Granulocyte microvesicles with a high plasmin generation capacity promote clot lysis and improve outcome in septic shock

Microvesicles (MVs) have previously been shown to exert profibrinolytic capacity, which is increased in patients with septic shock (SS) with a favorable outcome. We therefore hypothesized that the plasmin generation capacity (PGC) could confer to MVs a protective effect supported by their capacity to lyse a thrombus, and we investigated the mechanisms involved. Using a MV-PGC kinetic assay, ELISA and flow cytometry, we found that granulocyte MVs (Gran-MVs) from SS patients display a heterogeneous PGC profile driven by the uPA (urokinase)/uPAR system. In vitro, these MVs lyse a thrombus according to their MV-PGC levels in a uPA/uPAR-dependent manner, as shown in a fluorescent clot lysis test and a lysis front retraction assay. Fibrinolytic activators conveyed by MVs contribute to approximately 30% of the plasma plasminogenolytic capacity of SS patients. In a murine model of SS, the injection of high PGC Gran-MVs significantly improved mouse survival and reduced the number of thrombi in vital organs. This was associated with a modification of the mouse coagulation and fibrinolysis properties toward a more fibrinolytic profile. Interestingly, mouse survival was not improved when soluble uPA was injected. Finally, using a multiplex array on plasma from SS patients, we found that neutrophil elastase correlates with the effect of high-PGC-capacity plasma and modulates the Gran-MV plasmin generation capacity by cleaving uPA-PAI-1 complexes. In conclusion, we show that high PGC level displayed by Gran-MVs reduce thrombus formation and improve survival conferring to Gran-MVs a protective role in a murine model of sepsis.

Antibacterial Activity and Multi-Targeting Mechanism of Dehydrocorydaline From Corydalis turtschaninovii Bess. Against Listeria monocytogenes

Listeria monocytogenes is a foodborne pathogen, with relatively low incidence but high case-fatality. Phytochemicals have been recognized as a promising antimicrobial agent as an alternative to synthetic chemicals due to their safety and high efficacy with multi-target sites. This study identified and characterized a novel antibacterial agent, dehydrocorydaline, in the Corydalis turschaninovii rhizome using HPLC-LTQ-Orbitrap-HRMS, and its antibacterial effect with lowest MIC (1 mg/mL) and MBC (2 mg/mL) values. In addition, an in vitro growth kinetic assay, cytoplasmic nucleic acid and protein leakage assay, and observation of morphological changes in bacterial cells supported the strong antibacterial activity. Dehydrocorydaline also displayed effective inhibitory effects on biofilm formation and bacterial motility. In order to investigate the potential antibacterial mechanism of action of dehydrocorydaline against L. monocytogenes, label-free quantitative proteomics was used, demonstrating that dehydrocorydaline has multiple targets for combating L. monocytogenes including dysregulation of carbohydrate metabolism, suppression of cell wall synthesis, and inhibition of bacterial motility. Overall, this study demonstrated that dehydrocorydaline has potential as a natural and effective antibacterial agent with multi-target sites in pathogenic bacteria, and provides the basis for development of a new class of antibacterial agent.

RAA enzyme is a new family of class A extended-spectrum β-lactamase from the Riemerella anatipestifer RCAD0122 strain

Whole genome sequencing of Riemerella anatipestifer isolate RCAD0122 revealed a chromosomally-located β-lactamases gene, bla RAA-1 , which encoded a novel class A extended-spectrum β-lactamases (ESBL), RAA-1. The RAA-1 shared ≤ 65% amino acid sequence identity with other characterized β-lactamases. The kinetic assay of native purified RAA-1 revealed ESBL-like hydrolysis activity. Furthermore, bla RAA-1 could be transferred to a homologous strain by natural transformation. However, the epidemiological study showed that the bla RAA-1 gene is not prevalent currently.

Heme-Induced Platelet Mitochondrial Oxidant Production Regulates Platelet Granule Release

Background: Patients with Sickle Cell Disease (SCD) are at greater risk for thrombosis and the development of chronic vasculopathy, both of which are major contributors to morbidity and mortality in these patients. While thrombosis and vasculopathy are associated with hemolysis in SCD, the molecular mechanisms by which hemolysis propagates these conditions remains unclear. At the cellular level, we and others have shown that hemolytic components, including hemoglobin and its degradation product, free heme, directly activate platelets. Notably, activated platelets are not only central to thrombosis, but are also implicated in vasculopathy through their degranulation, which results in the release of vasoactive molecules. Though heme and hemoglobin-induced platelet activation has been widely studied, the effect of hemolytic products on platelet degranulation and the identity of the resulting platelet secretome remains less clear. We hypothesize that free heme activates a platelet signaling cascade resulting in platelet degranulation and the release of specific "secretome" molecules. Methods: Washed platelets were prepared from whole blood collected from healthy human volunteers in 0.32% sodium citrate (n=6). Platelets were treated with heme (2.5µM) in the presence or absence of MitoTEMPO (10 µM) - a mitochondrial oxidant (mtROS) scavenger, or ARQ092 (10 µM), a small molecule that prevents phosphorylation of the serine/threonine kinase Akt at S473. Platelet mtROS was measured by fluorescence spectroscopy using MitoSOX Red. Thrombospondin-1 (TSP1), CXCL7, Fibroblast Growth Factor (FGF) basic, TGFβ, IL-1β, PDGF-B, angiostatin, kininogen, CD40L and PAI-1 were quantified in heme treated platelet releasates in the presence and absence of MitoTEMPO by dot blot. The enzymatic activity of mitochondrial electron transport complex V was measured spectrophotometrically by kinetic assay. Results: We found that heme stimulated the release of a specific set of molecules from the α-granule of platelets, including TSP1, CXCL7, FGF basic, TGFβ, IL-1β, PDGF-B, angiostatin, and kininogen; but did not stimulate the release of CD40L or PAI-1. Mechanistic studies demonstrate that the release of several of these molecules was dependent on heme-induced activation of platelet Akt which inhibits mitochondrial complex V, resulting in mtROS production. Consistent with this mechanism, the heme-stimulated release of TSP1, CXCL7, FGF basic, IL-1β, PDGF-B, and angiostatin were significantly attenuated by preventing Akt phosphorylation at Ser473 with ARQ092, which also prevented complex V inhibition and mtROS production. Direct scavenging of mtROS with MitoTEMPO also attenuated heme-induced release of these molecules. Conclusion: These data, for the first time, begin to characterize the platelet secretome released in response to free heme. Further, they demonstrate a novel molecular pathway in which extracellular heme induces the activation of platelet Akt to inhibit mitochondrial complex V, ultimately inducing mtROS. Notably, this study suggests that release of a proportion of the heme-induced secretome is regulated by mtROS production and can be suppressed by mtROS scavengers. Ongoing studies are further characterizing the hemolysis-induced platelet secretome, the downstream effects of secretome products on vascular function, and the extent of regulation of the secretome by mtROS. These studies provide a mechanistic link between hemolysis and platelet degranulation, by which the release of mitogens can lead to the pathogenesis of vascular wall dysfunction. These studies also suggest that platelet mtROS may represent a novel therapeutic target to attenuate vascular dysfunction in hemolytic disorders including SCD. Note: The finding discussed in the above abstract are available as preprint in bioRxiv; doi: https://doi.org/10.1101/2021.08.02.454816 Disclosures No relevant conflicts of interest to declare.

Synthesis, structure and in vitro biological properties of a new copper(II) complex with 4-{[3-(pyridin-2-yl)-1H-pyrazol-1-yl]methyl}benzoic acid

The new copper(II) complex dichloridobis(4-{[3-(pyridin-2-yl-κN)-1H-pyrazol-1-yl-κN 2]methyl}benzoic acid)copper(II) methanol sesquisolvate hemihydrate, [CuCl2 L 2]·1.5CH3OH·0.5H2O, (1), has been synthesized from CuCl2·2H2O and the ligand 4-{[3-(pyridin-2-yl)-1H-pyrazol-1-yl]methyl}benzoic acid (L, C15H11N3O2). The complex was characterized by elemental analysis, Fourier transform IR spectroscopy, electrospray ionization mass spectrometry and single-crystal X-ray diffraction. Two chloride ligands and two bidentate L ligands coordinate the CuII centre in 1 in a Jahn–Teller-distorted octahedral geometry of rather unusual configuration: a chloride substituent and a pyrazole N atom of an N,N′-chelating ligand occupy the more distant axial positions. Classical O—H...O hydrogen bonds and O—H...Cl interactions link neighbouring complex molecules and cocrystallized methanol molecules into chains that propagate parallel to the b direction. The title compound shows intriguing bioactivity: the effects of 1 on the enzymatic activity of protein tyrosine phosphatase 1B (PTP1B) and on the viability of human breast cancer cells of cell line MCF7 were evaluated. Complex 1, with an IC50 value of 0.51 µM, can efficiently inhibit PTP1B activity. An enzyme kinetic assay suggests that 1 inhibits PTP1B in a noncompetitive manner. A fluorescence titration assay indicates that 1 has a strong affinity for PTP1B, with a binding constant of 4.39 × 106 M −1. Complex 1 may also effectively decrease the viability of MCF7 cells in an extent comparable to that of cisplatin (IC50 = 6.3 µM). The new copper complex therefore represents a promising PTP1B inhibitor and an efficient antiproliferation reagent against MCF7 cells.

Topological and Enzymatic Analysis of Human Alg2 Mannosyltransferase

N-glycosylation starts with the biosynthesis of lipid-linked oligosaccharide (LLO) on the endoplasmic reticulum. Alg2 mannosyltransferase adds both the α1,3- and α1,6-Man onto ManGlcNAc2-pyrophosphate-dolichol (M1Gn2-PDol) in either order to generate the branched M3Gn2-PDol product. The well-studied yeast Alg2 interacts with ER membrane through four hydrophobic domains. Unexpectedly, we show that Alg2 structure has diverged significantly between yeast and humans. Human Alg2 (hAlg2) associates with the ER via a single membrane-binding domain and is markedly more stable in vitro. These properties were exploited to develop an LC-MS quantitative kinetic assay for studying purified hAlg2. Under physiological conditions, hAlg2 prefers to transfer α1,3-Man on to M1Gn2 before adding the α1,6-Man. However, this bias is altered by an excess of GDP-Man donor or an increased level of M1Gn2 substrate, both of which trigger production of the M2Gn2 (α-1,6)-PDol. These results suggest that Alg2 may regulate the LLO biosynthetic pathway by controlling accumulation of M2Gn2 (α-1,6) intermediate.

Activation of Deoxyribonuclease I by Nicotinamide as a New Strategy to Attenuate Tetracycline-Resistant Biofilms of Cutibacterium acnes

Biofilms of Cutibacterium (C.) acnes (formerly Propionibacterium acnes) are responsible for the persistence and antibiotic resistance of acne vulgaris. In addition to the standard treatments for acne vulgaris, a common adjunctive treatment is the topical administration of nicotinamide (NAM). However, the effects of NAM on biofilms of C. acnes have never been explored. This study comprehensively investigates the effects of NAM against biofilms of C. acnes using in vitro and in vivo approaches. The results showed that NAM potentiated the efficacy of suboptimal dosing of tetracycline against C. acnes. Moreover, NAM alone decreased the formation and increased the degradation of biofilms in C. acnes. The antibiofilm effect of NAM against C. acnes was further enhanced in combination with deoxyribonuclease (DNase) I, an enzyme with known antibiofilm properties. The computational molecular docking, surface plasmon resonance analysis, and enzymatic kinetic assay demonstrated that NAM binds to DNase I and accelerated its reaction. In conclusion, NAM activates DNase I to attenuate biofilms of C. acnes. This offers valuable insights into the strategies against biofilms that are worth elaborating on in other biofilm-related chronic cutaneous infections in the future.

Pyrogallol Induces Antimicrobial Effect and Cell Membrane Disruption on Methicillin Resistant Staphylococcus aureus (MRSA)

Background: Pyrogallol is present naturally in numerous plants and is also an important functional group in many polyphenol compounds. Objectives: The antibacterial activity, efficacy and mechanism of pyrogallol towards MRSA strains were evaluated in this study. Methods: Microbroth dilution method was used to determine the minimum inhibitory concentration (MIC) and minimum bactericidal concentration (MBC). Time-kill kinetic assay was adopted to determine the killing pattern of pyrogallol towards MRSA. The antibacterial mechanism was determined using scanning electron microscopy (SEM), Fourier Transform-Infrared (FT-IR) spectroscopy and crystal violet assay. Results: Pyrogallol exhibited strong antibacterial activity against MRSA with MIC and MBC 15.6 µg/mL. Pyrogallol could inhibit the exponential growth of MRSA and kill the bacterial cells at higher concentrations. Pyrogallol was found targeting the cell membrane fatty acids, proteins/peptides, polysaccharides/carbohydrates and peptidoglycan of cell walls in the antibacterial mechanism. This has been confirmed through SEM, FT-IR spectroscopy and crystal violet assay. Conclusion : Overall, the findings suggest that pyrogallol has the potential to be used as antibiotics which are used to treat multidrug-resistant bacteria.

In vitro and In Silico Approach For Characterization of Antimicrobial Peptide From Probiotics Against Staphylococcus Aureus and Escherichia Coli

The focus of present study was to characterize antimicrobial peptide produced by probiotic cultures, Enterococcus durans DB-1aa (MCC4243), Lactobacillus plantarum Cu2-PM7 (MCC4246) and Lactobacillus fermentum Cu3-PM8 (MCC4233) against Staphylococus aureus and E. coli. The growth kinetic assay revealed 24 h of incubation to be optimum for bacteriocin production. The partially purified compound after ion-exchange chromatography was found to be thermoresistant and stable under wide range of pH. The compound was sensitive to proteinase-K, but resistant to trypsin, a-amylase and lipase. The apparent molecular weight of bacteriocin from MCC4243 and MCC4246 was found to be 3.5 KDa. Translated partial amino acid sequence of plnA gene in MCC4246 displayed 48 amino acid sequences showing 100% similarity with plantaricin A of Lactobacillus plantarum (WP_0036419). The sequence revealed 7 β sheets, 6 α sheets, 6 predicted coils and 9 predicted turns. The functions on cytoplasm show 10.82 isoelectric point and 48.6% hydrophobicity. The molecular approach of using Geneious Prime software and protein prediction data base for characterization of bacteriocin is novel and predicts “KSSAYSLQMGATAIKQVKKLFKKWGW” as peptide responsible for antimicrobial activity. The study provides information about broad spectrum bacteriocin in native probiotic culture and paves a way towards its application in functional foods as biopreservative agents.

Kinetics of tau aggregation reveals patient specific tau characteristics among Alzheimer's cases

The accumulation of tau aggregates throughout the human brain is the hallmark of a number of neurodegenerative conditions classified as tauopathies. Increasing evidence shows that tau aggregation occurs in a “prion-like” manner, in which a small amount of misfolded tau protein can induce other, naïve tau proteins to aggregate. Tau aggregates have been found to differ structurally among different tauopathies. Recently, however, we have suggested that tau oligomeric species may differ biochemically among individual patients with sporadic Alzheimer disease, and have also showed that the bioactivity of the tau species, measured using a cell-based bioassay, also varied among individuals. Here, we adopted a live-cell imaging approach to the standard cell-based bioassay to explore further whether the kinetics of aggregation also differentiated these patients. We found that aggregation can be observed to follow a consistent pattern in all cases, with a lag phase, a growth phase, and a plateau phase, which each provide quantitative parameters by which we characterize aggregation kinetics. The length of the lag phase and magnitude of the plateau phase are both dependent upon the concentration of seeding-competent tau, the relative enrichment of which differs among patients. The slope of the growth phase correlates with morphological differences in the tau aggregates, which may be reflective of underlying structural differences. This kinetic assay confirms and refines the concept of heterogeneity in the characteristics of tau proteopathic seeds among individuals with Alzheimer’s disease and is a method by which future studies may characterize longitudinal changes in tau aggregation and the cellular processes which may influence these changes.