Keywords
domestication
nilpa
phaseolus
human selection
zea
How to Cite
Abstract
Ash contains calcium, potassium and magnesium oxides that when combined with water generate hydroxides. Ash was used by human populations in the Pre-ceramic period to tan skins, make garments and footwear, cure wounds, apply tattoos and perform mummifications. We wondered if the application of ash could enable the consumption of grains and seeds of wild maize, beans and squash, and if the treatment with lime could arise from the procedure with ash. We conducted an ethnobotanical study for two years in an area with wild maize, beans and gourds among traditional peasants who cultivate milpa. We recorded the thermo-alkaline treatments related to the consumption of wild grasses, legumes and oleaginous plants. We observed four: three with ash and one with lime. We noted that these ash treatments allow the consumption of wild maize, beans and squashes and form a diet with carbohydrates, proteins and fatty acids with a complete amino acid profile. This could encourage interest in these species and lead to their domestication. The treatment with lime can be regarded as a technological innovation to the ash procedure. It is possible to trace a sequence in terms of energy cost and complexity in five levels, which is related to the domestication process of the three crops. However, it is necessary to experimentally demonstrate the changes in the nutritional characteristics of the wild plants when applying the thermo-alkaline methods with ash.
References
Bradley R, y B. Dahlin. 2007. Traditional burnt-lime production at Mayapan, Mexico. Journal of Field Archaeology 32 (4): 407-423.
Debouk D.G. 2016. Your beans of the last harvest and the posible adoption of bright ideas. Pp. 367- 387. In: R. Lira and A. Casas (Eds). Ethnobotany of Mexico. New York. Kluwer Academic Press.
Dillehay T.D., J. Rossen, D. Ugent, A. Karathanasis, V. Vásquez and P. y J. Netherly. 2010.Early Holocene coca chewing in northern Peru. Antiquity 84 (326): 939–953
Doebley J.F. 1984. “Seeds” of wild grasses: A major food for Southwestern Indians. Economic Botany 38:52-64.
Doebley J.F. 2004. The genetics of maize evolution. Annual Review of Genetics 38:37–59
Doebley J.F. 2006. Unfallen grains: how ancient farmers turned weeds into crops. Science 312:1318–1319
Ellwood E.C, M. P. Scott, W. D. Lipe, R.G. Matson, J. y G. Jones. 2013. Stone-boiling maize with limestone: experimental results and implications for nutrition among SE Utah preceramic groups. Journal of Archaeological Science 40: 35-44.
Ferrusquía–Villafranca, I. 1990. Provincias biogeográficas con base en rasgos morfo– tectónicos. Mapa IV8.10. In: Atlas Nacional de México, vol. III., Instituto de Geografía. México D.F. Universidad Nacional Autónoma de México.
Gry J., I. Sobog y H.S. Andersson. 2006. Cucurbitacins in plant food. Nordic Concil of Ministers. Copenhagen.
Hart P. J. 2004. Can Cucurbita pepo gourd seeds be made edible? Journal of Archaeological Science. 31:1631-1633.
Hart J.P, R.A. Daniels y C.J. Sheviak. 2004. Do Cucurbita pepo gourds float fishnets? Am Antiquity 69:141–148.
Iltis H.H. 2000. Homeotic sexual translocations and the origin of maize. Economic Botany 54(1): 7-42.
Kaplan L. y T.E. Lynch. 1999. Phaseolus (Fabaceae) in archaeology: AMS radiocarbon dates and their significance for pre-Colombian agriculture. Economic Botany. 53:261–272.
Kelly I. 1980. Ceramic sequence in Colima: Capacha, an Early Phase, Tucson, University of Arizona Press (Anthropological Papers, 37).
Koinange E.M.K, Singh S.P, y P. Gepts. 1996. Genetic control of the domestication syndrome in common bean. Crop Science 36:1037–1045
Marcus, J. y K. Flannery 2008. La Civilización Zapoteca. Fondo de cultura económica. México.
Mariscal-Moreno R.M., J.D.C. Figueroa, D. SantiagoRamos, G. Armbula-Villa, S. Jimenez-Sandoval, P. Rayas-Duarte, J. J. Véles-Medina y H.E. MartínezFlores. 2105. The effect of different nixtamalisation processes on some physicochemical properties, nutritional composition and glycemic index. Journal of Cereal Science 65:140-146.
Martinez-Bustos, F., H.E. Martinez-Flores, E. Sanmartin-Martinez, F. Sanchez-Sinencio, Y.K. Chang, D. Barrera-Arellano y E. Rios. 2001. Effect of the components of maize on the quality of masa and tortillas during the traditional nixtamalisation process. Journal of the Science of Food and Agriculture 81:1455-1462
Piperno D.R, I. Holst, L. Wessel-Beaver y T.C. Andres. 2002. Evidence for the control of phytolith formation in Cucurbita fruits by the hard rind (Hr) genetic locus: archaeological and ecological implications. . Proceedings of the National Academy of Sciences of the United States of America. 99:10923–10928
Piperno D.R, y E. Stothert. 2003. Phytolith for early Holocene Cucurbita domestication in Southwest Ecuador. Science 299:1054–7
Piperno D.R, y T.D. Dillehay. 2008. Starch grains on human teeth reveal early broad crop diet in northern Peru. Proceedings of the National Academy of Sciences of the United States of America. 105: 19622–19627.
Piperno D.R, A.J. Ranere, I. Holst, R. Dickau, y J. Iriarte. 2009. Starch grain and phytolith evidence for early ninth millennium B.P. maize in the central Balsas River valley, Mexico. . Proceedings of the National Academy of Sciences of the United States of America. 106:5019–5024.
Ranere A.J., Piperno D.R, I. Holst, R. Dickau y J. Iriarte. 2009. The cultural and chronological context of early Holocene maize and squash domestication in the central Balsas River Valley, Mexico. Proceedings of the National Academy of Sciences of the United States of America. 106:5014-5018
Reinhard KJ., K. L. Johnson, S. LeRoy-Toren, K. Wieseman, I. Teixeira-Santos y M. Vieira. 2012. Understanding the Pathoecological Relationship between Ancient Diet and Modern Diabetes through Coprolite Analysis. Current Anthropology. 53(4):506-512.
Salazar C., D. Zizumbo-Villarreal, P. ColungaGarcíaMarín y S. Brush. 2016. Contemporary Maya food system in the Lowlands of Northern Yucatan. Pp. 133- 150. In: R. Lira and A. Casas (Eds). Ethnobotany of Mexico. Kluwer Academic Press.
Smalley J. y Blake M. 2003. Sweet Beginnings: Stalk sugar and the domestication of maize. Current Anthropology, Vol. 44 (5): 675-703.
Standen V. y B.T. Arriaza. 2005. Las técnicas de momificación artificial entre los cazadores, pescadores, y recolectores del desierto de Atacama (Norte de Chile). Estudios de Antropología Biológica. XII: 1023-1033. México.
Thoms A.V. 2009. Rocks of ages: propagation of hotrock cookery in western North America. Journal of Archaeological Science 36 (2009) 573–591
Van der Poel A.F.B., Blonk J., Huisman J., y Den Hartog L.A. 1991. Effect of processing on anti-nutritional factors and protein nutritional value of dry beans (Phaseolus vulgaris L.). A review Livestock Production Science 28 (4): 305-319.
Wang H, B. Nussbaum-Waller, Q. Li, Q. Zhao, Y. Vigouroux, M. Faller, K. Bomblies, L. Lunkens y J. Doebley. 2005. The origin of the naked grains of maize. Nature 436:714–719
Zizumbo-Villarreal D. y P. Colunga-GarcíaMarín P. 2010. Origin of agriculture and plant domestication in West Mesoamerica. Genetic Resources and Crop Evolution 57:813-825
Zizumbo-Villarreal D., A. Flores-Silva y P. ColungaGarcíaMarín. 2012, The Archaic Diet in Mesoamerica: Incentive for milpa development and species domestication. Economic Botany. 66 (4) 328-343.
Zizumbo-Villarreal D., Flores-Silva A, y P. ColungaGarcíaMarín P. 2014. The food system during the formative period in West Mesoamerica. Economic Botany. 68 (1): 67–84.
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