芥菜型油菜与白菜正反杂交的胚胎学研究

利用荧光技术对芥菜型油菜（Brassica juncea）与白菜（B．pekinesis）种间正反杂交后花粉萌发和花粉管生长过程进行了观察。结果显示：芥菜型油菜与白菜正交授粉后,花粉在柱头上能正常萌发,多数花粉管沿花柱到达胚珠完成受精,且受精方式有珠孔受精、合点受精和中部受精,少量花粉管生长不正常,出现花粉管顶端膨大扭曲,花粉管分支等异常现象;反交授粉后,花粉在柱头上萌发时柱头乳突细胞产生强烈胼胝质反应,影响花粉管生长,只有少量花粉管通过花柱到达胚珠完成受精。用石蜡切片技术观察了正反杂交后杂种的胚胎发育,正交杂种胚胎发育较早,胚和胚乳生长较正常,杂种胚一般均能发育至成熟;反交杂种胚发育至心型期便不能继续发育,胚乳也停滞在游离核阶段并最终败育。综合分析表明,芥菜型油菜与白菜正反杂交都存在一定程度的受精不亲和性。     

芥菜型油菜和白菜型油菜种间杂种遗传分析

种间杂交是一种拓宽栽培作物遗传基础和转移优良性状的重要手段,已经广泛地用于作物品质的改良。本研究通过芥菜型油菜（Brassica juncea L.）和白菜型油菜（Brassica rapa L.）种间杂交,将芥菜型油菜的有利性状转移到白菜型油菜中,创造新型白菜型油菜,以改良白菜型油菜的农艺性状、提高抗逆性和拓宽其遗传基础。研究结果表明：以芥菜型油菜作母本、白菜型油菜作父本的杂交组合较易获得杂交种子,杂种F1植株营养生长具有较明显的杂种优势,但花粉完全不育;以白菜型油菜回交获得的BC1植株间表型差异明显,平均花粉可染率为34.8%,介于 0~84%之间,群体自交不亲和;BC1F1和BC2群体变异广泛,出现自交亲和植株和黄籽植株,平均花粉可染率分别为79.7%和79.1%。     

甘蓝型油菜和芥菜型油菜种间杂交研究

甘蓝型油菜与芥菜型油菜杂交研究结果表明,杂交结实力与杂交组合方式以及参与杂交的亲本材料有关,以芥菜型油菜作母本的杂交结实力高于以甘蓝型作母本的组合：芥×甘杂交组合的平均结实数／花为 ２．６４ 粒,而甘×芥杂交组合的平均结实数／花为 ０．１０ 粒。芥甘杂种一代形态特征和生育期介于双亲之间,甘芥杂种一代不表现整齐的中间类型,株间差异明显;总体来看,芥甘杂种一代与双亲回交的结实力（０．４０,０．２１）低于甘芥杂种一代与双亲回交的结实力（３．３０,１．７４）,无论是芥甘杂种一代还是甘芥杂种一代,用甘蓝型油菜作父本回交的结实力高于用芥菜型油菜作父本回交的结实力,但也有个别回交组合出现例外,不表现上述规律。 Ｂ Ｃ１ 代种子当年播种出苗率低（１８．５％ ）,群体株间性状差异明显,生育期极不一致。芥甘杂种一代与甘蓝型油菜亲本第二次回交,其平均结实数／花较回交一代提高 １．０８ 粒, Ｂ Ｃ２ 代种子当年播种出苗率仍较低,但较对应的 Ｂ Ｃ１ 代稍有提高,群体中出现趋回交父本性状但雄性育性彻底退化的植株。芥甘杂种一代自由授粉所得 Ｆ２ 群体是一个变异极为丰富的遗传群体。     

芥菜型和甘蓝型油菜及其杂种后代种子硫甙组成差异的研究

用高效液相色谱技术分析了芥菜型油菜（Ｂｒａｓｓｉｃａ ｊｕｎｃｅａ）和甘蓝型油菜（Ｂｒａｓｓｉｃａ ｎａｐｕｓ）种间杂种后代及共亲本的硫甙组成。结果表明,与亲本农艺性状相似的后代,那么其硫甙组成与亲本亦相似。各后代中硫甙组成与亲本相比,虽发生了不同管理的变化,但都有倾向母体的趋势。芥菜型油菜烯丙基硫甙含量,２－羟基－３－丁烯基硫甙含量低,而甘蓝型油菜２－羟基３－丁烯基硫甙含量高,烯丙基硫甙含量最低     

白菜型油菜,芥菜型油菜与诸葛菜的属间杂交合子胚的组织培养

TissueCultureofZygoticEmbryosofIntergenericHybridizationAmongBrassicacampestris,B．junceaandOrychophragmusviolaceusWUYan－You,JIANGJiu－Yu（InstituteofGeochemstry,TheAcademyofScience,Guiyang550002）1植物名称白菜型油菜（Brassicacampestris）品种川油8号（2n=20）、芥菜型油菜（B.juncea）品种沪州四棱（2n=36）和诸葛菜（Orychophragmusviolaceus,2n=24）。2材料类别白菜型油菜和芥菜型油菜作母本,诸葛菜作父本,人工授粉22d“萝卜”角果中的未成熟杂种胚。3培养条件分化培养基为MS＋6-BA2mg／L（单…     

芥菜型油菜和芥蓝种间杂种的获得及其性状表现

种间杂交是拓宽遗传种质资源,创制新物种、新材料的重要手段。利用芥菜型油菜和芥蓝种间杂交人工创制其种间杂种,并对其形态学、细胞学特点进行分析。结果表明:不同的杂交组合30 d后的子房残留数和获得幼胚数差异明显,杂交组合是影响种间杂交结子(幼胚)的重要因素;通过形态学鉴定出真杂种36份,均表现为较强的营养体杂种优势。真杂种减数分裂均为异常,在减数分裂后期具有不同程度的染色体丢失现象;无性系染色体数目部分为27条,部分为27~34条。真杂种花粉育性可染率在0~47.87%,自交结实率介于0~3.65%之间。     

白菜型油菜与蓝花子杂交的初步研究

通过胚胎培养,成功地获得了白菜型油菜（Ｂｒａｓｉｃａｃａｍｐｅｓｔｒｉｓ）与蓝花子（ＲａｐｈａｎｕｓｓａｔｉｖｕｓＬｖａｒｒａｐｈａｎｉｓｔｒｏｉｄｅｓＭａｋｉｎｏ）的属间杂种。该杂种具有两种类型;一种为大花类型,一种为小花类型。对它们进行花粉母细胞减数分裂的观察结果表明：小花类型为未加倍的杂种ＭＩ,存在１９个未配对染色体,大花类型为加倍或部分加倍杂种,加倍类型ＭＩ,１９个二价体排列在赤道板上;部分加倍类型ＡＩ,具有１０－１０－９的染色体组分割现象。大花类型具有可育性;它能够产生很多ｎ＝１９及ｎ＝９、ｎ＝１０的正常配子。染色体组分割能够产生倍半二倍体,它能用来研究染色体的功能和开展染色体工程。     

甘蓝型油菜和白菜型油菜种间杂种的小孢子培养

利用分离小孢子培养从甘蓝型油菜（Ｂｒａｓｓｉｃａ ｎａｐｕｓ）和白菜型油菜（Ｂ． ｃａｍ ｐｅｓｔｒｉｓ）种间杂种中获得了胚和再生植株。所用的培养程序是,将甘蓝型油菜和白菜型油菜杂种小孢子在蔗糖浓度为１７％ 、ＢＡ 为０．１ ｍ ｇ／Ｌ的液体ＮＬＮ 培养基中３２ ℃下暗培养４８ ｈ,再转入蔗糖浓度为１０％ 的ＮＬＮ 培养液中２５ ℃下暗培养３ 周。不同杂种间小孢子胚胎发生能力存在差异,其中ＵＭ９２１（白菜型油菜）×９１１１８６（甘蓝型油菜）正反交杂种的胚产量显著高于供试的其它组合。供体植株种植在１０ ℃／５ ℃（昼／夜）条件下能显著改善杂种小孢子胚产量和质量。杂种小孢子胚产量和杂种植株每荚种子数存在极显著正相关,但杂种植株的花粉育性和胚产量间相关不显著。大多数甘蓝型油菜和白菜型油菜杂种小孢子胚衍生植株为非整倍体,２２．８％ 的植株起源于具亲本染色体数的小孢子,几乎全部为ｎ＝ １９ 的类型。讨论了影响种间杂种小孢子胚胎发生的因素以及种间杂种小孢子培养技术的可能用途     

我国芥菜型油菜品种遗传多样性初探

用ＲＡＰＤ技术对包括春、冬芥菜型采及国外品种在内的３６个芥菜型油菜品种的遗传多样性进行了分析。在扩增得到的１２８条ＤＮＡ带中,多态性ＤＮＡ片段达８８．２８％。分析表明：春 油菜间遗传差异较大,国内冬性芥菜型油菜地方种多样性水平较高,２５份冬性品种分属Ⅰ、Ⅱ和Ⅲ类群,而春性芥菜型 采地方种均归于Ⅳ类;印度的ＲＬＭ１９８与四川的珙县金黄油菜、澳大利亚品种与我国春油菜品种亲缘关系密切。     

芥菜型多室油菜与甘蓝型油菜的种间远缘杂交

通过对芥菜型多室油菜与甘蓝型油菜种间杂交 以下简写为芥×甘或甘×芥 的结实性、交配性以及不同甘蓝型油菜对交配性的影响等研究发现:芥、甘正反交形成的饱满种子数较少,其形成种子的能力弱,但是芥×甘与甘×芥杂交相比,芥×甘形成饱满种子的能力较强,受精能力以及杂种胚胎的发育能力也强,在授粉后的子房发育上二者无显著差异.所以,芥菜型多室油菜与甘蓝型油菜种间杂交创建新资源时宜采用芥×甘杂交方式;不同甘蓝型油菜品种与芥菜型多室油菜正反交的结角率、受精指数、结籽指数和可交配指数均不相同,但可交配指数的变异系数最大.因此,筛选可交配性强的甘蓝型基因型应着眼于可交配指数高的甘蓝型油菜亲本材料,根据本试验结果,芥菜型多室油菜与甘蓝型油菜93-221-1杂交形成的杂种胚具有较强的可发育性.     

芥菜型油菜与埃塞俄比亚芥杂种基因组原位杂交分析

原产于非洲的埃塞俄比亚芥(Brassica carinata,2n=34,BBCC)具有适应于炎热干旱地区种植等特点,是改良我国芥菜型油菜(B.juncea,2n=36,AABB)的重要种质资源。本研究用基因组原位杂交方法(GISH,Genomic in situ hybridization)分析了芥菜型油菜与埃塞俄比亚芥种间杂种花粉母细胞的染色体分离,发现在后期I染色体主要以17∶18类型分离,其次是16∶19,染色体落后现象偶然发生,其中B染色体组以8∶8的分离比率较高,表明不同来源的B染色体可正常配对分离。本研究表明,芥菜型油菜与埃塞俄比亚芥远缘杂交,通过染色体同源重组(B染色体间),以及部分同源染色体配对交换的方式(A、B、C基因组间),有可能将埃塞俄比亚芥优良遗传成分转移到芥菜型油菜中。     

Male sterility caused by cytoplasm of Brassica oxyrrhina in B. campestris and B. juncea

Summary Synthetic alloploid Brassica oxyrrhina (2n = 18, OO) x B. campestris (2n = 20, AA) was repeatedly backcrossed with B. campestris to place B. campestris nucleus in the cytoplasm of B. oxyrrhina. Alloplasmic plants, obtained in BC₅ generation, were stably male sterile but mildly chlorotic during initial development. Synthetic alloploid B. oxyrrhina-campestris was also hybridized with B. juncea to transfer B. oxyrrhina cytoplasm. Segregation for green and chlorotic plants was observed in BC₁ and BC₂ generations. By selection, however, normal green male sterile B. juncea was obtained in BC₃. Pollen abortion in both B. campestris and B. juncea is post-meiotic.     

Interspecific hybridization between Brassica juncea and B. spinescens through protoplast fusion

Hypocotyl derived protoplasts of B. juncea cv. RLM-198 were fused with mesophyll protoplasts of B. spinescens using polyethylene glycol to produce interspecific hybrids. Fusion products could be microscopically identified by characteristics of the protoplasts of both parents in the hybrid cells; they are colourless and vacuolated like the hypocotyl protoplasts and possess chloroplasts of the mesophyll protoplasts. The heterokaryotic fusion frequency was around 5%. However, the frequency of calli regenerating hybrid shoots was more than 10% of the regenerating calli. Putative somatic hybrids had morphological features characteristic of both the parents. Twelve plants analysed cytologically, possessed 52 chromosomes (26_II) at meiosis representing the complete genomes of B. juncea (18_II) and B. spinescens (8_II). For esterase isozymes, the hybrids had bands of Doth the parents. Hybrid nature of some of the plants was confirmed by their close resemblance to B. juncea, chromosome number and isozyme bands of B. spinescens as in Rsp-19. Somatic hybrids had rudimentary, non-dehiscent anthers and completely sterile pollen. However, on back crossing with B. juncea, 10 out of 12 plants produced seeds and about 100 plants were realized.Abbreviations PEG Polyethylene glycol     

Genotypic Differences in Leaf Water Relations between Brassica juncea and B. napus

Various kinds of measurement of tissue water status were madeseveral times during water stress and recovery in Brassica juncea(cv Canadian Black) and B napus (cv Drakkar) Unstressed plantsof the two species had similar leaf water potentials (_w), solute(_s) and turgor potentials (_p) Values of relative water content(RWC) and the slope of the linear relationship between _p andRWC (_p/RWC) were greater in B napus than in B juncea Statistical correlations of pooled data for the watered andstressed treatments differentiated the relationships among RWC,_w and its components in the two species The major statisticaldifference was that _p/RWC was related to RWC in B napus andto _w and _s in B juncea A decline in _p/RWC with decreasing _sin B juncea may be a mechanism for maintaining _p at low soilwater potentials through maintenance of more elastic cell walls. Brassica juncea, Brassica napus, osmotic adjustment, tissue elasticity, water relations     

Tracing B-genome chromatin in Brassica napus x B. juncea interspecific progeny.

We used polymerase chain reaction (PCR) and fluorescence in situ hybridization (FISH) techniques to demonstrate the presence of Brassica B-genome chromosomes and putative B-genome introgressions in B. napus x B. juncea interspecific progeny. The B-genome--specific repeat sequence pBNBH35 was used to generate PCR products and FISH probes. The highest frequencies of viable progeny were obtained when B. napus was the maternal parent of the interspecific hybrid and the first backcross. B-genome--positive PCR assays were found in 34/51 fertile F2 progeny (67%), which was more than double the proportion found in fertile BC(1) progeny. Four B-genome--positive F(2)-derived families and 1 BC(1)-derived family were fixed or segregating for B. juncea morphology in the F(4) and BC(1)S(2), respectively, but in only 2 of these families did B. juncea-type plants exhibit B. juncea chromosome count (2n = 36) and typical B-genome FISH signals on 16 chromosomes. The remaining B. juncea-type plants had B. napus chromosome count (2n = 38) and no B-genome FISH signals, except for 1 exceptional F(4)-derived line that exhibited isolated and weak B-genome FISH signals on 11 chromosomes and typical A-genome FISH signals. B. juncea morphology was associated with B-genome--positive PCR signals but not necessarily with 16 intact B-genome chromosomes as detected by FISH. B-genome chromosomes tend to be eliminated during selfing or backcrossing after crossing B. juncea with B. napus, and selection of lines containing B-genome chromatin during early generations would be promoted by use of this B-genome repetitive marker.     

Simple Y-Autosomal Incompatibilities Cause Hybrid Male Sterility in Reciprocal Crosses Between Drosophila virilis and D. americana

Postzygotic reproductive isolation evolves when hybrid incompatibilities accumulate between diverging populations. Here, I examine the genetic basis of hybrid male sterility between two species of Drosophila, Drosophila virilis and D. americana. From these analyses, I reach several conclusions. First, neither species carries any autosomal dominant hybrid male sterility alleles: reciprocal F₁ hybrid males are perfectly fertile. Second, later generation (backcross and F₂) hybrid male sterility between D. virilis and D. americana is not polygenic. In fact, I identified only three genetically independent incompatibilities that cause hybrid male sterility. Remarkably, each of these incompatibilities involves the Y chromosome. In one direction of the cross, the D. americana Y is incompatible with recessive D. virilis alleles at loci on chromosomes 2 and 5. In the other direction, the D. virilis Y chromosome causes hybrid male sterility in combination with recessive D. americana alleles at a single QTL on chromosome 5. Finally, in contrast with findings from other Drosophila species pairs, the X chromosome has only a modest effect on hybrid male sterility between D. virilis and D. americana.SPECIATION occurs when populations evolve one or more barriers to interbreeding (Dobzhansky 1937; Mayr 1963). One such barrier is intrinsic postzygotic isolation, which typically evolves when diverging populations accumulate different alleles at two or more loci that are incompatible when brought together in hybrid genomes; negative epistasis between these alleles renders hybrids inviable or sterile (Bateson 1909; Dobzhansky 1937; Muller 1942). Classical and recent studies in diverse animal taxa have provided support for two evolutionary patterns that often characterize the genetics of postzygotic isolation (Coyne and Orr 1989a). The first, Haldane''s rule, observes that when there is F₁ hybrid inviability or sterility that affects only one sex, it is almost always the heterogametic sex (Haldane 1922). Over the years, many researchers have tried to account for this pattern, but only two ideas are now thought to provide a general explanation: the “dominance theory,” which posits that incompatibility alleles are generally recessive in hybrids, and the “faster-male theory,” which posits that genes causing hybrid male sterility diverge more rapidly than those causing hybrid female sterility (Muller 1942; Wu and Davis 1993; Turelli and Orr 1995; reviewed in Coyne and Orr 2004). In some cases, however, additional factors might contribute to Haldane''s rule, including meiotic drive, a faster-evolving X chromosome, dosage compensation, and Y chromosome incompatibilities (reviewed in Laurie 1997; Turelli and Orr 2000; Coyne and Orr 2004).The second broad pattern affecting the evolution of postzygotic isolation is the disproportionately large effect of the X chromosome on heterogametic F₁ hybrid sterility (Coyne 1992). This “large X effect” has been documented in genetic analyses of backcross hybrid sterility (e.g., Dobzhansky 1936; Grula and Taylor 1980; Orr 1987; Masly and Presgraves 2007) and inferred from patterns of introgression across natural hybrid zones (e.g., Machado et al. 2002; Saetre et al. 2003; Payseur et al. 2004). However, in only one case has the cause of the large X effect been unambiguously determined: incompatibilities causing hybrid male sterility between Drosophila mauritiana and D. sechellia occur at a higher density on the X than on the autosomes (Masly and Presgraves 2007). Testing the generality of this pattern will require additional high-resolution genetic analyses in diverse taxa (Presgraves 2008). But whatever its causes, there is now general consensus that the X chromosome often plays a special role in the evolution of postzygotic isolation (Coyne and Orr 2004).The contribution of the Y chromosome to animal speciation is less clear. Y chromosomes have far fewer genes than the X or autosomes, and most of these genes are male specific (Lahn and Page 1997; Carvalho et al. 2009). In Drosophila species, the Y chromosome is typically required for male fertility, but not for viability (Voelker and Kojima 1971). How often, then, does the Y chromosome play a role in reproductive isolation? In crosses between Drosophila species, hybrid male sterility is frequently caused by incompatibilities between the X and Y chromosomes (Schafer 1978; Heikkinen and Lumme 1998; Mishra and Singh 2007) or between the Y and heterospecific autosomal alleles (Patterson and Stone 1952; Vigneault and Zouros 1986; Lamnissou et al. 1996). In crosses between D. yakuba and D. santomea, the Y chromosome causes F₁ hybrid male sterility, and accordingly, shows no evidence for recent introgression across a species hybrid zone (Coyne et al. 2004; Llopart et al. 2005). In mammals, reduced introgression of Y-linked loci (relative to autosomal loci) has been shown across natural hybrid zones of mice (Tucker et al. 1992) and rabbits (Geraldes et al. 2008), suggesting that the Y chromosome contributes to reproductive barriers.Here I examine the genetic basis of hybrid male sterility between two species of Drosophila, D. virilis and D. americana. These species show considerable genetic divergence (K_s ∼0.11, Morales-Hojas et al. 2008) and are currently allopatric: D. virilis is a human commensal worldwide with natural populations in Asia, and D. americana is found in riparian habitats throughout much of North America (Throckmorton 1982; McAllister 2002). Nearly 70 years ago, Patterson et al. (1942) showed that incompatibilities between the D. americana Y chromosome and the second and fifth chromosomes from D. virilis cause hybrid male sterility, a result that was confirmed in a more recent study (Lamnissou et al. 1996). Another study suggested that the X chromosome might play the predominant role in causing hybrid male sterility between D. virilis and D. americana (Orr and Coyne 1989). But because previous genetic analyses had to rely on only a few visible markers to map hybrid male sterility, they lacked the resolution to examine the genomic distribution of incompatibility loci.Using the D. virilis genome sequence, I have developed a dense set of molecular markers to investigate the genetic architecture of hybrid male sterility between D. virilis and D. americana. In this study, I perform a comprehensive set of crosses to address several key questions: What is the effect of the X chromosome on hybrid male sterility between D. virilis and D. americana? What is the effect of the Y chromosome? Approximately how many loci contribute to hybrid male sterility between these Drosophila species? Perhaps surprisingly, the answers to these questions differ dramatically from what has been found for other Drosophila species, including the well-studied D. melanogaster group.     

遗传分析中“正反交结果”的几点归纳

在遗传教学中,"正反交结果"是判断遗传方式的重要依据.通过对"正反交结果"的几点探究,从而总结出正反交结果相同为细胞核遗传.正反交结果不相同,若子代雌雄表现型不一致者为伴性遗传;若子代表现型似母本性状为细胞质遗传;若分离比表现延迟一代者为母性影响.     

Inheritance of rapeseed (Brassica napus)-specific RAPD markers and a transgene in the cross B. juncea x (B. juncea x B. napus)

We have examined the inheritance of 20 rapeseed (Brassica napus)-specific RAPD (randomly amplified polymorphic DNA) markers from transgenic, herbicide-tolerant rapeseed in 54 plants of the BC₁ generation from the cross B. junceax(B. junceaxB. napus). Hybridization between B. juncea and B. napus, with B. juncea as the female parent, was successful both in controlled crosses and spontaneously in the field. The controlled backcrossing of selected hybrids to B. juncea, again with B. juncea as the female parent, also resulted in many seeds. The BC₁ plants contained from 0 to 20 of the rapeseed RAPD markers, and the frequency of inheritance of individual RAPD markers ranged from 19% to 93%. The transgene was found in 52% of the plants analyzed. Five synteny groups of RAPD markers were identified. In the hybrids pollen fertility was 0–28%. The hybrids with the highest pollen fertility were selected as male parents for backcrossing, and pollen fertility in the BC₁ plants was improved (24–90%) compared to that of the hybrids.