Look-through mutagenesis (LTM) is a multidimensional mutagenesis method that simultaneously assesses and optimizes combinatorial mutations of selected amino acids. The process focuses on a precise distribution within one or more complementarity determining region (CDR) domains and explores the synergistic contribution of amino acid side-chain chemistry. LTM was applied to an anti-TNF-␣ antibody, D2E7, which is a challenging test case, because D2E7 was highly optimized (Kd ؍ 1 nM) by others. We selected and incorporated nine amino acids, representative of the major chemical functionalities, individually at every position in each CDR and across all six CDRs (57 aa). Synthetic oligonucleotides, each introducing one amino acid mutation throughout the six CDRs, were pooled to generate segregated libraries containing single mutations in one, two, and͞or three CDRs for each V H and VL domain. Corresponding antibody libraries were displayed on the cell surface of yeast. After positive binding selection, 38 substitutions in 21 CDR positions were identified that resulted in higher affinity binding to TNF-␣. These beneficial mutations in both VH and VL were represented in two combinatorial beneficial mutagenesis libraries and selected by FACS to produce a convergence of variants that exhibit between 500-and 870-fold higher affinities. Importantly, these enhanced affinities translate to a 15-to 30-fold improvement in in vitro TNF-␣ neutralization in an L929 bioassay. Thus, this LTM͞combinatorial beneficial mutagenesis strategy generates a comprehensive energetic map of the antibody-binding site in a facile and rapid manner and should be broadly applicable to the affinity maturation of antibodies and other proteins.look-through mutagenesis ͉ maturation ͉ mutagenesis ͉ TNF-␣
A new directed evolution method was used to enhance the thermostability of the wild-type GH11 xylanase 2 (known as BD-11) from Hypocrea jecorina (Trichoderma reesei). Both Look-Through Mutagenesis (LTM™), which is a method for rapidly screening selected positions in the protein sequence for amino acids that introduce favorable properties, and Combinatorial Beneficial Mutagenesis (CBM™), which is a method for identifying the best ensemble of individual mutations, were employed to enhance the stability of an enzyme that has been thoroughly engineered by various means during the past 20 years. A diverse set of novel mutations was discovered, including N71D, Y73G, T95G and Y96Q. When these mutations were combined into a single construct (Hjx-81), the purified protein was active even after heating at 100°C for 20 min. This time-effective method should be generally applicable for quickly improving the physico-chemical properties of other industrial and therapeutic enzymes in only several months time.
A highly specific AXL-receptor targeted family of non-immunoglobulin, single domain protein binders (Pronectins™) have been isolated from three (3) synthetic libraries that employ the human scaffold of the 14th domain of Fibronectin III (14FN3) and evolutionary CDRs diversity of over 25 billion loop sequences. The three libraries, each containing diversity in two loops, were designed to expand upon a human database of more than 6000 natural scaffold sequences and approximately 3000 human loop sequences. We used a bioinformatic-based approach to maximize “human” amino acid loop diversity and minimize or prevent altogether CDR immunogenicity created by the use of mutagenesis processes to generate diversity. A combination of phage display and yeast display was used to isolate 59 AXL receptor targeted Pronectins with KD ranging between 2 and 100 nM. FACS analysis with tumor cells over-expressing AXL and the use of an AXL knock-out cell line allowed us to identify Pronectin candidates with exquisite specificity for AXL receptor. Based upon several in vitro cell-based tests, we selected the best candidate, AXL54, to further characterize its in vitro cancer cells killing activity. Finally, AXL54 was used to produce the first bi-specific T cell engager protein (AXL54 [Pronectin]-linker-scFV CD3), a “new in class” protein for further testing of its anti-tumor activity in vitro and in vivo.
Genedata Biologics is a novel informatics platform specifically designed for biologics R&D. Here, we discuss the main principles employed in designing such a platform, focusing on antibody engineering. To illustrate, we present a case study of how the platform effectively supports an antibody optimization workflow and ensures the successful integration and analysis of all relevant sequence, expression, assay, and analytics data.
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