Rivers shape population genetic structure in <i>Mauritia flexuosa</i> (Arecaceae)

Sander, Nilo Leal; Pérez-Zavala, Francisco; Silva, Carolina Joana da; Arruda, Joari Costa de; Pulido, María Teresa; Barelli, Marco Antônio Aparecido; Rossi, Ana B.; Viana, Alexandre Pío; Boechat, Marcela Santana Bastos; Bacon, Christine D.; Cibrián-Jaramillo, Angélica

doi:10.1002/ece3.4142

Cited by 15 publications

(12 citation statements)

References 69 publications

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“…Theoretically, a reduction in genetic diversity is expected for small, highly fragmented populations (Lowe et al., 2009). However, our results are similar to those observed from eight populations of Mauritia flexuosa scattered throughout the Brazilian Amazon ( N A = 4.6–7; H E = 0.63–0.74; Sander et al., 2018) and from 46 Mauritia flexuosa populations distributed throughout its biogeographical range ( N A = 4.4–11.8; H E = 0.52–0.88; Melo et al., 2018); both studies also based on microsatellites loci. The high diversity detected among the Mauritia flexuosa stands could be partially explained by ongoing gene flow, which although is low ( N m =0.29), maintains a certain level of diversity (Lowe & Allendorf, 2010).…”

Section: Discussionsupporting

confidence: 92%

“…These values suggest a mating among full‐sibs and support the occurrence of intrapopulation spatial genetic structure which leads to a reduction of heterozygotes and eventually inbreeding depression (Keller & Waller, 2002). The inbreeding rate in this study was slightly higher compared to Mauritia flexuosa populations from northern South America (Sander et al., 2018). These inbreeding coefficients were also higher compared to populations of another widespread palm species Euterpe edulis ( F IS = 0.12; Gaiotto, Grattapaglia, & Vencovsky, 2003).…”

Section: Discussioncontrasting

confidence: 55%

“…Second, under the presence of null alleles, we would expect that some loci deviate from the Hardy–Weinberg equilibrium (Dubreuil et al., 2010), This, however, was not recovered in our study as all stands and seven out of eight loci analyzed deviated significantly from the Hardy–Weinberg equilibrium. Third, previous studies on Mauritia flexuosa already showed homozygote excess at different spatial scales (Melo et al., 2018; Sander et al., 2018). These arguments suggest that our genetic indexes mainly reflect true values linked with the biology of these populations rather than genotyping errors.…”

Section: Discussionmentioning

confidence: 85%

“…However, unsustainable overharvesting via uncontrolled felling of female individuals for fruit harvesting has strong negative impacts on its conservation (Rojas‐Ruiz et al, 2001). Additionally, palynological and genetic studies have highlighted the role of climatic shift during the Quaternary and river dynamics on the genetic structure of Mauritia flexuosa at the continental level (Lima, Lima‐Ribeiro, Tinoco, Terribile, & Collevatti, 2014; Melo, Freitas, Bacon, & Collevatti, 2018; Rull, 1998; Sander et al., 2018).…”

Section: Introductionmentioning

confidence: 99%

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High genetic diversity with low connectivity among Mauritia flexuosa (Arecaceae) stands from Ecuadorean Amazonia

2020

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Mauritia flexuosa dominated palm swamps are an important forest resource covering over 30,000 km2 across the Amazon basin. In Ecuadorean Amazonia, Mauritia flexuosa, a dioecious and arborescent palm species, forms small and isolated populations or large and dense stands on poorly drained soils. How these populations are genetically interconnected and how genetic diversity varies between cohorts of different ages remains little studied although they are important for conservation of these ecosystems. The genetic structure of Mauritia flexuosa was studied in five natural stands using eight microsatellite loci and two cohorts (seedling and adults). In addition, age structure and sex ratio within the stands were assessed using transects. The age structure of the studied Mauritia flexuosa stands is represented by a high number of seedlings (mean = 1,153.6/ha) and adults (mean = 563.2/ha), with a sex ratio favoring female individuals (1.42:1). These stands are also characterized by a fine‐scale genetic structure, high observed heterozygosity (mean: HO seedlings=0.52; HO adults=0.52), high inbreeding (mean: FIS seedlings = 0.26; FIS adults = 0.26), low number of migrants (Nm=0.29), strong genetic differentiation (mean: pairwise RST/ D‐values seedlings = 0.08/ 0.74; mean RST/D‐values adults = 0.17/ 0.76), and an average effective population size (Ne) of 191.42 individuals. No intergenerational genetic variation was detected between seedlings and adults. We suggest that the high genetic diversity and inbreeding as well as the strong differentiation among stands of these populations could be explained, at least partially, by a low genetic connectivity among populations. Destructive harvesting of its fruits and defaunation will be major threats to Mauritia flexuosa populations in the future. Abstract in Spanish is available with online material

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Section: Discussionsupporting

confidence: 92%

Section: Discussioncontrasting

confidence: 55%

Section: Discussionmentioning

confidence: 85%

Section: Introductionmentioning

confidence: 99%

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High genetic diversity with low connectivity among Mauritia flexuosa (Arecaceae) stands from Ecuadorean Amazonia

2020

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“…Rabinowitz (1978) proposed that the interacting effects of water depth with species‐specific propagule traits (“tidal sorting”) might explain the differential distribution (zonation) of mangrove species along the tidal gradient. Similarly, the position of populations relative to open‐water channels and the spatial arrangement of these channels and their tidal currents may determine rates of hydrological connectivity and influence population genetic structure (Hughes et al., 2009; Pilger et al., 2017; Sander et al., 2018; Thomaz et al., 2016). However, while “riverscape genetics” is an active field of research and the importance of tidal inundation, dispersal traits, and establishment in determining mangrove forest structure (intertidal zonation) has been studied extensively (e.g., Clarke et al., 2001; Jiménez & Sauter, 1991; Rabinowitz, 1978; Sousa et al., 2007; Wang et al., 2019), few studies have linked these factors to the local (<10 km) and fine‐scale (i.e., within‐population) spatial genetic structure of mangroves.…”

Section: Introductionmentioning

confidence: 99%

Channel network structure determines genetic connectivity of landward–seaward Avicennia marina populations in a tropical bay

Triest

Stocken

Akinyi

et al. 2020

Ecology and Evolution

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Botany and geogenomics: Constraining geological hypotheses in the neotropics with large‐scale genetic data derived from plants

Bedoya

2024

American J of Botany

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Decades of empirical research have revealed how the geological history of our planet shaped plant evolution by establishing well‐known patterns (e.g., how mountain uplift resulted in high rates of diversification and replicate radiations in montane plant taxa). This follows a traditional approach where botanical data are interpreted in light of geological events. In this synthesis, I instead describe how by integrating natural history, phylogenetics, and population genetics, botanical research can be applied alongside geology and paleontology to inform our understanding of past geological and climatic processes. This conceptual shift aligns with the goals of the emerging field of geogenomics. In the neotropics, plant geogenomics is a powerful tool for the reciprocal exploration of two long standing questions in biology and geology: how the dynamic landscape of the region came to be and how it shaped the evolution of the richest flora. Current challenges that are specific to analytical approaches for plant geogenomics are discussed. I describe the scale at which various geological questions can be addressed from biological data and what makes some groups of plants excellent model systems for geogenomics research. Although plant geogenomics is discussed with reference to the neotropics, the recommendations given here for approaches to plant geogenomics can and should be expanded to exploring long‐standing questions on how the earth evolved with the use of plant DNA.

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Rivers shape population genetic structure in Mauritia flexuosa (Arecaceae)

Cited by 15 publications

References 69 publications

High genetic diversity with low connectivity among Mauritia flexuosa (Arecaceae) stands from Ecuadorean Amazonia

High genetic diversity with low connectivity among Mauritia flexuosa (Arecaceae) stands from Ecuadorean Amazonia

Channel network structure determines genetic connectivity of landward–seaward Avicennia marina populations in a tropical bay

Botany and geogenomics: Constraining geological hypotheses in the neotropics with large‐scale genetic data derived from plants

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