Mouse-human heterokaryons support efficient human immunodeficiency virus type 1 assembly.

Murine cells do not support human immunodeficiency virus type 1 (HIV-1) replication because of blocks to virus entry, proviral expression, and virion assembly. In murine 3T3 fibroblasts, the block to HIV-1 entry is relieved by the introduction of human CD4 and CCR5 or CXCR4, and proviral expression is increased by the introduction of the Tat cofactor, human cyclin T1; however, because of the assembly block, virus fails to spread. A panel of rodent cell lines expressing human CD4, CCR5, and cyclin T1 was established and studied for the ability to support virus replication. Mus musculus lymphoid cell lines EL4 and L1-2 and Mus dunni fibroblasts supported only low levels of virus assembly and released small amounts of infectious virus. CHO and Rat2 cell lines produced more infectious virus, but this production was still 40-fold lower than production in human cells. Only CHO cells expressing the three human cofactors were partially permissive for HIV-1 replication. To investigate the basis of the block to HIV-1 assembly, mouse-human heterokaryons were tested for ability to assemble and release virus. Fusion of human cells to HIV-1-infected mouse cells expressing CD4, CCR5, and cyclin T1 caused a 12-fold increase in virion release and a 700-fold increase in infectious virus production. Fusion of HIV-1-infected M. dunni tail fibroblasts to uninfected human cells caused a similar increase in virus release. More efficient virus release was not caused by increased proviral transcription or increased synthesis of virion components. Analysis of reciprocal heterokaryons suggested the absence of an inhibitor of virus assembly. Taken together, the results suggested that murine fibroblasts lack a cofactor that is required for efficient virus assembly and release.

Aminooxypentane addition to the chemokine macrophage inflammatory protein-1alpha P increases receptor affinities and HIV inhibition.

To enter its target cells, human immunodeficiency virus (HIV) must interact with CD4 and one of a family of chemokine receptors. CCR5 is widely used by the virus in this context, and its ligands can prevent HIV entry. Amino-terminal modified chemokine variants, in particular AOP-RANTES (aminooxypentane-linked regulated on activation normal T cell expressed and secreted), exhibit enhanced HIV entry inhibition. We have previously demonstrated that a non-allelic isoform of macrophage inflammatory protein (MIP)-1alpha, termed MIP-1alphaP, is the most active naturally occurring inhibitor of HIV entry known. Here we report the properties of a variant of MIP-1alphaP with an AOP group on the amino terminus. We show that, like RANTES, the addition of AOP to MIP-1alphaP enhances its interactions with CCR1 and CCR5, allows more effective internalization of CCR5, and increases the ligand's potency as an inhibitor of HIV entry through CCR5. Importantly, AOP-MIP-1alphaP is about 10-fold more active than AOP-RANTES at inhibiting HIV entry, making it the most effective chemokine-based inhibitor of HIV entry through CCR5 described to date. Surprisingly, the enhanced receptor interactions of AOP-MIP-1alphaP do not translate into increased chemotaxis or coupling to calcium ion fluxes, suggesting that this protein should be viewed as a partial, rather than a full, agonist for CCR1 and CCR5.