Welcome to the Recombinant Antibody Network

@article{pmid38594044,

title = {Structural Survey of Antigen Recognition by Synthetic Human Antibodies},

author = {Maryna Gorelik and Shane Miersch and Sachdev S Sidhu},

doi = {10.1101/pdb.over107759},

issn = {1559-6095},

year  = {2025},

date = {2025-02-01},

urldate = {2025-02-01},

journal = {Cold Spring Harb Protoc},

volume = {2025},

number = {2},

pages = {pdb.over107759},

abstract = {Synthetic antibody libraries have been used extensively to isolate and optimize antibodies. To generate these libraries, the immunological diversity and the antibody framework(s) that supports it outside of the binding regions are carefully designed/chosen to ensure favorable functional and biophysical properties. In particular, minimalist, single-framework synthetic libraries pioneered by our group have yielded a vast trove of antibodies to a broad array of antigens. Here, we review their systematic and iterative development to provide insights into the design principles that make them a powerful tool for drug discovery. In addition, the ongoing accumulation of crystal structures of antigen-binding fragment (Fab)-antigen complexes generated with synthetic antibodies enables a deepening understanding of the structural determinants of antigen recognition and usage of immunoglobulin sequence diversity, which can assist in developing new strategies for antibody and library optimization. Toward this, we also survey here the structural landscape of a comprehensive and unbiased set of 50 distinct complexes derived from these libraries and compare it to a similar set of natural antibodies with the goal of better understanding how each achieves molecular recognition and whether opportunities exist for iterative improvement of synthetic libraries. From this survey, we conclude that despite the minimalist strategies used for design of these synthetic antibody libraries, the overall structural interaction landscapes are highly similar to natural repertoires. We also found, however, some key differences that can help guide the iterative design of new synthetic libraries via the introduction of positionally tailored diversity.},

keywords = {},

pubstate = {published},

tppubtype = {article}

}

@article{pmid39865354,

title = {Engineered protein G variants for multifunctional antibody-based assemblies},

author = {Tomasz Slezak and Kelly M O'Leary and Jinyang Li and Ahmed Rohaim and Elena K Davydova and Anthony A Kossiakoff},

doi = {10.1002/pro.70019},

issn = {1469-896X},

year  = {2025},

date = {2025-02-01},

urldate = {2025-02-01},

journal = {Protein Sci},

volume = {34},

number = {2},

pages = {e70019},

abstract = {We have developed a portfolio of antibody-based modules that can be prefabricated as standalone units and snapped together in plug-and-play fashion to create uniquely powerful multifunctional assemblies. The basic building blocks are derived from multiple pairs of native and modified Fab scaffolds and protein G (PG) variants engineered by phage display to introduce high pair-wise specificity. The variety of possible Fab-PG pairings provides a highly orthogonal system that can be exploited to perform challenging cell biology operations in a straightforward manner. The simplest manifestation allows multiplexed antigen detection using PG variants fused to fluorescently labeled SNAP-tags. Moreover, Fabs can be readily attached to a PG-Fc dimer module which acts as the core unit to produce plug-and-play IgG-like assemblies, and the utility can be further expanded to produce bispecific analogs using the "knobs into holes" strategy. These core PG-Fc dimer modules can be made and stored in bulk to produce off-the-shelf customized IgG entities in minutes, not days or weeks by just adding a Fab with the desired antigen specificity. In another application, the bispecific modalities form the building block for fabricating potent bispecific T-cell engagers (BiTEs), demonstrating their efficacy in cancer cell-killing assays. Additionally, the system can be adapted to include commercial antibodies as building blocks, greatly increasing the target space. Crystal structure analysis reveals that a few strategically positioned interactions engender the specificity between the Fab-PG variant pairs, requiring minimal changes to match the scaffolds for different possible combinations. This plug-and-play platform offers a user-friendly and versatile approach to enhance the functionality of antibody-based reagents in cell biology research.},

keywords = {},

pubstate = {published},

tppubtype = {article}

}

@article{pmid39322765,

title = {Structural insights into translocation and tailored synthesis of hyaluronan},

author = {Ireneusz Górniak and Zachery Stephens and Satchal K Erramilli and Tomasz Gawda and Anthony A Kossiakoff and Jochen Zimmer},

doi = {10.1038/s41594-024-01389-1},

issn = {1545-9985},

year  = {2025},

date = {2025-01-01},

urldate = {2025-01-01},

journal = {Nat Struct Mol Biol},

volume = {32},

number = {1},

pages = {161--171},

abstract = {Hyaluronan (HA) is an essential component of the vertebrate extracellular matrix. It is a heteropolysaccharide of N-acetylglucosamine (GlcNAc) and glucuronic acid (GlcA) reaching several megadaltons in healthy tissues. HA is synthesized and translocated in a coupled reaction by HA synthase (HAS). Here, structural snapshots of HAS provide insights into HA biosynthesis, from substrate recognition to HA elongation and translocation. We monitor the extension of a GlcNAc primer with GlcA, reveal the coordination of the uridine diphosphate product by a conserved gating loop and capture the opening of a translocation channel to coordinate a translocating HA polymer. Furthermore, we identify channel-lining residues that modulate HA product lengths. Integrating structural and biochemical analyses suggests an avenue for polysaccharide engineering based on finely tuned enzymatic activity and HA coordination.},

keywords = {},

pubstate = {published},

tppubtype = {article}

}