Dual targeting of Myxococcus xanthus protoporphyrinogen oxidase into chloroplasts and mitochondria and high level oxyfluorfen resistance

Much attention has been paid to the signal sequences of eukaryotic protoporphyrinogen oxidases (protoxes); both the organelles targeted by protoxes and the role of protoxes in conferring resistance against protox‐inhibiting herbicides, such as oxyfluorfen, have been examined. However, there have been no reports on the translocation of prokaryotic protoxes. This study investigated the targeting ability of Myxococcus xanthus protox in vitro and in vivo. In an in vitro translocation assay using a dual import system, M. xanthus protein was detected in chloroplasts and mitochondria, suggesting that the M. xanthus protox protein was targeted into both organelles. In order to confirm the in vitro dual targeting ability of M. xanthus, we used a stable transgenic strategy to investigate dual targeting in vivo. In transgenic rice plants overexpressing M. xanthus protox, M. xanthus protox antibody cross‐reacted with proteins with predicted molecular masses of 50 kDa from both chloroplasts and mitochondria, and this in vivo transgene expression corresponded to a prominent increase in chloroplastic and mitochondrial protox activity. Seeds from the transgenic lines M4 and M7 germinated in solid Murashige and Skoog media of up to 500 µm of oxyfluorfen, whereas wild‐type seeds did not germinate in 1 µm . After 4‐week‐old‐rice plants were treated with oxyfluorfen for 3 d, lines M4 and M7 exhibited normal growth, whereas the wild‐type line was severely bleached and necrotized. The herbicidal resistance is attributed to the insignificant accumulation of photodynamic protoporphyrin IX in cytosol because the high chloroplastic and mitochondrial protox activity in oxyfluorfen‐treated transgenic lines, compared with that in oxyfluorfen‐treated and untreated wild‐type plants, metabolizes protoporphyrinogen IX to chlorophyll and heme. A practical application of the dual targeting of M. xanthus protox for obtaining outstanding resistance to peroxidizing herbicides is discussed.     

Evidence for extensive gene flow and Thermotoga subpopulations in subsurface and marine environments

Oil reservoirs represent a nutrient-rich ecological niche of the deep biosphere. Although most oil reservoirs are occupied by microbial populations, when and how the microbes colonized these environments remains unanswered. To address this question, we compared 11 genomes of Thermotoga maritima-like hyperthermophilic bacteria from two environment types: subsurface oil reservoirs in the North Sea and Japan, and marine sites located in the Kuril Islands, Italy and the Azores. We complemented our genomes with Thermotoga DNA from publicly available subsurface metagenomes from North America and Australia. Our analysis revealed complex non-bifurcating evolutionary history of the isolates'' genomes, suggesting high amounts of gene flow across all sampled locations, a conjecture supported by numerous recombination events. Genomes from the same type of environment tend to be more similar, and have exchanged more genes with each other than with geographically close isolates from different types of environments. Hence, Thermotoga populations of oil reservoirs do not appear isolated, a requirement of the ‘burial and isolation'' hypothesis, under which reservoir bacteria are descendants of the isolated communities buried with sediments that over time became oil reservoirs. Instead, our analysis supports a more complex view, where bacteria from subsurface and marine populations have been continuously migrating into the oil reservoirs and influencing their genetic composition. The Thermotoga spp. in the oil reservoirs in the North Sea and Japan probably entered the reservoirs shortly after they were formed. An Australian oil reservoir, on the other hand, was likely colonized very recently, perhaps during human reservoir development.     

基因工程改善植物生物质能利用的研究进展

利用植物木质纤维资源发酵产乙醇越来越受到人们的重视,但是要达到工业生产仍然存在很多难题。最近在利用植物基因工程技术改善植物自身性状,以利于能源植物的研究方面取得了一定的进展,这些研究包括减少植物自身细胞壁中的木质素含量、细胞中积累表达纤维素酶和木聚耱酶等的方法,使产生的生物质更利于降解利用。     

A role for synaptonemal complex in meiotic mismatch repair

A large subset of meiotic recombination intermediates form within the physical context of synaptonemal complex (SC), but the functional relationship between SC structure and homologous recombination remains obscure. Our prior analysis of strains deficient for SC central element proteins demonstrated that tripartite SC is dispensable for interhomolog recombination in Saccharomyces cerevisiae. Here, we report that while dispensable for recombination per se, SC proteins promote efficient mismatch repair at interhomolog recombination sites. Failure to repair mismatches within heteroduplex-containing meiotic recombination intermediates leads to genotypically sectored colonies (postmeiotic segregation events). We discovered increased postmeiotic segregation at THR1 in cells lacking Ecm11 or Gmc2, or in the SC-deficient but recombination-proficient zip1[Δ21-163] mutant. High-throughput sequencing of octad meiotic products furthermore revealed a genome-wide increase in recombination events with unrepaired mismatches in ecm11 mutants relative to wildtype. Meiotic cells missing Ecm11 display longer gene conversion tracts, but tract length alone does not account for the higher frequency of unrepaired mismatches. Interestingly, the per-nucleotide mismatch frequency is elevated in ecm11 when analyzing all gene conversion tracts, but is similar between wildtype and ecm11 if considering only those events with unrepaired mismatches. Thus, in both wildtype and ecm11 strains a subset of recombination events is susceptible to a similar degree of inefficient mismatch repair, but in ecm11 mutants a larger fraction of events fall into this inefficient repair category. Finally, we observe elevated postmeiotic segregation at THR1 in mutants with a dual deficiency in MutSγ crossover recombination and SC assembly, but not in the mlh3 mutant, which lacks MutSγ crossovers but has abundant SC. We propose that SC structure promotes efficient mismatch repair of joint molecule recombination intermediates, and that absence of SC is the molecular basis for elevated postmeiotic segregation in both MutSγ crossover-proficient (ecm11, gmc2) and MutSγ crossover-deficient (msh4, zip3) strains.     

水牛、大额牛和牦牛抑制素α亚基编码基因外显子1多态性分析

为了揭示牛科物种INHA基因的遗传特征,该文采用PCR产物直接测序法对水牛、大额牛和牦牛INHA基因外显子1及其侧翼序列进行多态性检测,并结合已发表的包括牛科物种在内的一些哺乳动物数据进行了比较分析。结果表明,在水牛INHA基因外显子1中存在c.73C>A替换,为同义替换,河流型和沼泽型水牛编码产物一致;在大额牛的INHA基因外显子1中发现c.62C>T、c.187G>A替换,分别引起INHA中氨基酸发生p.P21L、p.V63M改变,两者均为相同性质氨基酸的替换;在牦牛中发现c.62C>T、c.129A>G替换,前者也引起编码氨基酸发生p.P21L替换,后者为同义替换。在INHA基因5’侧翼区所测出的序列中,水牛、大额牛和牦牛等物种内均未发现SNP位点,但在种间发现存在c.-6T>G的替换,大额牛、牦牛和普通牛均为c.-6G,而水牛为c.-6T。在INHA基因内含子中,水牛的第31～36位核苷酸处发现有6个碱基的缺失,即c.262+31₂62+36delTCTGAC;该位点在河流型水牛中野生型（+/+）占主体,而在沼泽型水牛中则缺失型（-/-）占主体。在大额牛、牦牛和普通牛等其它牛科物种的内含子中均未发现该缺失,但与水牛相比,大额牛、牦牛和普通牛内含子中发现缺失c.262+78₂62+79delTG。序列比对显示,INHA基因外显子1序列中c.43A和c.67G为水牛中所特有,而c.173A和c.255G为大额牛、牦牛和普通牛所共有,c.24C、c.47G、c.174T和c.206T为山羊所特有。大额牛、牦牛和普通牛间INHA基因外显子1序列差异较小,而山羊和水牛与它们间的差异相对较大。     

狭果茶藨子果实多糖提取及其抗氧化和流变特性

以狭果茶藨子果实为原料,多糖提取量为考察指标,通过单因素试验及响应面试验对多糖提取工艺进行优化,结果表明最佳多糖制备工艺条件为:提取温度40℃,时间30 min,料液比1∶30 g/mL,此时狭果茶藨子中多糖提取量达115.32 mg/g;流变学特性研究表明狭果茶藨子果实多糖溶液属于非牛顿流体,多糖溶液表现出剪切稀化的现象,当多糖质量浓度为1.0%时,其流变学特性与0.1%的羧甲基纤维素钠溶液相似,且过酸、过碱的环境均不会改变狭果茶藨子果实多糖溶液的流变学特性;抗氧化试验结果表明狭果茶藨子果实多糖具有潜在的抗氧化能力,对DPPH自由基的清除能力低于抗坏血酸,而对羟自由基的清除能力显著高于抗坏血酸。本研究结果可为狭果茶藨子果实多糖在食品领域的开发利用提供理论依据。     

隐喻加工复合模式的ERP研究

本研究使用S1→S2范式研究中国人大脑隐喻加工模式是否与"等级显性理论"一致。被试对隐喻匹配任务和不相关匹配模式进行"是"和"否"隐喻的判断,同时脑电设备记录他们进行任务加工时的事件相关电位(ERP)。通过对相关电极N400的分析发现,右脑加工两个任务时,激活程度呈递增的趋势,与"等级显性理论"一致。另外,两个任务中顶叶空间加工区参与程度的差异说明,隐喻意义的整合需要对相似性、熟悉度等确定后再进行空间联系。     

SUMO Localizes to the Central Element of Synaptonemal Complex and Is Required for the Full Synapsis of Meiotic Chromosomes in Budding Yeast

The synaptonemal complex (SC) is a widely conserved structure that mediates the intimate alignment of homologous chromosomes during meiotic prophase and is required for proper homolog segregation at meiosis I. However, fundamental details of SC architecture and assembly remain poorly understood. The coiled-coil protein, Zip1, is the only component whose arrangement within the mature SC of budding yeast has been extensively characterized. It has been proposed that the Small Ubiquitin-like MOdifier, SUMO, plays a role in SC assembly by linking chromosome axes with Zip1''s C termini. The role of SUMO in SC structure has not been directly tested, however, because cells lacking SUMO are inviable. Here, we provide direct evidence for SUMO''s function in SC assembly. A meiotic smt3 reduction-of-function strain displays reduced sporulation, abnormal levels of crossover recombination, and diminished SC assembly. SC structures are nearly absent when induced at later meiotic time points in the smt3 reduction-of-function background. Using Structured Illumination Microscopy we furthermore determine the position of SUMO within budding yeast SC structure. In contrast to previous models that positioned SUMO near Zip1''s C termini, we demonstrate that SUMO lies at the midline of SC central region proximal to Zip1''s N termini, within a subdomain called the “central element”. The recently identified SUMOylated SC component, Ecm11, also localizes to the SC central element. Finally, we show that SUMO, Ecm11, and even unSUMOylatable Ecm11 exhibit Zip1-like ongoing incorporation into previously established SCs during meiotic prophase and that the relative abundance of SUMO and Ecm11 correlates with Zip1''s abundance within SCs of varying Zip1 content. We discuss a model in which central element proteins are core building blocks that stabilize the architecture of SC near Zip1''s N termini, and where SUMOylation may occur subsequent to the incorporation of components like Ecm11 into an SC precursor structure.