Differential impact of high-salt levels in vitro and in vivo on macrophage core functions.

The consumption of processed food is on the rise leading to huge intake of excess dietary salt, which strongly correlates with development of hypertension, often leading to cardiovascular diseases such as stroke and heart attack, as well as activation of the immune system. The effect of salt on macrophages is especially interesting as they are able to sense high sodium levels in tissues leading to transcriptional changes. In the skin, macrophages were shown to influence lymphatic vessel growth which, in turn, enables the transport of excess salt and thereby prevents the development of high blood pressure. Furthermore, salt storage in the skin has been linked to the onset of pro-inflammatory effector functions of macrophages in pathogen defence. However, there is only little known about the mechanisms which are involved in changing macrophage function to salt exposure. Here, we characterize the response of macrophages to excess salt both in vitro and in vivo. Our results validate and strengthen the notion that macrophages exhibit chemotactic migration in response to salt gradients in vitro. Furthermore, we demonstrate a reduction in phagocytosis and efferocytosis following acute salt challenge in vitro. While acute exposure to a high-salt diet in vivo has a less pronounced impact on macrophage core functions such as phagocytosis, our data indicate that prolonged salt challenge may exert a distinct effect on the function of macrophages. These findings suggest a potential role for excessive salt sensing by macrophages in the manifestation of diseases related to high-salt diets and explicitly highlight the need for in vivo work to decipher the physiologically relevant impact of excess salt on tissue and cell function.

Impaired neurogenesis alters brain biomechanics in a neuroprogenitor-based genetic subtype of congenital hydrocephalus.

Hydrocephalus, characterized by cerebral ventricular dilatation, is routinely attributed to primary defects in cerebrospinal fluid (CSF) homeostasis. This fosters CSF shunting as the leading reason for brain surgery in children despite considerable disease heterogeneity. In this study, by integrating human brain transcriptomics with whole-exome sequencing of 483 patients with congenital hydrocephalus (CH), we found convergence of CH risk genes in embryonic neuroepithelial stem cells. Of all CH risk genes, TRIM71/lin-41 harbors the most de novo mutations and is most specifically expressed in neuroepithelial cells. Mice harboring neuroepithelial cell-specific Trim71 deletion or CH-specific Trim71 mutation exhibit prenatal hydrocephalus. CH mutations disrupt TRIM71 binding to its RNA targets, causing premature neuroepithelial cell differentiation and reduced neurogenesis. Cortical hypoplasia leads to a hypercompliant cortex and secondary ventricular enlargement without primary defects in CSF circulation. These data highlight the importance of precisely regulated neuroepithelial cell fate for normal brain-CSF biomechanics and support a clinically relevant neuroprogenitor-based paradigm of CH.

The mRNA repressor TRIM71 cooperates with Nonsense-Mediated Decay factors to destabilize the mRNA of CDKN1A/p21.

Nonsense-mediated decay (NMD) plays a fundamental role in the degradation of premature termination codon (PTC)-containing transcripts, but also regulates the expression of functional transcripts lacking PTCs, although such 'non-canonical' functions remain ill-defined and require the identification of factors targeting specific mRNAs to the NMD machinery. Our work identifies the stem cell-specific mRNA repressor protein TRIM71 as one of these factors. TRIM71 plays an essential role in embryonic development and is linked to carcinogenesis. For instance, TRIM71 has been correlated with advanced stages and poor prognosis in hepatocellular carcinoma. Our data shows that TRIM71 represses the mRNA of the cell cycle inhibitor and tumor suppressor CDKN1A/p21 and promotes the proliferation of HepG2 tumor cells. CDKN1A specific recognition involves the direct interaction of TRIM71 NHL domain with a structural RNA stem-loop motif within the CDKN1A 3'UTR. Importantly, CDKN1A repression occurs independently of miRNA-mediated silencing. Instead, the NMD factors SMG1, UPF1 and SMG7 assist TRIM71-mediated degradation of CDKN1A mRNA, among other targets. Our data sheds light on TRIM71-mediated target recognition and repression mechanisms and uncovers a role for this stem cell-specific factor and oncogene in non-canonical NMD, revealing the existence of a novel mRNA surveillance mechanism which we have termed the TRIM71/NMD axis.

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.

Vav1 regulates MHCII expression in murine resting and activated B cells.

Vav1 is a guanine nucleotide exchange factor (GEF) for Rho GTPases, which is exclusively expressed in cells of the hematopoietic system. In addition to its well-documented GEF activity, it was suggested to have other functions due to the presence of multiple domains and nuclear localization signals in its protein structure. Although GEF-dependent and GEF-independent functions of vav have been implicated in T-cell development and T-cell receptor signaling, the role of vav1 in antigen-presenting cells is poorly understood. We found that vav1 is an important regulator of MHCII expression and transport. Microarray analysis of unstimulated bone marrow-derived macrophages revealed a novel role of vav1 in transcriptional regulation of the MHCII locus, possibly by indirect means. Primary immune cells from vav1-deficient mice had a significantly lower constitutive surface expression of MHCII with the strongest impact observed on splenic and peritoneal B cells. Impaired MHCII expression resulted in a diminished capacity for T-cell activation. Using 6-thio-GTP, a specific inhibitor of the GEF function of vav1, we were able to show that the GEF activity is required for MHCII upregulation in B cells after stimulation with LPS. Furthermore, our data show that vav1 not only affects transcription of the MHCII locus but also is an important regulator of MHCII protein transport to the cell surface.

Aryl hydrocarbon receptor is critical for homeostasis of invariant gammadelta T cells in the murine epidermis.

An immunoregulatory role of aryl hydrocarbon receptor (AhR) has been shown in conventional αß and γδ T cells, but its function in skin γδ T cells (dendritic epidermal T cells [DETC]) is unknown. In this study, we demonstrate that DETC express AhR in wild-type mice, and are specifically absent in the epidermis of AhR-deficient mice (AhR-KO). We show that DETC precursors are generated in the thymus and home to the skin. Proliferation of DETC in the skin was impaired in AhR-KO mice, resulting in a >90% loss compared with wild type. Surprisingly, DETC were not replaced by αß T cells or conventional γδ T cells, suggesting a limited time frame for seeding this niche. We found that DETC from AhR-KO mice failed to express the receptor tyrosine kinase c-Kit, a known growth factor for γδ T cells in the gut. Moreover, we found that c-kit is a direct target of AhR, and propose that AhR-dependent c-Kit expression is potentially involved in DETC homeostasis. DETC are a major source of GM-CSF in the skin. Recently, we had shown that impaired Langerhans cell maturation in AhR-KO is related to low GM-CSF levels. Our findings suggest that the DETCs are necessary for LC maturation, and provide insights into a novel role for AhR in the maintenance of skin-specific γδ T cells, and its consequences for the skin immune network.

The aryl hydrocarbon receptor mediates UVB radiation-induced skin tanning.

Melanogenesis is the vital response to protect skin cells against UVB-induced DNA damage. Melanin is produced by melanocytes, which transfer it to surrounding keratinocytes. Recently, we have shown that the aryl hydrocarbon receptor (AhR) is part of the UVB-stress response in epidermal keratinocytes. UVB triggers AhR signaling by generating the AhR ligand 6-formylindolo(3,2-b)carbazole from tryptophan. We show here that normal murine melanocytes express functional AhR. Using standard UVB tanning protocols, AhR-deficient mice were shown to tan significantly weaker than wild-type mice; in these mice, tyrosinase activity in the epidermis was lower as well. Tanning responses and tyrosinase activity, however, were normal in keratinocyte-specific conditional AhR knockout mice, indicating that release of melanogenic keratinocyte factors is unaffected by the UVB-AhR signaling pathway and that the diminished tanning response in AhR(-/-) mice is confined to the level of melanocytes. Accordingly, the number of dihydroxyphenylalanin-positive melanocytes increased significantly less on UVB irradiation in AhR(-/-) mice than in wild-type mice. This difference in melanocyte number was associated with a significantly reduced expression of stem cell factor-1 and c-kit in melanocytes of AhR(-/-) mice. Thus, the environmental signal sensor AhR links solar UVB radiation to skin pigmentation.

The aryl hydrocarbon receptor (AHR), a novel regulator of human melanogenesis.

Skin cancer, chloracne and hyperpigmentation have been associated with the exposure to environmental contaminants such as polychlorinated biphenyls, dioxins or polycyclic aromatic hydrocarbons. These compounds are xenobiotic high-affinity ligands for the aryl hydrocarbon receptor (AHR), a ligand-activated transcription factor with important physiological roles in, for example, the control of cell proliferation and inflammation. We show here that exposure of normal human melanocytes to the most potent dioxin, 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD), results in activation of the AHR signaling pathway and an AHR-dependent induction of tyrosinase activity, the key enzyme of the melanogenic pathway. In accordance with the upregulation of tyrosinase enzyme activity, total melanin content was also elevated in TCDD-exposed melanocytes. Neither the induction of tyrosinase enzyme activity or of total melanin could be attributed to enhanced cell proliferation, but was rather due to the induction of tyrosinase and tyrosinase-related protein 2 gene expression. Thus, the AHR is able to modulate melanogenesis by controlling the expression of melanogenic genes.

Small chemicals, bioactivation, and the immune system--a fragile balance of i-tox and benefits?

Immunotoxicology concerns actions of chemicals which lead to adverse immune reactions. Current research challenges are the prediction of the immunotoxicologic risk potential of a chemical and a deeper mechanistic understanding of chemical-induced adverse immune reactions, to develop therapeutic or avoidance strategies. Small chemicals (SCs) can interfere with any cell type or function of the immune system. SCs are ubiquitous as food components, life-style products, or environmental pollutants. Besides their possible unspecific toxicity, they might form protein adducts, become part of recognized antigens, or they could be disruptors of immune signalling pathways. The incidence of autoimmune and allergic diseases has been rising over the last years, and evidence increases that SCs are important in this. Also, immunopharmacologists actively search for immunomodulating chemicals as urgently needed drugs. The aryl hydrocarbon receptor (AhR) is a SC-triggered transcription factor, and thus could link environmental signals to cellular responses. Recent research has shown a defined role for AhR in immunotoxicology. Here, we discuss concepts of SC immunotoxicity, and how AhR might be involved in adverse immune responses.

Langerhans cell maturation and contact hypersensitivity are impaired in aryl hydrocarbon receptor-null mice.

Langerhans cells (LC) are professional APCs of the epidermis. Recently, it was suggested that they are tolerogenic and control adverse immune reactions, including against low molecular mass chemicals. The aryl hydrocarbon receptor (AhR), a ligand-activated transcription factor, is involved in low molecular mass chemical metabolism and cell differentiation. Growing evidence suggests a role for the AhR in the immune system, for example, by influencing dendritic cell and T cell differentiation. We found that the AhR and its repressor AhRR are expressed in LC of C57BL/6 mice. LC, unexpectedly, did not respond to a strong AhR agonist with induction of transcripts of xenobiotic metabolizing enzymes. To test for a physiological role of the AhR in LC, we investigated how AhR deficiency affects LC. We found that AhR-deficient LC were impaired in maturation; they remained smaller and less granular, did not up-regulate expression of costimulatory molecules CD40, CD80, and CD24a during in vitro maturation, and their phagocytic capacity was higher. Interestingly, the mRNA expression of tolerogenic Ido was severely decreased in AhR-deficient LC, and enzyme activity could not be induced in AhR-deficient bone marrow-derived dendritic cells. GM-CSF, needed for LC maturation, was secreted in significantly lower amounts by AhR-deficient epidermal cells. Congruent with this impaired maturity and capacity to mature, mice mounted significantly weaker contact hypersensitivity against FITC. Our data suggest that the AhR is involved in LC maturation, both cell autonomously and through bystander cells. At the same time, the AhR might be part of the risk strategy of LC against unwanted immune activation by potential skin allergens.

Small molecules as friends and foes of the immune system.

Every organism is in contact with numerous small molecules (<1000 Da). Chemicals may cause or trigger adverse health effects, including diseases of the immune system. They may also be exploited as drugs. In this review, we look at the interaction between small molecules and the immune system. We discuss the hapten and pharmacological interaction concepts of chemical interaction to trigger T cells and how chemicals can participate in cellular signaling pathways. As a sensor of small molecules, the arylhydrocarbon receptor controls expression of many xenobiotic metabolizing enzymes, including those in the immunological barrier organs; the skin and gut. The relevance of the arylhydrocarbon receptor in the dynamic interaction of the immune system with the chemical environment is therefore discussed.

CD24a expression levels discriminate Langerhans cells from dermal dendritic cells in murine skin and lymph nodes.

Langerhans cells (LCs) and dermal dendritic cells (dDCs) are the professional antigen-presenting cells of the skin. Recently, their immunogenic versus tolerogenic role has come under re-investigation. LCs are distinguished from dDCs by Langerin (CD207) staining or by detection of Birbeck granules. However, for in vitro experiments it is desirable to have a simple and robust flow cytometric demarcation of both cell types. We show here that CD24a is expressed on LCs but not on dDCs isolated directly from the skin. Moreover, in combination with major histocompatibility complex class II (MHCII), CD24a expression levels distinguish LCs from dDCs in skin-draining lymph nodes after antigen activation and migration. High expression of CD24a correlated strictly with CD207 expression. MHCII(high) cells were unique for skin-draining lymph nodes and were shown to be the only cells carrying antigen after FITC painting of the skin. CD24a expression levels further differentiated LCs and dDCs in the MHCII(high) population. As staining for CD24a does not require fixation of cells, CD24a-stained cells can be used for in vitro experiments to analyze and compare the functional roles and properties of dDCs and LCs.

Tissue distribution and function of the Aryl hydrocarbon receptor repressor (AhRR) in C57BL/6 and Aryl hydrocarbon receptor deficient mice.

The Aryl hydrocarbon receptor repressor (AhRR) is a new member of bHLH-PAS proteins which is important in the regulation of cell growth and differentiation. The AhRR shares structural similarities with Aryl hydrocarbon receptor (AhR) and AhR nuclear translocator (ARNT). The AhRR is thought to be involved in transcriptional control of AhR-regulated genes by sequestering ARNT. Most of the knowledge of regulation and function of the AhRR is from studies in cell lines. Here, we report the tissue distribution of AhRR in AhR deficient and wild type C57BL/6 mice. In addition, the inducibility of the AhRR and Cytochrome P450 (CYP) 1A1 in response to benzo(a)pyrene (B(a)P) (10 mg/kg bw i.p.) was investigated. The results show that the AhRR mRNA expression pattern in untreated C57BL/6 mice varies across tissues with high levels in hearts and brains. In other tissues, AhRR mRNA expression was low. In contrast to wild-type animals, the tissue levels in AhR-/- mice were about two to three orders of magnitude lower. Treatment of wild-type animals with B(a)P resulted in an induced AhRR expression in liver, spleen, lung and ovary. No significant induction of AhRR mRNA was found in brain and heart tissues, which have a constitutively high level of AhRR expression. Simultaneous measurements of CYP1A1 and AhRR mRNA expression do not strongly support the view that the AhRR tissue pattern triggers the tissue specific responsiveness of AhR-regulated genes to B(a)P treatment.