Structure-function relationships of the soluble form of the antiaging protein Klotho have therapeutic implications for managing kidney disease.

The fortuitously discovered antiaging membrane protein αKlotho (Klotho) is highly expressed in the kidney, and deletion of the Klotho gene in mice causes a phenotype strikingly similar to that of chronic kidney disease (CKD). Klotho functions as a co-receptor for fibroblast growth factor 23 (FGF23) signaling, whereas its shed extracellular domain, soluble Klotho (sKlotho), carrying glycosidase activity, is a humoral factor that regulates renal health. Low sKlotho in CKD is associated with disease progression, and sKlotho supplementation has emerged as a potential therapeutic strategy for managing CKD. Here, we explored the structure-function relationship and post-translational modifications of sKlotho variants to guide the future design of sKlotho-based therapeutics. Chinese hamster ovary (CHO)- and human embryonic kidney (HEK)-derived WT sKlotho proteins had varied activities in FGF23 co-receptor and ß-glucuronidase assays in vitro and distinct properties in vivo Sialidase treatment of heavily sialylated CHO-sKlotho increased its co-receptor activity 3-fold, yet it remained less active than hyposialylated HEK-sKlotho. MS and glycopeptide-mapping analyses revealed that HEK-sKlotho is uniquely modified with an unusual N-glycan structure consisting of N,N'-di-N-acetyllactose diamine at multiple N-linked sites, one of which at Asn-126 was adjacent to a putative GalNAc transfer motif. Site-directed mutagenesis and structural modeling analyses directly implicated N-glycans in Klotho's protein folding and function. Moreover, the introduction of two catalytic glutamate residues conserved across glycosidases into sKlotho enhanced its glucuronidase activity but decreased its FGF23 co-receptor activity, suggesting that these two functions might be structurally divergent. These findings open up opportunities for rational engineering of pharmacologically enhanced sKlotho therapeutics for managing kidney disease.

Transient CHO expression platform for robust antibody production and its enhanced N-glycan sialylation on therapeutic glycoproteins.

Large-scale transient expression in mammalian cells is a rapid protein production technology often used to shorten overall timelines for biotherapeutics drug discovery. In this study we demonstrate transient expression in a Chinese hamster ovary (CHO) host (ExpiCHO-S™) cell line capable of achieving high recombinant antibody expression titers, comparable to levels obtained using human embryonic kidney (HEK) 293 cells. For some antibodies, ExpiCHO-S™ cells generated protein materials with better titers and improved protein quality characteristics (i.e., less aggregation) than those from HEK293. Green fluorescent protein imaging data indicated that ExpiCHO-S™ displayed a delayed but prolonged transient protein expression process compared to HEK293. When therapeutic glycoproteins containing non-Fc N-linked glycans were expressed in transient ExpiCHO-S™, the glycan pattern was unexpectedly found to have few sialylated N-glycans, in contrast to glycans produced within a stable CHO expression system. To improve N-glycan sialylation in transient ExpiCHO-S™, we co-transfected galactosyltransferase and sialyltransferase genes along with the target genes, as well as supplemented the culture medium with glycan precursors. The authors have demonstrated that co-transfection of glycosyltransferases combined with medium addition of galactose and uridine led to increased sialylation content of N-glycans during transient ExpiCHO-S™ expression. These results have provided a scientific basis for developing a future transient CHO system with N-glycan compositions that are similar to those profiles obtained from stable CHO protein production systems. © 2018 American Institute of Chemical Engineers Biotechnol. Prog., 35: e2724, 2019.

Development of PF-06671008, a Highly Potent Anti-P-cadherin/Anti-CD3 Bispecific DART Molecule with Extended Half-Life for the Treatment of Cancer.

Bispecific antibodies offer a promising approach for the treatment of cancer but can be challenging to engineer and manufacture. Here we report the development of PF-06671008, an extended-half-life dual-affinity re-targeting (DART®) bispecific molecule against P-cadherin and CD3 that demonstrates antibody-like properties. Using phage display, we identified anti-P-cadherin single chain Fv (scFv) that were subsequently affinity-optimized to picomolar affinity using stringent phage selection strategies, resulting in low picomolar potency in cytotoxic T lymphocyte (CTL) killing assays in the DART format. The crystal structure of this disulfide-constrained diabody shows that it forms a novel compact structure with the two antigen binding sites separated from each other by approximately 30 Å and facing approximately 90° apart. We show here that introduction of the human Fc domain in PF-06671008 has produced a molecule with an extended half-life (-4.4 days in human FcRn knock-in mice), high stability (Tm1 > 68 °C), high expression (>1 g/L), and robust purification properties (highly pure heterodimer), all with minimal impact on potency. Finally, we demonstrate in vivo anti-tumor efficacy in a human colorectal/human peripheral blood mononuclear cell (PBMC) co-mix xenograft mouse model. These results suggest PF-06671008 is a promising new bispecific for the treatment of patients with solid tumors expressing P-cadherin.

Quantitative analysis of target coverage and germinal center response by a CXCL13 neutralizing antibody in a T-dependent mouse immunization model.

PURPOSE: Study the impact of CXCL13 neutralization on germinal center (GC) response in vivo, and build quantitative relationship between target coverage and pharmacological effects at the target tissue. METHODS: An anti-CXCL13 neutralizing monoclonal antibody was dosed in vivo in a T-dependent mouse immunization (TDI) model. A quantitative site-of-action (SoA) model was developed to integrate antibody PK and total CXCL13 levels in serum and spleen towards estimating target coverage as a function of dose. To aid in the SoA model development, a radio-labeled study using [I(125)] CXCL13 was conducted in mice. Model estimated target coverage was linked to germinal center response using a sigmoidal inhibitory effect model. RESULTS: In vivo studies demonstrated that CXCL13 inhibition led to an architectural change in B-cell follicles, dislocation of GCs and a significant reduction in the GC absolute numbers per square area (GC/mm(2)). The SoA modeling analysis indicated that ~79% coverage in spleen was required to achieve 50% suppression of GC/mm(2). The 3 mg/kg dose with 52% spleen coverage resulted in no PD suppression, whereas 30 mg/kg with 93% coverage achieved close to maximum PD suppression, highlighting the steepness of PD response. CONCLUSIONS: This study showcases an application of SoA modeling towards a quantitative understanding of CXCL13 pharmacology.

Oligomerization is required for the activity of recombinant soluble LOX-1.

LOX-1 is a scavenger receptor that functions as the primary receptor for oxidized low-density lipoprotein (OxLDL) in endothelial cells. The binding of OxLDL to LOX-1 is believed to lead to endothelial activation, dysfunction, and injury, which constitute early atherogenic events. Because of its potential pathological role in atherosclerosis, LOX-1 has been proposed as a therapeutic target for the treatment of this disease. In order to antagonize the ligand-binding function of cell surface LOX-1, we generated a series of recombinant human LOX-1-crystallizable fragment (Fc) fusion proteins and subsequently characterized their biochemical properties and ligand-binding activities in vitro. Consistent with the notion that oligomerization of cell surface LOX-1 is required for high-avidity binding of ligands, we found that LOX-1-Fc fusion protein containing four ligand-binding domains per Fc dimer, but not the one containing two ligand-binding domains, exhibited ligand-binding activity. Optimal ligand-binding activity could be achieved via crosslinking of LOX-1-Fc fusion proteins with a polyclonal antibody against Fc. The crosslinked LOX-1-Fc protein also effectively inhibited the binding and internalization of OxLDL by cell surface LOX-1. These findings demonstrate that functional oligomerization is required for recombinant LOX-1-Fc to function as an effective antagonist.