Genetic and demographic aspects of <i>Varronia curassavica</i> Jacq. in a heterogeneous coastal ecosystem

HOELTGEBAUM, MARCIA P.; LAUTERJUNG, MIGUEL B.; MONTAGNA, TIAGO; CANDIDO-RIBEIRO, RAFAEL; VIEIRA, WILLIAN; BERNARDI, ALISON P.; CRISTOFOLINI, CAROLINE; REIS, MAURÍCIO S. DOS

doi:10.1590/0001-3765202020180532

Abstract

The restinga is a threatened Brazilian ecosystem and a highly heterogeneous environment. This work aimed to evaluate demographic and genetic aspects of Varronia curassavica and whether environmental heterogeneity can influence the studied population parameters. Three annual evaluations were carried out in an area of restinga in Florianópolis-SC, Brazil. Demographic data were analyzed using descriptive statistics, and the spatial distribution pattern was calculated by Ripley’s K-function and correlated with environmental characteristics. To characterize diversity and genetic structure, eight microsatellite markers were used. This work demonstrated that variations in the distribution of individuals and genotypes can be related to specific environments. Dry lowlands were environments favorable to population development, and flooded lowland and mobile dunes were unfavorable. The fixation indices were distinct between environments, evidencing a tendency toward preferential crosses in favor of heterozygotes. We found absence of spatial genetic structure, indicating that genotypes are randomly distributed and that gene flow may be related to such genetic factors as the presence of autoincompatibility mechanisms. This diversity of environments contributed to the aggregate distribution and is relevant for the maintenance of demographic and genetic processes of the species in restingas, and this aspect should be considered for in situ conservation.

Key words
in situ conservation; population dynamics; restinga; spatial distribution; spatial genetic structure

INTRODUCTION

Varronia curassavica Jacq. (Boraginaceae) is an important medicinal species widely used in folk medicine and also by the pharmaceutical industry owing to its anti-inflammatory, analgesic, and healing properties (Lorenzi & Matos 2008LORENZI H & MATOS FJA. 2008. Plantas medicinais no Brasil. Nova Odessa: Instituto Plantarum., Melo et al. 2008MELO S, LACERDA VD & HANAZAKI N. 2008. Espécies de restinga conhecidas pela comunidade do Pântano do sul, Florianópolis, Santa Catarina, Brasil. Rodriguésia 59: 799-812., Bolzani et al. 2012BOLZANI VS, VALLI M, PIVATTO M & VIEGAS JÚNIOR C. 2012. Natural products from Brazilian biodiversity as a source of new models for medicinal chemistry. Pure Appl Chem 84: 1837-1937.). It is a perennial subshrubby tetraploid species, insect-pollinated and dispersed mainly by birds (Opler et al. 1975OPLER PA, BACKER HG & FRANKIE GW. 1975. Reproductive Biology of Some Costa Rican Cordia Species (Boraginaceae). Biotropica 7: 234-247., Hoeltgebaum et al. 2018HOELTGEBAUM MP, MONTAGNA T, LANDO AP, PUTTKAMMER C, ORTH AI, GUERRA MP & REIS MS. 2018. Reproductive Biology of Varronia curassavica Jacq. (Boraginaceae). An Acad Bras Cienc 90: 59-71.), that exhibits self-incompatibility mechanisms, such as heterostyly and protogyny (Hoeltgebaum & Reis 2017HOELTGEBAUM MP & REIS MS. 2017. Genetic diversity and population structure of Varronia curassavica: a medicinal polyploid species in a threatened ecosystem. J Hered 108: 415-423., Hoeltgebaum et al. 2018HOELTGEBAUM MP, MONTAGNA T, LANDO AP, PUTTKAMMER C, ORTH AI, GUERRA MP & REIS MS. 2018. Reproductive Biology of Varronia curassavica Jacq. (Boraginaceae). An Acad Bras Cienc 90: 59-71.). It is found along most of the Brazilian coastline, as characteristic vegetation of coastal tropical and subtropical moist broadleaf forest, locally known as restinga (Smith 1970SMITH LB. 1970. Boragináceas. Flora Ilustrada de Santa Catarina, Itajaí., Judd et al. 2009JUDD WS, CAMPBELL CS, KELLOGG EA, STEVENS PF & DONOGHUE MJ. 2009. Sistemática Vegetal: Um Enfoque Filogenético. 3a ed., Porto Alegre: Artmed.).

As suggested, restingas comprise the entire vegetation complex established in sandy soils of marine origin (Castro et al. 2007CASTRO D, SOUZA M & MENEZES LFT. 2007. Estrutura da formação arbustiva aberta não inundável na restinga da Marambaia, RJ. R Bras Bioci 5: 75-77., Brasil 2016BRASIL. 2016. Ministério do Meio Ambiente, Conselho Nacional de Meio Ambiente, CONAMA. Resolução CONAMA No 261, de 30 de junho de 1999. In: Resoluções 1999. Disponível em http://www.mma.gov.br. Acessado em 12 abril 2016.
http://www.mma.gov.br... ), and they are extremely sensitive and susceptible to environmental disturbances (Falkenberg 1999FALKENBERG D. 1999. Aspectos da flora e da vegetação secundária da restinga de Santa Catarina, sul do Brasil. Ínsula 28: 1-30.). Based on their coastal location, restingas have experienced a continuous degradation of natural characteristics (Barcelos et al. 2012BARCELOS MEF, RIGUETE JR, SILVA LTP & FERREIRA JR PF. 2012. A visão panorâmica sobre os solos das restingas e seu papel na definição de comunidades vegetais nas planícies costeiras do sudeste do Brasil. Natureza online 10: 71-76.), with a strong reduction in original area (SOS Mata Atlântica 1998SOS MATA ATLÂNTICA. 1998. Atlas da evolução dos remanescentes florestais e ecossistemas associados no domínio da Mata Atlântica no período 1990-1995. São Paulo: Fundação SOS Mata Atlântica, Instituto Socioambiental e Instituto Nacional de Pesquisas Espaciais., 2012-2013SOS MATA ATLÂNTICA. 2012-2013. Atlas dos remanescentes florestais da Mata Atlântica período 2012-2013. São Paulo: Fundação SOS Mata Atlântica, Instituto Socioambiental e Instituto Nacional de Pesquisas Espaciais., Rocha et al. 2003ROCHA CFD, BERGALLO HG, ALVES MAS & SLUYS MV. 2003. A biodiversidade nos grandes remanescentes florestais do Estado do Rio de Janeiro e nasrestingas da Mata Atlântica. São Carlos: Rima Editora, 160 p., Marques et al. 2015MARQUES CM, MENEZES S & LIEBSCH D. 2015. Coastal plain forests in southern and southeastern Brazil: ecological drivers, floristic patterns and conservation status. Brazilian. J Bot 38: 1-18.). The restinga is considered one of the most anthropically threatened ecosystems in the Atlantic Forest (Strohaecker 2008STROHAECKER TM. 2008. Dinâmica populacional. In: Macrodiagnóstico da Zona Costeira e Marinha do Brasil. Brasília: IBAMA/MMA., Barcelos et al. 2012BARCELOS MEF, RIGUETE JR, SILVA LTP & FERREIRA JR PF. 2012. A visão panorâmica sobre os solos das restingas e seu papel na definição de comunidades vegetais nas planícies costeiras do sudeste do Brasil. Natureza online 10: 71-76.).

Extractivist collection practices are still considered the main way of obtaining medicinal plants from nature (Reis & Siminski 2011REIS MS & SIMINSKI A. 2011. Espécies Medicinais Nativas da Região Sul do Brasil. In: Coradin L, Siminski A and Reis A (Eds). Espécies Nativas da Flora Brasileira de Valor Econômico Atual ou Potencial Plantas para o Futuro – Região Sul. MMA, Brasília, 934 p.). In general, when coupled with habitat fragility, the results can lead to an extensive reduction of their natural populations, and/or loss of genetic variability, compromising the maintenance capacity of these species. Consequently, understanding the ability of V. curassavica to maintain population dynamics in this context and understanding how individuals of this species are genetically structured would be fundamental to subsidizing and improving conservation and use initiatives (Epperson 1992EPPERSON BK. 1992. Spatial structure of genetic variation within populations of forest trees. New Forests 6: 257-278.), as well as adding to knowledge about flora of the restingas.

Demographic studies are an important tool for evaluating population processes and mechanisms (Griffith et al. 2016GRIFFITH AB, SALGUERO-GÓMEZ R, MEROW C & MCMAHON S. 2016. Demography beyond the population. J Ecol 104: 271-280.), especially when focused on the conservation of plant species and their populations, since they allow quantification of the regenerative potential through processes of birth, mortality and reproduction (Pavlik & Barbour 1988PAVLIK BM & BARBOUR MG. 1988. Demographic Monitoring of Endemic Sand Dune Plants, Eureka Valley, California. Biol Conserv 46: 217-242., Méndez et al. 2004MÉNDEZ M, DURHN R & OLMSTED I. 2004. Population dynamics of Pterocereus gaumeri, a rare and endemic columnar cactus of Mexico. Biotropica 36: 492-504.).

The literature has consistently demonstrated the importance of integrating genetic and demographic studies in our efforts to understand different mechanisms that define the population structure of plants, along with their interactions (e.g., Connell et al. 1984CONNELL JH, TRACEY JG & WEBB LJ. 1984. Compensatory recruitment, growth, and mortality as factors maintaining rain forest tree diversity. Ecol Monogr 54: 141-164., Martins 1987MARTINS PS. 1987. Estrutura populacional, fluxo gênico e conservação in situ. IPEF 35: 71-78., Diaz & Oyama 2007DIAZ IA & OYAMA K. 2007. Conservation genetics of an endemic and endangered epiphytic Laelias peciosa (Orchidaceae). Am J Bot 94: 184-193., Gonçalves et al. 2010GONÇALVES AC, REIS CAF, VIEIRA FA & CARVALHO D. 2010. Estrutura genética espacial em populações naturais de Dimorphandra mollis (Fabaceae) na região norte de Minas Gerais, Brasil. Rev Bras Bot 33: 325-332., Lara-Romero et al. 2016LARA-ROMERO C, GARCÍA-FERNÁNDEZ A, ROBLEDO-ARNUNCIO JJ, ROUMET M, MORENTE-LÓPEZ J, LÓPEZ-GIL A & IRIONDO JM. 2016. Individual spatial aggregation correlates with between population variation in fine-scale genetic structure of Sileneciliata (Caryophyllaceae). Heredity 116: 417-423.). This knowledge is important for improving both management and conservation strategies of plant genetic resources (Frankham et al. 2014FRANKHAM R, BRADSHAW CJA & BROOK BW. 2014. Genetics in conservation management: Revised recommendations for the 50/500 rules, Red List criteria and population viability analyses. Biol Conserv 170: 56-63.), evaluating the impact of habitat exploration and fragmentation (Young & Merriam 1994YOUNG AG & MERRIAM HG. 1994. Effects of forest fragmentation on the spatial genetic structure of Acer saccharum Marsh. (sugar maple) populations. Heredity 72: 201-208., Mona et al. 2014MONA S, RAY N, ARENAS M & EXCOFFIER L. 2014. Genetic consequences of habitat fragmentationduring a range expansion. Heredity 112: 291-299.), and supporting activities leading to the restoration of plant populations (Kettenring et al. 2014KETTENRING KM, MERCER KL, ADAMS CR & HINES J. 2014. Application of genetic diversity–ecosystem function research to ecological restoration. J Appl Ecol 51: 339-348.).

To date, no studies have integrated population genetic and demographic parameters for V. curassavica. Indeed, few studies have reported on restinga shrub species. In general, the population dynamics of shrub species is not as well known when compared to herbaceous and arboreal groups. Moreover, different methods are required to perform these studies (Crawley & May 1987CRAWLEY MJ & MAY RM. 1987. Population dynamics and plant community structure: competition between annuals and perennials. J Theor Biol 125: 475-489., Kyncl et al. 2006KYNCL T, SUDA J, WILD J, WILDOVA R & HERBEN T. 2006. Population dynamics and clonal growth of Spartocytisus su-pranubius (Fabaceae), a dominant shrub in the alpine zone of Tenerife, Canary Islands. Plant Ecol 186: 97-108.).

Restingas are very heterogeneous areas with several soil gradients that contribute to a mosaic-like phytophysiognomy with spotty vegetation in the landscape and, hence, uneven vegetation coverage (Waechter 1985WAECHTER L. 1985. Aspectos ecológicos da vegetação de restinga no Rio Grande do Sul, Brasil. Comunicações do Museu de Ciências da PUCRS, Série Botânica 33: 49-68., Castro et al. 2007CASTRO D, SOUZA M & MENEZES LFT. 2007. Estrutura da formação arbustiva aberta não inundável na restinga da Marambaia, RJ. R Bras Bioci 5: 75-77.), resulting in the formation of different local habitats.

Environmental heterogeneity is a relevant factor to be considered in demographic and genetic studies of plants (e.g. Janzen 1970JANZEN DH. 1970. Herbivores and the number of tree species in tropical forest. Am Nat 104: 501-508., Loveless & Hamrick 1984LOVELESS MD & HAMRICK JL. 1984. Ecological determinants of genetic structure in plant populations. Annu Rev Ecol Syst 15: 65-95., Ferreira et al. 2010FERREIRA LC, THOMAZI RD, OLIVEIRA DAC & SILVA AG. 2010. Estrutura populacional e padrão espacial de Protium icicariba (DC.) Marchand na Área de Proteção Ambiental de Setiba, Espírito Santo, sudeste do Brasil. Natureza online 8: 39-45.), since it may influence the distribution of genetic variation in populations (Gram & Sork 2001GRAM WK & SORK VL. 2001. Association between environmental and genetic heterogeneity in forest tree populations. Ecology 82: 2012-2021.) and the spatial distribution of plants (Bernasol & Lima-Ribeiro 2010BERNASOL WP & LIMA-RIBEIRO MS. 2010. Estrutura espacial e diamétrica de espécies arbóreas e seus condicionantes em um fragmento de cerrado sentido restrito no sudoeste goiano. Hoehnea 37: 181-198.).

In this context, this work aimed to evaluate aspects of population dynamics, spatial distribution of individuals and genotypes, genetic diversity and structure of V. curassavica. Due to the singularity of the restingas, we also sought to evaluate if the environmental heterogeneity, typical of this ecosystem, may have influenced the studied population parameters. That is, is it possible to detect environments that are limiting or favor population occurrence and development? Which characteristics of these distinct environments can be related to the presence or absence of individuals of the species? Are there differences in the distribution of allelic richness or genetic structure among individuals from different environments? We expect that our results would positively inform efforts to provide subsidies for the in situ conservation of this species.

MATERIALS AND METHODS

Study area

This study was carried out in the Parque Municipal Dunas da Lagoa da Conceição (PMDLC) (27°37’46.19”S; 48°27’1.59”W), a restinga area that covers almost 563 hectares. It is located at Joaquina Beach on the east side of Florianópolis City, Santa Catarina, Brazil. This region is classified as “Cfa mesothermal humid” (Koeppen 1948KOEPPEN W. 1948. Climatologia: con um estúdio de los climas de laTierra. México: Fondo de Cultura Economica.). The predominant vegetation is herbaceous shrubs associated with dunes and some sections formed by small trees or a few trees in the driest areas. Even though this area is presumably protected by law, it still is under anthropogenic pressure from tourism and real estate development.

Demographic and environmental characterization

To evaluate the aspects of population dynamics, annual surveys were carried out during three consecutive years, using a permanent plot of two hectares (100 m x 200 m) subdivided into 200 subplots of 10 m x 10 m. All individuals present within the plot were measured and located through a Cartesian coordinate system (x and y). This species exhibits a densely branched pattern and partial burial of the branches. Thus, for this study, we considered an individual to be a single axis of branches visible above the soil line. The height of all individuals was measured and also diameter at soil level of 30 individuals, representative from each height class were evaluated. The presence of reproductive structure was recorded in order to identify developmental stage.

To test if the distribution of the species was correlated with environmental characteristics, we evaluated the degree of vegetation coverage, the altimetric profile and the type of environment for each subplot (10 x 10 m). The classification of the environment followed Guimarães (2006)GUIMARÃES TB. 2006. Florística e Fenologia Reprodutiva de Plantas Vasculares na Restinga do Parque Municipal das Dunas da Lagoa da Conceição. Dissertation, Universidade Federal de Santa Catarina, Florianópolis/SC. (Unpublished). who proposed these classes: itinerant dune, semi-settled and settled dune; dry, humid and flooded lowland, and transition areas between them. The degree of vegetation coverage was visually estimated by means of an interval scale of scores (0 - 4), with amplitude of 25% between each interval (Fournier 1974FOURNIER LA. 1974. Un método cuantitativo para la medición de características fenológicas en árboles. Turrialba 24: 422-423.). Each subplot was divided into four quadrants with the help of a wooden cross positioned at the central point of the subplots. One score was assigned to each quadrant, and the subplot value was the average of quadrant. Altimetric profile was evaluated with the aid of laser tape with readings every 5 meters in the plot. The height of each point was estimated from the horizontal distance between the points, and the slope was calculated with the neighborhood method.

Characterization of diversity and genetic structure

For genetic characterization of the population in the different environments of the restinga, leaf samples were collected from the individuals sampled in the demographic survey. For extraction of genomic DNA from the leaves, the Nucleospin Plant II kit was used (Macherey-Nagel GmbH & Co. KG), according to the manufacturer’s instructions. Eight polymorphic microsatellite loci developed for the species by Figueira et al. (2010)FIGUEIRA GM, RISTERUCCI AM, ZUCCHI MI, CAVALLARI MM & NOYER JL. 2010. Development and characterization of microsatellite markers for Cordia verbenacea (Boraginaceae), an important medicinal species from the Brazilian coast. Conserv Genet 11: 1127-1129. were amplified by polymerase chain reaction (PCR) to genotype individuals. PCR reaction, DNA was diluted in water at 1:9 µL, and the KAPA PCR kit (KAPA Biosystems) was used with a volume of 10 μL per reaction. Each primer for each locus was labeled with the fluorochromes FAM, PET, NED and VIC for the eight microsatellite loci in two multiplex systems (MCvCIRCPQ14, MCvCIRCPQ3, MCvCIRCPQ8, MCvCIRCPQ6 - multiplex 1 - MCvCIRCPQ11, MCvCIRCPQ7, MCvCIRCPQ16, MCvCIRCPQ15 - multiplex 2), according to Hoeltgebaum & Reis (2017)HOELTGEBAUM MP & REIS MS. 2017. Genetic diversity and population structure of Varronia curassavica: a medicinal polyploid species in a threatened ecosystem. J Hered 108: 415-423.. The set of cycles and temperatures used were 95 °C for 3 min of denaturation and 30 cycles of three phases: 95 °C for 30 s, 61 ^oC for 30 s, and 72 °C for 30 s, with a final elongation step at 72 °C for 30 min. Capillary electrophoresis was performed using 1 μL of diluted PCR product in water (2:15µL), 0.25 µL of GS600 LIZ® and 8.75 µL of formamide HIDI™. Reading of the alleles was carried out in an ABI 3500XL Sequencer (Applied Biosystems). Gene Mapper v.3.2 (Applied Biosystems) was used to interpret the electropherograms.

Demographic data analysis

The total number of individuals (reproductive and nonreproductive) per hectare, height averages and diameter at soil level (DAS) were estimated, and incremental differences between years were estimated using the Student’s t-test (t; p < 0.05). The population growth rate was calculated by subtracting the individuals that were dead and not found from the recruits. For individuals with multiple ramifications, the diameter at soil level was unified by calculating the root of the sum of the squares.

The spatial distribution pattern was estimated using Ripley’s K Function (1977) and carried out in R software, version 3.3.0 (R Development Core Team 2016R DEVELOPMENT CORE TEAM. 2016. A Language and Environment for Statistical Computing.R-Foundation for Statistical Computing. 3.3.0. R Foundation for Statistical Computing, Vienna, Austria. URL: https://www.R-project.org/), with the Spatstat package (Baddeley & Turner 2005BADDELEY A & TURNER R. 2005. Spatstat: An R Package for Analyzing Spatial Point Patterns. J Stat Softw 12: 1-42.). The values obtained for K (h) were transformed by the function L (d) for better interpretation of the data. The deviations from the Complete Spatial Randomness were tested using confidence envelopes (p < 0.001) constructed from 1000 Monte Carlo simulations.

The relationship between the number of individuals and vegetation coverage, as well as altimetric profile, was evaluated by means of Spearman correlation. For vegetation coverage, the number of sampled V. curassavica individuals was correlated with the average percentage of cover obtained in each subplot. For the altimetric profile, the correlation between altimetric profile and presence of individuals was made from the slope angle obtained from 5 x 5 m subplots and the number of individuals present in them. The association between environment type and prensence of individuals was verified by comparing the frequency of occurrence of the individuals in the different environments, using the contingency table and chi-square test (χ ²). Differences between height increase averages and DAS and environments were tested by means of confidence intervals (p < 0.05). In transition zone subplots, the predominant environment was considered.

We used confidence intervals (p < 0.05) to test for potential differences in the growth of individuals (height and diameter) for the different environments, using the differences in average increment for each environment.

Analysis of genetic data

To verify possible genetic differences in the different environments, the following indices of genetic diversity were estimated for each environment: number of alleles per locus (Â) and per individuals (Â_i ); genotypic richness, which measures the number of genotype with four alleles per locus (Ĝ); observed (Ĥ _O) and expected (Ĥ_E ) heterozygosities and fixation index () for all loci, calculated as 1 - (Ĥ_O/ Ĥ_E ). Each locus deviating from the Hardy-Weinberg Equilibrium (HWE) model was tested using the chi-square test (χ²). Genetic diversity parameters were calculated using the Autotet program (Thrall & Young 2000THRALL PH & YOUNG A. 2000. AUTOTET: A program for analysis of autotetraploid genotypic data. J Hered 91: 348-349.), which is specific to polyploid organisms and calculates the observed heterozygosity by weighting five different classes of possible genotypes per locus inversely against the probability of any two alleles will be identical by descent; Ĥ_E and () were calculated on the basis of random chromosome segregation (Li 1955LI CC. 1955. Population genetics. Chicago: University of Chicago Press.). The confidence intervals at 95% probability were obtained by Jackknife resampling between loci for each environment.

The partition of genetic diversity within and among environments was calculated using the genetic diversity statistics of Nei (1973)NEI M. 1973. Analysis of gene diversity in subdivided populations. P Nat Acad Sci 70: 3321-3323., based on the following parameters: Ĥ_T – total genetic diversity; Ĥ_S – genetic diversity average within environments; Ď_ST – genetic diversity among environments and Ĝ_ST – proportion of the total genetic diversity among environments, using DISPAN software (Ota 1993OTA T. 1993. DISPAN: Genetic distance and phylogenetic analysis. Computer programand documentation distributed by the author, website: http://homes.bio.psu.edu/people/Faculty/Nei/ [accessed in 10 Dec. 2016].
http://homes.bio.psu.edu/people/Faculty/... ).

Spatial distribution of genotypes was estimated using the coancestry coefficient (, Loiselle et al. 1995LOISELLE BA, SORK VL, NASON J & GRAHAM C. 1995. Spatial genetic structure of a tropical understory shrub Psychotria officinalis (Rubiaceae). Am J Bot 82: 1420-1425.) between pairs of individuals and was obtained from SPAGEDI software, v. 1.4 (Hardy & Vekemans 2003HARDY O & VEKEMANS X. 2003. SPAGeDI 1.1: A program for spatial patternan alysis of genetic diversity. Version for Windows 95. http://www.ulb.ac.be/sciences/ecoevol/software.html.
http://www.ulb.ac.be/sciences/ecoevol/so... ). Confidence intervals (95%) for values in each distance interval were obtained by 1000 permutations of individual locations among all individuals.

RESULTS

Population dynamics

In the first year of evaluation (2014), 425 individuals (213 ind.ha^-1) were found, of which about 10% (42 individuals) were in the reproductive phase, and from 2014 to 2016, 125 individuals were recruited to the population (63 ind.ha^-1). We found 12 deads ind.ha^-1, and 37 ind.ha^-1 were not found, totaling 248 ind.ha^-1 survivors in 2016, representing an annual growth rate of 8%. Of these survivors, 26% were recorded in the reproductive phase. Of individuals who entered the population after 2014, four were not found and three died. Of those that died, 75% were in flooded areas. At the end of the first year, no reproductive structures were observed for the recruits of 2015.

Individuals of V. curassavica presented mean height of 0.57 m (± 0.30 SD), with no significant change between the years (t = - 0.89; p = 0.37) (Table I), ranging from 0.05 to 2.15 m. The recruits had height between 0.08 m and 1.32 m, with an average of 0.49 m (± 0.29), and the highest growth was 0.74 m / year. Reproductive individuals had, on average, a height ranging from 0.75 m (± 0.31) to 0.83 m (± 0.33) between evaluation years. Reproductive structures, such as floral buds, were recorded for individuals from 0.12 m in height.

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Table I
Mean, minimum and maximum heights by classes of individuals of Varronia curassavica Jacq. (Boraginaceae), which were evaluated between 2014 and 2016 in the restinga population of Joaquina - Florianópolis/SC.

Most V. curassavica individuals (67%) were concentrated in the first two height classes, but reduced in number as heights increased from 35 cm (Figure 1a). With respect to DAS, the mean ranged from 1.77 cm (SD = ± 0.92) to 2.75 cm (SD = ± 1.97) between the evaluated years. The maximum and minimum DAS values were 9.11 cm and 0.60 cm, respectively. The species had a frequency of individuals greater than 50% in the first diameter class, but as diameter increased, the number of individuals decreased during the first year of evaluation (Figure 1b). This pattern differed in subsequent years, with a shift in the number of individuals in the classes, owing to the increase in diameters. For both height and DAS classes, the population presented a tendency toward a J-inverted curve (Figure 1a, b).

Figure 1
a) Distribution of individuals of Varronia curassavica Jacq. (Boraginaceae) by height intervals (top); b) Distribution of individuals in diameter to soil level classes (30 individuals) (bottom). Results represent evaluations from 2014 to 2016 in the restinga area of Joaquina - Florianópolis/SC.

Spatial distribution and relationship with the environment

This species had an aggregate spatial structure (Figure 2). The function L (d) determined that the aggregation distances of individuals were constant and peaked at a distance of ~ 40 m.

Figure 2
Spatial distribution of individuals of Varronia curassavica Jacq. (Boraginaceae), between 2014 and 2016 (nonreproductive individuals represented in black and reproductive represented in gray), sampled in the restinga of Joaquina, Florianópolis / SC (left) and analysis of the spatial pattern by Ripley’s K function (right). Confidence interval represented by dotted lines.

The correlation values between number of individuals and environmental characteristics were low, but significant. The highest value was for vegetation coverage (r = 0.26; p = 0.0003), and for slope, the correlation was negative (r = - 0.146; p = 2.21 ∙ 10^-5).

Inside the plot, vegetation coverage was unevenly distributed. About 50% of the analyzed subplots (97 subplots) had, on average, 76-100% vegetation coverage; 58 subplots between 51-75%, and 36 subplots between 26-50% vegetation coverage values. Only 4% (9 subplots) of the evaluated area showed 0-25% vegetation coverage values. For qualitative classification of the environment (Table II), dry lowland occurred in 26% of the plots and predominated in 10% of transition zone subplots. Itinerant dunes occurred in 33% of the studied area, while fully covered with vegetation fixed occurred only in 11 subplots. Dune areas occurred in 51% of the plots, and the remaining 49% are lowlands.

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Table II
Environment type in the subplots sampled in the evaluation of demographic parameters of Varronia curassavica Jacq. (Boraginaceae) in the restinga of Joaquina, Florianópolis/SC.

The species exhibited preferential environments for occurrence, recruits and deaths (Figure 3). Of the sampled individuals, 99% were found on dry lowland (DL), itinerant dunes (ID), and transition zones between them (LTZ) (χ ² = 669.88 (₂₀₁₄); 618.24 (₂₀₁₅); 805.40 (₂₀₁₆); DF = 3; p < 0.05). Among these environments, 77% of individuals occurred in dry lowlands. For the remaining classes, the numbers of individuals were < 1%.

Figure 3
Frequency of (a) individual, (b) recruits and (c) deaths of Varronia curassavica Jacq. (Boraginaceae) from 2014 through 2016 in the different environments of the restinga of Joaquina / SC. FL = Flooded lowland; HL = Humid lowland; DL = Dry lowland; LTZ = Lowland transition zone; ID = Itinerant dune; SSD = Semi-settled dune; SD = Settled dune; DTZ = Dune transition zone.

Similarly, 94% of individuals entered the population in the following environments: DL, ID, LTZ, and DTZ (χ ² = 37.65 (₂₀₁₅); 99.64 (₂₀₁₆); DF = 3; p < 0.05), of which 66% occurred in dry lowlands. The number of dead individuals in dry lowlands was also higher for the last year evaluated (χ ² = 3.67 (₂₀₁₅); 21.26 (₂₀₁₆); p < 0.05; DF = 3).

Mean DAS increment for the evaluated period (three years) was significantly different between the environments of higher occurrence of the species. In the transition zones from dune to lowlands, the average increment was 0.314 cm (CI = ±0.28). In the itinerant dunes, the values were negative (-1.46 cm; CI = ±0.28), as well as on dry lowlands and lowland transition zones, where the increment was similar (0.80 cm and 0.87 cm; CI = ±0.28). Mean height increment was higher in the dry lowlands and itinerant dunes (0.05 cm; CI = ±0.01).

Diversity and genetic structure among environments

Seventy alleles were detected in eight polymorphic loci in the V. curassavica population. The mean number of alleles per locus was 9.9, ranging from 3 to 19 (Table III).

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Table III
Total genetic variation by environment of Varronia curassavica Jacq. (Boraginaceae) in the restinga population of Joaquina- Florianópolis/SC- Brazil. Mean values (first row) and confidence interval (second row) by environment.

The allelic frequencies were heterogeneous among environments (Table SIV -Supplementary Material). Rare alleles (frequency less than 5%) were detected in all environments with the highest occurrence of the species. For the population, 41% of alleles occurred with a frequency of less than 5%. This value was maintained for individuals in the dry lowlands, but in other environments, the values were lower than 21%. Private alleles were found only for the dry lowland environment (11 alleles at five loci).

The mean observed heterozygosity in the population (Ĥ_O ) was 0.711, and the expected heterozygosity average (Ĥ_E ) was 0.716, ranging from 0.305 to 0.914 in the eight loci evaluated (Table III). Fixation index () was significantly different from zero in seven of the eight loci evaluated (p < 0.001), suggesting HWE deviations. The mean index of fixation of the population, however, was not different from zero (p < 0.01). Allelic richness (Â) ranged from three to nineteen alleles per locus, while the mean number of alleles per individual / loci (Â_i ) ranged from 1.5 to 3.76 (tetraploid; Hoeltgebaum & Reis 2017HOELTGEBAUM MP & REIS MS. 2017. Genetic diversity and population structure of Varronia curassavica: a medicinal polyploid species in a threatened ecosystem. J Hered 108: 415-423.).

In the different environments (Table III), the mean observed heterozygosity (Ĥ _O) ranged from 0.703 to 0.737, with no significant differences among the environments, and the ranged from 0.675 to 0.730, where it was higher in semi-settled dune when compared to the dune transition zone, but showed no difference compared to the other environments. The highest mean allelic richness (9.88) was found in dry lowland, where the highest number of individuals were also found, while the mean number of alleles per individual / loci (Â_i ) was 2.90 to 2.98, with no significant difference among environments. The fixation indices () did present differences among environments, being negative and significant for dry lowland transition, semi-settled dune and dune transition, but no different from zero in dry lowland.

The analysis of genetic structure indicated low divergence between the environments (Ď_ST = 0.015; Table V). The estimated interpopulation divergence (Ĝ_ST ) indicated that around 2% of the allelic variation found was not shared among the different restinga environments. When analyzing the structure among environments (peer-to-peer), the values were found to closely range from 0.009 to 0.015 (Table V). For semi-settled dune and dune transition, however, the divergence was higher than the other environments (Ĝ_ST = 0.021), evidencing a trend towards greater divergence between dunes.

Thumbnail

Table V
Nei’s (1973) genetic diversity statistics of eight microsatellite loci for the Varronia curassavica Jacq. (Boraginaceae) population and among different environments of the restinga, Joaquina / SC- Brazil.

Spatial genetic structure

The population did not present significant spatial genetic structure for the distance classes evaluated, suggesting that the genotypes are distributed randomly in the area (Figure 4). When analyzing the different environments, this pattern was maintained with no variation among them.

Figure 4
Spatial genetic structure (SGE) of Varronia curassavica Jacq. (Boraginaceae) individuals in the different restinga environments of Joaquina/SC. The continuous line represents the estimate of the mean coancestry coefficient, and the dotted lines represent the estimate of the confidence interval at 95% probability of the hypothesis of absence of genetic structure (H0: θxy = 0).

DISCUSSION

The population of V. curassavica presented positive growth rate over the years, with a number of regenerants higher than the number of dead individuals andnot found, indicating that the population is expanding. Although the seedling stage, which is considered the most critical phase of the life cycle of many species, with greater structural fragility (Kozlowski 1971KOZLOWSKI TT. 1971. Growth and development of trees. v.l. New York: Academic Press.), the number of deaths and individuals not found in this class was low. This aspect is extremely important for the establishment of the population, especially because the species presents a considerable number of aborted flowers and fruits (Hoeltgebaum et al. 2018HOELTGEBAUM MP, MONTAGNA T, LANDO AP, PUTTKAMMER C, ORTH AI, GUERRA MP & REIS MS. 2018. Reproductive Biology of Varronia curassavica Jacq. (Boraginaceae). An Acad Bras Cienc 90: 59-71.), aside from being frequently subjected to trampling (men and animals) and herbivory.

Most seedling-stage deaths can be associated with “mobile flooding”. On the other hand, the number of individuals not found, is, in general, reflective of methodological difficulties observed in the demographic evaluation of species, such as the pattern of disordered growth of the branches and their easy detachment, which, apart from burial, result from movement of dunes.

In terms of diameter and height structure, the pattern that trends toward “J-inverted” indicates a positive balance between recruitment and mortality, which is characteristic of populations in regenerative equilibrium. However, the establishment of the classes proposed herein (recruits, nonreproductive, and reproductive) does not necessarily reflect cohorts in the population, since it was not possible to identify morphological characteristics by which to classify individuals sampled among seedlings, juveniles and adults. Sometimes, branches with regenerating aspects could be observed in mature plants. Depending on the degree of burial of the plant, older branches may not have been found. Likewise, individuals observed in the first class were observed in reproduction.

In the studied area, the species showed an aggregate distribution pattern. As evidenced in this study, the occurrence of environmental heterogeneity, in terms of habitats favorable to the propagation of plant species, as well as the discontinuity of the landscape in terms of physiognomy and vegetation coverage, has been commonly cited in order to explain the distribution of vegetation in restinga areas (Castro et al. 2007CASTRO D, SOUZA M & MENEZES LFT. 2007. Estrutura da formação arbustiva aberta não inundável na restinga da Marambaia, RJ. R Bras Bioci 5: 75-77., Pereira 2009PEREIRA J. 2009. Estrutura demográfica e fenologia reprodutiva de Cereus hildmannianus K. Schum. (Cactaceae), em uma restinga arbustiva do município de Jaguaruna, Santa Catarina. Dissertacion, Universidade Federal de Santa Catarina, Florianópolis. (Unpublished)., Ferreira et al. 2010FERREIRA LC, THOMAZI RD, OLIVEIRA DAC & SILVA AG. 2010. Estrutura populacional e padrão espacial de Protium icicariba (DC.) Marchand na Área de Proteção Ambiental de Setiba, Espírito Santo, sudeste do Brasil. Natureza online 8: 39-45.). In arid and semi-arid environments, the pattern of mosaic aggregation in plants has also been well documented (Montaña 1992MONTAÑA C. 1992. The colonization of bare areas in two-phase mosaics of an arid ecosystem. J Ecol 80: 315-327., Tirado & Pugnaire 2005TIRADO R & PUGNAIRE FI. 2005. Community structure and positive interactions in constraining environments. Oikos 111: 437-444., Kyncl et al. 2006KYNCL T, SUDA J, WILD J, WILDOVA R & HERBEN T. 2006. Population dynamics and clonal growth of Spartocytisus su-pranubius (Fabaceae), a dominant shrub in the alpine zone of Tenerife, Canary Islands. Plant Ecol 186: 97-108.).

Relationships between the occurrence of individuals of this species and different environmental variables of the restinga showed that higher slopesand lower degree of vegetation coverage are associated with lower frequency of individuals. Dry lowlands showed the highest occurrence. Although this restinga area has about the same proportion available between dunes and lowland environments (51% and 49% respectively), about 80% of the individuals of this V. curassavica population occur in dry lowlands. The transition zones are responsible for 19% of the population. On the other hand, the environments less favorable to the occurrence of the species are the flooded areas, as well as itinerant dune. Mobile dunes have little to no vegetation, whereas in settled dune, it is possible to find different densities of vegetation with shrub and tree species that can form canopies. The exposed has high temperature ranges, and water availability is low, generally limiting the establishment of several species (see: Pinheiro & Borghetti 2003PINHEIRO F & BORGHETTI F. 2003. Light and temperature requirements for germination of seeds of Aechmea nudicaulis (L.) Griesebach and Streptocalyx floribundus (Martius ex Schultes F.) Mez (Bromeliaceae). Acta Bot Bras 17: 27-35., Mantovani & Iglesias 2010MANTOVANI A & IGLESIAS RR. 2010. The effect of water stress on seed germination of three terrestrial bromeliads from restinga. Rev Bras Bot 33: 201-205.).

However, environments with dense vegetation may not favor germination since the species is heliophyta (Smith 1970SMITH LB. 1970. Boragináceas. Flora Ilustrada de Santa Catarina, Itajaí.), and shading in these areas may be one of the main factors influencing the establishment of a new individual. In addition to limited establishment, greater mortaility of seedlings occurs in environments subject to flooding, indicating that such conditions are unfavorable for the establishment of individuals. Recruits were also more frequent in dry lowlands (66%), as well as the number of deaths (68%), possibly by the higher number of individuals.

Apart from being areas of preferential occurrence of the species, lowland environments, along with the semi-settled dune, were places where the species presented the highest average increase in height within the observed period, while the increase of the average DAS was significantly higher in the dune transition zones. These results reinforce the importance of dry lowland environments and semifixed dune (and transition zones) for the establishment and development of the species.

Therefore, it can be concluded that the aggregate spatial distribution found for V. curassavica in this study results from the preference of this species for certain habitats (DL and SSD) and, consequently, their distribution in the restinga.

The analysis of genetic diversity also showed heterogeneity in allelic frequencies associated with differences among environments. Dry lowlands, environments with the highest number of individuals, also presented higher allelic richness. Rare alleles were sampled in all environments, but in the dry lowlands these represented 40%. Private alleles were found only in the dry lowlands. The presence of rare and private alleles is indicative of the importance and function of these environments in terms of species conservation and also the prioritization of areas to be conserved, since low frequency alleles are more susceptible to loss, mainly due to effects of genetic drift (Frankel et al. 1995FRANKEL OH, BROWN AHD & BURDON JJ. 1995. The conservation of plant biodiversity. Cambridge: Cambridge University Press, 320 p.). However, for a fair comparison, allelic richness data would need to be rarefied, since richness data tends to increase by sampling, and this result should be interpreted with care. Nevertheless, such an analysis could not be performed since the population sampled is tetraploid (Hoeltgebaum & Reis 2017HOELTGEBAUM MP & REIS MS. 2017. Genetic diversity and population structure of Varronia curassavica: a medicinal polyploid species in a threatened ecosystem. J Hered 108: 415-423.), and most of the softwares do not deal with this data.

In the population as a whole and in the dry lowland environment specifically, the fixation index was not significantly different from zero, evidencing the absence, or reduced effects, of inbreeding and genetic drift. This aspect can be explained by the reproductive system of the species, which is typically allogamic, with mechanisms of self-incompatibility, such as heterostyly and protogyny (Hoeltgebaum et al. 2018HOELTGEBAUM MP, MONTAGNA T, LANDO AP, PUTTKAMMER C, ORTH AI, GUERRA MP & REIS MS. 2018. Reproductive Biology of Varronia curassavica Jacq. (Boraginaceae). An Acad Bras Cienc 90: 59-71.). However, for the other environments, these values were negative and significant, indicating a tendency to preferential crosses or selection in favor of heterozygotes for this population. The selection in favor of heterozygotes has advantages for the species, increasing its genetic plasticity, allowing their survival and distribution in diverse environmental conditions.

In plants, spatial distribution and kinship degree may be associated. As a consequence of the aggregate pattern found for V. curassavica, we expected to find family structure at close range. Contrary to expectation, we found an absence of structure, indicating that genotypes are randomly distributed in the area. This result suggests that the gene flow within this population may be more related to genetic factors, such as the presence of self-incompatibility mechanisms (Hoeltgebaum et al. 2018HOELTGEBAUM MP, MONTAGNA T, LANDO AP, PUTTKAMMER C, ORTH AI, GUERRA MP & REIS MS. 2018. Reproductive Biology of Varronia curassavica Jacq. (Boraginaceae). An Acad Bras Cienc 90: 59-71.), and is not associated to environmental heterogeneity. Levin (1981)LEVIN DA. 1981. Dispersal versus gene flow in plants. Ann Mo Bot Gard 68: 233-253. demonstrated that the movement of genes within populations is conditioned by the degree of genetic compatibility between individuals. According to the author, the presence of autoincompatibility may prevent certain types of crosses and increase the probability of crossing between more distant plants, considering that the compatibility of pollen-pistil may be smaller between neighbors than between moderately spaced plants. The influence of heterostyly on spatial distribution of genes is also discussed by Martins (1987)MARTINS PS. 1987. Estrutura populacional, fluxo gênico e conservação in situ. IPEF 35: 71-78. for Cordia goeldiana Huber, where heterostyly, associated with population density and flowering, has implications for intra and interpopulation gene flow patterns. For V. curassavica, the possible preference of crosses between more distant individuals, owing to heterostyly, would act as a promoter of the gene flow within the population, thus reducing the formation of internal genetic structure. In addition, gene flow for this species is also favored by an ample guild of insects that pollinate it (Hoeltgebaum et al. 2018HOELTGEBAUM MP, MONTAGNA T, LANDO AP, PUTTKAMMER C, ORTH AI, GUERRA MP & REIS MS. 2018. Reproductive Biology of Varronia curassavica Jacq. (Boraginaceae). An Acad Bras Cienc 90: 59-71.).

Thus, the presence of mechanisms of self-incompatibility and the gene flow favored by generalist pollination may favor the random distribution of genotypes in the population, which would not otherwise be expected for the species owing to the aggregated spatial pattern. Dependence on genetically compatible neighbors implies larger areas for conservation.

This study demonstrates the quality of monitoring and evaluating the demographic and genetic dynamics of a representative number of individuals of the species. The diversity of environments, ranging from mobile dunes to fixed dunes, from flooded areas to dry dunes, exemplifies the heterogeneity that can be found in the Brazilian restingas. Therefore, it can demonstrate that variations in the distribution of individuals and genotypes can occur due to different environments.

Dry lowlands are of great relevance for the maintenance of the demographic and genetic processes of the species in restingas. On the other hand, areas such as flooded lowland and and mobile dunes were examples of environments unfavorable to the development of the species. This diversity of environments contributed to the aggregate distribution of the species, but did not influence the internal genetic structure. Although the population has evidenced the absence or reduced effects of inbreeding and genetic drift, in some environments the fixation indices indicate a tendency to preferential crosses or selection in favor of heterozygotes for this population. For V. curassavica, this selection may favor alleles or genotypic combinations more favorable to the diversity of environments found in the restinga, allowing their survival and distribution in diverse environmental conditions.

Thereby, the environmental heterogeneity, typical of restingas, is especially relevant for the establishment of the species and should be considered in deciding the minimum areas for conservation and effective population size when defining strategies for in situ conservation, and management approaches of the species.

ACKNOWLEGMENTS

This study is part of the doctoral thesis of the first author (Plant Genetic Resources Postgraduate Program – Universidade Federal de Santa Catarina (UFSC). The authors thank the Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq) process no. 140386/2013-0 to M.P.H, 130894/2015-0 to R.C.R and 309128/2014-5 to M.S.R.; and the Fundação de Amaparo à Pesquisa e Inovação do Estado de Santa Catarina (FAPESC) CP FAPESC/CNPq nº 005/2010 - PRONEX/2780/2012-4 for financial support; the Physiology of Development and Plant Genetics Laboratory of the UFSC for logistical support. We wish to thank researchers at the Tropical Rainforests Research Center (NPFT) for their kind help in fieldwork and Victor Hugo Buzzi, Newton Clóvis Freitas da Costa, Juliano Zafgo da Silva, Ana Paula Lando, Eduarda Rampinelli and Andréa Gabriela Mattos for their support in fieldwork.

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SUPPLEMENTARY MATERIAL

Table SIV.

Publication Dates

Publication in this collection
07 Sept 2020
Date of issue
2020

History

Received
30 May 2018
Accepted
18 Jan 2019

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] BADDELEY A & TURNER R. 2005. Spatstat: An R Package for Analyzing Spatial Point Patterns. J Stat Softw 12: 1-42.

[2] BARCELOS MEF, RIGUETE JR, SILVA LTP & FERREIRA JR PF. 2012. A visão panorâmica sobre os solos das restingas e seu papel na definição de comunidades vegetais nas planícies costeiras do sudeste do Brasil. Natureza online 10: 71-76.

[3] BERNASOL WP & LIMA-RIBEIRO MS. 2010. Estrutura espacial e diamétrica de espécies arbóreas e seus condicionantes em um fragmento de cerrado sentido restrito no sudoeste goiano. Hoehnea 37: 181-198.

[4] BOLZANI VS, VALLI M, PIVATTO M & VIEGAS JÚNIOR C. 2012. Natural products from Brazilian biodiversity as a source of new models for medicinal chemistry. Pure Appl Chem 84: 1837-1937.

[5] BRASIL. 2016. Ministério do Meio Ambiente, Conselho Nacional de Meio Ambiente, CONAMA. Resolução CONAMA No 261, de 30 de junho de 1999. In: Resoluções 1999. Disponível em http://www.mma.gov.br Acessado em 12 abril 2016.
» http://www.mma.gov.br

[6] CASTRO D, SOUZA M & MENEZES LFT. 2007. Estrutura da formação arbustiva aberta não inundável na restinga da Marambaia, RJ. R Bras Bioci 5: 75-77.

[7] CONNELL JH, TRACEY JG & WEBB LJ. 1984. Compensatory recruitment, growth, and mortality as factors maintaining rain forest tree diversity. Ecol Monogr 54: 141-164.

[8] CRAWLEY MJ & MAY RM. 1987. Population dynamics and plant community structure: competition between annuals and perennials. J Theor Biol 125: 475-489.

[9] DIAZ IA & OYAMA K. 2007. Conservation genetics of an endemic and endangered epiphytic Laelias peciosa (Orchidaceae). Am J Bot 94: 184-193.

[10] EPPERSON BK. 1992. Spatial structure of genetic variation within populations of forest trees. New Forests 6: 257-278.

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Classes	N. Individuals			Min. height (m)			Max. height (m)			Mean height ± SD (m)
Years	2014	2015	2016	2014	2015	2016	2014	2015	2016	2014	2015	2016
Recruits	-	54	71	-	0.08	0.1		0.98	1.32	-	0.57 ± 0.32	0.41 ± 0.26
Non Reprod.	383	322	367	0.05	0.06	0.08	1.85	1.31	1.8	0.54 ± 0.27	0.49 ± 0.23	0.51 ± 0.28
Reproductive	42	119	128	0.39	0.12	0.22	1.7	2.15	1.78	0.83 ± 0.33	0.75 ± 0.31	0.78 ±. 34
Total /Mean	425	441	495	-	-	-	-	-	-	0.57 ± 0.29	0.56 ± 0.30	0.58 ± 0.32

Environment	N	Â	Â _i	Ĝ	Ĥ ₀	Ĥ _E	$\hat{f}$
Dry lowland	306	9.88	2.93	63.75	0.709	0.718	0.012
Dry lowland	306	[9.05-10.7]	[2.83-3.02]	[56.42-71.08]	[0.678-0.740]	[0.692-0.744]
Dry lowland transition	32.4	7.25	2.91	14.13	0.703	0.699	-0.006*
Dry lowland transition	32.4	[6.7-7.8]	[2.8-3.01]	[12.96-15.29]	[0.669-0.736]	[0.673-0.724]
Semi-settled dune	34.5	7.88	2.98	14.88	0.737	0.730	-0.009*
Semi-settled dune	34.5	[7.25-8.5]	[2.89-3.07]	[13.67-16.08]	[0.71-0.764]	[0.709-0.751]
Dune transition	19	6.25	3.02	9.25	0.712	0.675	-0.054*
Dune transition	19	[5.79-6.71]	[2.89-3.15]	[8.62-9.88]	[0.678-0.745]	[0.643-0.708]
Total	396	9.9	2.9	74.9	0.711	0.716	0.01

Environment	Ĥ _T	Ĥ _S	Ĝ _ST
Population	0.720	0.705	0.020
DL x SSD	0.731	0.723	0.009
DL x LTZ	0.716	0.708	0.011
DL x DTZ	0.705	0.696	0.012
LTZ x SSD	0.725	0.714	0.015
LTZ X DTZ	0.696	0.687	0.012
DTZ X SSD	0.718	0.703	0.021

Environment type
Lowland	N^o SP	N^o SP TZ	Dune	N^o SP	N^o SP TZ
Flooded	3	1	Itinerant	14	11
Humid	10	14	Semi-settled	42	24
Dry	51	19	Settled	3	8

Brasil

Brasil

Genetic and demographic aspects of Varronia curassavica Jacq. in a heterogeneous coastal ecosystem

Abstract

INTRODUCTION

MATERIALS AND METHODS

Study area

Demographic and environmental characterization

Characterization of diversity and genetic structure

Demographic data analysis

Analysis of genetic data

RESULTS

Population dynamics

Spatial distribution and relationship with the environment

Diversity and genetic structure among environments

Spatial genetic structure

DISCUSSION

ACKNOWLEGMENTS

REFERENCES

SUPPLEMENTARY MATERIAL

Publication Dates

History