Invariant Chain Transmembrane Domain Trimerization:  A Step in MHC Class II Assembly

Dixon, Ann M.; Stanley, Bradford; Matthews, Erin; Dawson, Jessica; Engelman, Donald M.

doi:10.1021/bi052112e

Cited by 54 publications

(60 citation statements)

References 30 publications

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“…Notably, the G63V mutant was only mildly impaired, supporting our observations with the A64 mutant (Fig. 3C) and suggesting that the two N-terminal 52 GxxxG 56 and 57 GxxxG 61 motifs are important and that only Gly59 of the 59 GxxxG 63 motif is critical. Three inversion mutants, Inv55, Inv57, and Inv59, were also generated whereby select glycine res- idues were switched in position with neighboring amino acids ( Table 2).…”

Section: Resultssupporting

confidence: 88%

“…The inversion mutants disrupt GxxxG motifs by altering the primary sequence of the TM domain without affecting the chemical composition or hydrophobicity of the region. Infectivity experiments again reveal an important role for the two N-terminal 52 GxxxG 56 and 57 GxxxG 61 motifs as well as Gly59 in HPV16 infection (Fig. 3F).…”

Section: Resultsmentioning

confidence: 79%

“…3A). Upon further inspection of the primary sequence, we discovered that it contains three highly conserved GxxxG motifs, a single 52 (Fig. 3B).…”

Section: Resultsmentioning

confidence: 99%

“…A55 is predicted to be the most deleterious mutation, disturbing all the TM domain GxxxG motifs. A60 preserves the 52 GxxxG 56 motif but disrupts all downstream motifs, and A64 disrupts only the C-terminal 61 GxxxG 65 and 63 GxxxG 67 motifs. The A55 mutant was completely noninfectious, the A60 mutant had drastically reduced infectivity, and the A64 mutant had no reduction in infectivity (Fig.…”

Section: Resultsmentioning

confidence: 99%

“…3D). The severely reduced infectivity of A55 and A60 combined with the unaltered infectivity of A64 strongly suggests that only the N-terminal 52 GxxxG 56 , 57 GxxxG 61 , and 59 GxxxG 63 motifs are essential for infection. To further verify a role for these N-terminal GxxxG motifs in HPV16 infection, individual glycine-to-valine mutant viruses were generated and tested.…”

Section: Resultsmentioning

confidence: 99%

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A Transmembrane Domain and GxxxG Motifs within L2 Are Essential for Papillomavirus Infection

Bronnimann

Chapman

Park

et al. 2013

J Virol

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During cellular invasion, human papillomavirus type 16 (HPV16) must transfer its viral genome (vDNA) across the endosomal membrane prior to its accumulation at nuclear PML bodies for the establishment of infection. After cellular uptake, the capsid likely undergoes pH-dependent disassembly within the endo-/lysosomal compartment, thereby exposing hidden domains in L2 that facilitate membrane penetration of L2/vDNA complexes. In an effort to identify regions of L2 that might physically interact with membranes, we have subjected the L2 sequence to multiple transmembrane (TM) domain prediction algorithms. Here, we describe a conserved TM domain within L2 (residues 45 to 67) and investigate its role in HPV16 infection. In vitro, the predicted TM domain adopts an alpha-helical structure in lipid environments and can function as a real TM domain, although not as efficiently as the bona fide TM domain of PDGFR. An L2 double point mutant renders the TM domain nonfunctional and blocks HPV16 infection by preventing endosomal translocation of vDNA. The TM domain contains three highly conserved GxxxG motifs. These motifs can facilitate homotypic and heterotypic interactions between TM helices, activities that may be important for vDNA translocation. Disruption of some of these GxxxG motifs resulted in noninfectious viruses, indicating a critical role in infection. Using a ToxR-based homo-oligomerization assay, we show a propensity for this TM domain to self-associate in a GxxxG-dependent manner. These data suggest an important role for the self-associating L2 TM domain and the conserved GxxxG motifs in the transfer of vDNA across the endo-/lysosomal membrane.A ll nonenveloped viruses are faced with a cellular membrane barrier through which they must transfer their genetic material to establish a successful infection. These viruses behave as metastable particles, rigid enough to survive transmission through the extracellular milieu but structurally poised to undergo conformational rearrangements or partial disassembly upon encountering specific factors during cellular entry, including the engagement of host cell receptors, proteolytic and chaperone activity, and low pH of the intracellular endosomal compartment. In response to these factors, capsids rearrange to expose hidden and often hydrophobic membrane translocation domains (MTDs), thereby ensuring that the coordinated process of membrane penetration occurs only when the viral capsid has reached the appropriate intracellular locale. Through convergent evolution, viruses have become equipped with a variety of different MTDs, designed to accomplish the feat of membrane penetration in several ways (recently reviewed in reference 1). Amphipathic helices, myristoylated and/or hydrophobic peptides, and phospholipase activity have all been documented to facilitate membrane penetration through pore formation, local membrane disruption, or gross fragmentation of membranes although many molecular details of these MTD-driven activities remain obscure and are ongoing subjects of inve...

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Section: Resultssupporting

confidence: 88%

Section: Resultsmentioning

confidence: 79%

“…3A). Upon further inspection of the primary sequence, we discovered that it contains three highly conserved GxxxG motifs, a single 52 (Fig. 3B).…”

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

See 3 more Smart Citations

A Transmembrane Domain and GxxxG Motifs within L2 Are Essential for Papillomavirus Infection

Bronnimann

Chapman

Park

et al. 2013

J Virol

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Interaction and conformational dynamics of membrane‐spanning protein helices

2009

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Within 1 or 2 decades, the reputation of membrane-spanning alpha-helices has changed dramatically. Once mostly regarded as dull membrane anchors, transmembrane domains are now recognized as major instigators of protein-protein interaction. These interactions may be of exquisite specificity in mediating assembly of stable membrane protein complexes from cognate subunits. Further, they can be reversible and regulatable by external factors to allow for dynamic changes of protein conformation in biological function. Finally, these helices are increasingly regarded as dynamic domains. These domains can move relative to each other in different functional protein conformations. In addition, small-scale backbone fluctuations may affect their function and their impact on surrounding lipid shells. Elucidating the ways by which these intricate structural features are encoded by the amino acid sequences will be a fascinating subject of research for years to come.

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