Neotropical niche evolution of <i>Otoba</i> trees in the context of global biogeography of the nutmeg family

Frost, Laura A.; Santamaría-Aguilar, Daniel; Singletary, Daisy; Lagomarsino, Laura P.

doi:10.1111/jbi.14290

Cited by 10 publications

(13 citation statements)

References 94 publications

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“…Phylogenetic groups of species differ widely in their realised climatic niche. These differences may result from selective changes promoting niche widening or its converse (Aagesen et al 2016, Velasco et al 2018, Mondanaro et al 2020, Frost et al 2022), or be essentially neutral with regards to the fundamental niche (Bonetti & Wiens 2014, Boucher et al 2014, Saupe et al 2019). Whether or not the fundamental niche changes, identifying such differences has a huge impact on our understanding of species diversity patterns (Rolland & Salamin 2016, Olalla‐Tárraga et al 2017, Rolland et al 2018) of the link existing between climatic niche breadth and extinction risk (Wiens et al 2019, Taheri et al 2021) and of how climate change is impacting extinction and will continue to do so (Hanson et al 2020, Trisos et al 2020).…”

Section: Discussionmentioning

confidence: 99%

“…moves along the niche dimension), or both. Although there is solid recognition that phylogenetic effects must be considered to understand these changes under a proper comparative context (Kellermann et al 2012, Gutiérrez‐Pesquera et al 2016), most researchers just estimate the phylogenetic signal in bioclimatic variables, or rely on standard models of evolution such as BM (Münkemüller et al 2015, Corro et al 2021) or the Ornstein–Uhlenbeck process (Velasco et al 2018, Frost et al 2022). Yet, BM resides on assumptions that can be unrealistic for describing climatic niche evolution (Diniz‐Filho et al 2012, Kamilar & Cooper 2013), and even a significant signal does not indicate that the effect of shared ancestry on species' climatic niche is relevant (Freckleton & Jetz 2009, Cooper et al 2011, Münkemüller et al 2015).…”

Section: Discussionmentioning

confidence: 99%

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Testing for changes in rate of evolution and position of the climatic niche of clades

et al. 2022

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1.There is solid recognition that phylogenetic effects must be acknowledged to appreciate climatic niche variability among species clades properly. Yet, most currently available methods either work at the intra-specific level (hence they ignore phylogeny) or rely on the Brownian motion model of evolution to estimate phylogenetic effects on climatic niche variation. The Brownian motion model may be inappropriate to describe niche evolution in several cases, and even a significant phylogenetic signal in climatic variables does not indicate that the effect of shared ancestry was relevant to niche evolution. 2. We introduce a new phylogenetic comparative method which describes significant changes in the width and position of the climatic niche at the interspecific (clade) level, while making no a priori assumption about how niche evolution took place. 3. We devised the R function phylo.niche.shift to estimate whether the climatic niches of individual clades in the tree are either wider or narrower than expected, and whether the niche occupies unexpected climates. We tested phylo.niche.shift on realistic virtual species' distribution patterns applied to a phylogeny of 365 extant primate species. 4. We demonstrate via simulations that the new method is fast and accurate under widely different climatic niche evolution scenarios. phylo.niche.shift showed that the capuchin monkeys and langurs occupy much wider, and prosimian much narrower, climatic niche space than expected by their phylogenetic positions. 5. phylo.niche.shift may help to improve research on niche evolution by allowing researchers to test specific hypotheses on the factors affecting clades' realised niche width and position, and the potential effects of climate change on species' distributions.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Testing for changes in rate of evolution and position of the climatic niche of clades

et al. 2022

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“…Widely distributed species often share broad similarities in genetic structure across their geographic ranges, reflecting similar demographic responses to climate change and landscape features (Avise, 2009; Hickerson et al., 2010). In lowland Neotropical rain forests, landscape features such as large rivers (Gascon et al., 2000; Naka & Brumfield, 2018; Nazareno et al., 2019), dry forest corridors (Costa, 2003), and mountain ranges (Bemmels et al., 2018; Frost et al., 2022; Serrano et al., 2021) frequently structure species distributions and spatial patterns of genetic variation. Mountain ranges have long been hypothesized to represent especially strong dispersal barriers to lowland rain forest species due to the high degree of specialization to narrow, stable climatic niches exhibited by tropical taxa (Janzen, 1967).…”

Section: Introductionmentioning

confidence: 99%

“…Mountain ranges have long been hypothesized to represent especially strong dispersal barriers to lowland rain forest species due to the high degree of specialization to narrow, stable climatic niches exhibited by tropical taxa (Janzen, 1967). At phylogenetic scales, the Northern Andean Cordilleras are an important biogeographic barrier to rain forest trees (Frost et al., 2022; Winterton et al., 2014), birds (Cracraft & Prum, 1988), and other vertebrates (Ron, 2000), yet many lowland rain forest tree species are distributed on both sides of the Andes (Bemmels et al., 2018; Dick et al., 2005; Gentry, 1982) in both the Amazon Basin and Central America (here broadly defined to also include the Chocó or the Pacific coastal region of Colombia and Ecuador; Figure 1). Little is known about how such species dispersed across the Andes and whether dispersal has left similar patterns of population genetic structure across multiple taxa.…”

Section: Introductionmentioning

confidence: 99%

“…, and mountain ranges Frost et al, 2022;Serrano et al, 2021) frequently structure species distributions and spatial patterns of genetic variation. Mountain ranges have long been hypothesized to represent especially strong dispersal barriers to lowland rain forest species due to the high degree of specialization to narrow, stable climatic niches exhibited by tropical taxa (Janzen, 1967).…”

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Patterns in the genetic structure of 49 lowland rain forest tree species co‐distributed on opposite sides of the northern Andes

Bemmels,

Pérez,

Valencia

et al. 2024

Biotropica

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The Andes are a major dispersal barrier for lowland rain forest plants and animals, yet hundreds of lowland tree species are distributed on both sides of the northern Andes, raising questions about how the Andes influenced their biogeographic histories and population genetic structure. To explore these questions, we generated standardized datasets of thousands of SNPs from paired populations of 49 tree species co‐distributed in rain forest tree communities located in Panama and Amazonian Ecuador and calculated genetic diversity (π) and absolute genetic divergence (dXY) within and between populations, respectively. We predicted (1) higher genetic diversity in the ancestral source region (east or west of the Andes) for each taxon and (2) correlation of genetic statistics with species attributes, including elevational range and life‐history strategy. We found that genetic diversity was higher in putative ancestral source regions, possibly reflecting founder events during colonization. We found little support for a relationship between genetic divergence and species attributes except that species with higher elevational range limits exhibited higher dXY, implying older divergence times. One possible explanation for this pattern is that dispersal through mountain passes declined in importance relative to dispersal via alternative lowland routes as the Andes experienced uplift. We found no difference in mean genetic diversity between populations in Central America and the Amazon. Overall, our results suggest that dispersal across the Andes has left enduring signatures in the genetic structure of widespread rain forest trees. We outline additional hypotheses to be tested with species‐specific case studies.

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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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Neotropical niche evolution of Otoba trees in the context of global biogeography of the nutmeg family

Cited by 10 publications

References 94 publications

Testing for changes in rate of evolution and position of the climatic niche of clades

Testing for changes in rate of evolution and position of the climatic niche of clades

Patterns in the genetic structure of 49 lowland rain forest tree species co‐distributed on opposite sides of the northern Andes

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

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