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Abstract
Despite a number of recent therapeutic advancements, there remains an urgent need to develop a new class of therapy for human immunodeficiency virus (HIV). This review summarises attempts at blocking HIV binding and entry into host cells, an approach that would provide theoretical advantages over the currently available drugs targeting enzymes (reverse transcriptase and protease), brought into play in the later stages of the viral life cycle. The multi-step process of HIV entry into cells, binding of the surface glycoprotein (gp120) to the CD4 receptor and one of the chemokine receptors, followed by the membrane fusion step mediated by the transmembrane glycoprotein (gp41), has recently been understood with greater clarity. The importance of the chemokine co-receptors, such as CCR5 and CXCR4, for HIV entry may help to explain the limitations of earlier approaches using recombinant soluble CD4 or polyanionic compounds to interfere non-specifically with HIV glycoprotein function. Conversely, previous investigations demonstrating the in vitro inhibitory potential of beta chemokines themselves, or small-molecule chemokine receptor inhibitors, may now be understood in a new light. Promising laboratory investigations (particularly with the bicyclam compound, AMD3100) and extensive pharmaceutical experience with related chemical structures suggest great potential for targeting the chemokine nexus. Finally, the evolution of transmembrane peptide investigations from the laboratory to early clinical trials is described. Clinical trials of T-20, a peptide designed to inhibit gp-41 mediated fusion, have provided ‘proof of concept’ that therapeutics targeting a viral entry event can result in safe and potent inhibition of viral replication. The author speculates on the future prospect of using novel therapeutic strategies aimed at the initial interactions between HIV and target cells, in the battle against AIDS.