Overlapping effector interfaces define the multiple functions of the HIV-1 Nef polyproline helix

HIV-1 Nef is a multifunctional protein required for full pathogenicity of the virus. As Nef has no known enzymatic activity, it necessarily functions through protein-protein interaction interfaces. A critical Nef protein interaction interface is centered on its polyproline segment (P69VRPQVPLRP78) w...

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Bibliographic Details
Published in:Retrovirology 2012-05, Vol.9 (1), p.47-47, Article 47
Main Authors: Kuo, Lillian S, Baugh, Laura L, Denial, Sarah J, Watkins, Richard L, Liu, Mingjie, Garcia, J Victor, Foster, John L
Format: Article
Language:English
Subjects:
Adaptation, Biological
Amino Acid Motifs
Arginine - chemistry
Blotting, Western
CD4
Genes, MHC Class I
HEK293 Cells
HeLa Cells
HIV Infections - virology
HIV-1
HIV-1 - chemistry
HIV-1 - genetics
HIV-1 - pathogenicity
Humans
MHC class I
Mutation
Nef
nef Gene Products, Human Immunodeficiency Virus - chemistry
p21-activated protein kinase
Peptides - chemistry
Proline - chemistry
Protein Binding
Protein Interaction Mapping
Protein-protein interaction interface
SH3 domain
src Homology Domains
Transfection
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Summary:HIV-1 Nef is a multifunctional protein required for full pathogenicity of the virus. As Nef has no known enzymatic activity, it necessarily functions through protein-protein interaction interfaces. A critical Nef protein interaction interface is centered on its polyproline segment (P69VRPQVPLRP78) which contains the helical SH3 domain binding protein motif, PXXPXR. We hypothesized that any Nef-SH3 domain interactions would be lost upon mutation of the prolines or arginine of PXXPXR. Further, mutation of the non-motif "X" residues, (Q73, V74, and L75) would give altered patterns of inhibition for different Nef/SH3 domain protein interactions. We found that mutations of either of the prolines or the arginine of PXXPXR are defective for Nef-Hck binding, Nef/activated PAK2 complex formation and enhancement of virion infectivity (EVI). Mutation of the non-motif "X" residues (Q, V and L) gave similar patterns of inhibition for Nef/activated PAK2 complex formation and EVI which were distinct from the pattern for Hck binding. These results implicate an SH3 domain containing protein other than Hck for Nef/activated PAK2 complex formation and EVI. We have also mutated Nef residues at the N-and C-terminal ends of the polyproline segment to explore interactions outside of PXXPXR. We discovered a new locus GFP/F (G67, F68, P69 and F90) that is required for Nef/activated PAK2 complex formation and EVI.MHC Class I (MHCI) downregulation was only partially inhibited by mutating the PXXPXR motif residues, but was fully inhibited by mutating the C-terminal P78. Further, we observed that MHCI downregulation strictly requires G67 and F68. Our mutational analysis confirms the recently reported structure of the complex between Nef, AP-1 μ1 and the cytoplasmic tail of MHCI, but does not support involvement of an SH3 domain protein in MHCI downregulation. Nef has evolved to be dependent on interactions with multiple SH3 domain proteins. To the N- and C- terminal sides of the polyproline helix are multifunctional protein interaction sites. The polyproline segment is also adapted to downregulate MHCI with a non-canonical binding surface. Our results demonstrate that Nef polyproline helix is highly adapted to directly interact with multiple host cell proteins.
ISSN:1742-4690
1742-4690
DOI:10.1186/1742-4690-9-47