重离子束辐照牧草的细胞学研究

采用80MeV／u^20Ne^10 叶离子束贯穿处理豆科与禾本科牧草种子,从实验室种子萌发和根尖细胞的观测分析,随着贯穿剂量的增加,幼苗生长明显减弱,呈负相关性;而染色体总畸变率和徽核率随剂量的增加而显著增加,呈正相关性。结果表明：禾本科牧草比豆科牧草对重离子辐射敏感性强,禾本科牧草适宜剂量为20Gy～30Gy,豆科牧草辐照剂量应高于150Gy。     

紫杉醇对人肝癌SMMC7721细胞NDRG1表达及增值的影响

旨在探索紫杉醇对人肝癌SMMC7721细胞NDRG1表达的影响,及紫杉醇对肝癌SMMC7721细胞系增殖的抑制作用。分别提取紫杉醇处理前后SMMC7721细胞的RNA,进行逆转录-聚合酶链反应(RT-PCR),判断紫杉醇处理前后肝癌细胞中NDRG1表达的情况;采用蛋白印迹技术(Western blotting)分析紫杉醇处理前后肝癌细胞中NDRG1蛋白表达的情况;应用不同浓度紫杉醇处理肝癌细胞,以MTT法检测处理前后肝癌细胞的抑制率,流式细胞术(FCM)观察细胞周期变化的况。结果表明紫杉醇处理后的肝癌SMMC7721细胞中NDRG1表达下降,紫杉醇浓度越高,NDRG1表达水平越低,具有浓度依赖性。以MTT法观察紫杉醇对肝癌细胞的抑制作用,试验结果表明不同浓度的紫杉醇处理肝癌SMMC7721细胞后,癌细胞被明显抑制;以流式细胞术观察紫杉醇作用后肝癌SMMC7721细胞周期的变化,结果显示G2-M期细胞比例升高的程度随浓度增高而升高,细胞越来越多地被阻滞在G2-M期,不能继续分裂增殖。分化相关基因NDRG1的表达可能是肝癌的发病机制之一,紫杉醇可抑制肝癌SMMC 7721细胞中NDRG1的表达;同时紫杉醇能使肝癌SMMC7721细胞的生长阻滞在G2-M期,从而显著抑制SMMC7721细胞的增殖,并且具有剂量、时间依赖效应。     

12C6＋离子束辐照对大青叶生理生化特性的影响

利用辐射能量为100 MeV/u的12C6＋ 重离子束辐照大青叶种子,辐照剂量分别为20、40、50和80 Gy研究其对大青叶M1代的生物学效应.研究结果表明,随着辐照剂量的增大,大青叶的根系活力和叶绿素含量显著降低,发现辐照损伤主要抑制了根的生长及营养吸收;酚酸类化合物含量随着辐照剂量的增大而升高的趋势,表明辐照可提高大青叶的抗氧化和抗病虫害能力;可溶性糖、丙二醛、超氧化物歧化酶（SOD）和过氧化物酶（POD）含量变化的总体趋势为随着辐照剂量的增大先升后降.表明重离子辐照能改变大青叶的一些生理生化特征,其中40 Gy的12C6＋离子束辐照有利改善大青叶抗逆性和一些有效化学成分的积累.     

~(60)Co-γ辐照对中国仓鼠卵巢成纤维细胞DNA和组蛋白合成的影响

本文介绍了~(60)Co-γ辐照对同步的和非同步的CHO细胞的DNA合成和组蛋白合成关系的影响的研究,用~3H-胸腺嘧啶核苷和~(14)C-丙氨酸双标记,未经辐照的和经4Gy～60Gy ~(60)Co-γ辐照的CHO细胞,通过~3H和~(14)C的参入来估价DNA和组蛋白的合成,并用聚丙烯酰胺凝胶电泳鉴定辐照前后组蛋白各组分的变化情况,实验表明: 1)、在4～60Gy剂量范内,无论是同步的还是非同步的CHO细胞其DNA合成和组蛋白合成都受到不同程度的抑制。2)、在辐照后1—3小时,DNA合成和组蛋白合成都受到不同程度的抑制,但辐照后4小时,DNA合成被进一步抑制而组蛋白的合成却逐渐恢复正常,到辐照后48小时组蛋白的合成几乎接近对照水平。3)、16Gy ~(60)Co-γ辐照后8小时,非同步的CHO细胞的DNA合成被抑制的情况比G_1期CHO细胞更为严重。4)、16Gy ~(60)Co-γ辐照S期细胞,在辐照后1—24小时中DNA合成被明显抑制的同时,组蛋白的合成也受到相应的抑制。5)、从未经辐照的和经6、16和60Gy~(60)Co-γ辐照的CHO细胞分别提取全组蛋白,进行聚丙烯酰胺凝胶电泳,从电泳图谱的变化清楚地看到组蛋白H_1和H_3受辐照影响大于组蛋白H_4和H_(2B)+H_(2A),因此我们推测DNA合成和组蛋白H_1和H_3的关系较之组蛋白H_4和H_(2A)+H_(2B)更为密切。     

C~(+6)重离子辐照对枸杞萌发种子核酸合成的影响

C~(+6)重离子辐照对枸杞种子萌发的抑制效应随辐照剂量增加而增强。辐照种子细胞内产生的染色体畸变程度和辐照剂量呈正相关。在萌发过程中,辐照种子内DNA 合成起始时间和高峰期推迟。在DNA 合成非峰值期,DNA 合成水平较高。RNA 合成起始早于DNA,在培养8—20 h 时间,对照种子RNA合成水平高于辐照种子。     

三氧化二砷对肝癌细胞系SMMC-7721凋亡及 Smac caspase-9、caspase-3 蛋白表达的影响

目的：研究三氧化二砷（As203）对人肝癌细胞SMMC-7721的促凋亡作用及对Smac、caspase-9、caspase-3表达的影响。方法：人肝癌细胞SMMC-7721经As20,处理,共分为四组,分别为空白对照组、低剂量组、中等剂量组、高剂量组。分别采用MTT、Hoechst33258染色法、Annexin V-FITC／PI双染法观察其对SMMC．7721细胞增殖的抑制,凋亡细胞核的形态学变化,以及诱导凋亡作用;采用Westemblot法检测凋亡相关蛋白Smac、caspase-9、caspase-3表达的变化。结果：MTT显示：As203在体外能明显抑制SMMC-7721的生长,具有时间剂量依赖关系,与空白对照组相比,其余三组细胞生存率明显下降,差异均有统计学意义（P〈0．05）;Hoechst33258显示细胞呈明显的凋亡细胞形态学特征,具有剂量依赖性;AnnexinV-FITC／PI双染法显示：As203作用24小时可诱导SMMC-7721细胞凋亡,且呈剂量依赖性,与空白对照组相比（2．69±0．58）,其余三组（4．01±0．58）、（5．99±1．69）、（9．26±2．34）差异均有统计学意义（P〈0．05）;Westernblot显示：As2O3作用SMMC-7721细胞24小时,Smac、caspase-9、caspase-3表达上升,呈剂量依赖性,与空白对照组相比,其余三组蛋白表达量明显增加,差异均有统计学意义（P〈0．05）。结论：-定量的As203能抑制SMMC-7721细胞增殖,促进其凋亡,其机制可能与调控Smac、caspase-9、caspase-3表达有关。     

生物育种新技术——重离子束辐照

回顾了我国辐射育种的现状,阐述了重离子辐照育种新技术的优势:剂量分布具有Bragg峰,能够造成难以修复的DNA损伤,更有利于突变体的产生。最后介绍了重离子辐照育种所取得的成果。     

单能质子辐射致质粒DNA链断裂的剂量效应

利用16.4 MeV的质子在不同的剂量下辐照质粒DNApUC19溶液。凝胶电泳技术的分析结果表明随着辐照剂量的增加,DNA损伤变得越来越严重,使线性DNA成分明显增加。当添加了自由基清除剂甘露醇后,DNA的损伤明显减轻,线性DNA片段不再出现,但开环形态DNA的变化依然明显。与较早的重离子7Li和γ射线致DNA损伤的研究结果相比较,表明质子辐射中还是存在着一定的直接作用,在此次实验的能量和LET值范围内,质子的直接电离作用是高于γ射线而低于7Li离子的。     

重离子射线照射后抗辐射菌基因组DNA的损伤修复

研究了不同种类的重离子射线及同一射线的不同剂量照射后引起的抗辐射菌(Deinococcus radiodu-rans)R1的DNA二条链的切断损伤修复时间。结果表明,抗辐射菌经重离子射线照射后所引起的DNA二条链的切断损伤经过培养能被修复;切断的DNA二条链的修复时间随着照射剂量的增加而延长;高LET的重离子射线照射所引起的损伤修复比低LET的重离子射线需要更长的时间,损伤修复的时间与射线的LET之间存在一定的依存性。由此认为:抗辐射菌经照射后引起的DNA二条链切断损伤与射线的种类及照射的剂量有关,照射的剂量越大,射线的LET越高,则DNA二条链的切断损伤越多,损伤修复所需要的时间越长。     

氧离子辐射对体外人精子自发化学发光、运动性、顶体反应和存活率的影响(英文)

我们研究了不同剂量(0,0.25,0.5,1,2,4,8,16,32,64Gy)3.17MeV/u氧离子对体外人精子自发化学发光(SCL)、运动性,顶体反应(AR)和存活率的影响。结果表明,精子SCL随辐射剂量明显增强,最低有效剂量为0.5Gy;精子运动性在0.5—2Gy,AR在0.5—4Gy辐射组均明显高于其对照组,但均随辐射剂量的进一步增加而明显降低;在0.25—8Gy剂量之间,精子存活率与其对照组相比无明显变化,但当剂量进一步增加至16—64Gy时,存活率急剧下降。这些结果提示,低剂量重离子辐射能对精子运动性及AR等功能产生兴奋效应。而大剂量则明显抑制这些功能,甚至造成精子死亡。其作用机制可能与重离子辐射诱导的自由基反应有关。     

重离子及电子辐照沙打旺(Astragalus Adsurgens Pall)干种子的辐射生物学效应

本文采用80MeV/u12C6+和50keV的电子辐照沙打旺干种子,研究沙打旺干种子不同注量的辐照生物学效应,检测其生理生化指标。结果表明:无论是碳离子辐照还是电子辐照,发芽势都随注量的增加先升高后降低,发芽率都随注量增加逐渐降低。其次,碳离子辐照样品,其超氧化物歧化酶(SOD)、谷胱甘肽过氧化物酶(GSH-Px)活性变化随注量增加先升高后降低,即存在一个峰值,过氧化氢酶(CAT)在高于5×106ions/cm2注量的离子辐照中其活性基本不发生变化;不同注量的电子辐照,样品的CAT、SOD、GSH-Px活性都是先升高后降低。第三,无论是碳离子辐照还是电子辐照样品的谷胱甘肽(GSH)含量变化不显著,与注量的变化没有明显的相关性。总而言之,本工作发现碳离子及电子辐照样品,其多个生理生化指标均随注量的增加呈先升高后降低的趋势,但GSH变化对碳离子或电子辐照都不敏感。     

碳离子束辐照拟南芥介导外源基因转移的研究

采用700keV或4.0MeV碳离子束辐照拟南芥种子,通过对样品的显微摄影,发现随着辐照剂量的增加,碳离子束对种子表面的损伤逐渐加剧,特别是在4.0MeV碳离子束辐照下,当剂量达到1×1014ions·cm-2后,种皮局部逐渐被刻蚀殆尽,甚至造成种皮局部破裂。对拟南芥种子进行台盼蓝染色后的显微观测显示,碳离子束辐照可以导致拟南芥种皮细胞着染,在剂量较大的情况下,部分皮下细胞也可着染,表明碳离子束可作用到皮下细胞,为外源基因提供导入的通道。GUS基因导入后的组织化学检测表明:质粒pCAMBIA1301能够进入4.0MeV碳离子束辐照后的拟南芥种子,并在种子和幼芽中获得瞬间表达。     

沿重离子贯穿深度的番茄干种子辐射生物学效应研究

本文采用80MeV/u的^12C^6 辐照番茄干种子,研究处于不同离子贯穿深度番茄干种子的辐照生物学效应,检测其生理生化指标。结果表明：辐照后不同贯穿深度上番茄种子的发芽势与物理剂量对应,第8层样品（对应于碳离子在水中的贯穿深度为15mm）出现峰值76.7％,发芽率随离子入射深度的变化不明显;不同贯穿深度辐照样品的根尖细胞微核率也与物理剂量相对应,在第6、7层样品中出现峰值0.257％;另外,辐照样品幼苗茎叶的一氧化氮合酶（NOS）活性、谷胱甘肽（GSH）含量及总抗氧化力在第9层出现峰值,谷胱甘肽过氧化物酶（GSH-PX）活性在第7-8层出现峰值,超氧化物歧化酶（SOD）、过氧化氢酶（CAT）活性的变化与重离子贯穿深度没有明显的相关性。总而言之,本工作发现辐照品的多个生理生化指标均与入射离子的微剂量分布相对应,即存在生物效应峰。     

氧离子辐射对体外人精子自化学发光,运动性,顶体反应和存活率的影响

Effects of 16O+6 ion irradiation with different doses on human sperm spontaneous chemiluminescence (SCL), motility, acrosome reaction (AR) and viability were examined. Spermatozoa were irradiated with 0, 0.25, 0.5, 1, 2, 4, 8, 16, 32, or 64 Gy 16O+6 ion beam at the energy of 3.17 MeV/u. After irradiation, samples were analyzed by SCL measurement at 1, 2 and 3 h of incubation; motility was determined by the transmembrane migration method within 2 h of incubation; the percentage of AR and viability was evaluated by the triple-stain technique at 3.5 h of incubation. The results showed: sperm SCL was significantly increased with irradiation doses and the lowest effective dose was 0.5 Gy; compared with controls, the transmembrane migration ratio of spermatozoa progressively elevated with irradiation doses at 0.5, 1, and 2 Gy; the percentage of sperm AR markedly increased in 0.5-4 Gy irradiation and the optimal dose was 2 Gy, and then significant decreased with further increase of irradiation doses; the viability had no significant change within 0.25-8 Gy, but was progressively decreased at 16, 32 and 64 Gy. These data suggested that heavy ion at low doses increased motility and AR, whereas had deleterious effects at higher doses, which are associated with free radical reactions induced by heavy ion irradiation.     

碳离子束辐照对质粒DNA的损伤效应

为了证明DNA双链断裂(DSB)片段分布与DNA序列有关的假设,采用32keV／μm的^12C^6 离子和45ke V／μm的^13C^6 离子分别辐照pUCl8质粒,结合限制性内切酶处理,进行琼脂糖凝胶电泳,分析DNA断裂和片段分布。结果表明,除了由一个DSB导致的线性DNA带外,还出现了一条新的、小分子量线性DNA带;限制性内切酶处理后,有另一条线性DNA带产生。证明重离子辐照诱导的DSB是非随机分布的,DNA分子上存在对电离辐射相对敏感的位点。     

Characterization of the adaptive response to ionizing radiation induced by low doses of X rays to human lymphocytes

In previous studies we have shown that low doses of radiation from incorporated tritiated thymidine can make human lymphocytes less susceptible to the genetic damage manifested as chromatid breakage induced by a subsequent high dose of X rays. We have also shown that this adaptive response to ionizing radiation can be induced by very low doses of X rays (0.01 Gy; i.e., 1 rad) delivered during S phase of the cell cycle. To see if a low dose of X rays could induce this response in cells at other phases of the cell cycle, human lymphocytes were irradiated with 0.01 or 0.05 Gy before stimulation by phytohemagglutinin (G0) or with 0.01 Gy at various times after stimulation (G1), followed by 1.5 Gy (150 rad) at G2 phase. Although G0 lymphocytes failed to exhibit an adaptive response, G1 cells irradiated as early as 4 h after stimulation did show the response. Experiments were also carried out to determine how long the adaptive response induced by 0.01 Gy could persist. A 0.01-Gy dose was delivered to lymphocytes in the first S phase, followed by 1.5 Gy in the same or subsequent cell cycles. Lymphocytes receiving a 1.5-Gy dose at 40, 48, or 66 h after stimulation exhibited an adaptive response, whereas those receiving a 1.5-Gy dose at 90 or 114 h did not. Duplicate cultures containing bromodeoxyuridine showed that at 40 h all the lymphocytes were in their first cell cycle after stimulation, at 48 h half of the lymphocytes were in their first cell cycle and half in their second, and at 66 h 80% of the lymphocytes were in their third cell cycle. Thus the adaptive response persists for at least three cell cycles after it is induced by 0.01 Gy of X rays. In other experiments, the time necessary for maximal expression of the adaptive response was determined by delivering 0.01 Gy at hourly intervals 1-6 h before the 1.5-Gy dose. While a 4-h interval was enough for expression of the adaptive response, shorter intervals were not.     

Long-term consequences of radiation-induced bystander effects depend on radiation quality and dose and correlate with oxidative stress

Widespread evidence indicates that exposure of cell populations to ionizing radiation results in significant biological changes in both the irradiated and nonirradiated bystander cells in the population. We investigated the role of radiation quality, or linear energy transfer (LET), and radiation dose in the propagation of stressful effects in the progeny of bystander cells. Confluent normal human cell cultures were exposed to low or high doses of 1GeV/u iron ions (LET ～ 151 keV/μm), 600 MeV/u silicon ions (LET ～ 51 keV/μm), or 1 GeV protons (LET ～ 0.2 keV/μm). Within minutes after irradiation, the cells were trypsinized and co-cultured with nonirradiated cells for 5 h. During this time, irradiated and nonirradiated cells were grown on either side of an insert with 3-μm pores. Nonirradiated cells were then harvested and allowed to grow for 20 generations. Relative to controls, the progeny of bystander cells that were co-cultured with cells irradiated with iron or silicon ions, but not protons, exhibited reduced cloning efficiency and harbored higher levels of chromosomal damage, protein oxidation and lipid peroxidation. This correlated with decreased activity of antioxidant enzymes, inactivation of the redox-sensitive metabolic enzyme aconitase, and altered translation of proteins encoded by mitochondrial DNA. Together, the results demonstrate that the long-term consequences of the induced nontargeted effects greatly depend on the quality and dose of the radiation and involve persistent oxidative stress due to induced perturbations in oxidative metabolism. They are relevant to estimates of health risks from exposures to space radiation and the emergence of second malignancies after radiotherapy.     

Sequential exposures of mammalian cells to low- and high-LET radiations. II. As a function of cell-cycle stages

The synergistic effects of low- and high-LET radiations were further studied with partially synchronized Chinese hamster V79 cells. Principally, nearly monoenergetic 425 MeV/u neon ions and 570 MeV/u argon ions produced near the Bragg peak were employed as the high-LET radiations and 225 kVp X rays as the low-LET counterpart. It was found that the killing effect due to damage interaction after sequential irradiations with the particle beam and X rays varies throughout the cell cycle. The greatest effect was observed in late-S phase which was most resistant to either of the radiations. The effect was quantitatively less in the G1/S border and in G2. Effects on pure mitotic cells have not been investigated in this study. For all cell stages studied, a dose of high-LET particles modified the shape of the X-ray survival curve in a way similar to the modification predicted by an appropriately selected X-ray dose. This finding suggests that the mechanism for the synergistic effects is similar to that operating for sequential treatments with X rays alone. Experiments with an S population, either incubated at 37 degrees C or room temperature between fractionation of high- and low-LET radiation treatments further verified that the damage involved is a repairable type. At a certain fractionation interval (6 to 8 h) following a dose of high-LET treatment, initially asynchronous cells were found to be very sensitive to X-irradiation. It is noteworthy that the net killing measured at this "radiosensitive window" was as effective as the killing observed by "immediately" sequential treatments with the same doses of high- and low-LET radiations. Such a time window also existed when the order of the treatment sequence was reversed except that the time of occurrence was earlier and the window was broader. This sensitization effect may be explained by radiation-induced G2 arrest together with an increase of radiosensitivity as the previously irradiated cells progress into S phase. Radiotherapy strategies using combined high-LET and low-LET radiations for rapidly proliferative tumors are presented.     

N+离子注入对大豆种子活力及其幼苗的抗氧化酶活性影响

本文研究了用25keV N+注入丰豆103的种子后,N+离子对其种子的活力及子叶伸展后48小时和96小时的幼苗内蛋白质含量、谷胱甘肽巯基转移酶(GSH-Ts)、谷胱甘肽过氧化酶(GSH-Px)、抗坏血酸过氧化物酶(ASA-POD)活性的影响.结果表明当N+注量在2.6×1016N+/cm2～5.2×1016N+/cm2时,种子的发芽率、发芽指数、活力指数都明显提高;幼苗的可溶性蛋白含量高于对照.在6.5×1016N+/cm2～10.4×1016N+/cm2注量时,幼苗的可溶性蛋白含量低于对照,96小时幼苗可溶性蛋白的含量高于48小时,说明辐射引起的损伤可随生长时间的增加而有所恢复.高注量可引起幼苗内一些抗氧化酶活性的升高,且随注量的增加酶的活性升高也越明显,96小时幼苗的GSH-Px和ASA-POD活性高于48小时幼苗,GSH-Ts活性略有下降.而低注量(1.3×1016N+/cm2～5.2×1016N+/cm2)的上述酶指标升幅不大.说明经N+离子处理后可通过诱导这些抗氧化酶活性的升高起到减轻伤害的作用.