Abstract
Agroforestry is a promising method for enhancing land-use sustainability in the Bolivian Andes. However, its benefits in terms of rural development are under-recognized due to gaps in understanding users’ perceptions while taking into consideration both local and global environmental goals. Our study aimed to narrow these gaps by developing an analytical framework for analyzing the site-specific socio-ecological factors and interactions related to local woody species and assessing their ecological, economic, and socio-cultural plant values in order to identify the most promising agroforestry species. The framework was then tested in an indigenous community at 2,760–3,830 m a.s.l., incorporating vegetation surveys, environmental studies, and interviews on plant functions. Ecological, economic, and socio-cultural values and the ecological apparency of plants were calculated, and detrended correspondence and principal component analyses helped to reveal the socio-ecological context of significant factors for plant distribution and uses. Results showed dominating seral woody species along an altitudinal gradient. Although shrubs were more ecologically apparent than trees, trees were perceived to be more valuable as the usefulness and cultural importance of species increased with plant height and timber availability. Phytosociological factors played a minor but still significant role in perceived usefulness. Schinus molle and Prosopis laevigata (<3,200 m a.s.l.), Polylepis subtusalbida (>3,200 m a.s.l.), and Baccharis dracunculifolia (both zones) were evaluated as most promising for agroforestry use. In conclusion, our analytical framework proved to be a valuable tool for context-specific agroforestry plant selection. Nonetheless, economic, technical, and socio-cultural limitations of cultivating native agroforestry species were revealed as well. Agroforestry science and practice should, therefore, focus on enhancing reproductive potentials of existing woody vegetation, as well as problem-oriented horizontal dialogues between indigenous, expert, and scientific actors.
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References
Aguilar LC (1997) Predicción del tiempo y su influencia en la organización de la producción en la comunidad de Tres Cruces, provincia Tapacarí. Tesis de licenciatura. AGRUCO, Universidad Mayor de San Simón, Cochabamba
Aguilar LC, Bracamonte R (2002) Diagnóstico participativo y plan de ordenamiento predial de la comunidad Tres Cruces. AGRUCO, Municipio Tapacarí, Cochabamba
Ahmed P (1989) Eucalyptus in agroforestry: its effects on agricultural production and economics. Agrofor Syst 8:31–38
Alavalapati JRR, Shrestha RK, Stainback GA, Matta JR (2004) Agroforestry development: an environmental economic perspective. Agrofor Syst 61:299–310
Albuquerque UP, Lucena RFP, Monteiro JM, Florentino ATN, Almeida C (2006) Evaluating two quantitative ethnobotanical techniques. Ethnobot Res Appl 4:51–60
Alexander EB, Mallory JI, Colwell WL (1993) Soil-elevation relationships on a volcanic plateau in the southern Cascade Range, northern California, USA. Catena 20:113–128
Arrázola S, Atahuachi M, Saravia E, Lopez A (2002) Diversidad florística medicinal y potencial etnofarmacológico de las plantas de los valles secos de Cochabamba, Bolivia. Rev Boliv Ecol Conserv Ambient 12:53–85
Backes MM (2001) The role of indigenous trees for the conservation of biocultural diversity in traditional agroforestry land use systems: the Bungoma case study. In situ conservation of indigenous tree species. Agrofor Syst 52:119–132
Bennett BC, Prance GT (2000) Introduced plants in the indigenous pharmacopoeia of northern South America. Econ Bot 54(1):90–102
Boden AG (1994) Bodenkundliche Kartieranleitung. E. Schweizerbart’sche Verlagsbuchhandlung, Stuttgart
Boom BM (1986) A forest inventory in Amazonian Bolivia. Biotropica 18(4):287–294
Butterfield RP (1995) Promoting biodiversity: advances in evaluating native species for reforestation. For Ecol Manag 75:111–121
Chepstow-Lusty A, Winfield M (2000) Inca agroforestry: lessons from the past. Ambio 29(6):322–328
Cook FEM (1995) Economic botany data collection standard. Royal Botanic Gardens Kew, Richmond
Dahlgren RA, Boettinger JL, Huntington GL, Amundson RG (1997) Soil development along an elevational transect in the western Sierra Nevada, California. Geoderma 78:207–236
Fjeldså J (2002) Polylepis forests-vestiges of a vanishing ecosystem in the Andes. Ecotropica 8:111–123
Fjeldså J, Kessler M (1996) Conserving the biological diversity of Polylepis woodlands of the highland of Peru and Bolivia. A contribution to sustainable natural resource management in the Andes. NORDECO, Copenhagen
Gareca EE, Hermy M, Fjeldså J, Honnay O (2010) Polylepis woodland remnants as biodiversity islands in the Bolivian high Andes. Biodivers Conserv 19:3327–3346
Garibaldi A, Turner N (2004) Cultural keystone species: implications for ecological conservation and restoration. Ecol Soc 9(3):1. http://www.ecologyandsociety.org/vol9/iss3/art1/
Gausset Q (2004) Ranking local tree needs and priorities through an interdisciplinary action research approach. J Transdiscipl Environ Stud 3(1):1–17
Hensen I (2002) Impacts of anthropogenic activity on the vegetation of Polylepis woodlands in the region of Cochabamba, Bolivia. Ecotropica 8:183–203
Hernando A, Tejera R, Velázquez J, Núñez MV (2010) Quantitatively defining the conservation status of Natura 2000 forest habitats and improving management options for enhancing biodiversity. Biodivers Conserv 19:2221–2233
Honorable Alcaldía Municipal de Tapacarí (2003) Ajuste del plan de desarrollo municipal Tapacari (PDM) 2003–2007. Programa de Inversión Rural Participativo (PDCR II), AGRUCO, Cochabamba
Ibisch PL (2002) Evaluation of a rural development project in southwest Cochabamba, Bolivia, and its agroforestry activities involving Polylepis besseri and other native species—a decade of lessons learned. Ecotropica 8:205–218
IPNI (2011) The International Plant Names Index. Royal Botanic Gardens Kew, Harvard University Herbaria, Australian National Herbarium. http://www.ipni.org. Accessed 17 July 2011
ISSG (2011) Global Invasive Species Database. Invasive Species Specialist Group. http://www.issg.org/database/welcome. Accessed 3 June 2011
Jose S (2009) Agroforestry for ecosystem services and environmental benefits: an overview. Agrofor Syst 76:1–10
Jose S (2011) Managing native and non-native plants in agroforestry systems. Agrofor Syst 83:101–105
Kidanu S, Mamo T, Stroosnijder L (2005) Biomass production of Eucalyptus boundary plantations and their effect on crop productivity on Ethiopian highland vertisols. Agrofor Syst 63:281–290
Killeen TJ, García E, Beck SG (1993) Guía de árboles de Bolivia. Herbario Nacional de Bolivia, Missouri Botanical Garden, La Paz
Kolar CS, Lodge DM (2001) Progress in invasion biology: predicting invaders. Trends Ecol Evol 16:199–204
Langenberger G, Prigge V, Martin K, Belonias B, Sauerborn J (2009) Ethnobotanical knowledge of Philippine lowland farmers and its application in agroforestry. Agrofor Syst 76:173–194
Lawrence A, Phillips OL, Ismodes AR, Lopez M, Rose S, Wood D, Farfan AJ (2005) Local values for harvested forest plants in Madre de Dios, Peru: towards a more contextualised interpretation of quantitative ethnobotanical data. Biodivers Conserv 14:45–79
Lucena RFP, Araújo E, Albuquerque UP (2007) Does the local availability of woody Caatinga plants (northeastern Brazil) explain their use value? Econ Bot 61(4):347–361
Luzar J (2007) The political ecology of a “forest transition”: Eucalyptus forestry in the southern Peruvian Andes. Ethnobot Res Appl 5:85–93
Madge C (1995) Ethnography and agroforestry research: a case study from the Gambia. Agrofor Syst 32:127–146
Mahboubi P, Gordon AM, Stoskopf N, Voroney RP (1997) Agroforestry in the Bolivian Altiplano: evaluation of tree species and greenhouse growth of wheat on soils treated with tree leaves. Agrofor Syst 37:59–77
Mariscal JC, Rist S (1999) Tipos de relaciones bosque-comunidad y normas tradicionales de uso y acceso a la vegetación boscosa. El caso de las comunidades de Chorojo y Chullpa K’asa de las provincias Quillacollo y Tapacarí en el departamento de Cochabamba. AGRUCO, PROBONA, Cochabamba
Mathez-Stiefel SL, Vandebroek I (2012) Distribution and transmission of medicinal plant knowledge in the Andean highlands: a case study from Peru and Bolivia. Evid Based Complement Altern Med 2012:1–18
Mathez-Stiefel SL, Boillat S, Rist S (2007) Promoting the diversity of worldviews: an ontological approach to bio-cultural diversity. In: Haverkort B, Rist S (eds) Endogenous development and bio-cultural diversity: the interplay of worldviews, globalization and locality. COMPAS, CDE, Leusden, pp 67–81
MBG (2011) Tropicos. Missouri Botanical Garden. http://www.tropicos.org. Accessed 17 July 2011
McDonald MA, Hofny-Collins A, Healey JR, Goodland TCR (2003) Evaluation of trees indigenous to the montane forest of the Blue Mountains, Jamaica for reforestation and agroforestry. For Ecol Manag 175:379–401
McNeely JA, Schroth G (2006) Agroforestry and biodiversity conservation—traditional practices, present dynamics, and lessons for the future. Biodivers Conserv 15:549–554
Navarro G, Maldonado M (2002) Geografía ecológica de Bolivia: vegetación y ambientes acuáticos. Centro de Ecología Difusión Simón I. Patiño, Santa Cruz
Navarro G, Molina JA, De la Barra N (2005) Classification of the high-Andean Polylepis forests in Bolivia. Plant Ecol 176:113–130
Nuñez MA, Simberloff D (2005) Invasive species and the cultural keystone species concept. Ecol Soc 10(1): r4. http://www.ecologyandsociety.org/vol10/iss1/resp4/
Phillips O, Gentry AH (1993a) The useful plants of Tambopata, Peru: I. Statistical hypotheses tests with a new quantitative technique. Econ Bot 47(1):15–32
Phillips O, Gentry AH (1993b) The useful plants of Tambopata, Peru: II. Additional hypothesis testing in quantitative ethnobotany. Econ Bot 47(1):33–43
Ponce D (2003) Previsión del clima y recreación del conocimiento indígena como estrategia para la conservación de la diversidad cultivada en los Andes bolivianos: el caso de la comunidad de Chorojo, provincia Quillacollo, departamento Cochabamba. Tesis de maestría. AGRUCO, Universidad Mayor de San Simón, Cochabamba
Quinlan M (2005) Considerations for collecting freelists in the field: examples from ethnobotany. Field Methods 17(3):1–16
R Foundation (2010) The R project for statistical computing. http://www.r-project.org. Accessed 24 Sept 2010
Reed MS (2007) Participatory technology development for agroforestry extension: an innovation-decision approach. Afr J Agric Res 2(8):334–341
Reynel C, Léon J (1990) Árboles y arbustos andinos para agroforestería y conservación de suelos. Tomo I: Especies forestales útiles para el productor agropecuario. Tomo II: Las especies. Proyecto FAO Holanda/DGFF, Lima
Richardson DM, Binggeli P, Schroth G (2004) lnvasive agroforestry trees: problems and solutions. In: Schroth G, Da Fonseca GAB, Harvey CA, Gascon C, Vasconcelos HL, Izac AMN (eds) Agroforestry and biodiversity conservation in tropical landscapes. Island Press, Washington, pp 371–396
Rist S, Dahdouh-Guebas F (2006) Ethnosciences—a step towards the integration of scientific and indigenous forms of knowledge in the management of natural resources for the future. Environ Dev Sustain 8:467–493
Russo RO (1990) Evaluating Alnus acuminata as a component in agroforestry systems. Agrofor Syst 10:241–252
Ruthsatz B, Fisel U (1984) The utilization of natural resources by a small community on the highlands of Bolivia and its effects on vegetation cover and site conditions. Erdwiss Forsch 18:211–234
Saunders CD, Brook AT, Myers OE (2006) Using psychology to save biodiversity and human well-being. Conserv Biol 20(3):702–705
Tardío J, Pardo-de-Santayana M (2008) Cultural importance indices: a comparative analysis based on the useful wild plants of southern Cantabria (northern Spain). Econ Bot 62(1):24–39
Thomas E, Vandebroek I, Van Damme P (2007) What works in the field? A comparison of different interviewing methods in ethnobotany with special reference to the use of photographs. Econ Bot 61(4):376–384
Thomas E, Van Damme P, Goetghebeur P (2010a) Some factors determining species diversity of prepuna and puna vegetations in a Bolivian Andes region. Plant Ecol Evol 143(1):31–42
Thomas E, Douterlungne D, Vandebroek I, Heens F, Goetghebeur P, Van Damme P (2010b) Human impact on wild firewood species in the rural Andes community of Apillapampa, Bolivia. Environ Monit Assess 178:333–347
Torrico G, Peca C, Beck SG, García E (1994) Leñosas útiles de Potosí. Proyecto FAO/Holanda/CDF “Desarrollo forestal comunal en el Altiplano boliviano”, Potosí
Turner NJ (1988) “The importance of a rose”: evaluating the cultural significance of plants in Thompson and Lillooet Interior Salish. Am Anthropol 90:272–290
Vandebroek I, Calewaert JB, De Jonckheere S, Sanca S, Semo L, Van Damme P, Van Puyvelde L, De Kimpe N (2004) Use of medicinal plants and pharmaceuticals by indigenous communities in the Bolivian Andes and Amazon. Bull World Health Organ 82(4):243–250
Wiersum KF (2004) Forest gardens as an ‘intermediate’ land-use system in the nature-culture continuum: characteristics and future potential. Agrofor Syst 61:123–134
Zhang C, Fu S (2009) Allelopathic effects of Eucalyptus and the establishment of mixed stands of Eucalyptus and native species. For Ecol Manag 258(7):1391–1396
Zimmerer KS (1993) Soil erosion and labor shortages in the Andes with special reference to Bolivia, 1953–91: implications for “conservation-with-development”. World Dev 21(10):1659–1675
Acknowledgments
We greatly appreciate the financial support received from the Andrea-von-Braun-Stiftung in Munich, Germany. Our most sincere thanks go to the syndicate assembly of Tres Cruces and the local leaders of the sub-central Waka Playa for authorizing our research, and to all local peasants who facilitated the study with confidence and ready cooperation. We are also thankful for the technical assistance of the BioAndes conservation and development program, funded by the Swiss Agency for Development and Cooperation (SDC). Moreover, we would like to acknowledge the scientific support of the Swiss National Centre of Competence in Research (NCCR) North–South: Research Partnerships for Mitigating Syndromes of Global Change, a research program co-funded by the Swiss National Science Foundation (SNSF), SDC, and the participating institutions. Furthermore, we are thankful to the Bolivian National Meteorology and Hydrology Service (SENAMHI), Cochabamba, for providing climatic data, as well as to Magaly Mercado and the working team of the herbarium of Cochabamba (BOLV) for their support in plant identification. We are very grateful to our colleagues Sarah-Lan Mathez-Stiefel (CDE), Rolando Sánchez, Sonia Medrano, Roger Juárez, Deicy Mejía (AGRUCO), Michael Beckmann, Christine Voigt, Catharina Landschulz, Ronny Warzecha, and Heidi Hirsch (MLU) for cooperating in field studies, interview translation, soil analyses, and graphic presentation. Finally, we would like to acknowledge Marlène Thibault and Danny McCluskey for proofreading the manuscripts, and the anonymous reviewers who have contributed to improving this paper.
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Brandt, R., Zimmermann, H., Hensen, I. et al. Agroforestry species of the Bolivian Andes: an integrated assessment of ecological, economic and socio-cultural plant values. Agroforest Syst 86, 1–16 (2012). https://doi.org/10.1007/s10457-012-9503-y
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DOI: https://doi.org/10.1007/s10457-012-9503-y