Development of tumor targeting anti-MUC-1 multimer: effects of di-scFv unpaired cysteine location on PEGylation and tumor binding

doi:10.1093/protein/gzl020

PEDS Advance Access published online on June 7, 2006
Protein Engineering Design and Selection, doi:10.1093/protein/gzl020

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© The Author 2006. Published by Oxford University Press. All rights reserved. For Permissions, please e-mail: journals.permissions@oxfordjournals.org
Received October 31, 2005
Revised March 21, 2006
Accepted March 27, 2006

Article

Development of tumor targeting anti-MUC-1 multimer: effects of di-scFv unpaired cysteine location on PEGylation and tumor binding

Cheng-Yi Xiong ¹, Arutselvan Natarajan ¹, Xu-Bao Shi ¹, Gerald L. Denardo ¹, and Sally J. Denardo ¹ ^*

¹ Department of Internal Medicine, Division of Hematology/Oncology, Section of Radiodiagnosis and Therapy, University of California Davis Cancer Center, 1508 Alhambra Boulevard, Sacramento, CA 95816, USA

^* To whom correspondence should be addressed.
Sally J. Denardo, E-mail: sjdenardo{at}ucdavis.edu

Abstract

MUC1 mucin expressed in epithelial cancer, such as prostateand breast, is aberrantly glycosylated providing unique targetsfor imaging and therapy. In order to create a broadly applicableconstruct to target these unique epitopes on metastatic cancer,we selected an antibody fragment (scFv) that binds both syntheticMUC1 core peptide and epithelial cancer cell-expressed MUC1,and developed a recombinant bivalent molecule (di-scFv). Geneticallyengineered modifications of the di-scFv were constructed tocreate five molecular versions, each having a free cysteine(di-scFv-c) at different locations for site-specific conjugation.The effects of the engineered cysteine in the varied sites werestudied relative to tumor binding and polyethylene glycol-maleimide(PEG-Mal) conjugation (PEGylation). Escherichia coli productionas well as binding to MUC1 core peptide, human tumor cell linesand human tumor biopsies, were comparable. However, the locationof the engineered cysteine in these di-scFv-c did influencePEGylation efficiency of this free thiol; higher PEGylationefficiency occurred with this cysteine in the inter-scFv linkage.Di-scFv-c PEG, with the cysteine engineered after the fifthamino acid in the linker, was used as an example to demonstratecomparable antigen-binding to non-PEGylated di-scFv-c. In summary,novel anti-MUC1 di-scFv-c molecules can be efficiently produced,purified and conjugated by site-specific PEGylation withoutloss of immunoreactivity, thus providing flexible multidentateconstructs for cancer-targeted imaging and therapy.

Keywords: di-scFv; MUC-1; PEGylation; pretargeting.

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