral proteins in its lipid envelope, 12 glycosylated and three unglycosylated (Fig 1B) [19]. Four of these glycosylated proteins—gD, gH, gL, and gB—are essential for entry into target cells in tissue culture and in animal models (Fig 1A) [22, 23], whereas the other 11 proteins are typically referred to as “nonessential” with regard to entry because their deletions have mild phenotypes, if any, in cell culture [2426].

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Fig 1. HSV-1 envelope proteins and their roles in entry and membrane fusion.

(A) HSV-1 entry into cells requires the coordinated efforts of the receptor-binding glycoprotein gD (RCSB PDB: 2C36), the heterodimer gH/gL (RCSB PDB: 3M1C), and the fusogen gB (RCSB PDB: 5V2S). For gB, only the structure of its postfusion conformation is known, so the prefusion conformation of HSV-1 gB is depicted schematically. Interactions of these essential proteins with cellular coreceptors can influence the entry of HSV-1 into a cell. (B) HSV-1 contains 15 proteins within its lipid envelope, 12 glycosylated (gB, gC, gD, gE [RCSB PDB: 2GIY], gG, gH, gI, gJ, gK, gL, gM, gN) and three unglycosylated (UL20, UL45, US9). The roles of the 11 “nonessential” envelope proteins, with respect to entry route selection, are minimally understood. Glycoproteins gC and gG promote entry at the apical side of polarized epithelial cells. The glycoprotein gK promotes entry into neurons by fusion at the plasma membrane. Other envelope proteins (gE, gI, gM, gN, and UL45) have roles in cell-to-cell spread and membrane fusion but have not yet been assigned any roles in entry. 3-OS-HS, 3-O-sulfated-heparan sulfate; HSV-1, herpes simplex virus type 1; HVEM, herpes virus entry mediator; PDB, Protein Data Bank; PILRα, paired immunoglobulin-like type 2 receptor alpha; RCSB, Research Collaboratory for Structural Bioinformatics.

https://doi.org/10.1371/journal.ppat.1007660.g001

HSV-1 entry into any cell requires the coordinated efforts of gD, gH, gL, and gB. It is now known that in HSV-1 the receptor-binding and the fusogenic functions are distributed among these four glycoproteins [23]. First, gB (along with another glycoprotein, gC) mediates viral attachment to cell-surface heparan sulfate proteoglycans [22]. Next, HSV-1 uses its receptor-binding glycoprotein, gD, to engage one of its three entry receptors: nectin-1, herpes virus entry mediator (HVEM), or 3-O-sulfated-heparan sulfate (3-OS-HS) (Fig 1A) [16]. Binding to its receptor triggers a conformational change within gD that causes it to bind the heterodimer gH/gL [2729]. This event, in turn, activates gB, the fusogen that mediates the merger of the HSV-1 lipid envelope with the cellular membrane [30]. gD, gH, gL, and gB are not only essential for HSV-1 entry but are also sufficient for entry of heterologous viral particles pseudotyped with these four glycoproteins [31]. Moreover, gD, gH, gL, and gB can also mediate cell–cell fusion of uninfected, receptor-bearing cells expressing these four glycoproteins [23]. Collectively, these data suggest that gD, gH, gL, and gB represent the core receptor-binding/fusogenic machinery of HSV-1. Given that gD, gH, gL, gB, and a gD receptor are required for entry regardless of cell type or entry route, how does HSV-1 choose which route to take?

In some cases, entry route depends on cell type–specific interactions of gD, gH/gL, or gB with host receptors and the HSV-1 strain [3234]. For example, HSV-1 enters nectin-1-bearing Chinese hamster ovary (CHO) cells by endocytosis, but overexpression of the cellular protein paired immunoglobulin-like type 2 receptor alpha (PILRα)—which binds gB (Fig 1A)—switches the entry route to fusion at the plasma membrane [35, 36]. Similarly, HSV-1 entry into nectin-1-bearing CHO and J cells (a baby hamster kidney [BHK] cell derivative) by endocytosis requires both dynamin and cholesterol only when integrins αvβ3, αvβ6, or αvβ8, which bind gH/gL (Fig 1A), are present [37, 38]. These studies indicate that cellular interactions with gD, gH/gL, or gB can direct the entry route or change the cellular requirements for HSV-1 entry.

“Nonessential” HSV-1 envelope proteins influence HSV-1 entry pathways and fusion-dependent processes

Given these observations, one may think that gD, gH, gL, gB, and a cellular receptor for gD are all that HSV-1 needs to enter any target cell. However, the presence of 11 additional envelope proteins (eight glycosylated and three unglycosylated) suggests that they serve important roles during infection. This notion is supported by the observation that even highly passaged tissue culture–adapted strains of HSV-1 retain these envelope protein genes [39], in contrast to herpesviruses such as HCMV, which rapidly loses certain glycoprotein genes or their portions during passaging in tissue culture [40]. Even though these proteins are not required for HSV-1 entry [2426], their interactions with cellular factors, gD, gH, gL, gB, or some combination thereof, could influence the pathway HSV-1 takes into a cell.

Indeed, several studies have revealed context-dependent contributions of the “nonessential” envelope proteins (Fig 1B). For example, initial studies of glycoprotein gK demonstrated that gK was dispensable for HSV-1 entry even though its deletion reduced entry efficiency [41], consistent with the “nonessential” designation. However, later work revealed that gK enabled HSV-1 to enter neuronal cells by fusion at the plasma membrane [42]. When the amino terminus of gK was deleted, HSV-1 switched the entry route to clathrin- and dynamin-dependent endocytosis [43], suggesting that the amino terminus of gK is essential for HSV-1 entry by fusion at the plasma membrane, in the context of neuronal cells (Fig 1B). Similar to gK, the glycoproteins gG and gC are dispensable for HSV-1 entry into non-polarized epithelial cells [25, 26]. However, under culture conditions that produce polarized epithelial cells, both gC and gG promote HSV-1 entry at the apical side of these cells, whereas entry at the basal side does not require either protein (Fig 1B) [44, 45]. This suggests that gC and gG promote HSV-1 entry either by binding some necessary apically localized host factor or by overcoming a host restriction factor that normally prevents HSV-1 entry at the apical side of a polarized epithelial cell. These studies indicate that the so-called “nonessential” glycoproteins can serve to facilitate the selection of HSV-1 entry points. In other words, these proteins may guide HSV-1 into the most efficient “entry lane”; without them, the virus would still enter cells, albeit less efficiently. In this manner, these “nonessential” proteins may serve to increase HSV-1 fitness. Although the rest of the “nonessential” envelope proteins have not yet been ascribed clear roles in HSV-1 entry pathways, they do influence membrane fusion and cell-to-cell spread of HSV-1 (Fig 1B), processes that are both important for HSV-1 pathogenesis. For example, UL45, one of the three unglycosylated envelope proteins, and the glycoproteins gM and gN promote the formation of syncytia [25, 46, 47]. Likewise, the glycoproteins gE and gI, although not essential for entry, promote cell-to-cell spread [48]. It is tempting to speculate that, given their important roles in membrane fusion and cell-to-cell spread, these five envelope proteins may also contribute to HSV-1 entry mechanisms in certain cell-specific contexts.

Conclusion

HSV-1 entry is an enigmatic process, and despite much progress over the past half century, many questions about its entry process remain. How does HSV-1 choose its pathway into a cell? What cellular factors and viral proteins govern this choice? What are the molecular mechanisms surrounding the different HSV-1 entry pathways? Currently, we know that host factor–specific interactions with HSV-1 envelope proteins seem to dictate the way HSV-1 enters a given cell. Although cell-specific interactions of the essential entry proteins (gD, gH/gL, and gB) with host factors can alter HSV-1 entry modes, “nonessential” envelope proteins have been shown to make important contributions to HSV-1 entry in specific circumstances. Just as the cartoon character Inspector Gadget has the ability to call upon any number of tools to help him defeat criminals, HSV-1 may be able to call upon a large number of envelope glycoproteins and unglycosylated proteins to help it enter receptor-bearing cells in the most efficient way. Efforts characterizing the roles of gK, gC, and gG have lent credence to the hypothesis that envelope proteins other than gD, gH/gL, and gB can influence entry pathways and therefore warrant further investigation. Our current knowledge of the roles of the essential HSV-1 glycoproteins gD, gH/gL, and gB in HSV-1 entry has greatly benefited from a multidisciplinary approach combining structural biology, cell biology, biochemistry, and genetics. These approaches are now called for in investigating the roles of the “nonessential” envelope proteins in entry. A detailed understanding of HSV-1 entry strategies will inform the development of efficacious inhibitors and vaccines.

References

  1. 1. Flint J, et al. Principles of Virology. 4th ed. Washington: American Society of Microbiology; 2015.
  2. 2. Anthony SJ, et al. A strategy to estimate unknown viral diversity in mammals. MBio. 2013; 4(5): e00598–13. pmid:24003179
  3. 3. Kumar CS, et al. Breach: Host Membrane Penetration and Entry by Nonenveloped Viruses. Trends Microbiol. 2018; 26(6): 525–537. pmid:29079499
  4. 4. Mas VM, Melero JA. Entry of Enveloped Viruses into Host Cells: Membrane Fusion, in Structure and Physics of Viruses: An Integrated Textbook. Mateu MG, editor. Dordrecht: Springer Netherlands; 2013. p. 467–487.
  5. 5. Lindemann D, Steffen I, Pohlmann S. Cellular Entry of Retroviruses. Viral Entry into Host Cells. 2013; 790: 128–149.
  6. 6. Luo M. Influenza Virus Entry. Viral Molecular Machines. 2012; 726: 201–221.
  7. 7. Palgen JL, et al. Unity in Diversity: Shared Mechanism of Entry Among Paramyxoviruses. Molecular Basis of Viral Infection. 2015; 129: 1–32.
  8. 8. Guardado-Calvo P, Rey FA. The Envelope Proteins of the Bunyavirales. Advances in Virus Research. 2017; 98: 83–118. pmid:28433053
  9. 9. Hulswit RJG, de Haan CAM, Bosch BJ. Coronavirus Spike Protein and Tropism Changes. Advances in Virus Research. 2016; 96: 29–57. pmid:27712627
  10. 10. Martin B, et al. Filovirus proteins for antiviral drug discovery: A structure/function analysis of surface glycoproteins and virus entry. Antiviral Research. 2016; 135: 1–14. pmid:27640102
  11. 11. Millet JK, Whittaker GR. Host cell proteases: Critical determinants of coronavirus tropism and pathogenesis. Virus Research. 2015; 202: 120–134. pmid:25445340
  12. 12. Regan AD, Whittaker GR. Entry of Rhabdoviruses into Animal Cells. Viral Entry into Host Cells. 2013; 790: 167–177.
  13. 13. Smit JM, et al. Flavivirus Cell Entry and Membrane Fusion. Viruses-Basel. 2011; 3(2): 160–171.
  14. 14. Vancini R, Hernandez R, Brown D. Alphavirus Entry into Host Cells. Molecular Basis of Viral Infection. 2015; 129: 33–62.
  15. 15. Watashi K, Wakita T. Hepatitis B Virus and Hepatitis D Virus Entry, Species Specificity, and Tissue Tropism. Cold Spring Harbor Perspectives in Medicine. 2015; 5(8).
  16. 16. Agelidis AM, Shukla D. Cell entry mechanisms of HSV: what we have learned in recent years. Future Virol. 2015; 10(10): 1145–1154. pmid:27066105
  17. 17. Chesnokova LS, Hutt-Fletcher LM. Epstein-Barr virus infection mechanisms. Chin J Cancer. 2014; 33(11): 545–8. pmid:25322867
  18. 18. Martinez-Martin N, et al. An Unbiased Screen for Human Cytomegalovirus Identifies Neuropilin-2 as a Central Viral Receptor. Cell. 2018; 174(5): 1158–1171 e19. pmid:30057110
  19. 19. Karasneh GA, Shukla D. Herpes simplex virus infects most cell types in vitro: clues to its success. Virol J. 2011; 8: 481. pmid:22029482
  20. 20. Miranda-Saksena M, et al. Infection and Transport of Herpes Simplex Virus Type 1 in Neurons: Role of the Cytoskeleton. Viruses. 2018; 10(2).
  21. 21. Nicola AV, et al. Herpes simplex virus type 1 enters human epidermal keratinocytes, but not neurons, via a pH-dependent endocytic pathway. J Virol. 2005; 79(12): 7609–16. pmid:15919913
  22. 22. Heldwein EE, Krummenacher C. Entry of herpesviruses into mammalian cells. Cell Mol Life Sci. 2008; 65(11): 1653–68. pmid:18351291
  23. 23. Turner A, et al. Glycoproteins gB, gD, and gHgL of herpes simplex virus type 1 are necessary and sufficient to mediate membrane fusion in a Cos cell transfection system. J Virol. 1998; 72(1): 873–5. pmid:9420303
  24. 24. Dollery SJ, et al. Role of the UL45 protein in herpes simplex virus entry via low pH-dependent endocytosis and its relationship to the conformation and function of glycoprotein B. Virus Res. 2010; 149(1): 115–8. pmid:20080138
  25. 25. Komala Sari T, et al. Contributions of herpes simplex virus 1 envelope proteins to entry by endocytosis. J Virol. 2013; 87(24): 13922–6. pmid:24109213
  26. 26. Nicola AV, Straus SE. Cellular and viral requirements for rapid endocytic entry of herpes simplex virus. J Virol. 2004; 78(14): 7508–17. pmid:15220424
  27. 27. Cocchi F, et al. The soluble ectodomain of herpes simplex virus gD contains a membrane-proximal pro-fusion domain and suffices to mediate virus entry. Proc Natl Acad Sci U S A. 2004; 101(19): 7445–50. pmid:15123804
  28. 28. Fan Q, Longnecker R, Connolly SA. Substitution of herpes simplex virus 1 entry glycoproteins with those of saimiriine herpesvirus 1 reveals a gD-gH/gL functional interaction and a region within the gD profusion domain that is critical for fusion. J Virol. 2014; 88(11): 6470–82. pmid:24672037
  29. 29. Gallagher JR, et al. Displacement of the C terminus of herpes simplex virus gD is sufficient to expose the fusion-activating interfaces on gD. J Virol. 2013; 87(23): 12656–66. pmid:24049165
  30. 30. Atanasiu D, et al. Regulation of Herpes Simplex Virus gB-Induced Cell-Cell Fusion by Mutant Forms of gH/gL in the Absence of gD and Cellular Receptors. Mbio. 2013; 4(2).
  31. 31. Rogalin HB, Heldwein EE. Characterization of Vesicular Stomatitis Virus Pseudotypes Bearing Essential Entry Glycoproteins gB, gD, gH, and gL of Herpes Simplex Virus 1. J Virol. 2016; 90(22): 10321–10328. pmid:27605677
  32. 32. Nicola AV, McEvoy AM, Straus SE. Roles for endocytosis and low pH in herpes simplex virus entry into HeLa and Chinese hamster ovary cells. J Virol. 2003; 77(9): 5324–32. pmid:12692234
  33. 33. Gianni T, Campadelli-Fiume G, Menotti L. Entry of herpes simplex virus mediated by chimeric forms of nectin1 retargeted to endosomes or to lipid rafts occurs through acidic endosomes. J Virol. 2004; 78(22): 12268–76. pmid:15507614
  34. 34. Delboy MG, et al. Nectin-2-mediated entry of a syncytial strain of herpes simplex virus via pH-independent fusion with the plasma membrane of Chinese hamster ovary cells. Virol J. 2006; 3: 105. pmid:17192179
  35. 35. Arii J, et al. Entry of herpes simplex virus 1 and other alphaherpesviruses via the paired immunoglobulin-like type 2 receptor alpha. J Virol. 2009; 83(9): 4520–7. pmid:19244335
  36. 36. Satoh T, et al. PILRalpha is a herpes simplex virus-1 entry coreceptor that associates with glycoprotein B. Cell. 2008; 132(6): 935–44. pmid:18358807
  37. 37. Gianni T, Campadelli-Fiume G. alphaVbeta3-integrin relocalizes nectin1 and routes herpes simplex virus to lipid rafts. J Virol. 2012; 86(5): 2850–5. pmid:22171266
  38. 38. Gianni T, et al. alphavbeta6- and alphavbeta8-integrins serve as interchangeable receptors for HSV gH/gL to promote endocytosis and activation of membrane fusion. PLoS Pathog. 2013; 9(12): e1003806. pmid:24367260
  39. 39. Szpara ML, Parsons L, Enquist LW. Sequence variability in clinical and laboratory isolates of herpes simplex virus 1 reveals new mutations. J Virol. 2010; 84(10): 5303–13. pmid:20219902
  40. 40. Gerna G, et al. The pentameric complex of human Cytomegalovirus: cell tropism, virus dissemination, immune response and vaccine development. J Gen Virol. 2017; 98(9): 2215–2234. pmid:28809151
  41. 41. Foster TP, Rybachuk GV, Kousoulas KG. Glycoprotein K specified by herpes simplex virus type 1 is expressed on virions as a Golgi complex-dependent glycosylated species and functions in virion entry. J Virol. 2001; 75(24): 12431–8. pmid:11711633
  42. 42. Jambunathan N, et al. Site-specific proteolytic cleavage of the amino terminus of herpes simplex virus glycoprotein K on virion particles inhibits virus entry. J Virol. 2011; 85(24): 12910–8. pmid:21994443
  43. 43. Musarrat F, et al. The Amino Terminus of Herpes Simplex Virus 1 Glycoprotein K (gK) Is Required for gB Binding to Akt, Release of Intracellular Calcium, and Fusion of the Viral Envelope with Plasma Membranes. J Virol. 2018; 92(6).
  44. 44. Sears AE, McGwire BS, Roizman B. Infection of polarized MDCK cells with herpes simplex virus 1: two asymmetrically distributed cell receptors interact with different viral proteins. Proc Natl Acad Sci U S A. 1991; 88(12): 5087–91. pmid:1647025
  45. 45. Tran LC, et al. A herpes simplex virus 1 recombinant lacking the glycoprotein G coding sequences is defective in entry through apical surfaces of polarized epithelial cells in culture and in vivo. Proc Natl Acad Sci U S A. 2000; 97(4): 1818–22. pmid:10677539
  46. 46. El Kasmi I, Lippe R. Herpes simplex virus 1 gN partners with gM to modulate the viral fusion machinery. J Virol. 2015; 89(4): 2313–23. pmid:25505065
  47. 47. Haanes EJ, et al. The UL45 gene product is required for herpes simplex virus type 1 glycoprotein B-induced fusion. J Virol. 1994; 68(9): 5825–34. pmid:8057463
  48. 48. Dingwell KS, Johnson DC. The herpes simplex virus gE-gI complex facilitates cell-to-cell spread and binds to components of cell junctions. J Virol. 1998; 72(11): 8933–42. pmid:9765438