Tissue memory CD4+ T cells expressing IL-7 receptor-alpha (CD127) preferentially support latent HIV-1 infection.

The primary reservoir for HIV is within memory CD4+ T cells residing within tissues, yet the features that make some of these cells more susceptible than others to infection by HIV is not well understood. Recent studies demonstrated that CCR5-tropic HIV-1 efficiently enters tissue-derived memory CD4+ T cells expressing CD127, the alpha chain of the IL7 receptor, but rarely completes the replication cycle. We now demonstrate that the inability of HIV to replicate in these CD127-expressing cells is not due to post-entry restriction by SAMHD1. Rather, relative to other memory T cell subsets, these cells are highly prone to undergoing latent infection with HIV, as revealed by the high levels of integrated HIV DNA in these cells. Host gene expression profiling revealed that CD127-expressing memory CD4+ T cells are phenotypically distinct from other tissue memory CD4+ T cells, and are defined by a quiescent state with diminished NFκB, NFAT, and Ox40 signaling. However, latently-infected CD127+ cells harbored unspliced HIV transcripts and stimulation of these cells with anti-CD3/CD28 reversed latency. These findings identify a novel subset of memory CD4+ T cells found in tissue and not in blood that are preferentially targeted for latent infection by HIV, and may serve as an important reservoir to target for HIV eradication efforts

Perspectives from the NanoSafety Modelling Cluster on the validation criteria for (Q)SAR models used in nanotechnology

Nanotechnology and the production of nanomaterials have been expanding rapidly in recent years. Since many types of engineered nanoparticles are suspected to be toxic to living organisms and to have a negative impact on the environment, the process of designing new nanoparticles and their applications must be accompanied by a thorough exposure risk analysis. (Quantitative) Structure-Activity Relationship ([Q]SAR) modelling creates promising options among the available methods for the risk assessment. These in silico models can be used to predict a variety of properties, including the toxicity of newly designed nanoparticles. However, (Q)SAR models must be appropriately validated to ensure the clarity, consistency and reliability of predictions. This paper is a joint initiative from recently completed European research projects focused on developing (Q)SAR methodology for nanomaterials. The aim was to interpret and expand the guidance for the well-known “OECD Principles for the Validation, for Regulatory Purposes, of (Q)SAR Models”, with reference to nano-(Q)SAR, and present our opinions on the criteria to be fulfilled for models developed for nanoparticles

HIV-1: identification of a pathway for virus release and development of a new nanotechnological strategy to counteract the infection

Das Humane Immundefizienz-Virus 1 (HIV-1) rekrutiert Wirtszellproteine und -Signalwege für seinen eigenen Lebenszyklus und beeinträchtigt viele Funktionen von Immunzellen, darunter die Phagozytose von Pathogenen durch Makrophagen. Diese Schwächung der Immunabwehr verursacht das acquired immunodeficiency syndrome (AIDS).Der Zusammenbau von HIV-1 geschieht sowohl an der Plasmamembran als auch in endosomalen Kompartimenten und wird durch das Struktur-Polyprotein Gag kontrolliert, das auch für die Freisetzung virusähnlicher Partikel (VLPs) aus der Wirtszelle sorgt. Vorangegangene Studie haben gezeigt, dass durch hohe induzierte Calciumkonzentrationen im Zytoplasma die Anzahl an VLPs in endolysosomalen Kompartimenten steigt und die VLP-freisetzung drastisch zunimmt. Der verantwortliche Mechanismus ist jedoch bisher unbekannt. Die vorliegende Arbeit zeigt zunächst, dass Calciumausschüttung aus Lysosomen die Fusion von Endosomen und Lysosomen - und damit die Exozytose der in Lysosomen enthaltenen VLPs - auslöst. Dieser Prozess wird durch Synaptotagmin VII reguliert und verhindert den Abbau eines Teils der in späten Endosomen und Lysosomen eingschlossenen VLPs. Der zweite Teil dieser Arbeit beschreibt die Entwicklung eines nanobiotechnologischen Systems zur Eliminierung von Env/Gag-VLPs (HIV-VLPs) mit Hilfe von Makrophagen. Dieses basiert auf Immunoliposomen, die HIV-VLPs über anti-Env-Antikörper binden und von Makrophagen dank membranständigem Phosphatidylserin (PS), einem apoptotischen Signal, phagozytiert werden. Die Lipososmen imitieren apoptotische Zellen und induzieren ihre Internalisierung und die lysosomale Aufnahme von HIV-VLPs. Das System nutzt einen effizienten Internalisierungsweg, der während der HIV-1-Infektion nicht beeinträchtigt ist. Diese Ergebnisse bieten neue Einblicke in die intrazellulären Prozesse der HIV-1 Freisetzung und präsentieren PS-Immunoliposomen als neuen potentiellen nanomedizinischen Ansatz zur Virusbeseitigung und HIV-Antigenpräsentation.Human immunodeficiency virus 1 (HIV-1) hijacks proteins and signaling pathways of the host cell for its own life cycle, thereby impairing many functions of immune cells, including pathogen-phagocytosis by macrophages. The overall weakening of immune functions eventually results in the development of acquired immunodeficiency syndrome (AIDS). HIV-1 assembly takes place at the plasma membrane as well as in endosomal compartments and is governed by the structural polyprotein Gag, which is also sufficient for the release of virus-like particles (VLPs) from the host cell. It was shown that an induced high cytoplasmic calcium concentration increases the amount of VLPs in endo-lysosomal compartments and results in a dramatic enhancement of VLP release [1,2]. However, the mechanism by which calcium can promote the release of VLPs remains to be determined. The first part of this work shows that release of calcium from lysosomes causes fusion between endosomes and lysosomes as well as exocytosis of lysosomeentrapped VLPs. This mechanism is regulated by Synaptotagmin VII and prevents degradation of a part of the late endosome- and lysosome-entrapped VLPs. The second part focuses on the development of a nanobiotechnological system for the clearance of Env/Gag-VLPs (HIV-VLPs) by macrophages. This system is based on immunoliposomes that (1) bind HIV-VLPs via anti-Env antibodies and (2) are phagocytosed by macrophages due to the presence of phosphatidylserine (PS), an apoptotic signal. Essentially, the PS-liposomes mimic apoptotic cells thereby inducing internalization and lysosomal delivery of bound HIV-VLPs. These immunoliposomes exploit an efficient internalization pathway not impaired upon HIV-1 infection. The results of this thesis provide new insights into the intracellular pathways controlling HIV-1 release and demonstrate that PS-immunoliposomes can represent a novel nanomedical approach for viral clearance and HIV antigen presentation

The HIV-1 Envelope Transmembrane Domain Binds TLR2 through a Distinct Dimerization Motif and Inhibits TLR2-Mediated Responses

<div><p>HIV-1 uses a number of means to manipulate the immune system, to avoid recognition and to highjack signaling pathways. HIV-1 infected cells show limited Toll-Like Receptor (TLR) responsiveness via as yet unknown mechanisms. Using biochemical and biophysical approaches, we demonstrate that the trans-membrane domain (TMD) of the HIV-1 envelope (ENV) directly interacts with TLR2 TMD within the membrane milieu. This interaction attenuates TNFα, IL-6 and MCP-1 secretion in macrophages, induced by natural ligands of TLR2 both in <i>in vitro</i> and <i>in vivo</i> models. This was associated with decreased levels of ERK phosphorylation. Furthermore, mutagenesis demonstrated the importance of a conserved GxxxG motif in driving this interaction within the membrane milieu. The administration of the ENV TMD <i>in vivo</i> to lipotechoic acid (LTA)/Galactosamine-mediated septic mice resulted in a significant decrease in mortality and in tissue damage, due to the weakening of systemic macrophage activation. Our findings suggest that the TMD of ENV is involved in modulation of the innate immune response during HIV infection. Furthermore, due to the high functional homology of viral ENV proteins this function may be a general character of viral-induced immune modulation.</p></div

Factors affecting the performance of Bachelor of Science in Nursing students Batch 2015 of De La Salle Health Sciences Institute in administering immunization

This study utilized the quantitative, descriptive type of research. The respondents were the entire population of BSN batch 2015 composed of 89 students who were exposed in the community duty and had performed immunization and were chosen using total population sampling. The instrument used in this study was adapted and modified from the research instrument used by Gamez et al. (2007). Data was analysed using percentage, mean, standard deviation, t-test and Analysis of Variance (ANOVA). Majority of the respondents of the study belonged to the age group of 18-19 years old, female, have monthly income of 30,001 and above and Catholic. The factors often affecting the performance of BSN Batch 2015 in administering immunization were identified as environmental, behavioral and personal factors. There was no significant difference on the factors that affecting the performance of BSN batch 2015 in administering immunization when they were grouped according to age, gender, monthly family income and religion

ENV TMD inhibits secretion of cytokines and chemokines induced by TLR2.

<p>(<b>A–C</b>) RAW cells were incubated with/without the indicated peptides for 2 hours, then washed twice and activated with 500 ng hours, then washed twice and activated with 500 ng ng/ml of purified LTA. Media was collected after 5 hours (TNFα) or 24 hours (MCP-1 and IL-6). ELISA was performed using standard kits. (n = 3, ± represent SD) (<b>D</b>) THP-1 human macrophages were incubated using similar conditions as described in A, and TNFα levels were measured (* - p<0.05).</p