Effect of production environment, genotype and process on the mineral content of native bitter potato cultivars converted into white chuño.

BACKGROUND Variables and interaction effects affecting the mineral concentration of Andean bitter potatoes converted into so-called white chuño are unknown. We report on the effect of three contrasting production environments (E) on the dry matter (DM), zinc, iron, calcium, potassium, magnesium, phosphorus and sodium concentration of four potato native bitter genotypes (G) processed (P) into two different 'types' of white chuño. RESULTS The DM content and iron, calcium, magnesium and sodium concentration of white chuño are significantly dependent on E, G, P, and E × G × P interaction (predominantly at P < 0.01). In particular, the DM content and calcium concentration are influenced by all variables and possible interaction effects. The zinc and potassium concentration are not significantly dependent on E × G, G × P or E × G × P interaction effects, while the phosphorus concentration is not significantly affected by the G × P or E × G × P interaction effect. Zinc, phosphorus and magnesium concentrations decrease in the ranges of 48.3-81.5%, 61.2-73.0% and 62.0-89.7% respectively. The decrease in potassium is particularly severe, with 122- to 330-fold losses. Iron and calcium increase by 11.2-45.6% and 74.5-714.9% respectively. CONCLUSION E, G, P, and various interaction effects influence the mineral concentration of traditionally processed tubers. We speculate that mineral losses are caused by leaching, while increases of iron and calcium are a likely result of absorption.

[1]  M. Bonierbale,et al.  Traditional Processing of Black and White Chuño in the Peruvian Andes: Regional Variants and Effect on the Mineral Content of Native Potato Cultivars , 2010, Economic Botany.

[2]  J. C. Miller,et al.  Stability and Broad-Sense Heritability of Mineral Content in Potato: Iron , 2010, American Journal of Potato Research.

[3]  R. Flores,et al.  El sector papa en la region andina: Diagnostico y elementos para una vision estrategica (Bolivia, Ecuador y Peru). , 2010 .

[4]  B. Thompson,et al.  Combating micronutrient deficiencies: food-based approaches. , 2010 .

[5]  M. Bonierbale,et al.  Protein, iron, zinc and calcium concentrations of potatoes following traditional processing as “chuño” , 2009 .

[6]  S. Brush,et al.  Dynamics of Andean potato agriculture , 2008, Economic Botany.

[7]  M. Bonierbale,et al.  Fe bioavailability in Potato (Solanum tuberosum) , 2007 .

[8]  M. Bonierbale,et al.  Iron and zinc concentration of native Andean potato cultivars from a human nutrition perspective , 2007 .

[9]  Michael J. Potts,et al.  Nutritious subsistence food systems , 2007 .

[10]  D. V. Ollilainen,et al.  Glycoalkaloid Content and Starch Structure in Solanum Species and Interspecific Somatic Potato Hybrids , 2007 .

[11]  J. Hawkes,et al.  Breeding of the cultivated potato species Solanum x juzepczukii Buk. and Solanum x curtilobum Juz. etBuk. , 1980, Euphytica.

[12]  Robert E Black,et al.  Zinc deficiency, infectious disease and mortality in the developing world. , 2003, The Journal of nutrition.

[13]  M. A. Graham Seasonal dietary stress in Peruvian children. , 2003, Journal of tropical pediatrics.

[14]  R. Glahn,et al.  Micronutrient bioavailability techniques: Accuracy, problems and limitations , 1999 .

[15]  L. Rooney,et al.  Changes in Corn and Sorghum During Nixtamalization and Tortilla Baking , 1989 .

[16]  J. Woolfe The potato in the human diet: Preface , 1987 .

[17]  R. Werge Potato processing in the central highlands of Peru , 1979 .

[18]  S. F. Herb,et al.  Glycoalkaloid composition of wild and cultivated tuber-bearing Solanum species of potential value in potato breeding programs , 1978 .

[19]  J. Murra,et al.  Formaciones economicas y politicas del mundo andino. , 1976 .

[20]  J. Hoff,et al.  Chemical composition of potato cell wall , 1969 .