Macrophage autophagy in atherosclerosis

Macrophages play crucial roles in atherosclerotic immune responses. Recent investigation into macrophage autophagy (AP) in atherosclerosis has demonstrated a novel pathway through which these cells contribute to vascular inflammation. AP is a cellular catabolic process involving the delivery of cytoplasmic contents to the lysosomal machinery for ultimate degradation and recycling. Basal levels of macrophage AP play an essential role in atheroprotection during early atherosclerosis. However, AP becomes dysfunctional in the more advanced stages of the pathology and its deficiency promotes vascular inflammation, oxidative stress, and plaque necrosis. In this paper, we will discuss the role of macrophages and AP in atherosclerosis and the emerging evidence demonstrating the contribution of macrophage AP to vascular pathology. Finally, we will discuss how AP could be targeted for therapeutic utility

The IkB kinase inhibitor nuclear factor-kB essential modulator–binding domain peptide for inhibition of balloon injury-induced neointimal formation

Objective—The activation of nuclear factor-kB (NF-kB) is a crucial step in the arterial wall’s response to injury. The identification and characterization of the NF-kB essential modulator– binding domain (NBD) peptide, which can block the activation of the IkB kinase complex, have provided an opportunity to selectively abrogate the inflammation-induced activation of NF-kB. The aim of the present study was to evaluate the effect of the NBD peptide on neointimal formation.<br></br> Methods and Results—In the rat carotid artery balloon angioplasty model, local treatment with the NBD peptide (300 microg/site) significantly reduced the number of proliferating cells at day 7 (by 40%; P<0.01) and reduced injury-induced neointimal formation (by 50%; P<0.001) at day 14. These effects were associated with a significant reduction of NF-kB activation and monocyte chemotactic protein-1 expression in the carotid arteries of rats treated with the peptide. In addition, the NBD peptide (0.01 to 1 micromol/L) reduced rat smooth muscle cell proliferation, migration, and invasion in vitro. Similar results were observed in apolipoprotein E-/-, mice in which the NBD peptide (150 microg/site) reduced wire-induced neointimal formation at day 28 (by 47%; P<0.01).<br></br> Conclusion—The NBD peptide reduces neointimal formation and smooth muscle cell proliferation/migration, both effects associated with the inhibition of NF-kB activation

Functional characterization and transcriptional repression by Lacticaseibacillus paracasei DinJ-YafQ

DinJ-YafQ is a bacterial type II TA system formed by the toxin RNase YafQ and the antitoxin protein DinJ. The activity of YafQ and DinJ has been rigorously studied in Escherichia coli, but little has been reported about orthologous systems identified in different microorganisms. In this work, we report an in vitro and in vivo functional characterization of YafQ and DinJ identified in two different strains of Lacticaseibacillus paracasei and isolated as recombinant proteins. While DinJ is identical in both strains, the two YafQ orthologs differ only for the D72G substitution in the catalytic site. Both YafQ orthologs digest ribosomal RNA, albeit with different catalytic efficiencies, and their RNase activity is neutralized by DinJ. We further show that DinJ alone or in complex with YafQ can bind cooperatively to a 28-nt inverted repeat overlapping the -35 element of the TA operon promoter. Atomic force microscopy imaging of DinJ-YafQ in complex with DNA harboring the cognate site reveals the formation of different oligomeric states that prevent the binding of RNA polymerase to the promoter. A single amino acid substitution (R13A) within the RHH DNA-binding motif of DinJ is sufficient to abolish DinJ and DinJ-YafQ DNA binding in vitro. In vivo experiments confirm the negative regulation of the TA promoter by DinJ and DinJ-YafQ and unveil an unexpected high expression-related toxicity of the gfp reporter gene. A model for the binding of two YafQ-(DinJ)2-YafQ tetramers to the promoter inverted repeat showing the absence of protein-protein steric clash is also presented. KEY POINTS: • The RNase activity of L. paracasei YafQ toxin is neutralized by DinJ antitoxin. • DinJ and DinJ-YafQ bind to an inverted repeat to repress their own promoter. • The R13A mutation of DinJ abolishes DNA binding of both DinJ and DinJ-YafQ

Desarrollo de una aplicación de geofencing en android para monitoreo de corredores estudiantiles

Las amplias capacidades de los dispositivos móviles actuales hacen posible el desarrollo de aplicaciones que sirvan para traer mayor seguridad y tranquilidad a sus usuarios. Este proyecto plantea el desarrollo de una aplicación de monitoreo de estudiantes que utilizan ciertos corredores seguros para ir y volver desde su casa hasta el lugar de destino que puede ser el colegio, un club, la casa de un amigo, etc. Esta aplicación es especialmente útil para niños jóvenes que comienzan a movilizarse por su cuenta donde sus padres muchas veces se preocupan por su seguridad. Esta aplicación proporciona un monitoreo no invasivo alertando si se produce un desvío de / los caminos preestablecidos, así como también al entrar o salir a un área determinada en un horario no esperado utilizando técnicas de geofencing. La aplicación consta de un backend de configuración web y una aplicación móvil con la cual se realiza el monitoreo utilizando la geolocalización de los dispositivos móviles.Red de Universidades con Carreras en Informátic

Opioids inhibit the induction of nitric oxide synthase in J774 macrophages.

The effect of opioids on NO production by LPS-stimulated murine macrophages J774 has been investigated. Morphine (mu and k opioid receptor agonist), DAGO (selective mu receptor agonist) and U50-488H (selective k receptor agonist), added (10(-10)-10(-6) M) to the cells 0.5 h before activation with LPS, significantly inhibited NO production. This effect was reverted by naloxone (10(-12)-10(-8) M), an opioid specific antagonist. In contrast, DPDPE and deltorphin II respectively delta 1 and delta 2 receptor agonists (10(-10)-10(-6) M) did not affect NO generation. Morphine was not able to inhibit NO production when added after LPS challenge. The results of the present study indicate that opioids are able to inhibit NO formation in LPS-activated macrophages through the involvement of specific opioid receptors. Moreover, the ability of morphine to inhibit NO production only when given before LPS challenge suggests that the opiate inhibits the induction but not the activity of the inducible NO synthase