Characterization of a Tc1-like transposable element in zebrafish (Danio rerio)

We have characterized Tdr1, a family of Tc1-like transposable elements found in the genome of zebrafish (Danio rerio). The copy number and distribution of the sequence in the zebrafish genome have been determined, and by these criteria Tdr1 can be classified as a moderately repetitive, interspersed element. Examination of the sequences and structures of several copies of Tdr1 revealed that a particular deletion derivative, 1250 by long, of the transposon has been amplified to become the dominant form of Tdr1. The deletion in these elements encompasses sequences encoding the N-terminal portion of the putative Tdr1 transposase. Sequences corresponding to the deleted region were also detected, and thus allowed prediction of the nucleotide sequence of a hypothetical full-length element. Well conserved segments of Tc1-like transposons were found in the flanking regions of known fish genes, suggesting that these elements have a long evolutionary history in piscine genomes. Tdr1 elements have long, 208 by inverted repeats, with a short DNA motif repeated four times at the termini of the inverted repeats. Although different from that of the prototype C. elegans transposon Tc1, this inverted repeat structure is shared by transposable elements from salmonid fish species and two Drosophila species. We propose that these transposons form a subgroup within the Tc1-like family. Comparison of Tc1-like transposons supports the hypothesis that the transposase genes and their flanking sequences have been shaped by independent evolutionary constraints. Although Tc1-like sequences are present in the genomes of several strains of zebrafish and in salmonid fishes, these sequences are not conserved in the genus Danio, thus raising the possibility that these elements can be exploited for gene tagging and genome mapping.     

[3H]Histamine uptake and release by astrocytes from rat brain: Effects of sodium deprivation,high potassium,and potassium channel blockers

Histamine transport has been characterized in cultured astroglial cells of rat brain. The kinetics of [³H]-histamine uptake yielded a K_m of 0.19±0.03 M and a V_max of 3.12±0.75 pmol×mg protein^–1×min^–1. Transport system revealed high affinity for histamine and an approximately ten times higher capacity than that shown in cultured glial cells of chick embryonic brain. Ouabain which interferes with utilization of ATP to generate ion gradients, and the replacement of Na⁺ with choline inhibited the initial rate of uptake showing a strong Na⁺-dependency and suggesting the presence of a tightly coupled sodium/histamine symporter. Dissipation of K⁺-gradient (in>out) by high K⁺ or by K⁺-channel blockers, BaCl₂, (100 M), quinine (100 M) or Sparteine (20 M) produced also remarkable inhibitions in the uptake of [³H]-histamine. Impromidine, a structural histamine-analogue could inhibit the uptake non-competitively in a range of concentrations of 1 to 10 M with a K_i value of 2.8 M, indicating the specificity of the uptake. [³H]histamine uptake measurements carried out by using a suspension of dissociated hypothalamic cells, of rat brain showed a strong gliotoxin-sensitivity and yielded a Km of 0.33±0.08 M; and a V_max of 2.65±0.35 pmoles×mg protein^–1×min^–1. The uptake could be reversed by incubating the cells in histamine-free Krebs medium. The [³H]histamine efflux was sensitive to Na⁺ omission, ouabain treatment and high K⁺ or K⁺ channel blockers, resulting in marked elevations in the efflux. Data indicate that glial uptake of histamine is a high affinity, Na⁺-dependent and electrogenic, driven by an inward-oriented sodium ion gradient and an outward-oriented potassium ion gradient and functions as part of histamine inactivation, at least in a shunt mechanism.Abbreviations used HA histamine - [³H]HA [2.5-³H]-histamine - dl--aAA dl-alpha-aminoadipic acid - (Na⁺+K⁺) ATP-ase sodium and potassium activated adenosine triphosphatase - SAH S-Adenosyl-d-Homocysteine - HNMT histamine-N-methyltransferase     

Synthesis of Polyfused Heteroaromatics by Palladium-Catalyzed Cross-Coupling Reaction

The palladium-catalyzed coupling of unsaturated halides or triflates with organostannanes (the Stille reaction) or with organo-boronic acids (the Suzuki reaction) has envolved as a powerful means of carbon-carbon bond formation. As an extention of our work on the synthesis and reactivity of positively charged bridge-head nitrogen containing fused azinium salts, we have been studying the formation of polyfused heteroaromatics with angular anellation pattern. The reaction of such positively charged salts with nucleophiles has proven to be a suitable tool for the preparation of heteroaryl dienes, which have been shown to be excellent intermediates for several ring closure reaction. A selection of results will be presented, including applications to natural product synthesis.     

Pet127 governs a 5' -> 3'-exonuclease important in maturation of apocytochrome b mRNA in Saccharomyces cerevisiae

The details of mRNA maturation in Saccharomyces mitochondria are not well understood. All seven mRNAs are transcribed as part of multigenic units. The mRNAs are processed at a common 3'-dodecamer sequence, but the 5'-ends have seven different sequences. To investigate whether apocytochrome b (COB) mRNA is processed at the 5'-end from a longer precursor by an endonuclease or an exonuclease, a 64-nucleotide sequence, which is required for the protection of COB mRNA by the Cbp1 protein and is found at the 5'-end of the processed COB mRNA, was duplicated in tandem. The wild-type 64-nucleotide element functioned in either the upstream or downstream position when paired with a mutant element. In the tandem wild-type strain, the 5'-end of the mRNA was at the 5'-end of the upstream unit, demonstrating that the mRNA is processed by an exonuclease. Accumulation of precursor COB RNA in single and double element strains with a deletion of PET127 demonstrated that the encoded protein governs the 5'-exonuclease responsible for processing the precursor to the mature form.     

Resistance to <Emphasis Type="Italic">Erysiphe necator</Emphasis> in the grapevine ‘Kishmish vatkana’ is controlled by a single locus through restriction of hyphal growth

Vitis vinifera ‘Kishmish vatkana’, a cultivated grapevine from Central Asia, does not produce visible symptoms in response to natural or artificial inoculation with the fungus Erysiphe necator Schwein., the casual agent of powdery mildew. ‘Kishmish vatkana’ allowed pathogen entry into epidermal cells at a rate comparable to that in the susceptible control Vitis vinifera ‘Nimrang’, but was able to limit subsequent hyphal proliferation. Density of conidiophores was significantly lower in ‘Kishmish vatkana’ (33.6 ± 8.7 conidiophores mm⁻²) than in ‘Nimrang’ (310.5 ± 24.0 conidiophores mm⁻²) by 120 h after inoculation. A progeny of 310 plants from a ‘Nimrang’ × ‘Kishmish vatkana’ cross were scored for the presence or absence of visible conidiophores throughout two successive seasons. Phenotypic segregation revealed the presence of a single dominant allele termed Resistance to Erysiphe necator 1 (REN1), which was heterozygous in ‘Kishmish vatkana’. A bulked segregant analysis was carried out using 195 microsatellite markers uniformly distributed across the entire genome. For each marker, association with the resistance trait was inferred by measuring in the bulks the ratio of peak intensities of the two alleles inherited from ‘Kishmish vatkana’. The phenotypic locus was assigned to linkage group 13, a genomic region in which no disease resistance had been reported previously. The REN1 position was restricted to a 7.4 cM interval by analyzing the 310 offspring for the segregation of markers that surrounded the target region. The closest markers, VMC9H4-2, VMCNG4E10-1 and UDV-020, were located 0.9 cM away from the REN1 locus. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Exogenous auxin-induced NO synthesis is nitrate reductase-associated in Arabidopsis thaliana root primordia

Nitric oxide (NO) functions in various physiological and developmental processes in plants. However, the source of this signaling molecule in the diversity of plant responses is not well understood. It is known that NO mediates auxin-induced adventitious and lateral root (LR) formation. In this paper, we provide genetic and pharmacological evidence that the production of NO is associated with the nitrate reductase (NR) enzyme during indole-3-butyric acid (IBA)-induced lateral root development in Arabidopsis thaliana L. NO production was detected using 4,5-diaminofluorescein diacetate (DAF-2DA) in the NR-deficient nia1, nia2 and Atnoa1 (former Atnos1) mutants of A. thaliana. An inhibitor for nitric oxide synthase (NOS) N(G)-monomethyl-l-arginine (l-NMMA) was applied. Our data clearly show that IBA increased LR frequency in the wild-type plant and the LR initials emitted intensive NO-dependent fluorescence of the triazol product of NO and DAF-2DA. Increased levels of NO were restricted only to the LR initials in contrast to primary root (PR) sections, where NO remained at the control level. The mutants had different NO levels in their control state (i.e. without IBA treatment): nia1, nia2 showed lower NO fluorescence than Atnoa1 or the wild-type plant. The role of NR in IBA-induced NO formation in the wild type was shown by the zero effects of the NOS inhibitors l-NMMA. Finally, it was clearly demonstrated that IBA was able to induce NO generation in both the wild-type and Atnoa1 plants, but failed to induce NO in the NR-deficient mutant. It is concluded that the IBA-induced NO production is nitrate reductase-associated during lateral root development in A. thaliana.     

In situ activation of antigen-specific CD8+ T cells in the presence of antigen in organotypic brain slices

The activation of Ag-specific T cells locally in the CNS could potentially contribute to the development of immune-mediated brain diseases. We addressed whether Ag-specific T cells could be stimulated in the CNS in the absence of peripheral lymphoid tissues by analyzing Ag-specific T cell responses in organotypic brain slice cultures. Organotypic brain slice cultures were established 1 h after intracerebral OVA Ag microinjection. We showed that when OVA-specific CD8(+) T cells were added to Ag-containing brain slices, these cells became activated and migrated into the brain to the sites of their specific Ags. This activation of OVA-specific T cells was abrogated by the deletion of CD11c(+) cells from the brain slices of the donor mice. These data suggest that brain-resident CD11c(+) cells stimulate Ag-specific naive CD8(+) T cells locally in the CNS and may contribute to immune responses in the brain.     

Atropine-induced gastrointestinal cytoprotection dependences to the intact of vagal nerve against indomethacin-induced gastrointestinal mucosal and microvascular damage in rats

The non-steroidal antiinflammatory drugs, such as an indomethacin (IND), cause mucosal ulceration and increase the mucosal vascular permeability in the gastrointestinal (GI) tract. Some exogenous agents, e.g. the atropine, can protect the GI mucosa against these ulcerogenic effects. The gastrointestinal functions and mucosal protection, however, are regulated by the vagal nerve. The aims of this study was to examine the dependence of atropine-induced GI cytoprotection to the vagal innervation against the development of IND-caused ulcers and microvascular damage in the mucosa of stomach and small intestine in rats. METHODS: the observations were carried out on CFY-strain rats. The mucosal damage was produced by subcutaneous administration of IND in a 20 mg/kg dose 24 h prior to the killing of animals at the same time as the start of atropine-application, which was given in a small dose (0.1 mg/kg) every 5 h. The subdiaphragmatic bilateral surgical vagotomy was done 24 h before the experiment. The vascular permeability, indicated by the microvascular endothel damage, was measured by the appearance and concentration of intravenously administered Evans blue into the GI mucosa. The number and severity of mucosal lesions and the Evans blue content of mucosa were determined in the stomach and small intestine. RESULTS: (1) The IND caused mucosal ulcers and Evans blue extravasation into the mucosa of the stomach and small intestine. (2) The IND-induced mucosal ulceration and vascular permeability significantly decreased after atropine-administration in the same parts of GI tract. (3) The extent of cytoprotective effect of atropine against the IND was decreased after bilateral surgical vagotomy. CONCLUSIONS: (1) The IND causes microvascular endothel damage in the stomach and small intestinal. (2) The atropine has a cytoprotective effect in the stomach and small intestine against the aggressive effects of IND without decrease of gastric acid secretion. (3) The intact vagal nerve is necessary to the function of cytoprotective mechanisms of atropine against the IND.     

Inhibition of Sterol Biosynthesis Reduces Tombusvirus Replication in Yeast and Plants

The replication of plus-strand RNA viruses depends on subcellular membranes. Recent genome-wide screens have revealed that the sterol biosynthesis genes ERG25 and ERG4 affected the replication of Tomato bushy stunt virus (TBSV) in a yeast model host. To further our understanding of the role of sterols in TBSV replication, we demonstrate that the downregulation of ERG25 or the inhibition of the activity of Erg25p with an inhibitor (6-amino-2-n-pentylthiobenzothiazole; APB) leads to a 3- to 5-fold reduction in TBSV replication in yeast. In addition, the sterol biosynthesis inhibitor lovastatin reduced TBSV replication by 4-fold, confirming the importance of sterols in viral replication. We also show reduced stability for the p92^pol viral replication protein as well as a decrease in the in vitro activity of the tombusvirus replicase when isolated from APB-treated yeast. Moreover, APB treatment inhibits TBSV RNA accumulation in plant protoplasts and in Nicotiana benthamiana leaves. The inhibitory effect of APB on TBSV replication can be complemented by exogenous stigmasterol, the main plant sterol, suggesting that sterols are required for TBSV replication. The silencing of SMO1 and SMO2 genes, which are orthologs of ERG25, in N. benthamiana reduced TBSV RNA accumulation but had a lesser inhibitory effect on the unrelated Tobacco mosaic virus, suggesting that various viruses show different levels of dependence on sterol biosynthesis for their replication.Plus-stranded RNA [(+)RNA] viruses usurp various intracellular/organellar membranes for their replication. These cellular membranes are thought to facilitate the building of viral factories, promote a high concentration of membrane-bound viral proteins, and provide protection against cellular nucleases and proteases (1, 12, 35, 44). The membrane lipids and proteins may serve as scaffolds for targeting the viral replication proteins or for the assembly of the viral replicase complex. The subcellular membrane also may provide critical lipid or protein cofactors to activate/modulate the function of the viral replicase. Indeed, the formation of spherules, consisting of lipid membranes bended inward and viral replication proteins as well as recruited host proteins, has been demonstrated for several (+)RNA viruses (20, 30, 48). These virus-induced spherules serve as sites of viral replication. Importantly, (+)RNA viruses also induce membrane proliferation that requires new lipid biosynthesis. Therefore, it is not surprising that several genome-wide screens for the identification of host factors affecting (+)RNA virus replication unraveled lipid biosynthesis/metabolism genes (8, 23, 38, 50). However, in spite of these intensive efforts, understanding the roles of various lipids and lipid biosynthesis enzymes and pathways in (+)RNA virus replication is limited.Tomato bushy stunt virus (TBSV) is among the most advanced model systems regarding the identification of host factors affecting (+)RNA virus replication (32). Among the five proteins encoded by the TBSV genome, only the p33 replication cofactor and the p92^pol RNA-dependent RNA polymerase (RdRp) are essential for TBSV RNA replication (55). p33 and p92^pol are integral membrane proteins, and they are present on the cytosolic surface of the peroxisomes, the site of replicase complex formation and viral RNA replication (30, 42). Electron microscopic images of cells actively replicating tombusviruses have revealed the extensive remodeling of membranes and indicated active lipid biosynthesis (30, 34).Additional support for the critical roles of various lipids in TBSV replication comes from a list of 14 host genes involved in lipid biosynthesis/metabolism, which affected tombusvirus replication and recombination based on systematic genome-wide screens in yeast, a model host. These screens covered 95% of the host genes (16, 38, 50, 51). The 14 identified host genes involved in lipid biosynthesis/metabolism included 8 genes affecting phospholipid biosynthesis, 4 genes affecting fatty acid biosynthesis/metabolism, and 2 genes affecting ergosterol synthesis. These findings suggest that these lipids likely are involved, directly or indirectly, in TBSV replication in yeast.To further understand the roles of cellular membranes, lipids, and host factors in viral (+)RNA replication, we analyzed the importance of sterol biosynthesis in tombusvirus replication. Sterols are ubiquitous and essential membrane components in all eukaryotes, affecting many membrane functions. Sterols regulate membrane rigidity, fluidity, and permeability by interacting with other lipids and proteins within the membranes (4, 5). They also are important for the organization of detergent-resistant microdomains, called lipid rafts (45). The sterol biosynthesis differs in several steps in animals, fungi, and plants, but the removal of two methyl groups at the C-4 position is critical and rate limiting. The C-4 demethylation steps are performed by SMO1 (sterol4α-methyl-oxidase) and SMO2 in plants and by the orthologous ERG25 gene in yeast (10). Accordingly, erg25 mutant yeast accumulates 4,4-dimethylzymosterol, an intermediate in the sterol biosynthesis pathway (3). However, sterol molecules become functional structural components of membranes only after the removal of the two methyl groups at C-4. Therefore, ERG25 is an essential gene for yeast growth.Our previous genome-wide screens for factors affecting tombusvirus replication have identified two sterol synthesis genes, ERG25 and ERG4, that participate in different steps in the sterol biosynthesis pathway (11). In this work, we further characterized the importance of ERG25 in TBSV replication in yeast. The downregulation or pharmacological inhibition of ERG25 in yeast led to a 4- to 5-fold decreased TBSV RNA accumulation. The in vitro activity of the tombusvirus replicase was reduced when isolated from the yeast cells described above. We also found that the stability of p92^pol viral replication protein decreased by 3-fold in yeast treated with a chemical inhibitor of ERG25. The inhibition of sterol biosynthesis in plant protoplasts or in plant leaves with a chemical inhibitor or the silencing of SMO1 and SMO2 genes also resulted in a reduction in TBSV RNA accumulation, supporting the roles of sterols in tombusvirus replication in plants as well.