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51.
The I2C family from the wilt disease resistance locus I2 belongs to the nucleotide binding, leucine-rich repeat superfamily of plant resistance genes. 总被引:12,自引:4,他引:8 下载免费PDF全文
N Ori Y Eshed I Paran G Presting D Aviv S Tanksley D Zamir R Fluhr 《The Plant cell》1997,9(4):521-532
Characterization of plant resistance genes is an important step in understanding plant defense mechanisms. Fusarium oxysporum f sp lycopersici is the causal agent of a vascular wilt disease in tomato. Genes conferring resistance to plant vascular diseases have yet to be described molecularly. Members of a new multigene family, complex I2C, were isolated by map-based cloning from the I2 F. o. lycopersici race 2 resistance locus. The genes show structural similarity to the group of recently isolated resistance genes that contain a nucleotide binding motif and leucine-rich repeats. Importantly, the presence of I2C antisense transgenes abrogated race 2 but not race 1 resistance in otherwise normal plants. Expression of the complete sense I2C-1 transgene conferred significant but partial resistance to F. o. lycopersici race 2. All members of the I2C gene family have been mapped genetically and are dispersed on three different chromosomes. Some of the I2C members cosegregate with other tomato resistance loci. Comparison within the leucine-rich repeat region of I2C gene family members shows that they differ from each other mainly by insertions or deletions. 相似文献
52.
53.
Fli-1, an Ets-related transcription factor, regulates erythropoietin-induced erythroid proliferation and differentiation: evidence for direct transcriptional repression of the Rb gene during differentiation. 下载免费PDF全文
54.
Orión C. Norzagaray-López Luis E. Calderon-Aguilera Ana B. Castro-Ceseña Gustavo Hirata José M. Hernández-Ayón 《Facies》2017,63(2):7
Ocean acidification is widely accepted as a primary threat to coral reef populations. Negative physiological effects include decreased calcification rates, heightened metabolic energy expenditure, and increased dissolution of coral skeletons. However, studies on the dissolution of coral skeletons structures under ocean acidification conditions and their implications on sediments remain scarce. In this work, we examined skeletal dissolution kinetics from four of the most representative hermatypic corals of the Eastern Pacific coasts (Pocillopora, Porites, Pavona, and Psammocora). Samples were treated with a highly acidic solution for defined periods of time, and measurements of dissolved calcium ([Ca+2]) were used to evaluate the kinetics of coral skeleton dissolution. All genera tests except Porites showed a zero reaction rate. Porites exhibited a first-order reaction and a faster reaction rate than other genera. Compression strength tests and skeletal density did not correlate with reaction rate. Pavona showed greater structural strength. Porites were the most susceptible to acidic dissolution compared to other genera tested due to their morphology, i.e., possession of the largest surface area, suggesting a high vulnerability under low-pH conditions. The hierarchical response in dissolution kinetics among coral genera tested suggests that the most soluble coral might act as a buffer under ocean acidification conditions. 相似文献
55.
Marie‐Therese Mackmull Bernd Klaus Ivonne Heinze Manopriya Chokkalingam Andreas Beyer Robert B Russell Alessandro Ori Martin Beck 《Molecular systems biology》2017,13(12)
Nuclear transport receptors (NTRs) recognize localization signals of cargos to facilitate their passage across the central channel of nuclear pore complexes (NPCs). About 30 different NTRs constitute different transport pathways in humans and bind to a multitude of different cargos. The exact cargo spectrum of the majority of NTRs, their specificity and even the extent to which active nucleocytoplasmic transport contributes to protein localization remains understudied because of the transient nature of these interactions and the wide dynamic range of cargo concentrations. To systematically map cargo–NTR relationships in situ, we used proximity ligation coupled to mass spectrometry (BioID). We systematically fused the engineered biotin ligase BirA* to 16 NTRs. We estimate that a considerable fraction of the human proteome is subject to active nuclear transport. We quantified the specificity and redundancy in NTR interactions and identified transport pathways for cargos. We extended the BioID method by the direct identification of biotinylation sites. This approach enabled us to identify interaction interfaces and to discriminate direct versus piggyback transport mechanisms. Data are available via ProteomeXchange with identifier PXD007976. 相似文献
56.
Jun Ohwada Sawako Ozawa Masami Kohchi Hiroshi Fukuda Chikako Murasaki Hitomi Suda Takeshi Murata Satoshi Niizuma Masao Tsukazaki Kazutomo Ori Kiyoshi Yoshinari Yoshiko Itezono Mika Endo Masako Ura Hiromi Tanimura Yoko Miyazaki Akira Kawashima Shunsuke Nagao Eitarou Namba Koutarou Ogawa Nobuo Shimma 《Bioorganic & medicinal chemistry letters》2009,19(10):2772-2776
CH0793076 (1) is a novel hexacyclic camptothecin analog showing potent antitumor activity in various human caner xenograft models. To improve the water solubility of 1, water-soluble prodrugs were designed to generate an active drug 1 nonenzymatically, thus expected to show less interpatient PK variability than CPT-11. Among the prodrugs synthesized, 4c (TP300, hydrochloride) having a glycylsarcosyl ester at the C-20 position of 1 is highly water-soluble (>10 mg/ml), stable below pH 4 and rapidly generates 1 at physiological pH in vitro. The rapid (ca. <1 min) generation of 1 after incubation of TP300 with plasma (mouse, rat, dog and monkey) was also demonstrated. TP300 showed a broader antitumor spectrum and more potent antitumor activity than CPT-11 in various human cancer xenograft models. 相似文献
57.
Antizyme (Az) is a highly conserved key regulatory protein bearing a major role in regulating polyamine levels in the cell. It has the ability to bind and inhibit ornithine decarboxylase (ODC), targeting it for degradation. Az inhibitor (AzI) impairs the activity of Az. In this study, we mapped the binding sites of ODC and AzI on Az using Ala scan mutagenesis and generated models of the two complexes by constrained computational docking. In order to scan a large number of mutants in a short time, we developed a workflow combining high-throughput mutagenesis, small-scale parallel partial purification of His-tagged proteins and their immobilization on a tris-nitrilotriacetic-acid-coated surface plasmon resonance chip. This combination of techniques resulted in a significant reduction in time for production and measurement of large numbers of mutant proteins. The data-driven docking results suggest that both proteins occupy the same binding site on Az, with Az binding within a large groove in AzI and ODC. However, single-mutant data provide information concerning the location of the binding sites only, not on their relative orientations. Therefore, we generated a large number of double-mutant cycles between residues on Az and ODC and used the resulting interaction energies to restrict docking. The model of the complex is well defined and accounts for the mutant data generated here, and previously determined biochemical data for this system. Insights on the structure and function of the complexes, as well as general aspects of the method, are discussed. 相似文献
58.
59.
Kirk C. Hansen Lauren Kiemele Ori Maller Jenean O'Brien Aarthi Shankar Jaime Fornetti Pepper Schedin 《Molecular & cellular proteomics : MCP》2009,8(7):1648-1657
Epithelial cell behavior is coordinated by the composition of the surrounding
extracellular matrix (ECM); thus ECM protein identification is critical for
understanding normal biology and disease states. Proteomic analyses of ECM
proteins have been hindered by the insoluble and digestion-resistant nature of
ECM. Here we explore the utility of combining rapid ultrasonication- and
surfactant-assisted digestion for the detailed proteomics analysis of ECM
samples. When compared with traditional overnight digestion, this optimized
method dramatically improved the sequence coverage for collagen I, revealed the
presence of hundreds of previously unidentified proteins in Matrigel, and
identified a protein profile for ECM isolated from rat mammary glands that was
substantially different from that found in Matrigel. In a three-dimensional
culture assay to investigate epithelial cell-ECM interactions, mammary
epithelial cells were found to undergo extensive branching morphogenesis when
plated with mammary gland-derived matrix in comparison with Matrigel.
Cumulatively these data highlight the tissue-specific nature of ECM composition
and function and underscore the need for optimized techniques, such as those
described here, for the proteomics characterization of ECM samples.Extracellular matrix (ECM)1 is a critical component of the tissue microenvironment. ECM plays a pivotal role
in embryonic stem cell development and differentiation (1, 2) as well as many physiological (3) and pathological processes, including cancer
progression (4, 5). Cell regulation by ECM has been studied with high frequency in recent years
(7, 8).
However, our ability to globally characterize ECM composition both in
vitro and in vivo has been severely limited because of several
unique attributes of ECM proteins such as high molecular weight glycans and the presence
of covalent protein cross-links (6, 9, 10).
Traditional proteomics approaches have proven to be ineffective for the identification
of ECM proteins as demonstrated by the fact that collagens, despite being the most
abundant protein in mammals, are significantly underrepresented in tissue-based
proteomics data sets.Ultrasonication has long been used for the digestion of bioorganic materials to allow for
maximal and reproducible extraction and hence the accurate identification of small
molecule and inorganic analytes (11). More
recently, Capelo et al. (12)
have used ultrasonic energy to catalyze tryptic digestion of proteins for subsequent
mass spectrometry-based identification. Here we sought to determine whether this method
could be optimized to prepare ECM samples for mass spectrometry-based analysis. For
method development, we used rat tail collagen as a representative ECM protein for which
current proteomics approaches have proven relatively unsuccessful. Type I collagen is
defined as a right-handed triple helix heterotrimer comprising two identical
α1 chains and one α2 chain that form a fibrillar network (6). The physical properties of the triple helical
structure render the protein resistant to proteasch as trypsin (9). In this work, we focused our efforts on developing a digestion
approach that improves our ability to perform proteomics analysis on a type I collagen
preparation and then used this method to identify the protein composition of EHS murine
chondrosarcoma matrix (10), herein referred to as
Matrigel, and a matrix preparation from rat mammary tissue.In this study, we developed a digestion approach suitable for a two-dimensional liquid
chromatography-tandem mass spectrometry-based analysis of ECM proteins. Our digestion
approach involves three cycles of ultrasonication for rapid initial trypsin digestion
followed by overnight digestion using an acid-labile surfactant. This approach resulted
in significant improvement in collagen peptide identification and the identification of
numerous ECM proteins previously uncharacterized in Matrigel and in mammary tissue. The
application of our ECM-optimized ultrasonic assisted trypsin digestion method is
anticipated to significantly advance the identification of tissue- and disease
state-specific ECM proteins. 相似文献
60.
Pyramidal neurons in the piriform cortex from olfactory-discrimination trained rats show enhanced intrinsic neuronal excitability that lasts for several days after learning. Such enhanced intrinsic excitability is mediated by long-term reduction in the post-burst after-hyperpolarization (AHP) which is generated by repetitive spike firing. AHP reduction is due to decreased conductance of a calcium-dependent potassium current, the sIAHP. We have previously shown that learning-induced AHP reduction is maintained by persistent protein kinase C (PKC) and extracellular regulated kinase (ERK) activation. However, the molecular machinery underlying this long-lasting modulation of intrinsic excitability is yet to be fully described. Here we examine whether the CaMKII, which is known to be crucial in learning, memory and synaptic plasticity processes, is instrumental for the maintenance of learning-induced AHP reduction. KN93, that selectively blocks CaMKII autophosphorylation at Thr286, reduced the AHP in neurons from trained and control rat to the same extent. Consequently, the differences in AHP amplitude and neuronal adaptation between neurons from trained rats and controls remained. Accordingly, the level of activated CaMKII was similar in pirifrom cortex samples taken form trained and control rats. Our data show that although CaMKII modulates the amplitude of AHP of pyramidal neurons in the piriform cortex, its activation is not required for maintaining learning-induced enhancement of neuronal excitability. 相似文献