Genetic structure of plantations and the conservation of genetic resources of Brazilian pine (Araucaria angustifolia)

With growing concern about maintenance of genetic variation and conservation of gene resources, the question arises on the extent to which a planted population should be considered a resource able to preserve the gene pool of a species. In this study, levels of genetic diversity were assessed in natural and planted populations of Araucaria angustifolia using AFLPs and nuclear microsatellites, in order to assess the usefulness of planted forests in programs of species’ genetic resource conservation. In general, the genetic structure of the plantations was not strongly differentiated from the natural populations. For microsatellites, gene diversity (H) and allelic richness were significantly higher in plantations, while inbreeding was not different between planted and natural populations. For AFLPs, no significant difference was found between groups in the measures of genetic diversity. In the cluster analysis based on microsatellite data, plantations and natural populations from Santa Catarina State were grouped together, suggesting that plantations preserved genetic information very similar to natural populations. The cluster analysis of populations based on AFLP data differentiated plantations from natural populations. This pattern may be a result of genetic hitchhiking of AFLP fragments with genes under selective pressure due to plantations establishment and management. We suggest that the moderate to high level of genetic diversity retained in A. angustifolia populations after the intense fragmentation of the natural forest has the potential to supply plant material with sufficient genetic diversity for the species conservation through the establishment of planted forests. A sustainable management of the extant forest remnants and forestation/reforestation enterprises should additionally attend to trends revealed in previous studies concerning population structure and gene flow.     

Genetic similarity of natural populations and plantations of Pinus roxburghii Sarg. in Nepal

? Genetic structures of five population pairs each consisting of one natural population and one neighbouring plantation of Pinus roxburghii Sarg. in Nepal were assessed using nuclear (nSSRs) and chloroplast microsatellite loci (cpSSRs).

? The mean number of alleles at nSSRs loci in natural populations was 5.0 compared to 4.93 in plantations while the average observed heterozygosities were the same in both groups (H ₀ = 0.50). Most of the alleles were common to all the populations, indicating that the populations correspond to a single genetic entity. Similarly forty-seven haplotypes were observed in natural populations compared to fifty haplotypes in plantations. Mean haplotype diversities of natural populations (0.953) and plantations (0.955) were very similar. Genetic diversity of Pinus roxburghii was relatively high with low or no evidence of inbreeding while genetic differentiation among all populations was very low (about 1%).

? The very low differentiation among natural populations indicates efficient long-distance gene flow among populations resulting in homogeneous genetic structures at least at selectively neutral loci. Even though the harvest and production of seeds and seedlings was largely uncontrolled, genetic structures of most plantations show no signs of reduced variation, inbreeding or other negative effects compromising the adaptedness or adaptability of planted forests.

     

成都麻羊种群微卫星标记遗传多样性评估

作为优良的地方山羊品种,成都麻羊对我国山羊品种的改良和新品种培育起了重要作用。畜禽遗传资源本质上是基因资源,保护畜禽遗传资源就是保护基因的多样性。为了了解成都麻羊的遗传情况,通过微卫星标记技术,选用8对中高度多态微卫星标记进行成都麻羊圈养种群的遗传多样性评估,共检测到60个等位基因,平均等位基因和平均有效等位基因数分别为7.5、2.36,平均观察杂合度、平均期望杂合度和平均多态信息含量分别为0.577、0.634和0.580。研究结果表明成都麻羊种群遗传多样性较高,具有较高的保种潜力。     

林木群体遗传资源可持续经营探讨Ⅰ.有关群体遗传变异信息理论分析

森林可持续经营问题逐渐成为人们关注的焦点 ,而林木群体遗传资源的可持续经营则是其中的重要内容。群体遗传变异信息对群体遗传资源可持续经营具有至关重要的指导作用 ,有关的信息涉及到交配系统、起源与形成历史、群体空间分布形成方式、遗传结构变异分布、地理变异、遗传与环境互作等。这些信息可以用分子标记和适应性数量性状变异来检测。依据这些综合信息可以制定出科学的群体遗传资源保护决策、理想的群体维持规模及合理的经营管理     

Allozyme markers in forest genetic conservation

Genetic diversity is important in tree-breeding, in managing rare and endangered tree species, and in maintaining healthy populations of widespread native tree species. Allozymes are useful in determining genetic relationships among species, where they can be used to assess affiliations of rare taxa and predict relative endangerment among species. Because allozymes sometimes yield different information about genetic variation within species than revealed by other traits, when estimates of total or adaptive genetic variation are important, allozymes are best used in conjunction with other traits. Allozymes are useful for measuring direct allelic diversity when designing ex-situ and in-situ conservation strategies. We demonstrate an application of canonical trend-surface analysis for determining locations of in-situ genetic conservation areas. Allozymes also serve as useful markers in monitoring the effects of forest management and other environmental changes on genetic diversity.This article was written and prepared by U.S. Government employees on official time, and is therefore in the public domain.     

Genetic Diversity and Mating System Analysis of Pinus massoniana in Second-Generation Clonal Seed Orchard

A total 61 clone parents and 320 open-pollination progenies from 8 clone individuals were identified by 12 polymorphic SSR loci.The result showed that the level of genetic diversity in progeny population was the same as in maternal population, progeny population had all alleles detected in maternal population,and there were not obvious surplus phenomenon of homozygotes in progeny population (F= 0.046).The south crown had more strobili than the north crown,however the genetic diversity of the north crown strobili was not substantially reduced.The progeny of neutral trees had the same level of genetic diversity as in the progeny of partial female trees,with the fixation index tended to be zero,which was accorded with Hardy-Weinberg equilibrium.The multilocus outcrossing rate in the seed orchard was 1.097,and there was no significant inbreeding between parents(t_m-t_s= - 0.031).The multilocus outcrossing rate and singlelocus outcrossing rate in the south crown were higher than that in the north crown.The multilocus outcrossing rate of partial female trees was the same as in neutral trees,and the neutral tree had no obvious declining outcrossing rate with reduced proportion of female and male strobilus compared with partial female tree, with the fixation index tended to be zero.The progeny of the second generation clonal seed orchard still had rich genetic diversity,gene exchange among clones was relatively sufficient,and biparental inbreeding was not significant.     

大别山不同龄级映山红种群遗传多样性的SSR分析

[目的]利用SSR标记比较大别山黄狮寨不同年龄级映山红(Rhododendron simsii Planch.)种群的遗传多样性及遗传结构,探究映山红不同世代间遗传多样性的变化规律,为大别山野生映山红资源的合理利用和高效保护提供科学依据。[方法]按照基径大小和丛枝多少将大别山黄狮寨典型映山红种群划分为老树、成树、小树、幼苗4个年龄级,筛选出12对多态性强的SSR引物用于PCR扩增,扩增产物经6%变性聚丙烯酰胺凝胶电泳检测并银染。构建"0/1"矩阵,利用POPGENE 32. 0软件分析种群遗传多样性。基于Nei's遗传距离,采用软件MEGA5. 0进行UPGMA聚类。[结果]不同龄级的映山红遗传多样性差别较大,幼苗和老树种群多样性最差,小树种群多样性最丰富。12个微卫星标记观测等位基因数为3～9个,平均5. 08;有效等位基因数为2. 254 9 6. 129 7,平均3. 460 5;观察杂合度HO和期望杂合度HE分别为0. 676 4～0. 881 2和0. 607 7～0. 690 7。Shannon信息指数(I)以小树群体最高,成树次之,幼苗最低。近交系数Fis为-0. 638 3～0. 174 4,平均为-0. 294 6;总近交系数Fit为-0. 615 1～0. 270 6,平均为-0. 162 1,表明各龄级种群内主要繁殖方式为杂交。分子方差分析(AMOVA)表明89. 76%的遗传变异存在于年龄级内,仅10. 24%存在于年龄级间。基因流水平高,仅1个位点Nm 1。遗传一致度最高的为小树和成树种群。[结论]大别山黄狮寨映山红种群遗传多样性丰富,种群间中度分化,遗传变异主要存在于年龄级内。     

Low genetic diversity and high genetic differentiation among severely fragmented populations of the critically endangered tree Talbotiella gentii (Fabaceae)

The genetic diversity among 17 populations (including 10 newly discovered) of Talbotiella gentii (Fabaceae, Caesalpinioideae), a rare tree species endemic to Ghana, was assessed using random amplified polymorphic DNA (RAPD). A total of 80 polymorphic bands were generated from eight primers and analysed by cluster and correspondence analysis. This showed a clear distinction between populations, with two major groups associated with geographical origin. AMOVA analysis showed that 94.05% of the genetic variation was partitioned among populations, while only 5.95% was found within populations suggesting little gene flow between populations. Possible reasons for the high population genetic differentiation and the low levels of genetic variation within populations are inbreeding and genetic drift. Of a total of 26 known populations, 14 are now extinct, five during the course of this study. Action to prevent complete extinction of the species is therefore urgent.     

马尾松二代无性系种子园遗传多样性和交配系统分析

运用12对SSR引物,对马尾松二代无性系种子园内61个亲本及其中8个无性系单株的320个子代进行研究。结果显示:子代群体包含亲本群体的所有等位基因,子代与亲本具有同样高的遗传多样性,子代群体的F为0.045,纯合子过剩的现象不明显;树冠北面子代遗传多样性并未因其雌、雄球花量较树冠南面减少而有明显的降低;雌雄均衡和偏雌型植株子代遗传多样性基本一致,以偏雌型植株子代略大,二者F趋于0,子代基本符合哈温平衡。种子园异交率较高,多位点异交率为1.098,子代亲本的近交现象不显著(tm-ts=-0.033);树冠南面多位点与单位点异交率均高于树冠北面;偏雌与雌雄均衡型植株的多位点异交率基本相当,雌雄均衡型植株并未因其雌、雄球花量比例较偏雌型植株减小而呈现异交率明显降低的现象,2种类型植株的近交指数均接近于0。整体而言,马尾松二代种子园子代仍具有丰富的遗传多样性,无性系间基因交流相对充分,子代亲本近交现象不明显。     

Fine-scale analysis reveals a potential influence of forest management on the spatial genetic structure of Eremanthus erythropappus

Forest management may have significant effects on forest connectivity and natural population sizes.Harvesting old-growth single trees may also change natural patterns of genetic variation and spatial genetic structure.This study evaluated the impacts of forest management using a silvicultural system of seed trees on the genetic diversity and spatial genetic structure of Eremanthus erythropappus(DC.)MacLeish.A complete survey of 275 trees on four plots was undertaken out to compare the genetic variation of a managed stand with an unmanaged stand.We genotyped all adult and juvenile individuals 60 months after the management and compared the genetic diversity and the spatial genetic structure parameters.Genetic diversity was considered high because of an efficient gene flow between stands.There were no genetic differences between stands and no evidence of inbreeding.Genetic clustering identified a single population(K=1),indicating no genetic differentiation between managed and unmanaged stands.Adult and juvenile individuals of the unmanaged stand were more geographically structured than individuals from the managed one.There was a tendency of coancestry among juveniles at the first class of distance of the managed stand,suggesting a drift of genetic structure possibly caused by management.Understanding early responses to management on genetic diversity and stand structure is a first step to ensuring the effectiveness of conservation practices of tree species.The sustainability of forest management of E.erythropappus on genetic diversity,and more accurately,on spatial genetic structure needs evaluation over time to promote effective conservation of the population size and genetic variability.     

毛红椿天然群体遗传多样性及取样策略探讨

[目的]研究毛红椿天然群体遗传多样性取样策略,为其种质资源收集、保存和遗传多样性保护等提供参考依据。[方法]利用8对微卫星分子标记进行毛红椿天然群体遗传多样性和空间自相关分析,综合制定其天然群体合理取样策略。[结果]毛红椿天然群体等位基因数平均为7.5个,期望杂合度(H_e)和多态性信息指数(PIC)均值分别为0.643 7和0.636 0,基因分化系数(G_(ST))均值为0.290 7。在遗传多样性取样策略方面,提出了根据毛红椿群体基因分化系数来确定取样群体遗传变异所占总变异比例的运算公式为1-(G_(ST))~(n-1),其中,n为取样群体的数量。当取样群体达到4个时,基本上能包括该树种97.5%的遗传变异;同时确定了目标群体的选择方法,应选择与其它群体间基因分化系数均值较大的4个群体,即贵州册亨(CH)、浙江遂昌(SC)、浙江仙居(XJ)和云南师宗(SZ)。通过构建云南宾川(BC)、云南师宗(SZ)和江西宜丰(YF)群体内取样单株数量与基因多样性和等位基因之间的捕获曲线,确定了群体内取样单株数量应达到15个以上;毛红椿天然群体内300～520 m范围内的单株间存在相似关系,超出此范围个体间差别较大,说明在进行群体内单株取样时,单株间距应大于520 m。[结论]取样群体数量、群体间遗传分化系数、群体内单株数量以及单株间距离等影响了毛红椿取样群体的遗传多样性。毛红椿天然群体遗传多样性取样策略为取样群体4个、每个群体最少取样15个单株,单株间距大于520 m。     

濒危植物缙云卫矛不同种群的种子萌发研究

选取重庆特有濒危植物缙云卫矛7个相互间有不同程度空间隔离的种群,对其种子萌发特征进行研究.结果表明:7个种群的种子在实验室条件下萌发率差异极显著,种子萌发率与所处种群的大小呈极相关,大种群与小种群的种子萌发率差异达极显著水平,而各种群的种子萌发率与其所处生境的土壤因子相关性不显著.各种群的平均种子质量与种群大小及土壤条件均无关,说明种群平均种子质量是一个较为稳定的不易受影响的参数.小种群低萌发率的主要原因可能是由于近交衰退带来遗传多样性的丧失引起的,而不是环境因素的影响.研究表明:要长期保护这些小种群,应将种群统计因素与种群遗传因素结合起来考虑,增加种群中个体数目,扩大种群,提高种子萌发率,促进种群更新,才能有效地维持这些小种群的生存发展.     

基于微卫星DNA标记分析刺槐叶瘿蚊遗传多样性指数与样本量的相关性

[目的]探讨基于微卫星标记分析刺槐叶瘿蚊遗传多样性指数与样本量的相关关系。[方法]设置了12个样本量梯度,选取11对微卫星引物分析了我国刺槐叶瘿蚊5个种群的遗传多样性指数。[结果]表明,样本量的大小与平均等位基因数(Na)呈显著正相关,与有效等位基因数(Ne)呈中度正相关,与观测杂合度(Ho)呈负相关,而与期望杂合度(He)、Nei’s遗传多样性指数(H)和多态信息含量(PIC)没有明显相关性。此外,当样本量小于25时,随着样本量的增加,有效等位基因数增幅明显,观测杂合度起伏变化较大,但当样本量大于30时,随着样本量的增加,上述两个指数增(降)幅度平缓。[结论]在利用微卫星DNA标记对我国刺槐叶瘿蚊种群的遗传多样性研究中,选取的最适样本量应为25～30,分析的最适遗传多样性指数应为期望杂合度、Nei’s遗传多样性指数和多态信息含量。该研究结果将为我们后续研究提供科学数据,并有助于分析其他入侵昆虫种群遗传结构的研究,同时可为其他双翅目昆虫的遗传多样性研究提供样本量参考。     

Breeding without breeding: selection using the genomic best linear unbiased predictor method (GBLUP)

We demonstrate, using height data from a clonal trial, how the genomic best linear unbiased predictor method (GBLUP) is ideal for determining future breeding potential in situations (either in plantations or wild stands) where high mortality due to biotic or abiotic factors has occurred. The method is effective because it does not require the development of structured pedigree or classical progeny testing, rather it uses DNA fingerprinting to determine the genealogical relationship among individuals. The resulting genetic network is known as the realized relationship matrix, which in turn is used in classical quantitative genetics analyses to determine the genetic worth of all fingerprinted individuals. Selection of desirable individuals among the surviving population is aimed at maximizing genetic diversity even when the original genetic source is unknown. This is accomplished by determining the number of founder genome equivalents which can be used to estimate the inbreeding effective population size. During the selection phase, genetic diversity can be balanced against genetic gain so that diversity is maximized while gain for any particular attribute is optimized.     

Genetic variation and divergence in Scots pine (Pinus sylvestris L.) within its natural range in Italy

Twenty-one populations of Scots pine sampled over the entire Italian range of the species were analysed for genetic variation scored at nine nuclear SSR markers. The main aim of the work was to find genetic features useful for conservation management, namely allelic composition, gene diversity and differentiation. High levels of intra-population variability were scored. The only population sampled in the Apennines gave the lowest values, confirming the genetic erosion undergone in the Scots pine remnants in this area. A low level of genetic variability was also scored for populations from the Po valley and hills of Piedmont. Most genetic diversity was found within populations, while only a small amount occurred among them (F _ST?=?0.058). Both Bayesian clustering and sPCA analysis showed a East–West subdivision, notwithstanding the unclear position of populations from the Po valley. The population from the Apennines was always clearly separated from the others. The results are discussed in terms of post-glacial recolonisation, as well as for defining genetically homogeneous regions for Scots pine in Italy. The management of genetic resources could benefit from the identification of such ‘gene zones’, thereby avoiding the use of non-local reproductive material for plantations, which can represent one of the most important reasons for failure of reforestation. In addition, the assessment of the biogeographic genetic structure by neutral markers is a prerequisite for disentangling the influence of selectively neutral and non-neutral processes on the distribution of adaptive genetic variability.     

Genetic diversity and differentiation of yellowwood [<Emphasis Type="Italic">Cladrastis kentukea</Emphasis> (Dum.Cours.) Rudd] growing in the wild and in planted populations outside the natural range

Yellowwood (Cladrastis kentukea) grows in small, widely scattered populations in the wild, but is also a popular ornamental tree that thrives when planted in urban areas outside its natural range. Since the small native populations of yellowwood in several states are considered at risk of extirpation, the cultivated population could serve as an ex situ repository of yellowwood genetic diversity that could be used to restore lost local populations of the species. The potential value of cultivated yellowwood for conservation depends on the genetic diversity among cultivated trees compared to natural populations. Using nuclear microsatellite markers, we genotyped 180 yellowwoods from natural populations in Indiana, Missouri, Arkansas, and Kentucky, along with 61 trees from urban parks and landscapes in Indiana, Ohio, and Missouri. We found that, even when statistics were adjusted based on population size, the urban “population” had higher genetic diversity than any of the wild populations sampled, indicating that commercially-grown yellowwood is most likely a mixture of genotypes from isolated wild populations. We observed strong genetic differentiation among wild populations, and evidence for inbreeding in at least one of the wild populations.     

花吊丝竹居群遗传多样性的ISSR分析

[目的]研究花吊丝竹居群遗传多样性和遗传结构,为种质资源有效利用和良种选育提供理论指导。[方法]利用12条ISSR引物对48份种质(共3个居群)花吊丝竹居群进行遗传多样性和遗传距离分析。[结果]共检测到124个位点,其中,多态性位点为102个,种质和居群水平上的多态位点百分比(PPB)分别为82. 26%和50. 27%,Ne’基因多样性指数(He)分别为0. 220 4和0. 206 6,Shannon’s信息指数(I)分别为0. 349 4和0. 300 5,表明花吊丝竹居群间存在中等水平的遗传变异。根据Nei’s遗传多样性计算出不同居群间分化水平(Gst)=0. 163 3,表明16. 33%的遗传变异存在于居群间,居群内的遗传变异为83. 67%。居群间的基因流Nm为2. 562 1,表明花吊丝竹居群间存在较大基因流,很大程度减少居群间遗传差异。基于遗传距离的UPGMA聚类结果表明,48份种质可分为3组,3个居群可分为2组,居群间地理距离与亲缘关系无显著相关性。[结论]虽然花吊丝竹主要靠营养生殖来繁衍后代,其居群遗传多样性较丰富,且居群内遗传多样性大于居群间。此外,福建居群遗传多样性明显高于广西和广东地区居群。     

Fragmentation and spatial genetic structure in Tabebuia ochracea (Bignoniaceae) a seasonally dry Neotropical tree

In this study we investigate the effect of fragmentation and disturbance on the spatial genetic structure, heterozygosity and inbreeding in Tabebuia ochracea (Bignoniaceae) in a seasonally Neotropical dry forest in the medium São Francisco River basin, Centre-East Brazil, based on the polymorphism at seven microsatellite loci. Four populations with different histories of disturbance and fragmentation were sampled: two continuous population (CP1 and CP2), with no history of recent disturbance and two fragmented and isolated population (FP1 and FP2), with recent history of disturbance due to logging for pasture establishment. Fragmented and continuous populations did not differ in any estimated parameter. However, all populations showed low levels of polymorphism and genetic diversity and high levels of inbreeding. Also, no spatial genetic structure was detected for populations using SPAGeDI software and no differentiation between these four populations was detected by Bayesian analyses performed with STRUCTURE software (K = 1). Differentiation measure by Wright's θ (0.032) and Hedrick G_ST (0.032) were significant but low. Our results strongly suggest that continuous populations are seed sources for the fragmented populations and that fragmentation and disturbance have been affecting these populations of T. ochracea in the Centre-East Brazil, leading to low levels of polymorphism and genetic diversity, and high inbreeding. Therefore, conservation efforts should increase in this region, with a reduction of agriculture expansion and the remove of cultivated areas and cattle from the Mata Seca and Lagoa do Cajueiro State Parks.     

Effect of forest management on gene pools

The influence of current forest management practices on gene pools is discussed. These forest management methods range from natural regeneration to replacing local species with exotics. Genetic changes caused by drift, alterations in the mating system, and directional selection are considered. A baseline is provided by information on genetic variation and demography of natural populations. While biochemical markers are useful for monitoring broad changes in genetic diversity or levels of inbreeding, changes of adaptive characters are likely to go undetected because of the low correlation in level and pattern of variation between biochemical and adaptive characters.     

Analysis of genetic diversity for wild and captive green peafowl populations by random amplified polymorphic DNA technique

The genetic diversity of the populations for 14 wild green peafowls (Pavo muticus) and 18 captive green peafowls was investigated by using the technology of random amplified polymorphic DNA (RAPD). Totally 161 and 166 amplified bands were obtained by using 23 arbitrary primers to amplify the genomic DNA of wild and captive green peafowls respectively. The results showed that the average relative genetic distance of the wild and captive green peafowls populations was 0.0555 and 0.1355, respectively, and difference of the average relative genetic distances between the two populations was 0.1635. The Shannon diversity index for the wild and captive green peafowl populations was 0.4348 and 1.0163, respectively, which means that there exists significant difference in genetic diversity between the two populations, and the genetic diversity of wild green peafowl was low. The two populations originated from two different families according to analysis by the UPGMA method. This research can provide the theoretical basis for supervising genealogies management of peafowl populations.