Sunday, October 20, 2019
The History of the Common Bean
The History of the Common Bean The domestication history of the common bean (Phaseolus vulgaris L.) is vital to understanding the origins of farming.à Beans are one of the three sisters of traditional agricultural cropping methods reported by European colonists in North America: Native Americans wisely intercropped maize, squash, and beans, providing a healthful and environmentally sound way of capitalizing on their various characteristics.à Beans are one of the most important domestic legumes in the world, because of their high concentrations of protein, fiber, and complex carbohydrates. P. vulgaris is by far the most economically important domesticated species of the genus Phaseolus. Domesticate Properties P. vulgaris beans come in an enormous variety of shapes, sizes, and colors, from pinto to pink to black to white. Despite this diversity, wild and domestic beans belong to the same species, as do all of the colorful varieties (landraces) of beans, which are believed to be the result of a mixture of population bottlenecks and purposeful selection. The main difference between wild and cultivated beans is, well, domestic beans are less exciting. There is a significant increase in seed weight, and the seed pods are less likely to shatter than wild forms: but the primary change is a decrease in theà variability of grain size, seed coat thickness and water intake during cooking. Domestic plants are also annuals rather than perennials, a selected trait for reliability. Despite their colorful variety, the domestic bean is much more predictable. Centers Of Domestication Scholarly research indicates that beans were domesticated in two places: the Andes mountains of Peru, and the Lerma-Santiago basin of Mexico. The wild common bean grows today in the Andes and Guatemala: two separate large gene pools of the wild types have been identified, based on the variation in the type of phaseolin (seed protein) in the seed, DNA marker diversity, mitochondrial DNA variation and amplified fragment length polymorphism, and short sequence repeats marker data. The Middle American gene pool extends from Mexico through Central America and into Venezuela; the Andean gene pool is found from southern Peru to northwestern Argentina. The two gene pools diverged some 11,000 years ago. In general, Mesoamerican seeds are small (under 25 grams per 100 seeds) or medium (25-40 gm/100 seeds), with one type of phaseolin, the major seed storage protein of the common bean. The Andean form has much larger seeds (greater than 40 gm/100 seed weight), with a different type phaseolin. Recognized landraces in Mesoamerica include Jalisco in coastal Mexico near Jalisco state; Durango in the central Mexican highlands, which includes pinto, great northern, small red and pink beans; and Mesoamerican, in lowland tropical Central American, which includes black, navy and small white. Andean cultivars include Peruvian, in the Andean highlands of Peru; Chilean in northern Chile and Argentina; and Nueva Granada in Colombia. Andean beans include the commercial forms of dark and light red kidney, white kidney, and cranberry beans. Origins in Mesoamerica In 2012, work by a group of geneticists led by Roberto Papa was published in the Proceedings of the National Academy of Sciences (Bitocchi et al. 2012), making an argument for a Mesoamerican origin of all beans. Papa and colleagues examined the nucleotide diversity for five different genes found in all forms- wild and domesticated, and including examples from the Andes, Mesoamerica and an intermediary location between Peru and Ecuador- and looked at the geographic distribution of the genes. This study suggests that the wild form spread from Mesoamerica, into Ecuador and Columbia and then into the Andes, where a severe bottleneck reduced the gene diversity, at some time before domestication. Domestication later took place in the Andes and in Mesoamerica, independently. The importance of the original location of beans is due to the wild adaptability of the original plant, which allowed it to move into a wide variety of climatic regimes, from the lowland tropics of Mesoamerica into the Andean highlands. Dating the Domestication While the exact date of domestication for beans has not yet been determined, wild landraces have been discovered in archaeological sites dated to 10,000 years ago in Argentina and 7,000 years ago in Mexico. In Mesoamerica, the earliest cultivation of domestic common beans occurred before ~2500 in the Tehuacan valley (at Coxcatlan), 1300 BP in Tamaulipas (at (Romeros and Valenzuelas Caves near Ocampo), 2100 BP in the Oaxaca valley (at Guila Naquitz). Starch grains from Phaseolus were recovered from human teeth from Las Pircas phase sites in Andean Peru dated between ~6970-8210 RCYBP (about 7800-9600 calendar years before the present). Sources Angioi, SA. Beans in Europe: origin and structure of the European landraces of Phaseolus vulgaris L. Rau D, Attene G, et al., National Center for Biotechnology Information, U.S. National Library of Medicine, September 2010. Bitocchi E, Nanni L, Bellucci E, Rossi M, Giardini A, Spagnoletti Zeuli P, Logozzo G, Stougaard J, McClean P, Attene G et al. 2012. Mesoamerican origin of the common bean (Phaseolus vulgaris L.) is revealed by sequence data. Proceedings of the National Academy of Sciences Early Edition. Brown CH, Clement CR, Epps P, Luedeling E, and Wichmann S. 2014. The Paleobiolinguistics of the Common Bean (Phaseolus vulgaris L.). Ethnobiology Letters 5(12):104-115. Kwak, M. Structure of genetic diversity in the two major gene pools of common bean (Phaseolus vulgaris L., Fabaceae). Gepts P, National Center for Biotechnology Information, U.S. National Library of Medicine, March 2009. Kwak M, Kami JA, and Gepts P. 2009. The Putative Mesoamerican Domestication Center is Located in the Lerma-Santiago Basin of Mexico. Crop Science 49(2):554-563. Mamidi S, Rossi M, Annam D, Moghaddam S, Lee R, Papa R, and McClean P. 2011. Investigation of the domestication of common bean ( Functional Plant Biology 38(12):953-967.Phaseolus vulgaris) using multilocus sequence data. Mensack M, Fitzgerald V, Ryan E, Lewis M, Thompson H, and Brick M. 2010. Evaluation of diversity among common beans (Phaseolus vulgaris L.) from two centers of domestication using omics technologies. BMC Genomics 11(1):686. Nanni, L. Nucleotide diversity of a genomic sequence similar to SHATTERPROOF (PvSHP1) in domesticated and wild common bean (Phaseolus vulgaris L.). Bitocchi E, Bellucci E, et al., National Center for Biotechnology Information, U.S. National Library of Medicine, December 2011, Bethesda, MD. Peà ±a-Valdivia CB, Garcà a-Nava JR, Aguirre R JR, Ybarra-Moncada MC, and Là ³pez H M. 2011. Variation in Physical and Chemical Characteristics of Common Bean (Phaseolus vulgaris L.) Grain along a Domestication Gradient. Chemistry Biodiversity 8(12):2211-2225. Piperno DR, and Dillehay TD. 2008. Starch grains on human teeth reveal early broad crop diet in northern Peru. Proceedings of the National Academy of Sciences 105(50):19622-19627. Scarry, C. Margaret. Crop Husbandry Practices in North Americaââ¬â¢s Eastern Woodlands. Case Studies in Environmental Archaeology, SpringerLink, 2008. J, Schmutz. A reference genome for common bean and genome-wide analysis of dual domestications. McClean PE2, Mamidi S, National Center for Biotechnology Information, U.S. National Library of Medicine, July 2014, Bethesda, MD. Tuberosa (Editor). Genomics of Plant Genetic Resources. Roberto, Graner, et al., Volume 1, SpringerLink, 2014.
Subscribe to:
Post Comments (Atom)
No comments:
Post a Comment
Note: Only a member of this blog may post a comment.