The roles of rainfall, soil properties, and species traits in flowering phenology along a savanna-seasonally dry tropical forest gradient

Neves, Sâmia Paula Santos; Miranda, Lia d ́Afonsêca Pedreira de; Rossatto, Davi Rodrigo; Funch, Lígia Silveira

doi:10.1007/s40415-017-0368-1

Cited by 17 publications

(23 citation statements)

References 53 publications

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“…In seasonal tropical regions, the primary factor controlling and regulating phenological events is climate, especially precipitation, although temperature and photoperiod also play important roles (Borchert, 1998; Morellato et al, 2000; Borchert et al, 2005). Precipitation is essential as it regulates seasonality and water availability, and thus has a strong influence on tropical plant phenology (Méndez‐Alonzo et al, 2013; Morellato et al, 2016; Neves et al, 2017). However, biotic selective pressures such as herbivory, competition for pollinators and seed dispersers, and abiotic factors including fire and soil depth, fertility, and water availability also influence plant phenological responses and patterns (Aide, 1988; Cardoso et al, 2012; Lamarre et al, 2014; Morellato et al, 2016; Le Stradic et al 2018; Pillon et al, 2020).…”

Section: Introductionmentioning

confidence: 99%

Vegetative and reproductive phenology in a tropical grassland–savanna–forest gradient

Oliveira

Messeder

Teixido

et al. 2021

J Vegetation Science

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Question: Climate, particularly precipitation, is the primary factor driving tropical plant phenology because of its relevant role in regulating water availability. However, differences in soil physicochemical properties can also drive resource availability, potentially affecting plant phenology, especially under similar environments in terms of rainfall regime. We determined whether the seasonality and synchrony of the vegetative and reproductive phenophases differ along a grassland-savanna-forest gradient under the same climate regime in a Neotropical seasonal ecosystem. We hypothesized that species growing on shallow, nutrient-impoverished soils have a higher capacity to respond to precipitation pulses than those on rich soils.Location: Serra do Cipó, southeastern Brazil. Methods:We quantified soil physicochemical properties associated with fertility and water retention of the grassland (campo rupestre), savanna (cerrado) and forest, and determined the phenological strategies of 70 species across the three vegetation types by monitoring vegetative and reproductive phenophases over one year. For each phenophase, in each vegetation type, we evaluated the seasonality and synchrony of phenological patterns. We quantified the phylogenetic signal for phenophases to disentangle the relative roles of historical vs ecological drivers of plant phenology.Results: Soils from campo rupestre were more nutrient-and water-limited than those of cerrado and forest. Cerrado and forest communities had similar phenological strategies, whereas species from campo rupestre showed strategies that maximize resource acquisition and conservation. In the cerrado and forest, leafing and flowering patterns were seasonal, with leaf flushing and flowering peaking at the onset of the rainy season and leaf senescence in the dry season. Conversely, species from campo rupestre showed continuous leafing and flowering patterns, while fruiting was seasonal. Phenophases did not show a phylogenetic signal. Conclusions:We demonstrated changes in vegetative and reproductive phenology that are likely associated with variations in soil physicochemical properties. We argue that more severe edaphic filters may have shaped different phenological patterns in campo rupestre.

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Section: Introductionmentioning

confidence: 99%

Vegetative and reproductive phenology in a tropical grassland–savanna–forest gradient

Oliveira

Messeder

Teixido

et al. 2021

J Vegetation Science

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“…Natural environments can impose filters that select certain trait combinations (Carlucci et al 2014). Phenological traits, for example, are marked by the temporal variation of factors such as rainfall and day length (Cardoso et al 2012;Rossatto et al 2013;Neves et al 2017;Souza and Funch 2017). The leaf budding is mainly controlled by day length in environments where plant water balance remains positive throughout the year (Borchert et al 2005;Calle et al 2010;Souza and Funch 2017).…”

Section: Introductionmentioning

confidence: 99%

“…The leaf budding is mainly controlled by day length in environments where plant water balance remains positive throughout the year (Borchert et al 2005;Calle et al 2010;Souza and Funch 2017). The rainfall volumes and soil properties have also been well documented as defining factors of leaf turnover rhythms in tropical plant species (Reich and Borchert 1984;Reich 1995;Valdez-Hernández et al 2010;Cardoso et al 2012;Rossatto et al 2013;Neves et al 2017). To understand such interactions, it is necessary to analyze traits that indirectly affect growth, reproduction, and plant survival (Violle et al 2007;Vieira et al 2021).…”

Section: Introductionmentioning

confidence: 99%

Leaf trait variability maintains similar leaf exchange rhythms in Hirtella glandulosa Spreng. (Chrysobalanaceae) populations growing on contrasting soil types in the Brazilian Atlantic Forest

et al. 2021

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Abiotic and biotic factors constrain species occurrences, although many species are widely distributed. We investigated the performance of two populations of Hirtella glandulosa Spreng. (Chrysobalanaceae), a tropical tree or shrub that occurs from Venezuela to southeastern Brazil. This study was carried out in two evergreen Atlantic Forests fragments in the Chapada Diamantina Mountains (Brazil) growing on sites with different soil types and different water availabilities: a river margin on litholic soils (river/lithosol) and a plateau with the deep clayey soils (plateau/latosol). We examined leaf phenology, water potential (Ψ W ), wood density, leaf traits, and leaf gas exchange of populations growing at both sites in the rainy and dry seasons. Despite differences in their Ψ W values, both populations maintained similar leaf phenological patterns. Leaf traits, Ψ W , and leaf gas exchange differed spatially and temporally. The maintenance of phenological strategies conditioned by distinct leaf and gas exchange traits compensated for lower water potential levels in the river margin/lithosol site and favored the maintenance of a positive water balance and greater water use efficiency than in the plateau/latosol site. Morphological and physiological trait adjustments could allow the wide distribution of H. glandulosa in contrasting soil types with different water availabilities.

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“…The relationship between phases was evidenced, mainly in species showing more restricted distributions such as C. eugenioides var. desertorum and P. schenckianum -both more frequent in caatinga environments (Oliveira et al, 2012;Landrum, 2017), where seasonal water restrictions are strong drivers of plant ecological strategies (Neves et al, 2017). The field data of E. punicifolia reveals the initial development of young leaves, with flower bud development occurring slightly later (Moraes et al, 2017).…”

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confidence: 99%

Seasonality and the Relationships Between Reproductive and Leaf Phenophases In Myrtaceae Using Field and Herbarium Data

et al. 2021

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The roles of rainfall, soil properties, and species traits in flowering phenology along a savanna-seasonally dry tropical forest gradient

Cited by 17 publications

References 53 publications

Vegetative and reproductive phenology in a tropical grassland–savanna–forest gradient

Vegetative and reproductive phenology in a tropical grassland–savanna–forest gradient

Leaf trait variability maintains similar leaf exchange rhythms in Hirtella glandulosa Spreng. (Chrysobalanaceae) populations growing on contrasting soil types in the Brazilian Atlantic Forest

Seasonality and the Relationships Between Reproductive and Leaf Phenophases In Myrtaceae Using Field and Herbarium Data

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