HHV capsid portal protein

HHV Capsid Portal Protein, or HSV-1 U_L-6 protein, is the protein which forms a cylindrical portal in the capsid of Herpes simplex virus (HSV-1). The protein is commonly referred to as the HSV-1 U_L-6 protein because it is the transcription product of Herpes gene U_L-6.

HHV capsid portal protein
Identifiers
Organism	?
Symbol	UL6
UniProt	P10190
Search for Structures Swiss-model Domains InterPro

The Herpes viral DNA enters and exits the capsid via the capsid portal. The capsid portal is formed by twelve copies of portal protein arranged as a ring; the proteins contain a leucine zipper sequence of amino acids which allow them to adhere to each other.^[1] Each icosahedral capsid contains a single portal, located in one vertex.^[2][3]

The portal is formed during initial capsid assembly and interacts with scaffolding proteins that construct the procapsid.^{[4] [5] [6]} When the capsid is nearly complete, the viral DNA enters the capsid (i.e., the DNA is encapsidated) by a mechanism involving the portal and a DNA-binding protein complex similar to bacteriophage terminase.^[7] Multiple studies suggest an evolutionary relationship between Capsid Portal Protein and bacteriophage portal proteins.^[2][7]

When a virus infects a cell, it is necessary for the viral DNA to be released from the capsid. The Herpes virus DNA exits through the capsid portal.^[8]

The genetic sequence of HSV-1 gene U_L-6 is conserved across the family Herpesviridae and this family of genes is known as the "Herpesvirus UL6-like" gene family.^[9] "U_L-6" is nomenclature meaning that the protein is genetically encoded by the sixth (6th) open reading frame found in the viral genome segment named "Unique-Long (U_L)".

Studies

Studies by amino acid sequence location
pUL-6 Amino acid range	Summary	Reference
E121, A618, Q621	Point mutations confer resistance to portal assembly inhibitor WAY-150138	van Zeijl, et al., 2000[10]
198-295	Deletion mutant forms immature B-capsids with no portals	Nellissery, et al., 2007[3]
322-416	Deletion mutants form immature B-capsids which do contain portals	Nellissery, et al., 2007[3]
409-473
L429, L436	Mutation studies suggest putative leucine zipper required for portal ring formation	Nellissery, et al., 2007[3]
R676	Carboxyl (C)-terminal end	NCBI Sequence[11]
pUL-26.5 "Scaffolding protein" Amino acid range	Summary	Reference
143-151	Deletion inhibits UL-6 portal assembly	Singer, et al., 2005[6]

Dodecameric structure

Research performed in 2004 used electron microscopy to predict that U_L-6 forms 11, 12, 13, and 14-unit polymers. The dodecameric form was found to be most likely.^[2]

Refinements to the electron microscopy in 2007 allowed finding that the portal is a twelve (12)-unit polymer present at one of the twelve capsid vertices instead of the U_L-19 pentamer found at non-portal vertices.^[1]

Leucine zipper creates inter-protein adhesion

A study using deletion and mutation of the U_L-6 amino acid sequence demonstrated the leucine residues in a predicted leucine zipper motif were required for formation of the dodecameric ring structure.^[3]

Early involvement in capsid assembly

Assembly of portal units is an initial step in constructing capsids of viral progeny. Capsids assembled in the absence of portals lack portals.^[4]

Interaction with capsid scaffolding protein

In 2003, gel eletrophoresis studies demonstrated that intact U_L-6 portals associate in vitro with viral protein U_L-26. This association is antagonized by that action of WAY-150138, a thiourea inhibitor of HHV encapsidation.^[5]

Further investigation during 2006 showed that assembly of capsid with portal depends on interaction of U_L-6 with "scaffolding" protein U_L-26.5, amino acids 143 through 151.^[6]

Interaction with terminase complex

U_L-6 associates with a U_L-15/U_L-28 protein complex during capsid assembly. The U_L-15/U_L-28 is believed to bind with viral DNA and serve the same purpose as terminase by packing viral DNA into the capsid during capsid assembly.^[7]

Function during DNA egress

The DNA exits the capsid in a single linear segment. DNA exit may be controlled by U_L-6 and dependent on temperature or environmental proteins.^[8]

References

1. Cardone G, Winkler DC, Trus BL, Cheng N, Heuser JE, Newcomb WW, Brown JC, Steven AC (2007-05-10). "Visualization of the herpes simplex virus portal in situ by cryo-electron tomography". Virology. 361 (2): 426–34. doi:10.1016/j.virol.2006.10.047. PMC 1930166. PMID 17188319.
2. Trus BL, Cheng N, Newcomb WW, Homa FL, Brown JC, Steven AC (November 2004). "Structure and polymorphism of the UL6 portal protein of herpes simplex virus type 1". Journal of Virology. 78 (22): 12668–71. doi:10.1128/JVI.78.22.12668-12671.2004. PMC 525097. PMID 15507654.(Article: [1])
3. Nellissery JK, Szczepaniak R, Lamberti C, Weller SK (2007-06-20). "A putative leucine zipper within the HSV-1 UL6 protein is required for portal ring formation". Journal of Virology. 81 (17): 8868–77. doi:10.1128/JVI.00739-07. PMC 1951442. PMID 17581990.
4. Newcomb WW, Homa FL, Brown JC (August 2005). "Involvement of the portal at an early step in herpes simplex virus capsid assembly". Journal of Virology. 79 (16): 10540–6. doi:10.1128/JVI.79.16.10540-10546.2005. PMC 1182615. PMID 16051846.
5. Newcomb WW, Thomsen DR, Homa FL, Brown JC (September 2003). "Assembly of the herpes simplex virus capsid: identification of soluble scaffold-portal complexes and their role in formation of portal-containing capsids". Journal of Virology. 77 (18): 9862–71. doi:10.1128/JVI.77.18.9862-9871.2003. PMC 224603. PMID 12941896. (Article: [2])
6. Singer GP, Newcomb WW, Thomsen DR, Homa FL, Brown JC (2005). "Identification of a region in the herpes simplex virus scaffolding protein required for interaction with the portal". Journal of Virology. 79 (1): 132–9. doi:10.1128/JVI.79.1.132-139.2005. PMC 538710. PMID 15596809.
7. White CA, Stow ND, Patel AH, Hughes M, Preston VG (June 2003). "Herpes Simplex Virus Type 1 Portal Protein UL6 Interacts with the Putative Terminase Subunits UL15 and UL28". Journal of Virology. 77 (11): 6351–8. doi:10.1128/JVI.77.11.6351-6358.2003. PMC 154995. PMID 12743292.
8. Newcomb WW, Booy FP, Brown JC (2007-05-13). "Uncoating the Herpes Simplex Virus Genome". Journal of Molecular Biology. 370 (4): 633–42. doi:10.1016/j.jmb.2007.05.023. PMC 1975772. PMID 17540405.
9. Herpesvirus UL6 like Conserved Domains view at NCBI
10. Marja van Zeijl; Jeanette Fairhurst; Thomas R. Jones; Steven K. Vernon; John Morin; James LaRocque; Boris Feld; Bryan O'Hara; Jonathan D. Bloom; Stephen V. Johann (October 2000). "Novel Class of Thiourea Compounds That Inhibit Herpes Simplex Virus Type 1 DNA Cleavage and Encapsidation: Resistance Maps to the UL6 Gene". Journal of Virology. 74 (19): 9054–9061. doi:10.1128/JVI.74.19.9054-9061.2000. PMC 102102. PMID 10982350.
11. HSV-1 U_L-6 amino acid sequence at NCBI