Fragmentation can increase spatial genetic structure without decreasing pollen-mediated gene flow in a wind-pollinated tree

Wang, Rong; Compton, Stephen G.; Chen, Xiao‐Yong

doi:10.1111/j.1365-294x.2011.05293.x

Cited by 81 publications

(96 citation statements)

References 74 publications

(83 reference statements)

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“…Nonetheless, because empirical studies provided a mixed support for this prediction, it was argued that in many cases populations experienced fragmentation only recently, so that the observed inbreeding level still reflects more the historical conditions rather than the reduced population size (Aguilar et al 2008). Alternatively, fragmentation did not lead to increased inbreeding because of longdistance gene flow (Wang et al 2011;Leonardi et al 2012). In our study, however, A. campestre represents a stable distribution, with northern populations being naturally fragmented long enough to assure inbreeding to accumulate.…”

Section: Discussionmentioning

confidence: 99%

Population at the edge: increased divergence but not inbreeding towards northern range limit in Acer campestre

Chybicki

Waldon‐Rudzionek

Meyza

2014

Tree Genetics & Genomes

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Ecological conditions shape natural distribution of plants. Populations are denser in optimal habitats but become more fragmented in the areas of suboptimal environmental conditions. Usually, fragmentation increases towards the limits of species distribution. Fragmented populations are often characterised by decreased genetic variation, and this effect is frequent in peripheral populations, mostly due to the reduced effective population size. Interestingly, the genetic consequences of fragmentation seem to be relatively weak in forest trees. Using microsatellite markers, we assessed the impact of population fragmentation on the genetic structure of a European tree species Acer campestre. Within the study area, this medium-size wind-dispersed and insect-pollinated tree reveals a gradual decrease in population density towards the northern range limit. Over the distance of 150 km, we detected the significant decrease in allelic richness, heterozygosity as well as an increase in the rate of population divergence along with latitude. On the other hand, we failed to show that the observed patterns of genetic structure result from the variation in population densities. Moreover, inbreeding levels revealed no association with both density and geographic location, suggesting that pollen limitation does not occur, even at the range margin. As we showed that there is no difference in a dispersal scale between low-and highdensity populations in the study species, we argue that the genetic structure is a result of postglacial recolonization. However, unlike many other forest trees, A. campestre showed the sharp latitudinal genetic pattern at a very restricted spatial scale. Limited dispersal and high fragmentation are likely the reasons.

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Section: Discussionmentioning

confidence: 99%

Population at the edge: increased divergence but not inbreeding towards northern range limit in Acer campestre

Chybicki

Waldon‐Rudzionek

Meyza

2014

Tree Genetics & Genomes

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“…However there is evidence that gene flow dynamics may also be relatively robust to habitat fragmentation (e.g. Lowe et al 2005a;Wang et al 2011;Breed et al 2012b). In a study into the effects of habitat fragmentation on genetic structure of the wind-pollinated, gravity seed-dispersed chinquapin tree (Castanopsis sclerophylla) no significant difference was observed in genetic diversity or inbreeding between pre-and post-fragmented populations, and this was attributed to extensive pollen dispersal .…”

Section: Connectedness Of Populations and Level Of Gene Flowmentioning

confidence: 99%

Constraints to and conservation implications for climate change adaptation in plants

2015

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Contemporary climate change is having widespread impacts on plant populations. Understanding how plants respond to this change is essential to our efforts to conserve them. The key climate responses of plant populations can be categorised into one of three types: migration, in situ adaptation, or extirpation. If populations are to avoid extirpation then migration and/or in situ adaptation is essential. In this review we first articulate the current and future constraints of plant populations, but trees in particular, to the different adaptation strategies (e.g. space availability, rate of change, habitat fragmentation, niche availability). Secondly, we assess the use of the most appropriate methods (e.g. natural environmental gradients, genome and transcriptome scans) for assessing and understanding adaptive responses and the capacity to adapt to future challenges. Thirdly, we discuss the best conservation approaches (e.g. assisted migration, biodiversity corridors, ex situ strategies) to help overcome adaptive constraints in plants. Our synthesis of plant, and particularly tree, responses and constraints to climate change adaptation, combined with the identification of conservation strategies designed to overcome constraints, will help deliver effective management actions to assist adaptation in the face of current and future climate change.

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“…On Laoshan Island, both stock and seedling plants of C. sclerophylla have genetic diversity of over 88.9 %, making 81 % of its genetic variation from within the population (Shi 2008). Population fragmentation significantly reduces population genetic structure, but as a whole, gene flow does not change (Wang et al 2011(Wang et al , 2012. For C. sclerophylla, pollen spread has become more efficient although seed transmission has been restricted concomitant with the fragmentation, which has compensated for the disadvantage from restricted seed transmission.…”

Section: Discussionmentioning

confidence: 99%

“…For C. sclerophylla, pollen spread has become more efficient although seed transmission has been restricted concomitant with the fragmentation, which has compensated for the disadvantage from restricted seed transmission. The research of Shi (2008) and Wang (2012Wang ( , 2011, however, encompassed the genetic structure of C. sclerophylla on the larger scale of the whole Qiandao Lake region. On Laoshan Island, however, we believe the frequent genetic exchange within the community has prevented genetic drift, which has brought about low genetic variation within a short period, but the long-term inbreeding will increase the risk of within-community genetic drift and retrogression of the genetic structure.…”

Section: Discussionmentioning

confidence: 99%

Ecological succession of a natural community of Castanopsis sclerophylla on Laoshan Island, China

et al. 2016

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Castanopsis sclerophylla was surveyed for its root turion capacity on Laoshan Island in Zhejiang Province and dispersion patterns of seedlings, genetic diversity and genetic variation coefficient was studied using a SSR (simple sequence repeat) molecular marker technique to explore the genetic diversity of C. sclerophylla (Lindl.) Schott as a community and evaluate the community's development. The results showed that C. sclerophylla had strong root turion capacity, of which type Re2 was the most frequent, accounting for 32.4 and 82.4 % of the seedlings under the stock plant were from within-community mating; the 6 pairs of SSR primers chosen yielded high resolution with 97.6 % polymorphic sites; the within-community genetic diversity was over 88.9 % with stock plants (0.49) [ seedling plants (0.45). Apparently, C. scerophyllan on Laoshan Island, propagating mainly by root turions, has developed high genetic diversity within a short period, keeping the community in a stage of stable growth and moving toward a climax community. The tillers, however, aggravate closing of the community so that it receives less pollen from outside. Within-community mating is thus reaching seriously high levels, which can lead to lower within-community genetic variation, a decline in DNA genetic diversity, and is bad for its development. Therefore, human interference should be taken to expand genetic exchange among communities.

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Fragmentation can increase spatial genetic structure without decreasing pollen-mediated gene flow in a wind-pollinated tree

Cited by 81 publications

References 74 publications

Population at the edge: increased divergence but not inbreeding towards northern range limit in Acer campestre

Population at the edge: increased divergence but not inbreeding towards northern range limit in Acer campestre

Constraints to and conservation implications for climate change adaptation in plants

Ecological succession of a natural community of Castanopsis sclerophylla on Laoshan Island, China

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