亲和性试验与高等担子菌的系统学

真菌的不亲和性是在有性生殖系统中由基因型所决定的对核配的抑制现象,普遍存在于高等担子菌中。早期关于亲和性的研究大多只涉及其遗传出基础,近年来亲和性试验已被广泛地应用于担子菌系统学与酶和DNA等数据结合作为划分种,探讨生殖隔离机制和物种形成的依据。本文在介绍亲和性概念及其遗传学结构的基础上,简述了亲和性试验的方法,讨论了不亲和性与生物种的关系以及亲和性试验在高等担子菌系统学中的应用原理和实例。     

植物自交不亲和性机理的研究

植物自交不亲和性机理的研究罗光明,杨雅琴（江西中医学院药学系植物室,南昌３３０００６）在自然条件下,任何植物在开花时,其雌性器官既可能接触种内的花粉,也可能同时接触异种的花粉,但是,只有具备一定遗传背景的个体之间才能实现亲和性的交配。在一般情况下,交...     

水稻广亲和性遗传的再研究

水稻广亲和基因的利用是克服亚种间杂种不育性的重要途径。但在广亲和性的遗传上不同研究者的结论不尽一致。以3种有广亲和品种参加的三交组合为研究材料,研究了品种Ketan Nangka的广亲和性遗传。结果表明水稻亚种杂交F1同时存在着雄性不育和雌性不育,但雄性不育对小穗育性的作用大小因组合而异;无论是在雄性不育位点还是雄性不育位点上,Ketan Nangka均具有相对应的中性基因（广亲和基因）;广亲和性的遗传特点与所用的籼粳测验品种间的杂种不育性密切相关;S－5位点的广亲和基因遗传符合单位点孢子体－配子体互作模型。     

高等植物自花花粉的识别与拒绝

高等植物在长期的进化过程中,通过雌蕊识别并拒绝遗传上相近的花粉,防止近亲繁殖、保持遗传多样性,该机制被称为植物自交不亲和性。植物自交不亲和性已成为当今国内外研究的热点。近年来,芸薹属孢子体自交不亲和性、S-RNase调节的配子体自交不亲和性以及罂粟花科配子体自交不亲和性研究比较深入。最近的研究表明,泛素介导的蛋白酶体蛋白质降解途径参与芸薹属孢子体自交不亲和性和S-RNase调节的配子体自交不亲和性反应。另一种蛋白质降解途径,即半胱-天冬胺酸特异的蛋白酶介导的细胞程序化死亡似乎参与罂粟花科配子体自交不亲和性。本文回顾了3种自交不亲和性研究的最新进展,并就其自交不亲和性机制作进一步讨论。     

高等植物自交不亲和性的分子生物学

自交不亲和性是大多数高等植物防止近亲繁殖的一种遗传屏障。它涉及受精时雄配子（花粉）和雌蕊之间的相互作用。目前,已经分离获得了编码控制雌蕊自交不亲和性的Ｓ基因。在孢子体型自交不亲和的芸苔属中,雌蕊Ｓ基因编码Ｓ位点糖蛋白（ＳＬＧ）和Ｓ受体激酶（ＳＲＫ）。它们可能与磷酸化和去磷酸化参与了的某种信号传递有关,最后导致自交花粉生长的抑制。在配子分配体型自交不亲和的茄科中,雌蕊Ｓ位点糖蛋白为一种核糖核酸酶,称     

木兰科植物的杂交亲和性

采用常规杂交育种的方法,在木兰科属内和属间进行了62杂交试验,结果表明,除木兰属的木兰亚属和玉兰亚属之间没有杂交亲和性外,木兰科其他属内都有杂交亲和性,这表明属内不存在生殖隔离,除拟单性木兰属与木兰属的木兰亚属之间有杂交亲和性外,其它属间都没有杂交亲和性,这表明这些属间存在着生殖隔离,因此,木兰科植物的杂交亲和性基本上支持根据形态特征所建立的木兰科科下分类系统,同时,建议将拟单性木兰属与木兰属的木兰亚属合并为木兰属,并将玉兰亚属从木兰属中分出作为玉兰属。     

水稻广亲和性遗传的主基因一多基因混合模型分析

籼、粳亚种间的F1一般表现为半不育,这限制了籼、粳杂种优势的利用。广亲和基因的发现及其遗传研究有助于揭示这种半不育现象的遗传本质,使克服籼、粳亚种间F1的半不育成为可能。本研究采用主基因－多基因混合遗传模型,分析了籼、粳杂交组合3037/02428的P1、P2、F1、B1、B2和F2六世代材料。研究结果显示：广亲和性的遗传除受单个主基因控制外还受多基因的影响。在利用广亲和基因克服亚种间的半不育性时不仅要考虑主基因对育性的作用,也不能忽视多基因对育性的影响。     

白芥自交亲和性分析

对不同来源的8份白芥材料,采用人工自交法分析其自交亲和性。结果显示:白芥的自交亲和性存在较大幅度的变异,自交亲和指数在0.01~4.10之间,8份参试材料中,自交亲和指数小于1的材料有3个,自交亲和指数大于1的材料有5个。表明白芥中存在自交亲和材料,白芥自交亲和性变异不仅存在于材料间,而且也存在于同一材料内不同个体间。按自交亲和指数的高低,可将参试材料分为3种类型:高自交亲和类型(自交亲和指数大于3.00,如民乐洪水芥麻、04(X)等)、自交亲和类型(自交亲和指数为1.00~2.99)、自交不亲和类型(自交亲和指数0.00~1.00)。     

植物孢子体型自交不亲和性研究进展

本文综述了植物孢子体型自交不亲和性的有关研究进展,对这一生殖特性的遗传控制机理作了概述,探讨了Ｓ复等位基因之间的关系及其蛋白质产物特征,介绍了自交不亲和性测定方法的改进和发展．     

几个水稻株系的亲和性测定及微卫星标记分析

利用典型的籼稻南京11号、典型的粳稻秋光对16个水稻株系的亲和性进行了测定,测交结果表明,NLl73、NL15、NL61、NL67、NL82和NL279表现亲籼性,NL208表现亲粳性,NL78表现一定广亲和性,其余株系与籼、粳测验种杂交育性都不高。根据测交结果选择不同育性的株系用分布于12条染色体上的前人证明籼粳稻间有多态性的56个微卫星标记进行分析,在微卫星标记聚类分析基础上计算梗型性判别值Dj,并据此把NL173、NLl5、NL78、NL58判别为偏籼型,而NL208为偏粳型。综合亲和性测交结果和分子标记分析结果发现,在亲和性测交中表现亲籼的2个株系NL173、NL15分子标记判别为偏籼类型,杂交亲和性表现亲粳的株系NL208分子标记判断为偏粳类型,表现广亲和特性的株系NL78被分子标记判别为偏籼类型,与测验种杂交育性均不高的NL58分子标记判别为偏籼型。     

Natural variation for a hybrid incompatibility between two species of Mimulus

Understanding the process by which hybrid incompatibility alleles become established in natural populations remains a major challenge to evolutionary biology. Previously, we discovered a two-locus Dobzhansky-Muller incompatibility that causes severe hybrid male sterility between two inbred lines of the incompletely isolated wildflower species, Mimulus guttatus and M. nasutus. An interspecific cross between these two inbred lines revealed that the M. guttatus (IM62) allele at hybrid male sterility 1 (hms1) acts dominantly in combination with recessive M. nasutus (SF5) alleles at hybrid male sterility 2 (hms2) to cause nearly complete hybrid male sterility. In this report, we extend these genetic analyses to investigate intraspecific variation for the hms1-hms2 incompatibility in natural populations of M. nasutus and M. guttatus, performing a series of interspecific crosses between individuals collected from a variety of geographic locales. Our results suggest that hms2 incompatibility alleles are common and geographically widespread within M. nasutus, but absent or rare in M. guttatus. In contrast, the hms1 locus is polymorphic within M. guttatus and the incompatibility allele appears to be extremely geographically restricted. We found evidence for the presence of the hms1 incompatibility allele in only two M. guttatus populations that exist within a few kilometers of each other. The restricted distribution of the hms1 incompatibility allele might currently limit the potential for the hms1-hms2 incompatibility to act as a species barrier between sympatric populations of M. guttatus and M. nasutus. Extensive sampling within a single M. guttatus population revealed that the hms1 locus is polymorphic and that the incompatibility allele appears to segregate at intermediate frequency, a pattern that is consistent with either genetic drift or natural selection.     

Cytonuclear incompatibility contributes to the early stages of speciation

Genetic incompatibility is a hallmark of speciation. Cytonuclear incompatibilities are proposed to be among the first genetic barriers to arise during speciation. Accordingly, reproductive isolation (RI) within species should be heavily influenced by interactions between the organelle and nuclear genomes. However, there are few clear examples of cytonuclear incompatibility within a species. Here, we show substantial postzygotic RI in first‐generation hybrids between differentiated populations of an herbaceous plant (up to 92% reduction in fitness). RI was primarily due to germination and survival, with moderate RI for pollen viability. RI for survival was asymmetric and caused by cytonuclear incompatibility, with the strength of incompatibility linearly related to chloroplast genetic distance. This cytonuclear incompatibility may be the result of a rapidly evolving plastid genome. Substantial asymmetric RI was also found for germination, but was not associated with cytonuclear incompatibility, indicating endosperm or maternal‐zygote incompatibilities. These results demonstrate that cytonuclear incompatibility contributes to RI within species, suggesting that initial rates of speciation could be influenced by rates of organelle evolution. However, other genetic incompatibilities are equally important, indicating that even at early stages, speciation can be a complex process involving multiple genes and incompatibilities.     

Two allelic genes responsible for vegetative incompatibility in the fungus Podospora anserina are not essential for cell viability

Summary Vegetative incompatibility is a lethal reaction that destroys the heterokaryotic cells formed by the fusion of hyphae of non-isogenic strains in many fungi. That incompatibility is genetically determined is well known but the function of the genes triggering this rapid cell death is not. The two allelic incompatibility genes, s and S, of the fungus Podospora anserina were characterized. Both encode 30 kDa polypeptides, which differ by 14 amino acids between the two genes. These two proteins are responsible for the incompatibility reaction that results when cells containing s and S genes fuse. Inactivation of the s or S gene by disruption suppresses incompatibility but does not affect the growth or the sexual cycle of the mutant strains. This suggests that these incompatibility genes have no essential function in the life cycle of the fungus.     

A new look at incompatibility relationships in higher plants

Summary Pollen tube growth was evaluated using an 18-step scale after both intra- and interspecific pollinations of genotypically widely differing diploid potato species and potato dihaploids expressing monofactorial gametophytic incompatibility. The results obtained account for a wide array of types of pollen tube growth resulting from crossing partners with distinct incompatibility behavior. Based on the assumption that inhibition of pollen tubes is the rule and solely prevented by the pollen itself, a model proposing one common cause underlying different mechanisms for both intraspecific selfincompatibility and interspecific incompatibility in diploids is put forward. Data supporting the model are presented from the experimental results of this study and from the literature. The strength of pollen-style interaction depends on particular S-alleles in combination with recognition and activity properties of the basic S-genotypes. The model is suitable to explain all former observations on incompatibility in diploids with a gametophytic system of incompatibility and, with modifications of the manner of phenotypic expression, also in plants with sporophytic incompatibility. The proposed scheme of pollen tube growth phenotypes permits prediction of pollen tube growth behavior in an intended cross combination. The model is based on both classical Mendelian genetics and recent molecular genetic insight.     

A genomic approach to identify hybrid incompatibility genes

Uncovering the genetic and molecular basis of barriers to gene flow between populations is key to understanding how new species are born. Intrinsic postzygotic reproductive barriers such as hybrid sterility and hybrid inviability are caused by deleterious genetic interactions known as hybrid incompatibilities. The difficulty in identifying these hybrid incompatibility genes remains a rate-limiting step in our understanding of the molecular basis of speciation. We recently described how whole genome sequencing can be applied to identify hybrid incompatibility genes, even from genetically terminal hybrids. Using this approach, we discovered a new hybrid incompatibility gene, gfzf, between Drosophila melanogaster and Drosophila simulans, and found that it plays an essential role in cell cycle regulation. Here, we discuss the history of the hunt for incompatibility genes between these species, discuss the molecular roles of gfzf in cell cycle regulation, and explore how intragenomic conflict drives the evolution of fundamental cellular mechanisms that lead to the developmental arrest of hybrids.     

An unknown mechanism promotes somatic incompatibility in Ceratobasidium bicorne

Strains of Ceratobasidium bicorne (anamorph uninucleate Rhizoctonia), causing root dieback in nursery-grown conifer seedlings, were fruited in the laboratory and the pairing interactions among sibling, single-basidiospore progeny were investigated. No mating reactions were observed. Instead, a high frequency of somatic incompatibility was observed in progeny pairings, indicated by a killing reaction in hyphal anastomosis and by formation of a demarcation line. The F1 progeny also could be fruited, and the level of somatic incompatibility within the F2 progeny remained high, even if lower than in the F1 progeny. The interaction types in pairings within a family of progeny were similar in all respects to those between field isolates, indicating that the species is homothallic. The uninucleate condition of vegetative cells and the basidial characteristics would indicate homokaryotic fruiting, but the possibility of pseudohomothallism remains. We currently are not able to provide an explanation for the mechanism promoting somatic incompatibility in this species, but it seems likely that the classic heterogenic model of somatic incompatibility recognized in basidiomycetes is not applicable here. Alternative mechanisms are discussed.     

Trimorphic incompatibility in Eichhornia azurea (Pontederiaceae)

Eichhornia azurea (Pontederiaceae) is a mat-forming, clonal aquatic that inhabits lakes, marshes and river systems in many parts of the Neotropics. The species is tristylous with long-, mid-, and short-styled morphs commonly represented in natural populations. To investigate whether E. azurea possesses a trimorphic incompatibility system typical of tristylous species, we conducted a controlled pollination experiment on 15 clones representing the three style morphs from a natural population near Rosario, Argentina. Comparisons of fruit and seed set following self-, illegitimate, and legitimate pollinations clearly demonstrated the presence of trimorphic incompatibility in E. azurea. Self- and illegitimate pollinations produced significantly less fruit and seed than legitimate pollinations in all three style morphs. Pollen from the two anther levels within a flower exhibited contrasting compatibility relations in self-pollinations. In common with several other tristylous species in Pontederiaceae, the expression of self-incompatibility was weakest in the mid-styled morph and strongest in the short-styled morph. We discuss the ecological and evolutionary significance of the partial expression of trimorphic incompatibility in E. azurea. Received: 3 May 1999 / Revision accepted: 27 July 1999     

Diverse paths to hybrid incompatibility in Arabidopsis

One of the most essential questions of biology is to understand how different species have evolved. Hybrid incompatibility, a phenomenon in which hybrids show reduced fitness in comparison with their parents, can result in reproductive isolation and speciation. Therefore, studying hybrid incompatibility provides an entry point in understanding speciation. Hybrid incompatibilities are known throughout taxa, and the underlying mechanisms have mystified scientists since the theory of evolution by means of natural selection was introduced. In plants, it is only in recent years that the high‐throughput genetic and molecular tools have become available for the Arabidopsis genus, thus helping to shed light on the different genes and molecular and evolutionary mechanisms that underlie hybrid incompatibilities. In this review, we highlight the current knowledge of diverse mechanisms that are known to contribute to hybrid incompatibility.