Rapid and low-cost multiplex synthesis of chemokine analogs.

Peptides represent a promising source of new medicines, but improved technologies are needed to facilitate discovery and optimization campaigns. In particular, longer peptides with multiple disulfide bridges are challenging to produce, and producing large numbers of structurally related variants is dissuasively costly and time-consuming. The principal cost and time drivers are the multiple column chromatography purification steps that are used during the multistep chemical synthesis procedure, which involves both ligation and oxidative refolding steps. In this study, we developed a method for multiplex parallel synthesis of complex peptide analogs in which the structurally variant region of the molecule is produced as a small peptide on a 384-well synthesizer with subsequent ligation to the longer, structurally invariant region and oxidative refolding carried out in-well without any column purification steps. To test the method, we used a panel of 96 analogs of the chemokine RANTES (regulated on activation normal T cell expressed and secreted)/CCL5 (69 residues, two disulfide bridges), which had been synthesized using standard approaches and characterized pharmacologically in an earlier study. Although, as expected, the multiplex method generated chemokine analogs of lower purity than those produced in the original study, it was nonetheless possible to closely match the pharmacological attributes (anti-HIV potency, capacity to elicit G protein signaling, and capacity to elicit intracellular receptor sequestration) of each chemokine analog to reference data from the earlier study. This rapid, low-cost approach has the potential to support discovery and optimization campaigns based on analogs of other chemokines as well as those of other complex peptide and small protein targets of a similar size.

Chemical synthesis of a two-photon-activatable chemokine and photon-guided lymphocyte migration in vivo.

Chemokine-guided lymphocyte positioning in tissues is crucial for normal operation of the immune system. Direct, real-time manipulation and measurement of single-cell responses to chemokines is highly desired for investigating the cell biology of lymphocyte migration in vivo. Here we report the development of the first two-photon-activatable chemokine CCL5 through efficient one-pot total chemical synthesis in milligram scale. By spatiotemporally controlled photoactivation, we show at the single-cell level that T cells perceive the directional cue without relying on PI3K activities, which are nonetheless required for persistent migration over an extended period of time. By intravital imaging, we demonstrate artificial T-cell positioning in cutaneous tissues and lymph nodes. This work establishes a general strategy to develop high-quality photo-activatable protein agents through tailor-designed caging of multiple residues and highlights the potential of photo-activatable chemokines for understanding and potential therapeutic manipulation of cell positioning and position-controlled cell behaviours in vivo.

Molecular engineering of RANTES peptide mimetics with potent anti-HIV-1 activity.

The chemokine receptor CCR5 is utilized as a critical coreceptor by most primary HIV-1 strains. While the lack of structural information on CCR5 has hampered the rational design of specific inhibitors, mimetics of the chemokines that naturally bind CCR5 can be molecularly engineered. We used a structure-guided approach to design peptide mimetics of the N-loop and ß1-strand regions of regulated on activation normal T-cell-expressed and secreted (RANTES)/CCL5, which contain the primary molecular determinants of HIV-1 blockade. Rational modifications were sequentially introduced into the N-loop/ß1-strand sequence, leading to the generation of mimetics with potent activity against a broad spectrum of CCR5-specific HIV-1 isolates (IC(50) range: 104-640 nM) but lacking activity against CXCR4-specific HIV-1 isolates. Functional enhancement was initially achieved with the stabilization of the N loop in the ß-extended conformation adopted in full-length RANTES, as confirmed by nuclear magnetic resonance (NMR) analysis. However, the most dramatic increase in antiviral potency resulted from the engraftment of an in silico-optimized linker segment designed using de novo structure-prediction algorithms to stabilize the C-terminal α-helix and experimentally validated by NMR. Our mimetics exerted CCR5-antagonistic effects, demonstrating that the antiviral and proinflammatory functions of RANTES can be uncoupled. RANTES peptide mimetics provide new leads for the development of safe and effective HIV-1 entry inhibitors.

The synergy of ChemMatrix resin and pseudoproline building blocks renders RANTES, a complex aggregated chemokine.

Traditionally, solid-phase synthesis has relied on polystyrene-based resins for the synthesis of all kinds of peptides. However, due to their high hydrophobicity, these resins have certain limitations, particularly in the synthesis of complex peptides, and in such cases, poly(ethylene glycol) (PEG)-based resins are often found to give superior results. Another powerful strategy for expediting the assembly of complex peptides is to employ pseudoproline dipeptides. These derivatives disrupt the interactions among chains that are usually the cause of poor coupling yields in aggregated sequences. Here we report on an efficient stepwise solid-phase synthesis of RANTES (1-68) by combining the advantages of the totally PEG-based ChemMatrix resin and pseudoproline dipeptides.

Medicinal chemistry applied to a synthetic protein: development of highly potent HIV entry inhibitors.

We have used total chemical synthesis to perform high-resolution dissection of the pharmacophore of a potent anti-HIV protein, the aminooxypentane oxime of [glyoxylyl1]RANTES(2-68), known as AOP-RANTES, of which we designed and made 37 analogs. All involved incorporation of one or more rationally chosen nonnatural noncoded structures, for which we found a clear comparative advantage over coded ones. We investigated structure-activity relationships in the pharmacophore by screening the analogs for their ability to block the HIV entry process and produced a derivative, PSC-RANTES [N-nonanoyl, des-Ser1[L-thioproline2, L-cyclohexylglycine3]-RANTES(2-68)], which is 50 times more potent than AOP-RANTES. This promising group of compounds might be optimized yet further as potential prophylactic and therapeutic anti-HIV agents. The remarkable potency of our RANTES analogs probably involves the unusual mechanism of intracellular sequestration of CC-chemokine receptor 5 (CCR5), and it has been suggested that this arises from enhanced affinity for the receptor. We found that inhibitory potency and capacity to induce CCR5 down-modulation do appear to be correlated, but that unexpectedly, inhibitory potency and affinity for CCR5 do not. We believe this study represents the proof of principle for the use of a medicinal chemistry approach, above all one showing the advantage of noncoded structures, to the optimization of the pharmacological properties of a protein. Medicinal chemistry of small molecules is the foundation of modern pharmaceutical practice, and we believe we have shown that techniques have now reached the point at which the approach could also be applied to the many macromolecular drugs now in common use.

A new approach to the chemical synthesis of keto-proteins.

To increase the versatility of protein-conjugation, an orthogonal protection strategy is described, which enables the efficient synthesis of keto-proteins bearing a reactive ketone functionality using Boc, Fmoc, and chemical ligation methodologies. A 1,3-dithiolane group was used to protect the ketone function of levulinate- and pyruvate-derivatized peptides during solid-phase synthesis, acidolytic cleavage, and purification. When required, the 1,3-dithiolane group could be cleanly removed using aqueous silver or mercuric solutions to regenerate the reactive keto-protein at ambient temperature. The liberated keto-protein was chemoselectively conjugated in situ to an aminooxy-derivatized monodisperse polymer.

Covalent capture: a new tool for the purification of synthetic and recombinant polypeptides.

BACKGROUND: Purification of polypeptides and proteins derived from recombinant DNA techniques and of long synthetic polypeptides often represents a challenge. Affinity methods exist, but generally require addition of a large recognition unit to the target protein and use of expensive purification media. Use of large units is dictated by the characteristics of non-covalent complexes, where the energy necessary to form the complex derives from the sum of multiple weak energy interactions. Covalent interactions in contrast are of high energy, even when only a few bonds are formed. We decided to explore the use of the reversible covalent bond formed between N-terminal cysteine and threonine residues with an aldehyde as a method of protein purification. RESULTS: A series of test peptides with N-terminal cysteine and threonine were captured by a polyethyleneglycol-polyacrylamide resin to which an aldehyde function had been grafted. Peptides with other amino acids at the N-terminus did not interact with the resin. A recombinant polypeptide with N-terminal cysteine was purified to 90% purity in one step. Polypeptides were eluted from the resin simply by adding a hydroxylamine derivative, which reacts with aldehyde functions to form an oxime. CONCLUSIONS: Polypeptides possessing N-terminal cysteine or threonine can be easily purified using this 'covalent capture' approach.

Structural and functional analysis of the RANTES-glycosaminoglycans interactions.

Chemokines mediate their biological activity through activation of G protein coupled receptors, but most chemokines, including RANTES, are also able to bind glycosaminoglycans (GAGs). Here, we have investigated, by site-directed mutagenesis and chemical acetylation, the role of RANTES basic residues in the interaction with GAGs using surface plasmon resonance kinetic analysis. Our results indicate that (i) RANTES exhibited selectivity in GAGs binding with highest affinity (K(d) = 32.1 nM) for heparin, (ii) RANTES uses the side chains of residues R44, K45, and R47 for heparin binding, and blocking these residues in combination abolished heparin binding. The biological relevance of RANTES-GAGs interaction was investigated in CHO-K1 cells expressing CCR5, CCR1, or CCR3 and the various GAGs that bind RANTES. Our results indicate that the heparin binding site, defined as the 40s loop, is only marginally involved in CCR5 binding and activation, but largely overlaps the CCR1 and CCR3 binding and activation domain in RANTES. In addition, enzymatic removal of cell surface GAGs by glycosidases did not affect CCR5 binding and Ca(2+) response. Furthermore, addition of soluble GAGs inhibited both CCR5 binding and functional response, with a rank of potency similar to that found in surface plasmon resonance experiments. Thus, cell surface GAGs is not a prerequisite for receptor binding or signaling, but soluble GAGs can inhibit the binding and the functional response of RANTES to CCR5 expressing cells. However, the marked selectivity of RANTES for different GAGs may serve, in vivo, to control the concentration of specific chemokines in inflammatory situations and locations.

An efficient solid-phase strategy for the construction of chemokines.

Synthesis of chemokines via stepwise SPPS approaches has been shown to be a challenge. Herein, a complete study of different coupling methods, solvents and temperature combined with a continuous-flow synthesizer equipped with feedback monitoring was carried out. The results from this study indicate that this family of molecules can be prepared using an Fmoc/Bu(t) chemical approach and provide a general method to apply for the elongation of other difficult sequences.

Highly potent RANTES analogues either prevent CCR5-using human immunodeficiency virus type 1 infection in vivo or rapidly select for CXCR4-using variants.

The natural ligands for the CCR5 chemokine receptor, macrophage inflammatory protein 1alpha (MIP-1alpha), MIP-1beta, and RANTES (regulated on T-cell activation, normal T-cell expressed and secreted), are known to inhibit human immunodeficiency virus (HIV) entry, and N-terminally modified RANTES analogues are more potent than native RANTES in blocking infection. However, potent CCR5 blocking agents may select for HIV-1 variants that use alternative coreceptors at less than fully inhibitory concentrations. In this study, two N-terminal chemical modifications of RANTES produced by total synthesis, aminooxypentane (AOP)-RANTES[2-68] and N-nonanoyl (NNY)-RANTES[2-68], were tested for their ability to prevent HIV-1 infection and to select for coreceptor switch variants in the human peripheral blood lymphocyte-SCID mouse model. Mice were infected with a CCR5-using HIV-1 isolate that requires only one or two amino acid substitutions to use CXCR4 as a coreceptor. Even though it achieved lower circulating concentrations than AOP-RANTES (75 to 96 pM as opposed to 460 pM under our experimental conditions), NNY-RANTES was more effective in preventing HIV-1 infection. However, in a subset of treated mice, these levels of NNY-RANTES rapidly selected viruses with mutations in the V3 loop of envelope that altered coreceptor usage. These results reinforce the case for using agents that block all significant HIV-1 coreceptors for effective therapy.

Chemical synthesis and characterization of chemokine RANTES and its analogues.

RANTES, a polypeptide of 68 amino acid residues, is a member of the C-C chemokine subfamily including other monocyte chemoattractants such as MIP-1alpha, MIP-1beta, MCP-1, MCP-2 and MCP-3. To provide a chemically defined RANTES in quantity suitable for structure-function studies, RANTES and its analogues were synthesized, using a modified solid-phase chemistry approach. The fully protected RANTES and RANTES(3-68) were assembled by automated solid-phase methodology using Fmoc chemistry. Deprotection and cleavage of the resin bound peptides yielded crude peptides, which were then folded and further purified by reverse-phase HPLC. The chemically synthesized RANTES with its identity and purity established, was found to be immunochemically and functionally indistinguishable from the recombinant human RANTES. RANTES and its analog, RANTES(3-68), have recently been used as the substrate in the study of dipeptidyl peptidase IV (CD26)-mediated processing of RANTES and its effect on receptor specificity.

Total chemical synthesis and high-resolution crystal structure of the potent anti-HIV protein AOP-RANTES.

BACKGROUND: RANTES is a CC-type chemokine protein that acts as a chemoattractant for several kinds of leukocytes, playing an important pro-inflammatory role. Entry of human immunodeficiency virus-1 (HIV-1) into cells depends on the chemokine receptor CCR5. RANTES binds CCR5 and inhibits HIV-1 entry into peripheral blood cells. Interaction with chemokine receptors involves a distinct set of residues at the amino terminus of RANTES. This finding was utilized in the development of a chemically modified aminooxypentane derivative of RANTES, AOP-RANTES, that was originally produced from the recombinant protein using semisynthetic methods. RESULTS: AOP-RANTES has been produced by a novel total chemical synthesis that provides efficient, direct access to large amounts of this anti-HIV protein analog. The crystal structure of chemically synthesized AOP-RANTES has been solved and refined at 1.6 A resolution. The protein is a dimer, with the amino-terminal pentane oxime moiety clearly defined. CONCLUSIONS: Total chemical synthesis of AOP-RANTES provides a convenient method of producing the multi-milligram quantities of this protein needed to investigate the molecular basis of receptor binding and antiviral activity. This work provides the first truly high-resolution structure of a RANTES protein, although the structure of RANTES was known from previous nuclear magnetic resonance (NMR) determinations.

Synthetic full-length and truncated RANTES inhibit HIV-1 infection of primary macrophages.

OBJECTIVE: To determine the effect of beta-chemokines on HIV-1 infection of primary macrophages, and to search for chemokine derivatives devoid of biological effects but efficient at protecting CD4+ T lymphocytes and macrophages against HIV-1. DESIGN: Use of chemically synthesized molecules devoid of biological contaminants and monocyte-derived macrophages from healthy donors. METHODS: Full-length RANTES was chemically synthesized together with three derivatives, truncated of seven, eight and nine amino acids at the amino-terminus ([8-68]RANTES, [9-68]RANTES and [10-68]RANTES), which were tested for their biological activity and antiviral effects. RESULTS: Whereas full-length and truncated RANTES derivatives bound to beta-chemokine receptor CCR-5 with the same affinity as recombinant RANTES, the truncated forms were not chemotactic and acted as CCR-5 antagonists in this respect, although a partial agonist effect was noted on cell metabolism. Full-length RANTES and [8-68]RANTES protected T lymphocytes and macrophages from infection by HIV-1, although 10-fold higher concentrations of the truncated analogues were necessary to achieve the same effect as full-length RANTES. With regard to the effect of RANTES on HIV-1 infection of primary macrophages, our results contrast with most previously reported data. CONCLUSION: These data indicate that through binding to CCR-5, truncated RANTES derivatives that are devoid of detectable biological effects may represent candidates as drugs to protect both lymphocytes and macrophages from HIV- 1.