禾本科植物染色体消除型远缘杂交的研究进展

植物远缘杂交是作物育种中广泛应用的技术。除了核型稳定的种间杂交可以获得杂种以外,还可以利用核型不稳定的种间杂交后父本染色体消除的现象,通过胚培养和染色体加倍处理获得加倍单倍体（ＤＨ）植株。然而从小麦×玉米杂交获得的ＤＨ后代与其理论上应完全同质的遗传表现却不相符,总有２～５％的ＤＨ植株发生了形态学变异。最近的研究证明,通过小麦×玉米的受精作用,一些玉米特异ＤＮＡ可以被转移到小麦ＤＨ后代的基因组中。     

禾木科植物染色体消除型远缘杂交的研究进展

植物远缘杂交是作物育种中广泛应用的技术。除了核型稳定的种间杂交可以获得杂种以外,还可以利用核型不稳定的种间杂交后父本染色体消除的现象,通过胚培养和染色体加倍处理获得加倍单倍体(     

6个烟草杂交组合花药再生苗的培养和DH群体的构建

以6个烟草(Nicotiana tabacum L.)杂交组合的花药为实验材料,对各杂交组合花药再生苗出苗状况及培养过程中添加H液体基本培养基对花药出苗状况的影响进行了比较分析;在此基础上,采用质量体积分数0.4%秋水仙素浸苗法构建加倍单倍体(DH)群体,对加倍处理后不同杂交组合再生苗的成苗率、大田移栽成活率及染色体加倍率等进行分析,并对杂交组合DH1单倍体和加倍单倍体植株叶片气孔保卫细胞叶绿体数的差异进行了研究。结果表明:不同杂交组合每枚花药的出苗数、加倍处理后再生苗的成苗率、大田移栽成活率及染色体加倍率有较大差异。其中,每枚花药出苗数为1.57～3.30,杂交组合DH5每枚花药的出苗数最多,达到3.30株,显著高于其他5个杂交组合(P<0.05);加倍处理后再生苗的成苗率为21.12%～33.42%,大田移栽成活率为91.87%～98.86%,杂交组合DH6的成苗率和大田移栽成活率最高;染色体加倍率为6.64%～10.78%,杂交组合DH4的染色体加倍率最高。花药培养约15 d后,添加H液体基本培养基能够显著促进杂交组合DH1和DH2花药出苗。杂交组合DH1单倍体苗和加倍单倍体苗叶片气孔保卫细胞的平均叶绿体数分别为9.27和17.46,二者比值接近1∶2,差异显著。通过花药培养和染色体加倍处理,分别获得了6个烟草杂交组合的DH群体。     

多花黑麦草与普通小麦的杂交

多花黑麦草二倍体种,具有14条染色体。用普通小麦与多花黑麦草杂交,获得了杂种,杂交结实率为0.058%。杂种F1表现为畸形,其体细胞染色体数为28,F1植株产生的花粉败育,雌蕊不孕,用普通小麦和多花黑麦草回交均未获得回交种子,有待于用秋水仙素加倍染色体以获得异源四倍体。     

小麦花粉愈伤组织植株体细胞染色体的变异

研究了用花药培养方法诱导出来的小麦花粉愈伤组织和54个当代植株体细胞染色体的变异情况。发现它们大多是混倍体,但根据其染色体基数的不同,大量的花粉小麦是单倍体和纯合二倍体植株。同时,我们还首次获得了用花粉培养诱导的小麦5x植株和典型的混倍体植株在花粉愈伤组织中观察到染色体双着丝化现象。 离体培养和花粉的单倍性容易引起植物体细胞的核内有丝分裂,核融合,多极有丝分裂以及染色体断裂等现象。这些有丝分裂的异常过程,是产生染色体加倍、混倍体以及染色体变异的各种新类型的重要原因。 研究花粉发育时期在花药培养中的作用,改进培养条件和方法,不仅可以提高诱导花粉植株和提高花粉植株自然加倍的频率,同时还可能获得染色体和染色体组发生变异的新类型,为研究染色体工程和染色体组工程开辟新途径。     

小麦和黑麦染色体在小黑麦×小麦杂种的不同世代群体中的传递

使用单株植物C-带核型鉴定技术,研究了小麦和黑麦染色体在八倍体小黑麦×普通小麦的F_1,BC_1,F_2和F_3代中的遗传行为。黑麦染色体通过花粉和卵细胞的传递率显著不同,通过卵细胞丢失的染色体较多。黑麦染色体在F_2和F_3的传递率为36.0—38.8%,显著低于通过配子的平均传递率。不同的黑麦染色体通过配子的传递是随机的,而在F_2和F_3中却存在着显著的差异,1R的传递率最高,6R、7R最低。发生上述差异的原因可能是黑麦染色体的丢失不仅发生在配子形成和受精阶段,还受具有不同核型的受精卵在发育过程中夭亡的影响。受黑麦染色体的影响,小麦染色体也有不同程度的丢失。在不同的世代群体中,约有7.3—28.1%的植株丢失了小麦染色体。6R、5R和7R对小麦染色体丢失的作用较大。根据本研究的结果,在使用八倍体小黑麦×小麦的杂交方式利用黑麦遗传物质于小麦育种的工作中,F_2和F_3是有效选择的关键世代。本文建议的单株植物C-带核型鉴定技术是实现这一选择目标的有效方法。     

八倍体小黑麦×普通小麦杂种后代群体中的染色体易位

用改良的Giemsa C-带技术以单株为基础分析了八倍体小黑麦×普通小麦的杂种BC_1,F_(?)和F_(?)代植株的核型。在鉴定了C-带核型的1098株杂种后代植株中,发现了78条小麦-黑麦和277条黑麦-黑麦易位染色体。在不同的世代和株系中,小麦-黑麦染色体易位率变化在4.35—14.07%之间,平均7.10%;黑麦-黑麦染色体易位率在0.48—52.78%之间,平均25.23%。鉴定的小麦-黑麦易位染色体涉及了黑麦的14条不同的染色体臂和小麦的A、B和D组染色体。易位的48.57%发生在小麦和黑麦的部分同源染色体之间,51.43%发生在非部分同源染色体之间。不同的黑麦染色体臂参与易位的频率不同。小麦-黑麦染色体易位主要发生在杂种的早期世代,使用适当的选择技术在F_3获得了纯合的易位植株。文中讨论了快速选育易位系的技术和它们在小麦育种中的应用问题。     

玉米特异DNA通过有性杂交导入小麦DH后代的分子证据

构建了玉米的随机基因组文库,筛选了近100个玉米基因组特异的重复DNA克隆,用它们作探针分别对2个来自小麦×玉米的小麦DH群体进行RFLP分析.结果发现,玉米的MR64克隆导入到2个小麦群体的各1株后代中,即在普通小麦DH系的18号株和波斯小麦DH系的15号株中检测到强杂交信号,这个结果首次从DNA水平上证明某些玉米特异的DNA序列,可通过受精作用以很低的频率转移到小麦DH后代的基因组中.测序分析证实,克隆MR64的插入片段长度为695Pb,A+T含量为58%,用多种酶切玉米基因组进行RFLP分析表明它是一个带1～3个主串联重复单位的散布重复序列.同时还对它的序列结构、甲基化图谱、拷贝数和在玉米染色体上的分布以及在其它小麦品种和禾本科种基因组中的序列同源性情况进行了详细的研究.     

通过和玉米杂交诱导硬粒小麦单倍体

硬粒小麦（Ｔｒｉｔｉｃｕｍ ｄｕｒｕｍ Ｄｅｓｆ．）ＤＲ１４７授以超甜玉米（Ｚｅａ ｍ ａｙｓ Ｌ．） ｓｓ ７７００的花粉后,在８３．４％ 的柱头上观察到花粉萌发及花粉管长入胚囊,有９．９％ 的子房发生了卵细胞的单受精,１．９％ 的子房发生了中央细胞的单受精,３２．７％ 的子房发生了双受精。尽管双受精后可同时形成胚和胚乳,但胚乳往往发育迟缓,甚至败育。硬粒小麦×玉米形成的杂合子核型高度不稳定,在最初的几次细胞分裂中,来自父本玉米的染色体逐步被排除,最后形成硬粒小麦单倍体胚。在授以玉米花粉４ ｈ 后用１００ ｐｐｍ ２,４－Ｄ溶液浸蘸硬粒小麦穗部,可以有效地促进幼胚在缺乏胚乳或胚乳败育情况下的生长和发育。授粉９—１３ ｄ 后由５３３个硬粒小麦子房解剖出２５个胚,得胚率为４．７％ 。通过幼胚拯救获得１１棵正常植株,植株获得率为２．１％ 。根尖细胞染色体计数表明,它们为单倍体（２ｎ＝ ２ｘ＝ １４）。     

紫粒小麦核型及45S rDNA位点分析

[目的]建立紫粒小麦的染色体核型,明确紫粒小麦45S rDNA位点的数量与染色体分布,为育种应用提供细胞遗传学资料。[方法]制备紫粒小麦有丝分裂中期染色体制片,通过染色体核型分析软件进行图像采集、染色体长度测量分析,获得紫粒小麦的核型;以45S rDNA为探针,通过荧光原位杂交技术分析其在紫粒小麦染色体上的数量和分布特点。[结果]紫粒小麦的核型特征为2n=6x=42=34m(2SAT)+8sm(2B),染色体上具有3对位于较长染色体臂的近端部45S rDNA杂交位点。[结论]紫粒小麦为六倍体(2n=6x=42),具有不对称的进化属性2B型;在染色体组上有3对45S rDNA位点分布在3对不同染色体,为深入研究紫粒小麦的系统分类提供了细胞学资料。     

由小麦×玉米获得的普通小麦加倍单倍体后代的RFLP变异

用小麦（Ｔｒｉｔｉｃｕｍ　ａｅｓｔｉｖｕｍＬ．）的ｒＤＮＡ克隆ｐＴａ７１和与小麦基因组有部分同源性的玉米（ＺｅａｍａｙｓＬ．）ＤＮＡ克隆作探针,对由小麦ｘ玉米获得的普通小麦加倍单倍体（ＤＨ）后代群体进行ＲＦＬＰ分析。结果发现,不但用ｐＴａ７１在这些ＤＨ后代中检测到ｒＤＮＡ所发生的明显的减少和扩增及非转录间隔区的限制性片段长度的变化,而且用与小麦基因组部分同源的玉米克隆ＭＲ１３和ＭＲ５０在一些ＤＨ后代中检测到缺失变异,特别是用ＭＲ１３在普通小麦ＤＨ系的１８号株的基因组中检测到大幅度的限制性片段长度的变化,即原来的４．３ｋｂ的强信号带消失,取而代之的是４０．０ｋｂ、２．５ｋｂ和２．０ｋｂ三条杂交带。这可能与小麦基因组ＤＮＡ较大的重排事件有关,也可能是由外源的玉米ＤＮＡ插入造成的。     

RFLP Variations of Common Wheat Doubled Haploid Progenies from Wheat×Maize Crosses

Wheat ( Triticum aestivum L. ) and maize ( Zea mays L. ) crosses (the chromosome elimination system) can be used to produce frequently a large number of doubled haploid (DH) wheat lines by embryo rescue and doubling treatment. The resulting DH lines are genetically homogeneous. Significant RFLP variations were detected in common wheat DH progenies from wheat and maize crosses by using wheat rDNA clone pta71 and two maize DNA clones (MR13 and MRSO) homologous to wheat genome as probes. The results revealed that the copy number and restriction fragment length of rDNA in some wheat DH progenies was changed, and also that deletion was detected in several DH plants when probed with MR13 and MR5O. In particular, the RFLP pattern of DH line No. 18 was greatly changed using MR13 as a probe. In this line, three new bands, 40.0 kb, 2.5 kb and 2.0 kb emerged while a 4.3 kb intense band from the parental common wheat genome disappeared. This change may be related to a quite large DNA rearrangement within the wheat genomic DNA or an insertion by alien maize DNA fragment.     

Molecular evidence on maize specific DNA fragment transferred into wheat through sexual hybridization

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Cytological and molecular characterization of oat x maize partial hybrids

In cereals, interspecific and intergeneric hybridizations (wide crosses) which yield karyotypically stable hybrid plants have been used as starting points to widen the genetic base of a crop and to construct stocks for genetic analysis. Also, uniparental genome elimination in karyotypically unstable hybrids has been utilized for cereal haploid production. We have crossed hexaploid oat (2n=6x=42, Avena sativa L.) and maize (2n=2x=20, Zea mays L.) and recovered 90 progenies through embryo rescue. Fifty-two plants (58%) produced from oatxmaize hybridization were oat haploids (2n=3x=21) following maize chromosome elimination. Twenty-eight plants (31%) were found to be stable partial hybrids with 1–4 maize chromosomes in addition to a haploid set of 21 oat chromosomes (2n=21+1 to 2n=21+4). Ten of the ninety plants produced were found to be apparent chromosomal chimeras, where some tissues in a given plant contained maize chromosomes while other tissues did not, or else different tissues contained a different number of maize chromosomes. DNA restriction fragment length polymorphisms (RFLPs) were used to identify the maize chromosome(s) present in the various oat-maize progenies. Maize chromosomes 2, 3, 4, 5, 6, 7, 8, and 9 were detected in partial hybrids and chromosomal chimeras. Maize chromosomes 1 and 10 were not detected in the plants analyzed to-date. Furthermore, partial self-fertility, which is common in oat haploids, was also observed in some oat-maize hybrids. Upon selfing, partial hybrids with one or two maize chromosomes showed nearly complete transmission of the maize chromosome to give self-fertile maize-chromosome-addition oat plants. Fertile lines were recovered that contained an added maize chromosome or chromosome pair representing six of the ten maize chromosomes. Four independently derived disomic maize chromosome addition lines contained chromosome 4, one line carried chromosome 7, two lines had chromosome 9, one had chromosome 2, and one had chromosome 3. One maize chromosome-8 monosomic addition line was also identified. We also identified a double disomic addition line containing both maize chromosomes 4 and 7. This constitutes the first report of the production of karyotypically stable partial hybrids involving highly unrelated species from two subfamilies of the Gramineae (Pooideae — oat, and Panicoideae — maize) and the subsequent recovery of fertile oat-maize chromosome addition lines. These represent novel material for gene/ marker mapping, maize chromosome manipulation, the study of maize gene expression in oat, and the transfer of maize DNA, genes, or active transposons to oat.Joint contribution of the Minnesota Agricultural Experiment Station and USDA-ARS. Scientific journal series paper No. 21 859 of the Minnesota Agricultural Experiment Station. Mention of a trademark or proprietary product does not constitute a guarantee or warranty by the USDA-ARS or the University of Minnesota and does not imply approval over other products that also may be suitable     

Improvements in the production of doubled haploids in durum wheat (<Emphasis Type="Italic">Triticum turgidum</Emphasis> L<Emphasis Type="Italic">.</Emphasis>) through isolated microspore culture

The objective of this study was to produce durum wheat doubled haploid (DH) plants through the induction of microspore embryogenesis. The microspore culture technique was improved to maximize production of green plants per spike using three commercial cultivars. Studies on factors such as induction media composition, induction media support and the stage and growth of donor plants were carried out in order to develop an efficient protocol to regenerate green and fertile DH plants. Microspores were plated on a C₁₇ induction culture medium with ovary co-culture and a supplement of glutathione plus glutamine; 300 g/l Ficoll Type-400 was incorporated to the induction medium support. Donor plants were fertilized with a combination of macro and microelements. With the cultivars ‘Ciccio’ and ‘Claudio’ an average of 36.5 and 148.5 fertile plants were produced, respectively, from 1,000 anthers inoculated. This technique was then used to produce fertile DH plants of potential agronomic interest from a collection of ten F₁ crosses involving cultivars of high breeding value. From these crosses 849 green plants were obtained and seed was harvested from 702 plants indicating that 83% of green plants were fertile and therefore were spontaneously DHs. No aneuploid plant was obtained. The 702 plants yielded enough seeds to be field tested. One of the DH lines obtained by microspore embryogenesis, named ‘Lanuza’, has been sent to the Spanish Plant Variety Office for Registration by the Batlle Seed Company. This protocol can be used instead of the labor-intensive inter-generic crossing with maize as an economically feasible method to obtain DHs for most crosses involving the durum wheat cultivars grown in Spain.     

Comparison of bread wheat lines selected by doubled haploid, single-seed descent and pedigree selection methods

 Yield performance of each group of ten spring bread wheat lines selected by doubled haploid (DH), single-seed descent (SSD) and pedigree selection (PS) methods from three F₁ crosses was compared with the aim of evaluating the DH method in breeding programs. Populations of 65–97 DH lines and 110 SSD lines per cross were used for selection. PS lines were developed by repeated selections from 1500 F₂ plants. Yield evaluation was performed at the F₆ generation of SSD and PS lines along with DH lines in a 2-year field experiment. It took only 2 years from the planting of wheat materials for DH production to the planting of selected DH lines for yield evaluation. There was no significant difference in grain yield between DH lines and PS lines selected from an F₁ cross whose parental varieties were closely related in their pedigrees. In two crosses with low coefficients of parentage and a large variation in their progenies, grain yield of selected DH lines was significantly lower than those of selected SSD and PS lines. These results confirm that the DH method can save time in obtaining recombinant inbred lines ready for yield evaluation. However, a larger DH population is required to achieve the same level of genetic advance with the PS method in crosses containing greater genetic variation. Received: 23 December 1997 / Accepted: 12 March 1998     

Fertilization and Embryo Development in Wheat x Maize Crosses

The fertilization and embryo development in crosses of hexaploid wheat “Kangxuan 9” X maize “SS 7700” were studied. Of 180 florets fi,ced after pollination 34(18.9%) had embryo and endosperm, 46(25.6%) had only embryo and 12(6.7%) had only endosperm. Percentages of single or double fertilization were higher than that in control (“Chinese Spring” X maize). The hybrid embryos and endosperms obtained were karyotypically unstable and characterized by rapid elimination of the maize chromosomes to produce haploid wheat embryos. The potentials for wheat haploid production and transfer of DNA segments, including transposable elements, from maize to wheat is discussed.     

Inheritance and Sequence Homology Analysis of the Maize DNA Introgressed into the Wheat Doubled Haploid Plant Through Wheat×Maize Cross

A maize (Zea mays L.) genome-specific repeated DNA sequence (clone MR64) has been transferred into one DH line of wheat through wheat (Triticum persicum Vav. ex Zhuk.) and maize cross. In the present study by RFLP analysis the authors proved that this DNA sequence could stably transmit into DH3 plants, the next generation derived from DH2 self-crossing. A similarity search in all DNA databases using BLASTN program showed that the DNA sequence of MR64 had as high as 93% identity to PREM-2 and 79% to Opie-2 in nucleotides. Both PREM-2 and Opie-2 are known as retrotransposons in maize genome, suggesting that MR64 likely is the partial sequence of a maize retrotransposon. Therefore, the results indicate that some retrotransposon might involve the DNA introgression from maize to wheat genome through wide fertilization. Stable inheritance of this maize genome-specific retrotransposon-like DNA in the wheat genome opens up the possibility of using retrotransposon as a new tool for gene tagging, function analysis, and insertional mutagenesis in wheat genome.     

导入小麦加倍单倍体植株的玉米DNA在后代中的遗传及序列同源性分析

作者曾报道了一个玉米（Ｚｅａ ｍａｙｓ Ｌ．）基因组特异的重复序列ＤＮＡ（克隆ＭＲ６４）通过小麦（Ｔｒｉｔｉｃｕｍ ｐｅｒｓｉｃｕｍ Ｖａｖ．ｅｘ Ｚｈｕｋ．）与玉米杂交导入一个小麦加倍单倍体（ＤＨ）植株中。利用分析主宰该重复ＤＮＡ序列可以稳定地传递到小麦ＤＨ３代植株。通过Ｉｎｔｅｒｍｅｔ在ＤＮＡ数据库中进行序列相似性搜寻和同源性比较,结果显示,ＭＲ６４的ＤＮＡ序列和玉米的最近报道的两个逆转座子Ｐ     

The agronomic performance of wheat doubled haploid lines derived from wheat x maize crosses

Summary The agronomic performance of 9 doubled haploid (DH) lines of Chinese Spring, 6 DH lines of Hope, 14 DH lines of the single chromosome substitution line Chinese Spring (Hope 5 A) and their respective parents was analyzed under field conditions. Seventeen Chinese Spring DH lines derived from wheat x Hordeum bulbosum crosses were also included for comparison. No significant variation was detected in either population of Chinese Spring DH lines and neither DH population differed from its parent. The Hope DH lines differed significantly for tiller biomass, spikelet number per ear, ear grain weight and 50-grain weight. However, all the variation could be attributed to the poor performance of only one line. Chinese Spring (Hope 5 A) DH lines showed significant variation for ear emergence time, but this was probably due to genetic heterogeneity in the parental stock. Overall, the results suggest that most DH lines produced by the wheat x maize method resemble their wheat parent, and that the variation induced in DH production is likely to be similar to that found in DHs from wheat x Hordeum bulbosum crosses.