Anti-HIV-1 peptides derived from partial amino acid sequences of CC-chemokine RANTES. Regulated upon activation, normal T-cell expressed and secreted

Leveraging the therapeutic, biological, and self-assembling potential of peptides for the treatment of viral infections

Peptides and peptide-based materials have an increasing role in the treatment of viral infections through their use as active pharmaceutical ingredients, targeting moieties, excipients, carriers, or structural components in drug delivery systems. The discovery of peptide-based therapeutic compounds, coupled with the development of new stabilization and formulation strategies, has led to a resurgence of antiviral peptide therapeutics over the past two decades. The ability of peptides to bind cell receptors and to facilitate membrane penetration and subsequent intracellular trafficking enables their use in various antiviral systems for improved targeting efficiency and treatment efficacy. Importantly, the self-assembly of peptides into well-defined nanostructures provides a vast library of discrete constructs and supramolecular biomaterials for systemic and local delivery of antiviral agents. We review here the recent progress in exploiting the therapeutic, biological, and self-assembling potential of peptides, peptide conjugates, and their supramolecular assemblies in treating human viral infections, with an emphasis on the treatment strategies for Human Immunodeficiency Virus (HIV).

Rational design of novel HIV-1 entry inhibitors by RANTES engineering

The discovery that the CC chemokines RANTES, MIP-1alpha and MIP-1beta act as potent natural inhibitors of HIV-1, the causative agent of AIDS, and the subsequent identification of CCR5 as a major virus coreceptor have triggered a wealth of basic and applied research approaches aimed at developing safe and effective viral entry inhibitors. Some of these efforts have focused on RANTES engineering with the goal of enhancing the antiviral activity of the native molecule while reducing or abrogating its inflammatory properties. The wavefront generated a decade ago is still on its course, with a flow of promising leads constantly emerging and being evaluated in preclinical studies. Here, we present an overview of this rapidly evolving field, highlighting the most important features of RANTES molecular architecture and structure-function relationships.

Analogues of N-terminal truncated synthetic peptide fragments derived from RANTES inhibit HIV-1 infectivity

A series of synthetic peptide fragments derived from RANTES were designed, synthesized, and evaluated to determine the effect of N-terminal truncation on the ability of the lead compound Ac[Ala(10,11)]RANTES-(1-14)NH(2) to inhibit HIV-1 infectivity. Both the lead compound and the truncated analogue Ac[Ala(10,11)]RANTES-(3-14)NH(2) were able to significantly inhibit HIV-1 infectivity. These results suggest that a small synthetic peptide may be able to mimic RANTES and have the ability to prevent transmission of HIV-1.