Planning for optimal conservation of geographical genetic variability within species

Diniz‐Filho, José Alexandre Felizola; Melo, Dayane; Oliveira, Guilherme de; Collevatti, Rosane Garcia; Soares, Thannya Nascimento; Nabout, João Carlos; Lima, Jacqueline de Souza; Dobrovolski, Ricardo; Chaves, Lázaro José; Naves, Ronaldo Veloso; Loyola, Rafael; Telles, Mariana Pires de Campos

doi:10.1007/s10592-012-0356-8

Cited by 62 publications

(63 citation statements)

References 35 publications

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“…Under the present scenario of low gene flow, low genetic diversity and high population differentiation, decisions made on the conservation of D. alata should include allelic diversity and regional patterns of landscape fragmentation to establish corridors and improve connectivity among populations and potentially increasing effective population size (Diniz-Filho et al, 2012). Because allelic richness tends to decrease with distance from West Brazil, where one can find populations with the highest levels of allelic richness (for example, AMS, AQMS, CAMT, RAMT, SMS, Table 1), this region should be a priority in conservation planning, together with the RAGO and RAMT populations, where the vegetation is continuous.…”

Section: Discussionmentioning

confidence: 99%

“…Because allelic richness tends to decrease with distance from West Brazil, where one can find populations with the highest levels of allelic richness (for example, AMS, AQMS, CAMT, RAMT, SMS, Table 1), this region should be a priority in conservation planning, together with the RAGO and RAMT populations, where the vegetation is continuous. These populations have also been included in systematic conservation planning, to establish optimum strategies for in situ conservation of D. alata, as the smallest set of local population that should be conserved to represent the known genetic diversity (Diniz-Filho et al, 2012).…”

Section: Discussionmentioning

confidence: 99%

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Demographic history and the low genetic diversity in Dipteryx alata (Fabaceae) from Brazilian Neotropical savannas

et al. 2013

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Genetic effects of habitat fragmentation may be undetectable because they are generally a recent event in evolutionary time or because of confounding effects such as historical bottlenecks and historical changes in species' distribution. To assess the effects of demographic history on the genetic diversity and population structure in the Neotropical tree Dipteryx alata (Fabaceae), we used coalescence analyses coupled with ecological niche modeling to hindcast its distribution over the last 21 000 years. Twenty-five populations (644 individuals) were sampled and all individuals were genotyped using eight microsatellite loci. All populations presented low allelic richness and genetic diversity. The estimated effective population size was small in all populations and gene flow was negligible among most. We also found a significant signal of demographic reduction in most cases. Genetic differentiation among populations was significantly correlated with geographical distance. Allelic richness showed a spatial cline pattern in relation to the species' paleodistribution 21 kyr BP (thousand years before present), as expected under a range expansion model. Our results show strong evidences that genetic diversity in D. alata is the outcome of the historical changes in species distribution during the late Pleistocene. Because of this historically low effective population size and the low genetic diversity, recent fragmentation of the Cerrado biome may increase population differentiation, causing population decline and compromising long-term persistence.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Demographic history and the low genetic diversity in Dipteryx alata (Fabaceae) from Brazilian Neotropical savannas

et al. 2013

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“…However, there have also been discussions on how to conserve intraspecific genetic diversity, which began with the debate regarding the definitions of "evolutionarily significant units" and management units Telles, 2002, 2006). More recently, Diniz-Filho et al (2012) applied SCP reasoning to define a set of priorities at the population level using alleles from microsatellite loci as variables, where the goal was to establish the smallest number of local populations required to represent all known genetic diversity of the species (alleles). Schlottfeldt et al (2015a,b) developed a more complex model based on a set of multi-objective algorithms, which also allowed several properties of the populations to be optimized simultaneously.…”

Section: Introductionmentioning

confidence: 99%

Exhaustive search for conservation networks of populations representing genetic diversity

2016

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ABSTRACT. Conservation strategies routinely use optimization methods to identify the smallest number of units required to represent a set of features that need to be conserved, including biomes, species, and populations. In this study, we provide R scripts to facilitate exhaustive search for solutions that represent all of the alleles in networks with the smallest possible number of populations. The script also allows other variables to be added to describe the populations, thereby providing the basis for multi-objective optimization and the construction of Pareto curves by averaging the values in the solutions. We applied this algorithm to an empirical dataset that comprised 23 populations of Eugenia dysenterica, which is a tree species with a widespread distribution in the Cerrado biome. We observed that 15 populations would be necessary to represent all 249 alleles based on 11 microsatellite loci, and that the likelihood of representing all of the alleles with random networks is less than 0.0001. We selected the solution (from two with the smallest number of populations) obtained for the populations with a higher level of climatic stability as the best strategy for in situ conservation of genetic diversity of E. dysenterica. The scripts provided in this study are a simple and efficient alternative to more complex optimization methods, especially when the number of populations is relatively small (i.e., <25 populations).

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“…That study was pioneer in the use of information about allele frequency, heterozygosity, and Hardy-Weinberg equilibrium as objectives for simultaneous optimization. Diniz-Filho et al (2012b) used a mono-objective approach (in particular, simulated annealing) to find the Observe that for points B and C, it is not possible to obtain an improvement in one objective without a degradation of the other objective, i.e., f 1B < f 1C , f 2B > f 2C . The solutions (points) A, B, C, and D are optimal when f 1 and f 2 are considered.…”

Section: Introductionmentioning

confidence: 99%

Multi-objective optimization for plant germplasm collection conservation of genetic resources based on molecular variability

Schlottfeldt

Walter

Carvalho

et al. 2015

Tree Genetics & Genomes

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Germplasm collections play a significant role among strategies for conservation of diversity. It is common to select a core collection to represent the genetic diversity of a germplasm collection, in order to minimize the cost of conservation, while ensuring the maximization of genetic variation. We aimed to solve two main problems: (1) to select a set of individuals, from an in situ data set, that is genetically complementary to an existing germplasm collection, and (2) to define a core collection for a germplasm collection. We proposed a new multi-objective optimization (MOO) approach based on principles of systematic conservation planning (SCP) incorporating heterozygosity information; therefore, optimization takes genotypic diversity and variability patterns into account as well. As a case study, we used Dipteryx alata microsatellite loci information from two sources, an ex situ germplasm collection located at the Agronomy School of the Federal University of Goiás (UFG-AS), and an in situ data set composed of 642 sampled individual trees. We were able to identify within a population of several individuals, the exact accessions/samples that should be chosen in order to preserve the species diversity. We found that material from nine in situ individual trees are enough to complement the UFG-AS germplasm collection as it is, and that it is possible to define a core collection of 20 individual trees representing all studied genetic diversity. Moreover, we defined a method (a protocol) to deal with large amounts of accessions in the context of MOO. The proposed approach can be used to help constructing collections with maximal allelic richness and can also be extended to the in situ conservation. As far as we know, this is the first time that principles of SCP and the MOO approach are applied to the problem of complementing a germplasm collection and of finding a core collection for a germplasm collection.

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Planning for optimal conservation of geographical genetic variability within species

Cited by 62 publications

References 35 publications

Demographic history and the low genetic diversity in Dipteryx alata (Fabaceae) from Brazilian Neotropical savannas

Demographic history and the low genetic diversity in Dipteryx alata (Fabaceae) from Brazilian Neotropical savannas

Exhaustive search for conservation networks of populations representing genetic diversity

Multi-objective optimization for plant germplasm collection conservation of genetic resources based on molecular variability

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