Cleavage of DNA by viologen related compounds and their incorporation into oligodeoxyribonucleotides.

The DNA cleavage reaction by viologen and related compound such as 2,7-diazapyrenium salt was investigated. These viologen analogues were successfully incorporated into the oligothymidylate in the form of covalent bonding at the site of the phosphorous backbone through the linker arm.     

Tumor‐suppressive roles of ΔNp63β‐miR‐205 axis in epithelial–mesenchymal transition of oral squamous cell carcinoma via targeting ZEB1 and ZEB2

We previously revealed that epithelial‐to‐mesenchymal transition (EMT) was mediated by ΔNp63β, a splicing variant of ΔNp63, in oral squamous cell carcinoma (OSCC). Recent studies have highlighted the involvement of microRNA (miRNA) in EMT of cancer cells, though the mechanism remains unclear. To identify miRNAs responsible for ΔNp63β‐mediated EMT, miRNA microarray analyses were performed by ΔNp63β‐overexpression in OSCC cells; SQUU‐B, which lacks ΔNp63 expression and displays EMT phenotypes. miRNAs microarray analyses revealed miR‐205 was the most up‐regulated following ΔNp63β‐overexpression. In OSCC cells, miR‐205 expression was positively associated with ΔNp63 and negatively with zinc‐finger E‐box binding homeobox (ZEB) 1 and ZEB2, potential targets of miR‐205. miR‐205 overexpression by miR‐205 mimic transfection into SQUU‐B cells led to decreasing ZEB1, ZEB2, and mesenchymal markers, increasing epithelial markers, and reducing cell motilities, suggesting inhibition of EMT phenotype. Interestingly, the results opposite to this phenomenon were obtained by transfection of miR‐205 inhibitor into OSCC cells, which express ΔNp63 and miR‐205. Furthermore, target protector analyses revealed direct regulation by miR‐205 of ZEB1 and ZEB2 expression. These results showed tumor‐suppressive roles of ΔNp63β and miR‐205 by inhibiting EMT thorough modulating ZEB1 and ZEB2 expression in OSCC.     

The Adaptor Complex AP-4 Regulates Vacuolar Protein Sorting at the trans-Golgi Network by Interacting with VACUOLAR SORTING RECEPTOR1

Adaptor protein (AP) complexes play critical roles in protein sorting among different post-Golgi pathways by recognizing specific cargo protein motifs. Among the five AP complexes (AP-1–AP-5) in plants, AP-4 is one of the most poorly understood; the AP-4 components, AP-4 cargo motifs, and AP-4 functional mechanism are not known. Here, we identify the AP-4 components and show that the AP-4 complex regulates receptor-mediated vacuolar protein sorting by recognizing VACUOLAR SORTING RECEPTOR1 (VSR1), which was originally identified as a sorting receptor for seed storage proteins to target protein storage vacuoles in Arabidopsis (Arabidopsis thaliana). From the vacuolar sorting mutant library GREEN FLUORESCENT SEED (GFS), we isolated three gfs mutants that accumulate abnormally high levels of VSR1 in seeds and designated them as gfs4, gfs5, and gfs6. Their responsible genes encode three (AP4B, AP4M, and AP4S) of the four subunits of the AP-4 complex, respectively, and an Arabidopsis mutant (ap4e) lacking the fourth subunit, AP4E, also had the same phenotype. Mass spectrometry demonstrated that these four proteins form a complex in vivo. The four mutants showed defects in the vacuolar sorting of the major storage protein 12S globulins, indicating a role for the AP-4 complex in vacuolar protein transport. AP4M bound to the tyrosine-based motif of VSR1. AP4M localized at the trans-Golgi network (TGN) subdomain that is distinct from the AP-1-localized TGN subdomain. This study provides a novel function for the AP-4 complex in VSR1-mediated vacuolar protein sorting at the specialized domain of the TGN.Membrane trafficking in plants shares many fundamental features with those in yeast and animals (Bassham et al., 2008). In general, vacuolar proteins are synthesized on the rough endoplasmic reticulum and then transported to vacuoles via the Golgi apparatus (Xiang et al., 2013; Robinson and Pimpl, 2014). The vacuolar trafficking in plants has been studied by monitoring the transport of reporter proteins to lytic vacuoles in vegetative cells and tissues (Jin et al., 2001; Pimpl et al., 2003; Miao et al., 2008; Niemes et al., 2010). Recently, seed storage proteins became a model cargo for monitoring the transport of endogenous vacuolar proteins in plants (Shimada et al., 2003a; Sanmartín et al., 2007; Isono et al., 2010; Pourcher et al., 2010; Uemura et al., 2012; Shirakawa et al., 2014). During seed maturation, a large amount of storage proteins are synthesized and sorted to specialized vacuoles, the protein storage vacuoles (PSVs). To properly deliver vacuolar proteins, sorting receptors play a critical role in recognizing the vacuole-targeting signal of the proteins. VACUOLAR PROTEIN SORTING10 and Man-6-P receptor function as sorting receptors for vacuolar/lysosomal proteins in the trans-Golgi network (TGN) of yeast and mammals, respectively. The best-characterized sorting receptors in plants are VACUOLAR SORTING RECEPTOR (VSR) family proteins (De Marcos Lousa et al., 2012). VSRs have been shown to function in sorting both storage proteins to PSVs (Shimada et al., 2003a; Fuji et al., 2007) and lytic cargos to lytic vacuoles (Zouhar et al., 2010).To sort the receptors in the TGN into vacuoles/lysosomes, the adaptor protein (AP) complex binds the cytosolic domain of the receptors. The AP complexes form evolutionarily conserved machinery that mediates the post-Golgi trafficking in eukaryotic cells (Robinson, 2004). There are five types of AP complexes, AP-1 to AP-5. The functions of AP-1, AP-2, and AP-3 have been established. AP-1 appears to be involved in trafficking between the TGN and endosomes (Hirst et al., 2012), AP-2 is involved in clathrin-mediated endocytosis (McMahon and Boucrot, 2011), and AP-3 is involved in protein trafficking from the TGN/endosomes to the vacuole/lysosomes (Dell’Angelica, 2009). However, little is known about AP-4 and AP-5. Mammalian AP-4 may be involved in basolateral sorting in polarized cells and in the transport of specific cargo proteins, such as the amyloid precursor protein APP, from the TGN to endosomes (Burgos et al., 2010). The fifth AP complex, AP-5, was recently identified, and its orthologs are widely conserved in the eukaryotic genomes (Hirst et al., 2011). The AP complexes exist as heterotetrameric proteins that consist of two large subunits (β1-5 and one each of ɣ/α/δ/ε/ζ), one medium subunit (µ1-5), and one small subunit (σ1-5). The sorting mechanism is best characterized for the medium (µ) subunit, which is known to recognize the Tyr-based YXXФ motif (where Ф represents Leu, Ile, Phe, Met, or Val) that is present in the cytosolic domains of cargo proteins (Ohno et al., 1995). Mutations of the YXXФ motif abolish the interaction with µ and alter the subcellular localization of the cargo proteins.The genome of Arabidopsis (Arabidopsis thaliana) contains all five sets of putative AP genes (Bassham et al., 2008; Hirst et al., 2011). The function of AP-4 in membrane trafficking and its physiological roles in plants are largely unknown. In this study, we identified and characterized the AP-4 complex in Arabidopsis. Mutants lacking the AP-4 subunits exhibited defects in VSR1-mediated vacuolar sorting of storage proteins in seeds. Our results provide new insights into the receptor-mediated vacuolar trafficking in post-Golgi pathways.     

Site-specific and linkage analyses of fucosylated <Emphasis Type="Italic">N</Emphasis>-glycans on haptoglobin in sera of patients with various types of cancer: possible implication for the differential diagnosis of cancer

Fucosylation is an important type of glycosylation involved in cancer, and fucosylated proteins could be employed as cancer biomarkers. Previously, we reported that fucosylated N-glycans on haptoglobin in the sera of patients with pancreatic cancer were increased by lectin-ELISA and mass spectrometry analyses. However, an increase in fucosylated haptoglobin has been reported in various types of cancer. To ascertain if characteristic fucosylation is observed in each cancer type, we undertook site-specific analyses of N-glycans on haptoglobin in the sera of patients with five types of operable gastroenterological cancer (esophageal, gastric, colon, gallbladder, pancreatic), a non-gastroenterological cancer (prostate cancer) and normal controls using ODS column LC-ESI MS. Haptoglobin has four potential glycosylation sites (Asn184, Asn207, Asn211, Asn241). In all cancer samples, monofucosylated N-glycans were significantly increased at all glycosylation sites. Moreover, difucosylated N-glycans were detected at Asn 184, Asn207 and Asn241 only in cancer samples. Remarkable differences in N-glycan structure among cancer types were not observed. We next analyzed N-glycan alditols released from haptoglobin using graphitized carbon column LC-ESI MS to identify the linkage of fucosylation. Lewis-type and core-type fucosylated N-glycans were increased in gastroenterological cancer samples, but only core-type fucosylated N-glycan was relatively increased in prostate cancer samples. In metastatic prostate cancer, Lewis-type fucosylated N-glycan was also increased. These data suggest that the original tissue/cell producing fucosylated haptoglobin is different in each cancer type and linkage of fucosylation might be a clue of primary lesion, thereby enabling a differential diagnosis between gastroenterological cancers and non-gastroenterological cancers.     

Visualization of NO3?/NO2? Dynamics in Living Cells by Fluorescence Resonance Energy Transfer (FRET) Imaging Employing a Rhizobial Two-component Regulatory System

Nitrate (NO₃⁻) and nitrite (NO₂⁻) are the physiological sources of nitric oxide (NO), a key biological messenger molecule. NO₃⁻/NO₂⁻ exerts a beneficial impact on NO homeostasis and its related cardiovascular functions. To visualize the physiological dynamics of NO₃⁻/NO₂⁻ for assessing the precise roles of these anions, we developed a genetically encoded intermolecular fluorescence resonance energy transfer (FRET)-based indicator, named sNOOOpy (sensor for NO₃⁻/NO₂⁻ in physiology), by employing NO₃⁻/NO₂⁻-induced dissociation of NasST involved in the denitrification system of rhizobia. The in vitro use of sNOOOpy shows high specificity for NO₃⁻ and NO₂⁻, and its FRET signal is changed in response to NO₃⁻/NO₂⁻ in the micromolar range. Furthermore, both an increase and decrease in cellular NO₃⁻ concentration can be detected. sNOOOpy is very simple and potentially applicable to a wide variety of living cells and is expected to provide insights into NO₃⁻/NO₂⁻ dynamics in various organisms, including plants and animals.     

Leaf flushing and shedding,bud and flower production,and stem elongation in tall birch trees subjected to increases in aboveground temperature

Key message

Tall birch trees allocate extra resource due to aboveground temperature elevation to bud and male flower production rather than to plant growth. Saplings increased only plant growth under warming. Size-dependent response should be considered.

Abstract

We experimentally heated canopy organs of tall birch trees (Betula ermanii Cham.; 18–20 m high) growing at a high latitude to determine how leaf phenology, plant growth, and bud and male flower production might shift in response to increases in aboveground temperature during global climate change. We warmed the canopies with infrared heat lamps fixed to steel pipe scaffolds built around the trees. The temperature of the warmed canopies increased by approximately 1 °C. Warming extended the length of the growing season of canopy leaves (by accelerating leaf flush and delaying leaf fall), and significantly increased the numbers of buds and male flowers per shoot. Bud production and shoot length were positively correlated in both warmed and control branches. However, warming did not increase canopy shoot lengths. The intercept value of the positive regression slope between bud production and shoot length for warmed branches was higher than that for control branches. Thus, canopy warming had a direct positive effect on the bud production but had no indirect effect via increases in shoot length. Our experiment showed that tall birch trees allocated extra resources made available by increased aboveground temperature to bud and male flower production rather than to plant growth.

     

Three-dimensional temporal and spatial distribution of adult Rhyzopertha dominica in stored wheat and corn under different temperatures, moisture contents, and adult densities

Three-dimensional temporal and spatial distributions of adult Rhyzopertha dominica (F.) at adult densities of 1.0, 5.0, and 10.0 adults per kg grain and at 20 +/- 1, 25 +/- 1, and 30 +/- 1 degrees C were determined in 1.5 t bins filled with wheat (Triticum aestivum L.) with 11.0 +/- 0.8, 13.0 +/- 0.6, and 15.0 +/- 0.5% moisture content (wet basis) or corn (Zea mays L.) with 13.0 +/- 0.2% moisture content (wet basis). At each of five sampled locations, grain was separated into three 15-kg vertical layers, and adult numbers in each layer were counted. Inside both corn and wheat, adults did not prefer any location in the same layer except at high introduced insect density in wheat. The adults were recovered from any layer of the corn and >12, 65, and 45% of adults were recovered in the bottom layer of the corn at 20, 25, and 30 degrees C; respectively. However, <1% of adults were recovered in the bottom layer of wheat. Numbers of adults correlated with those in adjacent locations in both vertical and horizontal directions, and the temporal continuous property existed in both wheat and corn. Adults had highly clumped distribution at any grain temperature and moisture content. This aggregation behavior decreased with the increase of adult density and redistribution speed. Grain type influenced their redistribution speed, and this resulted in the different redistribution patterns inside wheat and corn bulks. These characterized distribution patterns could be used to develop sampling plans and integrated pest management programs in stored grain bins.     

Cutting edge: TREM-2 attenuates macrophage activation

The triggering receptor expressed on myeloid cells 2 (TREM-2) delivers intracellular signals through the adaptor DAP12 to regulate myeloid cell function both within and outside the immune system. The role of TREM-2 in immunity has been obscured by the failure to detect expression of the TREM-2 protein in vivo. In this study, we show that TREM-2 is expressed on macrophages infiltrating the tissues from the circulation and that alternative activation with IL-4 can induce TREM-2. TREM-2 expression is abrogated by macrophage maturation with LPS of IFN-gamma. Using TREM-2(-/-) mice, we find that TREM-2 functions to inhibit cytokine production by macrophages in response to the TLR ligands LPS, zymosan, and CpG. Furthermore, we find that TREM-2 completely accounts for the increased cytokine production previously reported by DAP12(-/-) macrophages. Taken together, these data show that TREM-2 is expressed on newly differentiated and alternatively activated macrophages and functions to restrain macrophage activation.