Andrea Hönscheid scite author profile

Zinc signals, i.e. a change of the intracellular concentration of free zinc ions in response to receptor stimulation, are involved in signal transduction in several immune cells. Here, the role of zinc signals in T-cell activation by IL-2 was investigated in the murine cytotoxic T-cell line CTLL-2 and in primary human T cells. Measurements with the fluorescent dyes FluoZin-3 and Zinquin showed that zinc is released from lysosomes into the cytosol in response to stimulation of the IL-2-receptor. Activation of the ERK-pathway was blocked by chelation of free zinc with N,N,N 0 ,N 0 -tetrakis-2(pyridyl-methyl)ethylenediamine, whereas zinc was not required for STAT5 phosphorylation. In addition, the key signaling molecules MEK and ERK were activated in response to elevated free intracellular zinc, induced by incubation with zinc and the ionophore pyrithione. Downstream of ERK activation, ERK-specific gene expression of c-fos and IL-2-induced proliferation was found to depend on zinc. Further experiments indicated that inhibition of MEK and ERK-dephosphorylating protein phosphatases is the molecular mechanism for the influence of zinc on this pathway. In conclusion, an increase of cytoplasmic free zinc is required for IL-2-induced ERK signaling and proliferation of T cells. Key words: IL-2 . T cells . Zinc Supporting Information available online IntroductionZinc signals have been observed in different cell types of the immune system, including monocytes, dendritic cells, and mast cells [1]. T-cell function is particularly susceptible to zinc deprivation, and zinc signals were suggested to activate protein kinase C in T cells [1,2]. Furthermore, zinc is involved in the activation of the Src-family kinase Lck by the TCR. Here, zinc ions are required for interactions at two protein/protein interface sites. First, they stabilize the interaction between Lck and CD4 or CD8, recruiting the kinase to the TCR signaling complex [3]. Second, zinc ions stabilize homodimerization of Lck, which promotes activating transphosphorylation between two Lck molecules [4]. Cellular zinc homeostasis is mediated by ten members of the ZnT family and 14 members of the Zrt-, Irt-like protein (ZIP) family of zinc transporters [5]. Intracellular localization for most of these transporters remains to be determined. So far, no nuclear zinc transporters were identified, even though there is evidence that nuclear and cytoplasmic zinc are differentially regulated [6]. In general, ZIP transport zinc into the cytoplasm, whereas ZnT transport zinc out of the cell or into cellular compartments, SHORT COMMUNICATION 1496including different vesicular structures [7]. Importantly, zinc accumulates in a lysosomal compartment of T cells, from which it is released by ZIP8 in response to TCR-mediated activation by antibodies against CD2, CD3, and CD28 [8].Previously, zinc was also shown to be required for T-cell activation by IL-2, a growth-factor that stimulates proliferation of T cells [9]. These data point to IL-2 signaling as another target for zinc in T cell...

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T-Lymphocytes: A Target for Stimulatory and Inhibitory Effects of Zinc Ions

Hönscheid

Rink²,

Haase

2009

EMIDDT

100

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The trace element zinc is a crucial cofactor for many proteins involved in cellular processes like differentiation, proliferation and apoptosis. Zinc homeostasis is tightly regulated and disturbance of this homeostasis due to genetic defects, zinc deficiency, or supplementation influences the development and the progression of various infectious and autoimmune diseases. The immune system is strongly impaired during zinc deficiency, predominantly the cell-mediated response by T-lymphocytes. During zinc deprivation T-lymphocyte development, polarization into effector cells, and function are impaired. This leads to reduced T-cell numbers, a decreased ratio of type 1 to type 2 T-helper cells with reduced production of T-helper type 1 cytokines like interferon-gamma, and compromised T-cell mediated immune defense. Accordingly, disturbed zinc homeostasis increases the risk for infections, and zinc supplementation restores normal immune function. Furthermore, several disorders, like mycobacterial infections, asthma, diabetes, and rheumatoid arthritis are accompanied by decreased zinc levels and in some cases disease progression can be affected by zinc supplementation. On the molecular level, apoptosis of T-cell precursors is influenced by zinc via the Bcl-2/Bax ratio, and zinc ions inhibit caspases-3, -6, -7, and -8. In mature T-cells, zinc interacts with kinases involved in T-cell activation, like protein kinase C and the lymphocyte protein tyrosine kinase (Lck), while higher zinc concentrations are inhibitory, reducing the activities of the interleukin-1 receptor-associated kinase (IRAK) and calcineurin. Taken together, zinc homeostasis influences T-lymphocytes via several molecular targets, leading to a modulation of T-cell-dependent immune responses.

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Autoimmune lymphoproliferative syndrome-like disease in patients with LRBA mutation

Revel‐Vilk

Fischer

Keller

et al. 2015

Clinical Immunology

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Cellular zinc homeostasis is a regulator in monocyte differentiation of HL-60 cells by 1α,25-dihydroxyvitamin D3

Dubben

Hönscheid

Winkler

et al. 2010

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It was reported previously that zinc-deficient mice show impaired lymphopoiesis. At the same time, monocyte numbers in these animals are increased, indicating a negative impact of zinc on monocyte development. Here, we investigate the role of zinc homeostasis in the differentiation of myeloid precursors into monocytes. Reduced gene expression of several zinc transporters, predominantly from the Zip family, was observed during 1 alpha, 25-dihydroxyvitamin D(3) (1,25D(3))-induced differentiation of HL-60 cells. This was accompanied by a reduction of intracellular-free zinc, measured by FluoZin-3. Amplifying this reduction with the zinc chelator TPEN or zinc-depleted cell-culture medium enhanced 1,25D(3)-induced expression of monocytic surface markers CD11b and CD14 on HL-60, THP-1, and NB4 cells. In contrast, differentiation of NB4 cells to granulocytes was not zinc-sensitive, pointing toward a specific effect of zinc on monocyte differentiation. Further, monocyte functions, such as TNF-alpha secretion, phagocytosis, and oxidative burst, were also augmented by differentiation in the presence of TPEN. The second messenger cAMP promotes monocyte differentiation. We could show that zinc inhibits the cAMP-synthesizing enzyme adenylate cyclase, and chelation of zinc by TPEN increases cAMP generation after stimulation with the adenylate cyclase activator forskolin. Based on our in vitro results and the in vivo observations from the literature, we suggest a model in which the intracellular-free zinc concentration limits AC activity, and the decrease of zinc after 1,25D(3) treatment promotes differentiation by relieving AC inhibition. Thus, cellular zinc homeostasis acts as an endogenous modulator of monocyte differentiation.

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