Tissue-specific expression of onco-fetal antigens during embryogenesis.

It has become evident from recent literature that especially in tumor virus systems, cell transformation leads to an arrest of differentiation or to a retrodifferentiation. This may be reflected by the expression of embryonic antigens and it is therefore particularly important to characterize such antigens according to their specificity as well as to their specificity during embryogenesis. We have demonstrated the expression of embryonic antigens which are cross-reactive in avian fibroblasts transformed either by Rous sarcoma virus or by methylcholanthrene. This paper is intended to demonstrate that these embryonic antigens are detected only at a certain period of embryogenesis and particularly in muscle cells. They are detected only occasionally or not at all in cells of other tissues such as brain, liver, lung, and the digestive organs. These antigens are absent from the target cells before transformation and are consequently induced by the transforming agent, either viral or chemical. Therefore, these results suggest that by transformation mechanism, cells become specifically reverted to an earlier stage of differentiation (retrodifferentiation).     

Chemical sensing by a novel electrical oscillator: detection and quantitation of polysaccharides in concanavalin A solutions

Electrical oscillations across two platinum electrodes connected to an external circuit and immersed in HEPES buffer solutions of concanavalin A (Con A) were measured at various concentrations of mannan, starch and dextran. The frequency of oscillations was found to change almost linearly with the logarithm of the concentration of mannan between 10(-4) and 1 w/v%; whereas the frequency remained nearly constant with dextran. With starch it slightly increased as the concentration increased. This method was suggested to be useful for quantitative and selective measurement of antigen-antibody reaction and also for detection of various cells with the specific binding site such as cancer cells.     

Conjugal acquisition and stable maintenance of Ent plasmids in nontoxigenic wild-type strains of Escherichia coli

In spite of the ability of the genetic determinants for enterotoxin production to be conjugally transferred, mobilized or transposed, enterotoxigenic Escherichia coli (ETEC) isolated from diarrheal patients is restricted to certain serotypes. Four conjugative enterotoxigenic plasmids (Ent plasmids) encoding either a heat-labile enterotoxin or a heat-stable enterotoxin or both and belonging to one of three incompatibility groups IncFI, IncHl, or IncX, were examined for their transferability to and stability in 157 nonenterotoxigenic Escherichia coli strains belonging to various serotypes and 89 clinical isolates nonenterotoxigenic but belonging to those serotypes in which ETEC from diarrheal patients are usually found. The serotypes of the strains to which Ent plasmids were efficiently transferred and in which they were maintained stably were not always the serotypes in which ETEC had usually been found and vice versa. The frequencies of transfer of four Ent and two R plasmids to each of the 157 recipients were correlated with each other, indicating that the frequency of transfer of the plasmid is not determined by a resident plasmid, if there is one, but by a recipient factor which commonly affects transferability to all donors. These results have led to the conclusion that the reason why only certain serotypes are found among ETEC isolated from diarrheal patients is not the ability of these strains specifically and preferentially to acquire and maintain the Ent plasmids.     

Fenofibrate reduces cisplatin-induced apoptosis by inhibiting the p53/Puma/Caspase-9 pathway and the MAPK/Caspase-8 pathway rather than by promoting autophagy in murine renal proximal tubular cells

The main lesion of cisplatin nephrotoxicity is damage to proximal tubular cells due to increased apoptosis via the mitochondrial and death receptor pathways, which may be alleviated by appropriate promotion of autophagy. Fenofibrate, a peroxisome proliferator-activated receptor-alpha (PPAR-α) activator, is recently reported to promote autophagy as well as protect against cisplatin nephrotoxicity, although the mechanisms were only partially analyzed. Here, the detailed mechanisms of these putative protective effects were investigated in a murine renal proximal tubular (mProx) cell line. Fenofibrate attenuated cisplatin-induced apoptosis of mProx cells based on flow cytometry. As for the mitochondrial apoptotic pathway, the reagent reduced cisplatin-stimulated caspase-3 activation by decreasing the phosphorylation of p53, JNK, and 14-3-3, cytosolic and mitochondrial Puma accumulation, cytochrome C release to the cytosol, and resulting cytosolic caspase-9 activation. Fenofibrate also decreased cisplatin-stimulated activation of caspases-8 by suppressing MAPK and NFkB pathways and reducing the gene expression of TNF-α, TL1A, and Fas, main mediators of the death receptor apoptotic pathway. Autophagy defined by p62 reduction and an increase in LC3 II/I was promoted by fenofibrate in mProx cells under starvation. Autophagy inhibition using 3-MA further increased basal and cisplatin-induced caspase-3 and -8 activation, but had no influence on the inhibitory effects of fenofibrate on caspase activation. In conclusion, our study suggests fenofibrate to be a candidate agent to mitigate cisplatin nephrotoxicity by inhibiting the mitochondrial and death apoptotic pathways rather than by promoting autophagy.     

Development of novel lithocholic acid derivatives as vitamin D receptor agonists

Lithocholic acid (2) was identified as the second endogenous ligand of vitamin D receptor (VDR), though its binding affinity to VDR and its vitamin D activity are very weak compared to those of the active metabolite of vitamin D₃, 1α,25-dihydroxyvitamin D₃ (1). 3-Acylated lithocholic acids were reported to be slightly more potent than lithocholic acid (2) as VDR agonists. Here, aiming to develop more potent lithocholic acid derivatives, we synthesized several derivatives bearing a 3-sulfonate/carbonate or 3-amino/amide substituent, and examined their differentiation-inducing activity toward human promyelocytic leukemia HL-60 cells. Introduction of a nitrogen atom at the 3-position of lithocholic acid (2) decreased the activity, but compound 6 bearing a 3-methylsulfonate group showed more potent activity than lithocholic acid (2) or its acylated derivatives. The binding of 6 to VDR was confirmed by competitive binding assay and X-ray crystallographic analysis of the complex of VDR ligand-binding domain (LBD) with 6.     

Synthesis and evaluation of in vivo anti‐hypothermic effect of all stereoisomers of the thyrotropin‐releasing hormone mimetic: Rovatirelin Hydrate

We discovered the orally active thyrotropin‐releasing hormone (TRH) mimetic: (4S,5S)‐5‐methyl‐N‐{(2S)‐1‐[(2R)‐2‐methylpyrrolidin‐1‐yl]‐1‐oxo‐3‐(1,3‐thiazol‐4‐yl)propan‐2‐yl}‐2‐oxo‐1,3‐oxazolidine‐4‐carboxamide 1 (rovatirelin). The central nervous system (CNS) effect of rovatirelin after intravenous (iv) administration is 100‐fold higher than that of TRH. As 1 has four asymmetric carbons in its molecule, there are 16 stereoisomers. We synthesized and evaluated the anti‐hypothermic effect of all stereoisomers of 1 , which has the (4S),(5S),(2S),(2R) configuration from the N‐terminus to the C‐terminus, in order to clarify the structure?activity relationship (SAR) of stereoisomers. The (4R),(5R),(2R),(2S)‐isomer 16 did not show any anti‐hypothermic effect. Only the (4S),(5S),(2S),(2S)‐isomer 10 , which has the (2S)‐2‐methylpyrrolidine moiety at the C‐terminus showed the anti‐hypothermic effect similar to 1 . Stereoisomers, which have the (5R) configuration of the oxazolidinone at the N‐terminus and the (2R) configuration at the middle‐part, showed a much lower anti‐hypothermic effect than that of 1 . On the other hand, stereoisomers, which have the (4R) configuration of the oxazolidinone at the N‐terminus or the (2S) configuration of the C‐terminus, have little influence on the anti‐hypothermic effect.     

A mass conserved reaction-diffusion system captures properties of cell polarity

Cell polarity is a general cellular process that can be seen in various cell types such as migrating neutrophils and Dictyostelium cells. The Rho small GTP(guanosine 5'-tri phosphate)ases have been shown to regulate cell polarity; however, its mechanism of emergence has yet to be clarified. We first developed a reaction-diffusion model of the Rho GTPases, which exhibits switch-like reversible response to a gradient of extracellular signals, exclusive accumulation of Cdc42 and Rac, or RhoA at the maximal or minimal intensity of the signal, respectively, and tracking of changes of a signal gradient by the polarized peak. The previous cell polarity models proposed by Subramanian and Narang show similar behaviors to our Rho GTPase model, despite the difference in molecular networks. This led us to compare these models, and we found that these models commonly share instability and a mass conservation of components. Based on these common properties, we developed conceptual models of a mass conserved reaction-diffusion system with diffusion-driven instability. These conceptual models retained similar behaviors of cell polarity in the Rho GTPase model. Using these models, we numerically and analytically found that multiple polarized peaks are unstable, resulting in a single stable peak (uniqueness of axis), and that sensitivity toward changes of a signal gradient is specifically restricted at the polarized peak (localized sensitivity). Although molecular networks may differ from one cell type to another, the behaviors of cell polarity in migrating cells seem similar, suggesting that there should be a fundamental principle. Thus, we propose that a mass conserved reaction-diffusion system with diffusion-driven instability is one of such principles of cell polarity.     

A Mass Conserved Reaction–Diffusion System Captures Properties of Cell Polarity

Cell polarity is a general cellular process that can be seen in various cell types such as migrating neutrophils and Dictyostelium cells. The Rho small GTP(guanosine 5′-tri phosphate)ases have been shown to regulate cell polarity; however, its mechanism of emergence has yet to be clarified. We first developed a reaction–diffusion model of the Rho GTPases, which exhibits switch-like reversible response to a gradient of extracellular signals, exclusive accumulation of Cdc42 and Rac, or RhoA at the maximal or minimal intensity of the signal, respectively, and tracking of changes of a signal gradient by the polarized peak. The previous cell polarity models proposed by Subramanian and Narang show similar behaviors to our Rho GTPase model, despite the difference in molecular networks. This led us to compare these models, and we found that these models commonly share instability and a mass conservation of components. Based on these common properties, we developed conceptual models of a mass conserved reaction–diffusion system with diffusion–driven instability. These conceptual models retained similar behaviors of cell polarity in the Rho GTPase model. Using these models, we numerically and analytically found that multiple polarized peaks are unstable, resulting in a single stable peak (uniqueness of axis), and that sensitivity toward changes of a signal gradient is specifically restricted at the polarized peak (localized sensitivity). Although molecular networks may differ from one cell type to another, the behaviors of cell polarity in migrating cells seem similar, suggesting that there should be a fundamental principle. Thus, we propose that a mass conserved reaction–diffusion system with diffusion-driven instability is one of such principles of cell polarity.