13 research outputs found
Directed evolution of stabilized IgG1-Fc scaffolds by application of strong heat shock to libraries displayed on yeast
AbstractWe have constructed IgG1-Fc scaffolds with increased thermal stability by directed evolution and yeast surface display. As a basis a new selection strategy that allowed the application of yeast surface display for screening of stabilizing mutations in proteins of already high intrinsic thermal stability and Tm-values up to 85Ā°C was developed. Besides library construction by error prone PCR, strong heat stress at 79Ā°C for 10min and screening for well-folded proteins by FACS, sorting rounds had to include an efficient plasmid DNA isolation step for amplification and further transfection. We describe the successful application of this experimental setup for selection of 17 single, double and triple IgG1-Fc variants of increased thermal stability after four selection rounds. The recombinantly produced homodimeric proteins showed a wild-type-like elution profile in size exclusion chromatography as well as content of secondary structures. Moreover, the kinetics of binding of FcRn, CD16a and Protein A to the engineered Fc-molecules was very similar to the wild-type protein. These data clearly demonstrate the importance and efficacy of the presented strategy for selection of stabilizing mutations in proteins of high intrinsic stability within reasonable time
Strong Enrichment of Aromatic Residues in Binding Sites from a Charge-neutralized Hyperthermostable Sso7d Scaffold Library
The Sso7d protein from the hyperthermophilic archaeon Sulfolobus solfataricus is an attractive binding scaffold because of its small size (7 kDa), high thermal stability (Tm of 98 Ā°C), and absence of cysteines and glycosylation sites. However, as a DNA-binding protein, Sso7d is highly positively charged, introducing a strong specificity constraint for binding epitopes and leading to nonspecific interaction with mammalian cell membranes. In the present study, we report charge-neutralized variants of Sso7d that maintain high thermal stability. Yeast-displayed libraries that were based on this reduced charge Sso7d (rcSso7d) scaffold yielded binders with low nanomolar affinities against mouse serum albumin and several epitopes on human epidermal growth factor receptor. Importantly, starting from a charge-neutralized scaffold facilitated evolutionary adaptation of binders to differentially charged epitopes on mouse serum albumin and human epidermal growth factor receptor, respectively. Interestingly, the distribution of amino acids in the small and rigid binding surface of enriched rcSso7d-based binders is very different from that generally found in more flexible antibody complementarity-determining region loops but resembles the composition of antibody-binding energetic hot spots. Particularly striking was a strong enrichment of the aromatic residues Trp, Tyr, and Phe in rcSso7d-based binders. This suggests that the rigidity and small size of this scaffold determines the unusual amino acid composition of its binding sites, mimicking the energetic core of antibody paratopes. Despite the high frequency of aromatic residues, these rcSso7d-based binders are highly expressed, thermostable, and monomeric, suggesting that the hyperstability of the starting scaffold and the rigidness of the binding surface confer a high tolerance to mutation.United States. National Institutes of Health (CA174795)United States. National Institutes of Health (CA96504
Peroxidasin protein expression and enzymatic activity in metastatic melanoma cell lines are associated with invasive potential
Peroxidasin, a heme peroxidase, has been shown to play a role in cancer progression. mRNA expression has been reported to be upregulated in metastatic melanoma cell lines and connected to the invasive phenotype, but little is known about how peroxidasin acts in cancer cells. We have analyzed peroxidasin protein expression and activity in eight metastatic melanoma cell lines using an ELISA developed with an in-house peroxidasin binding protein. RNAseq data analysis confirmed high peroxidasin mRNA expression in the five cell lines classified as invasive and low expression in the three non-invasive cell lines. Protein levels of peroxidasin were higher in the cell lines with an invasive phenotype. Active peroxidasin was secreted to the cell culture medium, where it accumulated over time, and peroxidasin protein levels in the medium were also much higher in invasive than non-invasive cell lines. The only well-established physiological role of peroxidasin is in the formation of a sulfilimine bond, which cross-links collagen IV in basement membranes via catalyzed oxidation of bromide to hypobromous acid. We found that peroxidasin secreted from melanoma cells formed sulfilimine bonds in uncross-linked collagen IV, confirming peroxidasin activity and hypobromous acid formation. Moreover, 3-bromotyrosine, a stable product of hypobromous acid reacting with tyrosine residues, was detected in invasive melanoma cells, substantiating that their expression of peroxidasin generates hypobromous acid, and showing that it does not exclusively react with collagen IV, but also with other biomolecules
Cytosolic delivery of siRNA by ultra-high affinity dsRNA binding proteins
Abstract Protein-based methods of siRNA delivery are capable of uniquely specific targeting, but are limited by technical challenges such as low potency or poor biophysical properties. Here, we engineered a series of ultra-high affinity siRNA binders based on the viral protein p19 and developed them into siRNA carriers targeted to the epidermal growth factor receptor (EGFR). Combined in trans with a previously described endosome-disrupting agent composed of the pore-forming protein Perfringolysin O (PFO), potent silencing was achieved in vitro with no detectable cytotoxicity. Despite concerns that excessively strong siRNA binding could prevent the discharge of siRNA from its carrier, higher affinity continually led to stronger silencing. We found that this improvement was due to both increased uptake of siRNA into the cell and improved pharmacodynamics inside the cell. Mathematical modeling predicted the existence of an affinity optimum that maximizes silencing, after which siRNA sequestration decreases potency. Our study characterizing the affinity dependence of silencing suggests that siRNA-carrier affinity can significantly affect the intracellular fate of siRNA and may serve as a handle for improving the efficiency of delivery. The two-agent delivery system presented here possesses notable biophysical properties and potency, and provide a platform for the cytosolic delivery of nucleic acids
Driving CARs with alternative navigation tools ā the potential of engineered binding scaffolds
T cells that are genetically engineered to express chimeric antigen receptors (CAR T cells) have shown impressive clinical efficacy against Bācell malignancies. In contrast to these highly potent CD19ātargeting CAR T cells, many of those directed against other tumor entities and antigens currently suffer from several limitations. For example, it has been demonstrated that many scFvs used as antigenābinding domains in CARs show some degree of oligomerization, which leads to tonic signaling, T cell exhaustion, and poor performance in vivo. Therefore, in many cases alternatives to scFvs would be beneficial. Fortunately, due to the development of powerful protein engineering technologies, also nonāimmunoglobulinābased scaffolds can be engineered to specifically recognize antigens, thus eliminating the historical dependence on antibodyābased binding domains. Here, we discuss the advantages and disadvantages of such engineered binding scaffolds, in particular with respect to their application in CARs. We review recent studies, collectively showing that there is no functional or biochemical aspect that necessitates the use of scFvs in CARs. Instead, antigen recognition can also be mediated efficiently by engineered binding scaffolds, as well as natural ligands or receptors fused to the CAR backbone. Finally, we critically discuss the risk of immunogenicity and show that the extent of nonhuman amino acid stretches in engineered scaffoldsāeven in those based on nonhuman proteinsāis more similar to humanized scFvs than might be anticipated. Together, we expect that engineered binding scaffolds and natural ligands and receptors will be increasingly used for the design of CAR T cells.ISSN:1742-464XISSN:1742-465
Solving the mystery of the FMC63-CD19 affinity
Abstract The majority of approved CAR T cell products are based on the FMC63-scFv directed against CD19. Surprisingly, although antigen binding affinity is a major determinant for CAR function, the affinity of the benchmark FMC63-scFv has not been unambiguously determined. That is, a wide range of affinities have been reported in literature, differing by more than 100-fold. Using a range of techniques, we demonstrate that suboptimal experimental designs can cause artefacts that lead to over- or underestimation of the affinity. To minimize these artefacts, we performed SPR with strictly monomeric and correctly folded soluble CD19, yielding an FMC63-scFv affinity of 2ā6Ā nM. Together, apart from analyzing the FMC63-scFv affinity under optimized conditions, we also provide potential explanations for the wide range of published affinities. We expect that this study will be highly valuable for interpretations of CAR affinity-function relationships, as well as for the design of future CAR T cell generations
Identification of Activating Mutations in the Transmembrane and Extracellular Domains of EGFR
The epidermal growth factor receptor (EGFR) is frequently
mutated
in human cancer, most notably non-small-cell lung cancer and glioblastoma.
While many frequently occurring EGFR mutations are known to confer
constitutive EGFR activation, the situation is less clear for rarely
detected variants. In fact, more than 1000 distinct EGFR mutations
are listed in the Catalogue of Somatic Mutations in Cancer (COSMIC),
but for most of them, the functional consequence is unknown. To identify
additional, previously unknown activating mutations in EGFR, we screened
a randomly mutated EGFR library for constitutive EGFR phosphorylation
using a recently developed high-throughput approach termed PhosphoFlowSeq.
Enrichment of the well-known activating mutations S768I, T790M, and
L858R validated the experimental approach. Importantly, we also identified
the activating mutations S442I and L658Q located in the extracellular
and transmembrane domains of EGFR, respectively. To the best of our
knowledge, neither S442I nor L658Q has been associated with an activating
phenotype before. However, both have been detected in cancer samples.
Interestingly, molecular dynamics (MD) simulations suggest that the
L658Q mutation located in the hydrophobic transmembrane region forms
intermolecular hydrogen bonds, thereby promoting EGFR dimerization
and activation. Based on these findings, we screened the COSMIC database
for additional hydrophilic mutations in the EGFR transmembrane region
and indeed detected moderate constitutive activation of EGFR-G652R.
Together, this study demonstrates that unbiased screening for activating
mutations in EGFR not only yields well-established substitutions located
in the kinase domain but also activating mutations in other regions
of EGFR, including the extracellular and transmembrane domains
Identification of Activating Mutations in the Transmembrane and Extracellular Domains of EGFR
The epidermal growth factor receptor (EGFR) is frequently
mutated
in human cancer, most notably non-small-cell lung cancer and glioblastoma.
While many frequently occurring EGFR mutations are known to confer
constitutive EGFR activation, the situation is less clear for rarely
detected variants. In fact, more than 1000 distinct EGFR mutations
are listed in the Catalogue of Somatic Mutations in Cancer (COSMIC),
but for most of them, the functional consequence is unknown. To identify
additional, previously unknown activating mutations in EGFR, we screened
a randomly mutated EGFR library for constitutive EGFR phosphorylation
using a recently developed high-throughput approach termed PhosphoFlowSeq.
Enrichment of the well-known activating mutations S768I, T790M, and
L858R validated the experimental approach. Importantly, we also identified
the activating mutations S442I and L658Q located in the extracellular
and transmembrane domains of EGFR, respectively. To the best of our
knowledge, neither S442I nor L658Q has been associated with an activating
phenotype before. However, both have been detected in cancer samples.
Interestingly, molecular dynamics (MD) simulations suggest that the
L658Q mutation located in the hydrophobic transmembrane region forms
intermolecular hydrogen bonds, thereby promoting EGFR dimerization
and activation. Based on these findings, we screened the COSMIC database
for additional hydrophilic mutations in the EGFR transmembrane region
and indeed detected moderate constitutive activation of EGFR-G652R.
Together, this study demonstrates that unbiased screening for activating
mutations in EGFR not only yields well-established substitutions located
in the kinase domain but also activating mutations in other regions
of EGFR, including the extracellular and transmembrane domains