The present invention relates to -PNA monomers according to Formula I where substituent groups R.sub.1, R.sub.2, R.sub.3, R.sub.4, R.sub.5, R.sub.6, B and P are defined as set forth in the specification. The invention also provides methodology for synthesizing compounds according to Formula I and methodology for synthesizing PNA oligomers that incorporate one or more Formula I monomers.

The present invention relates to -PNA monomers according to Formula I where substituent groups R.sub.1, R.sub.2, R.sub.3, R.sub.4, R.sub.5, R.sub.6, B and P are defined as set forth in the specification. The invention also provides methodology for synthesizing compounds according to Formula I and methodology for synthesizing PNA oligomers that incorporate one or more Formula I monomers.

The present invention relates to conjugates of a protein drug and two or more P/A peptides, and pharmaceutical compositions comprising them. The conjugates of the invention exhibit an advantageously reduced immunogenicity as compared to the respective unmasked protein drugs as well as a favorable safety and tolerability profile, which render them particularly suitable for therapeutic use. The conjugates further show an enhanced plasma half-life and, thus, a prolonged duration of action as compared to the respective unmasked protein drugs, which allows for a reduction in the dosing frequency and, thus, side-effect burden. The invention also provides processes of preparing such conjugates as well as activated P/A peptides that are useful as synthetic intermediates in the preparation of the conjugates.

Disclosed is a new process and intermediates for preparing dipyrrolidine peptide compounds such as, for example, rapastinel. Advantageously, the process may be industrially scalable and cost-effective and use less toxic reagents and/or solvents. Further, the process may be used to prepare peptide compounds having improved purity.

Disclosed is a new process and intermediates for preparing dipyrrolidine peptide compounds such as, for example, rapastinel. Advantageously, the process may be industrially scalable and cost-effective and use less toxic reagents and/or solvents. Further, the process may be used to prepare peptide compounds having improved purity.

The present invention provides a method for making uncapped cysteine protein preparations, including uncapped engineered cysteine antibody preparations. The methods include, inter alia, contacting a reducing agent with engineered cysteine antibody molecules, each of the antibody molecules having at least one capped engineered cysteine residue and at least one interchain disulfide bond and reacting the reducing agent with the antibody molecules under conditions sufficient to uncap engineered cysteine residues and form cap byproducts. The method also includes removing the cap byproduct during the reduction reaction. Substantially all of the interchain disulfide bonds present in the antibody molecules prior to reduction are retained following reduction. Antibody conjugates and methods for preparing antibody conjugates using uncapped antibody preparations are also described.

The present disclosure relates to site-selective labeling compounds, and methods of using such compounds.

Systems and processes for performing solid phase peptide synthesis are generally described. Solid phase peptide synthesis is a known process in which amino acid residues are added to peptides that have been immobilized on a solid support. In certain embodiments, the inventive systems and methods can be used to perform solid phase peptide synthesis quickly while maintaining high yields. Certain embodiments relate to processes and systems that may be used to heat, transport, and/or mix reagents in ways that reduce the amount of time required to perform solid phase peptide synthesis.

Systems and processes for performing solid phase peptide synthesis are generally described. Solid phase peptide synthesis is a known process in which amino acid residues are added to peptides that have been immobilized on a solid support. In certain embodiments, the inventive systems and methods can be used to perform solid phase peptide synthesis quickly while maintaining high yields. Certain embodiments relate to processes and systems that may be used to heat, transport, and/or mix reagents in ways that reduce the amount of time required to perform solid phase peptide synthesis.

Disclosed herein are formulations, substrates, and arrays for amino acid and peptide synthesis on microarrays. In certain embodiments, methods for manufacturing and using the formulations, substrates, and arrays including one-step coupling, e.g., for synthesis of peptides in a C.fwdarw.N orientation are disclosed. In some embodiments, disclosed herein are formulations and methods for high efficiency coupling of biomolecules to a substrate.