Arginine-based cationic liposomes accelerate T cell activation and differentiation in vitro.

Cationic liposomes are versatile lipid nanocarriers to improve the pharmacological properties of drug payloads. Recent advantages include the application of their intrinsic immunostimulatory effects to enhance immune activation. Herein, we report for the first time the structural effect of cationic lipids in promoting T cell activation and differentiation in vitro. Two types of cationic liposomes R3C14 and R5C14 were prepared from single type of lipids Arg-C3-Clu2C14 or Arg-C5-Clu2C14, which bear arginine head group and ditetradecyl tails but vary in the carbon number of the spacer in between. Murine CD8 or CD4 T cells were pretreated with 50 µM of each type of liposomes for 2 h, followed by stimulation with anti-CD3/CD28 antibodies for 24 h. In comparison to liposome-untreated T cells, R5C14-pretreatment induced a robust T cell activation (IL-2, CD25+) and differentiation into effector cells (CD44high, CD62Llow), whereas R3C14 did not show comparable effect. Furthermore, a weak activation of nuclear factor of activated T cells (NFAT) was detected in Jurkat-Lucia NFAT cells (InvivoGen), suggesting a potential signaling pathway for the liposomal effect. Although R5C14 liposomes did not activate T cells without subsequent CD3/CD28 stimulation, this study implied a recessive effect of some cationic adjuvant in priming T cells to enhance their responsiveness to antigens.

Cytohesin-3 is required for full insulin receptor signaling and controls body weight via lipid excretion.

Insulin plays a central role in regulating metabolic homeostasis and guanine-nucleotide exchange factors of the cytohesin family have been suggested to be involved in insulin signal transduction. The Drosophila homolog of cytohesin-3, steppke, has been shown to be essential for insulin signaling during larval development. However, genetic evidence for the functional importance of cytohesin-3 in mammals is missing. We therefore analyzed the consequences of genetic cytohesin-3-deficiency on insulin signaling and function in young and aged mice, using normal chow or high-fat diet (HFD). Insulin-receptor dependent signaling events are significantly reduced in liver and adipose tissue of young cytohesin-3-deficient mice after insulin-injection, although blood glucose levels and other metabolic parameters remain normal in these animals. Interestingly, however, cytohesin-3-deficient mice showed a reduced age- and HFD-induced weight gain with a significant reduction of body fat compared to wild-type littermates. Furthermore, cytohesin-3-deficient mice on HFD displayed no alterations in energy expenditure, but had an increased lipid excretion instead, as well as a reduced expression of genes essential for bile acid synthesis. Our findings show for the first time that an intact cyth3 locus is required for full insulin signaling in mammals and might constitute a novel therapeutic target for weight reduction.

The PDL1-inducible GTPase Arl4d controls T effector function by limiting IL-2 production.

Interleukin-2 (IL-2) is a key regulator of adaptive immune responses but its regulation is incompletely understood. We previously found that PDL1-dependent signals were pivotal for liver sinusoidal endothelial cell-mediated priming of CD8 T cells, which have a strongly reduced capacity to produce IL-2. Here, we show that the expression of the ARF-like GTPase Arl4d is PD-L1-dependently induced in such LSEC-primed T cells, and is associated with reduced IL-2 secretion and Akt phosphorylation. Conversely, Arl4d-deficient T cells overproduced IL-2 upon stimulation. Arl4d-deficiency in CD8 T cells also enhanced their expansion and effector function during viral infection in vivo. Consistent with their increased IL-2 production, Arl4d-deficient T cells showed enhanced development into KLRG1+CD127- short-lived effector cells (SLEC), which is dependent on IL-2 availability. Thus, our data reveal a PD-L1-dependent regulatory circuitry that involves the induction of Arl4d for limiting IL-2 production in T cells.

Hepatitis C coinfection enhances sensitization of CD4(+) T-cells towards Fas-induced apoptosis in viraemic and HAART-controlled HIV-1-positive patients.

BACKGROUND: Recently, we identified increased rates of CD4(+) T-cell apoptosis in HCV-infected HIV-positive patients as a potential mechanism for enhanced mortality in patients with HIV/HCV coinfection. Since this effect might be attributed to changes in receptor-induced apoptosis, we studied expression and function of Fas ligand (FasL) and its death receptor Fas on CD4(+) T-cells in HIV/HCV coinfection. METHODS: In this cross-sectional study, we simultaneously analysed surface expression of Fas and FasL on CD4(+) T-cells and serum levels of soluble FasL in HCV/HIV-coinfected, HIV-monoinfected and HCV-monoinfected patients. Susceptibility to FasL-induced apoptosis was analysed by incubating isolated peripheral blood mononuclear cells with rhFasL followed by measuring CD4(+) T-cell apoptosis. RESULTS: HIV and HCV monoinfection were associated with significantly enhanced surface expression of Fas. Highest Fas expression was detected in HIV/HCV-coinfected patients and correlated with low CD4(+) T-cell counts. By contrast, elevated levels of soluble and cellular FasL were found only in patients with HIV infection, but not in patients with HCV infection. Importantly, enhanced Fas expression in HCV/HIV coinfection rendered CD4(+) T-cells more susceptible towards FasL-induced apoptosis. While effective HAART normalized expression and secretion of FasL in HIV-infected and HIV/HCV-coinfected patients, expression of Fas decreased only slightly and still remained significantly elevated as compared with healthy controls. CONCLUSIONS: Our findings suggest a synergistic mechanism in HIV/HCV coinfection between up-regulation of Fas expression on CD4(+) T-cells and HIV-induced elevated levels of cellular and soluble FasL. Together, both effects contribute to enhanced apoptosis of CD4(+) T-cells in HIV/HCV coinfection.