Yeast surface display platform for rapid discovery of conformationally selective nanobodies

McMahon, Conor; Baier, Alexander; Pascolutti, Roberta; Wegrecki, Marcin; Zheng, Sanduo; Ong, Janice X.; Erlandson, Sarah C.; Hilger, Daniel; Rasmussen, Søren G. F.; Ring, Aaron M.; Manglik, Aashish; Kruse, Andrew C.

doi:10.1038/s41594-018-0028-6

Cited by 404 publications

(474 citation statements)

References 36 publications

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“…As a consequence, OrthoRep readily integrates with the existing rich ecosystem of cell-based and in vivo yeast genetic selections. For example, OrthoRep is already being used in our lab and others to evolve novel antibodies via yeast surface display (Boder and Wittrup, 1997; McMahon et al, 2018), protein-protein interactions (PPIs) or PPI inhibitors via yeast two-hybrid systems (Fields and Song, 1989), and heterologous metabolic enzymes like Pf DHFR that can replace essential yeast functions. The last of these applications may be especially useful in efforts to create humanized yeast models (Kachroo et al, 2015; Truong and Boeke, 2018) or to improve enzymes from difficult-to-transform hosts like plants.…”

Section: Discussionmentioning

confidence: 99%

Scalable, Continuous Evolution of Genes at Mutation Rates above Genomic Error Thresholds

Ravikumar

Arzumanyan

Obadi

et al. 2018

Cell

205

202

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Summary Directed evolution is a powerful approach for engineering biomolecules and understanding adaptation. However, experimental strategies for directed evolution are notoriously laborintensive and low-throughput, limiting access to demanding functions, multiple functions in parallel, and the study of molecular evolution in replicate. We report OrthoRep, an orthogonal DNA polymerase-plasmid pair in yeast that stably mutates ~100,000-fold faster than the host genome in vivo, exceeding the error threshold of genomic replication that causes singlegeneration extinction. User-defined genes in OrthoRep continuously and rapidly evolve through serial passaging, a highly straightforward and scalable process. Using OrthoRep, we evolved drug-resistant malarial DHFRs in 90 independent replicates. We uncovered a more complex fitness landscape than previously realized, including common adaptive trajectories constrained by epistasis, rare outcomes that avoid a frequent early adaptive mutation, and a suboptimal fitness peak that occasionally traps evolving populations. OrthoRep enables a new paradigm of routine, high-throughput evolution of biomolecular and cellular function.

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Section: Discussionmentioning

confidence: 99%

Scalable, Continuous Evolution of Genes at Mutation Rates above Genomic Error Thresholds

Ravikumar

Arzumanyan

Obadi

et al. 2018

Cell

205

202

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“…[15] Thus,t he targeted delivery of platinum drugs will both improve therapeutic effects and reduce systemic toxicity. [17] Thesmall size and spatial structure endow Nb with the capability of epitope recognition with high affinity and specificity,even when target antigens are densely packed and cryptic. [17] Thesmall size and spatial structure endow Nb with the capability of epitope recognition with high affinity and specificity,even when target antigens are densely packed and cryptic.…”

mentioning

confidence: 99%

“…[16] AD NA nanocarrier with active targeting groups may be an ideal platform for targeted platinum-drug delivery.T he camelid-derived singledomain antibody,r eferred to as an anobody (Nb), is the smallest (about 15 kDa) among all types of antibody analogues. [17,18] After antigen recognition, Nbs can subsequently block signal transduction of at arget receptor to inhibit proliferation for combined therapy. [17,18] After antigen recognition, Nbs can subsequently block signal transduction of at arget receptor to inhibit proliferation for combined therapy.…”

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confidence: 99%

A Nanobody‐Conjugated DNA Nanoplatform for Targeted Platinum‐Drug Delivery

et al. 2019

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The targeted delivery of chemotherapeutic drugs is amajor challenge in the clinical treatment of cancer.Herein, we constructed amultifunctional DNAnanoplatform as aversatile carrier of the highly potent platinum-based DNAintercalator, 56MESS.I no ur rational design, 56MESS was efficiently loaded into the double-bundle DNAt etrahedron through intercalation with the DNAd uplex. With the integration of an anobody that both targets and blocks epidermal growth factor receptor (EGFR), the DNAn anocarriers exhibit excellent selectivity for cells with elevated EGFR expression (a common biomarker related to tumor formation) and combined tumor therapyw ithout obvious systemic toxicity. This DNA-based platinum-drug delivery system provides apromising strategy for the treatment of tumors.

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“…Nanobodies fold into their native and functional structure once secreted at the surface of bacterial or yeast cells and nanobody display have been used for both screening purposes and for preparing wholecell biosensors [88][89][90][91]. The advantages represented by displaying functional macromolecules on cell surface are multiple and have been…”

Section: Cell Displaymentioning

confidence: 99%

Recombinant expression of nanobodies and nanobody-derived immunoreagents

Marco

2020

Protein Expression and Purification

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A B S T R A C TAntibody fragments for which the sequence is available are suitable for straightforward engineering and expression in both eukaryotic and prokaryotic systems. When produced as fusions with convenient tags, they become reagents which pair their selective binding capacity to an orthogonal function. Several kinds of immunoreagents composed by nanobodies and either large proteins or short sequences have been designed for providing inexpensive ready-to-use biological tools. The possibility to choose among alternative expression strategies is critical because the fusion moieties might require specific conditions for correct folding or posttranslational modifications. In the case of nanobody production, the trend is towards simpler but reliable (bacterial) methods that can substitute for more cumbersome processes requiring the use of eukaryotic systems. The use of these will not disappear, but will be restricted to those cases in which the final immunoconstructs must have features that cannot be obtained in prokaryotic cells. At the same time, bacterial expression has evolved from the conventional procedure which considered exclusively the nanobody and nanobody-fusion accumulation in the periplasm. Several reports show the advantage of cytoplasmic expression, surface-display and secretion for at least some applications. Finally, there is an increasing interest to use as a model the short nanobody sequence for the development of in silico methodologies aimed at optimizing the yields, stability and affinity of recombinant antibodies.

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Yeast surface display platform for rapid discovery of conformationally selective nanobodies

Cited by 404 publications

References 36 publications

Scalable, Continuous Evolution of Genes at Mutation Rates above Genomic Error Thresholds

Scalable, Continuous Evolution of Genes at Mutation Rates above Genomic Error Thresholds

A Nanobody‐Conjugated DNA Nanoplatform for Targeted Platinum‐Drug Delivery

Recombinant expression of nanobodies and nanobody-derived immunoreagents

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