Survival of Saplings in Recovery of Riparian Vegetation of Pandeiros River (MG)

Fagundes, Nathalle Cristine Alencar; Braga, Lílian de Lima; Silva, Wesley Alves; Coutinho, Chirley Alves; Neves, Walter Viana; Souza, Ricardo Almeida de; Veloso, Maria das Dores Magalhães; Nunes, Yule Roberta Ferreira

doi:10.1590/2179-8087.021215

ABSTRACT

This study monitored the survival of saplings planted according to different recovery models in a riparian forest of the Pandeiros river (Januária, MG). The models consisted of planting the saplings in lines of 2 or 4 m with presence (T2S and T4S, respectively) or absence of direct seeding (T2 and T4, respectively). We planted 16,259 saplings of 17 botanical families, 32 genera and 33 species. The saplings, in general, presented a survival rate after one year of 34.4% (±1.8). The species with highest survival rates were Jacaranda brasiliana, with 85.0% (±13.5) of survival, Anadenanthera colubrina, with 70.1% (±7.0), and Triplaris gardneriana, with 69.3% (±9.1). Survival did not vary between the models tested, probably due to the short evaluation period (12 months).

Keywords:
recovery models; planting of saplings; direct seeding

1. INTRODUCTION

The Cerrado, a region of considerable biological diversity, is identified as one of the richest and most threatened ecosystems in the world, with a large number of restricted and specialized endemic species (about 44% of the flora), which are therefore susceptible to extinction (Scariot et al., 2005Scariot A, Souza-Silva JC, Felfili JM. (Org.). Cerrado: ecologia, biodiversidade e conservação. Brasília: Ministério do Meio Ambiente; 2005.). This biome is considered a conservation priority for global biodiversity, since 55% of its original area was deforested or transformed by human action (Klink & Machado, 2005Klink CA, Machado RB. A conservação do Cerrado brasileiro. Megadiversidade 2005; 1: 148-155.). The relatively flat surface and the presence of fertile soils promotes the highest and fastest rates of agricultural growth in Brazil, being considered the last agricultural frontier of the country, attracting a significant part of the national agribusiness (Klink & Machado, 2005Klink CA, Machado RB. A conservação do Cerrado brasileiro. Megadiversidade 2005; 1: 148-155.).

In this context, the riverine formations (ciliar, riparian or gallery forests) that occur in the Cerrado show the effects of this agricultural expansion and represent environments significantly disturbed and degraded by anthropic action. Riparian forests protect and maintain water resources, since they are formations associated with watercourses, standing out for their richness and genetic diversity and acting as a physical barrier between terrestrial and aquatic systems (Hughes et al., 2008Hughes FMR, Moss T, Richards KS. Uncertainty in riparian and floodplain restoration. In: Darby S, Sear D. River restoration: managing the uncertainty in restoring physical habitat. Chichester: Wiley; 2008.; Roni & Beechie, 2013Roni P, Beechie T. Stream and watershed restoration. Oxford: Wiley-Blackwell; 2013.). These forests act to filter water flowing into the watercourses along which they are found, developing conditions conducive to infiltration and significantly reducing the possibility of water contamination by sediment, fertilizer residues and agricultural pesticides (Ribeiro & Schiavini, 1998Ribeiro JF, Schiavini I. Recuperação de matas de galeria: integração entre a oferta ambiental e a biologia das espécies. In: Ribeiro JF. Cerrado: matas de galeria. Planaltina: EMBRAPA-CPAC; 1998.; Roni & Beechie, 2013Roni P, Beechie T. Stream and watershed restoration. Oxford: Wiley-Blackwell; 2013.). Additionally, they are important ecological corridors for the movement of fauna and gene flows (Martins, 2007Martins SV. Recuperação de matas ciliares. Viçosa: Aprenda Fácil; 2007.). Thus, given these particular characteristics that highlight their importance, forests bordering streams and springs, are protected by federal legislation and are considered Permanent Preservation Areas (PPAs), according to the Forest Code, Law (number 12.651 of May 25^th 2012), that is, an ecological reserve that cannot undergo alteration, and whose vegetation must remain intact in its original state (Brasil, 2012Brasil. Lei Federal nº 12.651, de 25 de maio de 2012. Revoga as Leis nº 4.771, de 15 de setembro de 1965, e 7.754, de 14 de abril de 1989, e a Medida Provisória no 2.166-67, de 24 de agosto de 2001; e Institui o Novo Código Florestal. Diário Oficial da República Federativa do Brasil, Brasília, DF (2012).).

Even when protected by law, PPAs are not exempt from the impacts of human activity, both in the surroundings and in loco (Rezende, 2004Rezende RP. Recuperação de matas de galeria em propriedades rurais do Distrito Federal e entorno [dissertação]. Brasília: Universidade de Brasília; 2004.). In this sense, the recovery of degraded areas has become a priority to combat the environmental degradation processes to which natural areas are exposed (Martins, 2007Martins SV. Recuperação de matas ciliares. Viçosa: Aprenda Fácil; 2007.). However, to recover degraded areas, it is necessary to establish a model developed from studies of phenology, details regarding the biology and germination of species, and growth analysis, amongst others, that are fundamental for vegetation rehabilitation (Hughes et al., 2008Hughes FMR, Moss T, Richards KS. Uncertainty in riparian and floodplain restoration. In: Darby S, Sear D. River restoration: managing the uncertainty in restoring physical habitat. Chichester: Wiley; 2008.; Andel et al., 2012Andel JV, Grootjans AP, Aronson J. Unifying concepts. In: Andel JV, Aronson J, editors. Restoration ecology: the new frontier. Chichester: Wiley-Blackwell; 2012. p. 9-22.). Thus, techniques in combination such as sapling planting and direct seeding, which aim to guard against soil erosion and assist local revegetation, can offer good outcomes, which help to ensure the successful recovery of degraded areas (Martins, 2007Martins SV. Recuperação de matas ciliares. Viçosa: Aprenda Fácil; 2007.; Roni & Beechie, 2013Roni P, Beechie T. Stream and watershed restoration. Oxford: Wiley-Blackwell; 2013.).

In order to restore vegetation and ecological processes, several models for the recovery of degraded areas have been tested (Andel et al., 2012Andel JV, Grootjans AP, Aronson J. Unifying concepts. In: Andel JV, Aronson J, editors. Restoration ecology: the new frontier. Chichester: Wiley-Blackwell; 2012. p. 9-22.; Pereira & Rodrigues, 2012Pereira JS, Rodrigues SC. Crescimento de espécies arbóreas utilizadas na recuperação de área degradada. Caminhos de Geografia 2012; 13(41): 102-110.). Most studies are based on successional models (McClain et al., 2011McClain DC, Holl DK, Wood DM. Successional Models as Guides for Restoration of Riparian Forest Understory. Restoration Ecology 2011; 19(2): 280-289. http://dx.doi.org/10.1111/j.1526-100X.2009.00616.x.
http://dx.doi.org/10.1111/j.1526-100X.20... ) with species of different ecological groups (Gonçalves et al., 2005;Gonçalves RMG, Giannotti E, Giannotti JG, Silva AA. Aplicação de modelo de revegetação em áreas degradadas, visando à restauração ecológica da microbacia do córrego da Fazenda Itaqui, no município de Santa Gertrudes, SP. Revista Instituto Florestal 2005; 17(1): 73-95. Pereira & Rodrigues, 2012Pereira JS, Rodrigues SC. Crescimento de espécies arbóreas utilizadas na recuperação de área degradada. Caminhos de Geografia 2012; 13(41): 102-110.) or by facilitating species (Beltrame & Rodrigues, 2008Beltrame TP, Rodrigues E. Comparação de diferentes densidades de feijão guandu (Cajanus cajan (L.). Millsp.) na restauração florestal de uma área de reserva legal no Pontal do Paranapanema, SP. Scientia Florestalis 2008; 36: 317-327.). However, according to Tilman (1988)Tilman D. Plant strategies and the dynamics and structure of plant communities (Monograph). Princeton: Princeton University Press; 1988., in nutrient-deficient environments (such as disturbed and degraded environments), competition between species may be a determining factor for their establishment. Despite the importance of competition for seedling/sapling survival and growth, studies with recovery models of degraded areas based on distances between saplings to test the effect of competition, are scarce.

The Environmental Protection Area (EPA) of Pandeiros River was established by Law 11,901 of September 1^st 1995, with the objective of conserving the water resources and significant biological diversity present at the site (Nunes et al., 2009Nunes YRF, Azevedo IFP, Neves WV, Veloso MDM, Souza RA, Fernandes GW. Pandeiros: o Pantanal Mineiro. MG. Biota 2009; 2(2): 4-17.). The Pandeiros River EPA is located in northern Minas Gerais, an ecotonal area between the Cerrado and Caatinga domains, forms a junction between riparian forest, dry forest, cerrado (savanna) and veredas (palm swamps), occurring in alternating areas that may show abrupt vegetation changes within relatively small areas (Nunes et al., 2009Nunes YRF, Azevedo IFP, Neves WV, Veloso MDM, Souza RA, Fernandes GW. Pandeiros: o Pantanal Mineiro. MG. Biota 2009; 2(2): 4-17.). Among these physiognomies, the riparian forests, characterized by accompanying springs and water courses (Andel et al., 2012Andel JV, Grootjans AP, Aronson J. Unifying concepts. In: Andel JV, Aronson J, editors. Restoration ecology: the new frontier. Chichester: Wiley-Blackwell; 2012. p. 9-22.; Roni & Beechie, 2013Roni P, Beechie T. Stream and watershed restoration. Oxford: Wiley-Blackwell; 2013.) form ecological corridors that highlight the botanical diversity present, as well as protecting and sheltering terrestrial and aquatic fauna (Roni & Beechie, 2013Roni P, Beechie T. Stream and watershed restoration. Oxford: Wiley-Blackwell; 2013.).

Despite the protection afforded by Law (both PPAs and EPAs), there are several factors, mainly livestock and fires that impact the riparian forest of Pandeiros river compromising local biodiversity conservation and making the forest sparse and even wholly absent (Nunes et al., 2009;Nunes YRF, Azevedo IFP, Neves WV, Veloso MDM, Souza RA, Fernandes GW. Pandeiros: o Pantanal Mineiro. MG. Biota 2009; 2(2): 4-17. Rodrigues et al., 2009Rodrigues PMS, Azevedo IFP, Veloso MDM, Santos RM, Menino GC, Nunes YRF et al. Riqueza Florística da Vegetação ciliar do rio Pandeiros, norte de Minas Gerais. MG. Biota 2009; 2(2): 18-35.). In this sense, this study aimed to monitor the survival of saplings of native species planted according to different recovery models for the riparian vegetation of the Pandeiros River, to evaluate the most effective rehabilitation model for riparian forests in the region.

2. MATERIAL AND METHODS

2.1. Characterization of study area

This work was developed at the Pandeiros River EPA, Januária, northern Minas Gerais, Brazil. The region presents several phytophysiognomies, resulting from the transition between the Cerrado and Caatinga biomes, such as the Deciduous Seasonal Forest (dry forest), cerrado sensu stricto, riparian forests, floodplain areas and veredas (Nunes et al., 2009Nunes YRF, Azevedo IFP, Neves WV, Veloso MDM, Souza RA, Fernandes GW. Pandeiros: o Pantanal Mineiro. MG. Biota 2009; 2(2): 4-17.). Additionally, the riparian vegetation of the Pandeiros River presents a junction of riparian forest, dry forest, savanna, and palm swamps, exhibiting high tree diversity (Rodrigues et al., 2009Rodrigues PMS, Azevedo IFP, Veloso MDM, Santos RM, Menino GC, Nunes YRF et al. Riqueza Florística da Vegetação ciliar do rio Pandeiros, norte de Minas Gerais. MG. Biota 2009; 2(2): 18-35.; Menino et al., 2012Menino GCO, Nunes YRF, Santos RM, Fernandes GW, Fernandes LA. Environmental heterogeneity and natural regeneration in riparian vegetation of the Brazilian semi-arid region. Edinburgh Journal of Botany 2012; 69(1): 29-51. http://dx.doi.org/10.1017/S0960428611000400.
http://dx.doi.org/10.1017/S0960428611000... ; Veloso et al., 2014Veloso MDM, Nunes YRF, Azevedo IFP, Rodrigues PMS, Fernandes LA, Santos RM et al. Floristic and structural variations of the arboreal community in relation to soil properties in the Pandeiros river riparian forest, Minas Gerais, Brazil. Interciencia 2014; 39(9): 628-636.).

The climate of the region, according to Köppen, is Aw, with average annual temperature of 21 to 24 °C and rainfall of 900 to 1,200 mm, and rainfall concentrated in the months of November to January (Azevedo et al., 2014Azevedo IFP, Nunes YRF, Ávila MA, Silva DL, Fernandes GW, Veloso RB. Phenology of riparian tree species in a transitional region in southeastern Brazil. Brazilian Journal of Botany 2014; 37(1): 47-59. http://dx.doi.org/10.1007/s40415-014-0046-5.
http://dx.doi.org/10.1007/s40415-014-004... ). During the study period, the average temperature was 24.3 °C and 23.6 °C, the maximum average temperature was 31.9 °C and 31.3 °C, minimum average temperature was 18.4 °C and 17.5 °C and total precipitation was 1,302.6 mm and 1,877.4 mm, throughout the period from December 2009 to December 2010 and from January 2011 to December 2011, respectively. The rains were concentrated during the summer, with peaks in December/2009, March and December/2010 and March and December/2011 (Figure 1). The highest temperatures were observed in January and October/2010 and February and September/2011. The climatic data were obtained from the Meteorological Station of Januária, of the National Meteorological Institute (INMET 2016Instituto Nacional de Metereologia – INMET. Banco de dados meteorológicos para ensino e pesquisa [online]. Brasília: INMET; 2016. [cited 2016 Sep 17]. Available from: http://www.inmet.gov.br
http://www.inmet.gov.br... ).

Figure 1
Mean monthly of minimum, average and maximum temperature and total monthly precipitation from December 2009 to January 2011, obtained at the Meteorological Station of Januária, Minas Gerais (Source: INMET, 2016Instituto Nacional de Metereologia – INMET. Banco de dados meteorológicos para ensino e pesquisa [online]. Brasília: INMET; 2016. [cited 2016 Sep 17]. Available from: http://www.inmet.gov.br
http://www.inmet.gov.br... ).

Geomorphologically, the EPA of Pandeiros River is located in the São Fransiscana Depression and São Francisco Planalto, with a geological process of the Urucuia and Santa Helena Formations (sedimentary material) and limestone layers of the Bambuí Series (Jacomine, 1979Jacomine PKT. Conceituação sumaria de classes de solos e critérios para subdividi-las. Rio de Janeiro: EMBRAPA-SNLCS; 1979.). The predominant soil is the typical Dystrophic Red-Yellow Latosol, with a moderate A horizon and clayey texture, cerrado phase, with smooth to wavy relief, where there are spots of typical Eutrophic Haplic Cambisol with moderate A horizon and clayey texture added to the Argisol Red-Typical eutrophic yellow, with moderate A and clayey texture, deciduous forest phase, with flat to soft undulating relief (UFV, 2010aUniversidade Federal de Viçosa – UFV. Centro Tecnológico de Minas Gerais – CETEC. Universidade Federal de Lavras – UFLA. Fundação Estadual do Meio Ambiente –FEAM. Mapa de solos do estado de Minas Gerais. Belo Horizonte: Fundação Estadual do Meio Ambiente; 2010a., bUniversidade Federal de Viçosa – UFV. Centro Tecnológico de Minas Gerais – CETEC. Universidade Federal de Lavras – UFLA. Fundação Estadual do Meio Ambiente – FEAM. Mapa de solos do Estado de Minas Gerais: legenda expandida. Belo Horizonte: Fundação Estadual do Meio Ambiente; 2010b.).

For the experiment implementation, the areas destined for the revegetation were the PPAs, demarcated by the Brazilian Forest Code (Brasil, 1965Brasil. Lei Federal nº 4.771, de 15 de setembro de 1965. Institui o Novo Código Florestal. Diário Oficial da República Federativa do Brasil, Brasília, DF (1965).), in the year of implantation of the experiment (2009). The experiment was conducted on three farms: Agropecuária Ouro Preto - AGROPOP (15° 36 “S and 44° 42” W), Traçadal (15° 32 “S 44º 43” W) and Pandeiros (15° 39 “S 44° 39” W). All farms present extensive cattle breeding as an economic activity, where the areas used were deforested for cultivation of Brachiaria sp. Experimental plantations were carried out in December 2009, at AGROPOP, January 2010, at Traçadal, and December 2010 at Pandeiros farms.

2.2. Species selection, sapling production and recovery models

The native species used for recovery planting were species that occur in the region and were selected from floristic studies conducted in the riparian vegetation of the Pandeiros river, near the study areas (Rodrigues et al., 2009Rodrigues PMS, Azevedo IFP, Veloso MDM, Santos RM, Menino GC, Nunes YRF et al. Riqueza Florística da Vegetação ciliar do rio Pandeiros, norte de Minas Gerais. MG. Biota 2009; 2(2): 18-35.; Veloso et al., 2014Veloso MDM, Nunes YRF, Azevedo IFP, Rodrigues PMS, Fernandes LA, Santos RM et al. Floristic and structural variations of the arboreal community in relation to soil properties in the Pandeiros river riparian forest, Minas Gerais, Brazil. Interciencia 2014; 39(9): 628-636.). About 10 matrices for each species were marked for seed collection, close to the study areas, but from different forest remnants, to guarantee genetic diversity (Martins, 2007Martins SV. Recuperação de matas ciliares. Viçosa: Aprenda Fácil; 2007.). Seed collection and sapling production were undertaken in partnership with the Instituto Estadual de Florestas (IEF), using the IEF forest nursery in Januária, as well as the Plant Ecology Laboratory of the Universidade Estadual de Montes Claros (UNIMONTES).

Four different recovery models were implemented, with four replications each, consisting of 1.0 ha plots (50 m wide perpendicular to the river × 200 m long parallel to the river). Each plot was demarcated using treated eucalyptus fence and barbed wire. Treatment of the area was also undertaken, consisting of harrowing, with a tractor, and applying organic matter (chicken manure or mamona cake, used 0.5 t per area) manually. Harrowing was realized to decrease Brachiaria sp. grasses from the planting site, to incorporate the organic matter and for soil turning.

To plant the saplings, a fixed spacing of 2 m between the planting lines was applied and saplings were planted in 20 cm deep pits. The treatments (T), or implanted recovery models, consisted of planting saplings at two distances of either 2 or 4 m, with direct sowing - S (T2S and T4S, respectively) or no direct sowing (T2 and T4, respectively). The direct sowing in the soil was done between the saplings, with three seeds per hole, using holes of approximately 5 cm made with a hoe. The species used in direct seeding and the amount of seeds used (by weight) are described in Table 1. The experiment was carried out during the rainy season, aiming to reduce transplanting stress, since during this period the water supply would be sufficient for the establishment and growth of saplings and seed germination.

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Table 1
Native species used in direct seeding (weight in grams) and sapling planting (number of individuals) in the recovery of riparian vegetation of Pandeiros river (Januária, MG).

A total of 16,259 saplings were planted, distributed in 33 species, 32 genera and 16 families (Table 1), ranging from 20 cm to 1 m in height, all of them over four months old. After planting, the saplings were numbered with aluminum plates and tied by a nylon thread, and the survival of these saplings was monitored every four months for a year.

2.3. Data analysis

The survival rate of the individuals was determined by the ratio between the number of surviving individuals and the total number of individuals planted for each species and treatment throughout the four evaluations. To detect variations in survival of individuals between recovery models and between planted species, Variance Analysis (ANOVA) was used in GLM (Generalized Linear Models) procedure, followed by Tukey's post-test in the R (R Development Core Team, 2013R Development Core Team. R: A language and environment for statistical computing [online]. Vienna: R Foundation for Statistical Computing; 2013. [cited 2015 May 25]. Available from: http://www.R-project.org
http://www.R-project.org... ) statistical package.

3. RESULTS

The total survival percentage showed significant variation between the evaluation months (df = 3, F = 75.98, p < 0.001). The highest survival rate of the planted saplings was 70.3% (±1.8), after three months of evaluation, with values of 64.0% (± 1.8) after six months, and 51.0% (±1.9) nine months after planting. After 12 months of evaluation, survival dropped to 34.4% (± 1.8), showing that survival decreased significantly during the first year of experimental planting (Figure 2). However, there was no significant variation (df = 3, F = 2.58, p > 0.05) in survival rates between the models tested. The mean survival percentage was numerically higher in the model with sapling and direct sowing at 2 m distance between saplings - ST2 (57.3 ± 1.9%) and lower in the model with saplings at 4 m distance and absence of sowing - T4 (50.2 ± 2.0%). On the other hand, there was a decrease in survival in all treatments tested, over time, as observed between areas and between months of treatment.

Figure 2
Average survival percentage of saplings implanted in the restoration of riparian vegetation of Pandeiros river (Januária, MG), for restoration model and evaluation time. Restoration models: sapling planting with distance between rows of 2 m without (T2) and with (T2S) direct seeding and in lines of 4 m without (T2) and with (T2S) direct seeding.

The survival rate also showed significant variation between the study areas (df = 2, F = 109.83, p < 0.001). The area that presented the highest survival rate was AGROPOP (76.6 ± 1.7%), followed by Traçadal (47.2 ± 2.1%) and Pandeiros (46.2 ± 1.3%), which showed the lowest survival rates (Figure 3). Survival varied between the study months in the areas studied, but decreased over time in the three areas.

Figure 3
Average survival percentage of saplings planted for the rehabilitation of riparian vegetation of Pandeiros river (Januária, MG), for restoration areas and evaluation time.

The species with the highest average survival rate after one year of evaluation were Jacaranda brasiliana (caroba), with 85.0%, Anadenanthera colubrina (angico), with 70.1%, Triplaris gardneriana (pau-jaú), with 69.3%, Senna spectabilis (são-joão), with 68.8%, and Caesalpinia ferrea (pau-ferro), with 63.8% (Table 2). On the other hand, some species had a low average survival rate, such as Ziziphus joazeiro (juazeiro), with 1.50% and Anacardium humile (cajuí), with 8.03%, while all Inga vera (ingá) saplings died.

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Table 2
Average survival percentage in time and standard deviation (in parentheses) of the species implanted in the recovery of riparian vegetation of Pandeiros river (Januária, MG). Popular names, species’ authors name and their respective botanical families are presented in .

4. DISCUSSION

The first year of planting is considered a period of sapling adaptation to the adverse conditions present at the site being revegetated, and is therefore when seedlings present higher mortality (Mcdonald et al., 2003McDonald MA, Hofny-Collins A, Healey JR, Goodland TCR. Evaluation of trees indigenous to the montane forests of the Blue Mountains, Jamaica for reforestation and agroforestry. Forest Ecology and Management 2003; 175(1-3): 379-401. http://dx.doi.org/10.1016/S0378-1127(02)00132-9.
http://dx.doi.org/10.1016/S0378-1127(02)... ; Raman et al., 2009Raman TRS, Mudappa D, Kapoor V. Restoring Rainforest Fragments: survival of mixed-native species seedlings under contrasting site conditions in the Western Ghats, Índia. Restoration Ecology 2009; 17(1): 137-147. http://dx.doi.org/10.1111/j.1526-100X.2008.00367.x.
http://dx.doi.org/10.1111/j.1526-100X.20... ). The decrease in survival rates over the first year of evaluation may also be related to the climatic conditions of the region, since the rains are concentrated in the months of November to January (Azevedo et al., 2014Azevedo IFP, Nunes YRF, Ávila MA, Silva DL, Fernandes GW, Veloso RB. Phenology of riparian tree species in a transitional region in southeastern Brazil. Brazilian Journal of Botany 2014; 37(1): 47-59. http://dx.doi.org/10.1007/s40415-014-0046-5.
http://dx.doi.org/10.1007/s40415-014-004... ). The saplings were introduced during the rainy season (December and January), after which they went through a long period of drought during autumn and winter (April to October), until the arrival of the next rainy season in the summer. Therefore, water deficits may have led to the death of the plants, since low soil moisture is a limiting factor for the development of saplings (Paiva & Poggiani, 2000Paiva AV, Poggiani F. Crescimento de mudas de espécies arbóreas nativas plantadas no sub-bosque de um fragmento florestal. Scientia Forestalis 2000; 57: 141-151.). McDonald et al. (2003)McDonald MA, Hofny-Collins A, Healey JR, Goodland TCR. Evaluation of trees indigenous to the montane forests of the Blue Mountains, Jamaica for reforestation and agroforestry. Forest Ecology and Management 2003; 175(1-3): 379-401. http://dx.doi.org/10.1016/S0378-1127(02)00132-9.
http://dx.doi.org/10.1016/S0378-1127(02)... , in a study with native species implanted in a revegetation area in Jamaica, found a survival rate (39 to 48%, after 12 months) similar to the present study. Rezende (2004)Rezende RP. Recuperação de matas de galeria em propriedades rurais do Distrito Federal e entorno [dissertação]. Brasília: Universidade de Brasília; 2004., in a restoration of gallery forests in 88 rural properties in the Distrito Federal (Brazil), obtained lower survival data than that of the present study, with the survival of only 16.3% of the saplings planted.

Although fenced, the three study areas were affected by the presence of cattle within the plots, a factor that may have contributed to the decreased survival rates of the saplings, especially in the Pandeiros and Traçadal areas, where this influence was more intense. This fact was due to the possibility of animals entering via the river, during periods of drought, and when the fence was damaged. In addition, several studies (Figueiras, 1990Figueiras TS. Africanas no Brasil: gramíneas introduzidas da África. Cadernos de Geociências 1990; 5: 57-63.; Martins et al., 2004Martins CR, Leite LL, Haridasan M. Capim-gordura (Melinis minutiflora P. Beauv.), uma gramínea exótica que compromete a recuperação de áreas degradadas em unidades de conservação. Revista Árvore 2004; 28(5): 739-747. http://dx.doi.org/10.1590/S0100-67622004000500014.
http://dx.doi.org/10.1590/S0100-67622004... ; Rossi et al., 2010Rossi JP, Celini L, Mora P, Mathieu J, Lapied E, Nahmani JF et al. Decreasing fallow duration in tropical slash and burn agriculture alters soil macroinvertebrate diversity: a case study in southern French Guiana. Agriculture, Ecosystems & Environment 2010; 135(1-2): 148-154. http://dx.doi.org/10.1016/j.agee.2009.08.012.
http://dx.doi.org/10.1016/j.agee.2009.08... ) cite the aggressiveness and high competitiveness of African grasses introduced into Brazil, such as Brachiaria species with native plants. In a study by Figueiras (1990)Figueiras TS. Africanas no Brasil: gramíneas introduzidas da África. Cadernos de Geociências 1990; 5: 57-63., which classified African grasses according to aggressiveness in terms of competition with native flora, eight species of the Brachiaria genus were classified as “very aggressive” and “moderately aggressive”, seriously affecting natural regeneration. Thus, exotic grasses used in pasture formation may be an aggravating factor in the mortality of seedlings planted in recovery projects in areas impacted by cattle breeding.

In addition to competition and climatic conditions, survival may be related to factors such as soil type and drainage (McDonald et al., 2003McDonald MA, Hofny-Collins A, Healey JR, Goodland TCR. Evaluation of trees indigenous to the montane forests of the Blue Mountains, Jamaica for reforestation and agroforestry. Forest Ecology and Management 2003; 175(1-3): 379-401. http://dx.doi.org/10.1016/S0378-1127(02)00132-9.
http://dx.doi.org/10.1016/S0378-1127(02)... ). According to Braga (2011)Braga LL. Performance de mudas e desenvolvimento da regeneração natural em diferentes modelos de restauração em uma floresta ciliar no sudeste do Brasil [dissertação]. Montes Claros: Universidade Estadual de Montes Claros; 2011., in an experiment to evaluate the performance of saplings and the development of natural regeneration in different recovery models in the AGROPOP area, half of the plots of this area are located in places originally influenced by dry forest formation with very nutrient rich soils. The soil analysis for this area, according to Braga (2011)Braga LL. Performance de mudas e desenvolvimento da regeneração natural em diferentes modelos de restauração em uma floresta ciliar no sudeste do Brasil [dissertação]. Montes Claros: Universidade Estadual de Montes Claros; 2011., found high levels of phosphorus and a higher proportion of clay in these plots. Several authors discuss the positive influence of soil on plant establishment (Alpert et al., 1999Alpert P, Griggs FT, Peterson DR. Riparian forest restoration along large rivers: initial results from the Sacramento River Project. Restoration Ecology 1999; 7(4): 360-368. http://dx.doi.org/10.1046/j.1526-100X.1999.72030.x.
http://dx.doi.org/10.1046/j.1526-100X.19... ; Gurevitch et al., 2009Gurevitch J, Scheiner SM, Fox GA. Ecologia vegetal. São Paulo: Editora Artmed; 2009.). These same authors cite the importance of phosphorus as a limiting nutrient for the development of plants, as a constituent in several molecules and in cell membranes, acting directly on plant metabolism, and essential for the initial development of seedlings. Moreover, clay is a component that ensures greater soil moisture, providing water to the plants for longer periods during the dry season (Gurevitch et al., 2009Gurevitch J, Scheiner SM, Fox GA. Ecologia vegetal. São Paulo: Editora Artmed; 2009.) thus ensuring their survival.

The species with the highest survival rates (J. brasiliana, A. colubrina, T. gardneriana, S. spectabilis and C. ferrea), are characterized as pioneer species, heliophytes, fast growing, and are used in heterogeneous reforestation and recovery of degraded areas (Lorenzi, 1992,Lorenzi H. Árvores brasileiras: manual de identificação e cultivo de plantas arbóreas nativas do Brasil. Vol. 1. Nova Odessa: Plantarum; 1992. 1998Lorenzi H. Árvores brasileiras: manual de identificação e cultivo de plantas arbóreas nativas do Brasil. Vol. 2. Nova Odessa: Plantarum; 1998.; Carvalho, 2003Carvalho PER. Espécies arbóreas brasileiras. Vol. 1. Brasília: Embrapa Florestas; 2003., 2010Carvalho PER. Espécies arbóreas brasileiras. Vol. 4. Brasília: Embrapa Florestas; 2010.). Lorenzi (2002)Lorenzi H. Árvores brasileiras: manual de identificação e cultivo de plantas arbóreas nativas do Brasil. Vol. 3. Nova Odessa: Instituto Plantarum; 2002. points out that because of the rusticity and adaptation to dry lands, the various angico species are recommended for rehabilitation, as they grow well in poor and degraded soils, as well as having very rapid growth, being ready for field planting in less than four months. Barbosa (1980)Barbosa DCA. Estudos ecofisiológicos em Anadenanthera macrocarpa (Benth.) Brenan - aspectos de germinação e crescimento [tese]. São Paulo: Universidade de São Paulo; 1980. pointed out that saplings of the genus Anadenanthera supported relative humidity ranging from 1% to approximately zero, losing 85 to 90% of the initial water content, and recovering turgidity when rehydrated, showing the adaptation of species to the irregular precipitation regime. Among the 10 species with the best development (high survival and rapid growth) found in the recovery of gallery forests on rural properties in the Distrito Federal, Rezende (2004)Rezende RP. Recuperação de matas de galeria em propriedades rurais do Distrito Federal e entorno [dissertação]. Brasília: Universidade de Brasília; 2004. indicates J. brasiliana and A. colubrina (38.5% and 21.9%, respectively). These species maintained a high adaptive plasticity when confronted by the adverse conditions found in the field (Rezende, 2004Rezende RP. Recuperação de matas de galeria em propriedades rurais do Distrito Federal e entorno [dissertação]. Brasília: Universidade de Brasília; 2004.), which can also be observed in this study. It is of paramount importance to consider the adaptability of the species to the place where they will be introduced, since, in degraded areas, adverse conditions may decrease species survival (Rezende, 2004Rezende RP. Recuperação de matas de galeria em propriedades rurais do Distrito Federal e entorno [dissertação]. Brasília: Universidade de Brasília; 2004.; Martins, 2007Martins SV. Recuperação de matas ciliares. Viçosa: Aprenda Fácil; 2007.).

Although Inga vera is a heliophyte, pioneer or initial succession species (Carvalho, 2008Carvalho PER. Espécies arbóreas brasileiras. Vol. 3. Brasília: Embrapa Florestas; 2008.), in the present study, the saplings of this species that were planted showed 100% mortality after one year. Probably, the mortality of the species is related to water scarcity during the dry period in the study area, since according to Carvalho (2008)Carvalho PER. Espécies arbóreas brasileiras. Vol. 3. Brasília: Embrapa Florestas; 2008., Inga vera occurs naturally in moist, frequently humid soils and even in swampy areas. Neri et al. (2011)Neri AV, Soares MP, Meira-Neto JAA, Dias LE. Espécies de Cerrado com potencial para recuperação de áreas degradadas por mineração de ouro, Paracatu-MG. Revista Árvore 2011; 35(4): 907-918. http://dx.doi.org/10.1590/S0100-67622011000500016.
http://dx.doi.org/10.1590/S0100-67622011... emphasized that the identification of native species, with good development in degraded areas, is an important step in the implementation of recovery projects. These authors also argued that the correct choice of species for revegetation in Cerrado areas should take into account their need to adapt to low soil fertility, possible water deficits or flooding and an ability to compete with invasive weeds; factors that may determine the survival and growth of saplings.

Studies involving edaphic and environmental variables are necessary for a better understanding of the survival of the seedlings within the tested recovery models. Such studies are scarce, since there are few studies investigating the recovery of degraded areas that use native plants and that propose recovery models to be tested, which makes it difficult to compare the methods analyzed here.

5. CONCLUSION

The average survival of the saplings planted was low, probably due to the adverse conditions found in the degraded sites, such as long periods of water stress characteristic of the region and possible external interference, such as competition from Brachiaria sp. or trampling and grazing by domesticated animals. Some species are more resistant, such as Jacaranda brasiliana, Anadenanthera colubrina, Triplaris gardneriana, Senna spectabilis and Caesalpinia ferrea, and may be suitable for revegetation in degraded riparian forests in the Pandeiros river region. Additionally, the models tested should be reevaluated to give sufficient time for planted individuals to compete with their peers.

ACKNOWLEDGEMENTS

The authors wish to thank CNPq (Conselho Nacional de Desenvolvimento Científico e Tecnológico; 577460/2008-0; 306375/2016-8), FAPEMIG (Fundação de Amparo à Pesquisa do Estado de Minas Gerais; APQ-00627-16) and CAPES (Coordenação de Aperfeiçoamento de Pessoal de Nível Superior) for grant funding for this research. We would also like to thank IEF (Instituto Estadual de Florestas), UNIMONTES (Universidade Estadual de Montes Claros) and the Promotoria de Justiça de Defesa da Bacia do Rio São Francisco, for logistical and legal support; Dr. Rubens Manoel dos Santos (Universidade Federal de Lavras), for help with botanical identification; all the students of Laboratório de Ecologia Vegetal (UNIMONTES) and IEF staff, for field assistance; and the farm owners José Fernando Coura (AGROPOP farm), Hildo Fortunato Pinto (Pandeiros farm) and Ana Lúcia Gallo da França (Traçadal farm), for permission to conduct this research.

FINANCIAL SUPPORT CNP, FAPEMIG and CAPES.

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Publication Dates

Publication in this collection
2018

History

Received
10 Nov 2015
Accepted
23 Jan 2017

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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Family/ species	Common name	Direct seeding (g)	Sapling planting
Anacardiaceae
Anacardium humile A. St.-Hil.	Cajuí	1384.16	62
Anacardium occidentale L.	Cajueiro	253.08	96
Astronium fraxinifolium Schott ex Spreng.	Gonçalo	1045.92	1400
Myracrodruon urundeuva Allemão	Aroeira	1587.31	1364
Schinopsis brasiliensis Engl.	Pau-preto	261.76	508
Tapirira guianensis Aubl.	Tapiriri	2665.28	-
Annonaceae
Annona crassiflora Mart.	Cabeça-de-negro	-	516
Apocynaceae
Aspidosperma subincanum Mart. ex A. DC.	Pau-pereiro	1007	294
Bignoniaceae
Handroanthus chrysotrichus (Mart. ex A. DC.) Mattos	Ipê-tabaco	240	345
Jacaranda brasiliana (Lam.) Pers.	Caroba	-	187
Tabebuia sp.	Ipê	1362.64	1426
Burseraceae
Commiphora leptophloeus (Mart.) J.B.Gillet	Umburana-vermelha	-	137
Cannabaceae
Celtis iguanaea (Jacq.) Sarg.	Juá-mirim	-	21
Combretaceae
Combretum duarteanum Cambess.	Vaqueta	2073.92
Dilleniaceae
Curatella americana L.	Lixeira	200.64	21
Fabaceae-Caesalpinioideae
Caesalpinia ferrea Mart. Ex Tul.	Pau-ferro	16307	53
Copaifera coriacea Mart.	Pau-d’olinho		612
Dimorphandra mollis Benth.	Favela	1424.64
Hymenaea eriogyne Benth.	Jatobá	5919.4
Hymenaea martiana Hayne	Jatobá	3875.04
Hymenaea sp.	Jatobá	-	965
Senna spectabilis (DC.) H.S.Irwin & Barneby	São-joão	-	516
Fabaceae-Faboideae
Bowdichia virgilioides Kunth	Sucupira-preta	52.8	-
Machaerium opacum Vogel	Jacarandá-do-cerrado	4408.72	-
Plathymenia reticulata Benth.	Vinhático	417	-
Pterodon emarginatus Vogel	Sucupira-branca	3957.76	-
Swartzia flaemingii Vogel	Pau-sangue	423.28	-
Vatairea macrocarpa Ducke	Angelim	430.36	9
Fabaceae-Mimosoideae
Anadenanthera colubrina (Vell.) Brenan	Angico	869	1883
Chloroleucon dumosum (Benth.) G.P.Lewis	Rosqueira	896	144
Chloroleucon foliolosum (Benth.) G. P. Lewis	Tatarena	1768	-
Enterolobium contortisiliquum (Vell.) Morong	Tamboril	5438	218
Inga vera Willd.	Ingá	-	80
Machaerium punctatum (Poir.) Pers.	Jacarandá	930	-
Senegalia polyphylla (DC.) Britton & Rose	Periquiteira	1021	143
Malvaceae
Guazuma ulmifolia Lam.	Mutamba	-	524
Myrtaceae
Eugenia dysenterica DC.	Cagaita	-	585
Memecylaceae
Mouriri pusa Gardner	Pusa-preta	1534.08	-
Polygonaceae
Triplaris gardneriana Weddell	Pau-jaú	390	967
Rhamnaceae
Ziziphus joazeiro Mart.	Juazeiro	-	345
Rubiaceae
Genipa americana L.	Jenipapo	-	600
Sapindaceae
Dilodendron bipinnatum Radlk.	Mamoninha	1090.12	376
Magonia pubescens A.St.-Hil.	Tingui	9454.6	506
Talisia esculenta (A.St.-Hil.) Radlk.	Pitomba	-	273
Sterculiaceae
Sterculia striata A.St.-Hill. & Naudin	Chichá	1271	41
Urticaceae
Cecropia pachystachya Trécul	Embaúba	-	1042

Species	Survival (%)
Species	3 months	6 months	9 months	12 months
A. colubrina	87.12 (±6.76)	82.03 (±6.78)	70.13 (±6.48)	70.13 (±6.98)
A. crassiflora	76.19 (±9.21)	64.45 (±9.28)	39.25 (±10.09)	15.83 (±9.56)
A. fraxinifolium	80.33 (±6.73)	75.86 (±6.78)	61.86 (±7.36)	45.92 (±17.04)
A. humile	57.43 (±18.43)	47.32 (±18.57)	42.85 (±20.18)	8.03 (±19.12)
A. occidentale	60.10 (±18.43)	52.65 (±18.57)	26.59 (±20.19)	20.21 (±9.12)
A. subincanum	61.25 (±10.64)	61.25 (±10.72)	50.17 (±11.65)	24.73 (±11.03)
C. americana	78.56 (±18.43)	78.57 (±18.57)	64.28 (±20.18)	35.71 (±19.12)
C. coriacea	57.07 (±6.96)	46.66 (±7.02)	35.29 (±7.62)	18.48 (±7.22)
C. dumosum	84.02 (±9.85)	78.82 (±9.92)	70.93 (±10.78)	42.92 (±17.04)
C. ferrea	93.74 (±13.03)	93.74 (±13.13)	74.99 (±14.27)	63.88 (±13.64)
C. iguanaea	90.45 (±18.43)	70.45 (±18.57)	65.90 (±20.18)	29.09 (±19.02)
C. leptophloeus	82.94 (±10.64)	74.74 (±10.72)	47.59 (±11.65)	40.83 (±11.03)
C. pachystachya	47.95 (±7.23)	34.85 (±7.28)	26.57 (±7.91)	16.34 (±7.49)
D. bipinnatum	61.40 (±7.52)	58.26 (±7.58)	47.38 (±8.26)	28.42 (±7.80)
E. contortisiliquum	77.22 (±7.86)	69.32 (±7.91)	61.79 (±6.06)	47.71 (±8.22)
E. dysenterica	45.33 (±9.21)	41.64 (±9.28)	30.80 (±10.09)	17.70 (±9.56)
G. americana	92.56 (±9.85)	80.90 (±9.92)	44.59 (±6.78)	34.14 (±10.22)
G. ulmifolia	77.41 (±7.52)	70.23 (±7.58)	47.80 (±6.23)	31.88 (±7.80)
H. chrysotrichus	93.66 (±9.85)	84.84 (±9.55)	77.57 (±10.78)	51.55 (±10.31)
Hymenaea sp.	61.32 (±6.75)	55.66 (±6.78)	40.34 (±7.36)	28.04 (±6.98)
I. vera	28.94 (±26.07)	13.15 (±26.26)	0	0
J. brasiliana	98.19 (±13.03)	96.76 (±13.13)	96.05 (±14.27)	85.00 (±13.54)
M. pubescens	50.88 (±6.73)	43.52 (±6.78)	34.49 (±7.36)	24.39 (±6.98)
M. urundeuva	77.00 (±6.51)	74.24 (±6.56)	63.89 (±6.13)	42.78 (±6.75)
S. brasiliensis	71.57 (±6.96)	69.82 (±7.02)	57.29 (±7.62)	38.10 (±7.22)
S. polyphylla	58.43 (±9.85)	48.81 (±9.92)	43.90 (±10.78)	23.89 (±10.22)
S. spectabilis	87.04 (±9.21)	84.63 (±9.28)	81.47 (±10.09)	68.81 (±9.56)
S. striata	57.27 (±10.64)	57.27 (±10.72)	55.42 (±11.65)	28.40 (±11.03)
T. esculenta	93.25 (±10.64)	78.13 (±10.72)	56.64 (±11.65)	35.88 (±11.03)
T. gardneriana	85.54 (±8.69)	85.24 (±8.75)	81.55 (±9.51)	69.33 (±9.09)
Tabebuia sp.	76.16 (±6.51)	63.33 (±6.56)	44.73 (±7.13)	26.64 (±6.75)
V. macrocarpa	31.25 (±13.03)	31.25 (±13.13)	31.25 (±14.27)	25.00 (±13.51)
Z. joazeiro	50.10 (±10.64)	40.79 (±10.72)	22.11 (±11.65)	1.50 (±11.03)
Total	70.32 (±1.76)	64.00 (±1.80)	51.01 (±1.90)	34.41 (±1.82)