The IMiD target CRBN determines HSP90 activity toward transmembrane proteins essential in multiple myeloma.

The complex architecture of transmembrane proteins requires quality control (QC) of folding, membrane positioning, and trafficking as prerequisites for cellular homeostasis and intercellular communication. However, it has remained unclear whether transmembrane protein-specific QC hubs exist. Here we identify cereblon (CRBN), the target of immunomodulatory drugs (IMiDs), as a co-chaperone that specifically determines chaperone activity of HSP90 toward transmembrane proteins by means of counteracting AHA1. This function is abrogated by IMiDs, which disrupt the interaction of CRBN with HSP90. Among the multiple transmembrane protein clients of CRBN-AHA1-HSP90 revealed by cell surface proteomics, we identify the amino acid transporter LAT1/CD98hc as a determinant of IMiD activity in multiple myeloma (MM) and present an Anticalin-based CD98hc radiopharmaceutical for MM radio-theranostics. These data establish the CRBN-AHA1-HSP90 axis in the biogenesis of transmembrane proteins, link IMiD activity to tumor metabolism, and nominate CD98hc and LAT1 as attractive diagnostic and therapeutic targets in MM.

FerryCalin: an Engineered Lipocalin Protein Directed against the Transferrin Receptor with Potential for Brain Drug Delivery.

The transferrin receptor (TfR) mediates transcytosis across the blood-brain barrier (BBB), which offers a promising approach for the non-invasive delivery of therapeutics into the brain parenchyma. Employing the recombinant homodimeric murine TfR ectodomain, prepared in a biochemically functional state, we have selected a cognate Anticalin via phage display and bacterial cell surface display from a random library based on the human lipocalin 2 (Lcn2). After affinity maturation, several engineered lipocalin variants were identified that bind murine TfR in a non-competitive manner with the natural ligand (transferrin ⋅ Fe3+ ), among those an Anticalin - dubbed FerryCalin - exhibiting a dissociation constant (KD ) of 3.8 nM. Epitope analysis using the SPOT technique revealed a sequential epitope in a surface region of TfR remote from the transferrin-binding site. Due to the fast kon rate and short complex half-life, as evidenced by real-time surface plasmon resonance (SPR) measurements, FerryCalin, or one of its related mutants, shows characteristics as a potential vehicle for the brain delivery of biopharmaceuticals.

Molecular Design of 68Ga- and 89Zr-Labeled Anticalin Radioligands for PET-Imaging of PSMA-Positive Tumors.

Anticalin proteins directed against the prostate-specific membrane antigen (PSMA), optionally having tailored plasma half-life using PASylation technology, show promise as radioligands for PET-imaging of xenograft tumors in mice. To investigate their suitability, the short-circulating unmodified Anticalin was labeled with 68Ga (τ1/2 = 68 min), using the NODAGA chelator, whereas the half-life extended PASylated Anticalin was labeled with 89Zr (τ1/2 = 78 h), using either the linear chelator deferoxamine (Dfo) or a cyclic derivative, fusarinine C (FsC). Different PSMA targeting Anticalin versions (optionally carrying the PASylation sequence) were produced carrying a single exposed N- or C-terminal Cys residue and site-specifically conjugated with the different radiochelators via maleimide chemistry. These protein conjugates were labeled with radioisotopes having distinct physical half-lives and, subsequently, applied for PET-imaging of subcutaneous LNCaP xenograft tumors in CB17 SCID mice. Uptake of the protein tracers into tumor versus healthy tissues was assessed by segmentation of PET data as well as biodistribution analyses. PET-imaging with both the 68Ga-labeled plain Anticalin and the 89Zr-labeled PASylated Anticalin allowed clear delineation of the xenograft tumor. The radioligand A3A5.1-PAS(200)-FsC·89Zr, having an extended plasma half-life, led to a higher tumor uptake 24 h p.i. compared to the 68Ga·NODAGA-Anticalin imaged 60 min p.i. (2.5% ID/g vs 1.2% ID/g). Pronounced demetallation was observed for the 89Zr·Dfo-labeled PASylated Anticalin, which was ∼50% lower in the case of the cyclic radiochelator FsC (p < 0.0001). Adjusting the plasma half-life of Anticalin radioligands using PASylation technology is a viable approach to increase radioisotope accumulation within the tumor. Furthermore, 89Zr-ImmunoPET-imaging using the FsC radiochelator is superior to that using Dfo. Our strategy for the half-life adjustment of a tumor-targeting Anticalin to match the physical half-life of the applied radioisotope illustrates the potential of small binding proteins as an alternative to antibodies for PET-imaging.

Structural differences between the ectodomains of murine and human CD98hc.

The CD98 heavy chain (CD98hc) constitutes both a promising cell surface target for the treatment of cancers and a transcytosis receptor potentially useful for the brain delivery of therapeutics. However, pharmacokinetic studies and safety assessment of cognate antibodies or nonimmunoglobulin binding proteins in rodents is hampered by cross-species variability of both amino acid sequence and glycosylation pattern. Here, we report the crystal structure of the murine CD98hc extracellular domain and a comprehensive comparison with its human ortholog, revealing only one conserved surface patch that is neither shielded by glycosylation nor by the cell membrane with an accessible surface area typical for an antibody epitope. Our results imply the necessity of a surrogate approach for CD98hc-specific binding proteins with predictive power for clinical investigations.

Anticalin® proteins: from bench to bedside.

INTRODUCTION: Anticalin proteins are engineered versions of lipocalins that constitute a novel class of clinical-stage biopharmaceuticals. The lipocalins exhibit a central ß-barrel with eight antiparallel ß-strands and an α-helix attached to its side. Four structurally variable loops at the open end of the ß-barrel form a pronounced binding pocket, which can be reshaped to generate specificities toward diverse disease-relevant molecular targets. AREAS COVERED: This article reviews the current status of Anticalin engineering, from the basic principles to the development of Anticalins with high target affinity and specificity via combinatorial protein design and directed evolution, including examples of Anticalin-based drug candidates under preclinical and clinical development. EXPERT OPINION: Combinatorial gene libraries together with powerful molecular selection techniques have enabled the expansion of the natural ligand specificities of lipocalins from small molecules to peptides and proteins. This biomolecular concept has been validated by structural analyses of a series of Anticalin•target complexes. Promising Anticalin lead candidates have reached different preclinical and clinical development stages in the areas of (immuno)oncology, metabolic, and respiratory diseases, as antidotes to treat intoxications and as novel antibiotics. Thus, Anticalins offer an alternative to antibodies with promising and potentially superior features as next-generation biologics.

Design of a surrogate Anticalin protein directed against CD98hc for preclinical studies in mice.

The human CD98 heavy chain (CD98hc) offers a promising biomedical target both for tumor therapy and for drug delivery to the brain. We have previously developed a cognate Anticalin protein with picomolar affinity and demonstrated its effectiveness in a xenograft animal model. Due to the lack of cross-reactivity with the murine ortholog, we now report the development and X-ray structural analysis of an Anticalin with high affinity toward CD98hc from mouse. This binding protein recognizes the same protruding epitope loop-despite distinct structure-in the membrane receptor ectodomain as the Anticalin selected against human CD98hc. Thus, this surrogate Anticalin should be useful for the preclinical assessment of CD98hc targeting in vivo and support the translational development for medical application in humans.

Development of a high affinity Anticalin® directed against human CD98hc for theranostic applications.

Enhanced amino acid supply and dysregulated integrin signaling constitute two hallmarks of cancer and are pivotal for metastatic transformation of cells. In line with its function at the crossroads of both processes, overexpression of CD98hc is clinically observed in various cancer malignancies, thus rendering it a promising tumor target. Methods: We describe the development of Anticalin proteins based on the lipocalin 2 (Lcn2) scaffold against the human CD98hc ectodomain (hCD98hcED) using directed evolution and protein design. X-ray structural analysis was performed to identify the epitope recognized by the lead Anticalin candidate. The Anticalin - with a tuned plasma half-life using PASylation® technology - was labeled with 89Zr and investigated by positron emission tomography (PET) of CD98-positive tumor xenograft mice. Results: The Anticalin P3D11 binds CD98hc with picomolar affinity and recognizes a protruding loop structure surrounded by several glycosylation sites within the solvent exposed membrane-distal part of the hCD98hcED. In vitro studies revealed specific binding activity of the Anticalin towards various CD98hc-expressing human tumor cell lines, suggesting broader applicability in cancer research. PET/CT imaging of mice bearing human prostate carcinoma xenografts using the optimized and 89Zr-labeled Anticalin demonstrated strong and specific tracer accumulation (8.6 ± 1.1 %ID/g) as well as a favorable tumor-to-blood ratio of 11.8. Conclusion: Our findings provide a first proof of concept to exploit CD98hc for non-invasive biomedical imaging. The novel Anticalin-based αhCD98hc radiopharmaceutical constitutes a promising tool for preclinical and, potentially, clinical applications in oncology.