太空搭载处理对循化线辣椒M_1代的影响
|
摘要
本研究采用卫星“实践八号”对循化线辣椒的种子进行搭载处理,通过对循化线辣椒M1代的主要农艺性状、生理学特性、孢粉学特性和总蛋白表达等的分析获得如下结果。
(1)太空搭载处理提高了循化线辣椒种子的活力,并且M1代株高、茎粗增大,果实横径增粗,果肉加厚,平均果肉重增加。从太空搭载处理的M1代主要农艺性状的变异情况来看,正向变异居多,而且株高、茎粗、果横径、果纵径、果肉厚、平均单果重和干物质含量等产量性状的变异系数皆大于对照,这就为按育种目标进行的后代选择提供了丰富的变异来源和选择空间。
(2)太空搭载对循化线辣椒M1代的生理特性影响较大。太空搭载处理后的循化线辣椒M1代叶绿素a含量、叶绿素b含量和总叶绿素含量都比对照要高,并且差异达到极显著水平;叶绿素a/b的值有所降低但差异不显著;叶片可溶性蛋白含量小于对照,差异性也不显著;虽然辐射处理的果实VC含量的平均值小于对照,且差异性也都达到了极显著水平,但辐射处理的果实VC含量的变异系数要大于对照,并且VC含量最大值比对照的最大值要大,为从其后代中选育出高VC含量的新品系打下坚实的基础。
(3)M1代花粉在形状上出现了畸形,皱缩和空洞等性状的变化;与对照相比,M1代花粉的大小也比对照要小,并且差异达到极显著水平;M1代花粉育性降低,与对照存在显著差异,并且在M1代中发现一株花粉半不育的10A1。
(4)经过辐射处理的循化线辣椒M1代的总蛋白电泳谱带结果与对照存在不同程度的差异,说明总蛋白表达的差异是太空诱变导致基因变异表达的结果;M1代总蛋白电泳谱带结果之间的差异表明太空辐射诱变引起的变异是广泛的、不定向的。
The main agronomic traits, physiology characters, palynology traits and full protein expression of M1 generation were analyzed after seeds of Xunhua line pepper were carried by the satellite“practice on the 8th”.The results showed as follows:
1.The seeds vigor was increased,and the plant height,stem width,fruit width,fruit flesh and average fruit weight were increased all. The main Agronomic traits of M1 generation had more positive mutation. The yield traits such as plant height, stem width, fruit width, fruit length, flesh thickness of fruit, average weight of single fruit and dry matter were great than CK, these provide many mutation sources for Mutation Progeny Selection.
2.Satellite-carried had much more effect on physiology characters of M1 generation. The content of Chlorophyll a, Chlorophyll b and total Chlorophyll was more than CK., and had significant difference level; The value of Chlorophyll a/ Chlorophyll b decreased but had no significant difference; solubility protein of leaves was lower than CK, and had no significant difference; Although the Vc content of radiated fruits was lower than CK, the variation coefficient was higher than CK, and the max of Vc content was higher than the max of CK, these provide basis to select new line from mutation progeny.
3.The pollen shape of M1 generation had some changes such as abnormality, crimple and empty; The pollen size of M1 generation was small than CK, and had significant difference level; The Pollen fertility of M1 generation was decreased, and had significant difference, and discovered a Semi-sterile plant——10A1.
4.The Electrophoresis bands of total protein of XunHua line pepper M1 was difference with CK in some extent, this showed that Satellite -induction leaded to the change of gene expression, then directly leaded to the change of total protein expression; The Electrophoresis bands of M1 total protein showed that the variations came from Satellite -induction was extensive and nondirective.
(1)太空搭载处理提高了循化线辣椒种子的活力,并且M1代株高、茎粗增大,果实横径增粗,果肉加厚,平均果肉重增加。从太空搭载处理的M1代主要农艺性状的变异情况来看,正向变异居多,而且株高、茎粗、果横径、果纵径、果肉厚、平均单果重和干物质含量等产量性状的变异系数皆大于对照,这就为按育种目标进行的后代选择提供了丰富的变异来源和选择空间。
(2)太空搭载对循化线辣椒M1代的生理特性影响较大。太空搭载处理后的循化线辣椒M1代叶绿素a含量、叶绿素b含量和总叶绿素含量都比对照要高,并且差异达到极显著水平;叶绿素a/b的值有所降低但差异不显著;叶片可溶性蛋白含量小于对照,差异性也不显著;虽然辐射处理的果实VC含量的平均值小于对照,且差异性也都达到了极显著水平,但辐射处理的果实VC含量的变异系数要大于对照,并且VC含量最大值比对照的最大值要大,为从其后代中选育出高VC含量的新品系打下坚实的基础。
(3)M1代花粉在形状上出现了畸形,皱缩和空洞等性状的变化;与对照相比,M1代花粉的大小也比对照要小,并且差异达到极显著水平;M1代花粉育性降低,与对照存在显著差异,并且在M1代中发现一株花粉半不育的10A1。
(4)经过辐射处理的循化线辣椒M1代的总蛋白电泳谱带结果与对照存在不同程度的差异,说明总蛋白表达的差异是太空诱变导致基因变异表达的结果;M1代总蛋白电泳谱带结果之间的差异表明太空辐射诱变引起的变异是广泛的、不定向的。
The main agronomic traits, physiology characters, palynology traits and full protein expression of M1 generation were analyzed after seeds of Xunhua line pepper were carried by the satellite“practice on the 8th”.The results showed as follows:
1.The seeds vigor was increased,and the plant height,stem width,fruit width,fruit flesh and average fruit weight were increased all. The main Agronomic traits of M1 generation had more positive mutation. The yield traits such as plant height, stem width, fruit width, fruit length, flesh thickness of fruit, average weight of single fruit and dry matter were great than CK, these provide many mutation sources for Mutation Progeny Selection.
2.Satellite-carried had much more effect on physiology characters of M1 generation. The content of Chlorophyll a, Chlorophyll b and total Chlorophyll was more than CK., and had significant difference level; The value of Chlorophyll a/ Chlorophyll b decreased but had no significant difference; solubility protein of leaves was lower than CK, and had no significant difference; Although the Vc content of radiated fruits was lower than CK, the variation coefficient was higher than CK, and the max of Vc content was higher than the max of CK, these provide basis to select new line from mutation progeny.
3.The pollen shape of M1 generation had some changes such as abnormality, crimple and empty; The pollen size of M1 generation was small than CK, and had significant difference level; The Pollen fertility of M1 generation was decreased, and had significant difference, and discovered a Semi-sterile plant——10A1.
4.The Electrophoresis bands of total protein of XunHua line pepper M1 was difference with CK in some extent, this showed that Satellite -induction leaded to the change of gene expression, then directly leaded to the change of total protein expression; The Electrophoresis bands of M1 total protein showed that the variations came from Satellite -induction was extensive and nondirective.
引文
[1]陈芳远.高空环境对水稻遗传性的影响[J].中国水稻科学,1994,8(1):1~8.
[2]陈建勋,王晓峰主编.植物生理学实验指导[M].广州:华南理工大学出版社,2002.
[3]陈子元.从辐射育种的发展来展望航天育种的前景[J].核农学报,2002,16(5):261~266.
[4]储钟稀.空间条件对黄瓜种子及其后代的影响[C].航天育种论文集,北京:中国航天工业总公司第 710 所等主编,1995,156~163.
[5]邓立平,郭亚华,杨晓辉.利用空间条件探讨蕃茄青椒的遗传变异初报[J].哈尔滨师范大学自然科学报,1995,11(3):85~89.
[6] 邓 立 平 , 郭 亚 华 , 张 军 民 , 等 . 空 间 诱 变 在 甜 椒 育 种 中 的 应 用 [J]. 空 间 科 学 学报,1996,16(刊):126~131.
[7]杜峰,胡广明,杜法响.辣椒新品种——萧丰十三号.上海蔬菜[J],2003(4):13~14.
[8]董君,潘冀森,王耀萍,等.微重力下生长的蛋白质晶体的溶剂结构研究[J].航天医学与医学工程,1998,11(1):26~29.
[9] 方金梁 , 周永胜 . 利用航天诱变选育高产高蛋白质水稻新品种研究 [J]. 作物研究,2004(2):78~80.
[10]高文远,赵淑平,薛岚等.太空环境对药用植物甘草超微结构影响的初步研究[J].中草药,1998,29(11):770~771.
[11]高文远,赵淑平,肖培根等.空间环境对红花生理状况的影向[J].中国中药杂志,1999,24(2):77~79.
[12]高文远,赵淑平,薛岚等.太空飞行对药用植物蕃香叶绿体超微结构的影响[J].中国医学科学院学报 1999,21(6):478~482.
[13]高文远,赵淑平,薛岚等.空间飞行对霍香过氧化物酶、酷酶同工酶、可溶性蛋白质的影响[J].中国中药杂志,1999,24(3):138~140.
[14]龚振平,刘自华,刘根齐.高粱空间诱变效应研究[J].农业生物技术科学,2003,19(6):16~19.
[15]顾瑞琦,沈惠明.空间飞行对小麦种子的生长和细胞学特性的影响[J].植物生理学报,1989,15(4):403~407.
[16]郭亚华,邓立平,蒋兴村等.利用卫星搭载培育番茄新品系[J].北京:航天育种论文集1995,151~155.
[17] 郭亚华 , 邓立平 , 谢立波 . 空间辐射诱变育成番茄新品种宇番 1 号 [J]. 中国蔬菜,2001(6):28~29.
[18]郭亚华,谢立波,王雪,等.辣椒空间诱变育种技术创新及新品种(品系)的选育[J].核农学报,2004,8(4):205~208.
[19]郭亚华,尹若春,徐剑,等.激光预处理种子提高大豆幼苗抗冷害的机理探讨[J].激光技术2003,27(6):506~509.
[20]韩蕾,孙振元,钱永强等.“神舟”三号飞船搭载对草地早熟禾生物学特性的影响[J].草业科学,2004,21(5):17~19.
[21]黄荣庆.中国微重力科学与空间实验首届学术讨论会论文集[C].北京.中国科学技术出版社.1998.
[22]黄新根,熊小梅,何升荣.干鲜及加工多用型辣椒新品种――辛香四号[J].蔬菜,2005(4):10.
[23]胡能书,王国贤.同工酶技术及其应用[M].长沙:湖南科学技术出版社,1985.
[24]蒋兴村.863-2 空间诱变育种进展及前景[J].空间科学学报,1996,16(增刊):77~82.
[25]蒋兴村.8885 返地卫星对水稻遗传性状的影响[J].科学通报,1991,36(23):1820~1824.
[26]蒋兴村.农作物空间诱变育种进展及其前景[J].卫星应用,1996, 4(3):21~25.
[27]姜国勇,于常春,刘鹏起,等.高空环境诱发谷子个体及群体性状变异的研究[J].莱阳农学院学报,1996,13(1):11~14.
[28]江王栋,傅世墙,郑克等.在地面进行微重力生物学实验模拟用的回转器[J].生物化学与生物物理进展,1990,17(2):141.
[29]雷振生,林作揖,吴政卿,等.航天诱变小麦新品种太空 6 号的选育[J].河南农业科学,2004,(6):3~5.
[30]李汉霞,叶志彪,廖祥云等.空间微重力处理对番茄生长发育的影响[J].华中农业大学学报,1994,13 (3):310~313.
[31]李群,顾瑞琦.X 射线辐射对小麦幼苗生长及一些抗氧化酶活性的影响[[J].辐射研究与辐射工艺学报,1997,8:159~163.
[32]李群,顾瑞琦.卫星搭载选育小麦抗赤霉病突变体[J].空间科学学报,1996,16:98~102.
[33] 李 中 存 . 辐 射 小 麦 幼 胚 诱 发 和 筛 选 白 粉 病 抗 性 突 变 体 的 研 究 [J]. 华 北 农 学报,2002,17(2):58~61.
[34]李忠娴,谢建坤,张思文等.卫星搭载小麦主要性状的遗传变异研究[J].空间科学学报,1996,16(增刊):114~120.
[35]李金国,蒋兴林,王长城.空间条件对几种粮食作物的同工酶和细胞学特性的影响[J].遗传学报,1996,23(1):48~55.
[36]李金国,王培生,韩东,等.高空气球飞行对水稻、青椒的诱变效应[J].航天医学与医学工程,1997,10(2):79~83.
[37]李金国,王培生,张健,等.中国农作物航空航天诱变育种的进展及其前景[J].航天医学与医学工程,1999,12(6):465~468.
[38]李金国,刘敏,王培生,等.番茄种子宇宙飞行后的过氧化物同工酶及 RAPD 分析[J].园艺学报,1999,26(1):33~36.
[39]李金国,刘敏,王培生,等.空间条件对番茄诱变作用及遗传的影响[J].航天医学与医学工程,2000,13(2):114~118.
[40]李金国,王培生,张健,等.空间飞行诱导绿菜花的花粉母细胞学染色体畸变研究[J].航天医学与医学工程,1999,12(4):245~248.
[41]李金国,刘根齐,张健,等.高梁种子搭载返回式卫星的诱变研究[J].航天医学与医学工程,2000,14(1):57~59.
[42]李金国,潘光堂,曹墨菊,等.卫星搭载玉米雄性不育突变系的遗传稳定性研究[J].航天医学与医学工程.2002, 15(1): 51~54.
[43]李金国,李源祥,华育坚,等.利用搭载卫星水稻干种子选育出“赣早釉 47 号”的研究[J].航天医学与医学工程.2001,14(4):286~290.
[44]李金国,蒋兴村,王长城.空间条件对几种粮食作物的同下酶和细胞学特性的影响[[J].遗传学报,1996,23(1):48~55.
[45] 李 社 荣 , 刘 雅 楠 , 刘 敏 , 等 . 空 间 条 件 对 玉 米 叶 片 超 微 结 构 的 影 响 [J]. 核 农 学报,1998,12(5):274~280.
[46]李玉华,闫立英.辣椒主要农艺性状的相关分析[J].北京农学院学报,2003,18(1):10~12.
[47]李源祥,蒋兴村,李金国,等.水稻空间诱变育种的研究[J].航天医学与医学工程,1998, 11(1):21~25.
[48] 梁更生 , 尹艳兰 , 赵国珍 , 等 . 早熟长羊角椒新品种天椒 4 号的选育 [J]. 中国蔬菜,2005(3):27~28.
[49]刘存德,沈金光,杜晓光等.空间飞行的石刁柏种子其幼苗的生长发育及生理生化的变化[J].植物学报,1993,3(9):664~668.
[50]刘焕菊.生物多样性与农业可持续发展[J].农业环境与发展.2000(3):19~21.
[51]刘录祥,郑企成.空间诱变与作物改良[M].北京:原子能出版社,1997.
[52]刘录祥.空间技术育种现状与展望[J].国际太空,2001(7):8~11.
[53]刘录祥,王晶,赵林妹等.作物空间诱变效应及其地面模拟研究进展[J].核农学报2004,18(4):247~251.
[54]刘录祥,王晶,金海强,等.零磁空间诱变小麦的生物效应研究[J].核农学报,2002,16(1):2~7.
[55]刘敏,薛淮,潘毅等.地球外空间环境引起植物变异的研究进展[J].细胞生物学杂志.2003,25(3):160~163.
[56]刘敏,王亚林,薛淮.模拟微重力条件下植物细胞亚显微结构的研究[J].航天医学与医学土程,1999,12(5):360~363.
[57]刘敏,薛淮,鹿金颖,等.空间环境对植物试管苗生长发育及遗传变异的影响[J].科技导报,2004(6):23~25.
[58]刘敏,张赞,薛淮,等.卫星搭载的甜椒 87-2 过氧化物同工酶检测及 RAPD 分子检测初报[J].核农学报,1999,13 (5):291~294
[59]刘泽,赵仁渠.空间条件对油菜诱变效果的研究[J].中国油料作物学报,2000,22(4):6~8.
[60] 刘中申 , 都晓伟 , 丁桂清 , 等 . 中药黄等航天育种的初步实验研究 [J]. 中医药信息.1998,15(1):50~52
[61]龙卫平,郑锦荣.航天育种研究进展[J].长江蔬菜,2005(7):35~37.
[62]梅曼彤.空间诱变研究的进展[J].空间科学学报.1999,16(增刊):148~152.
[63]密士军,郝再彬.航天诱变育种研究的新进展[J].黑龙江农业科学,2002, (4):31~33.
[64]苗德全,近似空间条件对植物种子细胞膜透性的影响[J].莱阳农学院学报,1989,6(4):65~67.
[65]邱运兰,何远康,梅曼彤,等.太空飞行对玉米种子的生物学效应[J].华南农业大学学报.1994,15 (2):100~105.
[66]邱芳,李金国,翁曼丽,等.空间诱变绿豆一-长英型突变系的分子生物学分析[J].中国农业科学,1998,31(6):38~42.
[67]孙野青.航天育种青椒和番茄遗传变异研究[J].空间科学学报,1997,16(增刊):164.
[68]谭志刚,李玉玲.优良辣椒新品种——农蕾 24 号[J].农业科技通讯,2005(3):37.
[69]汤泽生,杨军,赵燕,等.航天诱导的凤仙花突变株性状及减数分裂过程的研究[J].核农学报,2004,18(4):289~293.
[70]汪炳良,郑积荣,王慧俐.飞船搭载处理对辣椒 SP1 发芽和和生物学特性的影响[J].核农学报,2004,18(4):317~320.
[71]王广金,闰文义,孙岩等.春小麦航天育种效果的研究[J].核农学报,2004,18(4):257~260.
[72]王镜岩.生物化学[M].北京.高等教育出版社.2002 年 9 月第 3 版.
[73]王瑞珍,程春明,胡水秀,等.春大豆空间诱变性状变异研究初报[J].江西农业学报,2001,13(4):62~64.
[74]王雁,李潞滨,韩蕾.空间诱变技术及其在我国花卉育种上的应用[J].林业科学研究,2002, 15(2):229~234.
[75]魏良明,姜鸿勋,胡学安等.植物诱变新技术及其在玉米育种上的应用[[J].玉米科学,2002,8(1):19~20.
[76]温贤芳,刘录祥.我国农业空间诱变育种研究进展[J].高科技与产业化,2001, (6):31~37.
[77] 温贤芳 , 张龙 , 戴维序 , 等 . 天地结合开展我国空间诱变育种研究 [J]. 核农学报2004,18(4):241~246.
[78]吴岳轩,曾富华.空间飞行对番茄种子活力及其活性氧代谢的影响[J].园艺学报1995,25(2):165~169.
[79]谢克强,杨良波,张香莲,等.白莲二次航天搭载的选育研究,核农学报,2004,18(4):300~302.
[80]邢金鹏,陈受宜,朱立煌,等.水稻种子经卫星搭载后大粒型突变体的分子生物分析[J].航天医学与医学工程,1995,8(2):109~113.
[81]徐继,闰田,赵琦.空间环境对石刁柏幼苗向性生长及代谢过程的影响[J].生物物理学报,1997,13(4):660~664.
[82]徐继,阎田,赵琦,等.微重力对石刁柏根尖组织和细胞中钙水平及分布的影响[J].生物物理学报,1999,15(6):381~386.
[83]徐建龙,李春寿,王俊敏等.空间环境诱发水稻多集矮秆突变体的筛选与鉴定[J].核农学报,2003,17(5):90~94.
[84]徐冠仁.核农学导论[M].北京,原子能出版社,1997.
[85]徐云远,贾敬芬,牛炳韬.空间条件对 3 种豆科牧草的影响[J].空间科学学报,1996,16(增刊):136~141.
[86]薛淮,刘敏,张纯花等,空间搭载后的蜀葵幼苗叶中光合色素含量及抗氧化酶活性变化[J].植物生理学通讯,2003,39(6): 592~594.
[87]薛淮,刘敏,鹿金颖,等空间环境对月季组培苗生物学特性的影响[J].自然科学进展,2005,15(2):173~178.
[88]薛淮,刘敏.植物空间诱变的生物效应及其育种研究进展[J].生物学通报,2002,37(11):7~9.
[89]杨利平,张思方,薛志军.空间条件对毛百合的影响[J].河北林果研究,1999,14(3):230~233.
[90]虞秋成,刘录祥,徐国沽,等.零磁空间处理水稻干种子诱变效应研究[J].核农学报,2002,16(3):139~143.
[91]虞秋成,黄宝才,严建民.作物空间诱变育种的现状及展望[J].江苏农业科学,2001,(4):3~6.
[92]张美荣,双志福,张瑞仙.小麦种子太空诱变效应研究[J].华北农学报,2002,17(2):36~39.
[93]张健,李金国,王培生,等.菜豆空间突变品系的分子生物学分析[J].航天医学与医学工程,2000,13(6):410~413.
[94]张军民.甜椒空间诱变后代的遗传变异检测及分析初报[J].黑龙江农业科学,1999,3:27~31.
[95] 张世成 ,林作缉 , 杨回民 . 航天诱变条件下小麦若干性状的变异 [J]. 空间科学学报,1996,16(增刊):103~107.
[96]张天真主编.作物育种学总论.北京:中国农业出版社,2003.
[97]张蕴薇,任卫波,刘敏等.红豆草空间诱变突变体叶片同工酶及细胞超微结构分析[J].草地学报,2004,12(3),223~226.
[98]张秀荣,李培武,程勇,等.航芝 1 号芝麻新品种的选育及配套栽培技术[J].中国油料作物学报,2003,25(3):34~37.
[99] 赵 琦 , 刘 敏 , 蔡 伟 明 模 拟 微 重 力 条 件 对 植 物 幼 苗 生 长 的 影 响 [J]. 植 物 生 理 学报,2000,26(3);201~205.
[100]赵燕,汤泽生,杨军,等.航天诱变凤仙花小抱子母细胞减数分裂的研究[J].生物学杂志.2004, 21(6);32~34.
[101]赵玉锦,赵琦,白志良,等.空间诱变高梁突变体的研究[J].植物学通报,2001,18(1):81~89.
[102]朱昌兰,胡岳峰,陈莹,等.作物空间诱变育种研究进展[J].江西农业大学学报,1999,21(3): 435~437.
[103]朱方红,喻小洪,徐小军.西甜瓜航天育种研究初报[J].江西园艺,2000(5):36~37.
[104]朱玉贤,李毅.现代分子生物学[M].北京:高等教育出版社,1997,50~59.
[105]Abilov Z K. Adaptive physiological and morphological changes in chloroplasts of plants different periods of dine cultivated of at "Salyut-7" station[C].In Plenary Meeting COSPAR. Abstr 6th , Toulouse,1986,301~306.
[106]Anikeeva I D,Kostina L N.Vaulina .Experiments with air-dried seeds of Arabidopsis(L.) wallr.aboard salyut 6[J].Adv Space Res, 1983,3:129~136.
[107]Barlow P W.(1999),Living plant systeins:how robust are they in the absence of gravity[J].Adv Space Res,23 (12):1975.
[108] Bradford M M. A raoid and sensitive method of the quantitation of microgram quantities of protein utilizing the principle of protein dye binding[J] .Anal Biochcm.1976, 72:248~254.
[109]Bradbury M,Bakern R.A quantitative determination of photochemical and non-photochmical quenching during the slow phase of chlorophyll fluorescence induction curve of bean leave [J].Biochem. Biophys.Acta.1984,765:275~281
[110]Cermeno M C,Lacadena J R.C-banding analysis of gamma-radiation-induced chromosomal interchanges in rye: The role of C-heteromtin in chromosome repatterning[J].Chromosoma, 1985,91:297~306.
[111]Cakmak I, Marschner H. Magnesium deficiency and high light intensity enhance activities of superoxide dismutase, ascorbate peroxidase, and glutathione reductase in bean leaves[J]. Plant Physiology, 1992, 98:1222~1227.
[112]C.F.Johnson, T.W.Dreschel, et al. 1996. Optimization of moisture content for wheat seedling germination in a cellulose acetate medium for a space flight experiment[J]. Ads. Space Res, 18(4/5):239~242
[113]Foyer, C. H.&B. Halliwel. Presence of glutathione and glutathione reductase in chloroplasts: a proposed role on ascorbic acid metabolism[J]. Planta, 1976,133:21~25
[114]Fryer M J, Andrews J R, Oxborough K, et al. Relationship between CO2 assimilation, photosynthetic election transport and active O2 metabolism in leaves of maize in the Tield during oeriods of low temperature[J].Plant Physiol,1998,116:571~580.
[115]Giannopolitis C N, Ries S K. Superoxide dismutase. I. Occurrence in higher plants[J]. Plant Physiology,1977,59:309~314.
[116]Halstcad W T, Dutchcr F R. Plant in spacc[R].Annu Rev Plant Physiol,1987,38:317~366.
[117]Hcycnga A G,Forsman A,Stodicck L S,ct al. Approaches in the determination of Plant nutrient uptake and distribution in space flight conditions[J].Adv Space Res,2000.26(2):299.
[118]Kuznetsov O A,Brown C S,Levine H G,et a1.Composition and physical properties of starchin microg ravity-grown plants[J].Adv Space Res, 2001,28(4):651.
[119]Klimchuk DA.Growth and ultastructural organization of plant cells in vitro under conditions of microgravity[J].Isitologiyai Genetika.1995,29(4):15~21.
[120]Kitava Y,Kawai M,Tsunyama J,et al. The effect of gravity on surface temperature and net photosynthetic rate of Plant leaves[J].Adv space Res,2000,28(4):659.
[121]Kuang A,Xiao Y, Musgrave ME. Cytochemical Localization of Reserves during Seed Development in Arabidopsis thaliana under Spaceflight Conditions[J]. Annals of Botany, 1996. 78: 343~351.
[122]Levine L H,Heyenga A G,Levine H G,et a1. Ce11-wall architecture and lignin compostion of wheat developed in a microgravity environment[J].Phytochemistry, 2001,57:57.
[123]Legue V. Cell cycle and differentiation in lentil wots grown on a slowly rotating clinostat[J]. Pysiologia Plantarum, 1992, 84(3): 386~392.
[124]Maksimova YN (1985),Effect on seeds of heave charged particles of galactic cosmic radiation[J].Space Biol Aerosp Med,1985,19(3):103~107.
[125]Mei M,Qiu Y, Sun Y,et a1.Morphological and molecular changes of maize plants after seeds been flown on recoverable satclfitc[J]. Advances in Space Rcscarch,1998,22(2):1691~1697.
[126]Maluszynski M K,Nichterlein L,Bhatia C R al.Officially released mutant varieties-the FAO/IAEA database[J].Mutation Breeding Review,2000,12:1~12.
[127]M.E.Cook,J.L.Croxdale, T.W.Tibbitts, et al. Development and growth of Potato tubers in microgravity[J]. Adv space Res,1998.21(8/9):1103~1110
[128]NakanoY, Asada K. Hydrogen peroxide is scavenged by ascorbate-specific peroxidase in spinach chloroplasts[J]. Plant Cell Physiology, 1981, 22: 867~880.
[129]Nevzgodina L V, Maksimova Y N. Cytogenetic effects of heavy charges particles of galactic cosmic radiation in experiments aboard Cosmos-1129 biosatellite[J].Space Biol Aerosp Med, 1982,16(4):103~108.
[130]P1ane1 H,Ganbin Y,Pimezzl B,et al.Spaceenvironmental factors affecting responses to radiation at thcccllular level [J].Adv Space Rcs,1989,9:157.
[131]Peterson R B,Sivak M N.Walker D A.Relationship between steady-state fluorescence yield and photosynthetic emciency in spinachlesftissue[J].P1ant Physiol.1998,88:158~163.
[132]Pickert M, Gartenbach K E, Kranz A R.Heavy ion induced mutation in genetic effective cells of high plant[J]. Adv Space Res, 1992,12:69~75.
[133]Qi J J, Ma R C, Chen X D, et al. 2003. Analysis of Genetic Variation in Ganoderma lucidumafter Space Flight[J]. Ads. Space Res,31(6):1617~1622
[134]Rasmussen O. The effect of 8 days of microgravity on regeneration of intact plants from protoplasts[J]. Physiologia Plantarum,1994,92 (3):404~411.
[135]Robert Ferl,Raymond Wheeler, et al. Plants in space[J]. Plant Biology, 2002,5:258~263.
[136]Smith CAD,Bray CM.Intracellular levels of polyadenylated RNA and loss of vigour ingerminating wheat embryos[J].Planta.1982,156:413.
[137]Tripathy BC. Growth and photosynthetic responses of wheat plants growth in space [J].Plant Physiology,1992.100(2):692~698.
[138]Tancjc SR,Sachar RC.Enzymc synthesis by conserved messages in germinating wheat embryos [J] .Phytochmisty.1975,15.1589.
[139]Ukai Y.Varietal difference in gamma-ray induced chromosome aberration in soybem[J].Jap J Genetics.1980,55:225~234.
[140]Vaulina EN,Anikeeva ID,Kostina LN.RadiosensibiIity of higher plant seeds after space flight[J].Adv Space Res,1984,4:103.
[141]Wilkins M R,Williams K L,Appel R D,et a1.Proteome Research New Frontiers in Functional Genomics[M],Germany:Sprin ger-Verlag.1997.
[2]陈建勋,王晓峰主编.植物生理学实验指导[M].广州:华南理工大学出版社,2002.
[3]陈子元.从辐射育种的发展来展望航天育种的前景[J].核农学报,2002,16(5):261~266.
[4]储钟稀.空间条件对黄瓜种子及其后代的影响[C].航天育种论文集,北京:中国航天工业总公司第 710 所等主编,1995,156~163.
[5]邓立平,郭亚华,杨晓辉.利用空间条件探讨蕃茄青椒的遗传变异初报[J].哈尔滨师范大学自然科学报,1995,11(3):85~89.
[6] 邓 立 平 , 郭 亚 华 , 张 军 民 , 等 . 空 间 诱 变 在 甜 椒 育 种 中 的 应 用 [J]. 空 间 科 学 学报,1996,16(刊):126~131.
[7]杜峰,胡广明,杜法响.辣椒新品种——萧丰十三号.上海蔬菜[J],2003(4):13~14.
[8]董君,潘冀森,王耀萍,等.微重力下生长的蛋白质晶体的溶剂结构研究[J].航天医学与医学工程,1998,11(1):26~29.
[9] 方金梁 , 周永胜 . 利用航天诱变选育高产高蛋白质水稻新品种研究 [J]. 作物研究,2004(2):78~80.
[10]高文远,赵淑平,薛岚等.太空环境对药用植物甘草超微结构影响的初步研究[J].中草药,1998,29(11):770~771.
[11]高文远,赵淑平,肖培根等.空间环境对红花生理状况的影向[J].中国中药杂志,1999,24(2):77~79.
[12]高文远,赵淑平,薛岚等.太空飞行对药用植物蕃香叶绿体超微结构的影响[J].中国医学科学院学报 1999,21(6):478~482.
[13]高文远,赵淑平,薛岚等.空间飞行对霍香过氧化物酶、酷酶同工酶、可溶性蛋白质的影响[J].中国中药杂志,1999,24(3):138~140.
[14]龚振平,刘自华,刘根齐.高粱空间诱变效应研究[J].农业生物技术科学,2003,19(6):16~19.
[15]顾瑞琦,沈惠明.空间飞行对小麦种子的生长和细胞学特性的影响[J].植物生理学报,1989,15(4):403~407.
[16]郭亚华,邓立平,蒋兴村等.利用卫星搭载培育番茄新品系[J].北京:航天育种论文集1995,151~155.
[17] 郭亚华 , 邓立平 , 谢立波 . 空间辐射诱变育成番茄新品种宇番 1 号 [J]. 中国蔬菜,2001(6):28~29.
[18]郭亚华,谢立波,王雪,等.辣椒空间诱变育种技术创新及新品种(品系)的选育[J].核农学报,2004,8(4):205~208.
[19]郭亚华,尹若春,徐剑,等.激光预处理种子提高大豆幼苗抗冷害的机理探讨[J].激光技术2003,27(6):506~509.
[20]韩蕾,孙振元,钱永强等.“神舟”三号飞船搭载对草地早熟禾生物学特性的影响[J].草业科学,2004,21(5):17~19.
[21]黄荣庆.中国微重力科学与空间实验首届学术讨论会论文集[C].北京.中国科学技术出版社.1998.
[22]黄新根,熊小梅,何升荣.干鲜及加工多用型辣椒新品种――辛香四号[J].蔬菜,2005(4):10.
[23]胡能书,王国贤.同工酶技术及其应用[M].长沙:湖南科学技术出版社,1985.
[24]蒋兴村.863-2 空间诱变育种进展及前景[J].空间科学学报,1996,16(增刊):77~82.
[25]蒋兴村.8885 返地卫星对水稻遗传性状的影响[J].科学通报,1991,36(23):1820~1824.
[26]蒋兴村.农作物空间诱变育种进展及其前景[J].卫星应用,1996, 4(3):21~25.
[27]姜国勇,于常春,刘鹏起,等.高空环境诱发谷子个体及群体性状变异的研究[J].莱阳农学院学报,1996,13(1):11~14.
[28]江王栋,傅世墙,郑克等.在地面进行微重力生物学实验模拟用的回转器[J].生物化学与生物物理进展,1990,17(2):141.
[29]雷振生,林作揖,吴政卿,等.航天诱变小麦新品种太空 6 号的选育[J].河南农业科学,2004,(6):3~5.
[30]李汉霞,叶志彪,廖祥云等.空间微重力处理对番茄生长发育的影响[J].华中农业大学学报,1994,13 (3):310~313.
[31]李群,顾瑞琦.X 射线辐射对小麦幼苗生长及一些抗氧化酶活性的影响[[J].辐射研究与辐射工艺学报,1997,8:159~163.
[32]李群,顾瑞琦.卫星搭载选育小麦抗赤霉病突变体[J].空间科学学报,1996,16:98~102.
[33] 李 中 存 . 辐 射 小 麦 幼 胚 诱 发 和 筛 选 白 粉 病 抗 性 突 变 体 的 研 究 [J]. 华 北 农 学报,2002,17(2):58~61.
[34]李忠娴,谢建坤,张思文等.卫星搭载小麦主要性状的遗传变异研究[J].空间科学学报,1996,16(增刊):114~120.
[35]李金国,蒋兴林,王长城.空间条件对几种粮食作物的同工酶和细胞学特性的影响[J].遗传学报,1996,23(1):48~55.
[36]李金国,王培生,韩东,等.高空气球飞行对水稻、青椒的诱变效应[J].航天医学与医学工程,1997,10(2):79~83.
[37]李金国,王培生,张健,等.中国农作物航空航天诱变育种的进展及其前景[J].航天医学与医学工程,1999,12(6):465~468.
[38]李金国,刘敏,王培生,等.番茄种子宇宙飞行后的过氧化物同工酶及 RAPD 分析[J].园艺学报,1999,26(1):33~36.
[39]李金国,刘敏,王培生,等.空间条件对番茄诱变作用及遗传的影响[J].航天医学与医学工程,2000,13(2):114~118.
[40]李金国,王培生,张健,等.空间飞行诱导绿菜花的花粉母细胞学染色体畸变研究[J].航天医学与医学工程,1999,12(4):245~248.
[41]李金国,刘根齐,张健,等.高梁种子搭载返回式卫星的诱变研究[J].航天医学与医学工程,2000,14(1):57~59.
[42]李金国,潘光堂,曹墨菊,等.卫星搭载玉米雄性不育突变系的遗传稳定性研究[J].航天医学与医学工程.2002, 15(1): 51~54.
[43]李金国,李源祥,华育坚,等.利用搭载卫星水稻干种子选育出“赣早釉 47 号”的研究[J].航天医学与医学工程.2001,14(4):286~290.
[44]李金国,蒋兴村,王长城.空间条件对几种粮食作物的同下酶和细胞学特性的影响[[J].遗传学报,1996,23(1):48~55.
[45] 李 社 荣 , 刘 雅 楠 , 刘 敏 , 等 . 空 间 条 件 对 玉 米 叶 片 超 微 结 构 的 影 响 [J]. 核 农 学报,1998,12(5):274~280.
[46]李玉华,闫立英.辣椒主要农艺性状的相关分析[J].北京农学院学报,2003,18(1):10~12.
[47]李源祥,蒋兴村,李金国,等.水稻空间诱变育种的研究[J].航天医学与医学工程,1998, 11(1):21~25.
[48] 梁更生 , 尹艳兰 , 赵国珍 , 等 . 早熟长羊角椒新品种天椒 4 号的选育 [J]. 中国蔬菜,2005(3):27~28.
[49]刘存德,沈金光,杜晓光等.空间飞行的石刁柏种子其幼苗的生长发育及生理生化的变化[J].植物学报,1993,3(9):664~668.
[50]刘焕菊.生物多样性与农业可持续发展[J].农业环境与发展.2000(3):19~21.
[51]刘录祥,郑企成.空间诱变与作物改良[M].北京:原子能出版社,1997.
[52]刘录祥.空间技术育种现状与展望[J].国际太空,2001(7):8~11.
[53]刘录祥,王晶,赵林妹等.作物空间诱变效应及其地面模拟研究进展[J].核农学报2004,18(4):247~251.
[54]刘录祥,王晶,金海强,等.零磁空间诱变小麦的生物效应研究[J].核农学报,2002,16(1):2~7.
[55]刘敏,薛淮,潘毅等.地球外空间环境引起植物变异的研究进展[J].细胞生物学杂志.2003,25(3):160~163.
[56]刘敏,王亚林,薛淮.模拟微重力条件下植物细胞亚显微结构的研究[J].航天医学与医学土程,1999,12(5):360~363.
[57]刘敏,薛淮,鹿金颖,等.空间环境对植物试管苗生长发育及遗传变异的影响[J].科技导报,2004(6):23~25.
[58]刘敏,张赞,薛淮,等.卫星搭载的甜椒 87-2 过氧化物同工酶检测及 RAPD 分子检测初报[J].核农学报,1999,13 (5):291~294
[59]刘泽,赵仁渠.空间条件对油菜诱变效果的研究[J].中国油料作物学报,2000,22(4):6~8.
[60] 刘中申 , 都晓伟 , 丁桂清 , 等 . 中药黄等航天育种的初步实验研究 [J]. 中医药信息.1998,15(1):50~52
[61]龙卫平,郑锦荣.航天育种研究进展[J].长江蔬菜,2005(7):35~37.
[62]梅曼彤.空间诱变研究的进展[J].空间科学学报.1999,16(增刊):148~152.
[63]密士军,郝再彬.航天诱变育种研究的新进展[J].黑龙江农业科学,2002, (4):31~33.
[64]苗德全,近似空间条件对植物种子细胞膜透性的影响[J].莱阳农学院学报,1989,6(4):65~67.
[65]邱运兰,何远康,梅曼彤,等.太空飞行对玉米种子的生物学效应[J].华南农业大学学报.1994,15 (2):100~105.
[66]邱芳,李金国,翁曼丽,等.空间诱变绿豆一-长英型突变系的分子生物学分析[J].中国农业科学,1998,31(6):38~42.
[67]孙野青.航天育种青椒和番茄遗传变异研究[J].空间科学学报,1997,16(增刊):164.
[68]谭志刚,李玉玲.优良辣椒新品种——农蕾 24 号[J].农业科技通讯,2005(3):37.
[69]汤泽生,杨军,赵燕,等.航天诱导的凤仙花突变株性状及减数分裂过程的研究[J].核农学报,2004,18(4):289~293.
[70]汪炳良,郑积荣,王慧俐.飞船搭载处理对辣椒 SP1 发芽和和生物学特性的影响[J].核农学报,2004,18(4):317~320.
[71]王广金,闰文义,孙岩等.春小麦航天育种效果的研究[J].核农学报,2004,18(4):257~260.
[72]王镜岩.生物化学[M].北京.高等教育出版社.2002 年 9 月第 3 版.
[73]王瑞珍,程春明,胡水秀,等.春大豆空间诱变性状变异研究初报[J].江西农业学报,2001,13(4):62~64.
[74]王雁,李潞滨,韩蕾.空间诱变技术及其在我国花卉育种上的应用[J].林业科学研究,2002, 15(2):229~234.
[75]魏良明,姜鸿勋,胡学安等.植物诱变新技术及其在玉米育种上的应用[[J].玉米科学,2002,8(1):19~20.
[76]温贤芳,刘录祥.我国农业空间诱变育种研究进展[J].高科技与产业化,2001, (6):31~37.
[77] 温贤芳 , 张龙 , 戴维序 , 等 . 天地结合开展我国空间诱变育种研究 [J]. 核农学报2004,18(4):241~246.
[78]吴岳轩,曾富华.空间飞行对番茄种子活力及其活性氧代谢的影响[J].园艺学报1995,25(2):165~169.
[79]谢克强,杨良波,张香莲,等.白莲二次航天搭载的选育研究,核农学报,2004,18(4):300~302.
[80]邢金鹏,陈受宜,朱立煌,等.水稻种子经卫星搭载后大粒型突变体的分子生物分析[J].航天医学与医学工程,1995,8(2):109~113.
[81]徐继,闰田,赵琦.空间环境对石刁柏幼苗向性生长及代谢过程的影响[J].生物物理学报,1997,13(4):660~664.
[82]徐继,阎田,赵琦,等.微重力对石刁柏根尖组织和细胞中钙水平及分布的影响[J].生物物理学报,1999,15(6):381~386.
[83]徐建龙,李春寿,王俊敏等.空间环境诱发水稻多集矮秆突变体的筛选与鉴定[J].核农学报,2003,17(5):90~94.
[84]徐冠仁.核农学导论[M].北京,原子能出版社,1997.
[85]徐云远,贾敬芬,牛炳韬.空间条件对 3 种豆科牧草的影响[J].空间科学学报,1996,16(增刊):136~141.
[86]薛淮,刘敏,张纯花等,空间搭载后的蜀葵幼苗叶中光合色素含量及抗氧化酶活性变化[J].植物生理学通讯,2003,39(6): 592~594.
[87]薛淮,刘敏,鹿金颖,等空间环境对月季组培苗生物学特性的影响[J].自然科学进展,2005,15(2):173~178.
[88]薛淮,刘敏.植物空间诱变的生物效应及其育种研究进展[J].生物学通报,2002,37(11):7~9.
[89]杨利平,张思方,薛志军.空间条件对毛百合的影响[J].河北林果研究,1999,14(3):230~233.
[90]虞秋成,刘录祥,徐国沽,等.零磁空间处理水稻干种子诱变效应研究[J].核农学报,2002,16(3):139~143.
[91]虞秋成,黄宝才,严建民.作物空间诱变育种的现状及展望[J].江苏农业科学,2001,(4):3~6.
[92]张美荣,双志福,张瑞仙.小麦种子太空诱变效应研究[J].华北农学报,2002,17(2):36~39.
[93]张健,李金国,王培生,等.菜豆空间突变品系的分子生物学分析[J].航天医学与医学工程,2000,13(6):410~413.
[94]张军民.甜椒空间诱变后代的遗传变异检测及分析初报[J].黑龙江农业科学,1999,3:27~31.
[95] 张世成 ,林作缉 , 杨回民 . 航天诱变条件下小麦若干性状的变异 [J]. 空间科学学报,1996,16(增刊):103~107.
[96]张天真主编.作物育种学总论.北京:中国农业出版社,2003.
[97]张蕴薇,任卫波,刘敏等.红豆草空间诱变突变体叶片同工酶及细胞超微结构分析[J].草地学报,2004,12(3),223~226.
[98]张秀荣,李培武,程勇,等.航芝 1 号芝麻新品种的选育及配套栽培技术[J].中国油料作物学报,2003,25(3):34~37.
[99] 赵 琦 , 刘 敏 , 蔡 伟 明 模 拟 微 重 力 条 件 对 植 物 幼 苗 生 长 的 影 响 [J]. 植 物 生 理 学报,2000,26(3);201~205.
[100]赵燕,汤泽生,杨军,等.航天诱变凤仙花小抱子母细胞减数分裂的研究[J].生物学杂志.2004, 21(6);32~34.
[101]赵玉锦,赵琦,白志良,等.空间诱变高梁突变体的研究[J].植物学通报,2001,18(1):81~89.
[102]朱昌兰,胡岳峰,陈莹,等.作物空间诱变育种研究进展[J].江西农业大学学报,1999,21(3): 435~437.
[103]朱方红,喻小洪,徐小军.西甜瓜航天育种研究初报[J].江西园艺,2000(5):36~37.
[104]朱玉贤,李毅.现代分子生物学[M].北京:高等教育出版社,1997,50~59.
[105]Abilov Z K. Adaptive physiological and morphological changes in chloroplasts of plants different periods of dine cultivated of at "Salyut-7" station[C].In Plenary Meeting COSPAR. Abstr 6th , Toulouse,1986,301~306.
[106]Anikeeva I D,Kostina L N.Vaulina .Experiments with air-dried seeds of Arabidopsis(L.) wallr.aboard salyut 6[J].Adv Space Res, 1983,3:129~136.
[107]Barlow P W.(1999),Living plant systeins:how robust are they in the absence of gravity[J].Adv Space Res,23 (12):1975.
[108] Bradford M M. A raoid and sensitive method of the quantitation of microgram quantities of protein utilizing the principle of protein dye binding[J] .Anal Biochcm.1976, 72:248~254.
[109]Bradbury M,Bakern R.A quantitative determination of photochemical and non-photochmical quenching during the slow phase of chlorophyll fluorescence induction curve of bean leave [J].Biochem. Biophys.Acta.1984,765:275~281
[110]Cermeno M C,Lacadena J R.C-banding analysis of gamma-radiation-induced chromosomal interchanges in rye: The role of C-heteromtin in chromosome repatterning[J].Chromosoma, 1985,91:297~306.
[111]Cakmak I, Marschner H. Magnesium deficiency and high light intensity enhance activities of superoxide dismutase, ascorbate peroxidase, and glutathione reductase in bean leaves[J]. Plant Physiology, 1992, 98:1222~1227.
[112]C.F.Johnson, T.W.Dreschel, et al. 1996. Optimization of moisture content for wheat seedling germination in a cellulose acetate medium for a space flight experiment[J]. Ads. Space Res, 18(4/5):239~242
[113]Foyer, C. H.&B. Halliwel. Presence of glutathione and glutathione reductase in chloroplasts: a proposed role on ascorbic acid metabolism[J]. Planta, 1976,133:21~25
[114]Fryer M J, Andrews J R, Oxborough K, et al. Relationship between CO2 assimilation, photosynthetic election transport and active O2 metabolism in leaves of maize in the Tield during oeriods of low temperature[J].Plant Physiol,1998,116:571~580.
[115]Giannopolitis C N, Ries S K. Superoxide dismutase. I. Occurrence in higher plants[J]. Plant Physiology,1977,59:309~314.
[116]Halstcad W T, Dutchcr F R. Plant in spacc[R].Annu Rev Plant Physiol,1987,38:317~366.
[117]Hcycnga A G,Forsman A,Stodicck L S,ct al. Approaches in the determination of Plant nutrient uptake and distribution in space flight conditions[J].Adv Space Res,2000.26(2):299.
[118]Kuznetsov O A,Brown C S,Levine H G,et a1.Composition and physical properties of starchin microg ravity-grown plants[J].Adv Space Res, 2001,28(4):651.
[119]Klimchuk DA.Growth and ultastructural organization of plant cells in vitro under conditions of microgravity[J].Isitologiyai Genetika.1995,29(4):15~21.
[120]Kitava Y,Kawai M,Tsunyama J,et al. The effect of gravity on surface temperature and net photosynthetic rate of Plant leaves[J].Adv space Res,2000,28(4):659.
[121]Kuang A,Xiao Y, Musgrave ME. Cytochemical Localization of Reserves during Seed Development in Arabidopsis thaliana under Spaceflight Conditions[J]. Annals of Botany, 1996. 78: 343~351.
[122]Levine L H,Heyenga A G,Levine H G,et a1. Ce11-wall architecture and lignin compostion of wheat developed in a microgravity environment[J].Phytochemistry, 2001,57:57.
[123]Legue V. Cell cycle and differentiation in lentil wots grown on a slowly rotating clinostat[J]. Pysiologia Plantarum, 1992, 84(3): 386~392.
[124]Maksimova YN (1985),Effect on seeds of heave charged particles of galactic cosmic radiation[J].Space Biol Aerosp Med,1985,19(3):103~107.
[125]Mei M,Qiu Y, Sun Y,et a1.Morphological and molecular changes of maize plants after seeds been flown on recoverable satclfitc[J]. Advances in Space Rcscarch,1998,22(2):1691~1697.
[126]Maluszynski M K,Nichterlein L,Bhatia C R al.Officially released mutant varieties-the FAO/IAEA database[J].Mutation Breeding Review,2000,12:1~12.
[127]M.E.Cook,J.L.Croxdale, T.W.Tibbitts, et al. Development and growth of Potato tubers in microgravity[J]. Adv space Res,1998.21(8/9):1103~1110
[128]NakanoY, Asada K. Hydrogen peroxide is scavenged by ascorbate-specific peroxidase in spinach chloroplasts[J]. Plant Cell Physiology, 1981, 22: 867~880.
[129]Nevzgodina L V, Maksimova Y N. Cytogenetic effects of heavy charges particles of galactic cosmic radiation in experiments aboard Cosmos-1129 biosatellite[J].Space Biol Aerosp Med, 1982,16(4):103~108.
[130]P1ane1 H,Ganbin Y,Pimezzl B,et al.Spaceenvironmental factors affecting responses to radiation at thcccllular level [J].Adv Space Rcs,1989,9:157.
[131]Peterson R B,Sivak M N.Walker D A.Relationship between steady-state fluorescence yield and photosynthetic emciency in spinachlesftissue[J].P1ant Physiol.1998,88:158~163.
[132]Pickert M, Gartenbach K E, Kranz A R.Heavy ion induced mutation in genetic effective cells of high plant[J]. Adv Space Res, 1992,12:69~75.
[133]Qi J J, Ma R C, Chen X D, et al. 2003. Analysis of Genetic Variation in Ganoderma lucidumafter Space Flight[J]. Ads. Space Res,31(6):1617~1622
[134]Rasmussen O. The effect of 8 days of microgravity on regeneration of intact plants from protoplasts[J]. Physiologia Plantarum,1994,92 (3):404~411.
[135]Robert Ferl,Raymond Wheeler, et al. Plants in space[J]. Plant Biology, 2002,5:258~263.
[136]Smith CAD,Bray CM.Intracellular levels of polyadenylated RNA and loss of vigour ingerminating wheat embryos[J].Planta.1982,156:413.
[137]Tripathy BC. Growth and photosynthetic responses of wheat plants growth in space [J].Plant Physiology,1992.100(2):692~698.
[138]Tancjc SR,Sachar RC.Enzymc synthesis by conserved messages in germinating wheat embryos [J] .Phytochmisty.1975,15.1589.
[139]Ukai Y.Varietal difference in gamma-ray induced chromosome aberration in soybem[J].Jap J Genetics.1980,55:225~234.
[140]Vaulina EN,Anikeeva ID,Kostina LN.RadiosensibiIity of higher plant seeds after space flight[J].Adv Space Res,1984,4:103.
[141]Wilkins M R,Williams K L,Appel R D,et a1.Proteome Research New Frontiers in Functional Genomics[M],Germany:Sprin ger-Verlag.1997.