模拟酸雨对小黑麦种子萌发及幼苗生理特性的影响

以小黑麦品种中饲237为材料。在不同pH值的模拟酸雨条件下对种子萌发及幼苗生理特性进行了研究。分别测定了发芽率、发芽势、发芽指数、活力指数和种子脱氢酶含量、幼苗鲜重、幼苗叶片叶绿素含量、叶片电导率等指标。结果表明,种子的各项发芽指标及种子脱氢酶含量、幼苗鲜重、叶绿素含量等随酸雨pH值减小整体呈降低趋势,叶片电导率则随酸雨pH值减小而有增加趋势。     

姜科植物研究进展

姜科植物在种类、外部性状及内部解剖等方面具有高度的复杂性,其传粉方式也显示出了丰富的多样性。因此,姜科植物的研究对姜目乃至单子叶植物的系统与进化研究,都具有十分重要的意义。本文综述了国内外有关姜科植物在分类学、系统学、解剖学、花器官发生学和繁殖生物学等方面的研究和进展,以期能为该类群的系统研究提供一定的帮助。     

植冠种子库及其生态意义研究

植冠种子库由成熟的种子宿存在植冠上形成。种子可在植物植冠中存留1～30年或者更长时间。40属木本植物中有1200种植物具有植冠种子库,它们大多分布在火灾易发区和干旱区。植冠种子库是植物繁殖对策的一个方面,具有延缓繁殖体传播、使繁殖体免受捕食、调节萌发时间、将种子降落在适宜位置等生态功能。本文对植冠种子库的概念、分类、具有植冠种子库物种的地理分布、植冠种子库的研究现状及植冠种子库研究中存在的问题进行了论述。应加强对干旱区植冠种子库种子脱落机制和沙漠地区植冠种子库生态意义的研究。     

果实(种子)化学防御与食果实动物的适应对策

种子植物在果实(种子)成熟后需要防御食果实动物捕食种子,同时要传播种子至适宜萌发的生境。很多植物依赖食果实动物传播种子,称动物传播植物。果实(种子)化学防御是抵御种子捕食者的重要手段。果实(种子)中次生物质包括各种生物碱、生氰糖苷、萜类和酚类等,种类繁多;次生物质的含量随果实成熟过程而变化。次生物质可以抵御动物的捕食,其毒性对种子传播者和种子捕食者没有选择性,即具泛毒性。果肉中的次生物质也可以起到轻泻剂的作用,缩短种子在动物消化道的滞留时间,以影响传播效率。果实(种子)次生物质的产生不受植物环境条件的影响,其产生与果实质量有关。在温带地区,通常SS型果实次生物质含量低,而FL型果实含量高。食果实动物可通过调整捕食行为、摄取环境中特殊物质和获得丰富营养等3个方面适应次生物质。果实(种子)中次生物质的研究对动植物相互作用、协同进化理论具有重要的意义。     

柴达木盆地唐古特白刺籽油保护肝损伤作用研究

对柴达木盆地唐古特白刺种籽油保护化学性肝损伤作用进行了研究.将小鼠按体重随机分为白刺籽油高、中、低剂量组,另设空白对照组和联苯双酯、藏茵陈阳性对照组.小鼠连续灌胃给药15 d后,用CCl4进行肝损伤,测定小鼠血清谷丙转氨酶（ALT）、谷草转氨酶（AST）;肝脏过氧化脂质（LPO）降解产物丙二醛（MDA）和谷胱甘肽过氧化物酶（GSH-Px）的含量.结果显示,白刺籽油对血清ALT、AST具有显著的抑制作用,显著拮抗肝脏MDA的升高,显著提高肝脏GSH-Px含量.表明白刺籽油具有明显的保护化学性肝损伤的保健作用.     

NaCl胁迫及Ca2+和GA3对南瓜属3种蔬菜种子发芽的影响

研究了NaCl胁迫对南瓜(Cucurbita moschata Duch.)、笋瓜(C. maxima Duch.)和西葫芦(C.pepo L.)种子萌发的影响及不同浓度外源Ca2+和GA3对NaCl胁迫下南瓜种子发芽的效应.结果表明,用30 mmol·L-1NaCl处理,南瓜种子的发芽率高于对照(蒸馏水),而用100和170 mmol·L-1NaCl处理,西葫芦和笋瓜种子的发芽率下降率为负值,表明较低浓度NaCl胁迫可一定程度提高西葫芦、笋瓜和南瓜种子的发芽率;高浓度NaCl胁迫对种子发芽有明显的抑制作用.种子萌发期耐盐能力从大至小依次为西葫芦、南瓜、笋瓜.在170 mmol·L-1NaCl胁迫下,施加5～30 mmol·L-1外源Ca2+或浸种处理,对南瓜种子发芽有促进作用,但高浓度外源Ca2+(≥50 mmol·L-1CaCl2)则具有抑制作用.在170 mmol·L-1NaCl胁迫下,用不同浓度GA3浸种处理,对南瓜种子发芽有抑制作用.     

不同贮藏温度和时间对钻喙兰人工种子萌发及其幼苗成活的影响

植物人工种子技术已广泛应用于花卉、林木和蔬菜的优良品种快速繁殖以及种质资源的超低温保存等方面[1].     

How important is long‐distance seed dispersal for the regional survival of plant species?

Long‐distance seed dispersal is generally assumed to be important for the regional survival of plant species. In this study, we quantified the importance of long‐distance seed dispersal for regional survival of plant species using wind dispersal as an example. We did this using a new approach, by first relating plant species’ dispersal traits to seed dispersal kernels and then relating the kernels to regional survival of the species. We used a recently developed and tested mechanistic seed dispersal model to calculate dispersal kernels from dispersal traits. We used data on 190 plant species and calculated their regional survival in two ways, using species distribution data from 36,800 1 km²‐grid cells and 10,754 small plots covering the Netherlands during the largest part of the 20th century. We carried out correlation and stepwise multiple regression analyses to quantify the importance of long‐distance dispersal, expressed as the 99‐percentile dispersal distance of the dispersal kernels, relative to the importance of median‐distance dispersal and other plant traits that are likely to contribute to the explanation of regional survival: plant longevity (annual, biennial, perennial), seed longevity, and plant nutrient requirement. Results show that long‐distance dispersal plays a role in determining regional survival, and is more important than median‐distance dispersal and plant longevity. However, long‐distance dispersal by wind explains only 1–3% of the variation in regional survival between species and is equally important as seed longevity and much less important than nutrient requirement. In changing landscapes such as in the Netherlands, where large‐scale eutrophication and habitat destruction took place in the 20th century, plant traits indicating ability to grow under the changed, increasingly nutrient‐rich conditions turn out to be much more important for regional survival than seed dispersal.     

Seed caching by woylies Bettongia penicillata can increase sandalwood Santalum spicatum regeneration in Western Australia

Abstract The role a small marsupial, the woylie Bettongia penicillata, might play in the recruitment and regeneration of Western Australian sandalwood Santalum spicatum through its seed caching behaviour was investigated in this study. To determine the fate of the seeds, cotton thread was attached to the seeds and the trail followed. A total of 25 seed caches were located. All of the seeds were found in separate caches, which was consistent with scatter‐hoarding behaviour. The average distance from the source of the seeds to the cache was 43.1 m ± 5.8 m at Dryandra woodland and 29.1 m ± 3.8 m at Karakamia sanctuary. The mean cache depth was 4.3 cm ± 0.2 cm at Dryandra woodland compared with 4.6 cm ± 0.3 cm at Karakamia sanctuary. Significantly more seedlings and saplings grew away from sandalwood trees at sites where woylies were present than at sites with no woylies. In contrast, significantly more seedlings and saplings grew under adult sandalwood trees at the site without woylies than where they were present, although there were significantly lower rates of recruitment and sandalwood regeneration at these sites. In addition, significantly more whole, undisturbed sandalwood seeds were found under the parent trees at the woylie‐free site than at the site with woylies. These findings strongly suggest that little seed dispersal or regeneration of sandalwood occurs in the absence of woylies. Through scatter‐hoarding, woylies have the potential to disperse and cache sandalwood seeds away from the source and significantly alter the subsequent regeneration of sandalwood. Furthermore, by caching seeds large distances away from a source, woylies could modify the distribution of sandalwood in an area.     

The ecology of restoration: historical links, emerging issues and unexplored realms

Restoration ecology is a young academic field, but one with enough history to judge it against past and current expectations of the science's potential. The practice of ecological restoration has been identified as providing ideal experimental settings for tests of ecological theory; restoration was to be the 'acid test' of our ecological understanding. Over the past decade, restoration science has gained a strong academic foothold, addressing problems faced by restoration practitioners, bringing new focus to existing ecological theory and fostering a handful of novel ecological ideas. In particular, recent advances in plant community ecology have been strongly linked with issues in ecological restoration. Evolving models of succession, assembly and state-transition are at the heart of both community ecology and ecological restoration. Recent research on seed and recruitment limitation, soil processes, and diversity–function relationships also share strong links to restoration. Further opportunities may lie ahead in the ecology of plant ontogeny, and on the effects of contingency, such as year effects and priority effects. Ecology may inform current restoration practice, but there is considerable room for greater integration between academic scientists and restoration practitioners.