Determination of Fructose in the Presence of a Large Excess of Glucose

Some factors affecting the skatole-hydrochloric acid reaction for fructose were studied. Especially, the stability of the chromogen to light, the effect of the amount of chloroform for complete extraction of the chromogen from the aqueous phase, and the time course of color development at various temperatures were studied in some detail. The time course of color development in the β-indolylacetic acid-hydrochloric acid reaction for fructose was also investigated. Based on the results obtained from these observations, some modifications to both the skatole-hydrochloric acid and β-indolylacetic acid-hydrochloric acid reactions were proposed.

A modification of the resorcinol-thiourea-hydrochloric acid method of Roe et al.⁷⁾ for the determination of fructose is described. The modification is based on the observation that by lowering the incubation temperature to 70°C, a greater color intensity ratio (fructose color/glucose color) is obtained, thus increasing the specificity of the method for fructose. By applying the principle of the two-point determination of Mokrasch¹²⁾ to the modified procedure, fructose in the presence of 100-fold excess of glucose can be determined with an error of about 10%.

A modified procedure of the cysteine-carbazole reaction for the determination of fructose is described. By incubating the components of the color reaction at 40°C for 1 hr, fructose is determined with good sensitivity (the millimolar absorbance value of 29.3) and specificity (the color intensity ratio of fructose to glucose is about 240). When the principle of the two-point determination is applied to this modified procedure (1 hr and 3 hr at 40°C), fructose as small an amount as 0.4 μg in the presence of 250-fold excess of glucose can be determined with an error of about 10 %.     

Effects of Phosphatase and Phosphoglucomutase on the Determination of Phosphorylase Activities in Crude Extracts from Plant Materials

The extent to which phosphatases interfere with the determination of phosphorylase activity in crude extracts from plant materials by hydrolyzing glucose-1-phosphate was determined. Sodium fluoride was an effective, although not satisfactory, inhibitor of phosphatase. Evidence was presented to show that in crude extract of broad bean seeds glucose-1-phosphate was hydrolyzed most probably via glucose-6-phosphate.     

Broad-Spectrum Detection of H5 Subtype Influenza A Viruses with a New Fluorescent Immunochromatography System

Immunochromatography (IC) is an antigen-detection assay that plays an important role in the rapid diagnosis of influenza virus because the protocol is short time and easy to use. Despite the usability of IC, the sensitivity is approximately 10³ pfu per reaction. In addition, antigen-antibody interaction-based method cannot be used for the detection of influenza viruses with major antigenic change. In this study, we established the use of fluorescent immunochromatography (FLIC) to detect a broad spectrum of H5 subtype influenza A viruses. This method has improved sensitivity 10–100 fold higher than traditional IC because of the use of fluorescent conjugated beads. Our Type-E FLIC kit detected all of the H5 subtype influenza viruses that were examined, as well as recombinant hemagglutinin (HA) proteins (rHAs) belonging to the Eurasian H5 subtype viruses and the Type-N diagnosed North American H5 subtype influenza A viruses. Thus, this kit has the improved potential to detect H5 subtype influenza viruses of different clades with both Type-E and Type-N FLIC kits. Compared with PCR-based diagnosis, FLIC has a strong advantage in usability, because the sample preparation required for FLIC is only mix-and-drop without any additional steps such as RNA extraction. Our results can provide new strategies against the spread and transmission of HPAI H5N1 viruses in birds and mammals including humans.     

Targeted Induction of Interferon-λ in Humanized Chimeric Mouse Liver Abrogates Hepatotropic Virus Infection

Background & Aims

The interferon (IFN) system plays a critical role in innate antiviral response. We presume that targeted induction of IFN in human liver shows robust antiviral effects on hepatitis C virus (HCV) and hepatitis B virus (HBV).

Methods

This study used chimeric mice harboring humanized livers and infected with HCV or HBV. This mouse model permitted simultaneous analysis of immune responses by human and mouse hepatocytes in the same liver and exploration of the mechanism of antiviral effect against these viruses. Targeted expression of IFN was induced by treating the animals with a complex comprising a hepatotropic cationic liposome and a synthetic double-stranded RNA analog, pIC (LIC-pIC). Viral replication, IFN gene expression, IFN protein production, and IFN antiviral activity were analyzed (for type I, II and III IFNs) in the livers and sera of these humanized chimeric mice.

Results

Following treatment with LIC-pIC, the humanized livers of chimeric mice exhibited increased expression (at the mRNA and protein level) of human IFN-λs, resulting in strong antiviral effect on HBV and HCV. Similar increases were not seen for human IFN-α or IFN-β in these animals. Strong induction of IFN-λs by LIC-pIC occurred only in human hepatocytes, and not in mouse hepatocytes nor in human cell lines derived from other (non-hepatic) tissues. LIC-pIC-induced IFN-λ production was mediated by the immune sensor adaptor molecules mitochondrial antiviral signaling protein (MAVS) and Toll/IL-1R domain-containing adaptor molecule-1 (TICAM-1), suggesting dual recognition of LIC-pIC by both sensor adaptor pathways.

Conclusions

These findings demonstrate that the expression and function of various IFNs differ depending on the animal species and tissues under investigation. Chimeric mice harboring humanized livers demonstrate that IFN-λs play an important role in the defense against human hepatic virus infection.     

Deregulation of Pancreas-Specific Oxidoreductin ERO1β in the Pathogenesis of Diabetes Mellitus

A growing body of evidence has underlined the significance of endoplasmic reticulum (ER) stress in the pathogenesis of diabetes mellitus. ER oxidoreductin 1β (ERO1β) is a pancreas-specific disulfide oxidase that is known to be upregulated in response to ER stress and to promote protein folding in pancreatic β cells. It has recently been demonstrated that ERO1β promotes insulin biogenesis in β cells and thus contributes to physiological glucose homeostasis, though it is unknown if ERO1β is involved in the pathogenesis of diabetes mellitus. Here we show that in diabetic model mice, ERO1β expression is paradoxically decreased in β cells despite the indications of increased ER stress. However, overexpression of ERO1β in β cells led to the upregulation of unfolded protein response genes and markedly enlarged ER lumens, indicating that ERO1β overexpression caused ER stress in the β cells. Insulin contents were decreased in the β cells that overexpressed ERO1β, leading to impaired insulin secretion in response to glucose stimulation. These data indicate the importance of the fine-tuning of the ER redox state, the disturbance of which would compromise the function of β cells in insulin synthesis and thus contribute to the pathogenesis of diabetes mellitus.     

Tupaia Belangeri as an Experimental Animal Model for Viral Infection

Tupaias, or tree shrews, are small mammals that are similar in appearance to squirrels. The morphological and behavioral characteristics of the group have been extensively characterized, and despite previously being classified as primates, recent studies have placed the group in its own family, the Tupaiidae. Genomic analysis has revealed that the genus Tupaia is closer to humans than it is to rodents. In addition, tupaias are susceptible to hepatitis B virus and hepatitis C virus. The only other experimental animal that has been demonstrated to be sensitive to both of these viruses is the chimpanzee, but restrictions on animal testing have meant that experiments using chimpanzees have become almost impossible. Consequently, the development of the tupaia for use as an animal infection model could become a powerful tool for hepatitis virus research and in preclinical studies on drug development.     

Fomiroid A,a Novel Compound from the Mushroom Fomitopsis nigra,Inhibits NPC1L1-Mediated Cholesterol Uptake via a Mode of Action Distinct from That of Ezetimibe

Hypercholesterolemia is one of the key risk factors for coronary heart disease, a major cause of death in developed countries. Suppression of NPC1L1-mediated dietary and biliary cholesterol absorption is predicted to be one of the most effective ways to reduce the risk of hypercholesterolemia. In a screen for natural products that inhibit ezetimibe glucuronide binding to NPC1L1, we found a novel compound, fomiroid A, in extracts of the mushroom Fomitopsis nigra. Fomiroid A is a lanosterone derivative with molecular formula C₃₀H₄₈O₃. Fomiroid A inhibited ezetimibe glucuronide binding to NPC1L1, and dose-dependently prevented NPC1L1-mediated cholesterol uptake and formation of esterified cholesterol in NPC1L1-expressing Caco2 cells. Fomiroid A exhibited a pharmacological chaperone activity that corrected trafficking defects of the L1072T/L1168I mutant of NPC1L1. Because ezetimibe does not have such an activity, the binding site and mode of action of fomiroid A are likely to be distinct from those of ezetimibe.     

A Novel Antiviral Target Structure Involved in the RNA Binding,Dimerization, and Nuclear Export Functions of the Influenza A Virus Nucleoprotein

Developing antiviral therapies for influenza A virus (IAV) infection is an ongoing process because of the rapid rate of antigenic mutation and the emergence of drug-resistant viruses. The ideal strategy is to develop drugs that target well-conserved, functionally restricted, and unique surface structures without affecting host cell function. We recently identified the antiviral compound, RK424, by screening a library of 50,000 compounds using cell-based infection assays. RK424 showed potent antiviral activity against many different subtypes of IAV in vitro and partially protected mice from a lethal dose of A/WSN/1933 (H1N1) virus in vivo. Here, we show that RK424 inhibits viral ribonucleoprotein complex (vRNP) activity, causing the viral nucleoprotein (NP) to accumulate in the cell nucleus. In silico docking analysis revealed that RK424 bound to a small pocket in the viral NP. This pocket was surrounded by three functionally important domains: the RNA binding groove, the NP dimer interface, and nuclear export signal (NES) 3, indicating that it may be involved in the RNA binding, oligomerization, and nuclear export functions of NP. The accuracy of this binding model was confirmed in a NP-RK424 binding assay incorporating photo-cross-linked RK424 affinity beads and in a plaque assay evaluating the structure-activity relationship of RK424. Surface plasmon resonance (SPR) and pull-down assays showed that RK424 inhibited both the NP-RNA and NP-NP interactions, whereas size exclusion chromatography showed that RK424 disrupted viral RNA-induced NP oligomerization. In addition, in vitro nuclear export assays confirmed that RK424 inhibited nuclear export of NP. The amino acid residues comprising the NP pocket play a crucial role in viral replication and are highly conserved in more than 7,000 NP sequences from avian, human, and swine influenza viruses. Furthermore, we found that the NP pocket has a surface structure different from that of the pocket in host molecules. Taken together, these results describe a promising new approach to developing influenza virus drugs that target a novel pocket structure within NP.     

Some Properties of Synthetic UDP(2)-fructose

UDP(2)-fructose was synthesized from d-fructofuranose-2-phosphate by the method of Khorana et al. The product thus obtained showed slightly higher paper chromatographic mobilities than those of UDP-glucose and UDP(1)-fructose, and a large negative optical rotation. In acid hydrolysis, this substance was quickly converted into UDP(1)-fructose and then the latter is hydrolyzed to UMP and fructose-1-phosphate. The rate constant of this first step is far larger than the acid hydrolysis rate constant of natural UDP-fructose isolated from the tubers of Jerusalem artichoke. When treated with the snake venom nucleotide pyrophosphatase, UDP(2)-fructose was splitted into UMP and a substance having the same paper chromatographic mobility as that of fructofuranose-2-phosphate. From these results and those reported previously, the structure of the synthetic product may be UDP(2)-β-d-fructofuranose. It was argued that the natural UDP-fructose may be UDP(2)-α-d-fructofuranose.     

Structural Changes in Starch Molecules during the Malting of Barley

Barley was made into a normal and an over-modified malt, and the loss in starch was 14.6% and 67.7%, respectively. Starch granules, isolated from the barley and malts, were observed by scanning electron and light microscopes. In normal malt, 14% of the large granules were eroded and the small granules remained almost intact. In the case of over-modified malt, 38% of the large granules were eroded, and a marked reduction was found in the population of the small granules. Iodine affinities and blue values of the starches increased as malting proceeded. The malting of barley resulted in an apparent increase in the amylose component of the starch but hardly affected its molecular size distribution when examined by Bio-Gel A-50m column chromatography. The fine structures of the barley and malt amylopectins were compared by Shephadex G-50 and Bio-Gel P-2 column chromatographies after debranching with pullulanase. No change was observed during malting in spite of a significant reduction in the amylopectin component of the starch.