Oded Ovadia

Improving Oral Bioavailability of Peptides by Multiple N-Methylation: Somatostatin Analogues†

Low bioavailability of peptides following oral administration is attributed to their inactivation in the gastro–intestinal tract through enhanced enzymatic degradation in the gut wall by a variety of peptidases expressed at the enterocytes brush border, and to poor intestinal permeation. In addition, the instability of peptides toward peptidases in the systemic blood circulation causes rapid elimination (i.e., short half-life). These factors limit the use of peptides as therapeutic agents in the clinical setting. Several strategies have been used to reduce enzymatic cleavage and uptake into the systemic blood circulation, including prodrug approaches, peptidomimetics, and structural modifications, such as covalent attachment of polyethylene glycol (PEG), lipidation, and chemical modifications, for example, cyclization, d-amino acid substitution, and N-methylation. Cyclic peptides show improved chemical stability and thereby display longer biological half-life compared to their linear counterparts. Yet, additional modifications are required to generate peptides with enhanced enzymatic stability and improved oral bioavailability. One of the techniques suggested to improve the enzymatic stability of peptides is N-methylation. We recently developed a simplified method which allows fast and efficient multiple N-methylation of peptides on solid support. This simplified synthetic capability led us to study the influence of multiple N-methylation of the peptide backbone on its conformation and bioactivity. Inspired by the bioavailability of the highly N-methylated transplantation drug cyclosporin A, which can be administered orally although it violates all Lipinski9s rules on oral bioavailability; we assumed this bioavailability was a result of its multiple N-methylation together with cyclization. Thus, it is possible to overcome the above mentioned bioavailability drawbacks of peptides providing both the biological activity and the receptor selectivity by multiple N-methylation of cyclic peptides. Hence, we planned to screen a complete library of all the possible N-methylated analogues of the Veber–Hirschmann cyclic hexapeptide cyclo(-PFwKTF-) (1; Figure 1) which was reported to be selective towards sst2 and

Intestinal permeability of cyclic peptides: common key backbone motifs identified.

Insufficient oral bioavailability is considered as a key limitation for the widespread development of peptides as therapeutics. While the oral bioavailability of small organic compounds is often estimated from simple rules, similar rules do not apply to peptides, and even the high oral bioavailability that is described for a small number of peptides is not well understood. Here we present two highly Caco-2 permeable template structures based on a library of 54 cyclo(-D-Ala-Ala(5)-) peptides with different N-methylation patterns. The first (all-trans) template structure possesses two β-turns of type II along Ala(6)-D-Ala(1) and Ala(3)-Ala(4) and is only found for one peptide with two N-methyl groups at D-Ala(1) and Ala(6) [(NMe(1,6)]. The second (single-cis) template possesses a characteristic cis peptide bond preceding Ala(5), which results in type VI β-turn geometry along Ala(4)-Ala(5). Although the second template structure is found in seven peptides carrying N-methyl groups on Ala(5), high Caco-2 permeability is only found for a subgroup of two of them [NMe(1,5) and NMe(1,2,4,5)], suggesting that N-methylation of D-Ala(1) is a prerequisite for high permeability of the second template structure. The structural similarity of the second template structure with the orally bioavailable somatostatin analog cyclo(-Pro-Phe-NMe-D-Trp-NMe-Lys-Thr-NMe-Phe-), and the striking resemblance with both β-turns of the orally bioavailable peptide cyclosporine A, suggests that the introduction of bioactive sequences on the highly Caco-2 permeable templates may result in potent orally bioavailable drug candidates.

The Effect of Multiple N-Methylation on Intestinal Permeability of Cyclic Hexapeptides

Recent progress in peptide synthesis simplified the synthesis of multiple N-methylation of peptides. To evaluate how multiple N-methylation affects the bioavailability of peptides, a poly alanine cyclic hexapeptide library (n = 54), varying in the number of N-methyl (N-Me) groups (1-5 groups) and their position, was synthesized. The peptides were evaluated for their intestinal permeability in vitro using the Caco-2 model. Further evaluation of the transport route of chosen analogues was performed using rat excised viable intestinal tissue, a novel colorimetric liposomal model and the parallel artificial membrane permeability assay (PAMPA). While most members were found to have poor permeability (permeability coefficient, P(app) < 1 x 10⁻⁶ cm/s, lower than mannitol, the marker for paracellular permeability), 10 analogues were found to have high Caco-2 permeability, (P(app) > 1 x 10⁻⁵ cm/s, similar to testosterone, a marker of transcellular permeability). No correlation was found between the number of N-methylated groups and the enhanced permeability. However, 9/10 permeable peptides in the Caco-2 model included an N-Me placed adjacently to the D-Ala position. While the exact transport route was not fully characterized, the data suggests a facilitated diffusion. It can be concluded that multiple N-methylation of peptides may improve intestinal permeability, and therefore can be utilized in the design of orally available peptide-based therapeutics.

Backbone cyclic peptidomimetic melanocortin-4 receptor agonist as a novel orally administrated drug lead for treating obesity.

The tetrapeptide sequence His-Phe-Arg-Trp, derived from melanocyte-stimulating hormone (alphaMSH) and its analogs, causes a decrease in food intake and elevates energy utilization upon binding to the melanocortin-4 receptor (MC4R). To utilize this sequence as an effective agent for treating obesity, we improved its metabolic stability and intestinal permeability by synthesizing a library of backbone cyclic peptidomimetic derivatives. One analog, peptide 1 (BL3020-1), was selected according to its selectivity in activating the MC4R, its favorable transcellular penetration through enterocytes and its enhanced intestinal metabolic stability. This peptide was detected in the brain following oral administration to rats. A single oral dose of 0.5 mg/kg in mice led to reduced food consumption (up to 48% vs the control group) that lasted for 5 h. Repetitive once daily oral dosing (0.5 mg/kg/day) for 12 days reduced weight gain. Backbone cyclization was shown to produce a potential drug lead for treating obesity.

Improvement of drug-like properties of peptides: the somatostatin paradigm.

Importance of the field: Peptides are promising candidates as therapeutic agents due to their wide involvement in physiological processes. However, their often non-selective activity and their poor drug-like properties, mainly their inherent low stability to enzymatic degradation and poor oral bioavailability, limit their clinical potential. Somatostatin is a peptide hormone involved in many different biological functions. The role of its five different receptor subtypes and their interplay in medicinal processes is only partially understood. In addition, it suffers from poor drug-like properties. Areas covered in this review: We review several promising chemical modifications, including head-to-tail and backbone cyclization as well as N-methylation, which were applied throughout the years in the development of various somatostatin analogs. What the reader will gain: These modifications led to enhanced metabolic stability and intestinal permeability. In addition, several analogs exhibited specific receptor subtype activation. Take home message: The results presented in this review suggest a potential use of these chemical modifications in order to achieve required characteristics for a bioactive peptide, mainly for clinical usage.

Structure-Activity Relationship and Metabolic Stability Studies of Backbone Cyclization and N-Methylation of Melanocortin Peptides

Backbone cyclization (BC) and N-methylation have been shown to enhance the activity and/or selectivity of biologically active peptides and improve metabolic stability and intestinal permeability. In this study, we describe the synthesis, structure-activity relationship (SAR) and intestinal metabolic stability of a backbone cyclic peptide library, BL3020, based on the linear alpha-Melanocyte stimulating hormone analog Phe-D-Phe-Arg-Trp-Gly. The drug lead, BL3020-1, selected from the BL3020 library (compound 1) has been shown to inhibit weight gain in mice following oral administration. Another member of the BL3020 library, BL3020-17, showed improved biological activity towards the mMC4R, in comparison to BL3020-1, although neither were selective for MC4R or MC5R. N-methylation, which restrains conformational freedom while increasing metabolic stability beyond that which is imparted by BC, was used to find analogs with increased selectivity. N-methylated backbone cyclic libraries were synthesized based on the BL3020 library. SAR studies showed that all the N-methylated backbone cyclic peptides demonstrated reduced biological activity and selectivity for all the analyzed receptors. N-methylation of active backbone cyclic peptides destabilized the active conformation or stabilized an inactive conformation, rendering the peptides biologically inactive. N-methylation of backbone cyclic peptides maintained stability to degradation by intestinal enzymes.

Carrier‐mediated transport of metformin across the human placenta determined by using the ex vivo perfusion of the placental cotyledon model

Metformin is a polar positively charged compound. The aim of the study was to characterize its permeability across the human placenta using the ex vivo placental perfusion model.

The effect of backbone cyclization on PK/PD properties of bioactive peptide-peptoid hybrids: The melanocortin agonist paradigm

A peptide-peptoid hybrid (peptomer) library was designed and synthesized, based on the sequence Phe-d-Phe-Arg-Trp-Gly. This sequence was previously found to specifically activate the melanocortin-4-receptor (MC4R) which participates in regulation of energy homeostasis and appetite. The library of peptomers included a peptoid bond in the Phe and/or d-Phe position and consisted of linear and backbone cyclic analogs, differed in their ring size. While the linear peptides rapidly degraded in serum and in brush border membrane vesicles (BBMVs), the linear peptomers were more stable. Backbone cyclic peptomers were also stable under the same conditions. Backbone cyclization significantly increased the intestinal permeability of two peptomers compared to their linear counterparts, in the Caco-2 model. Pharmacological evaluation revealed that two linear and one backbone cyclic peptomer, were found active towards MC4R at the nanomolar range. Thus, the conformational constrains imposed by these local and global modifications affect both the pharmacokinetic and pharmacodynamic properties of the parent peptide. This study demonstrates the potential of imposing backbone cyclization on bioactive peptomers as a promising approach in developing an orally available peptidomimetic drug leads.

Differential Expression of Prokineticin Receptors by Endothelial Cells Derived from Different Vascular Beds: a Physiological Basis for Distinct Endothelial Function

Prokineticins (PKs), multifunctional secreted proteins, activate two endogenous G protein-coupled receptors (R) termed PK-R1 and PK-R2. It was suggested that PK1 acts selectively on the endothelium of endocrine glands, yet PK-Rs were also found in endothelial cells (EC) derived from other tissues. Therefore we examined here the characteristics of PK - system in EC derived from different vascular beds. Corpus luteum (CL)-derived EC (LEC) expressed both PK-R1 and PK-R2. In contrast, EC from the aorta (BAEC) only expressed PK-R1. Interestingly, also EC from brain capillaries (BCEC) expressed only PK-R1. The distinct pattern of PK-R expression may define EC phenotypic heterogeneity. Regulation of receptor expression also differed in BAEC and LEC: TNFα markedly reduced PK-R1 only in BAEC, but serum removal decreased PK-R1 in both cell types. Therefore, if cells were initially serum-starved, the anti-apoptotic effect of PKs was retained only in LEC. Yet, addition of PKs concomitant with serum removal enhanced the proliferation and survival of both BAEC and LEC. Immunohistochemical staining showed that in CL and aorta PK1 was expressed in smooth muscle cells in vessel walls, suggesting a paracrine mode of action. PK1 enhanced the net paracellular transport (measured by electrical resistance and Mannitol transport) in LEC but not in BAEC or BCEC. Collectively, these findings indicate that PKs serve as mitogens and survival factors for microvascular (LEC) and macrovascular (BAEC) EC. However, the distinct expression and function of PK receptors suggest different physiological roles for these receptors in various EC types.

cis‐Peptide Bonds: A Key for Intestinal Permeability of Peptides?

Recent structural studies on libraries of cyclic hexapeptides led to the identification of common backbone conformations that may be instrumental to the oral availability of peptides. Furthermore, the observation of differential Caco-2 permeabilities of enantiomeric pairs of some of these peptides strongly supports the concept of conformational specificity driven uptake and also suggests a pivotal role of carrier-mediated pathways for peptide transport, especially for scaffolds of polar nature. This work presents investigations on the Caco-2 and PAMPA permeability profiles of 13 selected N-methylated cyclic pentaalanine peptides derived from the basic cyclo(-D-Ala-Ala4 -) template. These molecules generally showed moderate to low transport in intestinal epithelia with a few of them exhibiting a Caco-2 permeability equal to or slightly higher than that of mannitol, a marker for paracellular permeability. We identified that the majority of the permeable cyclic penta- and hexapeptides possess an N-methylated cis-peptide bond, a structural feature that is also present in the orally available peptides cyclosporine A and the tri-N-methylated analogue of the Veber-Hirschmann peptide. Based on these observations it appears that the presence of N-methylated cis-peptide bonds at certain locations may promote the intestinal permeability of peptides through a suitable conformational preorganization.