华南山坡地植物生物量的收获和植物资源的持续利用

本文主要从减少因生物量收获所造成的生态系统养分损失，讨论华南山坡地植物资源的利用问题。结果表明，不同的生物量收获方式、收获时期和刈割频率，以及利用不同的植被类型作为薪炭燃料所造成的养分损失有很大的差别。了解这些差别将有助于华南山坡地可更新资源的管理和持续利用。     

植物生物技术在黑麦草遗传改良中的应用

黑麦草是重要的牧草和草坪草,是畜牧业和草坪业重要的产业支柱.由于高度自交不亲和,传统遗传改良困难而复杂.生物技术尤其是转基因技术为其遗传改良带来希望.本文概述了组织培养技术、基因遗传转化技术、分子标记及数量性状基因定位、分子标记辅助育种等技术在黑麦草遗传改良中的应用及获得的成果;评述了遗传改良的重要意义,以及黑麦草遗传改良的主要目标,如品质改良、提高病害抗性、降低毒性生物碱浓度、控制花粉致敏性、抗除草剂品种的培育、提高抗逆性及其作为生物反应器的潜在应用价值等;并分析了功能基因组学的研究及RNA干扰技术在黑麦草研究中可能的应用前景.     

Gap Analysis of Conserved Genetic Resources for Forest Trees

Abstract:  We developed a gap analysis approach to evaluate whether the genetic resources conserved in situ in protected areas are adequate for conifers in western Oregon and Washington (U.S.A.). We developed geographic information system layers that detail the location of protected areas and the distribution and abundance of each tree species (noble fir [ Abies procera Rehd.] and Douglas-fir [ Pseudotsuga menzeisii Mirb.]). Distribution and abundance were inferred from available spatial data showing modeled potential and actual vegetation. We stratified the distribution of each species into units for genetic analysis using seed and breeding zones and ecoregions. Most strata contained at least 5000 reproductive-age individuals in protected areas, indicating that genetic resources were well protected in situ throughout most of the study region. Strict in situ protection was limited, however, for noble fir in the Willapa Hills of southwestern Washington. An in situ genetic resource gap arguably occurred for Douglas-fir in the southern Puget lowlands, but this gap was filled by extensive ex situ genetic resources from the same region. The gap analysis method was an effective tool for evaluating the genetic resources of forest trees across a large region.     

Application of Reproduction Technologies to the Conservation of Genetic Resources

Abstract: Maintaining the levels of genetic variability in captive populations of endangered species is an important objective of conservation biology. Because of the generally low sizes of captive populations, genetic drift is the main cause of loss of diversity. Several simple management rules, such as equalization of contributions from parents to the next generation, are recommended for minimizing genetic drift, but it cannot be removed completely because of the unavoidable random segregation of heterozygotes. Recent advances in reproductive technology, particularly developed for mammals, are now making a reality of the possibility of using more than one cell from a single meiosis in reproduction. With this technology it is possible to reduce or even completely cancel the genetic drift caused by segregation of heterozygotes. We evaluated the theoretical benefits of the use of such technologies to conservation biology. The effective population size can be increased enormously and, consequently, the amount of drift can be greatly reduced if manipulations in reproduction are made.     

Why the Conservation of Forest Genetic Resources Has Not Worked

Abstract:  Genetic diversity is indispensable for long-term forest sustainability and is therefore mentioned in numerous binding and nonbinding political covenants calling for action. Nevertheless, there are significant obstacles to the conservation of forest genetic resources. We discuss hindrances to genetic conservation, mainly in Europe. We identified impediments by reviewing the literature and on the basis of the experiences of the authors in this field and their participation in related political processes. The impediments include (1) difficulties in assessing and monitoring genetic erosion and human impacts (e.g., by the lack of markers showing adaptive variation and the lack of record keeping on the use and transfer of forest-tree germplasm), (2) complexities of European national structures that make the development of a common strategy toward forest genetic conservation problematic, (3) lack of effective forest governance in many parts of the world, (4) the general unattractiveness of genes as flagships in raising public awareness, (5) lack of integration of genetic aspects into biodiversity conservation, and (6) the fact that scientists and politicians are often at cross-purposes. To overcome these impediments, forest geneticists and their peers in species conservation have to participate more actively in decision making. In doing so, they must be prepared to face challenges on 2 fronts: participating in political processes and the provision of significant research findings to ensure that decisions with respect to forest genetic diversity are politically implementable and effectively address targets.     

Benefits of Conservation of Plant Genetic Diversity to Arthropod Diversity

Abstract:  We argue that the genetic diversity of a dominant plant is important to the associated dependent community because dependent species such as herbivores are restricted to a subset of genotypes in the host-plant population. For plants that function as habitat, we predicted that greater genetic diversity in the plant population would be associated with greater diversity in the dependent arthropod community. Using naturally hybridizing cottonwoods (  Populus spp.) in western North America as a model system, we tested the general hypothesis that arthropod alpha (within cross-type richness) and beta (among cross-type composition) diversities are correlated with cottonwood cross types from local to regional scales. In common garden experiments and field surveys, leaf-modifying arthropod richness was significantly greater on either the F₁ (1.54 times) or backcross (1.46 times) hybrid cross types than on the pure broadleaf cross type (  P. deltoides Marshall or P. fremontii Watson). Composition was significantly different among three cross types of cottonwoods at all scales. Within a river system, cottonwood hybrid zones had 1.49 times greater richness than the broadleaf zone, and community composition was significantly different between each parental zone and the hybrid zone, demonstrating a hierarchical concentration of diversity. Overall, the habitats with the highest cottonwood cross-type diversity also had the highest arthropod diversity. These data show that the genetics of habitat is an important conservation concept and should be a component of conservation theory.     

威海荣成鹿角菜野生种群遗传多样性及资源保护策略

利用随机扩增多态性DNA（RAPD）方法对威海荣成地区鹿角菜（Silvetiasiliquosa）野生种群共30个个体的遗传多样性水平及遗传结构进行研究。结果表明,利用21条随机引物共检测到112个多态性位点,多态性位点百分率为93．75％,Nei基因多样性指数为0．3515±0．1352,Shannon多样性指数为0．5046±0．1126。通过聚类分析而划为一类的3个亚种群间的遗传分化指数为0．1349～0．2189,基因流为1．7793。研究结果表明威海荣成地区的鹿角菜种群遗传多样性较高,种群内存在较为明显的遗传分化,种群遗传资源不受遗传漂变的影响。针对当地鹿角菜遗传资源的现状,应加强现存种群的就地保护,恢复种群规模;进行取样养殖保护时则需避免因近交而造成种群资源退化。     

Plant diversity, CO2, and N influence inorganic and organic N leaching in grasslands

In nitrogen (N)-limited systems, the potential to sequester carbon depends on the balance between N inputs and losses as well as on how efficiently N is used, yet little is known about responses of these processes to changes in plant species richness, atmospheric CO2 concentration ([CO2]), and N deposition. We examined how plant species richness (1 or 16 species), elevated [CO2] (ambient or 560 ppm), and inorganic N addition (0 or 4 g x m(-2) x yr(-1)) affected ecosystem N losses, specifically leaching of dissolved inorganic N (DIN) and organic N (DON) in a grassland field experiment in Minnesota, USA. We observed greater DIN leaching below 60 cm soil depth in the monoculture plots (on average 1.8 and 3.1 g N x m(-2) x yr(-1) for ambient N and N-fertilized plots respectively) than in the 16-species plots (0.2 g N x m(-2) x yr(-1) for both ambient N and N-fertilized plots), particularly when inorganic N was added. Most likely, loss of complementary resource use and reduced biological N demand in the monoculture plots caused the increase in DIN leaching relative to the high-diversity plots. Elevated [CO2] reduced DIN concentrations under conditions when DIN concentrations were high (i.e., in N-fertilized and monoculture plots). Contrary to the results for DIN, DON leaching was greater in the 16-species plots than in the monoculture plots (on average 0.4 g N x m(-2) x yr(-1) in 16-species plots and 0.2 g N x m(-2) x yr(-1) in monoculture plots). In fact, DON dominated N leaching in the 16-species plots (64% of total N leaching as DON), suggesting that, even with high biological demand for N, substantial amounts of N can be lost as DON. We found no significant main effects of elevated [CO2] on DIN or DON leaching; however, elevated [CO2] reduced the positive effect of inorganic N addition on DON leaching, especially during the second year of observation. Our results suggest that plant species richness, elevated [CO2], and N deposition alter DIN loss primarily through changes in biological N demand. DON losses can be as large as DIN loss but are more sensitive to organic matter production and turnover.     

绿色建筑植物资源信息系统的构建及应用

在前期研究的基础上,应用计算机技术建立绿色建筑植物资源信息系统(Green Building Plant Resources Information System,GBPRIS),该系统包括植物基本特征数据库、植物生态功能数据库、植物群落数据库和评价体系数据库4个基础数据库.共收录500种植物和上海常见48个植物群落的信息,将植物的生物学特性、生态习性及各项生态功能信息规范化、数字化输入,降低了绿色建筑适生植物选择的专业性要求,并具有多途径搜索、快速查询文档和图片的功能,既能用于对现有绿化体系进行评价,有针对性地提出改进意见,也可用于对建筑室外绿化规划设计进行预评价,为绿色建筑的绿化配置提供科学参考.     

A Hierarchical View of Genetic Structure in the Rare Annual Plant Clarkia springvillensis

Genetic structure at several spatial scales was examined in the rare California annual, Clarkia springvillensis . Using seven isozyme-encoding loci as genetic markers, we assessed the amount and distribution of genetic variation among three populations and eight subpopulations. Total genetic variation was lower than in species with similar life history traits but equivalent to that of other endemic plants. Spatial autocorrelation showed some evidence for very limited differentiation within subpopulations at a scale of 1–2 m. The subpopulations, separated by tens of meters, were found to be more differentiated from each other ( F _sp = 0.084) on average than were populations ( F,pt = 0.017). This local genetic differentiation was not correlated with physical distance between subpopulations. The low F_pt estimates suggest that substantial gene flow is occurring among populations. However, the lack of correlation between genetic and geographic distances and the significant differentiation of subpopulations suggest that genetic drift is occurring within populations. Therefore, we believe the apparent homogeneity of populations is due to each population's gene frequencies' being an average of several divergent subpopulations. If drift is causing differentiation within populations, it may eventually cause differentiation between populations. The importance of using a hierarchical approach to evaluating genetic structure is clear. Patterns occurring at one spatial scale may not be evident at others. One should not necessarily conclude that gene flow is substantial and that the risk of genetic erosion via drift is negligible just because differentiation between populations is small; the system may not be at equilibrium. This lesson is particularly important when recent changes in climate or land use are apparent.     

遗传资源获取与惠益分享制度的国际趋势及国家立法问题探讨

遗传资源及相关传统知识的获取与惠益分享已经成为许多国际论坛的焦点议题.<生物多样性公约>率先确立了遗传资源及传统知识的获取与惠益分享原则,联合国粮农组织(FAO)、联合国教科文组织(UNESCO)、世界卫生组织(WHO)、世界贸易组织(WTO)和世界知识产权组织(WIPO)等国际论坛也相继进行了相关议题的讨论,要求缔约方尊重和承认遗传资源及相关传统知识提供者的权利.我国在遗传资源及相关传统知识的获取与惠益分享方面还缺乏明确的政策,法规与制度体系尚未建立.需要建立获取与惠益分享的国家制度体系,此制度体系中需要确保公平公正分享惠益,体现遗传资源的国家主权,并尊重当地人民和地方社区的权利与利益.     

重庆大木山木本植物区系及植物资源特点

基于野外调查资料,对位于三峡库区腹心地带的大木山的木本植物区系及资源特点进行研究,以期为该地区生物多样性保护和可持续利用提供依据.野外调查共发现木本植物738种,隶属于86科、288属.其中裸子植物6科、10属、15种,双子叶植物77科、271属、699种,单子叶植物3科、7属、24种.乔木268种,灌木398种,木质藤本72种.科的组成优势现象十分明显,含10种以上的科有26个,包含164属、526种植物,分别占该区木本植物总属数和总种数的56.94%和71.27%,是该区木本植物区系构成的主导成分.木本植物区系成分复杂,属的分布类型有14个,种的分布类型有12个,区系具有明显的过渡性特征.有483个中国特有种分布于该地区,占总种数的65.71%,其中27.12%的物种为华中植物区特有种.13个地区的聚类分析表明大木山与华中植物区和华东植物区关系最为密切.木本植物资源以药用、材用、观赏、食用类为主,古老孑遗植物和珍稀濒危植物丰富.图l表5参35     

Genetic Diversity and Population Size in Four Rare Southern Appalachian Plant Species

Allozyme diversity was examined in four rare, high-montane plant species from the Appalachian Mountains of southeastern North America. These species may represent relictual members or descendants of an alpine community that was more widespread during the late Pleistocene. We sampled five populations of Geum radiatum (Rosaceae), Carex misera (Cyperaceae), Trichophorum cespitosum (Cyperaceae), and the four known populations of Calamagrostis cainii (Poaceae). Genetic diversity was low for all species but was typical of that found for plant species with limited ranges. Low genetic diversity may reflect historical events associated with changes in the species' biogeography. As the Pleistocene climate warmed, suitable habitat decreased in areal extent and became fragmented, probably resulting in smaller, more-isolated populations. In recent times these species, which co-occur in fragile rock outcrop habitats, have been adversely affected by human activities. Genetic analyses revealed reduced diversity in populations of decreasing size for three species. Estimates of gene flow were low ( Nm < 1.0) in all four species. Positive associations between genetic diversity and population size, evidence of recent population declines, and the low estimates of gene flow suggest that genetic drift may play a prominent role in shaping the present-day genetic composition of these species. Furthermore, these data suggest that the genetically depauperate populations are unlikely to regain genetic variation without human intervention.