试论种子顽拗性的复合数量性状特征

文章简要概述了从顽拗型种子到顽拗性种子这样一个对顽拗性种子认识提高的过程,在综述了前人关于顽拗性种子数量性状特征论述的基础上,把种子顽拗性的数量性状特征划分为种间、种内和个体发育三个层面,提出种子顽拗性是一种复合性状,其核心至少包括脱水耐性、低温耐性和贮藏耐性三方面的内容,其伴随性状包括种子尺度、千粒重、初始含水量、休眠特性、分类地位、地理分布和保护性物质含量等多方面的内容,而且这些核心内容和伴随性状的每一个方面都具有渐变的、过渡的、数量型的特征,从而阐明种子顽拗性是一种复合数量性状.种子顽拗性的复合数量性状特征的提出及其三个层面的划分,有助于加深对种子顽拗性的认识,并用以指导我们在实践中解决种子顽拗性方面的具体问题.     

植物顽拗性种子研究进展

对植物顽拗性种子的概念、物种分类、形态、分布及一些生理生态特征进行了综述,分析了顽拗性种子脱水敏感性的原因和对环境的生态适应性,探讨其可能的进化地位和贮存技术。同时,对顽拗性种子研究的发展趋势和应用前景进行了展望,即加强生境调查,更新顽拗性种子植物数据库,从形态学、生理生态学和分子生物学分析种子顽拗性本质。     

顽拗性种子研究

Roberts（1973）根据种子的贮藏行为把种子分为正常性种子和顽拗性种子,Ellis（1990）等认为红这两者之间还存在中间类型即中间型种子。种子的顽拗性是一个数量性状,具有连续性：分为低度顽拗性种子、中度顽拗性种子、高度顽拗性种子。具顽拗性种子的植物主要来自两类：一类为水生植物,如：茭白、菱等;另一类主要是具大粒种子的多年生木本,包括热带作物,热带水果,热带林木,如：可可,红毛丹等。     

种子顽拗性:最新评价

根据种子的脱水行为,可以把种子分为正常性、顽拗性和中间性种子三种类型.种子脱水耐性和脱水敏感性的鉴定是制定种子的贮藏策略和物种基因资源长期保存的依据.除了物种的内在特性外,种子的发育状态、脱水速率、脱水时和重新水合时的环境是影响种子脱水耐性的重要因子.种子的存活率、电解质渗漏速率和存活种子的萌发生长速率是衡量种子脱水耐性的良好的综合参数.种子的脱水耐性是一种数量性状,用"临界含水量"的概念来判断是不正确的,且在评价种子顽拗性中引起了一些混乱.本文还提出了一种全新的评价种子顽拗性的工作模式.     

顽拗性种子

本文讨论了顽拗性种子的基本特性,在劣变中的生理生化变化,脱水敏感性的细胞生物学基础,以及贮藏顽拗性种子的必要性和可能性。     

种子顽拗性：最新评价

根据种子的脱水行为,可以把种子分为正常性、顽拗性和中间性种子三种类型。种子脱水耐性和脱水敏感性的鉴定是制定种子的贮藏策略和物种基因资源长期保存的依据。除了物种的内在特性外,种子的发育状态、脱水速率、脱水时和重新水合时的环境是影响种子脱水耐性的重要因子。种子的存活率、电解质渗漏速率和存活种子的萌发生长速率是衡量种子脱水耐性的良好的综合参数。种子的脱水耐性是一种数量性状,用“临界含水量”的概念来判断是不正确的,且在评价种子顽拗性中引起了一些混乱。本文还提出了一种全新的评价种子顽拗性的工作模式。     

种子顽拗性的形成机理及其保存技术

根据种子的脱水行为将种子分为正常性种子、顽拗性种子和中间性种子。顽拗性种子在发育的末期不经历成熟脱水．脱落时有相对高的含水量,并且对低温和脱水干燥非常敏感。在自然界,顽拗性种子存在一个连续群,即低度、中度和高度顽拗性种子,其差异在于对脱水伤害的敏感程度。影响种子顽拗性的因素,既有种子本身的生理生化物质基础,也有种子在母株上发育过程中所经受的外界环境的影响。目前,对种子脱水耐性的分子机制及其保存技术研究得较多。本文综述了有关顽拗性种子研究的近期进展。     

低温保存技术在顽拗性种子种质保存中的利用

由于顽拗性种子不耐脱水且对低温敏感,常规保存方法难以达到长期保存的目的。因此,(超)低温保存顽拗性种子种质是最理想的方法。顽拗性种子的低温保存,应用较多的是玻璃化法和两步法。诸多因素影响着低温保存的成败,如种子或胚的含水量水平、溶液低温保护剂效应、降温冰冻与解冻方式、水合过程以及后培养等,这些需深入探索与解决。除顽拗性种子脱水耐性和低温敏感性机理外,植物细胞的冻害和抗冻机理也亟需探明,以便找到最佳冷冻方法,制定长期保存种质基因的最佳方案。     

顽拗性种子的研究进展

根据种子的贮藏特性,Roberts将种子分为正常性种子(Orthodox seeds)和顽拗性种子(Recalcitrant seeds)两大类。正常性种子包括大多数农作物种子,能够忍受脱水和低温,在5±1％含水量和-18℃低温下贮藏,种子的生活力可保持相当一段时间,有的可达数十年甚至更长,在我国东北地区天然干涸的湖床中发现的印度莲子是很老的活种子,应用放射性碳测定,据称这些种子的寿命在1000年以上。     

植物离体培养中的顽拗现象及其生理和遗传基础

介绍了植物离体培养中顽拗现象的若干表现形式 ,包括影响顽拗性的主要因子、多年生木本和草本植物的遗传预决定性生长特性、顽拗现象与自由基、离体肿瘤转化性进程中植物器官发生全能性的丧失等 ,并对有关的生理和遗传基础的研究进展进行了概述     

Trends in the evolution of dicotyledonous seeds based on character associations, with special reference to pachychalazy and recalcitrance

VON TEICHMAN, I. & VAN WYK, A. E., 1991. Trends in the evolution of dicotyledonous seeds based on character associations, with special reference to pachychalazy and recalcitrance. The possible evolutionary status of the endothelium, hypostase, pachychalaza and the recalcitrant viability behaviour of seeds is considered in relation to bitegmy/unitegmy, crassinucellate/tenuinucellate ovules, nuclear/cellular endosperm development, large/small seed size, woody/herbaceous habit and tropical/temperate habitat. The presence of the endothelium, hypostase, pachychalaza and recalcitrance in dicotyledonous families is plotted against Dahlgren's system of classification. Results are compared with Sporne's advancement index for the various families. An endothelium is considered derived since it occurs more often in highly evolved superorders and is significantly associated with derived ovule and endosperm character states as well as with smaller seed size. A hypostase appears to be relatively ancestral and is significantly associated with pachychalazy and recalcitrance. The endothelium and hypostase have developed independently in many taxa and could be interpreted as being structurally and functionally analogous. Pachychalazy and recalcitrance are significantly associated with ancestral ovule character states and, at the species level, with large seed size (overgrown seed), woody habit and tropical habitat. The presence of pachychalazy, recalcitrance and associated large seed size are therefore regarded as ancestral character states of the dicotyledons. Consideration of currently accepted dicta on seed character state polarity, suggests a reversal in the evolutionary status of pachychalazy and large seed size.     

Seed bank,seed size and dispersal in moisture gradients of temporary pools in Southern France

Plants reduce risk of extinction due to unpredictable rainfall by soil seed banks, dispersal or large seeds. However, seed size also increases independently in dry habitats, and since seed size is in a trade-off with seed number, size of seed banks is expected to increase in moister habitats. Therefore, we wanted to test if seed abundance in soil increases in wet habitats, if seed size increases in dry habitats, and if spread of seeds along the gradient is higher for plants of intermediate habitats in local moisture gradients.We studied 15 temporary pools in three biogeographically separated wetlands in Southern France. For each pool we studied five different moisture levels, totalling 75 local plant communities. We quantified soil seed bank by the seedling emergence method, seed size and an index of spatial spread of seeds in the soil for every species. We also quantified water levels for each plot.We found increasing abundance of seeds in the soil with increasing water levels but lower seed size and higher spread at intermediate water levels. When we controlled for niche position, we found no trade-off between seed size, spread and abundance in the soil seed bank.Type and importance of risk reduction strategies thus appeared to be strongly driven by the plant species’ moisture niche and the spatial arrangement of water levels.     

Recalcitrant Seeds: Short-term Storage Effects in Avicennia marina (Forsk.) Vierh. may be Germination-associated

When recalcitrant propagules (seeds) of Avicennia marina werestored in a dry air stream there was no significant change intheir moisture content for 10 days, after which it declinedrapidly. Seed viability remained high during this 10-d period,only then declining. Ultrastructural changes in embryonic rootprimordium cells during the 10-d storage period were similarto those characterizing germination. It is suggested that thecontinuation of germination processes after shedding may beresponsible for the deterioration in stored recalcitrant seeds. Avicennia marina, recalcitrance, seed storage, germination     

含水量对种子贮藏寿命的影响

建立以收集种子为主体的基因库乃是当今保护植物种质资源最为普遍且可靠易行的方式,在世界库存约 61 0 0 0 0 0份种质资源中,近 90 %是以种子形式保存于约 1 30 0个基因库中。低温贮藏仍是目前基因库中种子种质保存的主要方法。种子含水量和贮藏温度是影响种子在贮藏期间生活力和活力保持的关键因素。传统的经验认为控制温度比控制水分来得安全有效,因而趋向于向低温或超低温的贮藏方向发展。国际植物遗传资源研究所（ＩＰＧＲＩ）曾推荐 5%～ 6%的含水量和 - 1 8～- 2 0℃低温作为各国长期保存种子的理想条件。目前,世界各国都把更多的…     

Pollen and seed desiccation tolerance in relation to degree of developmental arrest, dispersal, and survival

In most species, arrest of growth and a decrease in water content occur in seeds and pollen before they are dispersed. However, in a few cases, pollen and seeds may continue to develop (germinate). Examples are cleistogamy and vivipary. In all other cases, seeds and pollen are dispersed with a variable water content (2-70%), and consequently they respond differently to environmental relative humidity that affects dispersal and maintenance of viability in time. Seeds with low moisture content shed by the parent plant after maturation drying can generally desiccate further to moisture contents in the range of 1-5% without damage and have been termed 'orthodox'. Pollen that can withstand dehydration also was recently termed orthodox. Seeds and pollen that do not undergo maturation drying and are shed at relatively high moisture contents (30-70%) are termed 'recalcitrant'. Since recalcitrant seeds and pollen are highly susceptible to desiccation damage, they cannot be stored under conditions suitable for orthodox seeds and pollen. Hence, there are four types of plants with regard to tolerance of pollen and seeds to desiccation. Orthodoxy allows for dispersal over greater distances, longer survival, and greater resistance to low relative humidity. The advantage of recalcitrance is fast germination. Orthodoxy and recalcitrance are often related to environment rather than to systematics. It has been postulated that certain types of genes are involved during presentation and dispersal of pollen and seeds, since molecules (sucrose, polyalcohols, late embryogenic abundant proteins, antioxidants, etc.) that protect different cell compartments during biologically programmed drying have been detected in both.     

The effects of seed size and pericarp on seedling recruitment and biomass in Cryptocarya alba (Lauraceae) under two contrasting moisture regimes

Establishment success of plants derived from large seeds has been proposed to be greater than that of those derived from smaller ones, particularly under unfavourable conditions of moisture. Therefore, the advantages conferred by large seeds in terms of seedling performance may be modulated by abiotic conditions. The effect of seed size on Cryptocarya alba seedling performance (as determined by seedling recruitment and seedling size) was evaluated under two contrasting rainfall regimes (wet and dry year regime), simulated in the laboratory. It was also determined whether the presence of a pericarp, which had been shown to reduce germination, decreases desiccation and if this counterbalances the greater recruitment of seeds without a pericarp, especially under unfavourable conditions of moisture. Large seeds had a greater probability of recruitment and their seedlings attained a greater biomass, independently of the amount of water applied. In the simulated wet year regime, seeds with a pericarp showed a greater probability of recruitment than those lacking a pericarp. However, seedlings derived from both seed types attained a similar biomass. Under the dry year regime, seeds with and without a pericarp showed similar recruitment probabilities and their seedlings had similar biomasses. These results do not support the assumption that under favourable conditions of moisture, individual differences in seed size would not matter in term of seedling performance. A possible explanation in this case, is the presence of recalcitrant seeds in C. alba, which determines a very short time period for germination following dispersal. Therefore, any attribute that increases germination (e.g., large seeds) would be advantageous, independently of the prevailing abiotic conditions.     

Dynamics of Water and Abscisic Acid During Embryogeny and Embryo Drying in the Recalcitrant Seeds of Vateria indica L.

Vateria indica L. is a critically endangered tree species in South-Western Ghats of India, commercially exploited for its valuable resins. Seed recalcitrance is a major problem hindering the natural regeneration of this species and it poses a great challenge in seed storage and conservation. There was a continuous import of water from the maternal tissues to seed tissues till maturity and the seeds were released in a fully hydrated state. Differential accumulation of water has been noticed in the cotyledons and embryonal axis. There was a positive correlation between seed moisture content and rate of germination which is a character of recalcitrant seeds. The critical moisture content was found to be 40% in the axis and 23.5% in the cotyledons, below which the embryo will not germinate. Loss of germination ability as a result of desiccation was attributed to the cell membrane damage, expressed as the electrolyte leakage exceeding 0.79 μS/cm. ABA peaked in the mid embryogenesis, then dropped drastically and maintained a lower level till seed maturity. On desiccation, ABA started to increase but gradually dropped down. Both cotyledons and embryonal axis had differential ABA content but exhibited a general pattern of ABA level during embryogeny. Due to the thin seed coat/embryo ratio and low investment in the seed coat, this recalcitrant seed could not hold water as efficient as orthodox seeds. Thus, it germinated as soon as it was shed from the mother plant. On desiccation, ABA shot up and moisture content decreased along with electrolyte leakage and cell membrane damage. All these hindered germination of the seed. Thus, we can see a clear interplay between moisture content and ABA levels during embryogeny and desiccation. Since the seed biology of this species has not been well documented, the present work is mainly intended to study the dynamics of water and ABA during embryogeny and embryo drying. This study can surely contribute to the long-term storage and conservation of recalcitrant seeds which is a less explored area.

     

On the adaptive value of large seeds for tropical moist forest trees: A review and synthesis

In moist temperate and tropical environments species that typically become established in closed, shaded habitats tend to have larger seeds than those that regenerate in open, secondary habitats. Despite this common pattern and the frequency with which benefits of small seed size for early successional species (large number, enhanced dispersal potential) have been discussed, little attention has focused on the advantages of large seeds for species that regenerate in closed, late successional associations. It is generally considered that large seeds enhance seedling survivorship at low light intensities. However, light intensity is only one of several factors that differ between shaded and sunlit habitats. This review examines microclimatic and biotic differences between shaded subcanopy habitats in mature tropical forests and those in sunlit, light gap habitats in which the early stages of tropical forest succession occur. Each factor is examined as a possible selective agent responsible for maintaining seed size differences between two guilds of tropical rainforest trees; the pioneer species that have small seeds and typically become established in large, sunlit gaps in the forest canopy and the persistent, relatively shade-tolerant species that have larger seeds and produce seedlings that survive for variable periods of time in the shade beneath the forest canopy. Three microclimatic factors that differ in subcanopy and gap habitats are examined; temperature, moisture, and light intensity. It is unlikely that temperature has been an important selective agent in maintaining the differences in seed sizes observed between the pioneer and persistent tree guilds. However, greater desiccation stress in light gaps might prevent successful regeneration of larger seeds in this habitat and thus might impose the smaller mean seed sizes of pioneer species. Reduced light intensities in subcanopy habitats also could favor larger seeds in the persistent guild because large seed reserves might 1) enhance the abilities of seeds to persist until suitable light (or moisture) conditions arise by providing for metabolic requirements of seeds during quiescent periods, 2) provide secondary compounds for defense of persistent seedlings against pathogens and predators during periods of low energy availability, 3) provide energy for construction of large amounts of photosynthetic tissue needed to maintain a positive net energy balance when light conditions are just above the leaf light compensation point of the plant, 4) provide energy for growth into higher light intensity strata, and 5) provide nutrients for replacement of lost or damaged tissues in persistent seedlings. Differences between soils in light gaps and subcanopy habitats are considered briefly. It is concluded that too little is known for predictions to be made regarding the probable effects of soil differences on the sizes of seeds able to survive in each habitat. Finally, differences between the two habitats in four biotic factors (competition, predation, pathogens, and mycorrhizal availability) are considered. Of these, greater competition for nutrients in the subcanopy habitat, and competition among co-germinating seedlings for light could have been important in favoring large seeds in the guild of persistent species. Pathogens are known to be more effective in shaded habitats, but data on seedling resistance to pathogens do not provide support for a role of seed size in enhancing resistance. Although differences in predation intensity and in mycorrhizal abundance in the two habitats have not been evaluated in the field, potential roles of these two factors in maintaining the seed size differential between these two guilds of forest trees are discussed. Despite the existence of numerous potential benefits of large seed reserves, seed sizes often must reflect compromises between conflicting selective pressures. Environmental conditions (e.g., moisture availability) can impose upper limits on seed size. Enhanced dispersal potential and greater total propagule numbers from maternal energy reserves are benefits of small seed size that can counterbalance selection for large seed reserves. The interactions between selective forces in molding seed sizes are discussed in a final section.