Abstract
We have applied small angle x-ray scattering and protein cross-linking coupled with mass spectrometry to determine the architectures of full-length HIV integrase (IN) dimers in solution. By blocking interactions that stabilize either a core-core domain interface or N-terminal domain intermolecular contacts, we show that full-length HIV IN can form two dimer types. One is an expected dimer, characterized by interactions between two catalytic core domains. The other dimer is stabilized by interactions of the N-terminal domain of one monomer with the C-terminal domain and catalytic core domain of the second monomer as well as direct interactions between the two C-terminal domains. This organization is similar to the "reaching dimer" previously described for wild type ASV apoIN and resembles the inner, substrate binding dimer in the crystal structure of the PFV intasome. Results from our small angle x-ray scattering and modeling studies indicate that in the absence of its DNA substrate, the HIV IN tetramer assembles as two stacked reaching dimers that are stabilized by core-core interactions. These models of full-length HIV IN provide new insight into multimer assembly and suggest additional approaches for enzyme inhibition.
Highlights
No full-length structure of HIV integrase alone has been reported
We have applied small angle x-ray scattering and protein cross-linking coupled with mass spectrometry to determine the architectures of full-length HIV integrase (IN) dimers in solution
Our enzymatic assays showed that single viral DNA end processing and joining activities were unaffected in the presence of 1 M urea; concerted integration into a target DNA was unaffected by 250 mM urea, and this activity was still detectable in 1 M urea (Fig. 2, B–D)
Summary
No full-length structure of HIV integrase alone has been reported. Results: We elucidated the architectures of dimers and tetramers of full-length HIV-1 integrase in solution. Results from our small angle x-ray scattering and modeling studies indicate that in the absence of its DNA substrate, the HIV IN tetramer assembles as two stacked reaching dimers that are stabilized by corecore interactions. These models of full-length HIV IN provide new insight into multimer assembly and suggest additional approaches for enzyme inhibition. The arrangement of monomers in the ASV IN reaching dimer structure resembles that of the inner dimer of the PFV intasome that engages the viral and target DNA substrates and catalyzes the concerted joining reaction. Insight into the modes of assembly of apoIN, we analyzed the solution structure of HIV IN using approaches that proved successful with the ASV IN protein
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