|Yellow and purple Oxalis tuberosa (oca) tubers|
Oxalis tuberosa (Oxalidaceae) is a perennial herbaceous plant that overwinters as underground stem tubers. These tubers are known as uqa in Quechua, Hispanicized oca, as New Zealand yam and a number of other alternative names. The plant was brought into cultivation in the central and southern Andes for its tubers, which are used as a root vegetable. The plant is not known in the wild, but populations of wild Oxalis species that bear smaller tubers are known from four areas of the central Andean region. Oca was introduced to Europe in 1830 as a competitor to the potato, and to New Zealand as early as 1860.
In New Zealand, oca has become a popular table vegetable and is simply called yam or New Zealand yam (although not a true yam). It is now available in a range of colours, including yellow, orange, pink, apricot, and the traditional red.
Grown primarily by Quechua and Aymara farmers, oca has been a staple of rural Andean diets for centuries. Of all Andean root and tuber crops, oca is currently second only to potato in area planted within the Central Andean region. Oca is important to local food security because of its role in crop rotations and its high nutritional content.
Oca morphotypes are distinguished by foliar, floral, fruit, stem, and tuber characteristics, as described in the International Plant Genetic Resources Institute’s document on oca descriptors. The morphological diversity of oca tubers, in particular, is astounding. Tubers range from 25 to 150 mm in length by 25 mm in width; skin and flesh color may be white, cream, yellow, orange, pink, red, and/or purple and distributed in range of patterns.
Local cultivar namesEdit
Oca-growing communities often name varieties based primarily on tuber morphology and secondarily on flavor. For example, common names may include ushpa negra (black ash) or puka panti (red Cosmos peucedanifolius). Great inconsistency of nomenclature has been reported within and among communities.
Numerous studies have additionally described oca diversity through molecular approaches to study protein and genetic variation. Molecular markers, such as allozymes (e.g., del Río, 1999) and inter-simple sequence repeats (e.g., Pissard et al., 2006), show oca diversity to be low relative to other crops, probably because of its vegetative mode of propagation. While genetic differentiation corresponds well with folk classification, cluster analyses indicate that folk cultivars are not perfect clones, but rather genetically heterogeneous groupings.
Oca is one of the highest vegetable sources of carbohydrate and energy. They are a good source of pro-vitamin A (beta carotene), and also contain potassium, vitamin B6 and small amounts of fibre. Yellow-orange coloured varieties indicate the presence of carotenoids; whilst red skins and red specks in flesh indicate the presence of anthocyanins.
|Vitamin C (mg)||38.4||2.4|
Oca is cultivated primarily for its edible stem tuber, but the leaves and young shoots can be eaten as a green vegetable also. Mature stems can be used similarly to rhubarb. Andean communities have various methods to process and prepare tubers, and in Mexico oca is eaten raw with salt, lemon, and hot pepper. The flavour is often slightly tangy, but there is a considerable degree of difference in flavors between varieties and some are not acidic at all. Texture ranges from crunchy (like a carrot) when raw or undercooked, to starchy or mealy when fully cooked.
Oca is fairly high in oxalates, concentrated in the skin, and the bioavailability of oxalate appears to be similar to spinach. Significant variation in oxalate concentration exists among varieties, and this variation distinguishes two oca use-categories recognized by Andean farmers.
One use-category, sour oca, contains cultivars with high levels of oxalic acid. Farmers process these tubers to form a usable storage product, called khaya in Quechua. To prepare khaya, tubers are first soaked in water for approximately one month. Then they are left outside during hot, sunny days and cold, freezing nights until they become completely dehydrated. This process is similar to the preparation of chuñu from bitter potatoes. Cultivars in this use category are referred to in Quechua as khaya (name of the dried, processed product) or p'usqu (sour/fermented), and in Aymara as luk’i.
The other use-category, sweet oca, contains cultivars with lower levels of oxalic acid. The traditional Andean preparation methods for this use-category are also geared towards reducing the oxalate level of the harvested vegetable, but without dehydration. This is done by exposure to sunlight, which decreases the organic acid content and thereby increases the sweet taste of the oca. Once exposed to sunlight, oca can be boiled, baked or fried. In the Andes it is used in stews and soups, served like potatoes, or can be served as a sweet. Cultivars in this category are referred to in Quechua as wayk'u (boiling), misk'i (sweet/delicious) and in Aymara as q'ini.
The table to the right displays the nutritional content for fresh and dried oca. Oca is a valuable source of vitamin C, potassium (included in value for ash), and iron. It also provides some protein, with valine and tryptophan its limiting amino acids. Cultivars vary greatly in nutritional content, so these measures should be taken only as approximates. It is also high ranks from the nutritional point of view.
Oca is planted in the Andean region from Venezuela to Argentina, from 2800 to 4100 meters above sea level. Its highest abundance and greatest diversity are in central Peru and northern Bolivia, the probable area of its domestication.
Oca needs a long growing season, and is day length dependent, forming tubers when the day length shortens in autumn (around March in the Andes). In addition, oca requires climates with average temperatures of approximately 10 to 12 °C (ranging between 4 and 17 °C) and average precipitation of 700 to 885 millimeters per year.
Oca requires short days in order to form tubers. Outside the tropics, it will not begin to form tubers until approximately the autumn equinox. If frosts occur too soon after the autumn equinox, the plant will die before tubers are produced.
Oca grows with very low production inputs, generally on plots of marginal soil quality, and tolerates acidities between about pH 5.3 and 7.8. In traditional Andean cropping systems, it is often planted after potato and therefore benefits from persisting nutrients applied to, or left over from, the potato crop.
Oca is usually propagated vegetatively by planting whole tubers.
Propagation by seed is possible but is rarely used in practice. Sexual propagation is complicated by several factors. First, like many other species in the genus Oxalis, oca flowers exhibit tristylous heterostyly and are consequently subject to auto-incompatibility. Furthermore, on the rare occasion that oca plants do produce fruit, their loculicidal capsules dehisce spontaneously, making it difficult to harvest seed. Oca flowers are pollinated by insects (e.g., genera Apis, Megachile, and Bombus). Data regarding the frequency of volunteer hybrids and farmers’ subsequent incorporation of them has not yet been published.
Oca tuber-seeds are planted in the Andes in August or September and harvested from April to June. The first flowers bloom around three to four months after planting, and the tubers also begin to form then. Between planting and harvesting, the oca crop requires little tending, except for a couple of weedings and hillings.
Oca is a component of traditional crop rotations and is usually planted in a field directly after the potato harvest. A common sequence in this rotation system may be one year of potato, one year of oca, one year of oats or faba beans, and two to four years fallow. Within this system, q’allpa is a Quechua term that signifies soil previously cultivated and prepared for planting of a new crop.
The cultural practice is similar to potatoes. Planting is done in rows or hills 80–100 cm apart, with plants spaced 40–60 cm apart in the rows. Monoculture predominates, but interplanting with several other tuber species, including mashua and olluco, in one field is common in Andean production. Often this intercoppng consists of several different varieties of each species. Such mixed fields may later be sorted into tuber types during harvest or before cooking.
Harmine found in root secretions of Oxalis tuberosa has been found to have insecticidal properties.
Yields vary with the cultural method. Annals from Andean countries report about 7-10 tonnes per hectare for Oxalis tuberosa production. But with adequate inputs and virus free propagation material, oca production can range from 35 to 55 tonnes per hectare.
Pests and diseases limit the production of oca. Crops in the Andes are often infected with viruses, causing chronic yield depression. Adequate techniques to remove viruses have to be applied before the varieties can be used outside the Andean region. Cultivation is also constrained by the Andean potato weevil (Premnotrypes spp), ulluco weevil (Cylydrorhinus spp), and oca weevil, the identification of which remains uncertain (possibly Adioristidius, Mycrotrypes, or Premnotrypes). These weevils often destroy entire crops. Further notable pests are nematodes.
As already mentioned, both day-length restrictions and the presence of oxalates can also be considered limiting factors. Scientists work with specific breeding, selection, and virus cleaning programs on these purposes.
Potential distribution to other suitable ecogeographical zones of, for example, Asia and Africa may be possible. The cultivation and use of a fleshy pink variety of Oxalis tuberosa in New Zealand already indicates a wider utilization and agricultural interest than has been previously recognized.
A number of ongoing ex situ and in situ conservation projects currently focus on the preservation of Oxalis tuberosa diversity. The International Potato Center (CIP) in Peru has several hundred accessions of oca collected from regions in Bolivia, Argentina and Peru to help ensure and maintain diversity. Currently, there are further efforts to collect accession of oca in regions where habitat destruction and pests are threatening diversity of wild oca accessions.
- Apilla in Bolivia
- Apiña in Bolivia and Peru
- Batata-baroa or mandioquinha (literally, "little mandioca") in Brazil, a name shared with the unrelated arracacha
- Cuiba or quiba in Venezuela
- Hibia, huasisai, or ibi in Colombia
- Macachin or miquichi in Venezuela
- Papa extranjera in Mexico
- Truffette acide in France
- Yam in many other places, such as Polynesia and New Zealand, where the Dioscorea vegetables known elsewhere as yams are generally very uncommon.
- Teofilo Laime Ajacopa, Diccionario Bilingüe Iskay simipi yuyayk'ancha, La Paz, 2007 (Quechua-Spanish dictionary)
- Bradbury, E. J., & Emshwiller, E. (2011). The Role of Organic Acids in the Domestication of Oxalis tuberosa: A New Model for Studying Domestication Resulting in Opposing Crop Phenotypes 1. Econ Bot, 1–9.
- National Research Council. (1989). Lost Crops of the Incas: Little-Known Plants of the Andes with Promise for Worldwide Cultivation. National Academy Press, Washington, D.C.
- "Oca, Ulluco, and Mashua": http://www.cipotato.org/roots-and-tubers/oca-ulluco-mashua
- IPGRI-CIP. 2001. Descriptores de oca. IPGRI, Rome, Italy; CIP, Lima, Peru.
- Martin, R.J., Savage, G.P., Deo, B., Halloy, S.R.P. and Fletcher, P.J. 2005. Development of new oca lines in New Zealand. Acta Hort. (ISHS) 670:87-92. http://www.actahort.org/books/670/670_9.htm
- Terrazas, F. and G. Valdivia. 1998. Spatial dynamics of in situ conservation: handling the genetic diversity of Andean tubers in mosaic systems. Pl Genet Res Newl 114: 9-15.
- Ramirez, M. 2002. On farm conservation of minor tubers in Peru: the dynamics of oca (Oxalis tuberosa) landrace management in a peasant community. Plant Genet Res Newsl 132: 1-9.
- del Río, A.H. 1990. Análisis de la variación isoenzimática de Oxalis tuberosa Molina "oca" y su distribución geográfica. Thesis, Universidad Ricardo Palma, Lima, Peru.
- Pissard, A., Ghislain, M., & Bertin, P. (2006). Genetic diversity of the Andean tuber-bearing species, oca (Oxalis tuberosa Mol.), investigated by inter-simple sequence repeats. Genome 49(1), 8–16. doi:10.1139/g05-084
- Emshwiller, E. 2006. Evolution and conservation of clonally propagated crops: Insights from AFLP data and folk taxonomy of the Andean tuber oca (Oxalis tuberosa). Pages 308–346 in T. J. Motley, N. Zerega, and H. Cross, eds., Darwin’s Harvest: New Approaches to the Origins, Evolution, and Conservation of Crops. Columbia University Press, New York.
- Albihn, P. B. E.; and Savage, G. P. (2001). "The effect of cooking on the location and concentration of oxalate in three cultivars of New Zealand-grown oca (Oxalis tuberosa Mol)". J. of the Science of Food and Agr. 81: 1027-1033.
- The Bioavailability of Oxalate from Oca (Oxalis tuberosa)
- Eve Emshwiller, Terra Theim, Alfredo Grau, Victor Nina and Franz Terrazas. (2009). Origins of domestication and polyploidy in oca (Oxalis tuberosa: Oxalidaceae) 3: AFLP data of oca and four wild, tuber-bearing taxa. Am J Bot 96(10): 1839-1848.
- Hermann, M., & Erazo, C. (2000). Compositional changes of oca tubers following post-harvest exposure to sunlight. CIP Program Report, 391–396.
- King, S. R., & Gershoff, S. N. (1987). Nutritional evaluation of three underexploited Andean tubers: Oxalis tuberosa (Oxalidaceae), Ullucus tuberosus (Basellaceae), and Tropaeolum tuberosum (Tropaeolaceae). Econ Bot 41(4), 503–511.
- Sperling, C.R.; and King, S.R. (1990). "Advances in new crops: Worldwide potential.". J. Janick and J.E. Simon (eds.). Advances in new crops. Timber Press, Portland, OR. p. 428-435.
- Arbizu, C., and Tapia, M. 1992. Tubérculos andinos. In Cultivos marginados: otra perspectiva de 1492. Edited by J.E. Hernández Bermajo and S. León. FAO, Rome, Italy. pp. 147–161.
- Gonzales, S., Terrazas, F., Almanza, J., & Condori, P. (2003). Producción de oca (Oxalis tuberosa), papalisa (Ullucus tuberosus), e isaño (Tropaeolum tuberosum) ( No. 20). (X. Cadima, W. García, & J. Ramos, Eds.)Importancia, zonas productoras, manejo y limitantes (pp. 1–46). Cochabamba, Bolivia: PROINPA.
- Carrión, S., Hermann, M., & Trognitz, B. (1995). La biología reproductive de la oca. Boletín de Lima, 48–68. Lima.
- M. Frére, J. Rea, J.Q. Rijks (1975) Ullucus tuberosus. In:Estudio agroclimatolgico de la zona Andina (informe tecnico). Organizacion de las naciones unidas para la alimentacion y la agriculture, Rome.
- Pal Bais, Harsh; Sang-Wook Parka; Frank R. Stermitzb; Kathleen M. Halliganb; Jorge M. Vivancoa (18 June 2002). "Exudation of fluorescent b-carbolines from Oxalis tuberosa L. roots" (PDF). Phytochemistry. 61 (5): 539–543. doi:10.1016/S0031-9422(02)00235-2. Retrieved 2008-02-02.
- Taraprasad(Programmer), Nishant(Designer) and. "Oca Diversity and its Conservation Status - International Potato Center". International Potato Center. Retrieved 2016-02-20.
- Cadima Fuentes X., 2006. Tubérculos. In: Moraes R. et al., eds. Botánica económica de los Andes Centrales. La Paz, Bolivia: Universidad Mayor de San Andrés, 347-369.
- Arbizu C., Huamán Z. & Golmirzaie A., 1997. Other andean roots and tubers. In: Fuccillo D., Sears L. & Stapleton P., eds. Biodiversity in trust: conservation and use of plant genetic resources in CGIAR centres. Cambridge, UK: Cambridge University Press, 39-56.
- Davidson, Alan. Oxford Companion to Food (1999). "Oca", p. 547 ISBN 0-19-211579-0
|Wikimedia Commons has media related to Oxalis tuberosa.|