植物交配系统的进化、资源分配对策与遗传多样性

影响植物自交率进化的选择力量主要体现在两个方面：当外来花粉量不足时，自交可以提高植物的结实率，即雌性适合度（繁殖保障）；而如果进行自交的花粉比异交花粉更易获得使胚珠受精的机会，那么自交也可以提高植物的雄性适合度（自动选择优势）。但是，鉴别什么时候是繁殖保障、什么时候是自动选择优势导致了自交的进化却是极其困难的。花粉贴现降低了自交植物通过异交花粉途径获得的适合度，即减弱了自动选择优势，而近交衰退既减少了自动选择优势也减少了繁殖保障给自交者带来的利益。具有不同交配系统的植物种群将具有不同的资源分配对策。理论研究已经说明，自交率增加将减少植物对雄性功能的资源分配比例，但将使繁殖分配加大，而且在一定条件下交配系统的改变甚至可以导致植物生活史发生剧烈变化，即从多年生变为一年生。文献中支持自交减少植物雄性投入的证据有很多，但是对繁殖分配与自交率的关系目前还没有系统的研究。资源分配理论可以解释植物繁育系统的多样性，尤其是能够说明为什么大多数植物都是雌雄同体的。自交对植物种群遗传结构的影响是减少种群内的遗传变异，增加种群间的遗传分化。长期以来人们一直猜测，自交者可能会丢掉一些长期进化的潜能，目前这个假说得到了一些支持。     

珍稀濒危物种格木传粉方式和交配系统的初步研究

为研究格木(Erythrophleum fordii Oliv.)的传粉方式和交配系统,在鼎湖山国家级自然保护区对珍稀濒危树种格木进行野外观察,花的微器官(花粉和柱头)用扫描电镜观察,并进行控制授粉实验和遗传分析。结果表明,格木具有颜色亮丽和散发香味的总状花序,格木花粉包被厚重的粘性物质,柱头没有易于捕获花粉的结构,风媒传粉没有坐果,推断格木应该是通过虫媒传播花粉,或者主要是通过虫媒传播。遗传分析和在不同繁殖环境的两棵目标树的坐果情况表明,格木偶尔可以自交产生后代,但异交占据着绝对的优势,鼎湖山格木种群的异交率达到90.6%。格木传粉方式和交配系统的研究有利于对格木进行保护和保育。     

利用SSR荧光标记对野慈姑异交率的估测

对自交亲和植物交配系统进行估测,有利于了解植物的繁殖状态、自异交进化的轨迹和特定种群的自然历史或选择压力。自交亲和的野慈姑有性繁殖和克隆繁殖并存,且其花序内和无性系分株间存在雌雄花同时开放的现象即给自交带来了机会。本研究利用SSR标记估测野慈姑自然种群的异交水平,并比较分析异交率估测中荧光定量法的准确性和优势,探讨野慈姑不同自然种群微卫星位点的多态性。结果表明,从28对SSR引物中筛选出3对多态性较高的引物,其多种群水平的位点数分别是5、6、6;对1个自然种群的6棵植株共计31个果实的异交率进行估测,其整体异交率为92.87%±2.5%,揭示了野慈姑自然种群的交配系统以异交为主,且无性繁殖对后代的贡献有限;单引物水平下,荧光定量技术检测出的多态性位点数和杂合率均高于NativePAGE成像电泳,且其对异交率估测的结果也更准确;另外,从检测效率实验耗时和实验成本等方面综合分析,本研究推荐使用荧光定量技术。     

基于生物学物种定义探讨物种形成理论与验证的研究进展

物种形成是进化生物学研究的一个永恒主题, 由于生物群体进化是连续和动态的, 物种界限变得难于界定。本文首先讨论了3种地理物种形成模式(同域、邻域及异域), 并分析了近期报道的研究证据。其次, 评述了合子后生殖隔离机制的分子遗传基础和应用群体基因组数据分析的证据, 包括BDMI模型(Bateson-Dobzhansky-Muller incompatibility)、QTLs (quantitative trait loci)、霍尔丹法则及大X染色体效应。最后, 探讨了交配系统作为合子前隔离机制之一与物种形成的关系, 认为近交或自交通过扩大种群遗传结构分化, 增强不同交配系统的种群间不对称基因渐渗, 或种群间无基因渐渗等途径, 促进新物种形成。已知植物交配系统的演化更倾向于从异交(或自交不亲和)向自交(或近交亲和)方式, 花性状和基因组的分化推动形成所谓的自交综合征, 研究交配系统驱动或强化物种形成模式对认识植物物种形成机制有重要意义。     

植物种群交配系统、亲本分析以及基因流动研究

 在过去的二十年中,有关植物种群交配与散布过程的研究与日俱增,重点集中在利用母本子代系列(Maternal progeny arrays)来估计种群间自交与异交的相对比例,种群的花粉散布与雄性育性变异的模式。早期的研究主要依靠排除法来确定亲本,但几乎同时也意识到基因流动事件几乎是检测不到的。在大多数估计中,难以做到为大多数非迁移子代确定唯一的亲本。因此,基因流动与雄性育性的最大似然性方法得以引入该领域的研究。本文介绍了用单位点和多位点模型来估计家系与种群自交与异交的相对频率,着重阐述了目前可用于亲本分析与基因流的估计方法。最后介绍了我们对木根麦冬交配系统与亲本分析的研究以及亲本分析将来的研究方向。     

矮慈姑的传粉机制与交配系统

对矮慈姑（ＳａｇｉｔａｒｉａｐｙｇｍａｅａＭｉｑ）的传粉过程与花粉流作了观察,用同工酶遗传标记法对其一个自然居群的异交率作出定量估计。在自然及人工居群中均观察到虫媒传粉,其中有较大比例的近距离传粉。未检出风媒花粉流。自交可育,同时存在雌雄同株和花序内雌雄花异熟等异交机制。异交率估计结果（ｔ＝４９９％）表明其交配系统为异交／自交兼性系统。作者认为,其较大比例的自交应归因于同株之不同克隆分株间交配的频繁发生     

红树植物木榄(Bruguiera gymnorrhiza)种群的交配系统

利用等位酶多态位点作遗传标记,采用水平切片淀粉凝胶电泳技术检测了我国福建浮宫（24°24′）、广东深圳福田（22°32′）、广西山口合浦（21°28′）和海南东寨港（19°51′）4个红树植物分布区内木榄种群的基因型,进而利用多位点异交率估测程序（MLT）估测其交配系统。所用多态酶位点在浮宫、广西、海南均为Mdh-1、Mdh-2、Me-1,在深圳为Mdh-1、Mdh-2、Aat-1、Aat-2。结果表明各种群多态位点异交率之间有很大差别,浮宫种群最大,为0.845;海南种群最小,为0.267。多位点异交率与单位点异交率平均值的差值显示出除广西种群为随机交配外,其余3个种群都存在轻度的双亲近交。因此,木榄属于混合交配类型,以杂交为主。这主要受植物种群密度、结构,传粉者适应性和活动能力以及是否自交亲和等因素的影响。     

普通野生稻小种群的交配系统与遗传多样性

小种群的遗传动态是保育遗传学关注的核心问题之一,而种群遗传动态又与交配系统密切相关.普通野生稻(Oryza rufipogon Griff.)是具有重要经济价值的濒危物种,目前其种群规模都较小,研究其小种群交配系统与遗传变异性对普通野生稻的保护具有重要意义.运用7对SSR引物,对采自江西东乡普通野生稻小种群的36份种茎和其中20个家系共计601份子代进行了分析.结果显示:该种群的表观异交率为0.318,多位点法估计(MLTR)的多位点异交率为0.481;50%以上的子代共享亲本,非随机交配明显;东乡普通野生稻种群交配系统属于混合交配类型.比较亲本和子代种群的遗传变异性显示:子代种群比亲本种群遗传变异性更丰富;子代种群的杂合子不足与种群变小自交比例上升有关;而亲本种群杂合子过剩可能与杂合基因型的选择优势有关.这些结果说明创造条件扩大种群规模对普通野生稻的原生境保护显得尤为重要.     

天仙子的花部特征及延迟自交机制

通过实验观察和野外控制授粉等方法,对天仙子的自交亲和能力和自交传粉机制进行了研究。结果显示:(1)天仙子的花不完全雌性先熟,开花进程中雄蕊伸长是维持其混合交配系统的重要花部特征。(2)野外控制授粉实验证明天仙子的自交亲和性高,具有主动自交能力,主动自交发生的时间集中在晚花期,与花药和柱头接触的时间吻合。(3)在花粉活力和柱头可授期内,花药与柱头的接触能够发生自花授粉,这种依赖花药与柱头接触发生的自花授粉机制属于典型的延迟自交类型。研究表明,天仙子不仅在花结构上首先选择了适于异交的特征,而且还利用雄蕊伸长成功实现自花授粉,通过异交与延迟自交混合的交配系统为该物种提供了灵活的遗传与繁殖保障。     

克隆生长对被子植物传粉过程的影响

克隆植物与其传粉者的相互作用是植物繁殖生态学的重要研究领域之一。植物克隆生长与有性繁殖通常相伴进行, 往往产生较大的花展示与复杂的克隆空间结构, 通过传粉过程对有性繁殖过程产生影响, 共同决定植物的适合度。本文回顾了克隆生长对被子植物传粉过程影响的国内外研究进展, 从植物克隆大小、花资源空间配置、克隆构型与种群遗传结构四个方面讨论了克隆生长对传粉过程的影响及其生态学与进化生物学意义。早期研究预期, 随着克隆增大, 同株异花授粉水平增加, 因而通过增大自交率或花粉阻塞效应降低植物的适合度。但是, 后来的一些模拟与野外实验研究发现, 传粉者在同一克隆内访问的花数量并不会随克隆增大而一直增加, 访花行为也主要发生在分株内; 而且分子标记的自交率组分分析也表明自交主要发生在分株内。另一方面, 人工模型模拟以及传粉者访问行为研究表明, 当花朵数量相同时, 与所有花集中生长在同一分株上相比, 将花朵分散在多个分株上的克隆生长方式不会增加, 反而降低了同株异花授粉的发生水平。如果花序内花雌雄同熟, 花朵同时提供与接收花粉, 克隆生长会使植物接收到更高比例的异交花粉, 在提高后代质量的同时不增加同株异花授粉概率。这是从传粉生物学角度对植物克隆生长习性进化的一个全新的解释。今后, 克隆植物传粉生物学研究需要针对传粉者与克隆生长之间的相互作用建立理论模型, 探究克隆大小、克隆构型、花资源空间配置模式对传粉者访问频率和行为、花粉散布、交配格局的影响。同时, 需要在自然种群中, 尤其是克隆与非克隆的近缘类群、同一物种克隆与非克隆种群开展比较研究, 利用更高效的分子标记来研究克隆生长的生态与进化意义。     

繁殖保障和延迟自交的研究进展

尽管植物在进化过程中面临不利自花授粉的选择,但许多植物仍维持混合的授粉机制。繁殖保障假说是解释自交进化的最重要因子之一,一直是植物生殖生态学和进化生物学关注的焦点之一。概述了近年来的主要研究热点及其进展,包括自交进化的遗传和生态机制及理论模型探讨、繁殖保障假说的提出、验证自交能否提供繁殖保障的例证、延迟自交的类型及延迟自交能否提供繁殖保障的例证等方面。介绍了我国在繁殖保障和延迟自交方面研究的现状和不足之处,结合国际上研究繁殖保障假说的发展趋势已由单季节、单种群、单因子的研究阶段过渡到多季节、多种群、多因子（自交方式及其所占比例、花粉折损、种子折损、自交率和近交衰退）的综合研究阶段,及由传统的、经典的研究方法过渡到应用现代实验手段（如SSR、SNP等分子标记）和先进仪器设备的研究阶段,提出今后研究中应注意的问题。有必要借用多学科（植物学、生态学和分子生物学）的方法及手段进行不同物种的对比和综合细致的研究。     

Epistasis,inbreeding depression,and the evolution of self-fertilization

Inbreeding depression resulting from partially recessive deleterious alleles is thought to be the main genetic factor preventing self-fertilizing mutants from spreading in outcrossing hermaphroditic populations. However, deleterious alleles may also generate an advantage to selfers in terms of more efficient purging, while the effects of epistasis among those alleles on inbreeding depression and mating system evolution remain little explored. In this article, we use a general model of selection to disentangle the effects of different forms of epistasis (additive-by-additive, additive-by-dominance, and dominance-by-dominance) on inbreeding depression and on the strength of selection for selfing. Models with fixed epistasis across loci, and models of stabilizing selection acting on quantitative traits (generating distributions of epistasis) are considered as special cases. Besides its effects on inbreeding depression, epistasis may increase the purging advantage associated with selfing (when it is negative on average), while the variance in epistasis favors selfing through the generation of linkage disequilibria that increase mean fitness. Approximations for the strengths of these effects are derived, and compared with individual-based simulation results.     

The best of both worlds? A review of delayed selfing in flowering plants

Premise of Study

In a seminal body of theory, Lloyd showed that the fitness consequences of selfing will depend on its timing in anthesis. Selfing that occurs after opportunities for outcrossing or pollen dispersal can provide reproductive assurance when pollinators are limited and is expected to incur little cost, even when inbreeding depression is high. As a result, delayed selfing is often interpreted as a “best‐of‐both‐worlds” mating system that combines the advantages of selfing and outcrossing.

Methods

We surveyed 65 empirical studies of delayed selfing, recording floral mechanisms and examining information on inbreeding depression, autofertility, and other parameters to test the support for delayed selfing as a best‐of‐both‐worlds strategy.

Key Results

Phylogenetic distribution of the diverse floral mechanisms suggests that some basic floral structures may predispose plant taxa to evolve delayed selfing. Delayed selfing appears to serve as a best‐of‐both‐worlds strategy in some but not all species. While the capacity for autonomous selfing is often high, it is lower, in some cases, than in related species with earlier modes of selfing. In other delayed‐selfers, low inbreeding depression and reduced investment in corollas and pollen suggest limited benefits from outcrossing.

Conclusions

Despite a growing literature on the subject, experimental evidence for delayed selfing is limited and major gaps in knowledge remain, particularly with respect to the stability of delayed selfing and the conditions that may favor transitions between delayed and earlier selfing. Finally, we suggest a potential role of delayed selfing in facilitating transitions from self‐incompatibility to selfing.     

Allee effect and self-fertilization in hermaphrodites: reproductive assurance in demographically stable populations

The fact that selfing increases seed set (reproductive assurance) has often been put forward as an important selective force for the evolution of selfing. However, the role of reproductive assurance in hermaphroditic populations is far from being clear because of a lack of theoretical work. Here, I propose a theoretical model that analyzes self-fertilization in the presence of reproductive assurance. Because reproductive assurance directly influences the per capita growth rate, I developed an explicit demographic model for partial selfers in the presence of reproductive assurance, specifically when outcrossing is limited by the possibility of pollen transfer (Allee effect). Mating system parameters are derived as a function of the underlying demographical parameters. The functional link between population demography and mating system parameters (reproductive assurance, selfing rate) can be characterized. The demographic model permits the analysis of the evolution of self-fertilization in stable populations when reproductive assurance occurs. The model reveals some counterintuitive results such as the fact that increasing the fraction of selfed ovules can, in certain circumstances, increase the fraction of outcrossed ovules. Moreover, I demonstrate that reproductive assurance per se cannot account for the evolution of stable mixed selfing rates. Also, the model reveals that the extinction of outcrossing populations depends on small changes in population density (ecological perturbations), while the transition from outcrossing to selfing can, in certain cases, lead the population to extinction (evolutionary suicide). More generally, this paper highlights the fact that self-fertilization affects both the dynamics of individuals and the dynamics of selfing genes in hermaphroditic populations.     

Does life in unstable environments favour facultative selfing? A case study in the freshwater snail <Emphasis Type="Italic">Drepanotrema depressissimum</Emphasis> (Basommatophora: Planorbidae)

One of the main advantages of self-fertilization is to provide reproductive assurance when pollen or mates are scarce. In plants, partial or facultative selfing limits the risk of pollination failure. In preferentially outcrossing species, this may result in mixed-mating. In hermaphroditic animals, recent studies suggest that mixed mating might be much rarer than in plants. However more studies are required to substantiate this claim, especially focusing on species whose lifestyle entails a high potential benefit of reproductive assurance via selfing. We studied a hermaphroditic snail, Drepanotrema depressissimum, which inhabits very unstable and fragmented freshwater habitats. Individuals often have to recolonize newly refilled ponds after long droughts, a situation of low population density and hence low mate availability in which selfing could be an advantage. We estimated selfing rates in natural populations from Guadeloupe (Lesser Antilles), and used laboratory experiments to characterize the reproductive behaviour and success of individuals with or without mates. We detected no sign of selfing in natural populations. Even when given no other option, isolated individuals were extremely reluctant to self. They produced either no or very small clutches, and in the latter case initiated egg-laying later than non-isolated individuals. Self-fertilized clutches suffered near-total (98%) inbreeding depression at the juvenile stage. The example of D. depressissimum therefore shows that a species can overcome periods of mate shortage and habitat instability without the potential to rely on facultative selfing. We hypothesize that metapopulation persistence in this landscape is probably related to a form of dormancy (aestivation in dry ground) rather than to recolonization by rare immigrants and reproductive assurance.     

SEX‐SPECIFIC INBREEDING DEPRESSION DEPENDS ON THE STRENGTH OF MALE–MALE COMPETITION

Inbreeding depression has become a central theme in evolutionary biology and is considered to be a driving force for the evolution of reproductive morphology, physiology, behavior, and mating systems. Despite the overwhelming body of empirical work on the reproductive consequences of inbreeding, relatively little is known on whether inbreeding depresses male and female fitness to the same extent. However, sex‐specific inbreeding depression has been argued to affect the evolution of selfing rates in simultaneous hermaphrodites and provides a powerful approach to test whether selection is stronger in males than in females, which is predicted to be the consequence of sexual selection. We tested for sex‐specific inbreeding depression in the simultaneously hermaphroditic freshwater snail Physa acuta by comparing the reproductive performance of both sex functions between selfed and outcrossed focal individuals under different levels of male–male competition. We found that inbreeding impaired both male and female reproductive success and that the magnitude of male inbreeding depression exceeded female inbreeding depression when the opportunity for sperm competition was highest. Our study provides the first evidence for sex‐specific inbreeding depression in a hermaphroditic animal and highlights the importance of considering the level of male–male competition when assessing sex differences in inbreeding depression.     

Does selfing provide reproductive assurance in the perennial herb Bulbine vagans (Asphodelaceae)?

Selection for selfing to provide reproductive assurance depends on the balance between increased reproductive output when pollinators or potential mates are scarce and the extent that inbreeding depression erodes such fertility gains. We use glasshouse and field experiments to examine the benefits of autonomous and facilitated selfing in Bulbine vagans . Autonomous selfing was delayed until after opportunities for outcrossing and reproductive output was 0.67 relative to manual selfing and open pollination. Values less than one probably reflected insufficient autonomous deposition of self pollen. In the field, reproductive output of emasculated flowers was 0.50 relative to intact flowers that could both outcross and self, indicating that outcross pollen was limited and that selfing boosted reproductive output. Because all pollen was removed from anthers before intact flowers closed, facilitated selfing rather than autonomous selfing occurred. In the glasshouse, inbreeding depression was 0.45, but under natural conditions would probably exceed 0.5. Values greater than 0.5 negate the automatic gene transmission advantage afforded by selfing and increasingly erode the benefits of reproductive assurance. We conclude that in B. vagans delayed and facilitated selfing can confer reproductive assurance, providing the latter does not usurp ovules that could be outcrossed.     

Plant population dynamics, pollinator foraging, and the selection of self-fertilization

Many flowering plants rely on pollinators, self-fertilization, or both for reproduction. We model the consequences of these features for plant population dynamics and mating system evolution. Our mating systems-based population dynamics model includes an Allee effect. This often leads to an extinction threshold, defined as a density below which population densities decrease. Reliance on generalist pollinators who primarily visit higher density plant species increases the extinction threshold, whereas autonomous modes of selfing decrease and can eliminate the threshold. Generalist pollinators visiting higher density plant species coupled with autonomous selfing may introduce an effect where populations decreasing in density below the extinction threshold may nonetheless persist through selfing. The extinction threshold and selfing at low density result in populations where individuals adopting a single reproductive strategy exhibit mating systems that depend on population density. The ecological and evolutionary analyses provide a mechanism where prior selfing evolves even though inbreeding depression is greater than one-half. Simultaneous consideration of ecological and evolutionary dynamics confirms unusual features (e.g., evolution into extinction or abrupt increases in population density) implicit in our separate consideration of ecological and evolutionary scenarios. Our analysis has consequences for understanding pollen limitation, reproductive assurance, and the evolution of mating systems.     

Effects of population size and metapopulation dynamics on a mating-system polymorphism

The evolutionary dynamics of neutral alleles under the Wright-Fisher model are well understood. Similarly, the effect of population turnover on neutral genetic diversity in a metapopulation has attracted recent attention in theoretical studies. Here we present the results of computer simulations of a simple model that considers the effects of finite population size and metapopulation dynamics on a mating-system polymorphism involving selfing and outcrossing morphs. The details of the model are based on empirical data from dimorphic populations of the annual plant Eichhornia paniculata, but the results are also of relevance to species with density-dependent selfing rates in general. In our model, the prior selfing rate is determined by two alleles segregating at a single diploid locus. After prior selfing occurs, some remaining ovules are selfed through competing self-fertilisation in finite populations as a result of random mating among gametes. Fitness differences between the mating-system morphs were determined by inbreeding depression and pollen discounting in a context-dependent manner. Simulation results showed evidence of frequency dependence in the action of pollen discounting and inbreeding depression in finite populations. In particular, as a result of selfing in outcrossers through random mating among gametes, selfers experienced a "fixation bias" through drift, even when the mating-system locus was selectively neutral. In a metapopulation, high colony turnover generally favoured the fixation of the outcrossing morph, because inbreeding depression reduced opportunities for colony establishment by selfers through seed dispersal. Our results thus demonstrate that population size and metapopulation processes can lead to evolutionary dynamics involving pollen and seed dispersal that are not predicted for large populations with stable demography.