Delivery of polypeptides in multi-kilogram quantities within commercially competitive timelines is extremely challenging, especially when coupled with a desire to minimize environmental and economic impact. This case study explores how CPC Scientific’s advanced process improvements and efficiencies within solid-phase peptide synthesis (SPPS) have enabled multi-kilogram delivery of a pharmaceutically-relevant decapeptide within a challenging timescale, driving sustainable and cost-saving production for the client.

Our team has developed an innovative DMF recycling strategy that substantially reduces solvent consumption during solid-phase peptide synthesis. Minimizing use of DMF, a major environmental and cost contributor in peptide manufacturing, has improved process sustainability and cost efficiency. This method neatly demonstrates how targeted green chemistry practices can be successfully integrated into large-scale SPPS, supporting more environmentally responsible and economically viable peptide production.

In Part 1 of our Minimal Protection Group Strategies for SPPS, we discussed methods for eliminating sidechain protection on hydroxy-bearing amino acids such as serine, threonine, tyrosine, and hydroxyproline. By omitting t-butyl protection, we enhanced atom economy and avoided the use of hazardous solvents typically required to remove these protection groups. In Part 2, we present a new case study, expanding our approach to include the unprotected side chains of histidine, tryptophan, and arginine. We demonstrate the synthesis of a Goserelin peptide API impurity, showcasing how a convergent peptide fragment strategy can be used to eliminate the need for TFA and diethyl ether, eliminate side chain protection of Arginine, Histidine, and Tryptophan.

The synthesis of the linear RP-182 analog, bicyclo[6.1.0]non-4-yn-9-ylmethyloxycarbonyl-PEG2-Lys-Phe-Arg-Lys-Ala-Phe-Lys-Arg-Phe-Phe-Lys(azido-PEG)-NH2, was achieved using standard solid-phase peptide synthesis (SPPS) protocols. After cleaving the linear peptide from the resin, macrocyclization was performed in the liquid phase through a strain-promoted click reaction. BCN introduces extra ring strain due to its fused cyclopropane structure. The combined effect of ring strain, the selection of BCN, and copper catalysis significantly increases the macrocyclization efficiency of longer peptides like RP-182.

Stapled peptides have emerged as a powerful tool in drug discovery and therapeutic development due to their ability to overcome the limitations associated with traditional peptide drugs, such as poor stability and low cell permeability. By introducing staples into the peptide backbone, researchers can stabilize peptide conformations and enhance their interactions with target proteins, resulting in improved efficacy and specificity. This approach not only addresses the challenges of peptide drug design but also opens new avenues for targeting challenging biomolecular interactions that are difficult to modulate with small molecules or antibodies. The development of stapled peptides has led to significant advancements in targeting protein-protein interactions, addressing previously intractable diseases, and enhancing the precision of therapeutic interventions.

Peptide receptor radionuclide therapy (PRRT) is a targeted therapeutic approach that utilizes peptides to deliver cytotoxic radiation to specific receptors overexpressed on cancer cells. Peptides offer several advantages as therapeutic vectors in PRRT due to their small size, favorable pharmacokinetics, high binding affinity, low immunogenicity and toxicity, and minimal off-target effects. Tumor-targeting peptides conjugated to radionuclide chelates represent a promising class of cancer therapeutics.

Most proteinogenic peptides, except for certain hydrophobic sequences, can be synthesized in a linear fashion using solid-phase peptide synthesis (SPPS) methods. However, longer sequences, particularly those exceeding 70 amino acids, often require alternative techniques due to challenges like steric hindrance. Other issues, such as poor solvation of the protected peptide during synthesis and the formation of intermolecular hydrogen bonds (e.g., β-sheets) between fragments, can also result in inefficient coupling and deprotection.

Synthetic oligonucleotides constitute an important class of therapeutics developed to treat a variety of indications. Two main synthetic approaches exist for the conjugation of a peptide to an oligonucleotide: parallel and linear. The primary benefit of the linear approach is the one-pot solid-phase assembly and compatibility with machine automation. However, in cases where poor compatibility of peptide and oligo chemistries exist or long peptide and oligo fragments are required, preparing both components separately and linking both compounds together may offer the simplest solution.

Solid-phase peptide synthesis (SPPS) approaches require that the side chains of certain amino acids be protected from undesired reactivity during synthesis. The installation and removal of these protection groups results in a lower atom economy in the production process. Removal of the protection groups often requires large volumes of trifluoroacetic acid (TFA) or other strong acids which can result in lower yields and pose a significant risk to the environment.

The transferred energy from a fluorescent donor is converted into molecular vibrations if the acceptor is a non-fluorescent dye (quencher). When the FRET is terminated (by separating donor and acceptor), an increase of donor fluorescence can be detected. The design and synthesis work at CPC for FRET and TR-FRET peptide substrates include modification of sequences, selection of donor/quencher pairs, improvement of FRET substrate solubility and quenching efficiency.