Allyl isothiocyanate increases carbohydrate oxidation through enhancing insulin secretion by TRPV1

Abstract

The transient receptor potential (TRP) V1 is a cation channel belonging to the TRP channel family and it has been reported to be involved in energy metabolism, especially glucose metabolism. While, we have previously shown that intragastric administration of allyl isothiocyanate (AITC) enhanced glucose metabolism via TRPV1, the underlying mechanism has not been elucidated. In this study, we examined the relationship between insulin secretion and the increase in carbohydrate oxidation due to AITC. Intragastric administration of AITC elevated blood insulin levels in mice and AITC directly enhanced insulin secretion from isolated islets. These observations were not reproduced in TRPV1 knockout mice. Furthermore, AITC did not increase carbohydrate oxidation in streptozotocin-treated mice. These results suggest that intragastric administration of AITC could induce insulin secretion from islets via TRPV1 and that enhancement of insulin secretion was related to the increased carbohydrate oxidation due to AITC.     

Effects of flavonol-rich green tea cultivar (Camellia sinensis L.) on plasma oxidized LDL levels in hypercholesterolemic mice

To examine the possible benefits of tea flavonols, we compared anti-atherogenic effects between common and flavonol-rich tea cultivars. The tea infusion made from a flavonol-rich cultivar, but not a common cultivar, significantly decreased the plasma oxidized low-density lipoprotein level in mice fed a high-cholesterol diet. The result suggests that tea flavonols have the potential to protect against cardiovascular diseases.     

Crim1C140S mutant mice reveal the importance of cysteine 140 in the internal region 1 of CRIM1 for its physiological functions

Cysteine-rich transmembrane bone morphogenetic protein regulator 1 (CRIM1) is a type I transmembrane protein involved in the organogenesis of many tissues via its interactions with growth factors including BMP, TGF-β, and VEGF. In this study, we used whole-exome sequencing and linkage analysis to identify a novel Crim1 mutant allele generated by ENU mutagenesis in mice. This allele is a missense mutation that causes a cysteine-to-serine substitution at position 140, and is referred to as Crim1^C140S. In addition to the previously reported phenotypes in Crim1 mutants, Crim1^C140S homozygous mice exhibited several novel phenotypes, including dwarfism, enlarged seminal vesicles, and rectal prolapse. In vitro analyses showed that Crim1^C140S mutation affected the formation of CRIM1 complexes and decreased the amount of the overexpressed CRIM1 proteins in the cell culture supernatants. Cys140 is located in the internal region 1 (IR1) of the N-terminal extracellular region of CRIM1 and resides outside any identified functional domains. Inference of the domain architecture suggested that the Crim1^C140S mutation disturbs an intramolecular disulfide bond in IR1, leading to the protein instability and the functional defects of CRIM1. Crim1^C140S highlights the functional importance of the IR1, and Crim1^C140S mice should serve as a valuable model for investigating the functions of CRIM1 that are unidentified as yet.

     

In situ Quantification of Pancreatic Beta-cell Mass in Mice

Tracing changes of specific cell populations in health and disease is an important goal of biomedical research. The process of monitoring pancreatic beta-cell proliferation and islet growth is particularly challenging. We have developed a method to capture the distribution of beta-cells in the intact pancreas of transgenic mice with fluorescence-tagged beta-cells with a macro written for ImageJ (rsb.info.nih.gov/ij/). Following pancreatic dissection and tissue clearing, the entire pancreas is captured as a virtual slice, after which the GFP-tagged beta-cells are examined. The analysis includes the quantification of total beta-cell area, islet number and size distribution with reference to specific parameters and locations for each islet and for small clusters of beta-cells. The entire distribution of islets can be plotted in three dimensions, and the information from the distribution on the size and shape of each islet allows a quantitative and qualitative comparison of changes in overall beta-cell area at a glance.Download video file.^{(98M, mp4)}     

Isolation and Characterization of Patient-derived, Toxic, High Mass Amyloid ��-Protein (A��) Assembly from Alzheimer Disease Brains

Amyloid β-protein (Aβ) assemblies are thought to play primary roles in Alzheimer disease (AD). They are considered to acquire surface tertiary structures, not present in physiologic monomers, that are responsible for exerting toxicity, probably through abnormal interactions with their target(s). Therefore, Aβ assemblies having distinct surface tertiary structures should cause neurotoxicity through distinct mechanisms. Aiming to clarify the molecular basis of neuronal loss, which is a central phenotype in neurodegenerative diseases such as AD, we report here the selective immunoisolation of neurotoxic 10–15-nm spherical Aβ assemblies termed native amylospheroids (native ASPDs) from AD and dementia with Lewy bodies brains, using ASPD tertiary structure-dependent antibodies. In AD patients, the amount of native ASPDs was correlated with the pathologic severity of disease. Native ASPDs are anti-pan oligomer A11 antibody-negative, high mass (>100 kDa) assemblies that induce degeneration particularly of mature neurons, including those of human origin, in vitro. Importantly, their immunospecificity strongly suggests that native ASPDs have a distinct surface tertiary structure from other reported assemblies such as dimers, Aβ-derived diffusible ligands, and A11-positive assemblies. Only ASPD tertiary structure-dependent antibodies could block ASPD-induced neurodegeneration. ASPDs bind presynaptic target(s) on mature neurons and have a mode of toxicity different from those of other assemblies, which have been reported to exert their toxicity through binding postsynaptic targets and probably perturbing glutamatergic synaptic transmission. Thus, our findings indicate that native ASPDs with a distinct toxic surface induce neuronal loss through a different mechanism from other Aβ assemblies.     

Oxidative degradation of 4-hydroxyacetophenone in Arthrobacter sp. TGJ4

The 4-hydroxyacetophenone assimilating bacterium Arthrobacter sp. TGJ4 was isolated from a soil sample. The resting cell reaction suggested that the strain cleaved 4-hydroxyacetophenone and its 3-methoxy derivative to the corresponding carboxylic acids and formaldehyde. Some properties of the enzyme catalyzing the cleavage reaction were examined.     

Molecular phylogeny of Russulaceae (Basidiomycetes; Russulales) inferred from the nucleotide sequences of nuclear large subunit rDNA

Phylogenetic relationships of the genera Russula and Lactarius were investigated using sequence data from the nuclear-encoded large subunit ribosomal DNA (LSU rDNA). Ninety-five sequences belonging to the genera Russula and Lactarius, including 31 sequences from the databases, were used in this study. Analysis of the LSU rDNA region indicated that Russulaceae was divided into six groups (group A–F) in the neighbor-joining (NJ) tree. Lactarius consisted of one large clade (group A). Therefore, this genus was found to be monophyletic. However, the monophyly of genus Russula remained unclear. The genus Russula consisted of five groups in the NJ tree. Group B includes sects. Plorantes and Archaeinae (Heim), and group C includes sects. Delicoarchaeae and Russula in the NJ tree. Neither of the two groups formed a single clade in the most parsimonius (MP) tree. Group D includes many taxa having colored spore prints and amyloid in suprahilar plage of spores in sect. Russula and sect. Rigidae. Group E consists of only sect. Compactae and is further divided into three subclades, represented by R. densifolia, R. nigricans, and R. subnigricans, respectively. Group F contains sects. Rigidae, Ingratae, and Pelliculariae. Sect. Compactae and sect. Plorantes should not be as closely related as previously supposed. Russula earlei may be placed in sect. Archaeinae Heim. Russula flavida (subsect. Amoeninae) is placed in sect. Russula with R. aurea with a high bootstrap value (99%). The nuclear LSU rDNA region is a useful tool in recognization of species of Russulaceae and may provide information concerning phylogenetic relationships between the genera Russula and Lactarius.     

Cooperation between alteration of DNA gyrase genes and over-expression of MexB and MexX confers high-level fluoroquinolone resistance in Pseudomonas aeruginosa strains isolated from a patient who received a liver transplant followed by treatment with fluoroquinolones

Clinical isolates of highly fluoroquinolone-resistant Pseudomonas aeruginosa had a mutation in either A or B subunit of DNA gyrase and over-expressed MexB and MexX, the efflux system proteins. Introduction of wild-type gyrase genes of Escherichia coli into the isolates made them as fluoroquinolonesusceptible as the moderately fluoroquinolone-resistant strains that only over-expressed efflux system proteins. These findings demonstrate that high fluoroquinolone-resistance in P. aeruginosa is attributed to cooperation between alteration in DNA gyrase genes and over-expression of efflux systems proteins.     

Polycomb group gene mel-18 regulates early T progenitor expansion by maintaining the expression of Hes-1, a target of the Notch pathway

Polycomb group (PcG) proteins play a role in the maintenance of cellular identity throughout many rounds of cell division through the regulation of gene expression. In this report we demonstrate that the loss of the PcG gene mel-18 impairs the expansion of the most immature T progenitor cells at a stage before the rearrangement of the TCR beta-chain gene in vivo and in vitro. This impairment of these T progenitors appears to be associated with increased susceptibility to cell death. We also show that the expression of Hes-1, one of the target genes of the Notch signaling pathway, is drastically down-regulated in early T progenitors isolated from mel-18(-/-) mice. In addition, mel-18(-/-) T precursors could not maintain the Hes-1 expression induced by Delta-like-1 in monolayer culture. Collectively, these data indicate that mel-18 contributes to the maintenance of the active state of the Hes-1 gene as a cellular memory system, thereby supporting the expansion of early T progenitors.