Safety, pharmacokinetics and pharmacodynamics of the anti-hepcidin Spiegelmer lexaptepid pegol in healthy subjects.

BACKGROUND AND PURPOSE: Anaemia of chronic disease is characterized by impaired erythropoiesis due to functional iron deficiency, often caused by excessive hepcidin. Lexaptepid pegol, a pegylated structured l-oligoribonucleotide, binds and inactivates hepcidin. EXPERIMENTAL APPROACH: We conducted a placebo-controlled study on the safety, pharmacokinetics and pharmacodynamics of lexaptepid after single and repeated i.v. and s.c. administration to 64 healthy subjects at doses from 0.3 to 4.8 mg·kg(-1) . KEY RESULTS: After treatment with lexaptepid, serum iron concentration and transferrin increased dose-dependently. Iron increased from approximately 20 µmol·L(-1) at baseline by 67% at 8 h after i.v. infusion of 1.2 mg·kg(-1) lexaptepid. The pharmacokinetics showed dose-proportional increases in peak plasma concentrations and moderately over-proportional increases in systemic exposure. Lexaptepid had no effect on hepcidin production or anti-drug antibodies. Treatment with lexaptepid was generally safe and well tolerated, with mild and transient transaminase increases at doses ≥2.4 mg·kg(-1) and with local injection site reactions after s.c. but not after i.v. administration. CONCLUSIONS AND IMPLICATIONS: Lexaptepid pegol inhibited hepcidin and dose-dependently raised serum iron and transferrin saturation. The compound is being further developed to treat anaemia of chronic disease.

A novel CGRP-neutralizing Spiegelmer attenuates neurogenic plasma protein extravasation.

BACKGROUND AND PURPOSE: Calcitonin gene-related peptide (CGRP) plays an important role in the pathology of migraine, and recent clinical trials suggest the inhibition of CGRP-mediated processes as a new therapeutic option in migraine. In this study, we describe the generation of NOX-L41, a CGRP-neutralizing mirror-image (L-)aptamer (Spiegelmer) and investigate its in vitro and in vivo function. EXPERIMENTAL APPROACH: A CGRP-binding Spiegelmer was identified by in vitro selection. Binding studies were performed using surface plasmon resonance (SPR), and the inhibitory activity was determined in cell-based assays. The pharmacokinetic profile comparing i.v. and s.c. dosing was analysed in rats. Intravital two-photon microscopy was employed to follow extravasation from meningeal vessels. Finally, in vivo efficacy was tested in a model of electrically evoked meningeal plasma protein extravasation (PPE) in rats. KEY RESULTS: We identified NOX-L41, a novel CGRP-neutralizing Spiegelmer. SPR studies showed that NOX-L41 binds to human and rat/mouse CGRP with sub-nanomolar affinities and is highly selective against related peptides such as amylin. In vitro, NOX-L41 effectively inhibited CGRP-induced cAMP formation in SK-N-MC cells. In rats, NOX-L41 had a plasma half-life of 8 h. Pharmacodynamic studies showed that NOX-L41 extravasates from blood vessels in the dura mater and inhibits neurogenic meningeal PPE for at least 18 h after single dosing. CONCLUSIONS AND IMPLICATIONS: This is the first description of the CGRP-neutralizing Spiegelmer NOX-L41. Preclinical studies confirmed a role for CGRP in neurogenic PPE and provided proof-of-concept for the potential use of this new drug candidate for the treatment or prevention of migraine.

Drugs made of RNA: development and application of engineered RNAs for gene therapy.

During the past decade, RNA has become a focus of investigation into new therapeutic schemes: antisense RNA, interfering RNA and trans-cleaving ribozymes are used to silence undesired gene expression. As an additional option with its own therapeutic potential, ribozymes may be employed to specifically alter the sequence of RNA. Among these RNA based strategies the mode of action varies: while antisense and interfering RNAs are capable of making specific contacts to other RNA molecules with the result of employing the cellular machinery for degradation of the RNA target, trans-cleaving ribozymes fold into specific three-dimensional structures to form catalytic centres and to specifically cleave a chosen RNA target. Beyond this, trans-splicing ribozymes have been engineered to first cleave a RNA target followed by ligation of a new RNA fragment delivered with the ribozyme. The latter strategy potentially extends the application of ribozymes from inhibition of gene expression to RNA repair, i. e. correction of genetic disorders at the level of RNA, and has already shown promising results in cell culture experiments. On the other side, advances in RNA synthesis, ribozyme engineering, delivery methods and expression systems have greatly enhanced the prospects of ribozymes, antisense and interfering RNAs in gene therapy. This review provides an overview of existing strategies for potential RNA based gene therapy. It is focussed on the engineering of ribozymes and functional RNAs to be used as drugs and on the basic molecular principles of their action.