Andean Root and Tuber Crops: Underground Rainbows Hector E. Flores1, 2 Department of Pathology and Biotechnology Institute, The Pennsylvania State University, University Park, PA 16802 Travis S. Walker1 Department of Horticulture and Landscape Architecture, Colorado State University, Fort Collins, CO 80526 Rejane L. Guimarães Department of Plant Pathology and Biotechnology Institute, The Pennsylvania State University, University Park, PA 16802 Harsh Pal Bais and Jorge M. Vivanco2 Department of Horticulture and Landscape Architecture, Colorado State University, Fort Collins, CO 80526 Additional index words. achira, Canna edulis, maca, Lepidium meyenii, mashua, tuberosum, mauka, Mirabilis expansa, oca, , , Solanum tuberosum, ulluco, tuberosus

The Andean region is recognized today as tions, inter-cropping techniques, and soil pres- and natural pesticides. The great adaptability one of the most important centers of crop origin ervation practices (Flores and Flores, 1997). of the ARTC favors their potential cultivation and diversity in the world (National Research Underground storage organs are among the outside their area of origin. For example, oca Council, 1989). Many of our most important most common and effi cient structures evolved is currently grown in Australia and New Zea- food crops worldwide, most notably potatoes, by for survival in challenging environ- land (National Research Council, 1989), while were domesticated in this system (National ments. Root and tuber crops can also exhibit other have recently been introduced Research Council, 1989). A unique feature of some of the highest yields for calories produced to Mexico, Central America, Brazil, Europe, the Andean agricultural system is a taxonomi- per area of cultivation; thus their adaptation and Australia. cally diverse group of Andean root and tuber and diversifi cation in the made both crops (ARTC), coupled to the commonly found ecological and economic sense. Tuber crops complement of grains and legumes, such as The ARTC today are common staples for Oca (Oxalis tuberosa, Oxalidaceae). After maize (Zea mays L.), chenopodium, beans, an estimated 25 million people in the Andean potato, oca is the most common tuber crop in and lupines. The ARTC played a vital role highlands, and are at least an occasional food the Andean region (Pulgar-Vidal, 1981). Oca in allowing sustained intensive cultivation source for another 100 million people in Ecua- is a prostrate herb with a compact growth habit and nourishment of a population that reached dor, Colombia, , , Argentina, and of ≈20–30 cm in height with cylindrical suc- 10–12 million people at the height of the In- Chile. The traditional agricultural system of the culent stems varying in color from green to red can Empire (1450–1535 A.D.) (King, 1987). Andes faces many challenges and uncertainties. (Fig. 1), and the tubers range from cylindrical About 17 species of root and tuber crops were Therefore, the need for promoting and preserv- to ovoid, averaging 7 to 11 cm in length. The domesticated in the Andes, making this the ing ARTC is immediate such that studies are texture of the tuber skin varies from smooth largest known geographical concentration of necessary to improve pest management and to rough, and the color is white, yellow, pink, underground crops (Hernandez-Bermejo and crop productivity to motivate farmers towards red, purple, or black (Seminario, 1988). Oca Leon, 1992; Tapia, 1993). the cultivation of these crops. Furthermore, the is widely adapted to divergent environments, The ARTC evolved in extremely inhospi- susceptibility of some of the more important and it is commonly cultivated in areas with table areas for agriculture, and Pre-Columbian ARTC such as mashua and ulluco to viral dis- elevations between 2800 and 4000 m and people made extremely effi cient use of what eases warrants the need to provide disease-free a range of precipitation of 570–2500 mm by todayʼs agricultural standards would be accessions to minimize annual crop losses due (Seminario, 1988). It grows in moderately considered marginal land (King, 1987). The to disease. The potential uses of the Andean root cool temperatures down to 5 °C, and poor steep slopes of the Andes are prone to constant and tuber crops are discussed in this paper as soil conditions with a pH range of 5.3–7.8 erosion, extreme fl uctuations in rainfall and we review their biology and biochemistry. (Leon, 1964; Seminario, 1988). This crop is temperature, and contain relatively poor soils. grown in greatest abundance in the highlands Crops grown in this environment were selected THE ANDEAN ROOT AND TUBER of , Peru, and Bolivia, but is also found for their ability to cope with long periods of CROPS in regions of Chile, Argentina, Colombia, and drought, freezing temperatures, and high UV . Oca has been commercialized in irradiation. The Andean farmers took advan- The ARTC span no fewer than nine plant New Zealand, Australia, Mexico, France, and tage of natural plant adaptations to extreme families: Asteraceae, , Brassica- Great Britain either as a food staple or as a environments to domesticate a unique cohort ceae, Leguminosae, Nyctaginaceae, Oxalida- home-garden ornamental (King and Gershoff, of crops, and combined their cultivation with ceae, , Tropaeolaceae, and Umbel- 1987; National Research Council, 1989). the use of complex irrigation canals, crop rota- liferae. The genetic diversity and potential of Evidence suggests that the cultivated these species is remarkable. Large germplasm oca is an octoploid species, 2n = 8x = 64 collections are available for the three major chromosomes (Arbizu and Tapia, 1994). For Received for publication 2 June 2002. Accepted for tuber crops, oca, mashua, and ulluco, with practical purposes, the crop is sterile and thus publication 8 Sept. 2002. Work reported in this review ≈8000 accessions combined. Thus, substan- maintained vegetatively. The ex-situ oca germ- was supported in part by the McKnight Foundation tial ARTC biodiversity still persists in situ and plasm is distributed amid several genebanks in to HEF, and grants from the National Science Foun- ex situ. Oca, ulluco, and mashua alone could , with 482 accessions cataloged dation (MCB-0093014), the Colorado State Univ. at the International Potato Center–Peru (CIP), Agriculture Experiment Station, the San Luis Valley signifi cantly expand the range of nutritional Research Center Committee, and the Charles A. and properties represented in the commonly culti- 1696 at Instituto Nacional de Investigacion Anne Morrow Lindbergh Foundation to J.M.V. vated and consumed Solanum sp. The ARTC Agropecuaria–Peru (INIA), 912 at Universidad 1Authors contributed equally to this work. represent a vast and mostly untapped pool of Nacional San Antonio–Peru (UNSAAC), 680 2To whom reprint requests should be addressed; e-mail: variation in type and content of starch, amino at Instituto Boliviano de Technologia Agro- [email protected] or [email protected] acid composition, other nutritional factors, pecuaria–Bolivia (IBTA). However, Andean

HORTSCIENCE, VOL. 38(2), APRIL 2003 161 FEATURE

Mashua (, Tropeola- ceae). Mashua is an herbaceous perennial plant, and a close relative of the garden nasturtium. The plant habit is prostrate or climbing and it grows over 1 m in diameter and 0.5 m in height, and produces slender leaves (Fig. 1). The tubers vary in color and shape. The tuber skin is white, yellow, or occasionally purplish or red. Some tubers are mottled or striped with red or purple, particularly below the “eyes,” and as in potato and oca, small leaf scales border the deep-set “eyes.” The fl esh of the tuber is generally yellow irrespective of the morphotype (National Research Council, 1989). Mashua can be propagated vegetatively, but it also produces a large quantity of viable seed (Arbizu and Tapia, 1994). Although mashua is grown from 2400 to 4300 m, the best production of mashua tu- bers occurs at elevations around 3000 m, with maximum yields of 30,000 kg·ha–1. Mashua is usually cultivated once a year because tuber formation occurs only during short photoperi- ods of ≈11–13.5 h of daylight. The life cycle of 5–6 months is relatively short compared with other root and tuber crops (National Research Council, 1989; Zela et al., 1997). Without tra- ditional irrigation practices, mashua requires annual precipitation amounts between 700 and 1600 mm, and the best soil type for this crop is a fertile, organic soil with pH values from 5.3 to 7.5 (Torres et al., 1992). Mashua is cultivated in Argentina, Bolivia, Colombia, Ecuador, Peru, and Venezuela, and has recently been introduced to New Zealand. Andean farmers recognize a number of differ- ent mashua morphotypes based on color, form, and taste of the tubers. Domesticated mashua is thought to be comprised of more than 400 dif- ferent morphotypes (Sperling and King, 1990). Mashua accessions in genebanks, distributed among different institutions around the Andean region, include 101 at Cuzco (Peru), 146 at Fig. 1. Images of plants of the six Andean root and tuber crops showing both aboveground foliage and belowground storage organs. Ayacucho (Peru), 125 at Universidad Nacional Mayor de San Marcos–Peru (UNMSM), 55 at Programa de Investigacion de Papa–Bolivia z Table 1. Nutritional values of the major Andean tuber crops in parts per million (ppm dry-weight basis). (PROIMPA), and 43 at Instituto Nacional de Nutritional facts Mashua Oc Oca Ulluco Potato Investigacion Agropeciaria–Ecuador (INIAP). Ascorbic acid 670–4800 370–2284 230–1750 170–990 The majority of these accessions are maintained Calcium 70–500 40–247 30–365 34–2550 through in vitro propagation. Carbohydrate 59–786 138–852 118–912 171–862 The Andean highlanders use mashua as a Fat 2–42.8 6–37.0 2–14.6 1–9.0 food crop and as a medicinal crop. All parts Fiber 6–57.0 5–49.0 3–44.0 3–27.0 of the plant can be consumed, including the Iron 2–85.0 8–49.0 7–58.0 5–128.0 Phosphorus 13–115.0 340–2099 340–2775 320–4200 tubers, leaves, and blossoms, but the tuber is Protein 220–3000 7–62.0 10–73.0 10–127.0 the most commonly consumed because of its Ribofl avin 0.8–8.5 0.3–4.3 0.2–2.2 0.4–1.9 fl avor and nutritional value (National Research Thiamine 0.6–9.3 0.5–3.1 0.4–4.3 1–5.0 Council, 1989). Compared to other Andean Kilocalories --- 630–3890 500–3725 780–3755 root and tuber crops, mashua contains high β- 0.3–2.1 0.2 0.7 1.0 levels of ascorbic acid (), thiamin ZData from the Agriculture Research Services Dr. Duke phytochemical and ethnobotanical database (http: (vitamin B1), ribofl avin (vitamin B2), as well //www.ars-grin.gov/duke). as lipids (Table 1), and the tubers are rela- tively high in protein content and fi ber. These farmers primarily maintain the biodiversity iron, fats, and fi ber (Table 1). Among differ- nutritional characteristics make the mashua of oca through on-farm propagation (Arbizu, ent morphotypes, protein levels vary widely, tuber an important component of an Andean 2000; Arbizu et al., 1997), and only a small ranging from 1% to 9% on a dry-weight basis. highlander diet. fraction of the total germplasm has been The bitter morphotypes contain oxalic acid at Ulluco (Ullucus tuberosus, Basellaceae). exploited by plant breeders to develop new concentrations up to 500 µg·kg–1 (National Re- Ulluco is a low-growing herb with heart- (Hodge, 1985). search Council, 1989). As is the case for most shaped succulent leaves, and morphotypes Oca tubers show high variability in nu- Andean root and tuber crops, there are very vary from prostrate, semiclimbing to tritional levels between genotypes, and they few reports on the basic biology, agronomy, dense and compact bushes (Fig. 1). Tubers are a good source of carbohydrates, calcium, and biochemistry of oca. can be elongated or curved, with a thin, soft

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