Evidence that the lizard helospectin peptides are O-glycosylated

Novel glycosylated VIP analogs: synthesis, biological activity, and metabolic stability

Vasoactive intestinal peptide (VIP) is a prominent neuropeptide, exhibiting a wide spectrum of biological activities in mammals. However, the clinical applications of VIP are mainly hampered because of its rapid degradation in vivo. Peptide glycosylation, a procedure frequently used to increase peptide resistance to proteolytic degradation and consequently increase peptide metabolic stability, has not been performed yet on VIP. The presence of three N-glycosylation sites on VIP receptor type 1 (VPAC1) was previously demonstrated. Therefore, glycosylation of the VIP ligand could potentially increase its receptor affinity because of glyco-glyco interactions between the ligand and the receptor. In order to enhance VIP's metabolic stability and to increase its ligand-receptor binding/activation, eight glycosylated VIP derivatives were successfully synthesized by the solid-phase procedure. Each VIP analog was monoglycosylated by a monosaccharide addition to one amino-acid residue along the sequence. Glycosylation did not affect the alpha-helical structure shown by the native VIP in organic environment. Few glycosylated VIP analogs displayed highly potent VPAC1 receptor binding and cAMP-induced activation; only 4-6 fold lower in comparison to the native VIP. Furthermore, the peptide analog glycosylated on Thr11 ([11Glyc]VIP) showed a significantly enhanced stability toward trypsin enzymatic degradation in comparison to VIP. Analysis of the degradation products of [11Glyc]VIP showed that differently from VIP, incubation of the peptide [11Glyc]VIP with trypsin resulted in no cleavage at the Arg12-Leu13 peptide bond, suggesting that VIP glycosylation may lead to enhanced metabolic stability.

Helodermin-loaded nanoparticles: Characterization and transport across an in vitro model of the follicle-associated epithelium

M cells represent a potential portal for oral delivery of peptides and proteins due to their high endocytosis abilities. An in vitro model of human FAE (co-cultures) was used to evaluate the influence of M cells on the transport of free and encapsulated helodermin--a model peptide--across the intestinal epithelium. M cells enhanced transport of intact helodermin (18-fold, Papp=3 x 10(-6) cm s(-1)). As pegylation increased nanoparticle transport by M cells, helodermin was encapsulated in 200 nm nanoparticles containing PEG-b-PLA:PLGA 1:1. Stability of the selected formulation was demonstrated in simulated gastric and intestinal fluids. M cells increased the transport of helodermin encapsulated in these nanoparticles by a factor of 415, as compared to Caco-2 cells. Transport of free and encapsulated helodermin occurred most probably by endocytosis. In conclusion, M cells improved helodermin transport across the intestinal epithelium, confirming their high potential for oral delivery of peptides.

Helospectin, induces a potent relaxation of human airways in vitro

Helospectin is a neuropeptide of the vasoactive intestinal polypeptide/secretin/glucagon family. Several members of this family display biological activities relevant to obstructive airway disease and although the literature in this area is rapidly expanding very little is known about the effects of helospectin. The smooth muscle relaxation induced by helospectin on human bronchi and pulmonary arteries were therefore assessed in vitro, using tissue baths. Helospectin induced a potent relaxation of human bronchi and since helospectin-like immunoreactive nerve fibers along with possible target receptors previously have been reported in the human lung, helospectin might play a role in endogenous regulation of airway tone.