Florian Kast scite author profile

The receptor tyrosine kinase HER2 acts as oncogenic driver in numerous cancers. Usually, the gene is amplified, resulting in receptor overexpression, massively increased signaling and unchecked proliferation. However, tumors become frequently addicted to oncogenes and hence are druggable by targeted interventions. Here, we design an anti-HER2 biparatopic and tetravalent IgG fusion with a multimodal mechanism of action. The molecule first induces HER2 clustering into inactive complexes, evidenced by reduced mobility of surface HER2. However, in contrast to our earlier binders based on DARPins, clusters of HER2 are thereafter robustly internalized and quantitatively degraded. This multimodal mechanism of action is found only in few of the tetravalent constructs investigated, which must target specific epitopes on HER2 in a defined geometric arrangement. The inhibitory effect of our antibody as single agent surpasses the combination of trastuzumab and pertuzumab as well as its parental mAbs in vitro and it is effective in a xenograft model.

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Analysis of IgG kinetic stability by differential scanning calorimetry, probe fluorescence and light scattering

Nemergut

Schaefer

Kast

et al. 2017

Protein Science

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Monoclonal antibodies of the immunoglobulin G (IgG) type have become mainstream therapeutics for the treatment of many life-threatening diseases. For their successful application in the clinic and a favorable cost-benefit ratio, the design and formulation of these therapeutic molecules must guarantee long-term stability for an extended period of time. Accelerated stability studies, e.g., by employing thermal denaturation, have the great potential for enabling high-throughput screening campaigns to find optimal molecular variants and formulations in a short time. Surprisingly, no validated quantitative analysis of these accelerated studies has been performed yet, which clearly limits their application for predicting IgG stability. Therefore, we have established a quantitative approach for the assessment of the kinetic stability over a broad range of temperatures. To this end, differential scanning calorimetry (DSC) experiments were performed with a model IgG, testing chaotropic formulations and an extended temperature range, and they were subsequently analyzed by our recently developed three-step sequential model of IgG denaturation, consisting of one reversible and two irreversible steps. A critical comparison of the predictions from this model with data obtained by an orthogonal fluorescence probe method, based on 8-anilinonaphthalene-1-sulfonate binding to partially unfolded states, resulted in very good agreement. In summary, our study highlights the validity of this easy-to-perform analysis for reliably assessing the kinetic stability of IgGs, which can support accelerated formulation development of monoclonal antibodies by ranking different formulations as well as by improving colloidal stability models.

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High-Throughput Quantification of Surface Protein Internalization and Degradation

2019

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Cell surface proteins are key regulators of fundamental cellular processes and, therefore, often at the root of human diseases. Thus, a large number of targeted drugs which are approved or under development act upon cell surface proteins. Although down-regulation of surface proteins by many natural ligands is well-established, the ability of drug candidates to cause internalization or degradation of the target is only recently moving into focus. This property is important both for the pharmacokinetics and pharmacodynamics of the drug but may also constitute a potential resistance mechanism. The enormous numbers of drug candidates targeting cell surface molecules, comprising small molecules, antibodies, or alternative protein scaffolds, necessitate methods for the investigation of internalization and degradation in high throughput. Here, we present a generic high-throughput assay protocol, which allows the simultaneous and independent quantification of internalization and degradation of surface proteins on a single-cell level. Because we fuse a HaloTag to the cell surface protein of interest and exploit the differential cell permeability of two fluorescent HaloTag ligands, no labeling of the molecules to be screened is required. In contrast to previously described approaches, our homogeneous assay is performed with adherent live cells in a 96-well format. Through channel rescaling, we are furthermore able to obtain true relative abundances of surface and internal protein. We demonstrate the applicability of our procedure to three major drug targets, EGFR, HER2, and EpCAM, examining a selection of well-investigated but also novel small molecule ligands and protein affinity reagents.

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Systemic analysis of tyrosine kinase signaling reveals a common adaptive response program in a HER2-positive breast cancer

et al. 2019

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Drug-induced compensatory signaling and subsequent rewiring of the signaling pathways that support cell proliferation and survival promotes the development of acquired drug resistance in tumors. Here, we sought to analyze the adaptive kinase response in cancer cells after distinct treatment with agents targeting human epidermal growth factor receptor 2 (HER2), specifically those which induce only temporary cell cycle arrest or apoptosis in HER2-overexpressing cancers. We compared trastuzumab, ARRY-380, the combination thereof, and a biparatopic HER2-targeted designed ankyrin repeat protein (DARPin; specifically 61LG) and quantified the phosphoproteome by isobaric tagging using tandem mass tag liquid chromatography/mass spectrometry (TMT LC-MS/MS). We found a specific signature of persistently phosphorylated tyrosine peptides after the non-apoptotic treatments, which we used to distinguish between different treatment-induced cancer cell fates. Next, we analyzed the activation of serine/threonine and tyrosine kinases after treatment using a bait peptide chip array and predicted the corresponding active kinases. Through a combined system-wide analysis, we identified a common adaptive kinase-response program that involved the activation of focal adhesion kinase (FAK1), protein kinase C-δ (PKCδ), and Ephrin (EPH) family receptors. The findings reveal potential targets to prevent adaptive resistance to HER2-targeted therapies.

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Inhibition of the MET Kinase Activity and Cell Growth in MET-Addicted Cancer Cells by Bi-Paratopic Linking

Andres

Iamele

Meyer

et al. 2019

Journal of Molecular Biology

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Florian Kast

Engineering an anti-HER2 biparatopic antibody with a multimodal mechanism of action

Analysis of IgG kinetic stability by differential scanning calorimetry, probe fluorescence and light scattering

High-Throughput Quantification of Surface Protein Internalization and Degradation

Systemic analysis of tyrosine kinase signaling reveals a common adaptive response program in a HER2-positive breast cancer

Inhibition of the MET Kinase Activity and Cell Growth in MET-Addicted Cancer Cells by Bi-Paratopic Linking

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