The biological activity of ubiquitinated BoNT/B light chain in vitro and in human SHSY‐5Y neuronal cells

BoNT/B light chain is a zinc‐dependent endopeptidase. After entering its target, the neuronal cell, BoNT/B is responsible for synaptobrevin‐2 (VAMP‐2) cleavage. This results in reduced neurotransmitter (acetylcholine) release from synaptic vesicles, yielding muscular paralysis. Since the toxin persists in neuronal cells for an extended period, regeneration of VAMP‐2 is prevented. We evaluated therapeutic targets to overcome botulinum persistence because early removal would rescue the neuronal cell. The ubiquitination/proteasome cellular pathway is responsible for removing “old” or undesirable proteins. Therefore, we assessed ubiquitination of BoNT/B light chain in vitro, and characterized the effects of ubiquitination modulating drugs, PMA (phorbol 12‐myristate 13‐acetate) and expoxomicin, on ubiquitination of BoNT/B light chain in neuronal cells. Both drugs altered BoNT/B light chain ubiquitination. Ubiquitination in vitro and in cells decreased the biological activity of BoNT/B light chain. These results further elucidate BoNT protein degradation pathways in intoxicated neuronal cells and mechanisms to enhance toxin removal. J. Cell. Biochem. 108: 660–667, 2009. Published 2009 Wiley‐Liss, Inc.     

Coupling of Graphene Plasmonics Modes Induced by Near-Field Perturbation at Terahertz Frequencies

Plasmonics - The coupling between graphene surface plasmonic (GSP) modes and evanescent wave modes induced by near-field perturbation is investigated systematically in the grating-spacer-graphene...     

Identification of the Third Binding Site of Arsenic in Human Arsenic (III) Methyltransferase

Arsenic (III) methyltransferase (AS3MT) catalyzes the process of arsenic methylation. Each arsenite (iAs³⁺) binds to three cysteine residues, methylarsenite (MMA³⁺) binds to two, and dimethylarsenite (DMA³⁺) binds to one. However, only two As-binding sites (Cys156 and Cys206) have been confirmed on human AS3MT (hAS3MT). The third As-binding site is still undefined. Residue Cys72 in Cyanidioschyzon merolae arsenite S-adenosylmethyltransferase (CmArsM) may be the third As-binding site. The corresponding residue in hAS3MT is Cys61. Functions of Cys32, Cys61, and Cys85 in hAS3MT are unclear though Cys32, Cys61, and Cys85 in rat AS3MT have no effect on the enzyme activity. This is why the functions of Cys32, Cys61, and Cys85 in hAS3MT merit investigation. Here, three mutants were designed, C32S, C61S, and C85S. Their catalytic activities and conformations were determined, and the catalytic capacities of C156S and C206S were studied. Unlike C85S, mutants C32S and C61S were completely inactive in the methylation of iAs³⁺ and active in the methylation of MMA³⁺. The catalytic activity of C85S was also less pronounced than that of WT-hAS3MT. All these findings suggest that Cys32 and Cys61 markedly influence the catalytic activity of hAS3MT. Cys32 and Cys61 are necessary to the first step of methylation but not to the second. Cys156 and Cys206 are required for both the first and second steps of methylation. The S^C32 is located far from arsenic in the WT-hAS3MT-SAM-As model. The distances between S^C61 and arsenic in WT-hAS3MT-As and WT-hAS3MT-SAM-As models are 7.5 Å and 4.1 Å, respectively. This indicates that SAM-binding to hAS3MT shortens the distance between S^C61 and arsenic and promotes As-binding to hAS3MT. This is consistent with the fact that SAM is the first substrate to bind to hAS3MT and iAs is the second. Model of WT-hAS3MT-SAM-As and the experimental results indicate that Cys61 is the third As-binding site.     

SENP3 senses oxidative stress to facilitate STING-dependent dendritic cell antitumor function

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Effect of Proline Analogues on Activity of Human Prolyl Hydroxylase and the Regulation of HIF Signal Transduction Pathway

Hypoxia inducible factor 1 (HIF-1) plays a pivotal role in cellular responses to hypoxia. Prolyl hydroxylase 3 (PHD3) degrades HIF-1α under normoxic conditions through the hydroxylation of HIF-1α for proteolysis. Inhibiting PHD3 activity is crucial for up-regulating HIF-1α, thereby acting as a potential target for treating hypoxia-related diseases. In this study, two proline analogues (PA1 and PA2) were screened as PHD3 inhibitors with apparent EC₅₀ values of 1.53 and 3.17 µM respectively, indicating good inhibition potency. Nine proteins, significantly regulated by PA1, were identified using 2-DE coupled with MALDI-TOF/TOF MS. Pyruvate kinase isozymes M1/M2 (PKM) and alpha-enolase 1 (ENO1), which are key modulators of glycolysis, are directly regulated by HIF-1α. Moreover, VEGF, a signal protein stimulating angiogenesis, was strongly promoted by PA1. Our findings suggest that PA1 stabilized HIF-1α as well as up-regulated glycolysis and angiogenesis proteins. Herein, for the first time, we systematically studied proline analogue PA1 as a PHD3 inhibitor, which provides innovative evidence for the treatment of HIF-related diseases.     

火龙果茎基因组DNA提取方法改良

火龙果(Hylocereus undulatus)是近年发展起来的一种新兴热带水果, 其茎富含多糖、多酚及其它次生代谢物, 黏性极大, 很难从中提取高质量的DNA。特别是一年生以上的老茎, 目前尚未有较好的DNA提取方法。为了解决这一难题, 该研究对CTAB+Tris-HCl洗涤法进行了3种方式的改良。结果表明, “改进三”方法可不受取样时期和取样部位的限制, 从一年生以上火龙果茎中提取的DNA质量最好且不含黏性物质, 可用于酶切与分子标记等生化和分子生物学实验。该研究探索了一条较为理想的火龙果茎DNA提取方法, 值得推广应用。     

林木共生菌系统及其作用机制——以杨树为例

杨树（Populus）是重要造林树种,也是研究林木基础生物学性状的模式材料。不仅如此,杨树可与多种细菌（内生细菌、内生固氮菌和根际促生菌）和真菌（外生菌根真菌、丛枝菌根真菌和内生真菌）类群建立共生关系,为揭示树木和微生物之间的互惠共生机制提供了理想模型。这些共生菌能积极调控林木生长发育、营养吸收和生理生态过程。目前在杨树-双色蜡蘑（Laccaria bicolor）形成的外生菌根发育、提高杨树耐盐、耐重金属的生理与分子机制、叶片内生真菌群落结构与病害发生、菌根辅助细菌和菌丝内共生细菌-真菌-杨树形成的三重跨界共生等方面取得多项突破。近年来,一批模式草本植物微生物组（microbiome）计划相继实施,对共生菌群落结构和功能的认识有了革命性的进步。以美洲黑杨、毛果杨和胶杨为代表的林木微生物组研究也已启动,表明宿主基因型和环境因子可显著影响共生菌群落结构与物种组成;在根际（rhizosphere）和内生（endosphere）环境存在结构和功能迥异的菌群。另一方面,以根系为诱饵,通过宿主表型来推测菌群功能的反向"钓鱼"策略将推动林木根际微生物工程研究,为揭示杨树-微生物群落的相互关系、菌群进化搭建了研究模型。总之,深入认识多元微生物对林木表型和生理代谢的表观遗传学调控机制将为今后创制新型菌剂并用于高效育苗和抗性育种提供新的思路,具有重要的科学意义和应用价值。     

茶树种子发育过程的转录组分析

该研究以‘铁观音’茶树品种的种子为试验材料,采用转录组测序技术分析种子发育的3个时期(幼果期、膨大期、成熟期)的表达差异,探究茶树种子油脂代谢的分子机制。结果表明:(1)经转录组测序、组装后共获得30 940 581个clean reads,经数据合并拼接最终得到36 951条非冗余Unigene序列,其中28 476个Unigene可得到功能注释;在转录本中能够被注释到GO分类的Unigene有11 201条(30.3%),KEGG分析发现共有17 172个基因参与了127个代谢通路。(2)经KEGG通路筛选出14条与脂肪酸代谢相关的通路,且随着茶籽的发育,大部分脂肪酸调控途径相关基因呈下调趋势,其中上调基因数最多的有α-亚麻酸代谢途径和脂肪酸降解途径(有17个基因表达量上调),下调基因数最多的是甘油磷脂代谢途径(有58个基因表达量下调);在茶籽发育幼果期α-亚麻酸代谢途径中表达量上调的基因数超过表达量下调的基因数。(3)研究发现茶籽脂肪酸合成相关的基因涉及14个脂类调控途径,共409条差异基因;随着茶树种子发育到成熟期,上调的差异表达基因数量在减少,下调的差异表达基因数量增加,其中α-亚麻酸途径中的基因PLA2G16、DAD1、pldA、FabF、FabI表达量上调显著,随后表达量下调。(4)qRT-PCR检测结果表明,7个茶树FAD和1个ACP差异表达基因的水平与转录组测序结果基本一致;随着茶籽的发育,基因CsFAD7和Δ6-CsFAD从幼果期、果实膨大期至果实成熟期都为差异下调表达,CsFAD2、CsFAD6和Δ7-CsFAD为差异上调表达,CsFAD8、Δ8-CsFAD和CsACP在幼果期至果实膨大期差异上调表达,在果实膨大期至果实成熟期差异下调表达。