耐冬山茶子叶再生体系的研究

青岛市市花——耐冬山茶为北方珍贵的冬季观赏物种,目前其栽培数量不能满足园林应用,亟需通过组培扩繁。以耐冬山茶的子叶为外植体,探讨不同因素对子叶愈伤组织诱导及植株再生的影响。结果表明,使用2%的NaClo对耐冬山茶果实灭菌的较佳时间是8 min,子叶愈伤组织的诱导率为100%。耐冬山茶子叶愈伤组织增殖的较优激素配比为0.5 mg·L^-1NAA+1.5 mg·L^-16-BA,其最大增殖量为4.06。将经过2次转接继代培养后的愈伤组织转入不定芽分化培养基MS+1.0mg/LNAA+10.0 mg·L^-16-BA进行不定芽的分化诱导,不定芽的分化率为10.7%。将耐冬山茶的不定芽芽条基部浸没在500 mg·L^-1的IBA溶液中70 min,再转接到1/2MS固体培养基,生根率达40%,成功建立了耐冬山茶子叶的植株再生体系。     

秋水仙素对草莓离体叶片再生和多倍体诱导的影响

以草莓(Fragaria×ananassa Duch.)栽培品种'雪蜜'(2n=8X=56)的离体叶片为外植体,研究了不同浓度秋水仙素对愈伤组织诱导率、不定芽再生率以及多倍体植株诱导的影响,并采用流式细胞仪对多倍体植株的倍性进行鉴定.结果显示,用质量体积分数0.1%、0.3%、0.5%和0.7%的秋水仙素浸泡2、4和6 d,草莓离体叶片均能诱导出愈伤组织和不定芽,但随秋水仙素浓度的提高和处理时间的延长,愈伤组织诱导率和不定芽再生率均显著下降.用不同浓度秋水仙素处理均能产生多倍体植株,倍性为9X、10X、11X、12X、14X和16X;随秋水仙素浓度的提高,多倍体诱导率呈现先上升后下降的变化趋势.用质量体积分数0.3%秋水仙素浸泡处理4 d是最佳的草莓离体叶片诱导方法,不定芽再生率达到40.5%,多倍体诱导率为100.0%,并且诱导产生出16X的植株.     

芍药花药愈伤组织诱导及体细胞胚发生

以芍药(Paeonia lactiflora)品种粉玉奴花药为外植体,研究不同浓度2,4-D对愈伤组织诱导、体胚发生及植株再生的影响,采用组织细胞学方法观察愈伤组织以及体细胞胚发育过程,采用根尖染色体法鉴定再生植株倍性。结果表明,芍药花药愈伤组织诱导的最适培养基为MS+1 mg·L–1 2,4-D+1 mg·L–1 N...     

非洲菊未授粉胚珠的离体诱导和植株再生

通过不同培养基及培养条件的筛选,离体诱导12个品种的非洲菊未授粉胚珠的结果表明:MS中的大量元素 Heller中的微量元素 1/2铁盐 0.2mg·L~(-1)6-BA 0.1mg·L~(-1)IAA较适宜于非洲菊未授粉胚珠愈伤组织的诱导和芽的再生,8个品种中以品种‘E19’诱导愈伤组织的诱导率最高(为23.1%);5个品种可再生形成不定芽,再生率为4.8%-19.6%。用根尖染色体鉴定法鉴定再生的23个植株的倍性的结果显示,21.7%为二倍体,43.5%为单倍体,34.8%为混倍体.     

二甲戊灵对离体大蒜染色体的加倍研究

在MS分化培养基中分别添加不同浓度的秋水仙素和二甲戊灵,以 "改良蒜" 的蒜瓣基部为外植体诱导愈伤组织染色体变异并再生植株,观察根尖细胞染色体数和叶片下表皮保卫细胞特征检测诱变效果.结果表明:大蒜染色体数变异受诱变剂浓度和处理持续时间的影响,诱变剂高浓度和短时间处理均有利于大蒜愈伤组织的分化;添加0.1%秋水仙素处理5 d,愈伤组织存活率为80.7%,分化率为78.1%,四倍体的诱导率为4%;添加 100 μmol/L二甲戊灵处理5 d,愈伤组织存活率为100%,四倍体的诱导率为6%.对根尖细胞染色体和叶片下表皮气孔数目和大小观察显示,诱变株具有四倍体的基本特征.说明二甲戊灵能在离体条件下有效诱导大蒜产生四倍体,可替代秋水仙素对大蒜染色体的加倍作用.     

寿锦的离体植株再生及组培产业化增殖

以寿锦(Haworthia retusa×cooperi cv.‘Variegata’)的幼嫩花蕾为外植体,对其进行了离体植株再生及组培产业化增殖研究。结果显示,外植体在MS+5.0 mg·L~(–1) 6-BA+0.5 mg·L~(–1) IBA培养基上诱导产生愈伤组织;不添加激素的MS基本培养基最适宜寿锦愈伤组织的分化;再生芽在MS+0.2 mg·L~(–1) 6-BA培养基上增殖时,不定芽增殖率及斑锦类型不定芽的诱导率最高,分别为16.7和79.9%。研究结果表明,通过愈伤组织途径能够诱导寿锦不定芽的再生,适当浓度的细胞分裂素有利于提高寿锦的诱导率。研究结果对于珍稀斑锦多肉植物种质资源的保护及其产业化应用具有重要的指导意义。     

玉米胚性愈伤组织的长期继代及其染色体分析

对５种基因型幼胚诱导的愈伤组织继代培养表明,玉米胚性愈伤组织的长期继代受基因型,培养基成分,激素,培养条件的影响。适时继代,逐代筛选对胚性保持起重要作用。适当降低培养温度（１２±２℃）有利于愈伤组织的保存和胚性保持,可以减少愈伤组织长期继代所需的物质和工作量。长期继代培养的胚性愈伤组织,胚状体发生能力和植株再生率无显著变化,但正常苗的再生频率显著下降。观察愈伤组织细胞染色体发现：（１）基因型对不同倍性细胞的比例有明显影响。（２）随着继代时间的延长,二倍体细胞下降,四倍体和非二倍体细胞增多。（３）愈伤组织中出现多种染色体结构变异,这些结构变异有可能导致非整倍体细胞的形成。     

培养基成分和培养时间对匍匐翦股颖植株再生的影响

以匍匐翦股颖成熟种子为外植体,研究了培养基2,4-D浓度、2,4-D和6-BA组合配比、蔗糖浓度对匍匐翦股颖愈伤组织诱导的影响以及愈伤组织再生过程中继代时间、6-BA浓度、蔗糖浓度对愈伤组织分化的影响。结果表明:在MS培养基上,2 mg·L^-1 2,4-D和0.1 mg·L^-1 6-BA的组合最利于愈伤组织的诱导,诱导率高达94%。蔗糖浓度为30 g·L^-1时愈伤组织诱导率最高,为82%; 在再生过程中,当6-BA浓度为1 mg·L^-1时分化率最高(62%),蔗糖浓度为40 g·L^-1时,愈伤组织分化率最高(52%)。经过2次继代培养的愈伤组织(外植体放到培养基后40天)的分化率为最高(71%),随着继代次数增多,分化率逐渐降低,在经过5次继代后(培养100 d)分化率仅有18%。     

苦荞胚性愈伤组织诱导与植株再生研究

以苦荞子叶和下胚轴为外植体,进行了不同浓度激素组合的MS和SH固体培养基对胚性愈伤组织诱导及植株再生的研究。结果发现,MS培养基比SH培养基更有利于胚性愈伤组织诱导;2,4-D是诱导愈伤组织的有效激素,KT能有效促进胚状体的形成;下胚轴和子叶都能有效诱导出胚性愈伤组织和再生植株。下胚轴在MS 1.5mg·L-12,4-D 1.5mg·L-1BA培养基,子叶在MS 2mg·L-12,4-D 0.5~1.5mg·L-1BA上能高效诱导出愈伤组织;愈伤组织在MS 2mg·L-12,4-D 0.1mg·L-1KT培养基中继代,能有效诱导胚性愈伤组织;来自下胚轴的胚性愈伤组织在1/2MS 2.0mg·L-1BA 0.5mg·L-1KT 0.1mg·L-1NAA培养基上能够高频再生出芽,来自子叶的胚性愈伤组织在1/2MS 1.0mg·L-1BA 0.1mg·L-1KT 0.1mg·L-1NAA培养基上芽诱导率较高;MS 1mg·L-1NAA是适宜的再生苗生根培养基。     

安祖花胚性愈伤组织诱导及植株再生研究

为构建安祖花(Anthurium andreanum)胚性愈伤组织再生体系,以3个盆栽品种幼嫩叶片和叶柄为外植体,分析了基本培养基、植物生长调节剂组合和培养条件等因素的影响。结果表明,安祖花胚性愈伤组织诱导的最佳培养基为改良MS3+1.5 mg L–1 2,4-D+0.5 mg L–1 KT+4%蔗糖+2%葡萄糖+0.25%Phytagel,且胚性愈伤组织诱导能力差异显著,表现为?粉冠军??罗宾奴??冠军?和叶片叶柄,其中?粉冠军?叶片的胚性愈伤组织诱导率可达57.9%。胚状体分化的最佳培养基为1/2改良MSa+2%蔗糖+0.25%Phytagel,其中?粉冠军?叶片诱导的胚状体分化率可达31.6%,且在光、暗下分化率的差异不显著。分化苗移栽后的成活率可达100%。     

基于响应面设计茎段形成层培养猕猴桃幼苗的优化研究

为降低猕猴桃组培快繁中的污染率,提高其繁殖效率,该文以猕猴桃的幼嫩茎段为外植体,采用两步培养法进行茎段形成层的愈伤及成苗诱导研究,并利用响应面设计软件对NAA浓度、6-BA浓度、低渗处理时间进行了各条件的优化,同时通过组织切片确定愈伤的来源及幼苗的形成方式。结果表明:(1)培养过程中撕除茎段周皮能显著降低污染率,用200～400 mg·L^-1的PVP处理猕猴桃茎段可有效防止去皮茎段的褐化。(2)愈伤诱导的最佳条件为预培养28.3 h、NAA 4.45 mg·L^-1、6-BA 0.28 mg·L^-1,而幼苗形成的最佳条件为预培养26.4 h、NAA 4.84 mg·L^-1、6-BA 0.42 mg·L^-1。这表明形成层愈伤诱导需较长低渗处理时间和较高生长素,而成苗诱导则需较高生长素、激动素及较短的低渗处理时间。(3)组织切片观察结果表明猕猴桃愈伤组织源于形成层干细胞的分裂,且幼苗株源于胚状体的发育。综上结果表明,通过除去猕猴桃嫩茎周皮,外加抗氧化、低渗处理,可有效降低猕猴桃组培快繁中的污染率,提高繁殖系数和胚状体发生率,为猕猴桃种苗的规模化生产提供技术支撑。     

Mapping QTLs that control the performance of rice tissue culture and evaluation of derived near-isogenic lines

Quantitative trait loci (QTLs) that control the performance of tissue culture in rice were detected by using 116 RFLP markers and 183 BC₁F₃ lines derived from two varieties, Koshihikari and Kasalath. With time, the seed callus of Koshihikari tends to turn brown and stop growing, while that of Kasalath remains yellowish-white and proliferates continuously. The performance of tissue culture in the induction of calli from seed, the subculture of induced calli, and shoot regeneration were evaluated by five indices: induced-callus weight, induced-callus color, subcultured-callus volume, subcultured-callus color, and regeneration rate. Through callus induction and subculture, eight putative QTLs (P < 0.001) were located on chromosomes 1, 4, and 9. Among these QTLs, five Kasalath alleles and three Koshihikari alleles improved tissue culture performance. No QTL for regeneration was found. Among all the QTLs, qSv1 explained the largest phenotypic variance, 33%, in subcultured-callus volume. In induced-callus color, two detected QTLs accounted for 36.4% of the total phenotypic variance; this was the highest score among the five indices used to evaluate the performance of tissue culture. Three near-isogenic lines for QTLs, located in two regions on chromosome 1, were developed to evaluate their tissue culture performance. The Kasalath alleles in qSv1 and qSc1-1 improved callus color through callus induction and subculture, and increased the subcultured-callus volume and the fresh weight of regenerated calli, including shoots, roots, and differentiated structures. In qSc1-2, the Kasalath allele improved callus color through induction and subculture. These results verified the presence of QTLs for the volume and color of subcultured callus on chromosome 1, qSv1, qSc1-1, and qSc1-2.     

Efficient procedures for callus induction and adventitious shoot organogenesis in sugar beet (<Emphasis Type="Italic">Beta vulgaris</Emphasis> L.) breeding lines

Summary Improved in vitro tissue culture systems are needed to facilitate the application of transgene technology to the improvement of sugar beet germplasms. Several commercially important sugar beet breeding lines (SDM, 3, 5, 8, 9, 10, 11, HB 526, and CMS 22003) and commercial varieties (Roberta and Gala) were tested for their regeneration capacity through adventitious shoot organogenesis from cotyledons, hypocotyls, root/hypocotyl/shoot transition zone tissues, and leaf lamina and petiole via an intervening callus phase. Callus induction and adventitious shoot regeneration was dependent on genotype and combinations of plant growth regulators. With cotyledon or hypocotyl explants, SDM 3 and 10 showed a better response on adventitious shoot regeneration in medium containing benzyladenine (BA) and 2,3,5-triiodobenzoic acid or 1-naphthaleneacetic acid (NAA) than SDM 11, 5, and 9. Shoot regeneration was obtained from hypocytyl-root or hypocotyl-shoot transition zone tissue in SDM 9, 10, and HB 526 grown on PGo medium supplemented with BA to induce callus, and the regeneration frequency was 25%. Adventitious shoots were also regenerated from leaf explants of SDM 3 and 9 cultured on medium containing NAA for callus induction and BA and NAA to induce shoot regeneration, and in SDM 10 and CSM 22003 cultured on medium containing BA for callus induction and to induce shoot regeneration.     

石灰土和酸性土生境下金花茶组植物叶片钙形态差异

为探究不同生境下金花茶组植物的叶片钙形态特征，该研究以10种石灰土生境和4种酸性土生境的金花茶为对象，测定了其生境土壤的钙含量和pH值，以及该生境下金花茶组植物叶中的硝酸钙和氯化钙、水溶性有机酸钙、果胶酸钙、磷酸钙和碳酸钙、草酸钙、硅酸钙和总钙的含量。结果表明：(1)石灰土生境的土壤钙含量和土壤pH均极显著(P<0.01)高于酸性土。(2)在石灰土生境中，金花茶组植物的叶钙形态以草酸钙(41.17%)为主，而在酸性土生境中则以果胶酸钙(43.10%)为主，除硝酸钙和氯化钙、果胶酸钙外，石灰土金花茶的各叶钙形态和总钙含量均极显著(P<0.01)高于酸性土金花茶。(3)相关性分析结果显示，大部分叶钙形态含量与土壤pH和土壤钙含量呈极显著(P<0.01)正相关，表明土壤环境对金花茶组植物叶钙形态特征具有重要影响。(4)单因素方差分析结果显示，各叶钙形态含量在物种间存在极显著(P<0.01)差异，表明金花茶组植物在物种分化过程中叶钙形态特征具有多样性。(5)基于叶钙形态特征的聚类分析显示，14种金花茶可归为3大类。总体而言，不同生境背景下金花茶组植物的叶钙形态差异可能是...     

Efficient plant regeneration from leaves of rapeseed (Brassica napus L.): the influence of AgNO3 and genotype

Factors influencing reliable shoot regeneration from leaf explants of rapeseed (Brassica napus L.) were examined. Addition of AgNO₃ to callus induction medium was significantly effective for shoot regeneration in all three genotypes initially tested. When 48 genotypes subsequently were surveyed, a large variation of shoot regenerability was observed, ranging from 100 to 0% in frequency of bud formation and from 7.5 to 0 in the number of buds per explant. A significant correlation (r=0.84) was observed between the frequency of bud formation and the number of buds per explant. The shoot regenerability from leaf explants was not related to that from cotyledonary explants (r=0.28). Histological observations showed that an organized structure developed from calluses produced at vascular bundle tissues after 7 days of culture on callus induction medium, and they developed shoot apical meristems one week after transfer onto shoot induction medium. Regenerated plantlets were obtained 2 months after the initiation of culture and they normally flowered and set seeds. No alterations of morphology or DNA contents were observed in regenerated plants and their S1 progenies.     

八角莲组织培养的器官发生途径研究

为探究小檗科植物八角莲组织培养的器官发生方式,该研究以八角莲离体叶片、叶柄在MS培养基上诱导产生的愈伤组织、不定芽、不定根为对象,用连续石蜡切片技术分析八角莲组织培养的器官发生途径。结果表明:八角莲愈伤组织形成的解剖学特征是靠近表皮的薄壁细胞经激素刺激恢复分裂能力,继续培养形成拟分生组织。拟分生组织可形成许多分化中心。通过对八角莲组织培养产生的不定芽细胞组织学观察发现芽原基起源于愈伤组织外侧的几层薄壁细胞,芽原基背离愈伤组织中央生长形成不定芽,故八角莲脱分化形成的芽起源方式为外起源。而八角莲的根原基起源于组织深处髓部薄壁细胞和部分维管形成层细胞,进而形成类似球形或楔形并朝韧皮部突起的根原基轮廓,根原基继续发育会突破表皮生成不定根,起源方式为内起源。八角莲离体再生途径为器官发生型,在组培苗生长过程中先诱导形成不定芽,再诱导形成不定根,在愈伤组织上形成维管组织将不定芽和不定根连接成完整植株。     

A tissue culture system for different germplasms of indica rice

Agrobacterium-mediated transformation of indica rice has been manipulated in only a limited number of cultivars because the majority of indica varieties are recalcitrant to in vitro response. Establishment of a highly efficient and widely used tissue culture system for indica rice will accelerate the application of transformation technology in breeding programs and the study of the functions of indica-specific genes. By manipulating plant growth regulators, organic components and salts within the culture media, we established two media for callus induction and subculture, respectively, in tissue culture of indica rice. The modified media could guarantee the production and proliferation of a great number of embryogenic calli with high regeneration capacity from mature seeds representing different indica rice germplasms. The calli obtained from this system should be ideal material for Agrobacterium-mediated transformation. The results suggest that this optimized tissue culture system will be widely applicable for the tissue culture of indica varieties. Electronic Supplementary Material Supplementary material is available for this article at The first two authors contributed equally to this work.     

A study of karyotypes and their alterations in cultured and Agrobacterium transformed roots of Lycopersicon peruvianum Mill

Summary Organ culture, plant regeneration from callus culture, and hairy root disease caused by Agrobacterium rhizogenes were utilized as methods of rapid in vitro propagation in Lycopersicon peruvianum Mill. A detailed and comparative karyotype analysis of the resulting material under such in vitro conditions revealed karyotypic stability under organ culture method, ploidy change in callus derived plants, and minor structural alterations of chromosomes in roots transformed by A. rhizogenes.Abbreviations BAP N6-benzylaminopurine - NAA naphthaleneacetic acid - MS Murashige and Skoog medium - RG regeneration medium - SDS sodium dodecyl sulfate     

Somatic chromosome number doubling of selected potato genotypes using callus culture or the colchicine treatment of shoot nodes in vitro

Experiments were carried out to double the somatic cell chromosome numbers of a monoploid and dihaploid of Solanum tuberosum and a genotype of S. circaeifolium subsp. quimense. Colchicine was used in vitro on shoot nodes from which the axillary meristems had been removed. Plants with doubled chromosome numbers were obtained from shoots grown from the tertiary, sub-axillary meristems of all three genotypes. The callus culture of stem and leaf explants was found to produce more shoots with doubled chromosome numbers than the colchicine treatment in the case of the dihaploid and quimense genotypes but no shoots were obtained from callus culture of the monoploid. Fifty-two % of the shoots from the dihaploid and 63% from the quimense clone were ploidy doubled in the case of the best callus culture system. Using a sub-lethal dose of colchicine, the dihaploid yielded 37% ploidy-doubled shoots whereas all the shoots produced from the monoploid were doubled and the quimense clone produced 27% doubled plants. Callus culture was highly dependent upon the type of growth medium and other, unknown, factors. The colchicine treatment, although yielding fewer products, was more reliable for achieving ploidy doubling in selected clones if the number of plants produced is not important.     

In vitro induction of tetraploids in Arachis paraguariensis

In this study, an efficient procedure was established for successful induction of tetraploid Arachis paraguariensis by treating diploid explants with colchicine. Quartered-seed, callus and shoot-tips were treated with colchicine at concentrations of 0.05, 0.1, 0.2 and 0.5?% (w/v) for 4, 8, 16, 20 and 24?h before they were transferred unto modified Murashige and Skoog medium for either callus induction or shoot regeneration. Results showed that quartered-seed displayed the highest frequency of in vitro plantlet regeneration and tetraploid induction, as well as the lowest mortality rate. Flow cytometric analysis also confirmed that the induced tetraploids from quartered-seed were true-to-type. The 0.5?% colchicine treatment for 4 to 8?h gave the best results with 39 and 43?% of the explants yielding tetraploid plants, respectively. Two?months following transfer to ex vitro environment, morphological and growth characteristics of the induced tetraploids were measured. Overall, increasing the ploidy level from 2× to 4× resulted in fewer stomata but more trichomes per unit leaf area. Tetraploid plants obtained in this study should expand the genetic base of Arachis, and can also be used in overcoming the existing hybridization barriers that may be due to ploidy differences within the genus Arachis.