Participation of protease‐activated receptor‐1 in thrombin‐induced microglial activation
Activation of microglia, the resident macrophages in the CNS, plays a significant role in neuronal death or degeneration in a broad spectrum of CNS disorders. Recent studies indicate that nanomolar concentrations of the serine protease, thrombin, can activate microglia in culture. However, in contrast to other neural cells responsive to thrombin, the participation of novel protease-activated receptors (PARs), such as the prototypic thrombin receptor PAR1, in thrombin-induced microglial activation was cast in doubt. In this report, by utilizing primary microglial cultures from PAR1 knockout (PAR1-/-) mice, application of the PAR1 active peptide TRAP-6 (SFLLRN) in comparison to a scrambled peptide (LFLNR), we have unambiguously demonstrated that murine microglia constitutively express PAR1 mRNA that is translated into fully functional protein. Activation of the microglial PAR1 induces a rapid cytosolic free [Ca 2+ ] i increase and transient activation of both p38 and p44/42 mitogen-activated protein kinases. Moreover, although in part, this PAR1 activation directly contributes to thrombin-induced microglial proliferation. Furthermore, although not directly inducing tumor necrosis factor-a (TNF-a) release, PAR1 activation up-regulates microglial CD40 expression and potentiates CD40 ligand-induced TNF-a production, thus indirectly contributing to microglial activation. Taken together, these results demonstrate an essential role of PAR1 in thrombin-induced microglial activation. In addition, strategies aimed at blocking thrombin signaling through PAR1 may be therapeutically valuable for diseases associated with cerebral vascular damage and significant inflammation with microglial activation.
Genetic mapping of mutations in model systems has facilitated the identification of genes contributing to fundamental biological processes including human diseases. However, this approach has historically required the prior characterization of informative markers. Here we report a fast and cost-effective method for genetic mapping using next-generation sequencing that combines single nucleotide polymorphism discovery, mutation localization, and potential identification of causal sequence variants. In contrast to prior approaches, we have developed a hidden Markov model to narrowly define the mutation area by inferring recombination breakpoints of chromosomes in the mutant pool. In addition, we created an interactive online software resource to facilitate automated analysis of sequencing data and demonstrate its utility in the zebrafish and mouse models. Our novel methodology and online tools will make next-generation sequencing an easily applicable resource for mutation mapping in all model systems.[Supplemental material is available for this article.]There can be little argument that genetic mapping has made a substantial contribution to our understanding of biology. For many years these studies used phenotypically defined markers, such as those used by Morgan in Drosophila and Haldane in mice (Morgan 1911;Haldane et al. 1915). The modern era of genetic analysis was heralded by the recognition that variation in genomic DNA sequence itself could be used as a facile assay for mapping (Botstein et al. 1980). This was initially accomplished using analysis of restriction fragmentlength polymorphisms, which were later replaced by microsatellites and subsequently by single nucleotide polymorphisms (SNPs). Despite the remarkable technological advances, these approaches hold in common with those of Morgan and Haldane the utilization of prespecified markers. Next-generation sequencing (NGS) technology enables simultaneous discovery of very dense sets of informative markers and actual gene mapping in the same experiment. Here, we present a strategy and computational tools to map genes in model organisms using sequencing of pooled samples. The approach can be applied to any model organism with a characterized genome and also to both spontaneous and induced mutants. We demonstrate the utility of the strategy and efficiency of the computational approach by mapping spontaneous and ethylnitrosourea (ENU)-induced developmental mutants in zebrafish and mouse.Large-scale forward mutagenesis screens in zebrafish have been used with success to investigate fundamental developmental processes. While the recent completion of the zebrafish genome has greatly aided in the identification of genes, mapping analyses continue to rely on the use of traditional microsatellite markers. However, the utilization of SNPs for mapping of zebrafish mutants was proposed almost a decade ago (Stickney et al. 2002), large numbers of SNPs have been identified (Guryev et al. 2006;Bradley et al. 2007), and the application of NGS for SNP discovery and mutat...
SUMMARY Sorting of endocytic ligands and receptors is critical for diverse cellular processes. The physiological significance of endosomal sorting proteins in vertebrates, however, remains largely unknown. Here we report that sorting nexin 3 (Snx3) facilitates the recycling of transferrin receptor (Tfrc), and thus is required for the proper delivery of iron to erythroid progenitors. Snx3 is highly expressed in vertebrate hematopoietic tissues. Silencing of Snx3 results in anemia and hemoglobin defects in vertebrates due to impaired transferrin (Tf)-mediated iron uptake and its accumulation in early endosomes. This impaired iron assimilation can be complemented with non-Tf iron chelates. We show that Snx3 and Vps35, a component of the retromer, interact with Tfrc to sort it to the recycling endosomes. Our findings uncover a role of Snx3 in regulating Tfrc recycling, iron homeostasis, and erythropoiesis. Thus, the identification of Snx3 provides a genetic tool for exploring erythropoiesis and disorders of iron metabolism.
The promising clinical effects of mesenchymal stromal/ stem cells (MSCs) rely especially on paracrine and nonimmunogenic mechanisms. Delivery routes are essential for the efficacy of cell therapy and systemic delivery by infusion is the obvious goal for many forms of MSC therapy. Lung adhesion of MSCs might, however, be a major obstacle yet to overcome. Current knowledge does not allow us to make sound conclusions whether MSC lung entrapment is harmful or beneficial, and thus we wanted to explore MSC lung adhesion in greater detail. We found a striking difference in the lung clearance rate of systemically infused MSCs derived from two different clinical sources, namely bone marrow (BM-MSCs) and umbilical cord blood (UCB-MSCs). The BM-MSCs and UCB-MSCs used in this study differed in cell size, but our results also indicated other mechanisms behind the lung adherence. A detailed analysis of the cell surface profiles revealed differences in the expression of relevant adhesion molecules. The UCB-MSCs had higher expression levels of a4 integrin (CD49d, VLA-4), a6 integrin (CD49f, VLA-6), and the hepatocyte growth factor receptor (c-Met) and a higher general fucosylation level. Strikingly, the level of CD49d and CD49f expression could be functionally linked with the lung clearance rate. Additionally, we saw a possible link between MSC lung adherence and higher fibronectin expression and we show that the expression of fibronectin increases with MSC culture confluence. Future studies should aim at developing methods of transiently modifying the cell surface structures in order to improve the delivery of therapeutic cells.
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