XeCl（308nm）准分子紫外激光对生物大分子酵母甘露聚糖分子结构的辐照效应

激光在农业和医疗等方面已有广泛应用,并且取得增产和一定疗效,但也有费介现象(暂称后继效应或潜在效应).激光辐照生物体虽然是局部的有限时间,但对由多种生物大分子组成的牛物体的影响可能是综合的.为了探索激光生物学效应的分子机理,以便进一步认识和掌握激光的生物学效应,对激光直接辐照有生物活性的生物大分子一酵母甘露聚糖产生的效应进行电镜扫描观察和紫外及红外光谱法分析研究.实验结果表明:308 nm 激光(单脉冲25 mJ,33.3 ml-34.4 ml,脉冲频率2次/s)无论是固定辐照时间(45 s)变化样晶所置距离,或反之固定样品所置距离(290 mm)改变辐照时广开J为15 s、30 s、45 s或60 s,都能引起受照样品的结构(构象)变化,特别足糖分子结构中富含的-OH、-CH-OH、-C-O-c-、-N-C=0、-C=0等结构部件处的IR谱线对激光能最变化影响敏感.它们既是糖分子内或分子间形成氧键和糖苷键的结构基础部件,又是甘露聚糖(Man-nan)糖基化其他生物大分子进而影响它们在生物信息流中作用的重要结构部件.结果显示糖在激光牛物效应中起了不可忽视的作用,这为综合探索激光生物效应分子机理和糖在生物信息传递中的作用提供了重要线索,为选择甘露聚糖作为生物导弹载体提供了参考依据.     

Cyanochromes Are Blue/Green Light Photoreversible Photoreceptors Defined by a Stable Double Cysteine Linkage to a Phycoviolobilin-type Chromophore

Phytochromes are a collection of bilin-containing photoreceptors that regulate a diverse array of processes in microorganisms and plants through photoconversion between two stable states, a red light-absorbing Pr form, and a far red light-absorbing Pfr form. Recently, a novel set of phytochrome-like chromoproteins was discovered in cyanobacteria, designated here as cyanochromes, that instead photoconvert between stable blue and green light-absorbing forms Pb and Pg, respectively. Here, we show that the distinctive absorption properties of cyanochromes are facilitated through the binding of phycocyanobilin via two stable cysteine-based thioether linkages within the cGMP phosphodiesterase/adenyl cyclase/FhlA domain. Absorption, resonance Raman and infrared spectroscopy, and molecular modeling of the Te-PixJ GAF (cGMP phosphodiesterase/adenyl cyclase/FhlA) domain assembled with phycocyanobilin are consistent with attachments to the C3¹ carbon of the ethylidene side chain and the C4 or C5 carbons in the A–B methine bridge to generate a double thioether-linked phycoviolobilin-type chromophore. These spectroscopic methods combined with NMR data show that the bilin is fully protonated in the Pb and Pg states and that numerous conformation changes occur during Pb → Pg photoconversion. Also identified were a number of photochromically inactive mutants with strong yellow or red fluorescence that may be useful for fluorescence-based cell biological assays. Phylogenetic analyses detected cyanochromes capable of different signaling outputs in a wide range of cyanobacterial species. One unusual case is the Synechocystis cyanochrome Etr1 that also binds ethylene, suggesting that it works as a hybrid receptor to simultaneously integrate light and hormone signals.Phytochromes (Phys)³ comprise a large and diverse superfamily of photoreceptors that regulate a wide range of physiological responses in plants, fungi, bacteria, and cyanobacteria (1–3). They are unique among photoreceptors by being able to photoconvert between two stable states, a red light-absorbing Pr form that is typically the dark-adapted and biologically inactive conformer and a far-red light-absorbing Pfr form that requires light for its production and is typically the biologically active conformer. By interconverting between Pr and Pfr, Phys act as light-regulated switches in controlling processes ranging from phototaxis and pigmentation in bacteria to seed germination, photomorphogenesis, and flowering time in higher plants.Light absorption by Phys is directed by a bilin (or linear tetrapyrrole) chromophore produced by the oxidative cleavage of heme. Although bacterial and fungal Phys use the immediate cleavage product biliverdin (BV), cyanobacterial and higher plant Phys use phycocyanobilin (PCB) and phytochromobilin, respectively, produced by enzymatic reduction of BV (1, 2). The bilin is then covalently bound autocatalytically to the photosensory unit of the apoprotein, which typically contains a sequence of Per/Arndt/Sim (PAS), cGMP phosphodiesterase/adenyl cyclase/FhlA (GAF), and Phy-associated (PHY) domains. Intimate contact between the bilin and surrounding protein residues then generates the unique photochromic properties of Phys. Recent three-dimensional structures of the Pr form of several bacterial Phys (BphPs) and two cyanobacterial Phys (Cphs) have shown that the bilin is deeply buried within the GAF domain in a ZZZssa configuration and that the connection between the GAF and PAS domains is stabilized by a rare figure-of-eight knot involving the region upstream of the PAS domain being lassoed by a conserved loop within the GAF domain (4–9). Although the structure of Pfr remains unsolved, various physicochemical studies have proposed that photoconversion involves a rotation of one of the three methine bridges between the pyrrole rings (1, 10–14). This rotation then induces much slower thermally driven movements of the protein to initiate signal transduction.In microorganisms, Pfr can activate a variety of signaling systems using output motifs directly appended to the C-terminal end of the photosensory region. The most prevalent are histidine kinase domains that then begin specific two-component phosphorelays (3, 15, 16). Although the output of plant Phys remains unclear, the presence of a C-terminal HK-related domain suggests that they also work as light-regulated protein kinases (17).In addition to the canonical Phys, it has become apparent through phylogenetic and biochemical studies that a heterogeneous collection of Phy-like photoreceptors exists (e.g. Refs. 3 and 18). These include Phys that prefer Pfr as the dark-adapted state (7, 19, 20), Phys that photoconvert from Pr to shorter wavelength-absorbing “near red” or Pnr forms (6, 21), and Phy-like photoreceptors that bind bilins but instead photoconvert between forms with maximal absorption other than red and far-red light (22–25). Often these Phy-like sequences are missing key residues or domains common among canonical Phys, suggesting that they employ novel bilins as chromophores, bind the bilin in different architectures, and/or use distinct photochemistries.One subclass of novel Phy-like photoreceptors present in a number of cyanobacteria, which we have designated cyanochromes (or Cycs) to better distinguish them from Cphs, is exemplified by Synechocystis sp. PCC6803 (Syn) PixJ (or TaxD1, locus sll0041) and its relatives. Syn-PixJ was discovered based on its involvement in blue light-mediated phototaxis in this mesophilic cyanobacterium (26, 27) with its close homolog Te-PixJ (locus tll0569) then found in the thermophilic cyanobacterium Thermosynechococcus elongatus BP-1 by sequence similarity (28). Like Cphs, the cyanochromes tested thus far covalently bind PCB but then generate photoreceptors that convert between blue and green light-absorbing forms designated Pb and Pg, respectively (22, 24, 29). Subsequent studies proposed that PCB is converted to phycoviolobilin (PVB) upon attachment to the apoprotein (30). PVB differs from PCB by having a methylene instead of a methine bridge between the A and B pyrrole rings, which blue-shifts the absorption of the chromophore by shortening the π-conjugation system. Phototransformation of Pb to Pg could then occur by a mechanism similar to Phys.How Te-PixJ and related cyanochromes bind PCB to generate more blue-shifted PVB-type chromophores remains unclear. Like Cphs, two cyanochromes examples link PCB via a thioether linkage between a cysteine in the Cyc-GAF domain and the C3¹ carbon of the ethylidene side chain of ring A (24, 28). Additionally, loss of the C4C5 double bond is necessary to generate PVB. One model by Ishizuka et al. (30) from studies with Te-PixJ proposed that the double bond moves from the C4-C5 position to the C2-C3 position by an autoisomerase activity intrinsic to the GAF domain. A more recent model by Rockwell et al. (24) using another Syn-PixJ relative in T. elongatus, Tlr0924, invoked the possibility of a second cysteine that also participates in PCB ligation. This cysteine was proposed to bind the bilin at the C10 position via a reversible thioether linkage. In the dark-adapted Pb state, the second linkage would then be formed to generate a rubin-like chromophore attached to the bridge between the B and C pyrrole rings. This bond would then break upon photoconversion to generate the more π-conjugated green light-absorbing photoproduct Pg.In this report, we employed a number of physicochemical approaches to help resolve the unique chromophore architecture and photochemical properties of cyanochromes, using Te-PixJ as the example. By independently mutagenizing the cysteine that binds the A ring ethylidene (Cys-522 (22)) and that proposed by Rockwell et al. (24) to reversibly bind the bilin at a second site (Cys-494), we demonstrate that both residues form light-stable covalent adducts with a PVB-type chromophore. In addition, we employed various spectroscopic methods to show that the bound PVB is fully protonated as both Pb and Pg, that only one pyrrole ring is active during photoconversion, and that the polypeptide may undergo extensive remodeling as Pb converts to Pg. We identified a set of conserved amino acids in Te-PixJ important for cyanochrome photochemistry, including several that when substituted generate yellow or red fluorescent chromoproteins potentially useful for cell biological applications. Phylogenetic analyses show that cyanochromes are widespread among cyanobacteria with their closest relatives being members of the red/far-red light-absorbing Phy subfamily defined by the absence of the N-terminal PAS domain (31).     

鄂尔多斯东胜地区不同生态功能区的土壤侵蚀敏感性

利用ETM影像数据和GIS技术,对鄂尔多斯东胜地区进行生态功能分区.以水土流失通用方程 (universal soil loss equation, USLE) 理论为基础,并依据土壤侵蚀敏感性驱动力的相似性和差异性,分析了降水、土壤质地、地形和地表覆盖因子对该区域不同生态功能分区土壤侵蚀与水土流失敏感性的影响.研究结果表明:典型草原丘陵区土壤侵蚀敏感性指数SSj为4.2,典型草原平原区为4.0,典型草原沙化区为4.6,荒漠草原区土壤侵蚀敏感性指数为5.0;4个生态功能区的土地沙漠化都属于土地沙漠化高度敏感区,其由高到低的排序为荒漠草原区 > 典型草原沙化区 = 典型草原平原区 > 典型草原丘陵区;就土壤侵蚀程度而言,典型草原平原区属于土壤侵蚀轻度敏感区,荒漠草原区、典型草原沙化区、典型草原丘陵区属于土壤侵蚀中度敏感区.将其土壤侵蚀化程度由高到低排序:荒漠草原区 > 典型草原沙化区 > 典型草原丘陵区 > 典型草原平原区;就土壤盐渍化而言,典型草原丘陵区属于土地盐渍化不敏感区,其它3个区属于土地盐渍化轻度敏感区.在综合评价其土壤侵蚀敏感性区域差异基础上,阐述了鄂尔多斯东胜地区水土流失敏感性区域土地利用格局的调整与优化取向.     

四合木种群的生态适应性

通过四合木异地播种生长量比较、以及四合木对土壤的适应性和对水热综合因子的适应性分析,得到如下结果：（1）四合木生长量高低的顺序为乌海区的东胜土（12．12g）〉乌海区的乌海土（10．62g）〉东胜区的乌海土（3．10g）〉东胜区的东胜土（2．59g）。同一地区不同土壤间四合木生长量之间没有差异（P≥0．05）,不同地区相同土壤间的生长量之间却有十分显著的差异,说明了土壤条件对四合木的生存影响是次要的,气候条件是保证四合木生存的最重要的条件。（2）四合木分布区与异地保护区之间9种土壤微量元素具有差异,但由于四合木植株中的微量元素含量均高于土壤中的有效量,说明四合木对微量元素具有富集作用,土壤微量元素含量不是四合木成活与生长的限制因子。（3）四合木分布区与异地保护区之间各月平均温度差异显著;全年气温日较差以及温暖指数、寒冷指数、湿润指数和水热综合因子指数差异显著;生长季地表地温昼夜温差具有特殊性,这可能是异地保护不易成功的限制因子之一。     

外来种互花米草入侵模式与爆发机制

互花米草（Spartina alterniflora Loisel）因其促淤造陆和消浪护堤作用显著而被许多国家引种,如今却在侵入地快速蔓延并呈现爆发趋势,对生态系统造成了极大危害,被认为是研究生物入侵生态学和遗传学的模式植物。从种群的入侵力、生态系统可入侵性和入侵通道3个方面探讨互花米草的爆发机制,研究结果表明高遗传分化和基因渗入能力是互花米草爆发的遗传基础,对逆境的高抗性和强竞争力是其快速扩张的保障,而高繁殖系数是互花米草爆发的源泉。我国互花米草种群的早期扩散人为影响超过了自然过程,快速扩张呈现出点源扩散和多点爆发的特点,从而为其种群控制带来困难,同时种子的跳跃式和连续式扩散在互花米草种群维持、更新和爆发中有重要作用,强有力的克隆生长能力也为互花米草种群的连续扩张提供了保障。现阶段要完全控制和根除互花米草是不实际的,但在及时预测预警的基础上,应用成本一效益分析方法,采取有序控制和综合开发利用的策略,仍可望妥善解决互花米草入侵所带来的负面效应。     

鄱阳湖六种野鸭越冬行为及觅食策略

2019年10月-2020年1月和2020年10月-2021年1月,采用瞬时扫描法和焦点动物法对鄱阳湖区6种野鸭越冬行为和觅食策略进行了观察.结果 表明,6种野鸭最多的4种行为均为取食、休息、修整和运动.绿头鸭(Anas platyrhynchos)、赤麻鸭(Tadorna ferruginea)和针尾鸭(Anas a...     

RAC2-P38 MAPK-dependent NADPH oxidase activity is associated with the resistance of quiescent cells to ionizing radiation

Our recent study showed that quiescent G0 cells are more resistant to ionizing radiation than G1 cells; however, the underlying mechanism for this increased radioresistance is unknown. Based on the relatively lower DNA damage induced in G0 cells, we hypothesize that these cells are exposed to less oxidative stress during exposure. As a catalytic subunit of NADPH oxidase, Ras-related C3 botulinum toxin substrate 2 (RAC2) may be involved in the cellular response to ionizing radiation. Here, we show that RAC2 was expressed at low levels in G0 cells but increased substantially in G1 cells. Relative to G1 cells, the total antioxidant capacity in G0 phase cells increased upon exposure to X-ray radiation, whereas the intracellular concentration of ROS and malondialdehyde increased only slightly. The induction of DNA single- and double-stranded breaks in G1 cells by X-ray radiation was inhibited by knockdown of RAC2. P38 MAPK interaction with RAC2 resulted in a decrease of functional RAC2. Increased phosphorylation of P38 MAPK in G0 cells also increased cellular radioresistance; however, excessive production of ROS caused P38 MAPK dephosphorylation. P38 MAPK, phosphorylated P38 MAPK, and RAC2 regulated in mutual feedback and negative feedback regulatory pathways, resulting in the radioresistance of G0 cells.     

miR-300 regulates cellular radiosensitivity through targeting p53 and apaf1 in human lung cancer cells

microRNAs (miRNAs) play a crucial role in mediation of the cellular sensitivity to ionizing radiation (IR). Previous studies revealed that miR-300 was involved in the cellular response to IR or chemotherapy drug. However, whether miR-300 could regulate the DNA damage responses induced by extrinsic genotoxic stress in human lung cancer and the underlying mechanism remain unknown. In this study, the expression of miR-300 was examined in lung cancer cells treated with IR, and the effects of miR-300 on DNA damage repair, cell cycle arrest, apoptosis and senescence induced by IR were investigated. It was found that IR induced upregulation of endogenous miR-300, and ectopic expression of miR-300 by transfected with miR-300 mimics not only greatly enhanced the cellular DNA damage repair ability but also substantially abrogated the G2 cell cycle arrest and apoptosis induced by IR. Bioinformatic analysis predicted that p53 and apaf1 were potential targets of miR-300, and the luciferase reporter assay showed that miR-300 significantly suppressed the luciferase activity through binding to the 3′-UTR of p53 or apaf1 mRNA. In addition, overexpression of miR-300 significantly reduced p53/apaf1 and/or IR-induced p53/apaf1 protein expression levels. Flow cytomertry analysis and colony formation assay showed that miR-300 desensitized lung cancer cells to IR by suppressing p53-dependent G2 cell cycle arrest, apoptosis and senescence. These data demonstrate that miR-300 regulates the cellular sensitivity to IR through targeting p53 and apaf1 in lung cancer cells.     

河流输送硅通量降低的机制及生态效应

从筑坝成库、硅藻吸收和固定、渔业发展、水体富营养化、水文结构变化几方面对河流输送硅通量降低的影响机制进行了归纳分析,综述了河流输送硅通量降低对河流、河口和近海产生的生态效应。研究表明,河流输送硅通量降低对硅的地球化学循环平衡产生了巨大影响,并造成了一系列的生态变迁。其中,硅藻是河流输送硅通量降低的主要因素,大量繁殖的硅藻将水库水体溶解性硅(DSi)吸收后转化成自身的生物硅(BSi),死亡后沉积到水库底部贮存起来,导致下游河流和海洋缺乏DSi,从而产生对人类具有重大影响的生态效应。