Chlorella virus SC-1A encodes at least five functional and one nonfunctional DNA methyltransferases

Chlorella virus SC-1A encodes at least six DNA methyltransferases (MTases): four N⁶-methyldeoxyadenine (m⁶A) MTases, M- CviSI (TGC^mA), M· CviSII C^mATG), M· CviSIII (TCG^mA) and M^mCviSIV (G^mATC), one 5-methyldeoxycytosine (m⁵C) MTase, M· CviSV (RC^mCG), and one nonfunctional m⁵C MTase, M· CviSVI, which is homologous to the MTase M· CviJI [RG^mC(T/C/G)] produced by another chlorella virus IL-3A. Genes encoding three of the SC-1A m⁶A MTases (M·CviSI, M· CviSII, and M· CviSIII) and the nonfunctional m⁵C MTase were cloned and sequenced. Neither M· CviSI nor M· CviSIII genes hybridized to genes for their respective isomethylomers, M· CviRI and M· CviBIII, from other chlorella viruses. However, the M· CviSII gene hybridized strongly to its M· CviAII isomethylomer gene from virus PBCV-1. Like the prototype chlorella virus PBCV-1, the SC-1A genome contains inverted terminal repeats, one of which is adjacent to the nonfunctional m⁵C MTase. The three cloned m⁶A MTase genes are distributed throughout the approx. 345 kb SC-1A genome.     

新生隐球菌RBP1基因克隆与功能分析

新生隐球菌是自然界广泛存在的具荚膜的酵母型病原真菌,能侵染人类中枢神经系统引起真菌性脑膜炎,每年导致全球大约18万人死亡。本研究在前期隐球菌交配表达谱的基础上,选择一上调表达的RNA结合蛋白基因（CNAG_04772）,进行克隆和功能分析。结果表明该基因全长2 247bp,cDNA全长1 518bp,编码505个氨基酸组成的蛋白,含有2个RNA识别基序RRM1和RRM2,命名为RBP1。基因表达模式分析表明RBP1在隐球菌酵母细胞、担子以及担孢子阶段都有表达,交配菌丝阶段不表达;亚细胞定位分析表明Rbp1蛋白定位于隐球菌的细胞核和细胞质中。与野生型菌株H99相比,敲除突变体菌株能够交配并产生双核菌丝,但丧失产生担孢子的能力,而互补菌株与野生型菌株H99间无显著差异。致病力测定结果显示,敲除突变体菌株致病性显著降低。     

1H NMR and NOE studies of the purple acid phosphatases from porcine uterus and bovine spleen.

The diiron active sites of the purple acid phosphatases from porcine uterus (also called uteroferrin, Uf) and bovine spleen (BSPAP) and their complexes with tungstate are compared by 1H NMR and NOE techniques. The paramagnetically shifted features of the 1H NMR spectrum of reduced BSPAP are similar to those of reduced Uf, while the spectra of the tungstate complexes are almost identical. These observations suggest that the two active sites are quite similar, in agreement with the greater than 90% sequence homology found in the two enzymes. Nuclear Overhauser effect (NOE) experiments on the His N-H resonances show that the Fe(III)-His residue is N epsilon-coordinated, while the Fe(II)-His is H delta-coordinated in both enzymes. On the basis of the above NMR and NOE results, our previously proposed model for the dinuclear iron active site of Uf [Scarrow, R. C., Pyrz, J. W., & Que, L., Jr. (1990) J. Am. Chem. Soc. 112, 657-665] is corroborated, refined, and found to represent the diiron center of BSPAP as well.     

A Protocol for the Comprehensive Flow Cytometric Analysis of Immune Cells in Normal and Inflamed Murine Non-Lymphoid Tissues

Flow cytometry is used extensively to examine immune cells in non-lymphoid tissues. However, a method of flow cytometric analysis that is both comprehensive and widely applicable has not been described. We developed a protocol for the flow cytometric analysis of non-lymphoid tissues, including methods of tissue preparation, a 10-fluorochrome panel for cell staining, and a standardized gating strategy, that allows the simultaneous identification and quantification of all major immune cell types in a variety of normal and inflamed non-lymphoid tissues. We demonstrate that our basic protocol minimizes cell loss, reliably distinguishes macrophages from dendritic cells (DC), and identifies all major granulocytic and mononuclear phagocytic cell types. This protocol is able to accurately quantify 11 distinct immune cell types, including T cells, B cells, NK cells, neutrophils, eosinophils, inflammatory monocytes, resident monocytes, alveolar macrophages, resident/interstitial macrophages, CD11b^- DC, and CD11b⁺ DC, in normal lung, heart, liver, kidney, intestine, skin, eyes, and mammary gland. We also characterized the expression patterns of several commonly used myeloid and macrophage markers. This basic protocol can be expanded to identify additional cell types such as mast cells, basophils, and plasmacytoid DC, or perform detailed phenotyping of specific cell types. In examining models of primary and metastatic mammary tumors, this protocol allowed the identification of several distinct tumor associated macrophage phenotypes, the appearance of which was highly specific to individual tumor cell lines. This protocol provides a valuable tool to examine immune cell repertoires and follow immune responses in a wide variety of tissues and experimental conditions.     

X-ray absorption spectroscopic studies of the methane monooxygenase hydroxylase component from Methylosinus trichosporium OB3b

The conversion from methane to methanol is catalyzed by methane monooxygenase (MMO) in methanotrophic bacteria. Earlier work on the crystal structures of the MMO hydroxylase component (MMOH) from Methylococcus capsulatus (Bath) at 4??°C and –160??°C has revealed two different core arrangements for the diiron active site. To ascertain the generality of these results, we have now carried out the first structural characterization on MMOH from Methylosinus trichosporium OB3b. Our X-ray absorption spectroscopic (XAS) analysis suggests the presence of two Fe-Fe distances of about 3?Å and 3.4?Å, which are proposed to reflect two populations of MMOH molecules with either a bis(μ-hydroxo)(μ-carboxylato)- or a (μ-hydroxo)(μ-carboxylato)diiron(III) core structure, respectively. The observation of these two different core structures, together with the crystallographic results of the MMOH from Methylococcus capsulatus (Bath), suggests the presence of an equilibrium that may reflect a core flexibility that is required to accommodate the various intermediates in the catalytic cycle of the enzyme. XAS studies on the binding of component B (MMOB) to the hydroxylase component show that MMOB does not perturb either this equilibrium or the gross structure of the oxidized diiron site in MMOH.     

Oxidative stress-induced DNA damage of mouse zygotes triggers G2/M checkpoint and phosphorylates Cdc25 and Cdc2

In vitro fertilized (IVF) embryos show both cell cycle and developmental arrest. We previously showed oxidative damage activates the ATM?→?Chk1?→?Cdc25B/Cdc25C cascade to mediate G2/M cell cycle arrest for repair of hydrogen peroxide (H₂O₂)-induced oxidative damage in sperm. However, the mechanisms underlying the developmental delay of zygotes are unknown. To develop a model of oxidative-damaged zygotes, we treated mouse zygotes with different concentrations of H₂O₂ (0, 0.01, 0.02, 0.03, 0.04, 0.05 mM), and evaluated in vitro zygote development, BrdU incorporation to detect the duration of S phase. We also examined reactive oxygen species level and used immunofluorescence to detect activation of γH2AX, Cdc2, and Cdc25. Oxidatively damaged zygotes showed a delay in G2/M phase and produced a higher level of ROS. At the same time, γH2AX was detected in oxidatively damaged zygotes as well as phospho-Cdc25B (Ser323), phospho-Cdc25C (Ser216), and phospho-Cdc2 (Tyr15). Our study indicates that oxidative stress-induced DNA damage of mouse zygotes triggers the cell cycle checkpoint, which results in G2/M cell cycle arrest, and that phospho-Cdc25B (Ser323), phospho-Cdc25C (Ser216), and phospho-Cdc2 (Tyr15) participate in activating the G2/M checkpoint.