Metabolism of galactosylceramide in the twitcher mouse, an animal model of human globoid cell leukodystrophy

The metabolism of galactosylceramide was investigated in normal and twitcher mice, an animal model for human globoid cell leukodystrophy. The findings were compared with data obtained on human tissues. In vitro studies demonstrated that there were two genetically distinct enzymes that hydrolyze galactosylceramide: galactosylceramidase I and II. The former was deficient in the twitcher, while the latter was intact. beta-Galactosidase preparations purified from normal mouse liver possessed the activity to hydrolyze galactosylceramide when the assay conditions for galactosylceramidase II was used. Therefore, galactosylceramidase II was considered to be identical to GM1 ganglioside beta-galactosidase. In contrast to the human enzyme, the murine beta-galactosidase had a relatively high Km value toward galactosylceramide. The galactosylceramide-loading test demonstrated that the twitcher fibroblasts hydrolyzed the lipid at lower rates than seen in cases of human globoid cell leukodystrophy fibroblasts. These differences in galactosylceramidase II between murine and human tissues suggest that galactosylceramide accumulates in twitcher mice but not in humans with globoid cell leukodystrophy, even though galactosylceramidase I is genetically deficient in both human and this mouse model.     

Metabolism of exogenous galactosylceramide in the twitcher mouse brain

The in vivo metabolism of galactosylceramide (gal-cer) in normal mice and in twitcher mice, a model of human GLD, was examined following intracerebral administration of gal-cer containing [1-¹⁴C]stearic acid. In normal mice, gal-cer was hydrolyzed to ceramide within 6 hours and ceramide was hydrolyzed to sphingosine and fatty acid. Most of the released fatty acid was immediately incorporated into other lipids. About 75% of injected gal-cer was hydrolyzed 80 hours after the injection, while in the twitcher mouse, only 17% of gal-cer was hydrolyzed. These results show that degradation of gal-cer is impaired in the twitcher mouse brain, but contradict to the fact that there was no evidence of any accumulation of gal-cer in the brain. This discrepancy may be due to the different sorting routes of biosynthesized and exogenously-administered gal-cer in the mouse brain. Most of the biosynthesized gal-cer is incorporated into myelin, while the injected gal-cer is incorporated into lysosomes.     

Occurrence of creatine kinase activity in human erythrocyte membrane

Some evidences for creatine kinase activity in normal human erythrocyte membrane were presented. The creatine kinase was indicated to be a constituent of the integral proteins of erythrocyte membrane or to be tightly bound to the membrane, and was contrasted to the results obtained with adenylate kinase. Isoenzyme distribution of the erythrocyte creatine kinase by electrophoresis was identical to MM-creatine kinase from rabbit muscle.     

Pifithrin-μ, an Inhibitor of Heat-Shock Protein 70, Can Increase the Antitumor Effects of Hyperthermia Against Human Prostate Cancer Cells

Hyperthermia (HT) improves the efficacy of anti-cancer radiotherapy and chemotherapy. However, HT also inevitably evokes stress responses and increases the expression of heat-shock proteins (HSPs) in cancer cells. Among the HSPs, HSP70 is known as a pro-survival protein. In this study, we investigated the sensitizing effect of pifithrin (PFT)-μ, a small molecule inhibitor of HSP70, when three human prostate cancer cell lines (LNCaP, PC-3, and DU-145) were treated with HT (43°C for 2 h). All cell lines constitutively expressed HSP70, and HT further increased its expression in LNCaP and DU-145. Knockdown of HSP70 with RNA interference decreased the viability and colony-forming ability of cancer cells. PFT-μ decreased the viabilities of all cell lines at one-tenth the dose of Quercetin, a well-known HSP inhibitor. The combination therapy with suboptimal doses of PFT-μ and HT decreased the viability of cancer cells most effectively when PFT-μ was added immediately before HT, and this combination effect was abolished by pre-knockdown of HSP70, suggesting that the effect was mediated via HSP70 inhibition. The combination therapy induced cell death, partially caspase-dependent, and decreased proliferating cancer cells, with decreased expression of c-Myc and cyclin D1 and increased expression of p21^WAF1/Cip, indicating arrest of cell growth. Additionally, the combination therapy significantly decreased the colony-forming ability of cancer cells compared to therapy with either alone. Furthermore, in a xenograft mouse model, the combination therapy significantly inhibited PC-3 tumor growth. These findings suggest that PFT-μ can effectively enhance HT-induced antitumor effects via HSP70 inhibition by inducing cell death and arrest of cell growth, and that PFT-μ is a promising agent for use in combination with HT to treat prostate cancer.     

Mammalian PIG-X and yeast Pbn1p are the essential components of glycosylphosphatidylinositol-mannosyltransferase I

Within the endoplasmic reticulum (ER), mannoses and glucoses, donated from dolichol-phosphate-mannose and -glucose, are transferred to N-glycan and GPI-anchor precursors, and serine/threonine residues in many proteins. Glycosyltransferases that mediate these reactions are ER-resident multitransmembrane proteins with common characteristics, forming a superfamily of >10 enzymes. Here, we report an essential component of glycosylphosphatidylinositol-mannosyltransferase I (GPI-MT-I), which transfers the first of the four mannoses in the GPI-anchor precursors. We isolated a Chinese hamster ovary (CHO) cell mutant defective in GPI-MT-I but not its catalytic component PIG-M. The mutant gene, termed phosphatidylinositolglycan-class X (PIG-X), encoded a 252-amino acid ER-resident type I transmembrane protein with a large lumenal domain. PIG-X and PIG-M formed a complex, and PIG-M expression was <10% in the absence of PIG-X, indicating that PIG-X stabilizes PIG-M. We found that Saccharomyces cerevisiae Pbn1p/YCL052Cp, which was previously reported to be involved in autoprocessing of proproteinase B, is the functional homologue of PIG-X; Pbn1p is critical for Gpi14p/YJR013Wp function, the yeast homologue of PIG-M. This is the first report of an essential subcomponent of glycosyltransferases using dolichol-phosphate-monosaccharide.     

Gastric acidity in patients with follicular gastritis is significantly reduced, but can be normalized after eradication for Helicobacter pylori

BACKGROUND: Follicular gastritis is thought to be caused by Helicobacter pylori infection. However, the pathophysiology of it remains unclear. MATERIALS AND METHODS: We assessed gastric acidity in 15 patients with follicular gastritis, aged 20-37 years, using a 24-hour intragastric pH-metry, as well as by histologic and serologic evaluations; and compared it with that in other age-matched groups: 18 cases of H. pylori-positive antrum-predominant gastritis, 12 of pangastritis, and 24 H. pylori-negative normals. In eight cases with follicular gastritis, it was re-assessed 6 months after the eradication therapy for H. pylori. RESULTS: During nighttime, the percentage of time with intragastric pH above 3.0 in follicular gastritis was significantly higher than that in normals (p<.0001), and in antrum-predominant gastritis (p<.001), but was comparable with that in pangastritis. In the daytime period, this parameter in follicular gastritis was significantly higher than that in normal (p<.001), in antrum-predominant gastritis (p<.001), and in pangastritis (p<.05). Marked mononuclear cell and neutrophil infiltration but no apparent glandular atrophy were observed in both the antrum and corpus. Serum pepsinogen I/II ratio was significantly lower in follicular gastritis than that in normals (p<.0001) and in antrum-predominant gastritis (p<.001), whereas serum gastrin was significantly higher than that in normals (p<.0001), in antrum-predominant gastritis (p<.01) and in pangastritis (p<.05). After eradication for H. pylori, all of the parameters in follicular gastritis were altered to the same ranges as those in normals. CONCLUSIONS: In follicular gastritis, gastric acidity is significantly reduced, but can be normalized by eradication of H. pylori. It can thus be speculated that inflammatory cytokines or H. pylori-infection-induced prostaglandins might strongly inhibit gastric acid secretion in follicular gastritis.     

Electrocardiograms Corresponding to the Development of Myocardial Infarction in Anesthetized WHHLMI Rabbits (Oryctolagus cuniculus), an Animal Model for Familial Hypercholesterolemia

The aim of this study was to determine whether features indicative of myocardial ischemia occur in the electrocardiograms (ECG) in myocardial infarction-prone Watanabe heritable hyperlipidemic (WHHLMI) rabbits, an animal model for human familial hypercholesterolemia. ECG were recorded in 110 anesthetized WHHLMI rabbits (age, 10 to 39 mo) by using unipolar and bipolar limb leads with or without chest leads. We noted the following electrocardiographic changes: T wave inversion (37.4%), ST segment depression (31.8%), deep Q wave (16.3%), reduced R wave amplitude (7.3%), ST segment elevation (2.7%), and high T wave (1.8%). These ECG changes resembled those in human patients with coronary heart disease. Histopathologic examination revealed that the left ventricular wall showed acute myocardial lesions, including loss of cross-striations, vacuolar degeneration, coagulation necrosis of cardiac myocytes, and edema between myofibrils, in addition to chronic myocardial lesions such as myocardial fibrosis. The coronary arteries that caused these ECG changes were severely stenosed due to atherosclerotic lesions. Ischemic ECG changes corresponded to the locations of the myocardial lesions. Normal ECG waveforms were similar between WHHLMI rabbits and humans, in contrast to the large differences between rabbits and mice or rats. In conclusion, ischemic ECG changes in WHHLMI rabbits reflect the location of myocardial lesions, making this model useful for studying coronary heart disease.Abbreviations: CHD, coronary heart disease; ECG, electrocardiogram; WHHL, Watanabe heritable hyperlipidemic; WHHLMI, myocardial infarction-prone Watanabe heritable hyperlipidemicCoronary heart disease (CHD) is prevalent in developed countries, including the United States.^16,24 Although potent compounds (for example, statins to inhibit cholesterol synthesis) have been developed to reduce the public health burden of this disease, CHD remains a leading cause of death, and further efforts are needed to reduce associated morbidity and mortality.²⁵ In evaluating the therapeutic effects of CHD interventions, the electrocardiogram (ECG) is an essential tool for examining myocardial function.³⁹In humans, various ischemic ECG changes occur in association with myocardial ischemia and infarction, such as high T wave, ST segment elevation, emergence of the deep Q wave, reduction of R wave amplitude, resolution of ST segment elevation, and T wave inversion.^21,39 In addition, ST segment depression is a typical change observed with subendocardial ischemia.^2,7In the study of myocardial ischemia, animal models that show ECG waveforms comparable to those of human patients with CHD play an important role. This similarity is important not only for assessing the effects of agents for the treatment of CHD but also for assessing adverse effects of newly developed agents on cardiac function. Although ECG have been used to study myocardial ischemia in several species including pigs, dogs, rabbits, rats, and mice,^{3,9,10,14,18,23} most of these studies used coronary ligation models. These models do not fully reflect the events that occur during myocardial ischemia caused by atherosclerotic coronary stenosis, which is seen typically in patients with CHD.The Watanabe heritable hyperlipidemic (WHHL) rabbit⁴⁰ and the myocardial infarction-prone WHHL (WHHLMI) rabbit³³ are animal models for the study of human myocardial ischemia. WHHLMI rabbits spontaneously develop hypercholesterolemia due to a deficiency of receptors for low-density lipoproteins and manifest severe coronary atherosclerosis and myocardial infarction. Importantly, lipoprotein metabolism in WHHL and WHHLMI rabbits resembles that in humans.^28,30 Using these advantages of the WHHL and WHHLMI models, we and others have been studying the effects of hypocholesterolemic and antiatherosclerotic agents on coronary atherosclerosis.^29,32,34 However, ECG were not examined in these studies. Because the rabbit heart is electrophysiologically similar to the human heart,^27,38 using ECG to monitor myocardial function in the WHHLMI rabbit may be valuable.In the present study, we examined whether ECG changes observed in WHHLMI rabbits reflect myocardial ischemia and whether those changes correspond to ECG features in human patients with CHD.     

COX-2 and CCR2 induced by CD40 ligand and MCP-1 are linked to VEGF production in endothelial cells

Recent studies have reported that expression of MCP-1 and its receptor, CCR2; and CD40-CD40 ligand (CD40L) interaction on mesenchymal cells play important roles in tumor development. Studies have also connected MCP-1, CCR2, and CD40L to COX-2 expression. The aim of this study was to examine the effect of MCP-1/CCR2 and CD40-CD40L interaction on COX-2 and VEGF expression in endothelial cells. We also investigated the localization of these proteins in gastric cancer tissue. COX-2 and CCR2 levels were evaluated in CD40L-stimulated HUVECs by Western blot and real-time PCR. VEGF secreted in the culture media was quantified by ELISA. Localizations of MCP-1, CD40L, CD34, CD40 and CCR2 in 34 gastric cancer tissue specimens were evaluated by immunohistochemistry. CD40-CD40L interaction-induced COX-2 production and subsequently, upregulated COX-2 production contributed to elevated VEGF and CCR2 levels in CD40L-stimulated HUVECs. CD40L-stimulated VEGF production was COX-2 but not COX-1 dependent. RS-102895, a CCR2-specific antagonist, significantly reduced VEGF production in CD40L- and MCP-1-stimulated HUVECs. MCP-1 had a synergistic effect on COX-2, CCR2 and VEGF levels in CD40L-stimulated HUVECs. In gastric cancer tissue, there was significant correlation between microvessel density and scores for CD40L, MCP-1 and CCR2 protein expression. Thus, MCP-1 had a synergistic effect on COX-2 and CCR2 protein expression in CD40L-stimulated HUVECs and thereby stimulated VEGF production in these cells.     

Characterization of Wise Protein and Its Molecular Mechanism to Interact with both Wnt and BMP Signals

Cross-talk of BMP and Wnt signaling pathways has been implicated in many aspects of biological events during embryogenesis and in adulthood. A secreted protein Wise and its orthologs (Sostdc1, USAG-1, and Ectodin) have been shown to modulate Wnt signaling and also inhibit BMP signals. Modulation of Wnt signaling activity by Wise is brought about by an interaction with the Wnt co-receptor LRP6, whereas BMP inhibition is by binding to BMP ligands. Here we have investigated the mode of action of Wise on Wnt and BMP signals. It was found that Wise binds LRP6 through one of three loops formed by the cystine knot. The Wise deletion construct lacking the LRP6-interacting loop domain nevertheless binds BMP4 and inhibits BMP signals. Moreover, BMP4 does not interfere with Wise-LRP6 binding, suggesting separate domains for the physical interaction. Functional assays also show that the ability of Wise to block Wnt1 activity through LRP6 is not impeded by BMP4. In contrast, the ability of Wise to inhibit BMP4 is prevented by additional LRP6, implying a preference of Wise in binding LRP6 over BMP4. In addition to the interaction of Wise with BMP4 and LRP6, the molecular characteristics of Wise, such as glycosylation and association with heparan sulfate proteoglycans on the cell surface, are suggested. This study helps to understand the multiple functions of Wise at the molecular level and suggests a possible role for Wise in balancing Wnt and BMP signals.Wise is a secreted protein that was isolated from a functional screen of a chick cDNA library of embryonic tissues. It was identified as being able to alter the antero-posterior character of neuralized Xenopus animal caps by promoting activity of the Wnt pathway (1). Independently, the homologous protein was isolated from a functional screen to detect genes that are preferentially expressed in the rat endometrium, which had been maximally sensitized to implantation, and named USAG-1 (uterine sensitization-associated gene-1) (2). The protein was identified a third time from the GenBank^TM sequence data base of mouse as a putative secreted protein, shown to be a BMP antagonist, and named Ectodin (3). The gene has also been called Sostdc1 (Sclerostin domain-containing 1) or Sostl (Sclerostin-like) due to the homology with Sclerostin-encoding gene Sost (4, 5). USAG-1/Wise/Ectodin/Sostdc1 is expressed in various tissues, such as the surface ectoderm of the posterior axis (1, 6), branchial arches (3, 6), the dermal papilla in hair follicles (7), vibrissae (3), mammalian tooth cusps (3, 8), rat endometrium (2), developing testis (9–11), interdigital tissues (12), and embryonic and adult kidneys (13, 14).Wise appears to have a dual role in modulating the Wnt pathway. Injection of Wnt8 RNA into a ventral vegetal blastomere of Xenopus embryos at the four-cell stage induces a full secondary axis to form, and this is blocked by the addition of Wise RNA as well as other Wnt inhibitors (1). Activation of the Wnt/β-catenin pathway in hair follicles triggers regeneration of hair growth, and expression of Wise appears to have a defined role to inhibit this (15). In this context, Wise expression is repressed by the nuclear receptor co-repressor, Hairless, which results in activation of the Wnt pathway; thus, a model of periodic regeneration of hair follicles has been proposed (15, 16). In addition, Wise and its homologue USAG-1 have been shown to block Wnt1, Wnt3a, and Wnt10b activities in reporter assays (14, 15, 17). Wise was found to bind to the Wnt co-receptor, LRP6, sharing the binding domain with Wnt ligands. Importantly, Wise was found to compete with Wnt8 for binding to LRP6, therefore suggesting a mechanism for inhibition of the Wnt pathway whereby Wise blocks the binding of ligand and receptor (1). Wise may also be retained in the endoplasmic reticulum and inhibit the trafficking of LRP6 to the cell surface (18). Wise also binds LRP4 (19), a member of the LRP family functioning inhibitory to Wnt signals (20). It is noteworthy that Wise was isolated from a screen designed to detect the activation of the Wnt/β-catenin pathway, not inhibition. The exact mechanism of how Wise exerts such a context-dependent modulation on the Wnt pathway is yet to be clarified.Osteoblast differentiation of MC3T3-E1 cells, as measured by alkaline phosphatase activity, can be induced by a wide range of BMP molecules. In this assay, Ectodin, the mouse ortholog of Wise, was shown to inhibit differentiation induced by BMP2, -4, -6, or -7 in a dose-dependent manner (3). Similarly, Ectodin (also known as USAG-1) was also found to inhibit the bone differentiation induced by BMP2, -4, or -7 in C2C12 cells (14). Ectodin also inhibits BMP2- or BMP7-induced Msx2 expression in dissected mouse tooth buds in organ culture (3). In tooth buds, Ectodin expression is detected in the dental ectoderm and mesenchymal cells excluding from the enamel knot (3). Ectodin/USAG-1-deficient mice created by targeted-disruption show altered tooth morphology and extra teeth, indicating that Ectodin and BMP tightly control tooth development and patterning in mammals (8, 21–23). Furthermore, in mouse adult kidneys, the ability of BMP7 to repair established renal injury is blocked by USAG-1 (13). All of these findings indicate that USAG-1/Wise/Ectodin has a clear antagonistic effect on BMP signaling, where it binds BMP2, -4, -6, and -7 (3, 14) and presumably prevents BMP binding to its receptors.Analysis of the sequence of Wise reveals that it has the C₁X_nC₂XGXC₃X_nC₄X_nC₅XC₆ motif of a six-membered cystine knot, where C₁ forms a disulfide bond with C₄, C₂ with C₅, and C₃ with C₆ (for a review of the cystine knot, see Refs. 24–27). This arrangement results in a globular protein with three loops, “finger 1,” “heel,” and “finger 2,” held together with an eight-membered ring of C₂XGXC₃C₆XC₅C₂ (Fig. 1). BMP antagonists represent a subfamily in the cystine knot superfamily, and this is further subdivided into three subfamilies based on the size of the cystine knot. These are the CAN family (eight-membered ring), Twisted Gastrulation (nine-membered ring), and Chordin and Noggin (10-membered ring) (27). There is generally little sequence homology between family members in the heel, finger 1, and finger 2 regions, yet Wise does show a moderate homology with Sclerostin (28). Sclerostin is involved in regulating bone mass (4, 5) and also appears to antagonize both Wnt (29–32) and BMP (28, 33, 34) signals. This paper aims to analyze the dual role of Wise on Wnt and BMP pathways by probing the structural features of the protein and reconciling them to physiological properties. It also aims to reveal the molecular nature of the protein in view of possible glycosylation, secretion, and association with extracellular matrix.Open in a separate windowFIGURE 1.Structure of chick Wise protein. A, stereo ribbon representation of the chick Wise three-dimensional structural model (residues 68–186). Purple, β-strands; green, loop regions. Yellow, disulfide bonds in the cystine knot plus a further disulfide (cysteines 89 and 147) linking two fingers of the structure. N- and C-terminal ends are indicated. B, schematic drawing of the full-length chick Wise structure. Arrowhead, the predicted signal sequence cleavage site for secretion; black dot, asparagine at position 47 (N47), the glycosylated site revealed in this study. Six cysteine residues forming the “cystine knot” are shown in circles, and disulfide bonds for the knot formation are shown by dotted lines. Three loops (Finger 1, Heel, and Finger 2) are indicated. The scheme also shows the deleted parts of Wise constructs ΔN, Δheel, and ΔC.