茎用芥菜细胞质雄性不育系子叶原生质体培养和高效植株再生

利用茎用芥工细胞质雄性不育系原生质体培养获得了再生植株,并研究了影响原生质体培养的因素。结果表明,子叶是茎用芥菜原生质体培养最佳的外植体,10d苗龄的子叶原生质体在改良MS培养基上培养3d后发生第1次细胞分裂,6d后发生第2次分裂,3周后形成细胞团,5周后形成肉眼可见的小愈伤,培养基中减少NAA或2,4－D都会降低愈伤组织的再生能力,在含一定浓度的NAA（0．25mg/L)和2,4－D（0．25mg/L)培养基上诱导的愈伤组织地致密且有光泽,芽的分化能力高;在MS＋BA 1mg/L NAA0.2mg/L的培养基上芽分化频率高达近29％,再生芽1／2MS＋NAA0．1mg/L培养基上生根,形成完整植株。     

丽格海棠的离体快繁

取丽格海棠幼叶为外植体,在诱导培养基MS＋BA 0．5mg/L NAA 1.0mm/L上培养20d左右,开始分化花芽,培养40d丛生芽长满整个外植体,丛生芽的增殖培养以MS＋BA 0．5mg/L为佳,芽长得大且粗壮,粗壮芽转入无激素的1／2MS生根培养基,生根率达100％。     

牡丹子叶离体再生体系研究

以日本牡丹品种“太阳”为试验材料,研究不同激素组合对牡丹胚初代培养、愈伤组织诱导、分化及植株再生的影响。结果表明：牡丹胚初代培养在1．0mg／L6-BA＋0．25mg／LTDZ的MS培养基上,牡丹胚诱导率最高可达96．1％;剪取无菌子叶转接到附加含有2．0mg／L6-BA＋2．0mg／L2,4-D＋0．2mg／LTDZ的MS培基养上进行愈伤组织培养．诱导率可达100％;愈伤组织在MS＋0．5mg／LKT培养基上分化出芽,分化率达26．6％：不定芽在1／2MS＋1．0mg／LNAA＋4．0mg／LIBA生根培养基上的生根率达27％．     

香蕉草叶柄离体培养与快速繁殖(简报)

以香蕉草叶柄为外植体进行离体培养及快速繁殖条件研究。结果表明,叶柄外植体在培养基MS＋6-BA 2．0mg／L＋NAA 0．3mg／L＋蔗糖30g／L＋卡拉胶7g／L上诱导形成愈伤组织后,转入分化培养基MS＋KT 1．0mg/L＋NAA0．2mg/L可诱导不定芽分化;不定芽转入增殖培养基MS＋6-BA 1.0mg/L＋NAA 0．5mg／L可旺盛增殖,增殖系数4．5。不定根分化培养基为MS＋IBA 0．2mg／L＋NAA 0．05mg／L,生根苗在水族箱移栽成活率达98％。     

火龙果愈伤组织诱导与植株再生

为了建立火龙果愈伤组织诱导与植株再生体系,以火龙果茎段、幼苗和子叶为外植体进行离体培养试验。结果表明：茎段诱导愈伤组织的最优培养基为1／2MS＋2,4-D2．0mg·L^-1＋6-BAO．5mg·L^-1,诱导子叶愈伤组织的最适培养基是1／2MS＋2,4-D2．0mg·L^-1＋6-BA1．0mg·L^-1,诱导愈伤组织分化的最优培养基为1／2MS＋6-BA4．0mg·L^-1＋NAA0．5mg·L^-1,最佳生根培养基为1／2MS＋6．BA1mg·L^-1＋NAA0-3mg·L^-1。     

峨眉双蝴蝶组织培养与快速繁殖(简报)

峨眉双蝴蝶植株带芽茎段的最佳芽诱导培养基为MS＋6-BA 1.5mg／L;在1／2MS＋IBA 1.0培养基上可诱导出根,生根率96％以上;生根苗经炼苗后移栽成活率在89％以上。     

千年健的组织培养和快速繁殖

1植物名称千年健（Homalomenaocculta）,别名翡翠宝石。2材料类别茎段。3培养条件基本培养基为MS。（1）诱导不定芽培养基：MS＋6－BA2．0mg·L-1（单位下同）＋NAA0．5;（2）芽增殖培养基：MS＋6－BA1．5＋NAA0．1;（3）生根培养基：1／2MS＋IBA0．5＋NAA0．5。附加3．0％蔗糖（生根培养基2．0％）,0．65％琼脂,pH5．8～6．0。培养温度28～30℃,光照10～12h·d－1,光照度1500～2000lx。4生长与分化情况4．1不定芽的诱导取生长健壮的植株,剥去叶片、叶柄,留下茎段,冲洗干净后用75％酒精消毒20S,然后放在0．回％的Hg…     

费尔干猪毛菜愈伤组织的诱导、分化及植株再生体系的建立

探讨了植物生长调节剂、外植体等因子对费尔干猪毛菜（Salsola fergartica Drob．）愈伤组织诱导、分化与植株再生的影响。结果表明：2,4-D与6-BA组合使用时,在一定浓度范围内均有愈伤组织产生,最佳的诱导培养基为MS＋2,4-D2．0mg／L＋6-BA0．2mg／L,下胚轴为诱导愈伤组织的最佳材料;愈伤组织继代培养较好的培养基为MS＋NAA0．1mg／L＋6-BA1．0mg／L;愈伤组织不定芽分化培养基为MS＋6-BA0．5mg／L＋NAA0．05mg／L;根分化的培养基为1／2MS＋IBA0．2mg／L,且生根率可达72％。以带柄子叶为外植体,诱导丛生芽的最佳分化培养基为MS＋6-BA1．0mg／L,再生频率可达90．74％。     

强德勒红心柚离体培养与植株再生体系的建立

以强德勒红心柚（Citrus grandis Osbeckcv. Chandler）种子萌发的无菌苗为材料,选取子叶、子叶节段、上胚轴、带芽的茎段进行离体培养研究。结果表明：子叶节段是诱导丛生芽的最佳外植体,诱导率100%;诱导丛生芽的最佳培养基为MS＋6-BA2.0mg/L＋NAA0.05mg/L＋蔗糖30g/L＋活性炭0.4g/L,丛生芽增殖可达11.2倍;最适生根培养基为1/2MS＋NAA0.5mg/L,生根率达100%,移栽15d后成活率100%。     

古巴兰的茎段原球茎诱导与植株再生的研究

试验以古巴兰幼嫩芽体为外植体,通过原球茎诱导途径,建立快速高效的古巴兰再生体系。结果表明：最适宜的诱导茎段和叶片原球茎的培养基分别为MS＋5．0mg／L6-BA＋1．5mg／LNAA和MS＋2．0mg／L6-BA＋1．5mg／LNAA;诱导出的原球茎在MS＋1．5mg／L6～BA＋0．5mg／LNAA培养基上继代最好;在MS＋1．0mg／L6-BA＋0．5mg／LNAA的培养基上能分化出不定芽苗;再生的植株在MS＋6．0mg／L6-BA＋1．0mg／LNAA的培养基上能实现增殖和复壮;最适宜的生根培养基为1／2MS＋0．1mg／LNAA。     

Transformation of Cucumis melo cv. Hetau with Tomato Antisense ACC Synthase Gene

An efficient in vitro plant regeneration system of Cucumis melo L. cv. Hetau was established. Regenerated plantlets were obtained from cotyledons after preculture, shoot inducing culture and root inducing culture. A high regeneration rate was achieved up to 58%. Cucumis melo was transformed with the antisense tomato ACC synthase gene in binary vector pMQ6 via Agrobacterium tumefaciens mediated gene transfer. Kanamycin resistant plantlets were obtained on MS medium with 6 mg/L zeatin, 50 mg/L kanamycin and 650 mg/L cefotaximine. PCR and molecular hybridization analysis showed that tomato ACC synthase antisense cDNA was integreted into the genome of C. melo.     

河套蜜瓜ACC合成酶cDNA片段的克隆和序列分析

1-氨基环丙烷-1-羧酸（ACC）合成酶是高等植物中乙烯生物合成的关键酶。以成熟河套蜜瓜（CucumismeloL．cvHetau）果实的RNA为模板,经反转录和PCR扩增得到预期大小的DNA片段,插入到pUC19的SmaⅠ位点后转化E.coliJM109,筛选出重组子pHMAS1。序列分析表明获得了长627bp的ACC合成酶cDNA片段。与已报道的ACC合成酶基因相应序列比较有很高的同源性．     

厚皮甜瓜（Cucumis melo var. reliculatus）的快速繁殖

以厚皮甜瓜（Cucumis melo var. reliculatus）西薄洛托带腋芽茎段为外植体进行离体快速繁殖研究。结果表明：在MS+BA 0.5～1.0 mg/L+IAA 0.1 mg/L 的培养基上利于诱导形成丛生芽, 芽的月增殖系数达到11以上; 在1/2 MS+IAA 0.5 mg/L培养基上并经暗处理3 d最易生根,生根率90%;在蛭石：草炭土=1：1(体积比)基质中移栽驯化效果好。试管植株定植大田后种性不变,生长和结果习性优于种子苗。     

Genetics of ethylene biosynthesis and restriction fragment length polymorphisms (RFLPs) of ACC oxidase and synthase genes in melon ( Cucumis melo L.)

We investigated the genetics of ethylene biosynthesis and its linkage to the RFLPs of the ACC oxidase and synthase genes in melon ( Cucumis melo L.). The results suggested that the A(0) and B(0) fragments of RFLP-MEL1 of the ACC oxidase gene were two alleles from a single locus, as were the B and C fragments of RFLP-MEACS1 of the ACC synthase gene. The B(0) allele seemed to be partially dominant over the A(0) allele, whereas B and C alleles appeared to map to quantitative trait loci (QTLs), which most likely contributed to ethylene production. Both RFLPs were linked to ethylene production rates, but they were not linked to each other. The interaction effects of the ACC oxidase and synthase genes on ethylene production were revealed by segregation of RFLP-MEL1 and RFLP-MEACS1. The results of single-copy-reconstruction assays suggested that the ACC oxidase gene is a single copy, whereas the ACC synthase gene is a component of a multigene family in the melon genome. The abscission phenotype appeared to be controlled by an independent locus, with the abscission (full-slip) allele dominant over the non-abscission (not full-slip) allele. These results may facilitate efforts toward mapping the quantitative trait loci (QTLs) of ethylene production. The RFLPs may be used in marker-assisted selection in developing melons with a more-desirable low ethylene production rate for enhancing postharvest storage life.     

嫁接对网纹甜瓜果实乙烯生物合成及CmACO1基因表达的影响

以“新汉城翠蜜”网纹甜瓜为接穗,以“圣砧一号”南瓜为砧木进行嫁接,研究嫁接对目光温室网纹甜瓜果实乙烯生物合成及CmACO1基因转录水平表达的影响。结果表明：嫁接明显降低了网纹甜瓜果实ACC含量及乙烯释放量,在乙烯释放高峰时,嫁接的网纹甜瓜果实乙烯释放量比自根的降低了12．6％;嫁接降低了果实中ACC合成酶和ACC氧化酶活性,其最大值分别比自根网纹甜瓜降低了9．0％和6．8％;嫁接抑制了CmACO1的表达,其相对表达量最大值比自根网纹甜瓜降低了39．0％;嫁接网纹甜瓜果实中乙烯释放高峰、ACC合成酶和ACC氧化酶活性峰值及CmACO1相对表达量峰值出现的时间均比自根的延迟了3d。     

Influence of genotype and explant source on the in vitro regeneration ability of different melon varieties

Nine genotypes of melon (Cucumis melo L.) were selected for the investigation of regeneration. Most of the tested varieties showed regeneration ability on medium containing 0.5 mg l?1 or 1 mg l?1 BA, but following the appearance of shoot buds, only six varieties produced leafy shoots. The effect of combinations of BA with different auxins (IAA, NA, 2,4-D) and ABA in the culture medium on shoot regeneration was tested on cotyledon explants of 'Hógolyó' and 'Hale's Best'. To establish optimal conditions for the adventitious shoot induction six types of seedling-derived explants were prepared from seedlings of four different ages. The best results for shoot forming capacity were achieved with cotyledons followed by decapitated seedlings and hypocotyls derived from 4-day-old seedlings. Cotyledon segments of 'Hógolyó' and 'Hale's Best' were also cultivated on media with different concentrations of IAA and BA supplemented with 0.26 mg l?1 ABA. The highest number of well-formed plantlets was counted for 'Hógolyó' on the medium supplemented with 0.9 mg l?1 BA+ 0.6 mg l?1 IAA+ 0.26 mg l?1 ABA. This is the first report on the in vitro regeneration of 'Hógolyó' from decapitated seedling and hypocotyl explants and of 'Javított Zentai', 'Muskotály', 'Hógolyó', 'Tétényi csereshéjú' and 'Magyar Kincs' from cotyledon explants.     

甘蓝型油菜与芝麻菜体的细胞杂交

为拓宽油菜育种的基因资源库, 改良油菜品种, 以甘蓝型油菜(Brassica napus)花油3号下胚轴和芝麻菜(Eruca sativa)下胚轴为材料分离制备原生质体; 然后采用PEG-高Ca2+-高pH法进行原生质体融合, 当PEG浓度为35%, 原生质体融合密度为5×105个/mL时, 融合25 min时, 融合率可达18.2%。融合后在培养密度为1×105个/mL时, 以附加1.0 mg/L 2,4-D +0.5 mg/L 6-BA+0.5 mg/L NAA+ 200 mg/L肌醇+300 mg/L水解酪蛋白的改良的KM8p为融合体培养基, 以0.1 mol/L 蔗糖+0.2 mol/L葡萄糖+0.2 mol/L甘露醇作渗透稳定剂进行液体浅层培养, 效果较好, 愈伤组织再生率最高为6.8%。将融合体再生的小愈伤组织转移至培养基(B5无机盐+0.087 mol/L蔗糖+0.2 mg/L 2, 4-D+0.5 mg/L NAA+0.2 mg/L 6-BA+ 0.5% Agar, pH 5.8)上增殖培养, 待愈伤组织长至直径为3~5 mm时, 及时将其转至分化培养基(MS无机盐+0.087 mol/L 蔗糖+0.1 mg/L IAA+0.8 mg/L 6-BA+0.8% Agar, pH 5.8)中诱导不定芽再生, 芽分化率为35.7%。当不定芽长为2~3 cm时, 将其切下转入附加0.5 mg/L IBA+0.2 mg/L 6-BA的1/2MS生根培养基中诱导生根, 14 d左右即可形成再生植株, 生根率可达88%。同时, 以紫外线(60 μW/cm2)照射芝麻菜原生质体, 进行不对称融合, 照射2 min的获得了愈伤组织和再生植株, 照射4 min的只获得愈伤组织, 而照射5 min以上的没有获得愈伤组织, 但其愈伤组织再生、增殖及植株再生均不如对称融合。从细胞学鉴定的21块杂种愈伤组织上再生出16株杂种植株。     

甘蓝型油菜与芝麻菜体的细胞杂交

为拓宽油菜育种的基因资源库, 改良油菜品种, 以甘蓝型油菜(Brassica napus)花油3号下胚轴和芝麻菜(Eruca sativa)下胚轴为材料分离制备原生质体; 然后采用PEG-高Ca2+-高pH法进行原生质体融合, 当PEG浓度为35%, 原生质体融合密度为5×105个/mL时, 融合25 min时, 融合率可达18.2%。融合后在培养密度为1×105个/mL时, 以附加1.0 mg/L 2,4-D +0.5 mg/L 6-BA+0.5 mg/L NAA+ 200 mg/L肌醇+300 mg/L水解酪蛋白的改良的KM8p为融合体培养基, 以0.1 mol/L 蔗糖+0.2 mol/L葡萄糖+0.2 mol/L甘露醇作渗透稳定剂进行液体浅层培养, 效果较好, 愈伤组织再生率最高为6.8%。将融合体再生的小愈伤组织转移至培养基(B5无机盐+0.087 mol/L蔗糖+0.2 mg/L 2, 4-D+0.5 mg/L NAA+0.2 mg/L 6-BA+ 0.5% Agar, pH 5.8)上增殖培养, 待愈伤组织长至直径为3~5 mm时, 及时将其转至分化培养基(MS无机盐+0.087 mol/L 蔗糖+0.1 mg/L IAA+0.8 mg/L 6-BA+0.8% Agar, pH 5.8)中诱导不定芽再生, 芽分化率为35.7%。当不定芽长为2~3 cm时, 将其切下转入附加0.5 mg/L IBA+0.2 mg/L 6-BA的1/2MS生根培养基中诱导生根, 14 d左右即可形成再生植株, 生根率可达88%。同时, 以紫外线(60 μW/cm2)照射芝麻菜原生质体, 进行不对称融合, 照射2 min的获得了愈伤组织和再生植株, 照射4 min的只获得愈伤组织, 而照射5 min以上的没有获得愈伤组织, 但其愈伤组织再生、增殖及植株再生均不如对称融合。从细胞学鉴定的21块杂种愈伤组织上再生出16株杂种植株。     

ACC氧化酶和ACC合成酶反义RNA融合基因导入番茄和乙烯合成的抑制

从番茄品种强力米寿的总DNA中克隆番茄果实特异启动子2A11,以番茄成熟果实的RNA为模板,进行RT-PCR扩增,克隆番茄全长的ACC氧化酶基因和ACC合成酶基因片段。完成两个基因的克隆和测序后,将888bp的番茄ACC氧化酶基因和943bp的ACC合成酶基因片段串联,构成全长1837bp的融合基因。将该融合基因以反义的方向插入植物双元载体pYPX145中番茄果实表达特异启动子下游,获得ACC氧化酶基因和ACC合成酶基因融合的植物双元载体pOSACC。该载体外源基因表达单元的两端含两个烟草SAR序列,利于转基因的稳定遗传。以番茄栽培品种合作903子叶和下胚轴为外植体,利用根癌农杆菌进行基因转化,通过200mg/L卡那霉素选择和GUS检测,获得了105株番茄GUS阳性植株,转基因番茄果实在当代表现明显耐贮特点。经过4代的耐贮和果实农艺性状的综合选择,获得了两个表现良好的株系DR-1和DR-2,两株系果实乙烯释放量显著下降,是未转基因材料的9.5%,番茄的贮存期在50天以上。     

ACC氧化酶和ACC合成酶反义RNA融合基因导入番茄和乙烯合成的抑制

从番茄品种强力米寿的总DNA中克隆番茄果实特异启动子2A11,以番茄成熟果实的RNA为模板,进行RT-PCR扩增,克隆番茄全长的ACC氧化酶基因和ACC合成酶基因片段。完成两个基因的克隆和测序后,将888bp的番茄ACC氧化酶基因和943bp的ACC合成酶基因片段串联,构成全长1837bp的融合基因。将该融合基因以反义的方向插入植物双元载体pYPX145中番茄果实表达特异启动子下游,获得ACC氧化酶基因和ACC合成酶基因融合的植物双元载体pOSACC。该载体外源基因表达单元的两端含两个烟草SAR序列,利于转基因的稳定遗传。以番茄栽培品种合作903子叶和下胚轴为外植体,利用根癌农杆菌进行基因转化,通过200mg／L卡那霉素选择和GUS检测,获得了105株番茄GUS阳性植株,转基因番茄果实在当代表现明显耐贮特点。经过4代的耐贮和果实农艺性状的综合选择,获得了两个表现良好的株系DR-1和DR-2,两株系果实乙烯释放量显著下降,是未转基因材料的9．5％,番茄的贮存期在50天以上。