Enantioselective organocatalytic syntheses of α-selenated α- and β-amino acid derivatives

Selenium-containing amino acids are valuable targets but methods for the stereoselective α-selenation of simple amino acid precursors are rare. We herein report the enantioselective electrophilic α-selenation of azlactones (masked α-amino...

An E x Vivo Model of Oxidatively Stressed Red Blood Cells Demonstrates a Role for Exogenous Amino Acids in Enhancing Red Blood Cell Function and Morphology

The capacity of mature red blood cells (RBCs) to respond to oxidative stress is limited due to lack of a full complement of organelles and as such, when faced with an oxidative environment, they rely on their endogenous antioxidant capacity (including superoxide dismutase, catalase, peroxiredoxin and glutathione) to protect against cellular damage. Low blood glutathione activity has been reported in several red cell disorders leading to increased oxidative stress. Targeting oxidative stress has thus been proposed as a secondary treatment in multiple anemia-causing diseases, such as sickle cell disease (SCD) and malaria, although its overall efficacy remains unclear. As glutathione itself is not permeable through the RBC membrane, treatment with cell-permeable amino acid precursors of glutathione (glutamine, cysteine and/or glycine) is a potential strategy to expand the RBC's antioxidant capacity and alleviate oxidative stress. Indeed, L-glutamine has recently been approved as a therapeutic for SCD, although the mechanistic basis for its effect is not clear. To fill this gap in our understanding, we performed detailed characterization of biophysical phenotype, morphology, and intracellular redox environment of oxidatively stressed RBCs in environments with varying amounts of available precursor amino acids. To assess the impact of exogenous amino acid precursors on the RBC's glutathione antioxidant capacity, we exposed mature RBCs from healthy adults to hydrogen peroxide (H 2O 2) and co-incubated with media that included glutamine, cysteine, and/or glycine. As catalase has the ability to scavenge high levels of exogenously fluxed H 2O 2, we performed these experiments using sodium azide to block catalase activity, enabling us to model oxidatively stressed RBCs. We performed osmotic gradient ektacytometry to quantify RBC deformability and hydration status, and assessed RBC morphology using osmotic-adjusted fixation techniques and scanning electron microscopy. As previously documented, H 2O 2 exposure in sodium azide-treated healthy RBCs was associated with decreased deformability, decreased hydration and increased numbers of echinocytes in a dose-dependent manner. We monitored red cell phenotypic changes following co-incubation with glutamine, cysteine, and/or glycine individually and in combination to test whether these amino acids extended the RBC's antioxidant abilities and contributed to improved function and morphology. We found that supplementation with all three amino acids in combination significantly improved both deformability and hydration of H 2O 2-stressed RBCs, as opposed to treatment with glutamine alone. To directly assess whether the exogenous amino acids were in fact contributing to less intracellular oxidative stress in RBCs, we quantified intracellular reactive oxygen species (ROS) using 2', 7' -dichlorofluorescein diacetate (DCFDA), a cell permeable dye used to measure ROS production. As expected, H 2O 2 exposure alone was associated with elevated intracellular ROS inside RBCs in both a time- and dose-dependent manner. Supplementation with the three amino acid cocktail during H 2O 2 stress resulted in a reduction in the level of intracellular ROS activity. In summary, we documented that exogenous added amino acids reduce oxidative damage in RBCs and we hypothesize that this protection occurs via the glutathione antioxidant pathways. In future studies, we plan to investigate the impact of exogenous amino acids on sickled and irreversibly sickled RBCs (ISCs) in the context of SCD, and on uninfected and infected RBCs in the context of malaria. Disclosures Kim-Shapiro: Beverage Operations LLC: Current holder of stock options in a privately-held company, Membership on an entity's Board of Directors or advisory committees, Patents & Royalties: co-inventor on a patent related to the use of nitrite under cardiovascular conditions, and a co-author on patents related to treatment of hemolysis.

Time Evolution of Microbial Composition and Metabolic Profile for Biogenic Amines and Free Amino Acids in a Model Cucumber Fermentation System Brined with 0.5% to 5.0% Sodium Chloride

Salt concentrations in brine and temperature are the major environmental factors that affect activity of microorganisms and, thus may affect formation of biogenic amines (BAs) during the fermentation process. A model system to ferment cucumbers with low salt (0.5%, 1.5% or 5.0% NaCl) at two temperatures (11 or 23 °C) was used to study the ability of indigenous microbiota to produce biogenic amines and metabolize amino acid precursors. Colony counts for presumptive Enterococcus and Enterobacteriaceae increased by 4 and up to 2 log of CFU∙mL−1, respectively, and remained viable for more than 10 days. 16S rRNA sequencing showed that Lactobacillus and Enterobacter were dominant in fermented cucumbers with 0.5% and 1.5% salt concentrations after storage. The initial content of BAs in raw material of 25.44 ± 4.03 mg∙kg−1 fluctuated throughout experiment, but after 6 months there were no significant differences between tested variants. The most abundant BA was putrescine, that reached a maximum concentration of 158.02 ± 25.11 mg∙kg−1. The Biogenic Amines Index (BAI) calculated for all samples was significantly below that needed to induce undesirable effects upon consumption. The highest value was calculated for the 23 °C/5.0% NaCl brine variant after 192 h of fermentation (223.93 ± 54.40). Results presented in this work indicate that possibilities to control spontaneous fermentation by changing salt concentration and temperature to inhibit the formation of BAs are very limited.

(Bio-)Synthesis of the Aquatic Phytotoxin Cyanobacterin – A Paradigm for Furanolide Core Structure Assembly

The gamma-butyrolactone structural motif is commonly found in many natural signaling molecules and other specialized metabolites. A prominent example is the potent aquatic phytotoxin cyanobacterin bearing a highly functionalized gamma-butyrolactone core structure. The enzymatic machinery assembling cyanobacterin and the many structurally related natural products – herein termed furanolides – has remained elusive over decades. Here we discover and characterize the underlying biosynthetic process of furanolide core structure assembly. The cyanobacterin biosynthetic gene cluster (<i>cyb</i>) is identified by targeted bioinformatic screening and validated by heterologous expression in <i>E. coli</i>. Functional evaluation of the recombinant key enzymes provides in-depth mechanistic insights into a streamlined <i>C</i>,<i>C</i>-bond-forming cascade that involves installation of compatible reactivity at seemingly unreactive C-alpha-positions of the amino acid precursors and facilitates development of a one-pot biocatalytic <i>in vitro</i> synthesis. Our work extends the biosynthetic and biocatalytic toolbox for gamma-butyrolactone formation. It thereby provides a general paradigm for the biosynthesis of furanolides and thus sets the stage for their targeted discovery, biosynthetic engineering and enzymatic synthesis.

(Bio-)Synthesis of the Aquatic Phytotoxin Cyanobacterin – A Paradigm for Furanolide Core Structure Assembly

The gamma-butyrolactone structural motif is commonly found in many natural signaling molecules and other specialized metabolites. A prominent example is the potent aquatic phytotoxin cyanobacterin bearing a highly functionalized gamma-butyrolactone core structure. The enzymatic machinery assembling cyanobacterin and the many structurally related natural products – herein termed furanolides – has remained elusive over decades. Here we discover and characterize the underlying biosynthetic process of furanolide core structure assembly. The cyanobacterin biosynthetic gene cluster (<i>cyb</i>) is identified by targeted bioinformatic screening and validated by heterologous expression in <i>E. coli</i>. Functional evaluation of the recombinant key enzymes provides in-depth mechanistic insights into a streamlined <i>C</i>,<i>C</i>-bond-forming cascade that involves installation of compatible reactivity at seemingly unreactive C-alpha-positions of the amino acid precursors and facilitates development of a one-pot biocatalytic <i>in vitro</i> synthesis. Our work extends the biosynthetic and biocatalytic toolbox for gamma-butyrolactone formation. It thereby provides a general paradigm for the biosynthesis of furanolides and thus sets the stage for their targeted discovery, biosynthetic engineering and enzymatic synthesis.

Arcopilus aureus MaC7A as a New Source of Resveratrol: Assessment of Amino Acid Precursors, Volatiles, and Fungal Enzymes for Boosting Resveratrol Production in Batch Cultures

The chemical factors that regulate the synthesis of resveratrol (RV) in filamentous fungi are still unknown. This work reports on the RV production by Arcopilus aureus MaC7A under controlled conditions and the effect of amino acid precursors (PHE and TYR), monoterpenes (limonone, camphor, citral, thymol, menthol), and mixtures of hydrolytic enzymes (Glucanex) as elicitors for boosting fungal RV. Batch cultures with variable concentrations of PHE and TYR (50–500 mg L−1) stimulated RV production from 127.9 ± 4.6 to 221.8 ± 5.2 mg L−1 in basic cultures developed in PDB (pH 7) added with 10 g L−1 peptone at 30 °C. Maximum levels of RV and biomass were maintained during days 6–8 under these conditions, whereas a dramatic RV decrease was observed from days 10–12 without any loss of biomass. Among the tested volatiles, citral (50 mg L−1) enhanced RV production until 187.8 ± 2.2 mg L−1 in basic cultures, but better results were obtained with Glucanex (100 mg L−1; 198.3 ± 7.6 mg L−1 RV). Optimized batch cultures containing TYR (200 mg L−1), citral (50 mg L−1), thymol (50 mg L−1), and Glucanex (100 mg L−1) produced up to 237.6 ± 4.7 mg L−1 of RV. Our results suggest that low concentrations of volatiles and mixtures of isoenzymes with β-1, 3 glucanase activity increase the biosynthesis of fungal RV produced by A. aureus MaC7A in batch cultures.

Asymmetric Catalytic Alkynylation of Thiazolones and Azlactones for Synthesis of Quaternary α-Amino Acid Precursors

Asymmetric alkynylation of thiazolones and azlactones with alkynylbenziodoxolones as electrophilic alkyne source catalyzed by thiourea phosphonium salt is described. By using thiazolones as nucleophiles, the desired alkyne functionalized thiazolones were...

Prebiotic synthesis of cysteine peptides that catalyze peptide ligation in neutral water

Peptide biosynthesis is performed by ribosomes and several other classes of enzymes, but a simple chemical synthesis may have created the first peptides at the origins of life. α-Aminonitriles—prebiotic α–amino acid precursors—are generally produced by Strecker reactions. However, cysteine’s aminothiol is incompatible with nitriles. Consequently, cysteine nitrile is not stable, and cysteine has been proposed to be a product of evolution, not prebiotic chemistry. We now report a high-yielding, prebiotic synthesis of cysteine peptides. Our biomimetic pathway converts serine to cysteine by nitrile-activated dehydroalanine synthesis. We also demonstrate that N-acylcysteines catalyze peptide ligation, directly coupling kinetically stable—but energy-rich—α-amidonitriles to proteinogenic amines. This rare example of selective and efficient organocatalysis in water implicates cysteine as both catalyst and precursor in prebiotic peptide synthesis.