Peptides with Potential Cardioprotective Effects Derived from Dry-Cured Ham Byproducts

"This document is the unedited Author s version of a Submitted Work that was subsequently accepted for publication in Journal of Agricultural and Food Chemistry, copyright © American Chemical Society after peer review. To access the final edited and published work see https://pubs.acs.org/doi/10.1021/acs.jafc.8b05888"[EN] The interest in using food byproducts as a source of bioactive peptides has increased significantly in the recent years. The goal of this work was to determine the presence and stability of peptides showing angiotensin I-converting enzyme (ACE-I), endothelin-converting enzyme (ECE), dipeptidyl peptidase-IV (DPP-IV), and platelet-activating factor-acetylhydrolase (PAF-AH) inhibitory activity derived from dry-cured ham bones, which could exert cardiovascular health benefits. ACE-I and DPP-IV inhibitory peptides were stable against heating typically used in Mediterranean household cooking methods and also to in vitro digestion. PAF-AH inhibitory activity significantly increased following simulated gastrointestinal digestion whereas ECE inhibitory significantly decreased (P < 0.05). The mass spectrometry analysis revealed a notable degradation of hemoglobin-derived peptides after simulated digestion, and the release of a large number of dipeptides that may have contributed to the observed bioactivities. These results suggest that natural peptides from Spanish dry-cured ham bones could contribute to a positive impact on cardiovascular health.This study was funded by the Emerging Research Group Grant from Generalitat Valenciana in Spain (GV/2015/138). A Ramon y Cajal postdoctoral contract to L.M. is acknowledged. Proteomic analysis was performed in the proteomics facility of SCSIE University of Valencia that belongs to ProteoRed, PRB2-ISCIII, supported by grant PT13/0001.Gallego-Ibáñez, M.; Mora Soler, L.; Hayes, M.; Reig Riera, MM.; Toldrá Vilardell, F. (2019). Peptides with Potential Cardioprotective Effects Derived from Dry-Cured Ham Byproducts. Journal of Agricultural and Food Chemistry. 67(4):1115-1126. https://doi.org/10.1021/acs.jafc.8b05888S1115112667

Computer-aided Design of Chalcone Derivatives as Lead Compounds Targeting Acetylcholinesterase

One of well-established biological activities for chalcone derivatives is as acetylcholinesterase inhibitors, which can be developed for the therapy of Alzheimer’s disease. Assisted byretrospectively validated structure-based virtual screening (SBVS) protocol to identify potent acetylcholinesterase inhibitors, 80chalcone derivatives were designed and virtually screened. The F-measure value as the parameter of the predictive ability of the SBVS protocol developed in the research presented in this article was 0.413, which was considerably better than the original SBVS protocol (F-measure = 0.226). Among the screened chalcone derivatives two were selected as potential lead compounds to designpotent inhibitors for acetylcholinesterase: 3-[4-(benzyloxy)-3-methoxyphenyl]-1-(4-hydroxy-3-methoxyphenyl)prop-2-en-1-one(3k) and 3-[4-(benzyloxy)-3-methoxyphenyl]-1-(4-hydroxyphenyl)prop-2-en-1-one (4k)

Rôle de la chymase humaine (CMA1) dans la conversion de la big-endothéline-1 en endothéline-1 (1-31)

Abstract : The chymase-dependant pathway responsible for converting Big ET-1 to ET-1 was established in vitro. It has only been recently, in 2009, that our group demonstrated that the conversion of Big ET-1 to ET-1 (1-31) can occur in vivo in mice (Simard et al., 2009), knowing that ET-1 (1-31) is converted to ET-1 via NEP in vivo (Fecteau et al., 2005). In addition, our laboratory demonstrated in 2013 that mMCP-4, the murine analogue of human chymase, produces ET-1 (1-31) from the Big ET-1 precursor (Houde et al. 2013). Thus far, in the literature, there are no specific characterizations of recombinant chymases (human or murine). In fact, the group of Murakami published in 1995 a study characterizing the CMA1 (human chymase) in a chymostatin-dependent fashion, using Angiotensin I as a substrate (Murakami et al., 1995). However, chymostatin is a non-specific inhibitor of chymase. It has been shown that chymostatin can inhibit elastase, an enzyme that can convert Angiotensin I to Angiotensin II (Becari et al., 2005). Based on these observations, the proposed hypothesis in the present study suggests that recombinant as well as extracted CMA1 from LUVA (human mast cell line), in addition to soluble fractions of human aortas, convert Big ET-1 into ET-1 (1-31 ) in a TY-51469 (a chymase-specific inhibitor) sensitive manner. In a second component, we studied the enzyme kinetics of CMA1 with regard to the Big ET-1 and Ang I substrate. The affinity of CMA1 against Big ET-1 was greater compared to Ang I (KM Big ET- 1: 12.55 μM and Ang I: 37.53 μM). However, CMA1 was more effective in cleaving Ang I compared to Big ET-1 (Kcat / KM Big ET-1: 6.57 x 10-5 μM-1.s-1 and Ang I: 1.8 x 10-4 ΜM-1.s- 1). In a third component involving in vivo experiments, the pressor effects of Big ET-1, ET-1 and Ang I were tested in conscious mMCP-4 KO mice compared to wild-type mice. The increase in mean arterial pressure after administration of Big ET-1 was greater in wild-type mice compared to mMCP- 4 KO mice. This effect was not observed after administration of ET-1 and / or Ang I.Résumé : La voie de conversion de Big ET-1 en ET-1, chymase dépendante a été établie in vitro. Ce n'est que récemment, en 2009 que notre groupe a démontré que la conversion de Big ET-1 en ET-1 (1-31) peut avoir lieu in vivo chez la souris (Simard et al., 2009), sachant que ET-1 (1-31) est convertie en ET-1 via NEP in vivo (Fecteau et al., 2005). En plus, en 2013, notre laboratoire a démontré que la mMCP- 4, l'analogue murin de la chymase humaine, produit l'ET-1 (1-31) à partir du précurseur Big ET-1 (Houde et al., 2013). Jusqu'a présent, dans la littérature, on ne trouve pas de caractérisations spécifiques de chymases (humaine ou murine) recombinantes. En fait, le groupe de Murakami, en 1995, a publié une étude caractérisant, d'une façon chymostatin dépendante, la CMA1 (chymase humaine) en utilisant l'Angiotensine I comme substrat (Murakami et al., 1995). Cependant, le chymostatin est un inhibiteur non-spécifique de la chymase. Il a été démontré que le chymostatin peut inhiber l'élastase, une enzyme pouvant convertir l'Angiotensine I en Angiotensine II (Becari et al., 2005). Basé sur ces observations, l'hypothèse formulée dans la présente étude est que la CMA1 recombinante ou extraite des cellules LUVA (lignée humaine de mastocytes) ou des fractions solubles des aortes humaines convertit la Big ET-1 en ET-1 (1-31) d'une façon TY-51469 (un inhibiteur spécifique de la chymase) sensible. Dans un deuxième volet, on a étudié la cinétique enzymatique de CMA1 en vers le substrat Big ET-1 et Ang I. L’affinité de CMA1 contre la Big ET-1 était plus grande comparé à l’Ang I (KM Big ET-1 : 12.55 μM et Ang I : 37.53 μM). Cependant CMA1 était plus efficace dans le clivage de l’Ang I comparé à la Big ET-1 (Kcat/KM Big ET-1 : 6.57 x 10-5 μM-1 .s-1 et Ang I : 1.8 x 10-4 μM-1 .s-1 ). Dans un troisième volet impliquant des expériences in vivo, l’effet presseur de la Big ET-1, l’ET-1 et l’Ang I a été testé chez des souris conscientes mMCP- 4 KO comparé à des souris de type sauvage. L’augmentation de la pression artérielle moyenne a été plus importante chez les souris de type sauvage après l’administration de Big ET-1 que chez les souris mMCP-4 KO. Cet effet n’a pas été observé après l’administration d’ET-1 et/ou d’Ang I ce qui explique le rôle de la chymase dans l’effet de la conversion de Big ET-1 en ET-1 (1-31)

TOP2A and EZH2 Provide Early Detection of an Aggressive Prostate Cancer Subgroup.

Purpose: Current clinical parameters do not stratify indolent from aggressive prostate cancer. Aggressive prostate cancer, defined by the progression from localized disease to metastasis, is responsible for the majority of prostate cancer–associated mortality. Recent gene expression profiling has proven successful in predicting the outcome of prostate cancer patients; however, they have yet to provide targeted therapy approaches that could inhibit a patient\u27s progression to metastatic disease. Experimental Design: We have interrogated a total of seven primary prostate cancer cohorts (n = 1,900), two metastatic castration-resistant prostate cancer datasets (n = 293), and one prospective cohort (n = 1,385) to assess the impact of TOP2A and EZH2 expression on prostate cancer cellular program and patient outcomes. We also performed IHC staining for TOP2A and EZH2 in a cohort of primary prostate cancer patients (n = 89) with known outcome. Finally, we explored the therapeutic potential of a combination therapy targeting both TOP2A and EZH2 using novel prostate cancer–derived murine cell lines. Results: We demonstrate by genome-wide analysis of independent primary and metastatic prostate cancer datasets that concurrent TOP2A and EZH2 mRNA and protein upregulation selected for a subgroup of primary and metastatic patients with more aggressive disease and notable overlap of genes involved in mitotic regulation. Importantly, TOP2A and EZH2 in prostate cancer cells act as key driving oncogenes, a fact highlighted by sensitivity to combination-targeted therapy. Conclusions: Overall, our data support further assessment of TOP2A and EZH2 as biomarkers for early identification of patients with increased metastatic potential that may benefit from adjuvant or neoadjuvant targeted therapy approaches. ©2017 AACR

Inhibitory activity against carbonic anhydrase IX and XII as a candidate selection criterion in the development of new anticancer agents

Analysis of the literature data reveals that while inhibition of cancer-related carbonic anhydrase IX and XII isoforms continues to be an important enrichment factor for designing anticancer agent development libraries, exclusive reliance on the in vitro inhibition of these two recombinant isozymes in nominating candidate compounds for evaluation of their effects on cancer cells may lead not only to identifying numerous compounds devoid of the desired cellular efficacy but also to overlooking many promising candidates which may not display the best potency in biochemical inhibition assay. However, SLC-0111, now in phase Ib/II clinical trials, was developed based on the excellent agreement between the in vitro, in vivo and more recently, in-patient data

Development of Thiophene Compounds as Potent Chemotherapies for the Treatment of Cutaneous Leishmaniasis Caused by Leishmania major

Leishmania major (L. major) is a protozoan parasite that causes cutaneous leishmaniasis. About 12 million people are currently infected with an annual incidence of 1.3 million cases. The purpose of this study was to synthesize a small library of novel thiophene derivatives, and evaluate its parasitic activity, and potential mechanism of action (MOA). We developed a structure–activity relationship (SAR) study of the thiophene molecule 5A. Overall, eight thiophene derivatives of 5A were synthesized and purified by silica gel column chromatography. Of these eight analogs, the molecule 5D showed the highest in vitro activity against Leishmania major promastigotes (EC50 0.09 ± 0.02 µM), with an inhibition of the proliferation of intracellular amastigotes higher than 75% at only 0.63 µM and an excellent selective index. Moreover, the effect of 5D on L. major promastigotes was associated with generation of reactive oxygen species (ROS), and in silico docking studies suggested that 5D may play a role in inhibiting trypanothione reductase. In summary, the combined SAR study and the in vitro evaluation of 5A derivatives allowed the identification of the novel molecule 5D, which exhibited potent in vitro anti-leishmanial activity resulting in ROS production leading to cell death with no significant cytotoxicity towards mammalian cells

Investigating domain-selective angiotensin converting enzyme inhibition and oxidative inactivation

Angiotensin converting enzyme (ACE) is a zinc metalloprotease comprised of two highly homologous, catalytically active domains (90% active site identity and 60% sequence similarity). The C-domain is responsible for blood pressure regulation via angiotensin I cleavage while the N-domain inactivates an antifibrotic peptide Acetyl-Ser-Asp-Lys-Pro (AcSDKP). Since selective N-domain inhibition will result in AcSDKP accumulation, it shows promise for the treatment of fibrosis without affecting blood pressure. Low bioavailability, however, precludes the use of currently available N-selective ACE inhibitors in a clinical setting. Inhibition of ACE by a phosphinic, peptidomimetic compound, 33RE, was characterized using a continuous assay with quenched fluorogenic substrate. The N-domain displayed nanomolar (Ki = 11.21±0.74nM) and the C-domain micromolar (Ki = 11 278±410nM) inhibition, thus 1000-fold selectivity. Residues predicted to contribute to selectivity based on the N-domain-33RE co-crystal structure were subsequently mutated to their C-domain counterparts. S2 subsite mutation with resulting loss of a hydrogen bond drastically decreased 33RE affinity (Ki = 2794±156nM), yet did not entirely account for the selectivity. Additional substitution of all unique S2’ residues, however, completely abolished N-selectivity (Ki = 10 009±157nM). Interestingly, these residues do not directly bind 33RE. All mutants were therefore subjected to molecular dynamics (MD) simulations in the presence and absence of 33RE in addition to co-crystallization of 33RE with the N-domain mutant having all S2 and S2’ residues mutated. Trajectory analyses highlighted the S2’ residues’ importance in formation of a favourable interface between the ACE subdomains and thus a closed, ligand-bound complex. This was supported by X-ray crystallography and provides a molecular basis for the inter-subsite synergism governing 33RE’s 1000-fold N-domain selectivity. Enzyme kinetics were also used to study the concentration-dependent competitive inhibition and time-dependent irreversible oxidative inactivation of ACE catalysed by the Cu-Gly-GlyHis-lisinopril (CuGGHLis) metallodrug. Although both domains displayed nanomolar affinity for metallodrug binding (N-domain Ki = 44.94±1.84nM and C-domain Ki = 15.57±1.30nM), rapid and complete CuGGHLis-mediated inactivation occurred exclusively in the N-domain upon incubation with ascorbate and H2O2 redox co-reactants (k2 = 59 710 M-1 min-1 ). Michaelis-Menten characterization of the residual activity after partial N-domain inactivation revealed a decreased rate for hydrolysis of a non-domain selective substrate. This suggests that although CuGGHLis binds with similar affinity to both domains, the metal-chelate is optimally orientated in the N- but not the C-domain to catalyze oxidation of residues involved in substrate hydrolysis. The C-domain, in contrast, showed increased susceptibility to oxidative inactivation by diffuse radicals. This is of physiological significance as C-domain inactivation in normotensive individuals could result in accumulation of pro-inflammatory peptides. Since the N-domain is more heavily glycosylated, the potential role of unique glycans in diffuse radical shielding was studied using glycoprotein MD simulations. Unique C-domain solvent tunnels were identified that could increase diffuse radical access and, additionally, the mechanism whereby glycosylation contributes to ACE thermal stability was described for each site. This has implications for future ACE crystallography studies and the design of ACE-modulating agents with potential anti-inflammatory activity. This study demonstrated the utility of combining in vitro and in silico approaches to reveal how subtle amino acid or glycosylation site differences between the highly homologous domains control dynamic behaviour. It furthermore elucidated how two inhibitors with different mechanisms of action selectively target the N-domain active site by exploiting these differences and provided valuable insight for future anti-fibrotic ACE inhibitor design

Selenazolyl-hydrazones as Novel Selective MAO Inhibitors With Antiproliferative and Antioxidant Activities: Experimental and In-silico Studies

The novel approach in the treatment of complex multifactorial diseases, such as neurodegenerative disorders and cancer, requires a development of efficient multi-targeting oriented drugs. Since oxidative stress significantly contributes to the pathogenesis of cancer and neurodegenerative disorders, potential drug candidates should possess good antioxidant properties Due to promising biological activities shown for structurally related (1,3-thiazol-2-yl)hydrazones, a focused library of 12 structurally related benzylidene-based (1,3-selenazol-2-yl)hydrazones was designed as potential multi-targeting compounds. Monoamine oxidases (MAO) A/B inhibition properties of this class of compounds have been investigated. Surprisingly, the p-nitrophenyl-substituted (1,3-selenazol-2-yl)hydrazone 4 showed MAO B inhibition in a nanomolar concentration range (IC50 = 73 nM). Excellent antioxidant properties were confirmed in a number of different in vitro assays. Antiproliferative activity screening on a panel of six human solid tumor cell lines showed that potencies of some of the investigated compounds was comparable or even better than that of the positive control 5-fluorouracil. In-silico calculations of ADME properties pointed to promising good pharmacokinetic profiles of investigated compounds. Docking studies suggest that some compounds, compared to positive controls, have the ability to strongly interact with targets relevant to cancer such as 5'-nucleotidase, and to neurodegenerative diseases such as the small conductance calcium-activated potassium channel protein 1, in addition to confirmation of inhibitory binding at MAO B

Natural phenolic compounds from Satureja L. as inhibitors of COVID-19 protease (Mpro): Computational investigations

Coronavirus (SARS-CoV-2) causes a new type of severe acute respiratory syndrome that first appeared in Wuhan in December 2019; it is a very fast-spreading and deadly virus. Therefore, urgent discovery or development of “lead compounds” against this virus is crucial. Natural compounds have always served as a great source, especially the use of traditional medicinal plants, in modern drug discovery. This study aimed to investigate the SARS-CoV-2 protease inhibition potential of the phenolic compounds in the genus Satureja L. The affinities of the chosen natural products were understood using molecular docking simulation against the SARS-CoV-2 protease enzyme. The study proved that three different phenolic compounds namely 5,6-dihydroxy-2-(4-hydroxy-3-methoxyphenyl)-7,8-dimethoxy-4H-chromen-4-one, 2-(3,4-dimethoxyphenyl)-5,6-dihydroxy-7,8-dimethoxy-4H-chromen-4-one, and 5,6-dihydroxy-2-(3-hydroxy-4-methoxyphenyl)-7,8-dimethoxy-4H-chromen-4-one obtained from Satureja L. taxa were found as promising against SARS-CoV-2 main protease