Biosynthesis of lanthionine-constrained agonists of G protein-coupled receptors.

The conformation with which natural agonistic peptides interact with G protein-coupled receptor(s) (GPCR(s)) partly results from intramolecular interactions such as hydrogen bridges or is induced by ligand-receptor interactions. The conformational freedom of a peptide can be constrained by intramolecular cross-links. Conformational constraints enhance the receptor specificity, may lead to biased activity and confer proteolytic resistance to peptidic GPCR agonists. Chemical synthesis allows to introduce a variety of cross-links into a peptide and is suitable for bulk production of relatively simple lead peptides. Lanthionines are thioether bridged alanines of which the two alanines can be introduced at different distances in chosen positions in a peptide. Thioether bridges are much more stable than disulfide bridges. Biosynthesis of lanthionine-constrained peptides exploiting engineered Gram-positive or Gram-negative bacteria that contain lanthionine-introducing enzymes constitutes a convenient method for discovery of lanthionine-stabilized GPCR agonists. The presence of an N-terminal leader peptide enables dehydratases to dehydrate serines and threonines in the peptide of interest after which a cyclase can couple the formed dehydroamino acids to cysteines forming (methyl)lanthionines. The leader peptide also guides the export of the formed lanthionine-containing precursor peptide out of Gram-positive bacteria via a lanthipeptide transporter. An engineered cleavage site in the C-terminus of the leader peptide allows to cleave off the leader peptide yielding the modified peptide of interest. Lanthipeptide GPCR agonists are an emerging class of therapeutics of which a few examples have demonstrated high efficacy in animal models of a variety of diseases. One lanthipeptide GPCR agonist has successfully passed clinical Phase Ia.

Agonists of MAS oncogene and angiotensin II type 2 receptors attenuate cardiopulmonary disease in rats with neonatal hyperoxia-induced lung injury.

Stimulation of MAS oncogene receptor (MAS) or angiotensin (Ang) receptor type 2 (AT2) may be novel therapeutic options for neonatal chronic lung disease (CLD) by counterbalancing the adverse effects of the potent vasoconstrictor angiotensin II, consisting of arterial hypertension (PAH)-induced right ventricular hypertrophy (RVH) and pulmonary inflammation. We determined the cardiopulmonary effects in neonatal rats with CLD of daily treatment during continuous exposure to 100% oxygen for 10 days with specific ligands for MAS [cyclic Ang-(1-7); 10-50 µg·kg(-1)·day(-1)] and AT2 [dKcAng-(1-7); 5-20 µg·kg(-1)·day(-1)]. Parameters investigated included lung and heart histopathology, fibrin deposition, vascular leakage, and differential mRNA expression in the lungs of key genes involved in the renin-angiotensin system, inflammation, coagulation, and alveolar development. We investigated the role of nitric oxide synthase inhibition with N(ω)-nitro-l-arginine methyl ester (25 mg·kg(-1)·day(-1)) during AT2 agonist treatment. Prophylactic treatment with agonists for MAS or AT2 for 10 days diminished cardiopulmonary injury by reducing alveolar septum thickness and medial wall thickness of small arterioles and preventing RVH. Both agonists attenuated the pulmonary influx of inflammatory cells, including macrophages (via AT2) and neutrophils (via MAS) but did not reduce alveolar enlargement and vascular alveolar leakage. The AT2 agonist attenuated hyperoxia-induced fibrin deposition. In conclusion, stimulation of MAS or AT2 attenuates cardiopulmonary injury by reducing pulmonary inflammation and preventing PAH-induced RVH but does not affect alveolar and vascular development in neonatal rats with experimental CLD. The beneficial effects of AT2 activation on experimental CLD were mediated via a NOS-independent mechanism.

The antitumor activity of hydrophobin SC3, a fungal protein.

The use of mushroom extracts has been common practice in traditional medicine for centuries, including the treatment of cancer. Proteins called hydrophobins are very abundant in mushrooms. Here, it was examined whether they have antitumor activity. Hydrophobin SC3 of Schizophyllum commune was injected daily intraperitoneally starting 1 day after tumor induction in two tumor mouse models (sarcoma and melanoma). SC3 reduced the size and weight of the melanoma significantly, but the sarcoma seemed not affected. However, microscopic analysis of the tumors 12 days after induction revealed a strong antitumor effect of SC3 on both tumors. The mitotic activity of the tumor decreased 1.6- (melanoma) to 2.3-fold (sarcoma), while the vital mass decreased 2.3- (melanoma) to 4.3-fold (sarcoma) compared to the control. Treatment did not cause any signs of toxicity. Behavior, animal growth, and weight of organs were similar to animals injected with vehicle, and no histological abnormalities were found in the organs. In vitro cell culture studies revealed no direct cytotoxic effect of SC3 towards sarcoma cells, while cytotoxic activity was observed towards melanoma cells at a high SC3 concentration. Daily treatment with SC3 did not result in detectable levels of anti-SC3 antibodies in the plasma. Instead, a cellular immune response was observed. Incubation of spleen cells with SC3 resulted in a 1.5- to 2.5-fold increase in interleukin-10 and TNF-α mRNA levels. In conclusion, the nontoxic fungal hydrophobin SC3 showed tumor-suppressive activity possibly via immunomodulation and may be of benefit as adjuvant in combination with chemotherapy and radiation.

Bacterial display and screening of posttranslationally thioether-stabilized peptides.

A major hurdle in the application of therapeutic peptides is their rapid degradation by peptidases. Thioether bridges effectively protect therapeutic peptides against breakdown, thereby strongly increasing bioavailability, enabling oral and pulmonary delivery and potentially significantly optimizing the receptor interaction of selected variants. To efficiently select optimal variants, a library of DNA-coupled thioether-bridged peptides is highly desirable. Here, we present a unique cell surface display system of thioether-bridged peptides and successfully demonstrate highly selective screening. Peptides are posttranslationally modified by thioether bridge-installing enzymes in Lactococcus lactis, followed by export and sortase-mediated covalent coupling to the lactococcal cell wall. This allows the combinatorial optimization and selection of medically and economically highly important therapeutic peptides with strongly enhanced therapeutic potential.

Angiotensin-(1-7) with thioether bridge: an angiotensin-converting enzyme-resistant, potent angiotensin-(1-7) analog.

The in vivo efficacy of many therapeutic peptides is hampered by their rapid proteolytic degradation. Cyclization of these therapeutic peptides is an excellent way to render them more resistant against breakdown. Here, we describe the enzymatic introduction of a thioether ring in angiotensin [Ang-(1-7)], a heptapeptide that plays a pivotal role in the renin-angiotensin system and possesses important therapeutic activities. The lactic acid bacterium Lactococcus lactis, equipped with the plasmid-based nisin modification machinery, was used to produce thioether-bridged Ang-(1-7). The resulting cyclized Ang-(1-7) is fully resistant against purified angiotensin-converting enzyme, has significantly increased stability in homogenates of different organs and in plasma derived from pig, and displays a strongly (34-fold) enhanced survival in Sprague-Dawley (SD) rats in vivo. With respect to functional activity, cyclized Ang-(1-7) induces relaxation of precontracted SD rat aorta rings in vitro. The magnitude of this effect is 2-fold larger than that obtained for natural Ang-(1-7). The Ang-(1-7) receptor antagonist D-Pro(7)-Ang-(1-7), which completely inhibits the activity of natural Ang-(1-7), also abolishes the vasodilation by cyclized Ang-(1-7), providing evidence that cyclized Ang-(1-7) also interacts with the Ang-(1-7) receptor. Taken together, applying a highly innovative enzymatic peptide stabilization method, we generated a stable Ang-(1-7) analog with strongly enhanced therapeutic potential.

Semi-microbiological synthesis of an active lysinoalanine-bridged analog of glucagon-like-peptide-1.

Some modified glucagon-like-peptide-1 (GLP-1) analogs are highly important for treating type 2 diabetes. Here we investigated whether GLP-1 analogs expressed in Lactococcus lactis could be substrates for modification and export by the nisin dehydratase and transporter enzyme. Subsequently we introduced a lysinoalanine by coupling a formed dehydroalanine with a lysine and investigated the structure and activity of the formed lysinoalanine-bridged GLP-1 analog. Our data show: (i) GLP-1 fused to the nisin leader peptide is very well exported via the nisin transporter NisT, (ii) production of leader-GLP-1 via NisT is higher than via the SEC system, (iii) leader-GLP-1 exported via NisT was more efficiently dehydrated by the nisin dehydratase NisB than when exported via the SEC system, (iv) individual serines and threonines in GLP-1 are dehydrated by NisB to a significantly different extent, (v) an introduced Ser30 is well dehydrated and can be coupled to Lys34 to form a lysinoalanine-bridged GLP-1 analog, (vi) a lysinoalanine(30-34) variant's conformation shifts in the presence of 25% trifluoroethanol towards a higher alpha helix content than observed for wild type GLP-1 under identical condition, (vii) a lysinoalanine(30-34) GLP-1 variant has retained significant activity. Taken together the data extend knowledge on the substrate specificities of NisT and NisB and their combined activity relative to export via the Sec system, and demonstrate that introducing a lysinoalanine bridge is an option for modifying therapeutic peptides.

Oral and pulmonary delivery of thioether-bridged angiotensin-(1-7).

Instability and proteolytic degradation limit the delivery options and in vivo efficacy of many therapeutic peptides. We previously generated a thioether stabilized angiotensin-(1-7) analog, cAng-(1-7), which is resistant against proteolytic degradation in the circulation. We here investigated oral and pulmonary delivery of this compound. In a first step we investigated the in vitro stability of the peptide under conditions that mimic those that will be met after oral administration. We demonstrated that cAng-(1-7) is stable at pH 2.0, a pH value close to that of the stomach, has enhanced resistance to breakdown by proteases from pancreas at pH 7.4, and is resistant to breakdown by proteases from liver at the lysosomal pH 5.0. We subsequently demonstrated that, in the absence of any delivery system or formulation, cAng-(1-7) can be delivered orally and via the lung, with bioavailabilities of 0.28+/-0.05% and 28+/-5%, whereas drug uptake was maximal after subcutaneous administration (bioavailability of 98+/-6%). Therapeutic concentrations could be reached via all three routes of administration. The data prove that introduction of a thioether bridge in peptides opens novel delivery options for medically important peptides.