The identification of an osteoclastogenesis inhibitor through the inhibition of glyoxalase I

Osteoclasts, bone-resorptive multinucleated cells derived from hematopoietic stem cells, are associated with many bone-related diseases, such as osteoporosis. Osteoclast-targeting small-molecule inhibitors are valuable tools for studying osteoclast biology and for developing antiresorptive agents. Here, we have discovered that methyl-gerfelin (M-GFN), the methyl ester of the natural product gerfelin, suppresses osteoclastogenesis. By using M-GFN-immobilized beads, glyoxalase I (GLO1) was identified as an M-GFN-binding protein. GLO1 knockdown and treatment with an established GLO1 inhibitor in osteoclast progenitor cells interfered with osteoclast generation, suggesting that GLO1 activity is required for osteoclastogenesis. In cells, GLO1 plays a critical role in the detoxification of 2-oxoaldehydes, such as methylglyoxal. M-GFN inhibited the enzymatic activity of GLO1 in vitro and in situ. Furthermore, the cocrystal structure of the GLO1/M-GFN complex revealed the binding mode of M-GFN at the active site of GLO1. These results suggest that M-GFN targets GLO1, resulting in the inhibition of osteoclastogenesis.     

Transmembrane tumor necrosis factor is a potent inducer of colitis even in the absence of its secreted form

BACKGROUND & AIMS: Tumor necrosis factor (TNF) is cleaved proteolytically from a 26-kilodalton transmembrane precursor protein into secreted 17-kilodalton monomers. Transmembrane (tm) and secreted trimeric TNF are biologically active and may mediate distinct activities. We assessed the consequences of a complete inhibition of TNF processing on the course of colitis in recombination activating gene (RAG)2 -/- mice on transfer of CD4 CD45RB hi T cells. METHODS: TNF -/- mice, transgenic for a noncleavable mutant TNF gene, were used as donors of CD4 T cells, and, on a RAG2 -/- background, also as recipients. Kinetics of disease development were compared in the absence of TNF, in the absence of secreted TNF, and in the presence of secreted and tmTNF. The analysis at the end of the observation period included the histopathologic assessment of the intestine and the localization of TNF and interferon gamma (IFNgamma)-expressing cells. RESULTS: The complete prevention of TNF secretion in tmTNF transgenic RAG2 -/- mice neither prevented nor delayed disease induction by transferred transgenic for a noncleavable transmembrane mutant of mouse TNF (tmTNF tg) CD4 CD45RB hi T cells. tmTNF expression by transferred CD4 T cells, however, was not required for disease induction because severe colitis and weight loss also were observed in tmTNF RAG2 -/- recipients of TNF -/- CD4 CD45RB hi T cells. In the presence of tmTNF, the absence of secreted TNF did not affect frequency and distribution of TNF and interferon-gamma messenger RNA (mRNA)-expressing cells. CONCLUSIONS: These results indicate that specific inhibitors of TNF processing are not appropriate for modulating the pro-inflammatory and disease-inducing effects of TNF in chronic inflammatory disorders of the intestine.     

Tau mutants bind tubulin heterodimers with enhanced affinity

Tau is a microtubule binding protein that forms pathological aggregates in the brain in Alzheimer’s disease and other tauopathies. Disease etiology is thought to arise from loss of native interactions between tau and microtubules, as well as from gain of toxicity tied to tau aggregation, although neither mechanism is well understood. Here we investigate the link between function and disease using disease-associated and disease-motivated mutants of tau. We find that mutations to highly conserved proline residues in repeats 2 and 3 of the microtubule binding domain have differential effects on tau binding to tubulin and the capacity of tau to enhance tubulin polymerization. Notably, mutations to these residues result in an increased affinity for tubulin dimers while having a negligible effect on binding to stabilized microtubules. We measure conformational changes in tau on binding to tubulin that provide a structural framework for the observed altered affinity and function. Additionally, we find that these mutations do not necessarily enhance aggregation, which could have important implications for tau therapeutic strategies that focus solely on searching for tau aggregation inhibitors. We propose a model that describes tau binding to tubulin dimers and a mechanism by which disease-relevant alterations to tau impact its function. Together, these results draw attention to the interaction between tau and free tubulin as playing an important role in mechanisms of tau pathology.Tau is a microtubule (MT)-associated protein that plays a critical role in the pathology of several neurodegenerative disorders including Alzheimer’s disease, frontotemporal dementias, and traumatic brain injury (1). Normally, tau is found primarily in the axons of neurons where it regulates the dynamic instability of MTs (2, 3) and plays an important role in axonal transport (4, 5). Both in vitro and in vivo measurements find that tau increases the rate of MT polymerization, as well as decreasing rates of catastrophe (2, 6, 7). In disease, tau is found as aggregated, filamentous deposits that are the defining feature of a diverse class of neurodegenerative diseases, called tauopathies (1, 8). Pathological mutations to tau are thought to alter the native interactions of tau with MTs, in addition to increasing the propensity of tau to aggregate (9–11). Although the precise cause or mechanism by which tau contributes to toxicity in disease is unknown, both a loss of native function and a gain of toxic function are implicated (1, 12, 13).Tau consists of a C-terminal microtubule binding domain (MTBR) composed of imperfect repeats (R1–R4; Fig. 1A) (14), a flanking proline-rich region that enhances MT binding and assembly (3), and an N-terminal projection domain with putative roles in MT spacing (15) and membrane anchoring (16). Alternative splicing results in the expression of six isoforms of tau in the adult human brain, with zero, one, or two N-terminal inserts and three or four MT binding repeat units. The repeat units contain an 18-residue imperfect repeat sequence, which terminates with a highly conserved proline-glycine-glycine-glycine (PGGG), and are linked by a 13–14 residue interrepeat sequence (Fig. 1C). Early biochemical studies depicted the conserved regions as binding weakly to MTs, with the interrepeats acting as spacers between them (14, 17). More recently, it was shown that the interrepeats are also directly involved in binding and polymerization (18, 19), with the N-terminal proline-rich region playing a regulatory role (20). Tau binds MTs with a biphasic pattern indicative of two distinct binding sites on the MT lattice with unequal affinities (21, 22). Binding to MTs is negatively regulated by phosphorylation on sites in the MTBR and adjacent regions (23). Tau derived from aggregates in the brain is hyperphosphorylated (24), suggesting a role for aberrant phosphorylation in disease.Open in a separate windowFig. 1.Schematic of tau constructs and an MTBR repeat. The functional domains of tau are indicated on the longest full-length isoform with alternatively spliced regions marked by dashed lines (A). The interrepeat regions that link the conserved repeat sequences are indicated by cross-hatching. On the fragments used in this study (B), K16 (residues 198–372) and K18 (residues 244–372), the residues mutated to cysteine for attachment of fluorophores (residues 244, 322, and 354), and proline to leucine/serine mutation sites (301 and 332) are indicated. A schematic of a repeat within the MTBR (C) illustrates interrepeat and repeats sequences, with the conserved residues shown.Attempts to obtain resolution structural information of tau have been hindered by the fact that it is intrinsically disordered under physiological conditions (25) and remains largely disordered even on binding to MTs. Contrasting models derived from cryo-EM suggest tau binds either along the outer protofilament ridge (26) or to the inner surface (27) of MTs. The MTBR carries a net positive charge, and binding of tau to the acidic carboxy termini of α and β tubulin has been observed both in the context of MTs (28) and for the isolated peptides corresponding to these tubulin sequences (29, 30). In addition, a secondary binding site has been mapped to an independent region within the C-terminal third of tubulin (30). Cleavage of the C-terminal tail of tubulin is sufficient to increase polymerization rates (30), and it has been suggested that tau may promote MT polymerization through a similar charge neutralization mechanism.The MTBR also plays a central role in tau pathology in that it forms the core of the aggregates found in disease (31) and contains the minimum sequence necessary to recapitulate relevant features of aggregation in vitro (32). Moreover, the majority of mutations to tau implicated in tauopathies are either point mutations within the MTBR or mutations that interfere with alternative splicing, altering the normal ∼1:1 ratio of 3R:4R tau (8, 9). Notable among the point mutants is P301L (tau_P301L) (Fig. 1B), implicated in frontotemporal dementia with Parkinsonism-17, which provided one of the first genetic links between tau and neurodegenerative disease (33). The P301L variant has emerged as a particularly reliable model for tau-based neurodegenerative disease, having successfully reproduced aspects of pathology in animal models of Alzheimer’s disease and other tauopathies (34).Although significant work has focused on tau interactions with MTs, very little is known about the mechanistic details of tau-mediated MT polymerization, including interactions of tau with tubulin dimers during the assembly process. Although many alterations to tau implicated in disease have been shown to affect MT polymerization both in vitro and in vivo, virtually nothing is known about the mechanism by which these changes occur. Tau_P301L exhibits impaired tubulin polymerization (35), as well as increased aggregation propensity relative to WT protein (tau_WT) (32) and thus serves as a model for both loss of function and gain of toxic function aspects of disease. This mutation is in the highly conserved PGGG sequence of R2 (Fig. 1C). To broaden our understanding of the impact of this point mutation on pathology, we designed a tau variant with the analogous proline to leucine substitution in the PGGG sequence of R3, tau_P332L, as well as a double mutant, tau_P301L/P332L. We use single molecule fluorescence to investigate structural and functional aspects of the interaction between tau and tubulin. In combination with ensemble polymerization and aggregation assays, this work provides insight into the relationship between functional and dysfunctional roles of tau.     

Atherogenic mononuclear cell recruitment is facilitated by oxidized lipoprotein-induced endothelial junctional adhesion molecule-A redistribution

Background

Junctional adhesion molecule (JAM-) A is a transmembrane protein expressed in many cell types and maintains junctional integrity in endothelial cells. Upon inflammatory stimulation, JAM-A relocates to the apical surface and might thereby facilitate the recruitment of leukocytes.

Objective

Although inflammatory JAM-A redistribution is an established process, further effort is required to understand its exact role in the transmigration of mononuclear cells, particularly under atherogenic conditions.

Methods

By the use of RNA interference and genetic deletion, the role of JAM-A in the transmigration of T cells and monocytes through aortic endothelial cells was investigated. JAM-A–localization and subsequent mononuclear cell rolling, adhesion and transmigration were explored during endothelial inflammation, induced by oxidized LDL or cytokines.

Results

RNA interference or genetic deletion of JAM-A in aortic endothelial cells resulted in a decreased transmigration of mononuclear cells. Treatment of the endothelial cells with oxLDL resulted in an increase of both permeability and apical JAM-A presentation, as shown by bead adhesion and confocal microscopy experiments. Redistribution of JAM-A resulted in an increased leukocyte adhesion and transmigration, which could be inhibited with antibodies against JAM-A or by lovastatin-treatment, but not with the peroxisome proliferator activated receptor gamma-agonist pioglitazone.

Conclusions

This study demonstrates that redistribution of JAM-A in endothelial cells after stimulation with pro-atherogenic oxidized lipoproteins results in increased transmigration of mononuclear cells. This inflammatory dispersal of JAM-A could be counteracted with statins, revealing a novel aspect of their mechanism of action.     

Chicken SLAMF4 (CD244, 2B4), a receptor expressed on thrombocytes,monocytes, NK cells,and subsets of αβ-, γδ- T cells and B cells binds to SLAMF2

The SLAM family of membrane receptors is involved in the regulation of immune responses by controlling cytokines production, cytotoxicity as well as cell development, differentiation and proliferation, but has only been described in chickens, recently. The aim of this study was to characterize the avian homologue to mammalian SLAMF4 (CD244, 2B4), a cell surface molecule which belongs to the SLAM family of membrane receptors. We generated a SLAMF4 specific monoclonal antibody (mab) designated 8C7 and analyzed the SLAMF4 expression on cells isolated from various lymphoid organs. Subsets of αβ and γδ T cells found in peripheral blood lymphocytes (PBL) and spleen coexpressed SLAMF4. The expression was restricted to CD8α⁺ T cells, whereas CD4⁺ T cells and all thymocytes showed little or no reactivity upon staining with the 8C7 mab. Blood and splenic γδ T cells could be further differentiated according to their expression levels of SLAMF4 into two and three subsets, respectively. SLAMF4 was absent from bursal and splenic B cells, however, it was expressed by a distinct fraction of circulating B cells that were characterized by high level expression of Bu1, Ig, and CD40. SLAMF4 was also present on NK cells isolated from intestine of adult chickens or embryonic splenocytes identified by their coexpression of the 28-4 NK cell marker. Moreover, SLAMF4 expression was found on thrombocytes and monocytes. The interaction of SLAMF4 with SLAMF2 was proven by a reporter assay and could be blocked with the 8C7 mab. In conclusion, the avian SLAMF4 expression markedly differs from mammals; it binds to SLAMF2 and will be an important tool to discriminate several γδ T cell subsets.     

Hemophagocytic lymphohistiocytosis and primary immune deficiency disorders

Hemophagocytic lymphohistiocytosis (HLH) is characterized by uncontrolled immune activation and is traditionally associated with inherited gene defects or acquired causes. In addition to abnormalities in cytotoxic granules and lysosomes, various primary immune deficiency disorders (PID) have been identified among patients suffering from HLH. Our purpose was twofold: to better characterize and detail the association between PID and HLH.     

Bone marrow micrometastases in a patient with localized Wilms' tumor

The case of a 7-year-old boy presenting at diagnosis with a localized (stage III) Wilms' tumor of favorable histology is presented. Immunocytologic analysis of bone marrow aspirates revealed cells positive for neural cell adhesion molecule (NCAM) and negative for class I major histocompatibility complex (MHC) antigens. These cells were interpreted as deriving from the tumor blastemal component. Postoperatively the child underwent radiotherapy and chemotherapy, and he remains free of disease 12 months after completion of therapy. In patients with non-metastatic Wilms' tumor at onset, the evaluation of the actual frequency of occult marrow involvement and the assessment of its clinical significance may necessitate further investigation. © 1996 Wiley-Liss, Inc.     

ADHESION MOLECULES IN HUMAN CRESCENTIC GLOMERULONEPHRITIS

The expression of the intercellular adhesion molecule-1 (ICAM-1) and its ligand lymphocyte function associated antigen-1 (LFA-1 or αL), the vascular cell adhesion molecule-1 (VCAM-1), endothelial leukocyte adhesion molecule-1 (ELAM-1), and the cellular receptors for extracellular matrix, α 1, α 2, α 3, α 5, α 6, α V, β 1, and β3 integrin subunits, was studied in 28 patients with crescentic glomerulonephritis (GN) related to several mechanisms: four patients with anti-glomerular basement membrane antibodies or anti-GBM disease; 16 with immune complex mediated GN; and eight with pauci-immune GN, associated with vasculitis in four cases. A three-step immunoperoxidase technique was used on sections obtained from frozen renal biopsies. At the initial stage of evolution of the lesions, all the cells of the crescents expressed the β 1, β 3, α 1, α 3, and α V subunits of integrins, ICAM-1, and VCAM-1, and some cells expressed the α 2, α 5, α 6, and αL subunits of integrins along the plasma membrane. At a later stage, when the crescents were fibrocellular, α 3 and α1 subunit expression was polarized, localized mainly in front of the extracellular matrix. In fibrotic crescents, the α 2, α 5, α 6, and αL chains were no longer detected, and VCAM-1 and ICAM-1 expression was decreased. VCAM-1 and ELAM-1 appeared on endothelial cells of peritubular capillaries in relation to the appearance of infiltrating inflammatory cells. The results of this study show that several adhesion molecules were expressed on cells forming crescents and were modified during crescent evolution; that these molecules were up-regulated on endothelial cells in relation to the severity of the inflammatory response; and that whatever the mechanism of the glomerulonephritis, adhesion molecule expression was identical. It can be postulated that adhesion molecules play a role in crescentic glomerulonephritis. Better knowledge of these molecules in human glomerulonephritis may open the way to a new therapeutic approach.