Rational design of a fibroblast growth factor 21-based clinical candidate, LY2405319.

Fibroblast growth factor 21 is a novel hormonal regulator with the potential to treat a broad variety of metabolic abnormalities, such as type 2 diabetes, obesity, hepatic steatosis, and cardiovascular disease. Human recombinant wild type FGF21 (FGF21) has been shown to ameliorate metabolic disorders in rodents and non-human primates. However, development of FGF21 as a drug is challenging and requires re-engineering of its amino acid sequence to improve protein expression and formulation stability. Here we report the design and characterization of a novel FGF21 variant, LY2405319. To enable the development of a potential drug product with a once-daily dosing profile, in a preserved, multi-use formulation, an additional disulfide bond was introduced in FGF21 through Leu118Cys and Ala134Cys mutations. FGF21 was further optimized by deleting the four N-terminal amino acids, His-Pro-Ile-Pro (HPIP), which was subject to proteolytic cleavage. In addition, to eliminate an O-linked glycosylation site in yeast a Ser167Ala mutation was introduced, thus allowing large-scale, homogenous protein production in Pichia pastoris. Altogether re-engineering of FGF21 led to significant improvements in its biopharmaceutical properties. The impact of these changes was assessed in a panel of in vitro and in vivo assays, which confirmed that biological properties of LY2405319 were essentially identical to FGF21. Specifically, subcutaneous administration of LY2405319 in ob/ob and diet-induced obese (DIO) mice over 7-14 days resulted in a 25-50% lowering of plasma glucose coupled with a 10-30% reduction in body weight. Thus, LY2405319 exhibited all the biopharmaceutical and biological properties required for initiation of a clinical program designed to test the hypothesis that administration of exogenous FGF21 would result in effects on disease-related metabolic parameters in humans.

Determination of the mechanism of action of anti-FasL antibody by epitope mapping and homology modeling.

Fas ligand (FasL) is a 40-kDa type II transmembrane protein belonging to the tumor necrosis factor (TNF) family of proteins and binds to its specific receptor, Fas, a member of the TNF receptor family. Membrane-bound FasL can be processed into a soluble form by a metalloprotease similar to that which cleaves TNFalpha. Elevated levels of FasL have been implicated in a wide variety of diseases ranging from cancer to inflammatory abnormalities, which could be targeted by antibody therapy. We generated a fully human high-affinity antibody against FasL that binds to and neutralizes the activity of both soluble and membrane-associated human FasL. In order to elucidate the mechanism of function of this antibody, we have mapped the region and critical residues involved in the recognition of FasL using a combination of homology modeling, immunoprecipitation, hydrogen-deuterium exchange mass spectrometry (H/DXMS), and alanine scanning site-directed mutagenesis. These studies have revealed the antibody binding site on human FasL. Furthermore, through molecular homology modeling, we have proposed a mechanism for the neutralizing activity of this antibody that involves interference with the docking of the ligand to its receptor by the antibody.

IL-1beta epitope mapping using site-directed mutagenesis and hydrogen-deuterium exchange mass spectrometry analysis.

Hu007, a humanized IgG1 monoclonal antibody, binds and neutralizes human, cynomolgus, and rabbit IL-1beta but only weakly binds to mouse and rat IL-1beta. Biacore experiments demonstrated that Hu007 and the type-I IL-1 receptor competed for binding to IL-1beta. Increasing salt concentrations decrease the association rate with only moderate effects on the dissociation rate, suggesting that long-range electrostatics are critical for formation of the initial complex. To understand the ligand-binding specificity of Hu007, we have mapped the critical residues involved in the recognition of IL-1beta. Selected residues in cynomolgus IL-1beta were mutated to the corresponding residues in mouse IL-1beta, and the effects of the changes on binding were evaluated by surface plasmon resonance measurements using Biacore. Specifically, substitution of F150S decreased binding affinity by 100-fold, suggesting the importance of hydrophobic interactions in stabilizing the antibody/antigen complex. Substitution of three amino acids near the N- and C-terminal regions of cIL-1beta with those found in mouse IL-1beta (V3I/S5Q/F150S) decreased the binding affinity of Hu007 to IL-1beta by about 1000-fold. Conversely, mutating the corresponding residues in mouse IL-1beta to the human sequence resulted in an increase in binding affinity of about 1000-fold. Hydrogen-deuterium exchange/mass spectrometry analysis confirmed that these regions of IL-1beta were protected from exchange because of antibody binding. The results from this study demonstrate that Hu007 binds to a region located in the open end of the beta-barrel structure of IL-1beta and blocks binding of IL-1beta to its receptor.

Inhibition of thrombin activatable fibrinolysis inhibitor by cysteine derivatives.

Thrombin Activatable Fibrinolysis Inhibitor (TAFI) is a basic carboxypeptidase that functions as a fibrinolysis inhibitor through the cleavage of C-terminal lysine on partially degraded fibrin. Modulation of TAFI activity provides a potential therapy for thrombosis complications by potentiating fibrinolysis. In our study, we identified three novel TAFI inhibitors containing a cysteine backbone. Three cysteine derivatives, guanidinyl-L-cysteine, glycyl-L-cysteine, and glycyl-glycyl-L-cysteine were tested in TAFI substrate assays and showed K(app)(i)=0.08, 0.14, and 0.99 microM, respectively. Subsequent fibrinolysis assays confirmed their TAFI inhibitory activities. Guanidinyl-L-cysteine showed inhibitory activity in a human plasma clot lysis assay (IC(50)=9.4 microM). Identification of these cysteine derivatives represents an opportunity to develop potent and specific TAFI inhibitors.

Noncalcemic actions of vitamin D receptor ligands.

1alpha,25-Dihydroxyvitamin D(3) [1,25-(OH)(2)D(3)], the active metabolite of vitamin D(3), is known for the maintenance of mineral homeostasis and normal skeletal architecture. However, apart from these traditional calcium-related actions, 1,25-(OH)(2)D(3) and its synthetic analogs are being increasingly recognized for their potent antiproliferative, prodifferentiative, and immunomodulatory activities. These actions of 1,25-(OH)(2)D(3) are mediated through vitamin D receptor (VDR), which belongs to the superfamily of steroid/thyroid hormone nuclear receptors. Physiological and pharmacological actions of 1,25-(OH)(2)D(3) in various systems, along with the detection of VDR in target cells, have indicated potential therapeutic applications of VDR ligands in inflammation (rheumatoid arthritis, psoriatic arthritis), dermatological indications (psoriasis, actinic keratosis, seborrheic dermatitis, photoaging), osteoporosis (postmenopausal and steroid-induced osteoporosis), cancers (prostate, colon, breast, myelodysplasia, leukemia, head and neck squamous cell carcinoma, and basal cell carcinoma), secondary hyperparathyroidism, and autoimmune diseases (systemic lupus erythematosus, type I diabetes, multiple sclerosis, and organ transplantation). As a result, VDR ligands have been developed for the treatment of psoriasis, osteoporosis, and secondary hyperparathyroidism. Furthermore, encouraging results have been obtained with VDR ligands in clinical trials of prostate cancer and hepatocellular carcinoma. This review deals with the molecular aspects of noncalcemic actions of vitamin D analogs that account for the efficacy of VDR ligands in the above-mentioned indications.

Oligomerization and cooperative RNA synthesis activity of hepatitis C virus RNA-dependent RNA polymerase.

The NS5B RNA-dependent RNA polymerase encoded by hepatitis C virus (HCV) plays a key role in viral replication. Reported here is evidence that HCV NS5B polymerase acts as a functional oligomer. Oligomerization of HCV NS5B protein was demonstrated by gel filtration, chemical cross-linking, temperature sensitivity, and yeast cell two-hybrid analysis. Mutagenesis studies showed that the C-terminal hydrophobic region of the protein was not essential for its oligomerization. Importantly, HCV NS5B polymerase exhibited cooperative RNA synthesis activity with a dissociation constant, K(d), of approximately 22 nM, suggesting a role for the polymerase-polymerase interaction in the regulation of HCV replicase activity. Further functional evidence includes the inhibition of the wild-type NS5B polymerase activity by a catalytically inactive form of NS5B. Finally, the X-ray crystal structure of HCV NS5B polymerase was solved at 2.9 A. Two extensive interfaces have been identified from the packing of the NS5B molecules in the crystal lattice, suggesting a higher-order structure that is consistent with the biochemical data.