Discovery, Merrimack Pharmaceuticals, Inc, Cambridge, Massachusetts, USA.
Research & Development, Diagonal Therapeutics, Cambridge, Massachusetts, USA.
MAbs. 2022 Jan-Dec;14(1):2083466. doi: 10.1080/19420862.2022.2083466.
Antibody-directed nanotherapeutics (ADNs) represent a promising delivery platform for selective delivery of an encapsulated drug payload to the site of disease that improves the therapeutic index. Although both single-chain Fv (scFv) and Fab antibody fragments have been used for targeting, no platform approach applicable to any target has emerged. scFv can suffer from intrinsic instability, and the Fabs are challenging to use due to native disulfide over-reduction and resulting impurities at the end of the conjugation process. This occurs because of the close proximity of the disulfide bond connecting the heavy and light chain to the free cysteine at the C-terminus, which is commonly used as the conjugation site. Here we show that by engineering an alternative heavy chain-light chain disulfide within the Fab, we can maintain efficient conjugation while eliminating the process impurities and retaining stability. We have demonstrated the utility of this technology for efficient ADN delivery and internalization for a series of targets, including EphA2, EGFR, and ErbB2. We expect that this technology will be broadly applicable for targeting of nanoparticle encapsulated payloads, including DNA, mRNA, and small molecules.
抗体导向的纳米疗法 (ADN) 代表了一种有前途的药物传递平台,可将封装的药物有效载荷选择性递送至疾病部位,从而提高治疗指数。尽管单链 Fv (scFv) 和 Fab 抗体片段都已被用于靶向,但没有出现适用于任何靶点的平台方法。scFv 可能存在固有不稳定性,而 Fab 由于天然二硫键过度还原和偶联过程末端的杂质而难以使用。这是因为连接重链和轻链的二硫键与 C 末端的游离半胱氨酸非常接近,而 C 末端通常用作偶联位点。在这里,我们展示了通过在 Fab 内工程设计替代的重链-轻链二硫键,我们可以在消除过程杂质的同时保持高效偶联并保持稳定性。我们已经证明了这项技术对于一系列靶点(包括 EphA2、EGFR 和 ErbB2)的高效 ADN 递释和内化的实用性。我们预计这项技术将广泛适用于包括 DNA、mRNA 和小分子在内的纳米颗粒封装有效载荷的靶向。
