First-in-human phase I study of the liposomal RNA interference therapeutic Atu027 in patients with advanced solid tumors.

PURPOSE Atu027 is a novel liposomal RNA interference therapeutic that includes a short-interfering RNA (siRNA), which silences expression of protein kinase N3 in the vascular endothelium. Atu027 has previously been shown to inhibit local tumor invasion as well as lymph node and pulmonary metastasis in mouse cancer models. This first-in-human study aimed to assess the safety, tolerability, and pharmacokinetics of Atu027 while evaluating therapeutic effects on both primary tumors and metastatic lesions. PATIENTS AND METHODS Thirty-four patients with advanced solid tumors received 10 escalating doses of Atu027 without premedication, as one single followed by eight intravenous infusions twice per week during a 28-day cycle. Response was monitored by computed tomography/magnetic resonance imaging at baseline, at the end of treatment (EoT), and at final follow-up (EoS), and was assessed according to RECIST. RESULTS Atu027 was well tolerated up to dose levels of 0.336 mg/kg; most adverse events (AEs) were low-grade toxicities (grade 1 or 2). No maximum tolerated dose was reached. Plasma levels of siRNA strands and lipids were dose proportional, peaking during 4-hour infusion. Disease stabilization was achieved in 41% of patients at EoT (n = 14 of 34 treated patients); eight patients had stable disease at EoS, and some experienced complete or partial regression of metastases. sFLT1 (soluble variant of vascular endothelial growth factor receptor-1) decreased from pretreatment levels in most patients after dose levels 04 to 10. CONCLUSION Atu027 was safe in patients with advanced solid tumors, with 41% of patients having stable disease for at least 8 weeks. In view of these results, further clinical trials have been initiated, and sFLT1 will be investigated as a potential biomarker.

[1]  B. Bettencourt,et al.  Effect of an RNA interference drug on the synthesis of proprotein convertase subtilisin/kexin type 9 (PCSK9) and the concentration of serum LDL cholesterol in healthy volunteers: a randomised, single-blind, placebo-controlled, phase 1 trial , 2014, The Lancet.

[2]  B. Bettencourt,et al.  Safety and efficacy of RNAi therapy for transthyretin amyloidosis. , 2013, The New England journal of medicine.

[3]  R. Jain Normalizing tumor microenvironment to treat cancer: bench to bedside to biomarkers. , 2013, Journal of clinical oncology : official journal of the American Society of Clinical Oncology.

[4]  N. Svrzikapa,et al.  First-in-humans trial of an RNA interference therapeutic targeting VEGF and KSP in cancer patients with liver involvement. , 2013, Cancer discovery.

[5]  J. Burnett,et al.  Nanoparticle-Based Delivery of RNAi Therapeutics: Progress and Challenges , 2013, Pharmaceuticals.

[6]  A. Santel,et al.  Depletion of protein kinase N3 (PKN3) impairs actin and adherens junctions dynamics and attenuates endothelial cell activation. , 2012, European journal of cell biology.

[7]  A. Klippel,et al.  The interaction of PKN3 with RhoC promotes malignant growth , 2012, Molecular oncology.

[8]  J. Dwyer,et al.  Jumping the barrier: VE‐cadherin, VEGF and other angiogenic modifiers in cancer , 2011, Biology of the cell.

[9]  Yechezkel Barenholz,et al.  Activation of complement by therapeutic liposomes and other lipid excipient-based therapeutic products: prediction and prevention. , 2011, Advanced drug delivery reviews.

[10]  P. Carmeliet,et al.  Antiangiogenic therapy, hypoxia, and metastasis: risky liaisons, or not? , 2011, Nature Reviews Clinical Oncology.

[11]  P. Carmeliet,et al.  Molecular mechanisms and clinical applications of angiogenesis , 2011, Nature.

[12]  R. Weinberg,et al.  A Perspective on Cancer Cell Metastasis , 2011, Science.

[13]  R. Kerbel,et al.  Antiangiogenic therapy: impact on invasion, disease progression, and metastasis , 2011, Nature Reviews Clinical Oncology.

[14]  K. Giese,et al.  Atu027 Prevents Pulmonary Metastasis in Experimental and Spontaneous Mouse Metastasis Models , 2010, Clinical Cancer Research.

[15]  O. Stoeltzing,et al.  556 Therapeutic siRNA delivery against PKN3 improves the antineoplastic efficacy of gemcitabine in an orthotopic pancreatic cancer model , 2010 .

[16]  A. Santel,et al.  RNA interference for therapy in the vascular endothelium. , 2010, Microvascular research.

[17]  M. Moore,et al.  Choice of starting dose for molecularly targeted agents evaluated in first-in-human phase I cancer clinical trials. , 2010, Journal of clinical oncology : official journal of the American Society of Clinical Oncology.

[18]  B. Wiedenmann,et al.  Atu027, a liposomal small interfering RNA formulation targeting protein kinase N3, inhibits cancer progression. , 2008, Cancer research.

[19]  F. Orsenigo,et al.  The role of adherens junctions and VE-cadherin in the control of vascular permeability , 2008, Journal of Cell Science.

[20]  A. Klippel,et al.  RNA interference in the mouse vascular endothelium by systemic administration of siRNA-lipoplexes for cancer therapy , 2006, Gene Therapy.

[21]  A. Klippel,et al.  A novel siRNA-lipoplex technology for RNA interference in the mouse vascular endothelium , 2006, Gene Therapy.

[22]  F. Leenders,et al.  PKN3 is required for malignant prostate cell growth downstream of activated PI 3‐kinase , 2004, The EMBO journal.

[23]  I. Fidler,et al.  The pathogenesis of cancer metastasis: the 'seed and soil' hypothesis revisited , 2003, Nature Reviews Cancer.

[24]  A. Klippel,et al.  Structural variations and stabilising modifications of synthetic siRNAs in mammalian cells. , 2003, Nucleic acids research.

[25]  P. Schneider,et al.  Molecular, genetic, and functional analysis of homozygous C8 beta-chain deficiency in two siblings. , 1997, Immunopharmacology.