Lasso peptide microcin J25 variant containing RGD motif as a PET probe for integrin a v ß 3 in tumor imaging

Microcin J25 (MccJ25), a lasso peptide, has a unique 3-D interlocked structure that provides high stability under acidic conditions, at high temperatures, and in the presence of proteases. In this study, we generated a positron emission tomography (PET) probe based on MccJ25 analog with an RGD motif and investigated their pharmacokinetics and utility for integrin αvβ3 imaging in tumors. The MccJ25 variant with an RGD motif in the loop region and a lysine substitution at the C-terminus (MccJ25(RGDF)GtoK) was produced in E. coli transfected with plasmid DNA containing the MccJ25 biosynthetic gene cluster (mcjABCD). [64Cu]Cu-MccJ25(RGDF)GtoK was synthesized using the C-terminal lysine labeled with copper-64 (t1/2 = 12.7 h) via a bifunctional chelator; it showed stability in 90% mouse plasma for 45 min. Using PET imaging for integrin αvβ3 positive U87MG tumor bearing mice, [64Cu]Cu-MccJ25(RGDF)GtoK could clearly distinguish the tumor, and its accumulation was significantly higher than that of MccJ25(GIGT)GtoK without the binding motif for integrin αvβ3. Furthermore, MccJ25(RGDF)GtoK enabled visualization of only U87MG tumors but not MCF-7 tumors with low integrin αvβ3 expression in double tumor-bearing mice. In ex vivo biodistribution analysis, the integrin αvβ3 non-specific accumulation of [64Cu]Cu-MccJ25(RGDF)GtoK was significantly lower in various tissues, except for the kidneys, as compared to the control probe ([64Cu]Cu-cyclic RGD peptide). These results of the present study indicate that 64Cu-labeling methods are appropriate for the synthesis of MccJ25-based PET probes, and [64Cu]Cu-MccJ25 variants are useful tools for cancer molecular imaging

Macrocyclic peptide-based inhibition and imaging of hepatocyte growth factor.

金沢大学がん進展制御研究所Activation of hepatocyte growth factor (HGF) by proteolytic processing is triggered in cancer microenvironments, and subsequent signaling through the MET receptor is involved in cancer progression. However, the structure of HGF remains elusive, and few small/medium-sized molecules can modulate HGF. Here, we identified HiP-8, a macrocyclic peptide consisting of 12 amino acids, which selectively recognizes active HGF. Biochemical analysis and real-time single-molecule imaging by high-speed atomic force microscopy demonstrated that HiP-8 restricted the dynamic domains of HGF into static closed conformations, resulting in allosteric inhibition. Positron emission tomography using HiP-8 as a radiotracer enabled noninvasive visualization and simultaneous inhibition of HGF–MET activation status in tumors in a mouse model. Our results illustrate the conformational change in proteolytic activation of HGF and its detection and inhibition by a macrocyclic peptide, which may be useful for diagnosis and treatment of cancers.Embargo Period 6 month

A20 Silencing by Lipid Envelope-Type Nanoparticles Enhances the Efficiency of Lipopolysaccharide-Activated Dendritic Cells

In a previous report, we described the development of lipid envelope-type nanoparticles (MEND) modified with octaarginine (R8) and a pH-sensitive fusogenic peptide (GALA) for delivering short interference RNA (siRNA) to mouse dendritic cells (DCs). A20 was recently reported to be a negative regulator of the toll-like receptor and the tumor necrosis factor receptor signaling pathways. Although A20 would be expected to be a useful target for boosting the effects of adjuvants in DC immunotherapy, limited information is available regarding the use of A20-silenced DC by an original non-viral vector. In this study, we loaded anti-A20 siRNA into a MEND and investigated the gene knockdown activity in DC and the immunological functions of A20-silenced DC. The use of a MEND resulted in a significant A20 knockdown effect, and the A20-silenced DC resulted in an enhanced production of proinflammatory molecules, after lipopolysaccharide (LPS) stimulation. The expression of co-stimulatory molecules by LPS stimulation was also increased in the A20-silenced DC. The findings reported herein show that a MEND loaded with anti-A20 siRNA is a potent non-viral vector that has the ability to enhance the adjuvant effect of LPS in DC

A lipid nanoparticle for the efficient delivery of siRNA to dendritic cells

Applying small interfering RNA (siRNA) to dendritic cell (DC) based therapy represents a potential candidate for cancer immunotherapy. However, delivering siRNA to DCs is a challenging issue for non-viral vectors. To date, only viral vectors have achieved efficient gene silencing in DCs. We report herein that a novel cationic lipid, YSK12-C4, when loaded in a nanoparticle with siRNA (YSK12-C4 multifunctional envelope type nano device [YSK12-MEND]), greatly facilitated gene silencing in mouse DCs. The use of the YSK12-MEND resulted in a gene silencing efficiency in excess of 90%, with a median effective dose (ED50) of 1.5 nM, whereas the maximum gene silencing efficiency of Lipofectamine RNAiMAX was less than 60% and the ED50 was 25 nM. Furthermore, suppressor of cytokine signaling 1, an immune suppressive molecule in DCs, silenced in the mouse DC by the YSK12-MEND showed a drastic enhancement in cytokine production, resulting in the significant suppression of tumor growth when it was applied to DC-based therapy against a mouse lymphoma. These results clearly indicate that YSK12-MEND overcomes the obstacle associated with non-viral vectors and can be considered to be a promising non-viral vector for siRNA delivery to DCs, thus accelerating DC-based therapies with siRNA. (C) 2016 Elsevier B.V. All rights reserved

64Cu-labeling of small extracellular vesicle surfaces via a cross-bridged macrocyclic chelator for pharmacokinetic study by positron emission tomography imaging

We developed a method of labeling the surfaces of small extracellular vesicles (sEVs) with 64Cu using a crossbridged, macrocyclic chelator (CB-TE1A1P) and applied to pharmacokinetics study with positron emission tomography (PET). After incubation in 20% plasma for 10 min, approximately a half of the 64Cu was desorbed from 64Cu-labeled sEVs purified by phosphate-buffered saline wash, suggesting partly weak interaction without coordinating to CB-TE1A1P. After subsequent purification with albumin, 64Cu desorption was greatly reduced, resulting in a radiochemical stability of 95.7%. Notably, labeling did not alter the physicochemical and biological properties of sEVs. After intravenous injection, 64Cu-labeled sEVs rapidly disappeared from the systemic blood circulation and accumulated mainly in the liver and spleen of macrophage-competent mice. In macrophagedepleted mice, 64Cu-labeled sEVs remained in the blood circulation for a longer period and gradually accumulated in the liver and spleen, suggesting mechanisms of hepatic and splenic accumulation other than macrophage-dependent phagocytosis. The comparison of tissue uptake clearance between macrophagecompetent and macrophage-depleted mice suggests that macrophages contributed to 67% and 76% of sEV uptake in the liver and spleen, respectively. The application of this method in pharmacokinetics PET studies can be useful in preclinical and clinical research and the development of sEV treatment modalities.International Journal of Pharmaceutics, 624, art. no. 121968; 202