花椰菜游离小孢子培养及植株再生研究

以186个花椰菜杂交品种及组合为试材,进行了游离小孢子培养研究。结果表明:基因型是胚状体发生的决定因素;24 h 32℃的高温前处理是胚状体发生的必须条件;单核靠边期到双核期的小孢子是进行胚状体诱导的最佳时期,胚状体发生频率最高;培养基中添加6-BA 0.1 mg/L,NAA 0.005 mg/L可以促进胚状体发育。将20 d的胚状体进行脱分化处理,可以大幅度提高胚状体的成活率,植株再生率为53%,再生植株中双单倍体占83.5%。     

苦瓜未授粉子房的胚状体诱导

苦瓜常规育种获得纯合株系耗时长、成本高,通过离体雌核培养途径获得单倍体可加速苦瓜育种进程。为建立苦瓜未授粉子房离体培养再生体系,本研究利用苦瓜未授粉子房为外植体,研究基因型、接种方式、激素配比、胚囊发育时期、预培养处理对胚状体诱导效果的影响。结果表明:MS+6-BA 0.5 mg/L+NAA1.00 mg/L+2,4-D 1.0 mg/L+TDZ 0.04 mg/L培养基胚状体的诱导率最高,为19.60%;在8个苦瓜品种中,2个植株生长势强的品种‘桂农科3号’和‘泰国山’苦瓜胚状体诱导率较高,适合作为离体雌核诱导的实验材料;开花当天的子房去除表皮后横切成2 mm的薄片可有效降低愈伤组织的形成,提高胚状体的诱导率;在黑暗和33℃条件下热激3 d有利于子房的转绿和出胚。本研究对苦瓜未授粉子房的胚状体诱导关键因子进行优化,为创制苦瓜单倍体育种材料提供帮助。     

辣椒花药培养研究进展

归纳了辣椒花药培养过程中影响雄性胚胎发生的诸多因素,包括供试材料、小孢子发育时期、基本培养基、植物生长调节剂、培养基添加物质和温度胁迫处理,总结了小孢子胚胎发生的细胞学观察、再生株的倍性水平和单倍体基因组加倍研究,指出尽管人类已从细胞和分子方面对辣椒花药培养中诱导小孢子胚胎发生和形成胚状体有了进一步的认识,但尚未完全了解小孢子是如何被激发进入孢子体发育途径。当小孢子胚胎发生之谜完全揭开后,辣椒花药培养技术将会应用于更加广泛的领域。     

草莓未受精子房的离体培养

花药培养和未受精子房或胚珠离体培养是人工诱导形成单倍体植株的2条途径。草莓染色体倍性复杂多样,为创新育种资源,本研究以草莓为试材,分析未受精子房的离体培养过程中基因型、外源激素、蔗糖浓度、低温预处理、生长环境及发育状况、光照条件6个关键因素对诱导雌核发育的影响。结果表明：选择合适基因型的露地栽培的一级花蕾,外源激素添加2,4-D,蔗糖浓度6%,低温预处理48 h,黑暗变温处理是草莓未受精子房离体培养获得单倍体胚囊植株的理想条件。本研究为草莓倍性育种提供参考。     

3个辣椒花药培养再生株群体主要农艺性状及苗期抗病性研究

对3个辣椒花药培养再生株DH-R2群体的主要农艺性状,包括株高、株幅、首花节位、叶色、单果质量、商品果横径、商品果纵径、果形指数、老熟果色等进行了较详细的测量和统计分析。结果表明:辣椒花药培养再生株群体的农艺性状存在基因型偏性;再生株群体的单果质量、商品果纵径、果形指数这3个性状都表现为低于供体,株高、株幅、首花节位、商品果横径这4个性状都表现为近似于供体;通过单倍体培养途径可以得到不同颜色层次的老熟果色的辣椒纯系,证明了该途径是多基因控制性状育种的有效途径;对耐TMV和CMV的亲本与感病亲本的杂种进行花药培养,获得了兼具TMV和CMV抗性的株系,证明了单倍体培养途径可以创造新的超亲抗病种质。     

基因型对陆地棉花药离体培养反应的影响

对２７种棉花基因型的花药在离体培养中的反应进行了比较,结果表明：所有的基因型在合适的培养条件下均能高频率地形成愈伤组织,但不同基因型间愈伤组织诱导率和诱导量不同;再生植株的花药比原始亲本的花药易诱导出愈伤组织;品种间杂种表现出部分优势,但不明显。本试验中,仅鲁棉６号和Ｓｉｏｋｒａ１－３两个品种诱导获得了胚性愈伤组织、胚状体和再生植株,且二者之间也存在着差别。从基因型在棉花花药培养中的效应、外界调控对棉花不同基因型花药培养效果的影响、棉花花药培养与体细胞培养基因型差异的比较等三个方面进行了讨论,提出了棉花花药培养愈伤组织诱导和植株再生是受两套遗传基因控制的遗传性状,并提出了棉花组织培养植株再生的阈值问题     

我国部分主推小麦品种组织培养再生能力评价

小麦细胞工程育种和基因工程育种存在强烈的基因型特异性, 从目前推广的优良小麦品种中筛选不同外植体再生能力强的基因型, 对于提高小麦生物技术育种效率和加速育成品种的生产应用具有重要意义。本研究以全国大面积推广的24个优良小麦品种和抗白粉病优良品系CB037为材料, 连续2年进行花药培养、幼胚培养和成熟胚培养, 统计愈伤组织诱导率、愈伤组织分化率和植株再生率, 分析、评价这些小麦品种(系) 3种外植体的组织培养再生性能。结果表明, 25个小麦品种(系)花药、幼胚、成熟胚的植株再生率分别为0~41.75%、2.25%~531.92%和3.24%~84.34%, 基因型差异显著; 组织培养再生能力以幼胚最强(119.79%), 成熟胚其次(36.23%), 花药最弱(4.91%)。CB037的3种外植体组织培养再生效率均最高, 轮选987、扬麦16、内麦836、科农199、新春6号、郑麦366、郑麦9023、新冬20、烟农19和川麦42幼胚培养植株再生能力表现较强, 新春6号、京冬8号、石麦4185、科农199和轮选987成熟胚培养植株再生率较高, 石麦4185和邯6172花药培养绿苗诱导率较高。小麦组织培养效率与基因型和外植体类型密切相关, 不同品种同一外植体再生能力差异显著, 同一品种不同外植体再生能力也存在显著差异, 并且3种外植体的组织培养再生能力不存在相关性。本研究筛选到不同外植体再生能力较好的优良小麦基因型, 可进一步用于小麦转基因育种和单倍体育种。     

石刁柏花药离体培养及单倍体植株再生的研究

1988至1990年进行了石刁柏花药离体培养,将采集不同时期花蕾接种,低温处理,激素配比,花药培养过程中形态学及花粉粒发育途径,愈伤组织诱导及其类型,花药愈伤组织再分化和染色体倍性,单倍体植株的再生及染色体加倍后入土移栽等方面,均做了较深入的研究,并获得了超雄株即纯合二倍体。     

菜心小孢子胚再生体系优化及植株倍性鉴定

为进一步优化菜心游离小孢子胚再生技术体系,本研究以3份不同基因型的菜心小孢子胚状体为试验材料,研究不同培养基类型、培养基中不同琼脂浓度和不同胚龄对胚再生的影响,并对再生植株进行倍性鉴定。结果表明,使用B5培养基时各基因型的成苗率均高于MS培养基,褐化率低于MS培养基,B5培养基是菜心小孢子胚状体再生的适宜培养基;培养基中添加适宜浓度的琼脂可提高再生植株的成苗率,随着琼脂浓度的增加,出苗率呈先升后降的趋势,琼脂浓度为1.0%时,各基因型的出苗率达到最高;胚状体再生的最佳胚龄是25～29 d,胚龄时间过长或过短均不利于胚状体出苗,其中40 d以上胚龄的胚状体几乎不出苗;倍性鉴定发现菜心小孢子再生植株中同时存在单倍体、二倍体和多倍体,3个基因型的二倍体自然加倍率在62.22%～71.11%之间;75 mg/L秋水仙素处理可提高菜心再生株系的二倍体率。本研究为菜心游离小孢子胚再生体系优化及再生植株倍性鉴定提供了技术基础。     

利用小孢子培养技术创制红菜薹早熟DH系

为获得早熟型的双单倍体(DH)植株,加快早熟型红菜薹育种进程,本研究以15个早熟型红菜薹品种为试材,进行小孢子培养,观察小孢子发育过程并对再生植株进行倍性鉴定。结果表明,当花瓣/花药(P/A)长度比值为0.6～0.8时,红菜薹小孢子72%～78%处于单核靠边期;共有6个基因型红菜薹出胚,其中出胚率最大的为gy21-55,平均出胚率为14.3胚/蕾;选取子叶形胚进行植株再生,成苗率在90%以上;利用流式细胞仪对再生植株进行倍性鉴定,平均自然加倍率达76.8%。gy21-40、gy21-55表现出早熟特性,与对照植株相比获得的DH植株可分别提早5 d和8 d抽薹。     

萝卜花药愈伤组织诱导及褐变因素初探

以萝卜为试材,研究了不同激素配比、供体基因型、光照与温度以及蔗糖浓度对花药愈伤组织诱导的影响,同时比较研究了花药愈伤组织褐变过程中几种抗氧化酶活性变化。结果如下：P403在2.0mg/L 2,4-D+1.0mg/L 6-BA+2.0mg/L KT的MS培养基中愈伤组织的诱导率最高,愈伤组织开始褐化的时间晚,抗氧化酶的活性较高;同时进行低温预处理、高温预培养和初期暗培养的协同效果较任何一种单独处理好;6%的蔗糖浓度有利于愈伤组织的诱导。     

Anther and isolated microspore culture response of wheat lines from northwestern and eastern Europe

Hexaploid wheat genotypes from north-western Europe show low responses to current anther culture techniques. This phenomenon was investigated on 145 north-western European wheat lines. Twenty-seven lines from eastern Europe were included to observe the response pattern of wheat from an area, where the technique has been used successfully. On average, eastern European wheat lines produced 3.6 green plants per 111 anthers, while only 1.4 green plants per 111 anthers were obtained in north-western European lines. This difference was due to the high capacity for embryo formation among the eastern European lines, while the ability to regenerate green plants was widespread in both germplasm groups. Isolated wheat microspore culture performed on 85 of these wheat lines gave an average 3.7-fold increase in green plants per anther compared with the anther culture response. The increased recovery of green plants was due to improved plant regeneration and increased green plant percentage from embryos derived from isolated microspore culture.     

组织培养途径改良定型小麦品种的研究

选用ＣＡ９０７０、ＣＡＤ８６９４,京４１１三个定型品种进行组织培养,比较了三种培养方式的培养效果,调查了Ｈ２,Ｒ２株系主要农艺性状的遗传变异情况,结果表明,幼胚培养效率最高,基因型间差异小,花药培养的基因型间差异显著,花药培养后代农艺性状的变异率高于幼胚培养,且其性状值向更小的方向变异,而幼胚培育诱花的变异范围大于花药培养,获得了ＣＡＤ８６９４的花培变异株系９５Ｈ０５５,株高降低了１１．５ｃｍ,获     

辣椒花药培养研究新进展

介绍了辣椒花药培养的研究概况,对影响辣椒花药培养的各主要因素,如基因型、供体植株生长状况、花药发育时期、预处理、培养基及其成分、培养条件等进行了详细阐述。另外,针对辣椒花药培养机理作以简单介绍,对辣椒单倍体培养存在的问题和未来的研究方向作了展望     

Somatic in vitro culture response of Lolium perenne L.: genetic effects and correlations with anther culture

Summary Genotypic effects on callus induction and plant regeneration in callus, suspension and protoplast culture, and their correlations with both phenotypic and GCA-values for anther culture response, were studied using 21 genotypes of perennial ryegrass. Differences between genotypes accounted for approximately 40% of the total variation for callus induction and initial callus growth, and 59 and 83% of the variation in callus culture for regeneration percentage and percentage of green plants. Effects of genotypes were less pronounced in suspension culture, where suspensions from the same genotype often behaved differently. Some suspension cultures retained their capacity for green plant regeneration for almost two years, repeatedly producing 80–100% green regenerants during this period. Genotypes with high regeneration percentage and a large proportion of green plants from callus culture were also superior in suspension culture for both regeneration performance and longevity. Regeneration percentage and percentage of green plants were uncorrelated, and probably under different genetic control. While capacity for green plant formation from the different genotypes showed no correlation between anther culture and somatic in vitro culture, a positive correlation was observed between the regeneration percentages in somatic in vitro culture and anther culture (r=0.44^*–0.85^***), suggesting some common genetic control of the two systems.     

An improved in vitro technique for isolated microspore culture of barley

A detailed procedure for isolated microspore culture of barley is presented along with examples of response across genotypes. Over 30 genotypes, including winter and spring growth habit and 2-row and 6-row genotypes, have shown an essentially genotype independent response, averaging about 10,000 embryos per 5 cm petri culture plate. The regeneration frequency, checked on samples of 500 embryos per plate ranged from 36 to 97% with most genotypes being in the range of 70 to 90%. About 70 to 80% of the plants regenerated have been completely fertile doubled haploids, thus eliminating the need to double the chromosome number of plants. Many little details are critical to success of the microspore procedure and while it saves much time compared to anther culture, greater attention to details and cleanliness is essential. This revised version was published online in August 2006 with corrections to the Cover Date.     

Regeneration of fertile doubled haploid plants from colchicine-supplemented media in wheat anther culture

The effect of colchicine added to induction medium for the production of fertile doubled haploid plants after in‐vitro anther culture was studied in wheat, Triticum aestivum L. For this, one winter and two spring wheat varieties were used. Anther cultures of the three genotypes were treated with 0.03% colchicine for 3 days at the beginning of microspore induction. Colchicine had no significant effect on anther response and embryoid production of the genotypes examined. However, in the winter wheat genotype ‘Mv Szigma’, colchicine caused a significant reduction in microspore‐derived structures. A significant decrease was also observed in plant regeneration ability of two genotypes (‘Vergina’ and ‘Acheloos’) after colchicine treatment. In addition, a significant reduction of the albinos produced was observed in all genotypes after olchicine treatment. In contrast, the regenerants obtained from the colchicine‐supplemented induction media produced significantly higher percentages of fertile plants in all genotypes. However, the level of fertility, was significantly different among the fertile plants obtained. This, together with the observation that in the case of the winter wheat variety the colchicine treatment resulted in 100% completely fertile plants with a high seed‐setting ability indicate that there is space for further improvement of the method when it is applied to spring cultivars. Finally, the increased number of seeds per 100 plated anthers obtained from all three genotypes after colchicine treatment, clearly demonstrates that the addition of colchicine to induction medium was superior to the conventional anther culture method and it could therefore be introduced into wheat breeding programmes.     

Effect of parental genotypes and colchicine treatment on the androgenic response of wheat F1 hybrids

The effect of the parental genotypes and colchicine treatment on the androgenic response of wheat (Triticum aestivum L.) F1 hybrids was studied. For this, anthers from three F1 hybrids and their parents were cultured on W14 initiation medium and W14 supplemented with 0.03% colchicine. The number of responding anthers, microspore‐derived structures/100 anthers, green plants/embryos cultured, green plants/100 anthers and albino plants/100 anthers were recorded. It was observed that embryo formation and plant regeneration ability were genetically controlled and genotype dependent. In both treatments the variety Kavkaz had a significantly higher percentage of responding anthers, microspore‐derived structures and green plants/100 anthers than the other genotypes. On the other hand, the variety Myconos also demonstrated high microspore‐derived structure production and green plant regeneration when treated with colchicine. The good response observed in these two varieties indicates the importance of colchicine treatment only for certain genotypes. Green plant production capacity of the hybrids was intermediate to that of the parental varieties. As one parent with a high or even an intermediate response to anther culture could lead to the production of sufficient (for breeding purposes) green plants from the F₁ hybrids, it was concluded that screening the inbred lines for the response to anther culture with and without colchicine treatment could contribute to utilization of breeding material with a low response to anther culture via the proper hybrid combinations.     

Comparative analysis of in vitro anther- and isolated microspore culture in hexaploid Triticale (X Triticosecale Wittmack) for androgenic parameters

Two haploid induction media (190-0 and W14mi) were tested in isolated microspore culture of two triticale (X Triticosecale Wittmack) genotypes. The W14mi medium proved superior for the production of green plantlets in both genotypes. This basic medium (W14) was used to compare two doubled haploid production methods (isolated microspore culture and anther culture) with the same genotypes. The induction of androgenesis was more effective in isolated microspore culture than in anther culture. The number of embryo-like structures was 9.2 times higher in microspore culture (511.0/100 anthers) compared to anther culture (55.5/100 anthers) and the number of regenerant plantlets was also 3.4 times higher (anther culture—20.15/100 anthers; isolated microspore culture—67.6/100 anthers). However, the regenerant plantlets from isolated microspore culture were mainly albinos while predominantly green plantlets were regenerated from anther culture. The production of green plantlets from anther culture (16.8/100 anthers) was 2.9 times higher than from isolated microspore culture (5.8/100 anthers). The efficiency of anther culture was tested with eight winter triticale genotypes. The phenomenon of albinism did not hinder the green plant production in anther culture. Mean green plantlet production was 10.87/100 anthers. This value was two times higher than the number of albinos (5.01/100 anthers) and higher than previously published reports. The anther culture protocol described in this study is an efficient tool for the production of microspore-derived green plantlets in triticale.