Structure-Activity Relationship of Synthetic Linear KTS-Peptides Containing Meta-Aminobenzoic Acid as Antagonists of α1ß1 Integrin with Anti-Angiogenic and Melanoma Anti-Tumor Activities.

To develop peptide drugs targeting integrin receptors, synthetic peptide ligands endowed with well-defined selective binding motifs are necessary. The snake venom KTS-containing disintegrins, which selectively block collagen α1ß1 integrin, were used as lead compounds for the synthesis and structure-activity relationship of a series of linear peptides containing the KTS-pharmacophore and alternating natural amino acids and 3-aminobenzoic acid (MABA). To ensure a better stiffness and metabolic stability, one, two and three MABA residues, were introduced around the KTS pharmacophore motif. Molecular dynamics simulations determined that the solution conformation of MABA peptide 4 is more compact, underwent larger conformational changes until convergence, and spent most of the time in a single cluster. The peptides' binding affinity has been characterized by an enzyme linked immunosorbent assay in which the most potent peptide 4 inhibited with IC50 of 324 ± 8 µM and 550 ± 45 µM the binding of GST-α1-A domain to collagen IV fragment CB3, and the cell adhesion to collagen IV using α1-overexpressor cells, respectively. Docking studies and MM-GBSA calculations confirmed that peptide 4 binds a smaller region of the integrin near the collagen-binding site and penetrated deeper into the binding site near Trp1. Peptide 4 inhibited tube formation by endothelial cell migration in the Matrigel angiogenesis in vitro assay. Peptide 4 was acutely tolerated by mice, showed stability in human serum, decreased tumor volume and angiogenesis, and significantly increased the survival of mice injected with B16 melanoma cells. These findings propose that MABA-peptide 4 can further serve as an α1ß1-integrin antagonist lead compound for further drug optimization in angiogenesis and cancer therapy.

Synthesis of Novel Arginine Building Blocks with Increased Lipophilicity Compatible with Solid-Phase Peptide Synthesis.

Arginine, due to the guanidine moiety, increases peptides' hydrophilicity and enables interactions with charged molecules, but at the same time, its presence in a peptide chain might reduce its permeability through biological membranes. This might be resolved by temporary coverage of the peptide charge by lipophilic, enzyme-sensitive alkoxycarbonyl groups. Unfortunately, such a modification of a guanidine moiety has not been reported to date and turned out to be challenging. Here, we present a new, optimized strategy to obtain arginine building blocks with increased lipophilicity that were successfully utilized in the solid-phase peptide synthesis of novel arginine vasopressin prodrugs.

PH-Binding Motif in PAR4 Oncogene: From Molecular Mechanism to Drug Design.

While the role of G-protein-coupled receptors (GPCR) in cancer is acknowledged, their underlying signaling pathways are understudied. Protease-activated receptors (PAR), a subgroup of GPCRs, form a family of four members (PAR1-4) centrally involved in epithelial malignancies. PAR4 emerges as a potent oncogene, capable of inducing tumor generation. Here, we demonstrate identification of a pleckstrin-homology (PH)-binding motif within PAR4, critical for colon cancer growth. In addition to PH-Akt/PKB association, other PH-containing signal proteins such as Gab1 and Sos1 also associate with PAR4. Point mutations are in the C-tail of PAR4 PH-binding domain; F347 L and D349A, but not E346A, abrogate these associations. Pc(4-4), a lead backbone cyclic peptide, was selected out of a mini-library, directed toward PAR2&4 PH-binding motifs. It effectively attenuates PAR2&4-Akt/PKB associations; PAR4 instigated Matrigel invasion and migration in vitro and tumor development in vivo. EGFR/erbB is among the most prominent cancer targets. AYPGKF peptide ligand activation of PAR4 induces EGF receptor (EGFR) Tyr-phosphorylation, effectively inhibited by Pc(4-4). The presence of PAR2 and PAR4 in biopsies of aggressive breast and colon cancer tissue specimens is demonstrated. We propose that Pc(4-4) may serve as a powerful drug not only toward PAR-expressing tumors but also for treating EGFR/erbB-expressing tumors in cases of resistance to traditional therapies. Overall, our studies are expected to allocate new targets for cancer therapy. Pc(4-4) may become a promising candidate for future therapeutic cancer treatment.

Novel humanin analogs confer neuroprotection and myoprotection to neuronal and myoblast cell cultures exposed to ischemia-like and doxorubicin-induced cell death insults.

Humanin (HN) is a 24-amino acid mitochondrial-derived peptide, best known for its ability to protect neurons from damage caused by ischemic stroke and neurodegenerative insults and cardiomyocytes from myocardial infarction or doxorubicin (Dox)-induced cardiotoxicity. This study examines the neuroprotective and myoprotective effects of HN novel synthetic analogs HUJInin and c(D-Ser14-HN), prepared by solid-phase peptide synthesis. The cellular models employed were oxygen-glucose-deprivation (OGD) followed by reoxygenation (R)-induced neurotoxicity in PC12 and SH-SY5Y neuronal cell cultures and Dox-induced cardiotoxicity in H9c2 and C2C12 myoblast cell cultures, respectively. Necrotic and apoptotic cell death was measured by LDH release and caspase-3 activity. Erk 1/2 and AKT phosphorylations were examined by western blotting. Mitochondrial calcium and mitochondrial membrane potential were measured using the fluorescent dye tetramethylrhodamine-methyl ester. It was found that HUJInin and c(D-Ser14-HN) conferred significant dose-dependent neuroprotection, a phenomenon related to attenuation of OGD insult-induced Erk 1/2 phosphorylation, stimulation of AKT phosphorylation and improvement of mitochondrial functions. These peptides also conferred myoprotective effect towards Dox-induced apo-necrotic cell death insults. HUJInin and c(D-Ser14-HN) synthetic analogs may provide new lead compounds for the development of a potential candidate drug for stroke treatment and/or Dox-induced cardiotoxicity therapy in cancer patients.

Orally Active Peptides: Is There a Magic Bullet?

For decades, the development of peptides as potential drugs was aimed solely at peptides with the highest affinity, receptor selectivity, or stability against enzymatic degradation. However, optimization of their oral availability is highly desirable to establish orally active peptides as potential drug candidates for everyday use. A twofold optimization process is necessary to produce orally active peptides: 1) optimization of the affinity and selectivity and 2) optimization of the oral availability. These two steps must be performed sequentially for the rational design of orally active peptides. Nevertheless, additional knowledge is required to understand which structural changes increase oral availability, followed by incorporation of these elements into a peptide without changing its other biological properties. Considerable efforts have been made to understand the influence of these modifications on oral availability. One approach is to improve the oral availability of a peptide that has been previously optimized for biological activity, as described in (1) above. The second approach is to first identify an intestinally permeable, metabolically stable peptide scaffold and then introduce the functional groups necessary for the desired biological function. Previous approaches to achieving peptide oral availability have been claimed to have general applicability but, thus far, most of these solutions have not been successful in other cases. This Review discusses diverse chemical modifications, model peptides optimized for bioavailability, and orally active peptides to summarize the state of the research on the oral activity of peptides. We explain why no simple and straightforward strategy (i.e. a "magic bullet") exists for the design of an orally active peptide with a druglike biological function.

Overcoming the Lack of Oral Availability of Cyclic Hexapeptides: Design of a Selective and Orally Available Ligand for the Integrin†αvß3.

A highly systematic approach for the development of both orally bioavailable and bioactive cyclic N-methylated hexapeptides as high affinity ligands for the integrin αvß3 is based on two concepts: a) screening of systematically designed libraries with spatial diversity and b) masking of the peptide charge with a lipophilic protecting group. The key steps of the method are 1) initial design of a combinatorial library of N-methylated analogues of the stem peptide cyclo(d-Ala-Ala5 ); 2) selection of cyclic peptides with the highest intestinal permeability; 3) design of sublibraries with the bioactive RGD sequence in all possible positions; 4) selection of the best ligands for RGD-recognizing integrin subtypes; 5) fine-tuning of the affinity and selectivity by additional Ala to Xaa substitutions; 6) protection of the charged functional groups according to the prodrug concept to regain intestinal and oral permeability; 7) proof of biological effects in mice after oral administration.

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.

Shared epitope-antagonistic ligands: a new therapeutic strategy in mice with erosive arthritis.

OBJECTIVE: The mechanisms underlying bone damage in rheumatoid arthritis (RA) are incompletely understood. We recently identified the shared epitope (SE), an HLA-DRB1-coded 5-amino acid sequence motif carried by the majority of RA patients as a signal transduction ligand that interacts with cell surface calreticulin and accelerates osteoclast (OC)-mediated bone damage in collagen-induced arthritis (CIA). Given the role of the SE/calreticulin pathway in arthritis-associated bone damage, we sought to determine the therapeutic targetability of calreticulin. METHODS: A library of backbone-cyclized peptidomimetic compounds, all carrying an identical core DKCLA sequence, was synthesized. The ability of these compounds to inhibit SE-activated signaling and OC differentiation was tested in vitro. The effect on disease severity and OC-mediated bone damage was studied by weekly intraperitoneal administration of the compounds to DBA/1 mice with CIA. RESULTS: Two members of the peptidomimetics library were found to have SE-antagonistic effects and antiosteoclast differentiation effects at picomolar concentrations in vitro. The lead mimetic compound, designated HS(4-4)c Trp, potently ameliorated arthritis and bone damage in vivo when administered in picogram doses to mice with CIA. Another mimetic analog, designated HS(3-4)c Trp, was found to lack activity, both in vitro and in vivo. The differential activity of the 2 analogs depended on minor differences in their respective ring sizes and correlated with distinctive geometry when computationally docked to the SE binding site on calreticulin. CONCLUSION: These findings identify calreticulin as a novel therapeutic target in erosive arthritis and provide sound rationale and early structure/activity relationships for future drug design.

Mechanistic studies of malonic acid-mediated in situ acylation.

We have previously introduced an easy to perform, cost-effective and highly efficient acetylation technique for solid phase synthesis (SPPS). Malonic acid is used as a precursor and the reaction proceeds via a reactive ketene that acetylates the target amine. Here we present a detailed mechanistic study of the malonic acid-mediated acylation. The influence of reaction conditions, peptide sequence and reagents was systematically studied. Our results show that the methodology can be successfully applied to different types of peptides and nonpeptidic molecules irrespective of their structure, sequence, or conformation. Using alkyl, phenyl, and benzyl malonic acid, we synthesized various acyl peptides with almost quantitative yields. The ketenes obtained from the different malonic acid derived precursors were characterized by in situ (1) H-NMR. The reaction proceeded in short reaction times and resulted in excellent yields when using uronium-based coupling agents, DIPEA as a base, DMF/DMSO/NMP as solvents, Rink amide/Wang/Merrifield resins, temperature of 20°C, pH 8-12 and 5 min preactivation at inert atmosphere. The reaction was unaffected by Lewis acids, transition metal ions, surfactants, or salt. DFT studies support the kinetically favorable concerted mechanism for CO2 and ketene formation that leads to the thermodynamically stable acylated products. We conclude that the malonic acid-mediated acylation is a general method applicable to various target molecules.

Inhibition of inositol monophosphatase (IMPase) at the calbindin-D28k binding site: molecular and behavioral aspects.

Bipolar-disorder (manic-depressive illness) is a severe chronic illness affecting ∼1% of the adult population. It is treated with mood-stabilizers, the prototypic one being lithium-salts (lithium), but it has life threatening side-effects and a significant number of patients fail to respond. The lithium-inhibitable enzyme inositol-monophosphatase (IMPase) is one of the viable targets for lithium's mechanism of action. Calbindin-D28k (calbindin) up-regulates IMPase activity. The IMPase-calbindincomplex was modeled using the program MolFit. The in-silico model indicated that the 55-66 amino-acid segment of IMPase anchors calbindin via Lys59 and Lys61 with a glutamate in between (Lys-Glu-Lys motif) and that the motif interacts with residues Asp24 and Asp26 of calbindin. We found that differently from wildtype calbindin, IMPase was not activated by mutated calbindin in which Asp24 and Asp26 were replaced by alanine. Calbindin's effect was significantly reduced by a linear peptide with the sequence of amino acids 58-63 of IMPase (peptide 1) and by six amino-acid linear peptides including at least part of the Lys-Glu-Lys motif. The three amino-acid peptide Lys-Glu-Lys or five amino-acid linear peptides containing this motif were ineffective. Mice administered peptide 1 intracerebroventricularly exhibited a significant anti-depressant-like reduced immobility in the forced-swim test. Based on the sequence of peptide 1, and to potentially increase the peptide's stability, cyclic and linear pre-cyclic analog peptides were synthesized. One cyclic peptide and one linear pre-cyclic analog peptide inhibited calbindin-activated brain IMPase activity in-vitro. Our findings may lead to the development of molecules capable of inhibiting IMPase activity at an alternative site than that of lithium.

Studying protein-peptide interactions using benzophenone units: a case study of protein kinase B/Akt and its inhibitor PTR6154.

Protein-protein interactions (PPIs) govern nearly all processes in living cells. Peptides play an important role in studying PPIs. Peptides carrying photoaffinity labels that covalently bind the interacting protein can be used to obtain more accurate information regarding PPIs. Benzophenone (BP) is a useful photoaffinity label that is widely used to study PPIs. We developed a one-pot two-step synthesis for the preparation of novel BP units. To map the binding site more thoroughly, linkers of various lengths were attached to the BP moiety. These units can be incorporated into peptide sequences using well-established solid phase peptide synthesis (SPPS) protocols. As a proof of concept, we studied the interaction between protein kinase B (PKB/Akt) and its synthetic peptide inhibitor, PTR6154. The methodology is general and can be implemented to study PPIs in a variety of biological systems.

Developing potent backbone cyclic peptides bearing the shared epitope sequence as rheumatoid arthritis drug-leads.

Rheumatoid arthritis (RA) is a common human leukocyte antigen-associated disease. Most RA patients have a five-residue sequence motif called the shared epitope (SE) in the DRß-chain of the HLA-DRB1 protein. The SE was found to activate nitric oxide (NO) production, suggesting a possible mechanism for RA development. The native conformation of the SE is presumed to be an α-helix, thus using cyclic peptides to stabilize this conformation may produce a potent SE mimetic which will have drug-like properties. We present the development of a backbone cyclic SE mimetic that activates NO production in the low nM range. Circular dichroism analysis revealed a conformational change from for the parent linear peptides to the cyclic analogs. The most active cyclic analog is completely stable towards trypsin/chymotrypsin degradation while the linear 15-mer analogs completely degraded within 30 min. The outcome of this study is a potent cyclic peptide with drug-like properties that can be used as a template for drug development.

Metabolic stability of peptidomimetics: N-methyl and aza heptapeptide analogs of a PKB/Akt inhibitor.

Linear peptides suffer from poor pharmacokinetic and pharmacodynamic properties. Peptidomimetics are designed to overcome these pharmacological drawbacks while maintaining the biological effects of the parent peptides. Aza-peptides, in which an alpha carbon is replaced with nitrogen, are promising peptidomimetic analogs; however, little is known about the stability of these analogs toward enzymatic degradation. We performed systematic aza and N-methyl scans of a PKB/Akt inhibitor, PTR6154. We evaluated the stability of the aza-scan and N-methyl scan libraries toward enzymatic degradation by trypsin/chymotrypsin. Our results indicate that the modification site is important for metabolic stability and that aza-peptides have a more global effect than N-methylation, affecting cleavage sites distant from the modification site.

Backbone cyclic peptide inhibitors of protein kinase B (PKB/Akt).

Elevated levels of activated protein kinase B (PKB/Akt) have been detected in many types of cancer. Substrate-based peptide inhibitors have the advantage of selectivity due to their extensive interactions with the kinase-specific substrate binding site but often lack necessary pharmacological properties. Chemical modifications of potent peptide inhibitors, such as cyclization, may overcome these drawbacks while maintaining potency. We present an extensive structure-activity relationship (SAR) study of a potent peptide-based PKB/Akt inhibitor. Two backbone cyclic (BC) peptide libraries with varying modes of cyclization, bridge chemistry, and ring size were synthesized and evaluated for in vitro PKB/Akt inhibition. Backbone-to-backbone urea BC peptides were more potent than N-terminus-to-backbone amide BC peptides. Several analogues were up to 10-fold more active than the parent linear peptide. Some activity trends could be rationalized using computational surface mapping of the PKB/Akt kinase catalytic domain. The novel molecules have enhanced pharmacological properties which make them promising lead candidates.

Microwave-assisted solid-phase aza-peptide synthesis: aza scan of a PKB/Akt inhibitor using aza-arginine and aza-proline precursors.

Aza-peptides are peptidomimetics in which one or more of the α-carbons, bearing the side-chain residues, has been replaced by a nitrogen. These peptidomimetics have been shown to be promising for the generation of drug leads and for structure-activity relationship studies. Aza-scan is the systematic replacement of amino acid residues in a given peptide with their aza counterparts. We report here an aza-scan of a potent, peptide-based PKB/Akt inhibitor, PTR6154. Procedures for microwave-assisted, Fmoc/t-Bu chemistry, solid-phase aza-peptide synthesis were developed which significantly reduce standard reaction time and are suitable for automation. Novel substituted hydrazines have been prepared for the straightforward incorporation of aza-arginine and aza-proline residues. This work will enable aza-scan to become a more common and standard method for structure-activity relationship studies of peptides.

Novel method for the synthesis of urea backbone cyclic peptides using new Alloc-protected glycine building units.

Cyclization of bioactive peptides, utilizing functional groups serving as natural pharmacophors, is often accompanied with loss of activity. The backbone cyclization approach was developed to overcome this limitation and enhance pharmacological properties. Backbone cyclic peptides are prepared by the incorporation of special building units, capable of forming amide, disulfide and coordinative bonds. Urea bridge is often used for the preparation of cyclic peptides by connecting two amine functionalized side chains. Here we present urea backbone cyclization as an additional method for the preparation of backbone cyclic peptide libraries. A straightforward method for the synthesis of crystalline Fmoc-N(alpha) [omega-amino(Alloc)-alkyl] glycine building units is presented. A set of urea backbone cyclic Glycogen Synthase Kinase 3 analogs was prepared and assessed for protein kinase B inhibition as anticancer leads.

Synthesis and structure-activity relationship studies of peptidomimetic PKB/Akt inhibitors: the significance of backbone interactions.

Elevated levels of activated Protein Kinase B (PKB/Akt) have been detected in many types of human cancer. In contrast to ATP site inhibitors, substrate-based inhibitors are more likely to be selective because of extensive interactions with the specific substrate binding site. Unfortunately, peptide-based inhibitors lack important pharmacological properties that are required of drug candidates. Chemical modifications of potent peptide inhibitors, such as peptoids and N(alpha)-methylated amino acids, may overcome these drawbacks, while maintaining potency. We present a structure-activity relationship study of a potent, peptide-based PKB/Akt inhibitor, PTR6154. The study was designed to evaluate backbone modifications on the inhibitory activity of PTR6154. Two peptidomimetic libraries, peptoid and N(alpha)-methylation, based on PTR6154, were synthesized and evaluated for in vitro PKB/Akt inhibition efficiency. All the peptoid analogs reduced potency significantly, as well as most of the members of the N-methyl library, suggesting that the backbone conformation and/or hydrogen bond interactions of PTR6154 derivatives are essential for inhibition activity. Two N-terminal members of the N-methyl library did not decrease potency and can be used as future drug leads.

N-methylation of peptides: a new perspective in medicinal chemistry.

The potential of peptides as drug candidates is limited by their poor pharmacokinetic properties. Many peptides have a short half-life in vivo and a lack of oral availability. Inspired by the excellent pharmacokinetic profile of cyclosporine, a natural, multiply N-methylated cyclic peptide, we envisioned multiple N-methylation as a promising way to rationally improve key pharmacokinetic characteristics. In this Account, we summarize our efforts toward modulating the properties of peptides by multiple N-methylation. As a first step, we simplified the synthesis of N-methylated amino acids in solution, by employing very mild conditions that could be tolerated by the diverse protecting groups required when working with naturally occurring amino acids. We also report the rapid and inexpensive syntheses of N-methylated peptides on a solid support; this facilitated the N-methyl scanning of bioactive peptides. Because of a lack of information regarding the conformational behavior of multiply N-methylated peptides, a complete library of N-methylated cyclic alanine pentapeptides was synthesized. The library provided valuable insight into the conformational modulation of cyclic peptides by N-methylation. This information is extremely valuable for the design of bioactive peptides and spatial screening of cyclic N-methylated peptides. To demonstrate the applicability of N-methylation to highly active but poorly bioavailable peptides, we performed a full N-methyl scan of the cyclopeptidic somatostatin analog cyclo(-PFwKTF-), known as the Veber-Hirschmann peptide. We show here for the first time that the simple approach of multiple N-methylation can drastically improve the metabolic stability and intestinal permeability of peptides, for example, resulting in 10% oral bioavailability for a tri-N-methylated Veber-Hirschmann peptide analog. In addition, we also describe a designed approach to N-methylated peptide library synthesis, which can accelerate the screening of N-methylated bioactive peptides. Finally, we find that multiple N-methylation of a cyclic hexapeptide integrin antagonist of GPIIb-IIIa (alphaIIb beta3 integrin), cyclo(-GRGDfL-), increases the selectivity of this peptide toward different integrin subtypes. This result demonstrates the utility of multiple N-methylation in elucidating the bioactive conformation of peptides.

Synthesis of a novel macrocyclic library: discovery of an IGF-1R inhibitor.

We present a new approach for the conversion of active sequences of proteins and peptides into small molecules. A library of macrocyclic disulfide molecules was made, in which the active pharmacophores of the parent peptide are preserved while the size of the macromolecular scaffold on which the pharmacophores are arranged is varied. This enables a systematic search for macromolecules in which the pharmacophores are in an appropriate conformation for biological activity. We developed two procedures for the synthesis of such libraries from building blocks that include commercial amino acids and functionalized aldehydes. Chemical synthesis using the "tea-bag" method gave a library with higher diversity, but low yields, compared to the manual synthesis of the library, in which the compounds were synthesized in individual vessels and the yield and purity improved dramatically. As a proof of concept, we synthesized a 34-member library derived from the sequence of the activation loop of insulin-like growth factor-1 receptor. Selected compounds were screened, and one was found to be biologically active in the low micromolar range. The concept presented here may prove particularly useful in cases where the pharmacophores are known but need to be systematically screened for a spatial arrangement that will enable biological activity.