Target engagement and intracellular delivery of mono- and bivalent LDL receptor-binding peptide-cargo conjugates: Implications for the rational design of new targeted drug therapies.

Targeted delivery to specific tissues and subcellular compartments is of paramount importance to optimize therapeutic or diagnostic interventions while minimizing side-effects. Using recently identified LDL receptor (LDLR) -targeting small synthetic peptide-vectors conjugated to model cargos of different nature and size, we investigated in LDLR-expressing cells the impact of vector-cargo molecular engineering and coupling valency, as well as the cellular exposure duration on their target engagement and intracellular trafficking and delivery profiles. All vector-cargo conjugates evaluated were found to be delivered to late compartments together with the natural ligand LDL, although to varying extents and with different kinetics. Partial recycling together with the LDLR was also consistently observed. Under continuous cellular exposure, the extent of intracellular vector-cargo delivery primarily relies on their endosomal unloading potential. In this condition, the highest intracellular delivery potential was observed with a monovalent conjugate displaying a rather high LDLR dissociation rate. On the contrary, under transient cellular exposure followed by chase, low dissociation-rate bivalent conjugates revealed a higher intracellular delivery potential than the monovalent conjugate. This was shown to rely on their ability to undergo multiple endocytosis-recycling rounds, with limited release in the ligand-free medium. The absence of reciprocal competition with the natural ligand LDL on their respective intracellular trafficking was also demonstrated, which is essential in terms of potential safety liabilities. These results demonstrate that not only molecular engineering of new therapeutic conjugates of interest, but also the cellular exposure mode used during in vitro evaluations are critical to anticipate and optimize their delivery potential.

Molecular design, synthesis and cell based HCV replicon assay of novel benzoxazole derivatives.

Hepatitis C virus inhibitors based on benzoxazole scaffold were designed based on molecular modeling simulation study including docking into the NS5B polymerase active site. Several compounds showed significant high simulation docking scores relative to the assigned benzimidazole lead compound. The designed compounds were synthesized, structurally elucidated and their antiviral activity was evaluated through cell-based replicon in cultured Huh 5-2 cells. A number of the synthesized compounds showed significant inhibitory activity ranging from (52.2% inhibition up to 98% at<50 µg/mL). N-Benzyl-2-phenylbenzo[1,3]oxazole-5-carboxamide (8b) and N-Phenethyl-2-phenylbenzo[1,3] oxazole-5-carboxamide (8c) demonstrated genuine HCV inhibitory activity with EC50 values of 41.6 and 24.5 µg/mL respectively.

Virtual screening and synthesis of new chemical scaffolds as VEGFR-2 kinase inhibitors.

VEGFR-2 tyrosine kinase inhibitors are currently receiving high interest in drug discovery process as anticancer agents. We have used virtual screening techniques in order to discover new scaffolds that can be used for developing new VEGFR-2 kinase inhibitors.Similarity ensemble approach was used to reduce the chemical space of ZINC database to select a subset of compounds. A validated structure-based pharmacophore was developed and adopted to screen the selected subset. Initial hits mapped to the pharmacophore were filtered using docking and scoring. Selected compounds were synthesized and biologically tested. Compound 9 showed very good cytotoxicity profile against the NCI 60 cancer cell lines, while compound 8 showed reasonable inhibition of VEGFR-2 tyrosine kinase.Stepwise virtual screening of databases such as ZINC may result in new scaffolds for developing VEGFR-2 kinase inhibitors.

Synthesis and anti-proliferative activity of substituted-anilinoquinazolines and its relation to EGFR inhibition.

4-Anilinoquinazoline is a privileged scaffold in developing small molecule inhibitors of tyrosine kinases (TK) especially epidermal growth factor receptor (EGFR). 2 series belonging to 3'-substituted-4-anilinoquinazoline scaffold were synthesized and screened in vitro on isolated and a breast cancer cell line. The research aims at exploring the activity of compounds having diverse substituents at 3' position of the aniline moiety. Generally, the meta-substituted-anilinoquinazolines exhibited significant inhibitory activity against isolated enzyme as well as MCF-7 cancer cell line. For instance, compound 10b inhibited >99% of EGFR activities at 10 µM concentration. 6 of the tested compounds exhibited range of anti-proliferative activity below 10 µM potency. In particular, compounds 6e and 10b displayed the highest activity among the tested compounds with IC50 values equal to 8.6 and 4.84 µM, respectively. Structure-based tools were utilized to rationalize EGFR-TK binding of compound 10b since it is the most active compound in the enzyme inhibition test.

Computer--based drug design, synthesis and biological evaluation of new pyrimidinone derivatives linked to arylpiperazine and 2'-carbethoxy-biphenylylmethyl moeities as alpha1-adrenoceptor antagonists and angiotensin II AT1 receptor antagonists.

Two new series of pyrimidinone derivatives linked to arylpiperazine moieties and 2'-carbethoxy-biphenylmethyl moieties were designed, synthesized and biologically evaluated for their in vivo hypotensive activities. The design of arylpiperazine analogues (IIa-f, IIIa-c, VIIa.b, IX) was based upon structural modification of the newly discovered selective alpha1-AR antagonist drug; Urapidil. Compare/fit studies of these molecules with the previously generated and validated alpha1-AR antagonist hypothesis showed that these molecules have comparable affinities for the alpha1-AR antagonist hypothesis while compound IIIc had the highest fitting value. The in vivo biological evaluation of these compounds for their effects on blood pressure of normotensive cats in comparison to the lead compound prazosin, was consistent with the results of molecular modeling fit values. As expected, compound IIIc exhibited the highest hypotensive activity among the test set compounds. Meanwhile, the design of 2'-carbethoxy-biphenylylmethyl analogues (XIa,b) was based upon the molecular modeling simulation fitting of their carboxylic acid bioprecursors with the previously generated and validated Ang II receptor antagonist hypothesis. Such compare/fit studies predicted that the designed compounds (XIa,b) showed comparable fitting affinities between their de-esterified analogues and the Ang II antagonist pharmacophore. In vivo biological evaluation of these compounds for their effects on blood pressure of normotensive cats showed that compound Xla exhibited hypotensive activity more or less similar to losartan.

Substrate specificity and stereoselectivity of rat brain microsomal anandamide amidohydrolase.

Anandamide amidohydrolase (AAH) catalyzes the hydrolysis of arachidonylethanolamide (anandamide), an endogenous cannabinoid receptor ligand. To delineate the structural requirements of AAH substrates, rat brain microsomal AAH hydrolysis of a series of anandamide congeners was studied using two reverse-phase high-performance liquid chromatography (RP-HPLC) assays developed in our laboratory. Arachidonamide (1) was found to be the best substrate with an apparent Km of 2.34 mM and a Vmax of 2.89 nmol/min/mg of protein. Although anandamide (2) has a similar Km value, its Vmax is approximately one-half that of arachidonamide. N, N-Bis(2-hydroxyethyl)arachidonamide (3) was not hydrolyzed, suggesting specificity for unsubstituted or mono-N-substituted arachidonamides. Analogues with a methyl group at the 1'-position of the ethanolamido headgroup were also found to have greater resistance to enzymatic turnover and therefore increased metabolic stability. The enzyme exhibited high stereoselectivity as the rate of hydrolysis of (R)-alpha-methanandamide (2.4%) (anandamide = 100%) was about 10-fold lower than that of its (S)-enantiomer (23%). In contrast, (R)-beta-methanandamide was 6-times more susceptible (121%) than the (S)-beta-enantiomer (21%). Interestingly, an inverse correlation was shown between AAH stereoselectivity and the brain cannabinoid receptor affinity as the enantiomers with high receptor affinity displayed low susceptibility to hydrolysis by AAH. Metabolic stability is also imparted to analogues with a short hydrocarbon headgroup as well as to those possessing 2-monomethyl or 2,2-dimethyl substituents. 2-Arachidonylglycerol and racemic 1-arachidonylglycerol were shown to be excellent AAH substrates. To identify AAH inhibitors, hydrolysis of anandamide was also studied in the presence of a select group of cannabimimetics. Of these, (-)-Delta8-THC and SR141716A, a biarylpyrazole CB1 antagonist, were found to inhibit enzymatic activity. These newly defined enzyme recognition parameters should provide a foundation for the rational development of stable, therapeutically useful anandamide analogues with high receptor affinity.

Head group analogs of arachidonylethanolamide, the endogenous cannabinoid ligand.

Several analogs of an endogenous cannabimimetic, arachidonylethanolamide (anandamide), were synthesized to study the structural requirements of the ethanolamide head group. CB1 receptor affinities of the analogs were evaluated by a standard receptor binding assay using tritiated CP-55,940 as the radioligand and compared to anandamide which was shown to have a Ki of 78 nM. Replacement of the amide carbonyl oxygen by a sulfur atom had a detrimental effect on the CB1 affinity. The thio analogs of both anandamide and (R)-methanandamide showed very weak affinity for CB1. The secondary nature of the amidic nitrogen was also shown to be important for affinity, indicating a possible hydrogen-bonding interaction between the amide NH and the receptor. Introduction of a phenolic moiety in the head group resulted in the loss of receptor affinity except when a methylene spacer was introduced between the amidic nitrogen and the phenol. A select group of analogs were also tested for their affinity for the CB2 receptor using a mouse spleen preparation and were found to possess low affinities for the CB2 sites. Notably, anandamide and (R)-methanandamide demonstrated high selectivity for the CB1 receptor. Overall, the data presented here show that structural requirements of the head group of anandamide are rather stringent.