Maintenance of Bone Homeostasis by DLL1‐Mediated Notch Signaling

Adult bone mass is maintained through a balance of the activities of osteoblasts and osteoclasts. Although Notch signaling has been shown to maintain bone homeostasis by controlling the commitment, differentiation, and function of cells in both the osteoblast and osteoclast lineages, the precise mechanisms by which Notch performs such diverse and complex roles in bone physiology remain unclear. By using a transgenic approach that modified the expression of delta‐like 1 (DLL1) or Jagged1 (JAG1) in an osteoblast‐specific manner, we investigated the ligand‐specific effects of Notch signaling in bone homeostasis. This study demonstrated for the first time that the proper regulation of DLL1 expression, but not JAG1 expression, in osteoblasts is essential for the maintenance of bone remodeling. DLL1‐induced Notch signaling was responsible for the expansion of the bone‐forming cell pool by promoting the proliferation of committed but immature osteoblasts. However, DLL1‐Notch signaling inhibited further differentiation of the expanded osteoblasts to become fully matured functional osteoblasts, thereby substantially decreasing bone formation. Osteoblast‐specific expression of DLL1 did not alter the intrinsic differentiation ability of cells of the osteoclast lineage. However, maturational arrest of osteoblasts caused by the DLL1 transgene impaired the maturation and function of osteoclasts due to a failed osteoblast‐osteoclast coupling, resulting in severe suppression of bone metabolic turnover. Taken together, DLL1‐mediated Notch signaling is critical for proper bone remodeling as it regulates the differentiation and function of both osteoblasts and osteoclasts. Our study elucidates the importance of ligand‐specific activation of Notch signaling in the maintenance of bone homeostasis. J. Cell. Physiol. 232: 2569–2580, 2017. © 2016 The Authors. Journal of Cellular Physiology Published by Wiley Periodicals Inc.     

Physiological stress exacerbates murine colitis by enhancing proinflammatory cytokine expression that is dependent on IL-18

Psychological stress is an environmental factor considered to be a precipitating factor of inflammatory bowel disease. Interleukin (IL)-18 plays a role in stress-induced aggravation in some diseases. The aim of this study was to establish a model of murine colitis exacerbated by psychological stress and to clarify the role of IL-18 in this model. Male C57Bl/6 mice and IL-18(-/-) mice were used for this study. The mice received dextran sulfate sodium (DSS) for induction of colitis. Some mice were exposed to psychological stress using a communication box. Body weight, colonic length, and histological inflammation were measured for assessment of colitis. Tumor necrosis factor (TNF)-α and IL-18 expression in the colon and IL-18 expression in the adrenal gland were analyzed using real-time PCR. The effect of anti-IL-18 antibody was also investigated. Effects of TNF-α and IL-18 on cytokine expressions were studied using the colonic epithelial cell line LS174T. Induction of psychological stress in DSS-treated wild-type mice significantly exacerbated colitis with enhanced expression of proinflammatory cytokines and IL-18. However, induction of psychological stress in DSS-treated IL-18(-/-) mice did not aggravate colitis compared with that in the IL-18(-/-) group given only DSS treatment. Stress-induced aggravation of colitis was ameliorated significantly by anti-IL-18 antibody treatment. IL-18 did not enhance TNF-α-induced expression of intercellular adhesion molecule-1 or IL-8 in LS174T. We established a model of colitis exacerbated by psychological stress. Psychological stress enhanced IL-18 expression and plays a proinflammatory role in stress-induced aggravation of colitis.     

Cellular expression and localization of DGKζ-interacting NAP1-like proteins in the brain and functional implications under hypoxic stress

Diacylglycerol kinase (DGK) catalyzes conversion of a lipid second messenger diacylglycerol to another messenger molecule phosphatidic acid. Consequently, DGK plays a pivotal role in cellular pathophysiology by regulating the levels of these two messengers. We reported previously that DGKζ translocates from the nucleus to cytoplasm in hippocampal neurons under ischemic/hypoxic stress. In addition, we also identified nucleosome assembly protein 1 (NAP1)-like proteins NAP1L1 and NAP1L4 as novel DGKζ-interacting partners using a proteomic approach and revealed that these NAP1-like proteins induce cytoplasmic translocation of DGKζ in overexpressed cells because NAP1-like proteins associate with the nuclear localization signal of DGKζ and block its nuclear import via importin α. In the present study, we examined whether NAP1-like proteins are expressed in the brain and whether the molecular interaction of DGKζ and NAP1-like proteins would be changed in the brain after hypoxic stress. Immunohistochemistry revealed that NAP1L1 and NAP1L4 are widely expressed in neurons and glial cells in the brain with some differences. After 3 days of transient whole-body hypoxic stress, DGKζ translocated from the nucleus to cytoplasm in hippocampal pyramidal neurons, whereas NAP1-like proteins remained in the cytoplasm. Contrary to our expectations, NAP1-like proteins showed no change in their expression levels. The molecular interaction between DGKζ and NAP1-like proteins was attenuated after hypoxic stress. These results suggest that DGKζ cytoplasmic translocation in neurons under hypoxic stress is regulated by some mechanism which differs from that mediated by NAP1-like proteins.     

Germ cell mutations of the ascidian Ciona intestinalis with TALE nucleases

Summary: Targeted mutagenesis of genes‐of‐interest, or gene‐knockout, is a powerful method to address the functions of genes. Engineered nucleases have enabled this approach in various organisms because of their ease of use. The ascidian Ciona intestinalis is an excellent organism to analyze gene functions by means of genetic technologies. In our previous study, we reported mutagenesis of Ciona somatic cells with TALE nucleases (TALENs) by electroporating expression constructs. In this study, we report germ cell mutagenesis of Ciona by microinjecting mRNAs encoding TALENs. TALEN mRNAs introduced mutations to target genes in both somatic and germ cells. TALEN‐mediated mutations in the germ cell genome were inherited by the next generation. We conclude that knockout lines of Ciona that have disrupted target genes can be established through TALEN‐mediated germ cell mutagenesis. genesis 52:431–439, 2014. © 2014 Wiley Periodicals, Inc.     

The gene sequence and some properties of protein H. A novel IgG-binding protein

The gene for protein H, a novel bacterial cell wall protein with specific affinity for human IgG Fc, was cloned from a group A Streptococcus and expressed in Escherichia coli. Recombinant E. coli cells produced two forms of a human IgG Fc-binding protein, one with an apparent Mr of 42 kDa in a periplasmic fraction and the other with an apparent Mr of 45 kDa in a mixed fraction of cytoplasms and membranes. Both 42-kDa and 45-kDa protein preparations similarly bound to human IgG1 to IgG4, human IgG Fc, and rabbit IgG, but not to IgG of mouse, rat, bovine, sheep, goat, and human IgA, IgD, IgE, and IgM. The complete nucleotide sequence of the cloned 1.8-kb DNA fragment was determined. An open reading frame encoded a hypothetical protein of 376 amino acid residues (Mr = 42,498). The N-terminal amino acid sequence, consisting of 41 residues, which was removed post-translationally had typical characteristics of Gram-positive bacterial signal peptides. Thus, the mature form of protein H was suggested to consist of 335 residues (Mr = 38,162). There were 3 repeated sequences consisting of 42 residues that were highly homologous to those of protein Arp, an IgA-binding streptococcal cell wall protein, and streptococcal M6 and M24 proteins. The C-terminal amino acid sequence consisting of 93 residues, directly following the repeated sequences, was also highly homologous to that of M6 and M24 proteins. No sequence homology was found between protein H and protein A or protein G, two other IgG-binding bacterial cell wall proteins.     

Specific inhibition by prostaglandin D2 and its metabolites of lysozyme synthesis in mouse macrophage-like cell line, Mm-1

The cultured mouse macrophage-like cell line Mm-1 synthesizes and secretes lysozyme continuously like normal macrophages. Culture of the cells in the presence of prostaglandin D2 for 3 days strongly inhibited their production of lysozyme activity. Prostaglandin D2 caused dose-dependent inhibition of the activity: 1 X 10(-6) M prostaglandin D2 caused about 50% inhibition. Inhibition by prostaglandin D2 was not related to cytotoxicity and was reversible. The rate of synthesis of lysozyme protein was measured by culturing Mm-1 cells with radioactive amino acids and then immunoprecipitating the protein. At the concentrations used, prostaglandin D2 inhibited the synthesis of lysozyme dose-dependently, but did not suppress the synthesis of total protein. Of the various types of prostaglandin, only prostaglandin D2 inhibited the production of lysozyme in Mm-1 cells. Moreover, prostaglandin D2 did not inhibit the production of other lysosomal enzymes, such as acid proteinase, acid phosphatase and beta-glucuronidase, and did not affect Fc receptors on the cell surface, adherence of cells to the culture dish or the cell morphology. These results indicate that prostaglandin D2 specifically inhibits the synthesis of lysozyme in Mm-1 cells. When Mm-1 cells were cultured for 3 days in the presence of the ethyl acetate extract from the culture medium in which Mm-1 cells had been cultured with prostaglandin D2 for 3 days, the production of lysozyme activity of Mm-1 cells was also markedly inhibited by the extract. After the incubation of prostaglandin D2 for 3 days with Mm-1 cells, less than 10% of the initial prostaglandin D2 remained and two major metabolites appeared. These results suggest that the metabolites of prostaglandin D2 were involved in the inhibitory action of prostaglandin D2 in Mm-1 cells.     

Class II antigen-specific murine cytolytic T lymphocytes (CTL). II. Genuine class II specificity of Lyt-2+ CTL clones

Class II-specific allogeneic cytolytic T lymphocytes (CTL) consist of two types of cells, i.e., Lyt-2+L3T4- and Lyt-2-L3T4 T cells. The Lyt-2+L3T4- class II-specific CTL population constitutes a conspicuous exception to the general correlation observed between the class of major histocompatibility complex antigen recognized and the type of accessory molecules expressed by T cells. In order to examine the specificity of such an exceptional T cell population, CTL clones were established by limiting dilution of a bulk CTL line developed in an I region incompatible combination of mouse strains, B10.QBR anti-B10.MBR. These CTL lines showed single genetic specificity indicating their clonal nature with respect to CTL activities. Lyt-2+L3T4- (2+4-), Lyt-2-L3T4+ (2-4+) and Lyt-2-L3T4- (2-4-) clones were obtained. Among many CTL clones showing a spectrum of genetic specificities, 2+4- and 2-4+ clones with apparent I-Ak-specificity, were studied further and four lines of evidence confirmed their class II specificity: 1) genes encoding the target antigen for these CTL clones were mapped within the I-A subregion by simple genetics; 2) an I-Ak-specific monoclonal antibody readily blocked specific cytolysis by these clones; 3) the clones failed to react with cells expressing mutated I-Ak antigens; and 4) a B cell tumor transfected with alpha- and beta-chain genes of I-Ak was specifically lysed by these CTL clones. These data therefore establish the existence of Lyt-2+ CTL with genuine class II specificity. All 2-4+ CTL were sensitive to the blocking effect of an antibody to L3T4, whereas none of the 2+4- class II-specific CTL were sensitive to blocking by an anti-Lyt-2 antibody, indicating that class II-specific CTL with "wrong phenotype" is not dependent on the function of the accessory molecule. Besides true class II-specific CTL clones, 2+4- clones with a spectrum of genetic specificities were obtained, including clones recognizing a combination of an I-Ak product and the Kb molecule. Two 2-4- clones were also specific for the combination of Kb + I-Ak. These clones most likely recognize an allogeneic class II antigen in the context of a class I antigen and therefore would more appropriately be included in the class I-restricted T cell population.