Abstract

Rock outcrop vegetation is recognized worldwide by its singular and biodiverse flora. Campo Rupestre forms hyperdiverse mosaics in rocky environments across a wide latitudinal and altitudinal gradient, with high species turnover at macro- and micro-scales. The surrounding biomes, climate, and geological formations are the main drivers of species turnover on a macro-scale while micro-habitat seems to be the main one determining the peculiarities of the Campo Rupestre on a micro-scale. In a quartzitic Campo Rupestre area we evaluate how the outcrop micro-habitats influence floristic composition and functional traits. The study area is located in the municipality of Ouro Preto, Minas Gerais state, southeastern Brazil. Two main outcrop habitats were considered: top surfaces, with bare rock, shallow depressions and ephemeral ponds; and lateral surfaces, with clefts and crevices. We recorded the vascular species, their respective life-forms (according to Raunkiaer’s system) as well as their coverage in 18 plots. We identified 71 species in 31 families. The floristic spectra and species composition were similar between top and lateral surfaces. There was no significant difference among the vegetational spectra. However, hemicryptophytes were slightly dominant on top, while on the sides chamaephytes were the dominant life-form. Understanding plant adaptations to these environments provides insights into the mechanisms underlying geomorphological heterogeneity in plant communities.

Key words
biological spectra; Brazilian flora; Campo Rupestre; life-form; Quadrilátero Ferrífero

Resumo

A vegetação de afloramentos rochosos é reconhecida mundialmente pela biodiversidade e singularidade de sua flora. O Campo Rupestre forma mosaicos hiperdiversos em ambientes rochosos distribuídos ao longo de um amplo gradiente latitudinal e altitudinal, com altas taxas de substituição de espécies em macro e microescalas. Em macroescala, os biomas adjacentes, clima e formações geológicas influenciam as taxas de substituição de espécies, enquanto os micro-habitats parecem influenciar as peculiaridades do Campo Rupestre em microescala. Este estudo foi realizado no município de Ouro Preto, Minas Gerais, Brasil. Visamos avaliar como os micro-habitats de afloramentos rochosos quartzíticos determinam a composição florística e os atributos funcionais considerando dois habitats principais: superfície superior, com rocha exposta, depressões rasas e poças efêmeras; e superfície lateral, com fendas e fissuras. Espécies vasculares e suas respectivas formas de vida e cobertura foram registradas em 18 parcelas. Identificamos 71 espécies pertencentes a 31 famílias. O espectro florístico e a composição de espécies foram similares entre os habitats. Não houve diferença significativa entre os espectros vegetacionais. Entretanto, hemicriptófitas foram ligeiramente dominantes na superfície superior e caméfitas, na lateral. Compreender as adaptações das plantas a esses ambientes fornece informações sobre os mecanismos subjacentes à heterogeneidade geomorfológica nas comunidades vegetais.

Palavras-chave
espectro biológico; flora brasileira; Campo Rupestre; formas de vida; Quadrilátero Ferrífero

Introduction

Rocky outcrops present a vegetation pattern distinct from their surroundings, often selecting for xeric-adapted species that are able to survive harsh climatic conditions (Porembski & Barthlott 2000Porembski S & Barthlott W (2000) Inselbergs: biotic diversity of isolated rock outcrops in tropical and temperate regions. Ecological Studies. Vol. 146. Springer-Verlag, Berlin, Heidelberg, New York, Tokyo. 524p.; Michael & Lindenmayer 2012Michael DR & Lindenmayer DB (2012) Vegetation structure and floristics of granite landforms in the South-west Slopes of New South Wales. Cunninghamia 9620: 309-323.). The distinct geomorphological features formed by rock outcrops create micro-habitats that further enhance biodiversity (Burnett et al. 1998Burnett MR, August PV, Brown JH & Killingbeck KT (1998) The influence of geomorphological heterogeneity on biodiversity I. A Patch-Scale Perspective. Conservation Biology 12: 363-370.). Campo Rupestre presents an extremely biodiverse vegetation and is defined by the presence of rocky outcrops; they are recognized as a mosaic of micro-habitats, with many endemics and stenotopic species (Conceição & Pirani 2005Conceição AA & Pirani JR (2005) Delimitação de habitats em Campos Rupestres na Chapada Diamantina, Bahia: substratos, composição florística e aspectos estruturais. Boletim de Botânica da Universidade de São Paulo 23: 85-111.; Conceição et al. 2007Conceição AA, Giulietti AM & Meirelles ST (2007) Ilhas de vegetação em afloramentos de quartzito-arenito no Morro do Pai Inácio, Chapada Diamantina, Bahia, Brasil. Acta Botanica Brasilica 21: 335-347.; Echternacht et al. 2011; Silveira et al. 2016Silveira FAO, Negreiros D, Barbosa NPU, Buisson E, Carmo FF, Carstensen DW, Conceição AA, Cornelissen TG, Echternacht L, Fernandes GW, Garcia QS, Guerra TJ, Jacobi CM, Lemos-Filho JP, Le Stradic S, Morellato LPC, Neves FS, Oliveira RS, Schaefer CE, Viana PL & Lambers H (2016) Ecology and evolution of plant diversity in the endangered Campo Rupestre: a neglected conservation priority. Plant Soil 403: 129-152.; Castro et al. 2018Castro SAB, Silveira FAO, Marcato MS & Lemos-Filho JP (2018) So close, yet so different: divergences in resource use may help stabilize coexistence of phylogenetically-related species in a megadiverse grassland. Flora 238: 72-78.). Studies on the heterogeneity of Campo Rupestre have been performed at several levels, from kilometric (Neves et al. 2018) to centimetric scales (Carmo et al. 2016).

From a broad perspective, the very existence of the Campo Rupestre is conditioned by structurally resistant lithotypes, mainly quartzite and itabirite, which form a higher relief above the surrounding (Rizzini 1979; Benites et al. 2007; Schaefer et al. 2016aSchaefer CEGR, Corrêa GR, Cândido HG, Arruda DM, Nunes JA, Araujo RW, Rodrigues PMS, Fernandes-Filho EI, Pereira AFS, Brandão PC & Neri AV (2016a) The physical environment of rupestrian grasslands (Campos Rupestres) in Brazil: geological, geomorphological and pedological characteristics, and interplays. In: Fernandes GW (ed.) Ecology and conservation of mountaintop grasslands in Brazil. Springer, Switzerland. Pp. 15-53.). The most continuous geological formation of this type is found in the Espinhaço Mountain Range (Giulietti et al. 1997Giulietti AM, Pirani JR & Harley RM (1997) Espinhaço range region. In: Davis SD, Heywood VH, Herrera-MacBryde O, Villa-Lobos J & Hamilton AC (eds.) Centres of Plant Diversity. Vol. 3. WWF & IUCN, Gland. Pp. 397-404.), in eastern Brazil, which extends over a thousand kilometers northerly-southerly throughout Bahia and Minas Gerais states, with rocks protruding at the top, usually from 900 m to 2,100 m.a.s.l., ranging in latitude from 10º00’S to 20º30’S. Its inherent disjunct distribution and large latitudinal, altitudinal, and climatic influences determine high species turnover (beta diversity) and endemism (Echternacht et al. 2011; Silveira et al. 2016Silveira FAO, Negreiros D, Barbosa NPU, Buisson E, Carmo FF, Carstensen DW, Conceição AA, Cornelissen TG, Echternacht L, Fernandes GW, Garcia QS, Guerra TJ, Jacobi CM, Lemos-Filho JP, Le Stradic S, Morellato LPC, Neves FS, Oliveira RS, Schaefer CE, Viana PL & Lambers H (2016) Ecology and evolution of plant diversity in the endangered Campo Rupestre: a neglected conservation priority. Plant Soil 403: 129-152.; Castro et al. 2018Castro SAB, Silveira FAO, Marcato MS & Lemos-Filho JP (2018) So close, yet so different: divergences in resource use may help stabilize coexistence of phylogenetically-related species in a megadiverse grassland. Flora 238: 72-78.). In the southern portion of Espinhaço Range, there is the Quadrilátero Ferrífero, a mountain complex of quadrangular relief and ferriferous or quartzitic rocks at mountaintops, located between the municipalities of Ouro Branco, Belo Horizonte, Catas Altas and Moeda. In spite of different geological origins for the Espinhaço Range and the Quadrilátero Ferrífero, they may be considered as a biogeographic unit (Echternacht et al. 2011; Colli-Silva et al. 2019Colli-Silva M, Vasconcelos TNC & Pirani JR (2019) Outstanding plant endemism levels strongly support the recognition of campo rupestre provinces in mountaintops of eastern South America. Journal of Biogeography 46: 1723-1733.).

At the macro-scale, the Campo Rupestre is highly influenced by the biomes in which they are inserted: from the north by the Caatinga, from the west by the Cerrado, and from the southeast by the Atlantic Forest (IBGE 2012IBGE - Instituto Brasileiro de Geografia e Estatística (2012) Manual técnico da vegetação brasileira. IBGE, Rio de Janeiro. 272p.). At an intermediate scale, rock types and geoforms are important determinants of the flora and vegetation patterns (Giulietti et al. 1997Giulietti AM, Pirani JR & Harley RM (1997) Espinhaço range region. In: Davis SD, Heywood VH, Herrera-MacBryde O, Villa-Lobos J & Hamilton AC (eds.) Centres of Plant Diversity. Vol. 3. WWF & IUCN, Gland. Pp. 397-404.; Vincent & Meguro 2008; Messias et al. 2013Messias MCTB, Leite MGP, Meira-Neto JAA, Kozovits AR & Tavares R (2013) Soil-vegetation relationship in quartzitic and ferruginous brazilian rocky outcrops. Folia Geobotanica 48: 509-521.; Schaefer et al. 2016aSchaefer CEGR, Corrêa GR, Cândido HG, Arruda DM, Nunes JA, Araujo RW, Rodrigues PMS, Fernandes-Filho EI, Pereira AFS, Brandão PC & Neri AV (2016a) The physical environment of rupestrian grasslands (Campos Rupestres) in Brazil: geological, geomorphological and pedological characteristics, and interplays. In: Fernandes GW (ed.) Ecology and conservation of mountaintop grasslands in Brazil. Springer, Switzerland. Pp. 15-53., 2016bSchaefer CEGR, Cândido HG, Corrêa GR, Nunes JA & Arruda DM (2016b) Soils associated with rupestrian grasslands. In: Fernandes GW (ed.) Ecology and conservation of mountaintop grasslands in Brazil. Springer, Switzerland. Pp. 55-69.). Rock composition, hardness, metamorphism, and relief are determinants, forming two main types of Campo Rupestre: the quartzitic, with mainly siliciclastic rocks, and the ferruginous (Cangas) (Uhlein & Noce 2012Uhlein A & Noce CM (2012) Quadrilátero Ferrífero. In: Hasui Y, Carneiro CDR, Almeida FFM & Bartorelli A (eds.) Geologia do Brasil. Beca, São Paulo. Pp. 228-235.).

On a small scale, micro-habitats and phytophysiognomies play an important role in determining local diversity. They may be regarded as vegetational patches associated with and interspersed among the outcrops, as for example the open herbaceous grassland among marshes and riparian forests (Rapini et al. 2008Rapini A, Ribeiro PL, Lambert S & Pirani JR (2008) A flora dos campos rupestres da Cadeia do Espinhaço. Megadiversidade 4: 15-23.). Focusing on the diversity of Campo Rupestre, cracks and crevices play an important role in supporting plant species in the outcrops, as they accumulate soil and retain water, providing less arid conditions and reducing over-heating and drought (Alves & Kolbek 1993Alves RJV & Kolbek J (1993) Penumbral rock communities in Campo Rupestre sites in Brazil. Journal of Vegetation Science 4: 357-366.; Conceição & Pirani 2005Conceição AA & Pirani JR (2005) Delimitação de habitats em Campos Rupestres na Chapada Diamantina, Bahia: substratos, composição florística e aspectos estruturais. Boletim de Botânica da Universidade de São Paulo 23: 85-111.; Porembski 2007Porembski S (2007) Tropical inselbergs: habitat types, adaptive strategies and diversity patterns. Revista Brasileira de Botânica 30: 579-586.). In addition, the influence of fine-scale surface heterogeneity on rock vegetation was analyzed by Carmo et al. (2016)Carmo FF, Campos IC & Jacobi CM (2016) Effects of fine-scale surface heterogeneity on rock outcrop plant community structure. Journal of Vegetation Science 27: 50-59., who showed that the microtopography of fissures, cracks and rock fragments affect the distribution of functional groups.

Human exploitation of mineral resources is the main impact on Campo Rupestre, especially the open pit mining in the Quadrilátero Ferrífero, leading to irreversible biodiversity losses (Roeser & Roeser 2010Roeser HMP & Roeser PA (2010) O Quadrilátero Ferrífero - MG, Brasil: aspectos sobre sua história, seus recursos minerais e problemas ambientais relacionados. Geonomos 18: 33-37.; Silva 2016Silva JB (2016) Panorama sobre a vegetação em afloramentos rochosos do Brasil. Oecologia Australis 20: 451-463.; Carmo et al. 2017Carmo FF, Kamino LHY, Tobias Junior R, Campos IC, Carmo FF, Silvino G, Castro KJSX, Mauro ML, Rodrigues NUA, Miranda MPS & Pinto CEF (2017) Fundão tailings dam failures: the environment tragedy of the largest technological disaster of Brazilian mining in global context. Perspectives in Ecology and Conservation 15: 145-151.; Fitzsimons & Michael 2017Fitzsimons JA & Michael DR (2017) Rocky outcrops: a hard road in the conservation of critical habitats. Biological Conservation 211: 36-44.), especially on ferruginous outcrops but also on quartzite ones. Detailed studies regarding plant communities in post-mining areas have focused mainly on recovery and succession of natural communities (e.g., Schulz & Wiegleb 2000Schulz F & Wiegleb G (2000) Development options of natural habitats in a post-mining landscape. Land degradation and development 11: 99-110.; Heras et al. 2008Heras MM, Nicolau JM & Espigares T (2008) Vegetation succession in reclaimed coal-mining slopes in a Mediterranean-dry environment. Ecological Engineering 34: 168-178.; Gould 2011Gould SF (2011) Does post-mining rehabilitation restore habitat equivalent to that removed by mining? A case study from the monsoonal tropics of northern Australia. Wildlife Research: 38: 482-490.). Understanding the distribution of species in preserved areas may contribute to restoration strategies and increase the current knowledge for restoring mined areas in Brazil and worldwide (Bétard 2013Bétard F (2013) Patch-scale relationships between geodiversity and biodiversity in hard rock quarries: case study from a disused quartzite quarry in NW France. Geoheritage 5: 59-71.; Lemke et al. 2013Lemke D, Schweitzer CJ, Tazisong IA, Wang Y & Brown JA (2013) Invasion of a mined landscape: what habitat characteristics are influencing the occurrence of invasive plants? International Journal of Mining, Reclamation and Environment 27: 275-293.; Sharma & Chaudhry 2018Sharma V & Chaudhry S (2018) Vegetation composition and plant diversity in mining disturbed tropical thorn forest of Asola-Bhatti Wildlife Sanctuary, Northern India. Taiwania 63: 267-280.).

In spite of the great endemism of Campo Rupestre, it is hardly defined by floristics and taxonomy alone (Alves & Kolbek 2009Alves RJV & Kolbek J (2009) Summit vascular flora of Serra de São José, Minas Gerais, Brazil. Check List 5: 35-73.; Neves et al. 2017). Studies on plant functional traits and life forms may contribute to uncover patterns of plant species composition in different phytophysiognomies (Raunkiaer 1934Raunkiaer C (1934) The life forms of plants and statistical geography. Arno Press, Oxford. 632p.; Coelho et al. 2018Coelho MS, Carlos PP, Pinto VD, Meireles A, Negreiros D, Morellato LPC & Fernandes GW (2018) Connection between tree functional traits and environmental parameters in an archipelago of montane forests surrounded by rupestrian grasslands. Flora 238: 51-59.; Silva Mota et al. 2018Silva Mota G, Luz GR, Mota NM, Silva Coutinho E, Veloso MDM, Fernandes GW & Nunes YRF (2018) Changes in species composition, vegetation structure, and life forms along an altitudinal gradient of rupestrian grasslands in south-eastern Brazil. Flora 238: 32-42.).

Several studies have shown how habitat or micro-habitat in rock outcrops determine different flora and vegetation patterns (Porembski et al. 1997Porembski S, Seine R & Barthlott W (1997) Inselberg vegetation and the biodiversity of granite outcrops. Journal of the Royal Society of Western Australia 80: 193-199.; Conceição & Pirani 2005Conceição AA & Pirani JR (2005) Delimitação de habitats em Campos Rupestres na Chapada Diamantina, Bahia: substratos, composição florística e aspectos estruturais. Boletim de Botânica da Universidade de São Paulo 23: 85-111.; Gröger & Huber 2007Gröger A & Huber O (2007) Rock outcrop habitats in the Venezuelan Guayana lowlands: their main vegetation types and floristic components. Revista Brasileira de Botânica 30: 599-609.; Jacobi et al. 2007Jacobi CM, Carmo FF, Vincent RC & Stehmann JR (2007) Plant communities on ironstone outcrops: a diverse and endangered Brazilian ecosystem. Biodiversity and Conservation 16: 2185-2200.; Porembski 2007Porembski S (2007) Tropical inselbergs: habitat types, adaptive strategies and diversity patterns. Revista Brasileira de Botânica 30: 579-586.; Paula et al. 2017Paula LFA, Mota NFO, Viana PL & Stehmann JR (2017) Floristic and ecological characterization of habitat types on an inselberg in Minas Gerais, southeastern Brazil. Acta Botanica Brasilica 31: 199-211.). According to these authors, patterns are related with soil depth, humidity and shading. These variables are higher in crevices, common in the lateral quartzite rock blocks, compared with the soil pools on the top of the rock blocks. We analyzed two micro-habitats (top and lateral surfaces of quartzite rock) to evaluate the influences, in a meter scale, of habitat heterogeneity on the plant community in terms of floristic, vegetational and functional aspects in Campo Rupestre. We hypothesized that these micro-habitats would determine different flora, vegetation and functional traits, since they are under different soil and sunlight conditions. We expect higher flora and life-form diversity in lateral habitat, since it is more heterogeneous. We described the species composition, floristic and vegetational spectra as a reflex of these environmentally distinct habitats. Further discussion concerning species and rock outcrops conservation are provided.

Material and Methods

Study Area

The study was carried out at the Serra das Camarinhas locality, municipality of Ouro Preto, southeastern of the Quadrilátero Ferrífero, Minas Gerais state, Brazil (Fig. 1), at 20°22’S and 43°30’W, 1,357 m to 1,433 m above sea level. The study site is within the Área de Proteção Ambiental (APA) Cachoeira das Andorinhas, a conservation unit of sustainable use, and neighbor to the Parque Natural Municipal da Cachoeira das Andorinhas, a fully protected conservation unit. The Quadrilátero Ferrífero is strongly affected by quarrying, which is one of its main anthropic impacts (Roeser & Roeser 2010Roeser HMP & Roeser PA (2010) O Quadrilátero Ferrífero - MG, Brasil: aspectos sobre sua história, seus recursos minerais e problemas ambientais relacionados. Geonomos 18: 33-37.; Silva 2016Silva JB (2016) Panorama sobre a vegetação em afloramentos rochosos do Brasil. Oecologia Australis 20: 451-463.; Carmo et al. 2017Carmo FF, Kamino LHY, Tobias Junior R, Campos IC, Carmo FF, Silvino G, Castro KJSX, Mauro ML, Rodrigues NUA, Miranda MPS & Pinto CEF (2017) Fundão tailings dam failures: the environment tragedy of the largest technological disaster of Brazilian mining in global context. Perspectives in Ecology and Conservation 15: 145-151.; Fitzsimons & Michael 2017Fitzsimons JA & Michael DR (2017) Rocky outcrops: a hard road in the conservation of critical habitats. Biological Conservation 211: 36-44.). In the study site, urban expansion is the main current threat (Myr 2017Myr - Projetos Sustentáveis (2017) Resumo executivo: plano de manejo - Parque Natural Municipal das Andorinhas em Ouro Preto. Myr Projetos Sustentáveis, Belo Horizonte, 128p. Available at <https://parquedasandorinhas.ouropreto.mg.gov.br/plano-manejo/>. Access on 10 June 2020.
https://parquedasandorinhas.ouropreto.mg... ).

Rocks associated with Campo Rupestre may present distinct geological origins. Most of the Campo Rupestre is located on the Espinhaço Mountain Range and belongs to the Espinhaço Supergroup (Alkmim 2012Alkmim FF (2012) Serra do Espinhaço e Chapada Diamantina. In: Hasui Y, Carneiro CDR, Almeida FFM & Bartorelli A (eds.) Geologia do Brasil. São Paulo, Beca. Pp. 236-244.; Uhlein & Noce 2012Uhlein A & Noce CM (2012) Quadrilátero Ferrífero. In: Hasui Y, Carneiro CDR, Almeida FFM & Bartorelli A (eds.) Geologia do Brasil. Beca, São Paulo. Pp. 228-235.). The Quadrilátero Ferrífero has multiple geological formations and the quartzitic outcrops of this survey belong to the Caraça Group, Minas Supergroup (Baltazar et al. 2005Baltazar OF, Baars FJ, Lobato LM, Reis LB, Achtschin AB, Berni GV & Silveira VD (2005) Mapa geológico Mariana na escala 1:50.000 com nota explicativa. In: Lobato LM, Baltazar OF, Reis LB, Achtschin AB, Baars FJ, Timbó MA, Berni GV, MendonçaBRV & Ferreira DV (eds.) Projeto Geologia do Quadrilátero Ferrífero - integração e correção cartográfica em SIG com nota explicativa. CODEMIG, Belo Horizonte. Pp. 1-68.).

The climate of the region is classified as Cwb according to Köppen, i.e. mesothermic, with a warm and rainy season from September to April and a cold and dry season from May to August (Alvares et al. 2013Alvares CA, Stape JL, Sentelhas PC, Moraes Gonçalves JL & Sparovek G (2013) Köppen’s climate classification map for Brazil. Meteorologische Zeitschrift 22: 711-728.). The vegetation on the rocky outcrops is distributed as patches, perceived as vegetation islands within a montane Atlantic Forest matrix (Porembski et al. 1998Porembski S, Martinelli G, Ohlemüller R & Barthlott W (1998) Diversity and ecology of saxicolous vegetation mats on inselbergs in the Brazilian Atlantic rainforest. Diversity and Distributions 4: 107-119.; Caiafa & Silva 2005; Paula et al. 2017) (Fig. 2a).

Sampling

To perform this survey, nine quartzitic outcrops were selected. Two main habitats were considered (Fig. 2b): (1) outcrop top surface, which is defined by flat or slightly tilted surfaces (corresponding to a slope less than 45 degrees) and comprises mainly bare rocks, with small depressions filled with shallow sandy substrate and ephemeral ponds, very exposed to sunlight and wind; and (2) outcrop lateral surface, defined by steepness higher than 45 degrees, composed mainly of clefts and crevices, with deeper soil accumulation, high humidity and shading. The first habitat is sunnier, exposed, more xeric. The second is more shaded and mesic, sheltered by projections of the outcrop and by the surrounding vegetation. These two environments represent the heterogeneity and complexity of micro-habitats of outcrops in the area.

The survey was carried out from August/2017 to June/2018 by monthly field trips in 18 sampling plots of the selected outcrops. Nine plots were sampled for each habitat, corresponding to 1,000 m² for the outcrop top surface and 450 m² for the outcrop lateral surface, totaling 1,450 m². All the individuals of vascular species with at least four definitive leaves were sampled in order to evaluate the floristic composition and the dominance of each registered species. All vascular species were collected, identified, grouped by family according to the Angiosperm Phylogeny Group IV System (APG IV 2016APG IV - Angiosperm Phylogeny Group (2016) An update of the Angiosperm Phylogeny Group classification for the orders and families of flowering plants: APG IV. Botanical Journal of the Linnean Society 181: 1-20.) and to the Pteridophyte Phylogeny Group I System (PPG I 2016PPG I - The Pteridophyte Phylogeny Group (2016) A community-derived classification for extant lycophytes and ferns. Journal of Systematics and Evolution 54: 563-603.). Vouchers were deposited in the Herbarium “Professor José Badini” (OUPR) of the Federal University of Ouro Preto. Each species was also classified into life-forms as stated by Raunkiaer’s System (Raunkiaer 1934Raunkiaer C (1934) The life forms of plants and statistical geography. Arno Press, Oxford. 632p.). Species were identified by direct comparison with physical herbarium specimens (OUPR), consultation with specialists, and specialized literature (Araujo et al. 2005Araujo AO, Souza VC & Chautems A (2005) Gesneriaceae da Cadeia do Espinhaço de Minas Gerais, Brasil. Revista Brasileira de Botânica 28: 109-135.; Dutilh 2005Dutilh JHA (2005) Amaryllidaceae. Flora fanerogâmica do estado São Paulo. Instituto de Botânica, São Paulo. Vol. 4, pp. 244-256.; Kinoshita & Simões 2005Kinoshita LS & Simões AO (2005) Flora da Serra do Cipó, MG: Apocynaceae s. str. (Rauvolfioideae e Apocynoideae). Boletim de Botânica da Universidade de São Paulo 23: 235-256.; Amaral 2007Amaral AC (2007) Amaryllidaceae Jaume St.-Hil.: levantamento das espécies do Distrito Federal, Brasil, e estudos de multiplicação in vitro. Dissertação de Mestrado. Universidade de Brasília, Brasília, 114p.; Rolim 2007Rolim LB (2007) Pteridófitas do Parque Estadual do Itacolomi, Minas Gerais, Brasil. Dissertação de Mestrado. Universidade de Brasília, Brasília. 271p.; Coser & Paula 2008Coser TS & Paula CC (2008) Bromeliaceae Juss. dos Campos Rupestres do Parque Estadual do Itacolomi, Minas Gerais, Brasil: florística e aspectos fenológicos. Dissertação de Mestrado. Universidade Federal de Viçosa, Viçosa. 84p.; Rolim 2011Rolim T (2011) Melastomataceae Juss. no Campo Rupestre do Parque Estadual do Itacolomi, Minas Gerais, Brasil: relações ecológicas, fitofisionômicas, padrões de distribuição geográfica e comparação florística. Dissertação de Mestrado. Universidade Federal de Viçosa, Viçosa. 89p.; Montserrat & Mello-Silva 2013Montserrat L & Mello-Silva R (2013) Velloziaceae do Parque Estadual de Ibitipoca, Minas Gerais, Brasil. Boletim de Botânica da Universidade de São Paulo 31: 131-139.; Almeida et al. 2014Almeida GSS, Carvalho-Okano RM, Nakajima JN & Garcia FCP (2014) Asteraceae Dumort nos campos rupestres do Parque Estadual do Itacolomi, Minas Gerais, Brasil: Barnadesieae e Mutisieae. Rodriguésia 65: 311-328.; Coelho & Giulietti 2010Coelho AAOP & Giulietti AM (2010) O gênero Portulaca L. (Portulacaceae) no Brasil. Acta Botanica Brasilica 24: 655-670.; Amaral-Lopes & Cavalcanti 2015Amaral-Lopes AC & Cavalcanti TB (2015) Habranthus (Amaryllidaceae) do Brasil. Rodriguésia 66: 203-220.; Guarçoni 2015Guarçoni EAE (2015) Estudos taxonômicos e de anatomia foliar em espécies de Dyckia Schult. & Schult. f. (Bromeliaceae, Pitcairnioideae). Tese de Doutorado. Universidade Federal de Viçosa, Viçosa. 175p.; Gonzaga et al. 2017Gonzaga DR, Menini Neto L & Peixoto AL (2017) Cactaceae no Parque Nacional do Itatiaia, Serra da Mantiqueira, Brasil. Rodriguésia 68: 1397-1410.).

Analysis

The following phytosociological parameters were measured for each species: absolute frequency, relative frequency, absolute dominance, relative dominance and importance value (IV). Dominance was assessed by coverage. The cover area of each species in each habitat was estimated visually by the vertical projection of the aerial parts of each species as a percentage of the total area of the plot (Mueller-Dombois & Ellenberg 1974Mueller-Dombois D & Ellenberg H (1974) Aims and methods of vegetation ecology. Wiley & Sons, New York. 547p.). Many other authors (Conceição & Giulietti 2002Conceição AA & Giulietti AM (2002) Composição florística e aspectos estruturais de campo rupestre em dois platôs do Morro do Pai Inácio, Chapada Diamantina, Bahia, Brasil. Hoehnea 29: 37-48.; Conceição & Pirani 2005Conceição AA & Pirani JR (2005) Delimitação de habitats em Campos Rupestres na Chapada Diamantina, Bahia: substratos, composição florística e aspectos estruturais. Boletim de Botânica da Universidade de São Paulo 23: 85-111.; Conceição et al. 2007Conceição AA, Giulietti AM & Meirelles ST (2007) Ilhas de vegetação em afloramentos de quartzito-arenito no Morro do Pai Inácio, Chapada Diamantina, Bahia, Brasil. Acta Botanica Brasilica 21: 335-347.; Messias et al. 2011; Gastauer et al. 2012Gastauer M, Messias MCTB & Meira-Neto JAA (2012) Floristic composition, species richness and diversity of Campo Rupestre vegetation from the Itacolomi State Park, Minas Gerais, Brazil. Environment and Natural Resources Research 2: 115-130.) have used coverage as a measure of dominance in herbaceous communities, since the many tussock of caespitose species make it difficult to assess density. In addition, cover data estimation is more independent of the plot size and can be assessed by the same way in all the life-form types, from small herbs to trees (Mueller-Dombois & Ellenberg 1974Mueller-Dombois D & Ellenberg H (1974) Aims and methods of vegetation ecology. Wiley & Sons, New York. 547p.).

The classification of species in life-forms was performed following Raunkiaer’s major classes: phanerophytes, chamaephytes, hemicryptophytes, cryptophytes and therophytes (Raunkiaer 1934Raunkiaer C (1934) The life forms of plants and statistical geography. Arno Press, Oxford. 632p.). In this way, epiphytes and lianas were grouped into phanerophytes. In our samples, the cryptophyte class was represented only by geophytes.

Data regarding the life-form of each species were used to construct floristic and vegetational spectra. The floristic spectra represent the species richness in each life-form while the vegetational spectra represent the dominance or abundance of each life-form (Mueller-Dombois & Ellenberg 1974Mueller-Dombois D & Ellenberg H (1974) Aims and methods of vegetation ecology. Wiley & Sons, New York. 547p.). Each species was assigned to a single life-form, being always considered the one in which renewing buds were less protected. To construct the floristic spectrum, each life-form was weighted by the number of species that occur in each habitat, whereas in the vegetational spectrum, each life-form was weighted by its coverage. In order to test if life-form proportions were significantly different, the biological spectra of each habitat were compared pairwise by using the G-test with Williams correction (Zar 1999Zar JH (1999) Biostatistical analysis. 4th ed. Prentice Hall, New Jersey. 663p.).

The species similarity of the habitats was also compared by using the Jaccard index and organized into a Venn diagram (Magurran 2004Magurran AE (2004) Measuring biological diversity. Blackwell Publishing, Oxford. 256p.).

Results

Floristics

In this survey, 71 vascular species (62 angiosperms and nine monilophytes) belonging to 31 families were identified (Tab. 1). The monocotyledonous families with the highest species richness were Orchidaceae (12 species), Bromeliaceae (five) and Poaceae (four). The richest families of eudicotyledons were Apocynaceae, Asteraceae (five each), Melastomataceae and Gesneriaceae (three each). Amongst the ferns, the richest families were Hymenophyllaceae and Polypodiaceae (three each).

The richest genera among angiosperms were Ditassa R.Br. and Mandevilla Lindl. (Apocynaceae), Anthurium Schott (Apocynaceae) and Vellozia Vand. (Velloziaceae), presenting two species each. Regarding the monilophytes, the richest genus was Hymenophyllum Sm. (Hymenophyllaceae), with three species.

The top-surface habitat presented 15 exclusive species while the lateral, 21. The 35 shared species indicate high similarity (49.3%) between these habitats (Fig. 3).

Phytosociological parameters

In the top outcrop surfaces, the species with the highest Importance Values (IV) were Nematanthus strigillosus (Mart.) H.E.Moore, Sinningia magnifica (Otto & A.Dietr.) Wiehler, Vellozia albiflora Pohl, Christensonella subulata (Lindl.) Szlach., Bulbophyllum weddellii (Lindl.) Rchb.f., Billbergia elegans Mart. ex Schult. & Schult.f., Pleroma heteromallum D.Don, Vriesea cf. marceloi Versieux & T.Machado and Philodendron minarum Engl. (Tab. 2). The species with the highest IV on the lateral outcrop surfaces were Barbacenia damaziana Beauverd, Vellozia albiflora, Christensonella subulata, Anthurium minarum, Ichnanthus sp., Paliavana sericiflora Benth., Matayba marginata Radlk., Panicum sp., Nematanthus strigillosus, Pleroma heteromallum and Deluciris rupestris (Ravenna) Lovo & A.Gil (Tab. 2; Fig. 4).

Biological spectra

Considering the floristic spectrum, hemicryptophyte was the predominant life-form for both (top and lateral surfaces) habitats, followed by phanerophyte, chamaephyte, geophyte and therophyte (Figs. 5-6). No significant difference was found between the floristic spectrum of the two studied habitats (G = 1.5234; d.f. = 4; p = 0.8225).

Taking into account the vegetational spectrum (Figs. 5, 7), the phytophysiognomies of the two habitats were not significantly different (G = 3.7897; g.l. = 4; p = 0.2851). Hemicryptophytes presented higher coverage in both habitats. Phanerophytes presented higher coverage in the lateral (29%), when compared with the top habitat (18%), and hemicryptophytes were more predominant in the top habitat.

Conservation

Threatened species were found in the studied area, occurring in both micro-habitats (CNCFlora 2020CNCFlora - Centro Nacional de Conservação da Flora (2020). Lista Vermelha. Available at <http://cncflora.jbrj.gov.br/portal>. Access on 15 June 2020.
http://cncflora.jbrj.gov.br/portal... ): Dyckia rariflora Schult. & Schult.f. (Bromeliaceae, Endangered), Hippeastrum morelianum Lem. (Amaryllidaceae, Vulnerable), Nematanthus strigillosus (Gesneriaceae, Near Threatened), Senecio pohlii Sch.Bip. ex Baker (Asteraceae, Near Threatened), Sinningia magnifica (Gesneriaceae, Least Concern), and Vellozia albiflora (Velloziaceae, Near Threatened).

Discussion

Plant species diversity in Campo Rupestre has been accessed at several scales (e.g., Giulietti et al. 1997Giulietti AM, Pirani JR & Harley RM (1997) Espinhaço range region. In: Davis SD, Heywood VH, Herrera-MacBryde O, Villa-Lobos J & Hamilton AC (eds.) Centres of Plant Diversity. Vol. 3. WWF & IUCN, Gland. Pp. 397-404.; Silveira et al. 2016Silveira FAO, Negreiros D, Barbosa NPU, Buisson E, Carmo FF, Carstensen DW, Conceição AA, Cornelissen TG, Echternacht L, Fernandes GW, Garcia QS, Guerra TJ, Jacobi CM, Lemos-Filho JP, Le Stradic S, Morellato LPC, Neves FS, Oliveira RS, Schaefer CE, Viana PL & Lambers H (2016) Ecology and evolution of plant diversity in the endangered Campo Rupestre: a neglected conservation priority. Plant Soil 403: 129-152.), throughout floristics, biogeography and ecology (e.g., Jacobi et al. 2007Jacobi CM, Carmo FF, Vincent RC & Stehmann JR (2007) Plant communities on ironstone outcrops: a diverse and endangered Brazilian ecosystem. Biodiversity and Conservation 16: 2185-2200.; Messias et al. 2011Messias MCTB, Leite MGP, Meira-Neto JAA & Kozovits AR (2011) Life-form spectra of quartzite and itabirite rocky outcrop sites, Minas Gerais, Brazil. Biota Neotropica 11: 255-268.; Mota et al. 2018Mota GM, Luz GR, Mota NM, Coutinho ES, Veloso MDM, Fernandes GM & Nunes YRF (2018) Changes in species composition, vegetation structure, and life forms along an altitudinal gradient of rupestrian grasslands in south-eastern Brazil. Flora 238: 32-42.), demonstrating the role of micro-habitat and soil structure, among others (e.g., Conceição & Pirani 2005Conceição AA & Pirani JR (2005) Delimitação de habitats em Campos Rupestres na Chapada Diamantina, Bahia: substratos, composição florística e aspectos estruturais. Boletim de Botânica da Universidade de São Paulo 23: 85-111.; Carmo et al. 2016Carmo FF, Campos IC & Jacobi CM (2016) Effects of fine-scale surface heterogeneity on rock outcrop plant community structure. Journal of Vegetation Science 27: 50-59.). Microenvironmental heterogeneity may contribute to species coexistence and to the extraordinary richness of the Campo Rupestre.

Floristic patterns

The main families of the study area exhibit great representativeness in other Campo Rupestre of the Quadrilátero Ferrífero (Messias et al. 2011Messias MCTB, Leite MGP, Meira-Neto JAA & Kozovits AR (2011) Life-form spectra of quartzite and itabirite rocky outcrop sites, Minas Gerais, Brazil. Biota Neotropica 11: 255-268., 2012Messias MCTB, Leite MGP, Meira-Neto JAA & Kozovits AR (2012) Fitossociologia de campos rupestres quartzíticos e ferruginosos no Quadrilátero Ferrífero, Minas Gerais. Acta Botanica Brasilica 26: 230-242.; Oliveira et al. 2018Oliveira PA, Pereira IM, Messias MCTB, Oliveira MLR, Pinheiro AC, Machado ELM & Oliveira JLA (2018) Phytosociology of the herbaceous-subshrub layer of a rupestrian complex in Serra do Espinhaço, Brazil. Acta Botanica Brasilica 32: 141-149.) and on the septentrional Espinhaço (Conceição & Giulietti 2002Conceição AA & Giulietti AM (2002) Composição florística e aspectos estruturais de campo rupestre em dois platôs do Morro do Pai Inácio, Chapada Diamantina, Bahia, Brasil. Hoehnea 29: 37-48.; Conceição et al. 2007Conceição AA, Giulietti AM & Meirelles ST (2007) Ilhas de vegetação em afloramentos de quartzito-arenito no Morro do Pai Inácio, Chapada Diamantina, Bahia, Brasil. Acta Botanica Brasilica 21: 335-347.), and are also frequent in granitic (Caiafa & Silva 2005; Porembski 2007Porembski S (2007) Tropical inselbergs: habitat types, adaptive strategies and diversity patterns. Revista Brasileira de Botânica 30: 579-586.; Couto et al. 2017Couto DR, Francisco TM, Manhães VC, Dias HM & Pereira MCA (2017) Floristic composition of a Neotropical inselberg from Espírito Santo state, Brazil: an important area for conservation. Check List 13: 1-12.; Paula et al. 2017Paula LFA, Mota NFO, Viana PL & Stehmann JR (2017) Floristic and ecological characterization of habitat types on an inselberg in Minas Gerais, southeastern Brazil. Acta Botanica Brasilica 31: 199-211.) and carbonatic rocks (e.g., Melo et al. 2013Melo PHAD, Lombardi JA, Salino A & Carvalho DAD (2013) Composição florística de angiospermas no carste do Alto São Francisco, Minas Gerais, Brasil. Rodriguésia 64: 29-36.). The richness and predominance of monocots found here corroborates the pattern described for Neotropical rocky outcrops (Ibisch et al. 1995Ibisch PL, Rauer G, Rudolph D & Barthlott W (1995) Floristic, biogeographical, and vegetational aspects of Pre-Cambrian rock outcrops (inselbergs) in eastern Bolivia. Flora 190: 299-314.; Porembski et al. 1998Porembski S, Martinelli G, Ohlemüller R & Barthlott W (1998) Diversity and ecology of saxicolous vegetation mats on inselbergs in the Brazilian Atlantic rainforest. Diversity and Distributions 4: 107-119.; Conceição et al. 2007Conceição AA, Giulietti AM & Meirelles ST (2007) Ilhas de vegetação em afloramentos de quartzito-arenito no Morro do Pai Inácio, Chapada Diamantina, Bahia, Brasil. Acta Botanica Brasilica 21: 335-347.).

Epilithic Orchidaceae, Bromeliaceae and Araceae species were frequent in the top surface habitat. These families present strategies for maintaining water balance, like water-storing pseudobulbs in Orchidaceae (Santana et al. 2016Santana KC, Souza IM, Miranda LDP & Funch LS (2016) Phenodynamics of five orchids species growing on rock outcrops in the Chapada Diamantina Mountains in northeastern Brazil. Acta Botanica Brasilica 30: 508-513.), tank-leaves (Males & Griffiths 2017Males J & Griffiths H (2017) Functional types in the Bromeliaceae: relationships with drought-resistance traits and bioclimatic distributions. Functional Ecology 31: 1868-1880.) or foliar water uptake (Berry et al. 2019Berry ZC, Emery NC, Gotsch SG & Goldsmith GR (2019) Foliar water uptake: processes, pathways, and integration into plant water budgets. Plant, Cell and Environment 42: 410-423.) that enable them to occupy xeric environments such as bare rock (Porembski 2007Porembski S (2007) Tropical inselbergs: habitat types, adaptive strategies and diversity patterns. Revista Brasileira de Botânica 30: 579-586.).

In the heterogeneous environments of the Campo Rupestre, habitats suitable for growth and survival of species are sparsely distributed. Within this landscape, there is low probability for seeds to be dispersed to patches better than the parental one (Elmqvist & Cox 1996Elmqvist T & Cox PA (1996) The evolution of vivipary in flowering plants. Oikos 77: 3-9.). Thus, clonal growth, common in hemicryptophytic species, may be an advantageous adaptation. In addition, vegetative organs involved in clonal reproduction and storage, like rhizomes, may enhance resistance to fire and drought as well as favor regrowth at favorable seasons (Grace 1993Grace JB (1993) The adaptive significance of clonal reproduction in angiosperms: an aquatic perspective. Aquatic Botany 44: 159-180.).

Desiccation-tolerant species were also present, as Vellozia albiflora Pohl (Alcantara et al. 2015Alcantara S, Mello-Silva R, Teodoro GS, Drequeceler K, Ackerly DD & Oliveira RS (2015) Carbon assimilation and habitat segregation in resurrection plants: a comparison between desiccation- and non-desiccation-tolerant species of Neotropical Velloziaceae (Pandanales). Functional Ecology 29: 1499-1512.), which occurs at top and lateral surfaces, often forming monocotyledonous mats with non-desiccation-tolerant Poaceae species in both habitats. A desiccation-tolerant genus of monilophyte was also present in both habitats [Lytoneuron lomariaceum (Klotzsch) Yesilyurt]. Dried leaves resulting from desiccation, together with the growth of vegetative organs of monocot-mats, mostly hemicryptophytes, promote litter accumulation and soil water storage, thus creating a favorable environment for the development of other plant species (Burbanck & Phillips 1983Burbanck M & Phillips D (1983) Evidence of plant succession on granite outcrops of the Georgia Piedmont. American Midland Naturalist 109: 94-104.; Tyler 1997Tyler G (1997) Soil chemistry and plant distributions in rock habitats of southern Sweden. Nordic Journal of Botany 16: 609-635.).

Monocots, being non-woody plants, predominate in open environments such as Campo Rupestre (Burkart 1975Burkart A (1975) Evolution of grasses and grasslands in South America. Taxon 24: 53-66.). Nevertheless, eudicotyledons present features that allow them to occupy shallow depressions and crevices on exposed and shaded habitats of the outcrop. Amongst the eudicots with higher Importance Values (IV), we observed species with bulbs (e.g., Sinningia magnifica); water-storing leaves (e.g., Nematanthus strigillosus); and the metallophyte Pleroma heteromallum.

Among the eudicots, Clusia L. plays an important role as a nurse plant when growing in stressful, sandy habitats at the periphery of the Atlantic rainforest complex and in ironstone outcrops, together with bromeliads (Scarano 2002Scarano FR (2002) Structure, function and floristic relationships of plant communities in stressful habitats marginal to the brazilian Atlantic Rainforest. Annals of Botany 90: 517-524.; Jacobi et al. 2007Jacobi CM, Carmo FF, Vincent RC & Stehmann JR (2007) Plant communities on ironstone outcrops: a diverse and endangered Brazilian ecosystem. Biodiversity and Conservation 16: 2185-2200.). This ecological role possibly occurs for Clusia mexiae P.F.Stevens in our survey area, as seedlings of other plants species were observed under its canopy.

The top habitat is less species rich than the lateral, with most species presenting adaptations to xeric environment. However, in shaded spots of the top habitat, species as Hillia parasitica Jacq. and Coccocypselum erythrocephalum Cham. & Schltdl. were found, which are typical from montane cloud Atlantic Forest understory (Costa & Mamede 2002Costa CB & Mamede MCH (2002) Sinopse do gênero Coccocypselum P. Browne (Rubiaceae) no estado de São Paulo, Brasil. Biota Neotropica 2: 1-14.; Oliveira 2010Oliveira CT (2010) A flora do complexo rupestre altomontano da Serra do Caraça (Minas Gerais) e suas relações fitogeográficas. Tese de Doutorado. Universidade Federal de Minas Gerais, Belo Horizonte. 96p.). These shaded micro-habitats also shelter Peperomia tetraphylla (G.Forst.) Hook. & Arn., a species noted in the literature as an epiphyte (Mucunguzi 2007Mucunguzi P (2007) Diversity and distribution of vascular epiphytes in the forest lower canopy in Kibale National Park, western Uganda. African Journal of Ecology 45: 120-125.; Alves et al. 2008Alves RJV, Kolbek J & Becker J (2008) Vascular epiphyte vegetation in rocky savannas of southeastern Brazil. Nordic Journal of Botany 26: 101-117.; Ceballos et al. 2016Ceballos SJ, Chacoff NP & Malizia A (2016) Interaction network of vascular epiphytes and trees in a subtropical forest. Acta Oecologica 77: 152-159. ). In addition, the genus Peperomia was described by Gröger & Huber (2007)Gröger A & Huber O (2007) Rock outcrop habitats in the Venezuelan Guayana lowlands: their main vegetation types and floristic components. Revista Brasileira de Botânica 30: 599-609. as presenting shade-tolerant lithophyte species. Therefore, the typical, more xeric conditions of the top habitat, may be attenuated if the surrounding forest shadows the outcrops.

The totality of species shared between both habitats occurs in other Campo Rupestre localities (Giulietti et al. 1987Giulietti AM, Menezes NL, Pirani JR, Meguro M & Wanderley MGL (1987) Flora da Serra do Cipó, MG: caracterização e lista das espécies. Boletim de Botânica da Universidade de São Paulo 9: 1-151.; Oliveira 2010Oliveira CT (2010) A flora do complexo rupestre altomontano da Serra do Caraça (Minas Gerais) e suas relações fitogeográficas. Tese de Doutorado. Universidade Federal de Minas Gerais, Belo Horizonte. 96p.; Gastauer et al. 2012Gastauer M, Messias MCTB & Meira-Neto JAA (2012) Floristic composition, species richness and diversity of Campo Rupestre vegetation from the Itacolomi State Park, Minas Gerais, Brazil. Environment and Natural Resources Research 2: 115-130.). The higher habitat heterogeneity of lateral surfaces favored not only rupicolous or saxicolous species, but also terricolous species of distinct life-forms [e.g., Calea clematidea Baker, Dioscorea debilis Uline ex. R.Knuth, Leandra aurea Cogn. and Monteverdia imbricata (Mart. ex. Reissek) Biral]. The occurrence of soil accumulations in some places like the vertical fissures in the rocks of the lateral habitat allows the rooting of taller species like phanerophytes (Giulietti et al. 1997Giulietti AM, Pirani JR & Harley RM (1997) Espinhaço range region. In: Davis SD, Heywood VH, Herrera-MacBryde O, Villa-Lobos J & Hamilton AC (eds.) Centres of Plant Diversity. Vol. 3. WWF & IUCN, Gland. Pp. 397-404.; Jacobi et al. 2007Jacobi CM, Carmo FF, Vincent RC & Stehmann JR (2007) Plant communities on ironstone outcrops: a diverse and endangered Brazilian ecosystem. Biodiversity and Conservation 16: 2185-2200.).

Phytosociological parameters

The predominant life-forms, hemicryptophyte, phanerophyte and chamaephyte, observed in our study are well represented in other studies regarding biological spectra of outcrops in different lithotypes of Campo Rupestre, inselbergs and other montane grasslands. The lower proportion of therophytes and geophytes has also been found in the biological spectra of other rocky outcrop sites (Vitta 1995Vitta FA (1995) Composição florística e ecologia de comunidades campestres na Serra do Cipó, Minas Gerais. Dissertação de Mestrado. Universidade de São Paulo, São Paulo. 111p.; Meirelles et al. 1999Meirelles ST, Pivello VR & Joly CA (1999) The vegetation of granite rock outcrops in Rio de Janeiro, Brazil, and the need for its protection. Environonmental Conservation 26: 10-20.; Conceição & Giulietti 2002Conceição AA & Giulietti AM (2002) Composição florística e aspectos estruturais de campo rupestre em dois platôs do Morro do Pai Inácio, Chapada Diamantina, Bahia, Brasil. Hoehnea 29: 37-48.; Caiafa & Silva 2005Caiafa AN & Silva A (2005) Composição florística e espectro biológico de um Campo de Altitude no Parque Estadual da Serra do Brigadeiro, Minas Gerais. Rodriguésia 56: 163-173.; Jacobi et al. 2007Jacobi CM, Carmo FF, Vincent RC & Stehmann JR (2007) Plant communities on ironstone outcrops: a diverse and endangered Brazilian ecosystem. Biodiversity and Conservation 16: 2185-2200.; Ribeiro et al. 2007Ribeiro KT, Medina BMO & Scarano FR (2007) Species composition and biogeographic relations of the rock outcrop flora on the high plateau of Itatiaia, SE-Brazil. Revista Brasileira de Botânica 30: 623-639.; Messias et al. 2011Messias MCTB, Leite MGP, Meira-Neto JAA & Kozovits AR (2011) Life-form spectra of quartzite and itabirite rocky outcrop sites, Minas Gerais, Brazil. Biota Neotropica 11: 255-268.; Paula et al. 2017Paula LFA, Mota NFO, Viana PL & Stehmann JR (2017) Floristic and ecological characterization of habitat types on an inselberg in Minas Gerais, southeastern Brazil. Acta Botanica Brasilica 31: 199-211.).

The low nutrient budgets on rocky outcrop substrates do not favor the fast growth and establishment of therophytes (Ribeiro et al. 2007Ribeiro KT, Medina BMO & Scarano FR (2007) Species composition and biogeographic relations of the rock outcrop flora on the high plateau of Itatiaia, SE-Brazil. Revista Brasileira de Botânica 30: 623-639.). The low frequency of cryptophytes in rocky outcrops is due to their characteristic underground systems, which need soil to develop (Raunkiaer 1934Raunkiaer C (1934) The life forms of plants and statistical geography. Arno Press, Oxford. 632p.).

The biological spectra and the species with higher IV values for top and lateral habitats showed that hemicryptophytes were common at both habitats, similar to several other studies of rocky outcrops (Vitta 1995Vitta FA (1995) Composição florística e ecologia de comunidades campestres na Serra do Cipó, Minas Gerais. Dissertação de Mestrado. Universidade de São Paulo, São Paulo. 111p.; Conceição & Giulietti 2002Conceição AA & Giulietti AM (2002) Composição florística e aspectos estruturais de campo rupestre em dois platôs do Morro do Pai Inácio, Chapada Diamantina, Bahia, Brasil. Hoehnea 29: 37-48.; Caiafa & Silva 2005Caiafa AN & Silva A (2005) Composição florística e espectro biológico de um Campo de Altitude no Parque Estadual da Serra do Brigadeiro, Minas Gerais. Rodriguésia 56: 163-173.; Ribeiro et al. 2007Ribeiro KT, Medina BMO & Scarano FR (2007) Species composition and biogeographic relations of the rock outcrop flora on the high plateau of Itatiaia, SE-Brazil. Revista Brasileira de Botânica 30: 623-639.). The environmental constraints of rocky outcrops, especially the xeric conditions, favor the prevalence of hemicryptophytes, which are dominant in both outcrop habitats.

Woody species like chamaephytes and phanerophytes stood out in the lateral habitat when compared with the top habitat. They are represented mainly by shrub and subshrub species like Paliavana sericiflora, Matayba marginata and Pleroma heteromallum. The presence of organic and fibrous soil in lateral depressions and the shady micro-habitats may explain the higher phanerophyte coverage of this habitat. However, many of the phanerophytes counted were lianas and epiphytes (according to Raunkiaer 1934), which increased the proportion of this life-form for this habitat.

Other studies in rocky outcrops also found chamaephyte as a dominant class (Conceição & Giulietti 2002Conceição AA & Giulietti AM (2002) Composição florística e aspectos estruturais de campo rupestre em dois platôs do Morro do Pai Inácio, Chapada Diamantina, Bahia, Brasil. Hoehnea 29: 37-48.; Conceição et al. 2007Conceição AA, Giulietti AM & Meirelles ST (2007) Ilhas de vegetação em afloramentos de quartzito-arenito no Morro do Pai Inácio, Chapada Diamantina, Bahia, Brasil. Acta Botanica Brasilica 21: 335-347.). Aside from the environmental conditions that shape the distribution of plant life-forms, distinct methods have been used to perform these studies. The lack of a clear pattern to measure life-form biological spectra makes comparison unequitable, although there are some general tendencies in studies of life-forms among rocky outcrops.

Another outstanding result of this study was that the lateral surface stood out from the top surface in some parameters regarding species richness. Even though the lateral surface presented half of the total area of the top surface, it showed higher total species richness (56), a higher richness of phanerophytes and an equitable richness of hemicryptophytes. These results reinforce the importance of micro-habitat heterogeneity in the maintenance of saxicolous flora richness and diversity.

Despite the striking differences of micro-habitat composition of the two habitats studied, they presented analogous floristic spectra. Thus, the species richness within each life-form is similar. The redundancy of species that play the same role in processes that are fundamental to the maintenance of biodiversity ensures that if one of them is locally reduced, it may be replaced by similar forms, giving continuity to the ecological function of the whole community.

The floristic spectrum represents the taxonomic aspects of the flora. However, in ecological investigations, assessing the vegetation response with a description of the physiognomy complements the floristic data. The floristic spectra differed from vegetational spectra in both habitats (p < 0.05). The vegetational spectra revealed that chamaephytes play an important role in Campo Rupestre vegetation, even though their species richness was not so expressive. This result offers evidence that life-form coverage reflects the functional trait preference to the environment.

Quartzitic Campo Rupestre in a studied site in Chapada Diamantina (northern Espinhaço Range) presented a higher proportion of phanerophytes (Conceição & Pirani 2005Conceição AA & Pirani JR (2005) Delimitação de habitats em Campos Rupestres na Chapada Diamantina, Bahia: substratos, composição florística e aspectos estruturais. Boletim de Botânica da Universidade de São Paulo 23: 85-111.), as well as near our study site in Ouro Preto (Messias et al. 2011Messias MCTB, Leite MGP, Meira-Neto JAA & Kozovits AR (2011) Life-form spectra of quartzite and itabirite rocky outcrop sites, Minas Gerais, Brazil. Biota Neotropica 11: 255-268.). According to Mota et al. (2018)Mota GM, Luz GR, Mota NM, Coutinho ES, Veloso MDM, Fernandes GM & Nunes YRF (2018) Changes in species composition, vegetation structure, and life forms along an altitudinal gradient of rupestrian grasslands in south-eastern Brazil. Flora 238: 32-42., the proportion of hemicryptophytes increases and that of woody species decreases with increasing altitude. Indeed, in both studies (Conceição & Pirani 2005Conceição AA & Pirani JR (2005) Delimitação de habitats em Campos Rupestres na Chapada Diamantina, Bahia: substratos, composição florística e aspectos estruturais. Boletim de Botânica da Universidade de São Paulo 23: 85-111.; Messias et al. 2011Messias MCTB, Leite MGP, Meira-Neto JAA & Kozovits AR (2011) Life-form spectra of quartzite and itabirite rocky outcrop sites, Minas Gerais, Brazil. Biota Neotropica 11: 255-268.), hemicryptophytes were more frequent in higher altitudes. The predominance of hemicryptophytes in our study may be partly explained by a higher altitude of our study site. These peculiarities of Campo Rupestre spectra give evidence of how complex the functionality of this ecosystem is and the importance of its conservation as a whole.

Endemism

The majority (81%) of endemic species of the Quadrilátero Ferrífero occurs in Campo Rupestre, 45% of them in quartzitic outcrops (Borsali 2012Borsali E (2012) A Flora Vascular endêmica do Quadrilátero Ferrífero, Minas Gerais, Brasil: levantamento das espécies e padrões de distribuição geográfica. Dissertação de Mestrado. Universidade Federal de Minas Gerais, Belo Horizonte. 189p.). In the Quadrilátero Ferrífero there is a great number of plant species which are known by their type population only and are thus considered micro-endemic. Heterogeneous sampling efforts among distinct areas may hamper the evaluation of the conservation status of these species, since populations may be undersampled (Madeira et al. 2008Madeira JA, Ribeiro KT, Oliveira MJR & Paiva CL (2008) Distribuição espacial do esforço de pesquisa biológica na Serra do Cipó, Minas Gerais: subsídios ao manejo das unidades de conservação da região. Megadiversidade 4: 257-271.; Borsali 2012Borsali E (2012) A Flora Vascular endêmica do Quadrilátero Ferrífero, Minas Gerais, Brasil: levantamento das espécies e padrões de distribuição geográfica. Dissertação de Mestrado. Universidade Federal de Minas Gerais, Belo Horizonte. 189p.; Le Stradic et al. 2015Le Stradic S, Buisson E & Fernandes GW (2015) Vegetation composition and structure of some neotropical mountain grasslands in Brazil. Journal of Mountain Science 12: 864-877.; speciesLink 2019SpeciesLink (2019) Available at <http://www.splink.org.br/.>. Access on 20 April 2019.
http://www.splink.org.br/... ).

The type population of Barbacenia damaziana (Velloziaceae) is from the Itacolomi State Park, very close to our study area (Ouro Preto, Minas Gerais state), and the species occurrence is limited to Ouro Preto (Borsali 2012Borsali E (2012) A Flora Vascular endêmica do Quadrilátero Ferrífero, Minas Gerais, Brasil: levantamento das espécies e padrões de distribuição geográfica. Dissertação de Mestrado. Universidade Federal de Minas Gerais, Belo Horizonte. 189p.). Despite its narrow occurrence, the conservation status of this species was not yet formally evaluated (CNCFlora 2020CNCFlora - Centro Nacional de Conservação da Flora (2020). Lista Vermelha. Available at <http://cncflora.jbrj.gov.br/portal>. Access on 15 June 2020.
http://cncflora.jbrj.gov.br/portal... ). This evaluation should be prioritized as the southern Espinhaço Mountain Range presents endemism rates of 70% for Velloziaceae (Mello-Silva 2009Mello-Silva R (2009) Flora de Grão-Mogol, Minas Gerais: Velloziaceae. Boletim de Botânica da Universidade de São Paulo 27: 109-118.) and micro-endemic species are more susceptible to extinction.

Bromeliaceae has many endemic species in the Quadrilátero Ferrífero, among which the xeromorphic Hoplocryptanthus schwackeanus was recorded at the study site. Vriesea marceloi is known from the Serra do Caraça only, about 25 km from the site studied here (Versieux & Machado 2012Versieux LM & Machado TM (2012) A new ornithophilous yellow-flowered Vriesea (Bromeliaceae) from Serra do Caraça, Minas Gerais, Brazil. Phytotaxa 71: 36-41.), and possible occurs in the study site; unfortunately, it was not possible to confirm the identification for the lack of the diagnostic organs on the collected specimen.

Mining and natural revegetation

Mining negatively impacts the habitat and biodiversity of rock vegetation, since outcrops are broken into smaller boulders, turning the ecosystem into a homogeneous, soilless environment (Kolbek & Alves 2008Kolbek J & Alves R (2008) Impacts of cattle, fire and wind in rocky savannas, southeastern Brazil. Acta Universitatis Carolinae, Environmentalica 22: 111-130.; Bétard 2013Bétard F (2013) Patch-scale relationships between geodiversity and biodiversity in hard rock quarries: case study from a disused quartzite quarry in NW France. Geoheritage 5: 59-71.). The loss of micro-habitats decreases the richness of native species and increases colonization by invasive species (Holmes & Richardson 1999Holmes PM & Richardson DM (1999) Protocols for restoration based on recruitment dynamics, community structure, and ecosystem function: perspectives from South African fynbos. Restoration Ecology 7: 215-230.). Due to their life-history and functional traits, invasive and r-strategist species tend to begin the colonization of post-mining areas going through natural revegetation (Romoff 1986Romoff N (1986) Revegetation of disturbed areas in the fynbos biome - the current status. Veld & Flora 72: 46-48.; Řehounková & Prach 2010Řehounková K & Prach K (2010) Life-history traits and habitat preferences of colonizing plant species in long-term spontaneous succession in abandoned gravel-sand pits. Basic and Applied Ecology 11: 45-53.). Revegetation with native species requires dedicated management (Romoff 1986Romoff N (1986) Revegetation of disturbed areas in the fynbos biome - the current status. Veld & Flora 72: 46-48.; Silc 2010Silc U (2010) Synanthropic vegetation: pattern of various disturbances on life history traits. Acta Botanica Croatica 69: 215-227.).

In our survey area we recorded several species described in the literature as important to the restoration of degraded areas such as Anthurium minarum, Leandra aurea, Pleroma heteromallum, Acianthera teres (Lindl.) Luer, Epidendrum secundum Jacq., Gomesa warmingii (Rchb.f.) M.W.Chase & N.H.Williams, Vellozia albiflora and Vellozia compacta (Jacobi et al. 2008Jacobi CM, Carmo FF & Vincent RC (2008) Estudo fitossociológico de uma comunidade vegetal sobre canga como subsídio para a reabilitação de áreas mineradas no Quadrilátero Ferrífero, MG. Revista Árvore 32: 345-353.; Lima et al. 2016Lima CT, Furtini Neto AE, Giulietti AM, Mota NFO, Braga RP & Viana PL (2016) Guia de plantas para a recuperação de áreas degradadas nas cangas do Quadrilátero Ferrífero de Minas Gerais. Fundação Brasil Cidadão, Fortaleza. 179p.). These species present features such as clonal growth and metal-tolerance and should be considered for ex situ cultivation in order to revegetate nearby areas undergoing quartzite exploitation.

Nine quartzitic outcrops were studied here at single rock-blocks, a level of focus that revealed the complexity of Campo Rupestre at meter-scale. In each block two habitats were recognized: the top surface with bare rock, small pools and cracks, shallow depressions and stacked boulders; and the lateral surface with cavities, crevices and cracks, more soil accumulation, and more shelter. Our results point out that more than 50% of the species are unique to each of these habitats, despite the floristic and vegetation spectra being statistically similar. The dominance of hemicryptophytes, such as epilithic or saxicolous species, shows them to be well adapted to the environmental constraints of the outcrops. Chamaephytes and phanerophytes were slightly more dominant in the lateral habitat, with a higher proportion in clefts and crevices, which allow for the development of deeper root systems. Our results contribute to the understanding of the influences of habitat heterogeneity on the plant community, in terms of floristic, vegetational and life-form aspects. Restoration strategies should take into account plant preferences regarding the micro-habitats created by the relief of rock-blocks.

Acknowledgements

We would like to thank the Universidade Federal de Ouro Preto - Minas Gerais and the Herbário Professor José Badini - OUPR, for logistical support. We also thank Rodrigo Alves, for providing high quality photos for this study; Scott Heald, for the English revision; and editor and referees, for improvements on early versions of this manuscript. This research was carried out with permission from the Instituto Estadual de Florestas - Minas Gerais (IEF - MG, 010/2018). The work was led by the first author as an undergraduate student, as part of the requirements for obtaining the academic degree on Biological Sciences at UFOP, under the supervision of Dr. Livia Echternacht and co-supervision of Dr. Maria Cristina T.B. Messias. Funding was partially provided by UFOP (Pró-Reitoria de Pesquisa, process 23109.003268/2017-47) and FAPEMIG (CRA-01060-14).

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