Abstract

In the savanna-seasonally dry tropical forest ecotone in Northeastern Brazil, we studied variations in flora and structure within old growth and two sites in secondary succession (10 and 25 years). We sampled 2,127 trees and shrubs with a diameter at ground level of 3 cm or more, excluding cacti, palm trees, and vines. Old growth contained 478 plants from 29 species, the 25-year site had 819 plants from 27 species, and the 10-year site had 829 plants from 25 species, totaling 38 species across the sites. Regarding the regenerating stratum, we found 2,776 individuals, with the largest and smallest number of individuals for 10 and 25 years regeneration, respectively. Rarefaction and Jacknife richness showed greater tree richness in old growth, whereas 10 and 25 years regeneration presented similar richness estimates; furthermore, the highest richness in the regenerating stratum was observed in 10 years and the lowest in old growth. Our results reveal that changes in composition are caused by species replacement, demonstrating that even in areas deforested for traditional agriculture, turnover causes significant changes in composition and results in the requirement of a long time for reestablishment, similar to the old growth.

Key words:
arid environments; species richness; succession; turnover; woody plants.

Resumo

Em uma área de ecótono entre a savana e a floresta tropical sazonalmente seca no Nordeste do Brasil, estudamos variações na flora e na estrutura em áreas com estágio de sucessão avançada e em dois locais em sucessão secundária (10 e 25 anos). Amostramos 2.127 árvores e arbustos com um diâmetro ao nível do solo de 3 cm ou mais, excluindo cactos, palmeiras e trepadeiras. A vegetação antiga continha 478 plantas de 29 espécies, o local de 25 anos tinha 819 plantas de 27 espécies, e o local de 10 anos tinha 829 plantas de 25 espécies, totalizando 38 espécies nos locais. Em relação ao estrato regenerante, encontramos 2.776 indivíduos, com maior e menor número de indivíduos para 10 e 25 anos de regeneração, respectivamente. Rarefação e riqueza de Jacknife mostraram maior riqueza de árvores em crescimento antigo, enquanto 10 e 25 anos de sucessão secundária apresentaram estimativas de riqueza semelhantes; além disso, a maior riqueza no estrato regenerante foi observada em 10 anos de sucessão secundária e a menor em crescimento antigo. Nossos resultados revelam que as mudanças na composição são causadas pela substituição de espécies, demonstrando que mesmo em áreas desmatadas para agricultura tradicional, o turnover causa mudanças significativas na composição e resulta na exigência de um longo tempo para restabelecimento, semelhante ao crescimento antigo.

Palavras-chave:
ambientes áridos; riqueza de espécies; sucessão; turnover; plantas lenhosas.

Introduction

In Northeastern Brazil, the Cerrado-Caatinga ecotone covers vast areas, with transition between savannas and seasonally dry tropical forests and woodlands, where the most notable ecotones are the ecotonal belts between the Caatinga and the Cerrado phytogeographic domain (Moro et al. 2016Moro RS & Milan E (2016) Natural forest fragmentation evaluation in the Campos Gerais region, Southern Brazil. Environment and Ecology Research 4: 74-78.). The ecotones can be defined as areas that connect different biological communities, being a transition zone that has species characteristic of each community and, consequently, is intermediate in terms of environmental conditions, representing areas of ecological tension in the territorial extensions where two or more plant domains coexist (Moro & Milan 2016). Ecotones often appear along ecological gradientes, these are created because of spatial shifts in elevation, climate, soil, and many other ecological factors (Erdõs 2011Erdős L (2011) On the terms related to spatial ecological gradients and boundaries. Acta Biologica Szegediensis 55: 279-287.; Kark 2013Kark S (2013) Ecotones and ecological gradients. In: Leemans R (ed.) Ecological systems. Springer, New York. Pp. 147-160. ). Ecotones are more than just a boundary or an edge; the idea of an ecotone indicates the presence of active interaction between two or more ecosystems, with features that are not present in either of the neighboring ecosystems (Rahman et al. 2021Rahman IU, Afzal A, Iqbal Z, Hashem A, Al-Arjani A-BF, Alqarawi AA, Abd_Allah EF, Abdalla M, Calixto ES, Sakhi S, Ali N & Bussmann RW (2021) Species distribution pattern and their contribution in plant community assembly in response to ecological gradients of the ecotonal zone in the Himalayan region. Plants 10: 2372.).

The transition between such vegetation types Savanna (Cerrado) and SDTFW (Caatinga) occupies vast areas in such as in Piauí sState, where 37% of its territorial area is covered by seasonally dry tropical forest and woodland (SDTFW), 33% by savanna, 19% by savanna-SDTFW transition, and the rest of the territory corresponds to other vegetation types with lower expression in the state (Farias & Castro 2004Farias RRS & Castro AAJ (2004) Fitossociologia de trechos da vegetação do Complexo de Campo Maior, PI, Brasil. Acta Botanica Brasilica 18: 949-963.; Macedo et al. 2019Macedo WS, Silva LS, Alves AR & Martins AR (2019) Análise do componente arbóreo em uma área de ecótono Cerrado-Caatinga no sul do Piauí, Brasil. Scientia Plena 15: 010201. DOI: 10.14808/sci.plena.2019.010201
https://doi.org/10.14808/sci.plena.2019.... ). The ecotone concept arose from community ecology to indicate a change in structure and composition of plant communities, but its use was then generalized to broader spatial scales such as landscapes and biomes (Risser 1995Risser PG (1995) The status of the science examining ecotones. Bioscience 45: 318-325.; Ferro & Morrone 2014Ferro I & Morrone JJ (2014) Biogeographic transition zones: a search for conceptual synthesis. Biological Journal of the Linnean Society 113: 1-12.).

The Cerrado domain has been identified as one of the richest and most threatened in the world (Felfili et al. 2004Felfili JM, Silva Júnior MC, Sevilha AC, Fagg CW, Walter BMT, Nogueira PE & Rezende AV (2004) Diversity, floristic and structural patterns of Cerrado vegetation in Central Brazil. Plant Ecology 175: 37-46.), and its main vegetation type, the Cerrado Savanna, is one of the remarkable ecosystems of South America originally covering millions of hectares (Overbeck et al. 2022Overbeck GE, Vélez-Martin E, Silva Menezes L, Anand M, Baeza S, Carlucci MB, Dechoum MS, Durigan G, Fidelis A, Guido A, Moro MF, Munhoz CBR, Reginato M, Rodrigues RS, Rosenfield MF, Sampaio AB, Silva FHB, Silveira FAO, Sosinski Jr EE, Staude IE, Temperton VM, Turchetto C, Veldman JW, Viana PL, Zappi DC & Müller SC (2022) Placing Brazil’sgrasslands and savannas on the map of science and conservation. Perspectives in Plant Ecology, Evolution and Systematics 53: 125687.; Fiaschi & Pirani 2009Fiaschi P & Pirani JR (2009) Review of plant biogeographic studies in Brazil. Journal of Systematics and Evolution 47: 477-496.; Ab’Saber 2003). The Cerrado is considered one of the world’s biodiversity hotspots due to the great biological richness, high proportion of endemic species and high human threat, due deforestation for agriculture (Myers et al. 2000Myers N, Mittermeier RA, Mittermeler CG, Fonseca GAB & Kent J (2000) Biodiversity hotspots for conservation priorities. Nature 403: 853-858.; Maracahipes-Santos et al. 2017Maracahipes-Santos L, Lenza E, Santos JO, Mews HÁ & Oliveira B (2017) Effects of soil and space on the woody species composition and vegetation structure of three Cerrado phytophysiognomies in the Cerrado-Amazon transition. Brazilian Journal of Biology 77: 830-839.). The Brazilian savanna covers approximately 2 million kilometers, representing 23% of the country’s land surface (Ratter et al. 1997Ratter JA, Ribeiro JF & Bridgewater S (1997) The Brazilian Cerrado vegetation and threats to its biodiversity. Annals of Botany 80: 223-230. ; Abreu & Durigan 2011Abreu RCR & Durigan G (2011) Changes in the plant community of a Brazilian grassland savannah after 22 years of invasion by Pinus elliottii Engelm. Plant Ecology & Diversity 4: 269-278.; Overbeck et al. 2022), with two main strata: the woody, which includes larger trees and shrubs, and the subshrub and grass strata (Rizzini 1992Rizzini EL (1992) pp interactions in P-wave and related topics. La Rivista Del Nuovo Cimento 15: 1-29.; Madonsela et al. 2018Madonsela S, Cho MA, Ramoelo A, Mutanga O & Naidoo L (2018) Estimating tree species diversity in the savannah using NDVI and woody canopy cover. International Journal of Applied Earth Observation and Geoinformation 66: 106-115.; Vieira et al. 2019Vieira LTA, Castro AAJF, Coutinho JMCP, Sousa SR, Farias RRS, Castro NMCF & Martins FR (2019) A biogeographic and evolutionary analysis of the flora of the North-eastern Cerrado, Brazil. Plant Ecology & Diversity 12: 475-488.). Across the Cerrado domain, vegetation is very variable, ranging from grassland areas and sites with sparse cover of shrubs and small trees to areas with an almost closed forest physiognomy with a 12-15 m tall canopy (Ratter & Dargie 1992; Ratter et al. 1997; Ribeiro & Walter 2008Ribeiro JF, Walter BMT (2008). As principais fitofisionomias do Cerrado. In: Sano SM, Almeida SP & Ribeiro JF (ed.) Cerrado: ecologia e flora. Embrapa Cerrados, Planaltina. Pp. 153-212.). One hectare of Cerrado can include 80 to 90 woody species, distributed in diverse families, among which Fabaceae and Myrtaceae are among the most richly represented and dominant components (Rossatto 2014Rossatto DR (2014) Spatial patterns of species richness and phylogenetic diversity of woody plants in the neotropical savannas of Brazil. Brazilian Journal of Botany 37: 283-292.). Piauí has a territorial area of 251,617 km², of which 132,721 km² is represented by the Cerrado biome (IBGE 2019).

The phytophysiognomy and flora of the seasonally dry tropical forest and woodland that is regionally called Caatinga, are quite varied, presenting both a shrubby and arboreal pattern and reaching a forest physiognomy in many places, or a shrubland in other places. While the structure of the woody component varies from open and dense shrub to arboreal, the herbaceous component is mostly composed of therophytes, with short-lived annual plants (Moro et al. 2016Moro RS & Milan E (2016) Natural forest fragmentation evaluation in the Campos Gerais region, Southern Brazil. Environment and Ecology Research 4: 74-78.; Queiroz et al. 2015Queiroz RT, Moro MF & Loiola MIB (2015). Evaluating the relative importance of woody versus non-woody plants for alpha-diversity in a semiarid ecosystem in Brazil. Plant Ecology and Evolution 148: 361-376. ). This makes the ecology of Caatinga different from, the savanna vegetation, where the herbaceous layer is perennial. The flora of Caatinga is represented by approximately 3.347 species, of which at least 526 are endemic, with a high proportion of herbaceous species observed, although this component is commonly neglected in studies carried out on this vegetation (Queiroz et al. 2015; Lima et al. 2019Lima JR, Silva RG, Tomé MP, Sousa Neto EP, Queiroz RT, Branco MSD & Moro MF (2019) Fitossociologia dos componentes lenhoso e herbáceo em uma área de Caatinga no Cariri Paraibano, PB, Brasil. Hoehnea 46: e792018. DOI: 10.1590/2236-8906-79/2018
https://doi.org/10.1590/2236-8906-79/201... ; Fernandes et al. 2020Fernandes MF, Cardoso D & Queiroz LP (2020). An updated plant checklist of the Brazilian Caatinga seasonally dry forests and woodlands reveals high species richness and endemism. Journal of Arid Environments 174: 2.). Seasonally dry tropical forests and woodlands have received attention from researchers in recent decades, as they have begun to reveal higher levels of species richness and endemism than previously expected (Moro et al. 2015).

Species richness, uniformity, and various other measures of abundance and rarity are essential components of biological diversity, but the number of species present in a location (alpha diversity) is the easiest biodiversity variable to quantify; therefore, it has been used as a measure of the relative conservation value between different areas (Bock et al. 2007Bock CE, Jones ZF & Bock JH (2007) Relationships between species richness, evenness, and abundance in a Southwestern Savanna. Ecology 88: 1322-1327.; Silva et al. 2013Silva DM, Batalha MA & Cianciaruso MV (2013) Influence of fire history and soil properties on plant species richness and functional diversity in a neotropical savanna. Acta Botanica Brasilica 27: 490-497.). Changes in the vegetation structure of tropical savannas often occur due to fires, human activities, and climate change (Gonçalves et al. 2021Gonçalves RVS, Cardoso JCF, Oliveira PE & Oliveira DC (2021) Changes in the Cerrado vegetation structure: insights from more than three decades of ecological succession. Web Ecology 21: 55-64.). Some of these changes along the scale have been observed, such as changes in tree density and floristic diversity, causing negative impacts on ecosystem functioning and the benefits it provides (Sambuichi 1991Sambuichi RHR (1991) Efeitos de longo prazo do fogo periódico sobre a fitossociologia da camada lenhosa de um Cerrado em Brasília, DF. Dissertação de Mestrado. Universidade de Brasília, Brasília. 129p.; Fiedler et al. 2004Fiedler NC, Azevedo INC, Rezende AV, Medeiros MB & Venturoili F (2004) Efeito de incêndios florestais na estrutura e composição florística de uma área de Cerrado sensu stricto na fazenda Água Limpa-DF. Árvore 28: 129-138.; Madonsela et al. 2018Madonsela S, Cho MA, Ramoelo A, Mutanga O & Naidoo L (2018) Estimating tree species diversity in the savannah using NDVI and woody canopy cover. International Journal of Applied Earth Observation and Geoinformation 66: 106-115.). These processes can lead to primary or secondary succession, depending on whether these changes and disturbances alter the substrate and floristic composition of the site (Neto et al. 2017Neto C, Cardigos C, Oliveira SC & Zêzere JL (2017) Floristic and vegetation successional processes within landslides in a Mediterranean environment. Science of the Total Environment 574: 969-981.).

Understanding the patterns of plant species diversity is of great importance in determining conservation strategies (Henneron et al. 2019Henneron L, Sarthou C, Massary JC & Ponge JF (2019) Habitat diversity associated to island size and environmental filtering control the species richness of rock-savanna plants in neotropical inselbergs. Ecography 42: 1536-1547.). This can be explained by the alpha diversity that describes the species diversity at a local scale, by the gamma diversity or regional diversity, which is the total number of species observed in all habitats, and by beta diversity that is used on a landscape or regional scale to compare the variation in species composition between communities (Nogueira et al. 2008Nogueira IS, Nabout JC, Oliveira JE & Silva KD (2008) Diversity (alpha, beta and gama) of phytoplankton community at four artificial lakes in Goiânia city, GO. Hoehnea 35: 219-233.; Zhang et al. 2015Zhang Y, Ma K, Anand M, Ye W & Fu B (2015) Scale dependence of the beta diversity-scale relationship. Community Ecology 16: 39-47.; Li et al. 2019Li N, Chu H, Qi Y, Li C, Ping X, Sun Y & Jiang Z (2019) Alpha and beta diversity of birds along elevational vegetation zones on the southern slope of Altai Mountains: Implication for conservation. Global Ecology and Conservation 19: e00643.; Soares et al. 2020Soares CJRS, Sampaio MB, Santos-Filho FS, Fernando R, Martins FR & Santos FAM (2020) Patterns of species diversity in different spatial scales and spatial heterogeneity on beta diversity. Acta Botanica Brasilica 34: 9-16.). Understanding the mechanisms that drive alpha and beta diversities is important for regional biodiversity studies (Koleff et al. 2003Koleff P, Gaston KJ & Lennon JJ (2003) Measuring beta diversity for presence-absence data. Journal of Animal Ecology 72: 367-382.). Beta diversity is used to measure the variation in species composition; in the narrowest sense, it is the ratio between gamma and alpha diversity (Whittaker 1960Whittaker RH (1960) Vegetation of the Siskiyou Mountains, Oregon and California. Ecological Monographs 30: 279-338.; Baselga & Orme 2012Baselga AC & Orme DL (2012) Betapart: an R package for the study of beta diversity. Methods in Ecology and Evolution 3: 808-812.).

Beta diversity emerges from two distinct processes, turnover and nestedness (Baselga 2010Baselga A (2010) Partitioning the turnover and nestedness components of beta diversity. Global Ecology and Biogeography 19: 134-143.; Piroozi et al. 2018Piroozi N, Kohandel A, Jafari M, Ali Tavili A & Farizhendi GM (2018) Plant alpha and beta diversity in relation to spatial distribution patterns in different plant community types. Pakistan Journal of Botany 50: 2317-2323.; Magurran et al. 2019Magurran AE, Dornelas M, Moyes F & Henderson PA (2019) Temporal β diversity - a macroecological perspective. Global Ecology and Biogeography 28: 1949-1960.). Turnover refers to the replacement of some species by others, which can be explained by dispersal processes, either simultaneously or historically (Barton et al. 2013Barton PS, Cunningham SA, Adrian D, Manning AD, Gibb H, Lindenmayer DB & Didham RK (2013) The spatial scaling of beta diversity. Global Ecology and Biogeography 22: 639-647.; Piroozi et al. 2018). Thus, a high species turnover rate is expected, where conditions are very different between two neighboring localities (Soares et al. 2020Soares CJRS, Sampaio MB, Santos-Filho FS, Fernando R, Martins FR & Santos FAM (2020) Patterns of species diversity in different spatial scales and spatial heterogeneity on beta diversity. Acta Botanica Brasilica 34: 9-16.). Nestedness, however, is responsible for differences in composition, occurring when no species is replaced from one location to another (Piroozi et al. 2018). Analyzing the floristic and structural composition, as well as working on aspects of diversity in areas with different stages of natural regeneration, will provide information on the dynamics of plant species between areas and how they are distributed in these environments (Silva et al. 2002Silva LO, Costa DA, Santo Filho KE, Ferreira HD & Brandão D (2002) Floristic and phytosociology inventory in two areas of “Cerrado” stricto sensu in the Parque Estadual da Serra de Caldas Novas, Goiás. Acta Botanica Brasilica 16: 43-53.; Vasconcelos et al. 2017Vasconcelos ADM, Henriques IGN, Souza MP, Santos WS & Ramos GG (2017) Caracterização florística e fitossociológica em área de Caatinga para fins de manejo florestal no município de São Francisco-PI. Revista ACSA 13: 329-337.). Furthermore, provide further understanding on how succession is the process of vegetation recovery following disturbance (Clements 1916Clements FE (1916) Plant succession: an analysis of the development of vegetation. Carnegie Institute, Washington. 512p.; Chang & Turner 2019Chang CC & Turner BL (2019) Ecological succession in a changing world. Journal of Ecology 107: 503-509.; Prach & Walker 2011Prach K & Walker LR (2011) Four opportunities for studies of ecological succession. Trends in Ecology and Evolution 26: 119-123.).

The present study aimed to investigate changes in the structure and composition of species in the tree/shrub community and in the regenerating stratum in areas of conserved vegetation and secondary succession in the savanna-SDTFW transition, in the extreme south of the state of Piauí, Northeastern Brazil. We hypothesized that there would be differences in structure (basal area, height), abundance, richness of tree and shrub species, and species composition in regenerating strata between areas of conserved vegetation and secondary succession. Additionally, we expect that changes in species composition among the areas will be determined by turnover. Evaluation of floristic and structural variation upon succession may improve our understanding of succession, and also help practitioners in restoring sites or predicting the future vegetation of disturbed sites (Vítovcová et al. 2021).

Material and Methods

Study area

The study area is located in the chapadas region, in the municipality of Corrente, south of Piauí state, at coordinates 10º31’16,5”S 45º11’24,51”W. The municipality whose area of 3,521 km², is located in Northeastern Brazil, comprises a mosaic of savanna and seasonally dry tropical forest (Fig. 1), subdeciduous broadleaved forest. This is an ecotonal area influenced by the Amazon, Cerrado, and Caatinga phytogeografical domains (Andrade et al. 2019Andrade FN, Lopes JB, Barros RFM, Lopes CGR & Sousa HS (2019) Composição florística e estrutural de uma área de transição entre Cerrado e Caatinga em assentamento rural no município de Milton Brandão-PI, Brasil. Scientia Forestalis 47: 203-215.). The region has a tropical climate (type Aw based on the Köppen system; Alvares et al. 2013Alvares CA, Stape JL, Sentelhas PC, Gonçalves JLM & Sparovek G (2013) Köppen’s climate classification map for Brazil. Meteorologische Zeitschrift 22: 711-728.), characterized by rainy summers and dry winters, with a rainy season from December to May, 1,035 mm of annual rainfall, and 23 ºC to 39 ºC of temperature (Aguiar & Gomes 2004Aguiar RB & Gomes JRC (2004) Projeto cadastro de fontes de abastecimento por água subterrânea estado do Piauí: diagnóstico do município de Picos. Ministério de Minas e Energia, Fortaleza. Pp. 3-4.).

Data collection

This study was conducted at two vegetation fragments (10º31’48.05”S-45º11’44.29”W, 10º21’37.99”S-45º11’15.62”W) respectively, with different stages of secondary succession, as well as at an old growth site with no record of previous deforestation. Thus, in each fragment, we stablished plots in three sites: a site without know deforestation in the last decades, which we termed old growth plot (Fig. 2a-b); a deforested site, in which fire was used for cleaning and subsequent agricultural planting, which has been in regeneration for 10 years, which we termed secondary succession 10 years regeneration (Fig. 2c-d); and a deforested site, in which fire was used for cleaning and subsequent agricultural planting, which has been in regeneration for 25 years, which we termed secondary succession 25 years regeneration (Fig. 2e-f). A total of six plots were established for this study, that is, three plots in each fragment.

Figure 1
Location of the study areas and vegetation coverage in the Piauí state, Brazil.

Plots with dimensions of 50 × 50 m were adopted and subsequently subdivided into subplots of 10 × 10 m, totaling 25 subplots. Two 50 × 50 m plots were implanted in each successional stage, totaling six 50 × 50 m plots and a total sample area of ​​1.5 hectares (0.5 ha per successional stage). We sampled living and dead arboreal and shrub individuals in the three plots with a diameter at ground height (DGH) ≥ 3 cm (Lemos & Rodal 2002Lemos JR & Rodal MJN (2002) Fitossociologia do componente lenhoso de um trecho da vegetação de Caatinga no Parque Nacional Serra da Capivara, Piauí, Brasil. Acta Botanica Brasilica 16: 23-42.). Cacti and palm trees did not occur in the plots, however, climbing plants were excluded from the samples. The following information was obtained for each individual measured: species, DGH of the stem and tillers (when present) and total height of each individual. For each 50 × 50 m plot, 10 subplots were randomly selected for sampling the regenerating stratum, totaling 20 subplots in each regeneration stage. For the survey of the regenerating stratum, woody species were surveyed, and the researchers adopted as a criterion plant with a height of less than 1 m and above 50 cm, and perimeter at ground height (DGH) < 3 cm.

Fertile plant specimens were collected in expeditions carried out between November 2020 and December 2021, and identification was carried out with the help of specialized literature such as Rodal et al. (1998Rodal MJN, Andrade KVSA, Sales MF & Gomes APS (1998) Fitossociologia do componente lenhoso de um refúgio vegetacional no município de Buíque, Pernambuco. Revista Brasileira de Biologia 58: 517-526.), Lemos (2004Lemos JR (2004) Composição florística do Parque Nacional Serra da Capivara, Piauí, Brasil. Rodriguésia 55: 55-66.), Moro et al. (2011Moro MF, Castro ASF & Araújo FS (2011) Composição florística e estrutura de um fragmento de vegetação savânica sobre os tabuleiros prélitorâneos na zona urbana de Fortaleza, Ceará. Rodriguésia 62: 407-423.), Soares Neto et al. (2014Soares Neto RLSN, Cordeiro LS & Loiola IB (2014) Flora do Ceará, Brasil: Combretaceae. Rodriguésia 65: 685-700.), Souza & Lorenzi (2019Souza VC & Lorenzi H (2019) Botânica sistemática: guia ilustrado para identificação das famílias de fanerógamas nativas e exóticas no Brasil, baseado em APG IV. Instituto Plantarum, Nova Odessa. ), specialists and specialized taxonomic databases, such as Flora do Brasil (2020). Family circumscriptions followed the classification proposed by APG IV (2016APG IV (2016) An update of the Angiosperm Phylogeny Group classification for the orders and families of flowering plants. APG III. Botanical Journal of the Linnean Society 161: 105-121.). Appropriate herborization techniques followed (Fidalgo & Bononi (1984Fidalgo O & Bononi VL (1984) Técnicas de coleta, preservação e herborização de material botânico, Manual. Instituto de Botânica, São Paulo. 62p.) and herbarium samples were deposited at the HUEFS (Universidade Estadual de Feira de Santana herbarium). Duplicates, when available, were also deposited at the HUEFS herbarium for posterior donation to other herbaria.

Figure 2
Study areas during dry and rainy season, September and March, Chapadas Region, Piauí - a-b. old growth; c-d. 10 years regeneration; e-f. 25 years regeneration.

Data analysis

ANOVA and Tukey’s test were used to verify differences in the average basal area of the three seres, both for the arboreal and regenerating strata. For these analyses we used the value of p < 0.05 (Callegari-Jacques 2004Callegari-Jacques SM (2004) Bioestatística: princípios e aplicações. Artmed, Porto Alegre. Pp. 153-164.). For the analysis of the ANOVA, we considered each subplot as a sampling unit. To understand the consequence of regeneration for species richness for both the adult and regenerating strata, we used rarefaction. The rarefaction curve is an intuitive way to compare sampling richness with different numbers of individuals (Gotelli & Ellison 2011Gotelli NJ & Ellison AM (2011) Princípios de estatística em ecologia. Artmed, Porto Alegre .). A rarefaction curve was elaborated with 999 permutations to compare the richness of sampled areas (Magurran 2004Magurran AE (2004) Measuring biological diversity. Blackwell Science, Oxford. ). An abundance matrix was used to calculate the Jackknife I estimator with 999 permutations to verify whether the observed richness was close to the estimated values for the surveyed areas (Magurran 2004; Gotelli & Ellison 2011).

By analyzing the abundances of the species, a ranking of the relative abundances was performed for all areas. In the graphical representation, the species abundance ranks are presented along the horizontal axis in ascending order of relative abundance. The abundance rank is commonly used to infer which species abundance model best describes a community (Magurran 2013Magurran AE (2013) Open questions: some unresolved issues in biodiversity. BMC Biology 11: 118.; Gotelli & Ellison 2011Gotelli NJ & Ellison AM (2011) Princípios de estatística em ecologia. Artmed, Porto Alegre .).

Non-metric multidimensional scaling (NMDS) (Felfilli et al. 2011; Gotelli & Ellison 2011Gotelli NJ & Ellison AM (2011) Princípios de estatística em ecologia. Artmed, Porto Alegre .; Legendre & Legendre 2012) was used to order the areas based on the assumption that the species composition of areas with different regeneration times had distinct communities. A matrix of abundance of species was used to calculate a distance matrix using the Bray Curtis index. The representation of ordination in portraying the actual distribution of species was verified by PERMANOVA with 999 permutations (Felfilli et al 2011). To assess which areas presented significant differences in species composition, an a posteriori test was performed using the “pairwise.perm.amanova” function of the “RVAideMemoire” package (Hervé 2018Hervé M (2018) RVAideMemoire: testing and plotting procedures for biostatistics. R package version 0.9-70. Available at <Available at https://CRAN.R-project.org/package=RVAideMemoire >. Access on 1 June 2019.
https://CRAN.R-project.org/package=RVAid... ).

To check whether the difference in species composition during succession is explained by nestedness or turnover, we used beta.multi and parwise functions of the betapart package (Baselga & Orme 2012Baselga AC & Orme DL (2012) Betapart: an R package for the study of beta diversity. Methods in Ecology and Evolution 3: 808-812.) in R. Initially, we used the beta.multi function with the presence-absence matrix to calculate a dissimilarity matrix using the Sørensen index to obtain a measure of total dissimilarity and, later, the values ​​of the turnover and nestedness components. The beta.pair function calculates the same three dissimilarity metrics as the previous function using the Sørensen index. Instead of returning three unique values, as in the beta.multi function, the beta.pair generates three dissimilarity matrices (total dissimilarity, turnover component, and nestedness). The generated dissimilarity matrices can be submitted to the construction of a cluster, which is selected as the component that best explains the diversity between areas (Baselga & Orme 2012).

Results

In total, we sampled 2.127 individual trees with DGH ≥ 3cm distributed across 18 families and 38 species in all six 50 × 50 m plots (150 10 × 10 m subplots). In the old growth site, we sampled 478 individuals, belonging to 17 families and 29 species. For the secondary succession plots with 10 years of regeneration, secondary succession, we sampled 829 individuals, 13 families, and 25 species. In the secondary succession area with 25 years under regeneration, we sampled 819 individuals, 12 families, and 27 species. Eugenia dysenterica (Mart.) DC. was the most abundant species in old growth and 25 years regeneration. In the area with 10 years of regeneration, we obtained greater abundance for Combretum leprosum Mart. (Tab. 1).

We sampled 2.776 individual from the regenerating stratum with DGH ≤ 3 cm in the 60 randomly selected 10 × 10 m subplots. These were, distributed in 38 species across 16 families. In the old growth, we sampled 724 individuals, 24 species and 14 families. For the plots with 10 years under regeneration, we sampled 1.386 individuals, 31 species and 13 families. In the plots with 25 years under regeneration, we sampled 666 individuals, 27 species ad 14 families (Tab. 2).

The Jackknife I richness estimator estimated 40±2 species for all six component plots summed. The highest value was for individual areas was in the old growth plot, while the secondary succession plots presented similar richness estimates. For the regenerated stratum, the total estimated richness was 39±2 for the total dataset of all plots. The highest richness value estimate was obtained from the secondary succession plots with 10 years under regeneration, and the lowest from the old growth plot (Tab. 3).

Regarding the structure of vegetation, old growth plots had the largest basal area (and presumably the highest biomass), followed by 25 years regeneration. The plots in the 10 years regeneration site had the smallest basal area (and presumably less biomass). In the regenerating stratum, the 10 years regeneration showed the largest basal area and number of individuals, reflecting a large number of smaller trees. We found a statistically significant difference in mean basal area per 10 × 10 subplot when compared with old growth and 10 years regeneration (Df=57, F=10.22, p<0,001) (Fig. 3a). For the adult tree stratum we found differences in mean basal area (Fig. 3b), with the lager mean for old growth and the less mean basal area for 10 years regeneration (Df=147, F=9.19, p<0,001).

We verified differences in the mean of abundance in the regenerating stratum (Fig. 4a), with the lager mean for 10 years and old growth and the less mean abundance area for 25 years regeneration (Df=57, F=7.607, p=0,001). In the tree stratum, only old growth showed less mean when compared with old growth and 25 years and 10 years regeneration (Df=147, F=16.04, p<0,001) (Fig. 4b).

In the regenerating stratum, the 10 years regeneration and old growth showed a difference in means richness when compared with 25 years regeneration (Df=57, F=7.521, p=0,001) (Fig. 5a). For the tree stratum we found differences in mean richness (Fig. 5b), with the lager mean for 25 years and 10 years regeneration and the less mean old growth (Df=147, F=3.205, p=0,043).

We verified the relationship between tree richness and the number of individuals sampled using the rarefaction curve for each area of the tree stratum. The old growth fragment showed the highest ascending richness, showing that the richness for a given number of sampled individuals was higher in this area than in the regenerating plots. On the other hand, considering the extrapolation of the curves, all areas presented asymptotic curves (Fig. 6a). In the regenerating stratum, the same relationship between number of species and number of individuals sampled was verified; however, considering the interpolation and extrapolation intervals, we found greater richness for the areas at 10 and 25 years in regeneration (Fig. 6b).

Figure 3
Basal area for the adult tree stratum (a) regenerating stratum (b) for 10 years regeneration, 25 years regeneration and old growth, Chapadas region, Piauí.

Figure 4
Abundance for the adult tree stratum (a) regenerating stratum (b) for 10 years regeneration, 25 years regeneration and old growth, Chapadas region, Piauí.

Figure 5
Richness for the adult tree stratum (a) regenerating stratum (b) for 10 years regeneration, 25 years regeneration and old growth, Chapadas region, Piauí.

Both the tree strata (Fig. 7a) and regenerating strata (Fig. 7b) exhibited few species, representing more than 50% of the relative abundance, with the other species represented by a few individuals. Eugenia dysenterica represented 55.4% of the total relative abundance in the tree stratum during old gowth. For secondary succession (10 years regeneration), Combretum leprosum (33.1%) and Eugenia dysenterica (27.5%), together accounted for 60.6% of the relative abundance. Finally, in the secondary succession (25 years regeneration), Eugenia dysenterica accounted for 54.4% of the total relative abundance (Fig. 7a). Bauhinia acreana represented 55.11% of the total relative abundance in the regenerating stratum for old growth. Secondary succession (10 years), Eugenia dysenterica (38%) and Bauhinia acreana (25%), together accounted for 63% of the total relative abundance. During secondary succession (25 years), Astronium urundeuva accounted for 40.2% of the total relative abundance (Fig. 7b).

The NMDS showed differences in species composition between the three areas, both in the tree (Fig. 8a) and regenerating strata (Fig. 8b). For the tree stratum, stress was 0.263 a moderate quality ordination, but Permanova showed that the difference in species composition was significant, although NMDS does not present a clear separation of areas. For the regenerated stratum, the ordination stress was 0.222 a moderate quality ordination. Permanova showed that the order of sampling units for the regenerant was also significant (p=0.001).

The NMDS showed differences in species composition between the two strata for the three areas. The stresses for the old growth, 10 and 25 years regeneration (secondary sucession) were 0.176 (Fig. 9a), 0.200 (Fig. 9b), and 0.184 (Fig. 9c), respectively. Permanova showed that the difference in the species composition between the two strata was significant (p=0.001).

The beta diversity analysis for the tree stratum between successional stages showed that turnover was 0.95 and nestedness was 0.10. Beta diversity analysis for the regenerating stratum showed that the change in species composition was also influenced more by the turnover (0.88) than by nestedness (0.05). For the tree stratum, the species present exclusively in old growth were: Cochlospermum regium (Mart. ex Schrank) Pilg., Tocoyena formosa (Cham. & Schltdl.) K.Schum., Erythroxylum sp, Hymenaea stigonocarpa Mart. ex Hayne. In 10 years regeneration Callisthene fasciculata Mart., Guazuma ulmifolia Lam., Tabebuia aurea (Silva Manso) Benth. & Hook.f. ex S.Moore, Libidibia ferrea (Mart. ex Tul.) L.P. Queiroz and Mimosa sp. Finally, in 25 years regeneration: Brosimum gaudichaudii Trécul, Tachigali rubiginosa (Mart. ex Tul.) Oliveira-Filho, Annona leptopetala (R.E.Fr.) H.Rainer And Andira cujabensis Benth. (Fig. 10a).

Figure 6
Rarefaction curve for the tree (a) and regenerating stratum (b) for old growth, 10 years regeneration and 25 years regeneration, Chapadas region, Piauí.

Figure 7
Rank of relative abundances of species for the tree (a) and regenerating stratum (b) for old growth, 10 years regeneration and 25 years regeneration, Chapadas region, Piauí.

Figure 8
Ordination for the tree (a) and regenerating stratum (b) for old growth, 10 years regeneration and 25 years regeneration, Chapadas region, Piauí.

Figure 9
Ordination of species from the tree and regenerating stratum for three areas, Chapadas region, Piauí - a. old growth; b. 10 years regeneration c. 25 years regeneration.

For the regenerating stratum, the species present exclusively in old growth were: Xylopia aromatica (Lam.) Mart, Stryphnodendron adstringens (Mart.) Coville. To 10 years regeneration were Cochlospermum regium (Mart. ex Schrank) Pilg., Tachigali aurea Tul., Annona crassiflora Mart. And Annona acutiflora Mart. In the area with 25 years of regeneration, only the species Tabebuia aurea (Silva Manso) Benth. & Hook.f. ex S. Moore was exclusively present. (Fig. 10b).

Discussion

Our results support the initial hypotheses of this study. We found differences in the structure, abundance, and richness of trees and shrubs, and regenerating strata between the three areas. These changes in species composition among areas were determined mainly by turnover. We found greater species richness of the tree stratum in old growth, many species represented by a few individuals, and differences in species composition between the three areas. For the regenerating stratum, we verified similarities in species richness and the contribution of species richness represented by low-abundance species. With this, we show that even in deforested areas for traditional agriculture, as in the secondary succession plots (10 and 25 years regeneration), there were significant changes in species composition when compared with non disturbed sites, which can take a relatively long time for the reestablishment of communities, similar to the old growth.

Figure 10
Venn diagram for the tree (a) and regenerating stratum (b) for old growth, 10 years regeneration and 25 years regeneration, Chapadas region, Piauí.

According to Gotelli & Colwell (2001Gotelli NJ & Colwell RK (2001) Quantifying biodiversity: procedures and pitfalls in the measurement and comparison of species richness. Ecology Letters 4: 379-391.), as ecological disturbances reduce the abundance of species, it was expected, in some cases, that the disturbance would decrease the density of species, as there would be fewer individuals present to be sampled after a disturbance. However, the ranking of species abundance showed that the increase in community richness in the studied areas was influenced by the equability of species abundance (Magurran 2004Magurran AE (2004) Measuring biological diversity. Blackwell Science, Oxford. ). The prevalence of rare species in the presence of a few high-abundance species shows the importance of rare species in increasing local richness (alpha diversity) (Magurran 2004; Gotelli & Colwell 2011). We highlight the importance of rare species for increasing richness in areas that are undergoing natural regeneration processes and the dominant species for the contribution of population density, which in the Cerrado rarely exceeds 100 woody species per hectare (Felfili et al. 2004Felfili JM, Silva Júnior MC, Sevilha AC, Fagg CW, Walter BMT, Nogueira PE & Rezende AV (2004) Diversity, floristic and structural patterns of Cerrado vegetation in Central Brazil. Plant Ecology 175: 37-46.; Spera et al. 2005Spera ST, Reatto A, Martins ES & Correia JR (2005) Atributos físicos de solos e distribuição das fitofisionomias de Cerrado na bacia hidrográfica do Rio Jardim, DF. Embrapa, Planaltina. Pp. 7-15.). Recent studies suggest that species of late succession of old growth can be replaced by pioneer species (with rapid growth), where pioneer species may become dominant in areas that have undergone anthropogenic disturbances (Villa et al. 2019Villa PM, Martins SV, Rodrigues AC, Safar NVH, Bonilla MAC & Ali A (2019) Testing species abundance distribution models in tropical forest successions: implications for fine-scale passive restoration. Ecological Engineering 135: 687-694.; Villa et al. 2020).

The most representative families in terms of the number of individuals were Fabaceae, Combretaceae, and Myrtaceae, which were also found in floristic and phytosociological studies in ecological transition areas (Farias & Castro 2004Farias RRS & Castro AAJ (2004) Fitossociologia de trechos da vegetação do Complexo de Campo Maior, PI, Brasil. Acta Botanica Brasilica 18: 949-963.; Silva et al. 2015Silva KA, Santos JMFF, Santos DM, Andrade JR, Ferraz EMN & Araújo EL (2015) Interactions between the herbaceous and shrubby-arboreal components in a semiarid region in the Northeast of Brazil: competition or facilitation? Revista Caatinga 28: 157-165.; Macedo et al. 2019Macedo WS, Silva LS, Alves AR & Martins AR (2019) Análise do componente arbóreo em uma área de ecótono Cerrado-Caatinga no sul do Piauí, Brasil. Scientia Plena 15: 010201. DOI: 10.14808/sci.plena.2019.010201
https://doi.org/10.14808/sci.plena.2019.... ). Studies performed in the Caatinga by Moro et al. (2014Moro MF, Nic Lughadha E, Filer DL, Araújo FS & Martins FR (2014) A catalogue of the vascular plants of the Caatinga hytogeographical domain: a synthesis of floristic and phytosociological surveys. Phytotaxa 160: 1. ) found similar results, where the Fabaceae family was the most representative. Legumes are often featured prominently in Caatinga inventories (Machado et al. 2012Machado WJ, Prata APN & Mello AA (2012). Floristic composition in areas of Caatinga and Brejo de Altitude in Sergipe state, Brazil. Check List 8: 1089-1101.; Costa et al. 2015Costa GMC, Cardoso D, Queiroz LP & Conceição AA (2015). Local changes in floristic richness in two ecorregions of the Caatinga. Rodriguésia 66: 685-709. ). We found few species with high abundance of individuals and with high dominance, shown in the abundance rank and floristic list, considering that the Cerrado has a low number of species, where few abundant or rare species participate in the occupation of space (Andrade et al. 2002Andrade LAZ, Felfili MJ & Violatti L (2002) Fitossociologia de uma área de Cerrado denso na RECOR-IBGE, Brasília-DF. Acta Botanica Brasilica 16: 225-240.; Assunção & Felfili 2004Felfili JM, Silva Júnior MC, Sevilha AC, Fagg CW, Walter BMT, Nogueira PE & Rezende AV (2004) Diversity, floristic and structural patterns of Cerrado vegetation in Central Brazil. Plant Ecology 175: 37-46.). This result also agrees with what was found in research carried out in the Caatinga, where the Fabaceae family presented a higher value of importance as a result of the large number of individuals, when compared to less abundant species (Rodal et al. 2008Rodal MJN , Martins FR & Sampaio EVSB (2008). Levantamento quantitativo das plantas lenhosas em trechos de vegetação de Caatinga em Pernambuco. Revista Caatinga 21: 192-205. ; Guedes 2012Guedes RDAS, Santana GM, Zanella FCV, Costa Júnior JEV, Santana GM & Silva JA (2012) Caracterização florístico-fitossociológica do componente lenhoso de um trecho de Caatinga no semiárido paraibano. Revista Caatinga 25: 99-108. ). Abundance patterns are quite variable for species and families in general; that is, the abundance of individuals is not always proportional to the number of species, as few species can be represented by large populations, or a single species can be very abundant in the community (Araújo et al. 2009). The species abundance values for the studied areas may indicate progress in the regeneration process.

Similarity analysis and beta diversity were influenced by turnover, reinforcing the idea that this change in species composition between areas is caused by species replacement, which can be explained by different stages of regeneration. The difference in species found can be justified by the succession time and changes in the structure of these communities due to agricultural activities, which can change soil and niche conditions and limit the occupation of late species in these communities leading to changes in species composition (Moutinho 2011Moutinho MF (2011) Facilitação ou competição? Relação interespecífica entre duas espécies de plantas de dunas. In: Prática de pesquisa em ecologia da Mata Atlântica. Universidade de São Paulo, São Paulo. Pp. 1-4.; Chang & Turner 2019Chang CC & Turner BL (2019) Ecological succession in a changing world. Journal of Ecology 107: 503-509.). Beta diversity was more affected by turnover than by nestedness in ecosystems with high diversity and environmental heterogeneity, suggesting that the history of disturbance or colonization is most responsible for community structuring (Soares et al. 2020Soares CJRS, Sampaio MB, Santos-Filho FS, Fernando R, Martins FR & Santos FAM (2020) Patterns of species diversity in different spatial scales and spatial heterogeneity on beta diversity. Acta Botanica Brasilica 34: 9-16.).

For the three studied areas, we observed differences in species composition between the tree and regenerating strata, which indicates the entry of propagules in the areas, contributing to an increase in diversity, thus being important in the structuring of communities, as the regenerating strata will initiate ecological succession until tree species settle in the area. This process of replacing species over time commonly occurs in areas that are undergoing ecological succession, causing changes in species composition and reflecting the functionality of the community (Silva et al. 2012Silva RMG, Santos VHM, Borges FM, Melo FFQ & Silva LP (2012) Potencial alelopático e levantamento do banco natural de sementes sob a copa de Copaifera langsdorffii Desf. Bioscience Journal 28: 641-653.). Thus, ecological succession can be used to describe vegetation change processes at various scales such as temporal or spatial post-disruption events (Silva et al. 2012; Chang & Turner 2019Chang CC & Turner BL (2019) Ecological succession in a changing world. Journal of Ecology 107: 503-509.). Thus, during this process, changes occur in a community over time, and because of disturbances, species can be removed (Moutinho 2011Moutinho MF (2011) Facilitação ou competição? Relação interespecífica entre duas espécies de plantas de dunas. In: Prática de pesquisa em ecologia da Mata Atlântica. Universidade de São Paulo, São Paulo. Pp. 1-4.; Chun & Lee 2019Chun J & Le C (2019) Temporal changes in species, phylogenetic, and functional diversity of temperate tree communities: insights from assembly patterns. Frontiers of Plant Science 19: 294.). Despite the presence of old growth species in secondary communities, it is assumed that the total recovery of the composition of the old communities takes centuries, and that although these secondary communities have a high conservation value in human-modified context, but, in the short term, they do not replace old growth communities that are home to many old growth species (Rozendaal et al. 2019Rozendaal DMA, Bongers F, Aide TM, Alvarez-Dávila E, Ascarrunz N, Balvanera P, Becknell JM, Bentos TV, Brancalion PHS, Cabral GAL, Calvo-Rodriguez S, Chave J, César RG, Chazdon RL, Condit R, Dallinga JS, Almeida-Cortez JS, Jong B, De Oliveira A, Denslow JS, Dent DH, Walt SJ, Dupuy JM, Durán SM, Dutrieux LP, Espírito-Santo MM, Fandino MC, Fernandes GW, Finegan B, García H, Gonzalez N, Moser VG, Hall JS, Hernández-Stefanoni JL, Hubbell S, Jakovac CC, Hernández AJ, Junqueira AB, Kennard D, Larpin D, Letcher SG, Licona J-C, Lebrija-Trejos E, Marín-Spiotta E, Martínez-Ramos M, Massoca PES, Meave JA, Mesquita RCG, Mora F, Müller SC, Muñoz R, Oliveira Neto SN, Norden N, Nunes YRF, Ochoa-Gaona S, Ortiz-Malavassi E, Ostertag R, Peña-Claros M, Pérez-García EA, Piotto D, Powers JS, Aguilar-Cano J, Rodriguez-Buritica S, Rodríguez-Velázquez J, Romero-Romero MA, Ruíz J, Sanchez-Azofeifa A, Almeida AS, Silver WL, Schwartz NB, Thomas WW, Toledo M, Uriarte M, Sá Sampaio EV, Van Breugel M, Van Der Wal H, Martins SV, Veloso MDM, Vester HFM, Vicentini A, Vieira ICG, Villa P, Williamson GB, Zanini KJ, Zimmerman J & Poorter L (2019) Biodiversity recovery of Neotropical secondary forests. Science Advances 5: eaau3114.).

We note that the old-growth and secondary communities present differences in the richness estimates, which may be a response to disturbance and successional time. The richness in these areas was influenced by the equity of abundances of species with fewer individuals, both for trees and shrubs, and for the regenerating stratum. We emphasize that the predominant species contribute to the density and the rare ones to the increase in richness. Differences in species composition may reflect both the successional stage and the effect of the disturbance that areas were subjected to, which was corroborated by the partitioning of beta diversity, showing that turnover was more prevalent for diversity.

Acknowledgments

The authors would like to thank the CAPES (BOL 88887.603430/2021-00) and the graduate program in Botany (UEFS) of the Master’s study grant awarded to the first author and for financial support

Open Access

In accordance with Open Science communication practices, the authors inform that all raw data generated by this study can be accessed in our supplementary data at http://doi.org/10.6084/m9.figshare.21830283

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