Quantitative and time-course analysis of microbial degradation of 1H,1H,2H,2H,8H,8H–perfluorododecanol in activated sludge

A methylene group in the fluorinated carbon backbone of 1H,1H,2H,2H,8H,8H–perfluorododecanol (degradable telomer fluoroalcohol, DTFA) renders the molecule cleavable by microbial degradation into two fluorinated carboxylic acids. Several biodegradation products of DTFA are known, but their rates of conversion and fates in the environment have not been determined. We used liquid chromatography coupled with tandem mass spectrometry (LC/MS/MS) to quantitatively investigate DTFA biodegradation by the microbial community in activated sludge in polyethylene terephthalate (PET) flasks, which we also determined here showed least adsorption of DTFA. A reduction in DTFA concentration in the medium was accompanied by rapid increases in the concentrations of 2H,2H,8H,8H–perfluorododecanoic acid (2H,2H,8H,8H–PFDoA), 2H,8H,8H-2-perfluorododecenoic acid (2H,8H,8H-2-PFUDoA), and 2H,2H,8H-7-perfluorododecenoic acid and 2H,2H,8H-8-perfluorododecenoic acid (2H,2H,8H-7-PFUDoA/2H,2H,8H-8-PFUDoA), which were in turn followed by an increase in 6H,6H–perfluorodecanoic acid (6H,6H–PFDeA) concentration, and decreases in 2H,2H,8H,8H–PFDoA, 2H,8H,8H-2-PFUDoA, and 2H,2H,8H-7-PFUDoA/2H,2H,8H-8-PFUDoA concentrations. Accumulation of perfluorobutanoic acid (PFBA), a presumed end product of DTFA degradation, was also detected. Our quantitative and time-course study of the concentrations of these compounds reveals main routes of DTFA biodegradation, and the presence of new biodegradation pathways.

     

H2S人工诱导小鼠冬眠成功

H2S是一种公认的毒性气体,但最近发现其是神经、心血管等系统功能调节的新型气体信号分子。BlackstoneE等在Science杂志上报道:将小鼠暴露于80ppm(80mg/m3)的H2S中,五分钟小鼠的氧消耗下降50%,CO2的排出量下降60%,暴露6小时,代谢率下降90%,中心体温下降到比周围环境温度高2℃。在最低体温时,CO2的排出量及氧的消耗仅为正常时的10%,且小鼠的呼吸频率从120次/分降到10次/分。将小鼠暴露于不同浓度的H2S(0ppm～80ppm),H2S呈浓度依赖性抑制中心体温,且代谢率的降低不依赖于周围环境的温度。在80ppm的H2S条件下暴露6小时后回到正常环境下,…     

H2O2介导的H2S产生参与干旱诱导的拟南芥气孔关闭

以野生型拟南芥(Arabidopsis thaliana)及其突变体(atrbohD、atrbohF、atrbohD/F、atl-cdes、atd-cdes)和过表达株系(OEL-CDes、OED-CDes)为材料,利用药理学实验,结合分光光度法和激光共聚焦显微技术,探讨硫化氢(hydrogen sulfide,H2S)在干旱诱导的拟南芥气孔关闭中的作用及其与过氧化氢(hydrogen peroxide,H2O2)的关系.结果表明,H2S清除剂次牛磺酸(hypotaurine,HT)及合成抑制剂氨氧基乙酸(aminooxy acetic acid,AOA)、羟胺(hydroxylamine,NH2OH)和丙酮酸钾(potasium pyruvate,C3H3KO3)+氨水(ammonia,NH3)均可不同程度抑制干旱诱导的气孔关闭;干旱对OEL-CDes和OED-CDes植株气孔关闭的诱导作用明显,而atl-cdes和atd-cdes叶片气孔对干旱胁迫反应的敏感性下降;干旱胁迫能明显增加拟南芥保卫细胞中H2O2水平及叶片中H2S含量,提高D-/L-半胱氨酸脱巯基酶活性及基因表达量,而对突变体atrbohD、atrbohF和atrbohD/F没有显著影响.清除H2O2可减弱干旱胁迫对H2S含量和D-/L-半胱氨酸脱巯基酶活性的诱导效应.研究结果表明H2S位于H2O2下游参与干旱诱导拟南芥气孔关闭的信号转导过程.     

H2O2介导的H2S产生参与干旱诱导的拟南芥气孔关闭

以野生型拟南芥(Arabidopsis thaliana)及其突变体(atrbohD、atrbohF、atrbohD/F、atl-cdes、atd-cdes)和过表达株系(OEL-CDes、OED-CDes)为材料, 利用药理学实验, 结合分光光度法和激光共聚焦显微技术, 探讨硫化氢(hydrogen sulfide, H₂S)在干旱诱导的拟南芥气孔关闭中的作用及其与过氧化氢(hydrogen peroxide, H₂O₂)的关系。结果表明, H₂S清除剂次牛磺酸(hypotaurine, HT)及合成抑制剂氨氧基乙酸(aminooxy acetic acid, AOA)、羟胺(hydroxylamine, NH₂OH)和丙酮酸钾(potasium pyruvate, C₃H₃KO₃)+氨水(ammonia, NH₃)均可不同程度抑制干旱诱导的气孔关闭; 干旱对OEL-CDes和OED-CDes植株气孔关闭的诱导作用明显, 而atl-cdes和atd-cdes叶片气孔对干旱胁迫反应的敏感性下降; 干旱胁迫能明显增加拟南芥保卫细胞中H₂O₂水平及叶片中H₂S含量, 提高D-/L-半胱氨酸脱巯基酶活性及基因表达量, 而对突变体atrbohD、atrbohF和atrbohD/F没有显著影响。清除H₂O₂可减弱干旱胁迫对H₂S含量和D-/L-半胱氨酸脱巯基酶活性的诱导效应。研究 结果表明H₂S位于H₂O₂下游参与干旱诱导拟南芥气孔关闭的信号转导过程。     

H2S在植物抗逆中的作用研究进展

综述了H2S在植物体内的产生途径及其在植物抗逆中的作用。越来越多的证据表明在动物体内,H2S是人们发现的第3种气体信号分子,但对植物体内的H2S的研究较少。     

中枢神经系统H2S的作用及机制研究进展

中枢神经系统内源性硫化氢 (H2 S)主要由胱硫醚 β 合酶合成。脑内H2 S对中枢神经系统多种生理和病理过程有重要的影响 :(1)H2 S通过cAMP途径 ,易化海马长时程增强的产生 ;(2 )H2 S通过下丘脑 垂体 肾上腺轴来参与神经内分泌功能的调节 ;(3)H2 S协同一氧化氮松弛脑血管平滑肌 ,从而调节血压。此外 ,H2 S还与脑血管损害、多种遗传性疾病的脑功能障碍有关     

Ca2+位于H2O2上游参与H2S诱导的拟南芥气孔关闭过程

以拟南芥为材料,利用药理学实验,结合分光光度法和激光共聚焦显微技术,研究了Ca2+在硫化氢(H2S)诱导拟南芥气孔关闭过程中的作用及其与过氧化氢(H2O2)的关系。结果表明： H2S诱导气孔关闭, Ca2+螯合剂EGTA和质膜Ca2+通道阻断剂硝苯地平(Nif)能不同程度抑制H2S诱导的气孔关闭,而内质网钙泵阻断剂毒胡萝卜素(Thaps)对H2S的作用无显著影响。由此推测, Ca2+参与调节H2S诱导的拟南芥气孔关闭过程,且胞质中Ca2+来源于胞外Ca2+的内流。另外, H2S诱导拟南芥叶片NADPH氧化酶基因AtRBOHD和AtRBOHF以及细胞壁过氧化物酶基因AtPRX34表达增强,促进叶片和保卫细胞中H2O2积累, EGTA对此起抑制作用,而外源CaCl2处理上调AtRBOHD、AtRBOHF和AtPRX34的表达。表明Ca2+可能位于H2O2上游参与H2S诱导的拟南芥气孔关闭过程。     

H2S可能作为H2O2的下游信号介导茉莉酸诱导的蚕豆气孔关闭

以蚕豆（Vicia faba）为材料,利用激光共聚焦显微技术和分光光度技术,结合药理学实验,探讨硫化氢（hydrogen sulphide,H2S）和过氧化氢（hydrogen peroxide,H2O2）在茉莉酸（jasmonic acid,JA）调控气孔运动信号转导中的作用。结果表明,H2S合成抑制剂氨氧基乙酸（aminooxy acetic acid,AOA）、羟胺（hydroxylamine,NH2OH）、丙酮酸钾（potasium py-ruvate,C3H3KO3）和氨水（ammonia,NH3）,H2O2清除剂抗坏血酸（ascorbic acid,AsA）,合成抑制剂水杨羟肟酸（salicylhydroxamic acid,SHAM）、二苯基碘（diphenylene iodonium,DPI）均可逆转JA诱导的气孔关闭效应。JA能够明显提高蚕豆叶片及保卫细胞中的H2O2水平、H2S含量和L-/D-半胱氨酸脱巯基酶活性;H2S合成抑制剂可抑制JA引起的叶片H2S含量的增加;而H2O2清除剂则可减弱JA对H2S含量变化和L-/D-半胱氨酸脱巯基酶活性的诱导效应。以上结果表明H2S和H2O2均参与了JA诱导的蚕豆气孔关闭,且H2S（主要由L-/D-半胱氨酸脱巯基酶合成）可能作为H2O2的下游组分参与调控这一信号转导过程。     

How relevant are S=O and P=O Double Bonds for the Description of the Acid Molecules H2SO3, H2SO4, and H3PO4, respectively?

The acid molecules H₂SO₃, H₂SO₄, and H₃PO₄ are usually drawn using "Lewis structures" which exhibit the octet extension by 3d-orbitals on sulfur and phosphorus, respectively. Thus, S=O and P=O double bonds are assumed to be formed. The natural d-orbital occupancies on S and P, however, were calculated to be as low as 0.1 e, and therefore, an octet extension can hardly be expected. After the natural bond orbitals (NBO) search procedure was forced to attempt to form different Lewis structures of bonds and lone pairs, we defined the optimal Lewis structure, if a dominant structure exists at all, by the maximum electronic charge in Lewis orbitals. Indeed, sulfur obeys the octet rule in the optimal zwitterionic Lewis structures and does not form S=O double bonds. No dominant resonance structure could be found for H₃PO₄ where polarized PO ?-bond and zwitterionic PO bond structures exhibit similar weights.     

内源性H2S --一种新的气体信号分子

20世纪90年代中期,发现半胱氨酸代谢生成气体分子硫化氢（H2S）,对神经系统特别是海马的功能具有调节作用,并可以调节消化道和血管平滑肌的张力,而其作用特点有别于另外两种气体信号分子NO及CO,但H2S的信号转导途径一直未能阐明,直到最近研究证实,内源性H2S直接作用于KATP通道实现对血管的调节作用;而且可以刺激神经细胞cAMP水平增加,提高NMDA受体介导的突触后兴奋性电位,提高诱导海马长时程增强。越来越多的证明表明,内源性H2S是一种新的气体信号分子,对其研究是当前生物学领域的崭新课题,具有重要的理论和临床意义。     

外源性H2S恢复缺氧后适应对衰老H9C2细胞的保护作用及机制

目的：探讨外源性硫化氢（H₂S）恢复缺氧后适应对衰老H9C2细胞的保护作用及相关机制。方法：H9C2细胞（心肌细胞系）用30 μmol/L过氧化氢（H₂O₂）处理2 h后再培养3 d,诱导生成衰老细胞。衰老H9C2细胞被随机分5组（n=8）：正常组（Control）、缺氧/复氧组（H/R）、H/R+NaHS组、缺氧后适应（PC）组、PC+NaHS组。缺氧/复氧（H/R）模型：衰老H9C2细胞用缺氧液（无血清、无糖培养基,pH=6.8）培养3 h,然后正常培养6 h;缺氧后适应（PC）模型：方法同H/R模型,缺氧结束复氧前连续进行3次5 min间隔的复氧/再缺氧处理,随后复氧6 h。ELISA试剂盒分别检测大鼠晚期糖基化终末产物（AGEs）含量和caspase-3活性;CCK-8试剂盒检测细胞活力;DCFH-DA染色检测活性氧（ROS）水平;Hoechst 33342染色检测细胞凋亡率;Real-time PCR检测相关基因mRNA水平。结果：30 μmol/L H₂O₂可诱导H9C2细胞衰老但不会导致其凋亡;与Control组比较,H/R和PC均降低细胞活力,增加细胞凋亡率、ROS水平及caspase-3、caspase-9和Bcl-2 mRNA水平（P<0.01）;且PC组与H/R组比较,上述指标变化无明显差异;在H/R和PC组加入NaHS,可显著提高细胞活力,降低细胞凋亡率和氧化应激;PC+NaHS对上述指标的作用明显强于H/R+NaHS。结论：外源性H₂S能够恢复PC对衰老H9C2细胞的保护作用,其机制与抑制氧化应激和细胞凋亡有关。     

H2S巯基化修饰蛋白质调节谷子响应逆境胁迫

气体信号分子硫化氢（H2S）通过对蛋白质巯基化修饰参与动物体内许多重要的生理活动,但是在植物中该方面的报道甚少. 本论文证明,H2S信号提高蛋白质的巯基化水平参与谷子（foxtail millet）对低温、高温、盐、渗透和紫外胁迫的响应. 用5种方式4℃、42℃、NaCl、PEG和UV处理,引起谷子H2S产生速率和内源H2S含量的升高. 实时荧光定量PCR检测上述5种处理后谷子幼苗H2S产生酶基因Lcd1、Lcd2、Dcd1、Dcd2和Des的表达,Lcd1受盐、低温和渗透胁迫诱导;Lcd2受高温、低温和渗透胁迫诱导;Dcd1受盐诱导;Dcd2和Des受低温诱导;UV处理后5个酶基因表达均下降. Western 印迹检测表明,外源H2S熏蒸和5种胁迫处理引起谷子幼苗蛋白质巯基化水平升高. 上述结果证明,H2S信号通过提高蛋白质的巯基化水平参与谷子对低温、高温、盐、渗透和紫外胁迫的响应.     

Abiotic stress-triggered oxidative challenges: Where does H2S act?

Hydrogen sulfide (H₂S) was once principally considered the perpetrator of plant growth cessation and cell death. However, this has become an antiquated view, with cumulative evidence showing that the H₂S serves as a biological signaling molecule notably involved in abiotic stress response and adaptation, such as defense by phytohormone activation, stomatal movement, gene reprogramming, and plant growth modulation. Reactive oxygen species (ROS)-dependent oxidative stress is involved in these responses. Remarkably, an ever-growing body of evidence indicates that H₂S can directly interact with ROS processing systems in a redox-dependent manner, while it has been gradually recognized that H₂S-based posttranslational modifications of key protein cysteine residues determine stress responses. Furthermore, the reciprocal interplay between H₂S and nitric oxide (NO) in regulating oxidative stress has significant importance. The interaction of H₂S with NO and ROS during acclimation to abiotic stress may vary from synergism to antagonism. However, the molecular pathways and factors involved remain to be identified. This review not only aims to provide updated information on H₂S action in regulating ROS-dependent redox homeostasis and signaling, but also discusses the mechanisms of H₂S-dependent regulation in the context of oxidative stress elicited by environmental cues.     

H2S作为植物个体间交流的气体信号分子

植物遭受到昆虫取食、创伤及非生物胁迫时,会向环境中释放多种挥发性物质,直接或间接地帮助受胁迫植株抵抗伤害。同时,这些挥发性物质向附近的健康植株传递信息,以应对可能到来的侵害。硫化氢(H2S)作为细胞内气体信号分子提高植物对多种胁迫的抗性已有报道,本论文对H2S是否作为植物个体间传递信息的信号分子进行了研究。结果表明:40%PEG8000处理可以使谷子、白菜、番茄和拟南芥Col-0植株所在环境空气中H2S含量升高;谷子和拟南芥Col-0植株经PEG8000处理后,可以使邻近的非胁迫植株叶片的H2S含量升高和H2S响应基因表达变化,并诱导非胁迫植株气孔关闭;而拟南芥内源H2S产生酶基因LCD和DES1双基因突变体lcd/des1经PEG8000处理,不能引起空气中和邻近植物的H2S含量升高,不能诱导邻近植株气孔关闭。本论文表明,H2S可以作为植物个体间的信息传递分子;即受胁迫植物通过向周围环境中释放H2S,向邻近植株提供胁迫预警信息,可能对种群的生存有重要意义。     

Antitubercular activity of α,ω-diaminoalkanes,H2N(CH2)nNH2

A series of 11 α,ω-diaminoalkanes, (H₂N(CH₂)_nNH₂, n = 2–12) have been evaluated for their in vitro antibacterial activity against Mycobacterium tuberculosis H37Rv. Compounds, (H₂N(CH₂)_nNH₂, n = 9–12), exhibited a very good activities in the range 2.50–3.12 μg/mL, which can be compared with that of the first line drug, ethambutol (3.12 μg/mL). These results and a preliminary QSAR study can be considered an important start point for the rational design of new leads for anti-TB compounds.     

苜蓿体内H2S信号与Ca2+调节气孔运动的作用机制

为探究H₂S信号在苜蓿（Medicago sativa）体内调节气孔运动的作用,及在此过程中H₂S与Ca²⁺的关系,以蒺藜苜蓿（Medicago truncatula）的野生型和钙离子转运体突变体为试验材料,分别从转录水平、细胞水平和生理水平开展研究。采用qRT-PCR比较相关基因的表达量变化、荧光探针显示体内Ca²⁺含量、电极法测定H₂S含量、光学显微镜观察和测量气孔孔径等。结果表明：蒺藜苜蓿突变体NF3011和NF2734体内H₂S的含量与野生型相比极显著降低（P<0.01）;H₂S信号在一定程度上抑制钙离子转运体编码基因MTR_6g027580的表达;外源生理浓度H₂S熏蒸可诱导蒺藜苜蓿气孔关闭,与Ca²⁺通道阻断剂LaCl₃联合处理对野生型气孔运动未产生影响,而在突变体中的结果截然相反;利用荧光探针测定保卫细胞内的Ca²⁺含量,所得结果与气孔孔径的变化规律完全一致。综上所述,H₂S信号促进叶片保卫细胞内Ca²⁺的含量增加,最终表现为植物气孔孔径变小,在此过程中胞内Ca²⁺含量变化主要通过Ca²⁺转运体进行,少部分依赖Ca²⁺离子通道。该研究结果不仅在理论上丰富了H₂S信号的作用机制,更具应用于苜蓿生产实践并推广于其他作物的潜力。     

H2S对干旱胁迫下高山离子芥的作用研究

以高山冰缘植物高山离子芥（Chorispora bungeana）试管苗为实验材料,研究了0.3 mol·L^-1甘露醇模拟干旱胁迫响应过程中硫化氢（H₂S）调节高山离子芥的膜系统损伤程度、渗透调节物质和抗氧化酶系的作用,以及磷脂酶D（PLD）、活性氧（ROS）与H₂S信号分子在高山离子芥中响应干旱胁迫中的作用和可能存在的信号关系。结果显示：干旱胁迫下,外施H₂S供体NaHS显著降低高山离子芥电解质渗漏率及MDA含量、抑制ROS产生,提高渗透调节物质和抗氧化水平,从而增强高山离子芥的抗旱能力;干旱可诱导PLD活性、H₂S含量、ROS发生显著变化;当分别外施PLD下游产物PA与ROS供体H₂O₂均可促进干旱胁迫下H₂S的释放,当同时外施PA和ROS抑制剂DPI时对干旱胁迫下H₂S含量没有显著影响,当同时外施PLD抑制剂正丁醇与ROS抑制剂DPI则显著抑制干旱胁迫下H₂S含量的产生,表明干旱胁迫下,高山离子芥中ROS位于PLD的下游、H₂S的上游发挥作用。     

胞质Ca2+参与外源H2S促进盐碱胁迫下裸燕麦种子萌发

硫化氢（Hydrogen sulfide,H₂S）是植物新型气体信号分子,钙离子（Calcium,Ca²⁺）为重要的第二信使,两者在植物逆境响应中分别发挥着重要作用。为明确胞质Ca²⁺在外源H₂S促进盐碱胁迫下作物种子萌发中的作用,以裸燕麦（Avena nude）为材料,采用培养皿培养,以混合盐碱（NaCl、Na₂SO₄、Na₂CO₃、NaHCO₃的摩尔比为12：8：1：9）模拟甘肃裸燕麦种植地盐碱环境,蒸馏水为对照,测定了胞外Ca²⁺螯合剂乙二醇-双-（2-氨基乙醚）四乙酸（EGTA）、质膜Ca²⁺通道阻断剂氯化镧（LaCl₃）、液泡Ca²⁺释放抑制剂钌红（RR）和内质网钙泵阻断剂毒胡萝卜素（Thaps）分别与H₂S供体硫氢化钠（NaHS）共处理下种子的发芽势、发芽率、发芽指数、活力指数、平均发芽速率、胚根长和胚芽长7个发芽指标,利用隶属函数分析方法综合评价胞质Ca²⁺对H₂S缓解盐碱胁迫抑制种子萌发的影响。结果表明,随着盐碱胁迫浓度增大,裸燕麦种子的发芽势、发芽率、发芽指数、活力指数、平均发芽速率、胚根长和胚芽长显著下降。与对照相比,15~75 mmol·L^-1盐碱胁迫导致裸燕麦种子萌发的隶属函数综合评价值（D）显著降低,30 mmol·L^-1盐碱胁迫下D值下降了73.1%;100~1 000 μmol·L^-1 NaHS不同程度提高了裸燕麦种子萌发的D值,且100 μmol·L^-1 NaHS缓解30 mmol·L^-1盐碱胁迫下D值下降的作用最大;EGTA、LaCl₃和RR均显著逆转了100 μmol·L^-1 NaHS对30 mmol·L^-1盐碱胁迫下D值下降的缓解作用,而Thaps对NaHS的作用无显著影响。表明胞质Ca²⁺参与外源H₂S促进盐碱胁迫下裸燕麦种子萌发的信号传导过程,且胞质Ca²⁺主要来源于胞外Ca²⁺的内流和液泡中Ca²⁺的释放。     

Analysis of [2H7]methionine, [2H4]methionine,methionine, [2H4]homocysteine and homocysteine in plasma by gas chromatography–mass spectrometry to follow the fate of administered [2H7]methionine

Homocysteine plays a key role in several pathophysiological conditions. To assess the methionine–homocysteine kinetics by stable isotope methodology, we developed a simultaneous quantification method of [²H₇]methionine, [²H₄]methionine, methionine, [²H₄]homocysteine and homocysteine in rat plasma by gas chromatography–mass spectrometry (GC–MS). [¹³C]Methionine and [¹³C]homocysteine were used as analytical internal standards to account for losses associated with the extraction, derivatization and chromatography. For labeled and non-labeled homocysteine measurements, disulfide bonds between homocysteine and other thiols or proteins were reduced by dithiothreitol. The reduced homocysteine and methionine species were purified by cation-exchange chromatography and derivatized with isobutyl chlorocarbonate in water–ethanol–pyridine. Quantification was carried out by selected ion monitoring of the molecular-related ions of N(O,S)-isobutyloxycarbonyl ethyl ester derivatives on the chemical ionization mode. The intra- and inter-day precision of the assay was less than 6% for all labeled and non-labeled methionine and homocysteine species. The method is sensitive enough to determine pharmacokinetics of labeled methionine and homocysteine.