Natural Toxins in Sprouted Seeds

NATURAL TOXINS IN SPROUTED SEEDS: SEPARATING MYTH FROM REALITY

By Warren Peary and William Peavy, Ph.D.

Natural toxins in food has become a hot and controversial subject recently. In the last few years, some popular writers have attacked sprouts (particularly alfalfa and legume sprouts) as containing natural toxins. These writers may have heard something about a lathyrogen toxin, saponins, canavanine, and maybe other nasty-sounding toxins, and concluded that the sprouts of legumes are toxic in the raw state and so should not be eaten. These statements are taken out of context.

LATHYROGEN TOXIN

One of the natural toxins that has been mentioned comes from peas of the genus Lathyrus. It is blamed for causing a disease known as lathyrism. Lathyrism causes paralysis in the legs in susceptible individuals and is believed to be caused by a toxic amino acid. This sounds scary, but it’s not, because peas of the genus Lathyrus are NOT edible peas. The toxin is found only in the seeds of certain Lathyrus species (L. sativus, L. cicera, L. clymenum).1 Edible peas and beans are of the genera Cicer, Glycine, Phaseolus, Pisum, and Vigna. They DO NOT contain any such toxin.

Non-edible peas of the genus Lathyrus include sweet peas, which are ornamentals grown for their scented flowers. In India, where food is often scarce, some people have resorted to eating a non-edible pea known as Lathyrus sativus. It is often called “chickpea” but is NOT the same chickpea eaten in this country or any other developed country. The edible chickpea is of the genus Cicer and in botany is known as Cicer arieti-num.

Outbreaks of lathyrism in India have been blamed on eating large amounts of the non-edible chickpea without proper cooking. Well-cooked, it is safe to eat. But it shouldn’t matter to us at all because it is considered an inedible species.

There are at least 1,500 species of legumes within one of three subfamilies of the family Leguminosae (Latin for legume). Of these 1,500 species, only a few dozen are regularly used as human food. Of course there are toxins in many of the raw legumes not usually used for human food; that’s why humans have learned not to eat them. This is the first mistake sometimes made in warning about natural toxins – talking about a toxin that’s found in some non-edible species people don’t or shouldn’t eat to begin with!

SAPONINS

The second mistake often made in talking about natural toxins is to call something toxic that, in the body, is not toxic at all but rather, is beneficial. Such is the case with saponins.

Saponins are a compound found in legumes and legume sprouts. They are toxic to red blood cells only in vitro (outside of the body in a test tube) but harmless when ingested.2-3 In fact, Saponins appear to be beneficial, being responsible for a major part of the cholesterol- lowering effect of legumes.3 Perhaps it is more than coincidence that the increase in the incidence of heart disease in the 20th century in the Western countries coincides with a decline in the consumption of saponin-rich legumes. Saponins also seem to be anticarcinogens; in one study they inhibited colon cancer.4

Even some of the most beneficial nutrients, such as vitamin C, can be shown to be toxic under certain laboratory conditions. Vitamin C is considered an important antioxidant, and substantial evidence shows that it is involved in cancer prevention.5 Yet under the right experimental conditions, in the presence of iron (Fe III) or copper (Cu II) ions, ascorbic acid can actually cause the formation of harmful free radicals.6 Does this mean you should try to avoid vitamin C? Absolutely not! These experimental conditions do not appear to be relevant to what goes on in our bodies.

CANAVANINE

The third mistake made in warning about some natural toxins is failing to say that the amount encountered in a food is so minuscule that it is completely insignificant. Such is the case with a toxin called canavanine, which is found in alfalfa seeds. While some writers may make canavanine sound like a dangerous carcinogen – it isn’t. Canavanine is a non-protein amino acid that’s toxic in high amounts. In the dry seed it serves as a storage protein, a growth inhibitor, and a defense against natural predators. As you might guess, as the sprout grows, canavanine falls rapidly to insignificant levels.7 The text, Seed Physiology, clearly states that “Canavanine…is non-toxic to mammals at low concentration.”8 Canavanine is so irrelevant that the 1980 text, Toxic Constituents of Plant Foodstuffs, doesn’t even mention it. A 150-pound human would have to consume 14,000 milligrams of canavanine all at once for it to be toxic at the same level it is toxic in mice.9 This is an incredible amount! It is doubtful that with a generous helping of alfalfa sprouts, you would get more than a few milligrams. There is NO canavanine at all in other legumes that are commonly used as human food.7, 10

Even in toxic amounts, canavanine has nothing to do with cancer. In very high, toxic amounts it can cause a lupus-like anemia in susceptible animals due to an alteration in the red blood cells. These studies are not relevant to the human diet. The minute doses found in the diet are completely irrelevant and harmless.

Just remember that most substances can show some kind of toxic effect at a high enough dose. Vitamin A, selenium, copper, zinc, and iron will all kill you at a high enough dose. So don’t stop eating alfalfa sprouts any more than you would any other food because of some minute toxin that may be present. They are a good source of vitamin C, folic acid, and other protective compounds.

ANTI-NUTRIENTS IN SPROUTED LEGUMES

As far as the sprouts of other edible legumes go, the only other toxins for which any concern has been raised is for a class known as anti- nutrients. These are sub-stances that bind enzymes or nutrients and inhibit the absorption of the nutrients. The commonly alleged anti- nutrients are protease inhibitors, amylase inhib-itors, phytic acid, and polyphenolic compounds such as tannins. With proper soaking and germination, none of these is anything to worry about.

Around the world, studies have been and are being conducted on the use of germinated seeds as a low-cost, highly nutritive source of human food. It is well-established that when legumes are properly soaked and germinated, their nutritive value increases greatly, usually to levels equal to or exceeding those of the cooked bean. (Nutritive value is the ability of food to provide a usable form of nutrients: protein, carbohydrates, vitamins and minerals). This has been shown for mung bean, 11-13 lentil,13-14 chickpea (garbanzo bean), 15-17 cowpea (blackeye pea), 18 pigeon pea,19 fava bean,20-21 fenugreek seeds22-23 (a member of the pea family), green & black gram,15-17 kidney bean,24-26 moth bean,27 rice bean,28 soybean,13, 29-36 and legumes in general.37-40

The increase in nutritive value in the raw sprouted seed is due to an explosion of enzyme activity, which breaks down the storage-protein and starch in the seed into amino acids, peptides, and simpler carbohydrates needed for the seed to grow. The seed is literally digesting its own protein and starch and creating amino acids in the process. Because of this process, sprouted seeds are essentially a predigested food. At the same time, the anti-nutritional factors such as enzyme inhibitors and other anti-nutrients are greatly decreased to insignificant levels or to nothing.11, 20, 22, 33, 41-65

Soaking alone causes a significant decrease in anti-nutrients, as the antinutrients are leached into the soak water. Soaking for 18 hours removed 65% of hemag-glutinin activity in peas.66 Soaking for 24 hours at room temperature removed 66% of the trypsin (protease) inhibitor activity in mung bean, 93% in lentil, 59% in chickpea, and 100% in broad bean.42 Then as germination proceeds, anti-nutrients are degraded further to lower levels or nothing. Soaking for 12 hours and 3-4 days of germination completely removed all hemagglutinating activity in mung bean and lentil.56 Soaking for 10 hours and germination for 3 days completely eliminated amylase inhibitor in lentils.62 Normal cooking removes most or all of the anti-nutrients.

ANTI-NUTRIENTS AS PROTECTORS

Some of the substances commonly referred to as anti-nutrients are actually powerful cancer-protecting phyto-chemicals. These include protease inhibitors and tannins. The problem in most diets is that we don’t get enough of these substances.

Substantial research shows that protease inhibitors are one of the most powerful anti-carcinogens we have in our arsenal. They have proven to be particularly protective against cancer of the colon, breast, and prostate. 67-72

Tannins have also been shown to give substantial protection against cancer (including cancer of the stomach and lungs) when ingested orally.72 Tannins and other polyphenols may play a role in fighting tooth decay. Evidence shows that some tannins inhibit the growth of bacteria that cause tooth decay.73

Phytates, like tannins, may also interact with digestive processes in a beneficial way. Small amounts in food slow down the absorption of sugars and regulate insulin levels. This is beneficial in the prevention and treatment of diabetes and hyperlipidemia (high blood fats).74

Small amounts of protease inhibitors, tannins, and phytates are beneficial and can be considered to be a normal part of our nutritional ecology.

ENDNOTES

1. Liener IE (ed). Toxic Constituents of Plant Foodstuffs. (Academic Press, New York, 1980) 239-260.
2. Liener IE (ed). Toxic Constituents of Plant Foodstuffs. (Academic Press, New York, 1969) 194-201.
3. Savage GP, Deo S. The nutritive value of peas. Nutr Abstr Rev 1989; 59: 66-83.
4. Messina M, Barnes S. The role of soy products in reducing risk of cancer. J Natnl Cancer Inst 1991; 83: 543-544.
5. Sies H, Stahl W, Sundquist AR. Antioxidant functions of vitamins. In: Sauberlich HE and Machlin LJ eds. Beyond Deficiency. New Views of the Function and Health Effects of Vitamins. Ann NY Acad Sci 1992; 669: 7-19, and Block G. Vitamin C status and cancer: 280-292.
6. Floyd RA. Role of oxygen free radicals in carcinogenesis and brain eschemia. FASEBJ 1990; 4: 2587-2597.
7. Bell EA. Canavanine in the Leguminosae. Biochem J 1960; 75: 618-620.
8. Murray DR ed. Seed Physiology Vol I (Academic Press, New York, 1984) 254.
9. Bell EA. Uncommon amino acids in plants. Fed Europ Biochem Soc Lett 1976; 64: 29-35.
10. Bell EA, Lackey JA, Polhill RM. Systematic significance of canavanine in the papilionoideae. Biochem Syst Ecol 1978; 6: 201-212.
11. Kataria A, Chauhan BM, Punia D. Antinutrients and protein digestibility of mung bean as affected by domestic processing and cooking. Food Chem 1989; 32(1): 9-17.
12. Kataria A, Chauhan BM, Ring SG, Gee JM. Contents & digestibility of carbohydrates of mung beans as affected by domestic processing and cooking. Plant Foods Hum Nutr 1988; 38: 51-59.
13. Kylen Am, McCready RM. Nutrients in seeds & sprouts of alfalfa, lentils, mung bean and soybeans. J Food Sci 1975; 40: 1008-1009.
14. El-Mahdy AR, Moharram YG, Aou-Smaha Or. Influence of germination on the nutritional quality of lentil seeds. Zeitschrift fur Lebensmittel- Untersuchung 1985; 181: 318
15. Jaya TV, Venkataraman LV. Influence of germination on the carbohydrate digestibility of chickpea and greengram. Ind J Nutr Diet 1981; 18: 62-68.
16. Jood S, Chauhan BM, Kappoor Ac. Contents and digestibility of carbohydrates of chickpea & black gram. Food Chem 1988; 30: 113-127.
17. Jood S, Chauhan BM, Kapoor AC. Protein digestibility of chickpea & blackgram seeds as affected by domestic processing & cooking. Plant Foods Hum Nutr 1989; 39: 149-154.
18. Ologhobo AD, Fetuga BL. Changes in carbohydrate content of germinating cowpea seeds. Food Chem 1986; 20: 117-125.
19. Obizaba IC. Effect of sprouting on the nitrogenous constituents and mineral composition of pigeon pea. Plant Food Hum Nutr 1991; 41: 21-26.
20. Ndzondzi-Bokouango G, Bau HM, Giannangeli F, Debry G. Effect of germination on the chemical composition and nutritive value of fava beans. Sciences des Aliments 1989; 9: 785-797.
21. Rahma EH, El-Bedawey AA et al. Changes in chemical & antinutritional factors and functional properties of fava beans during germination. Lebensmittel–Wissenscheft and Technologie 1987; 20: 271-276.
22. Allam MH. Chemical composition & nutritional value of fenugreek seeds during germination. Ann Agri Sci 1987; 32: 1538-1551.
23. El-Aal MHA. Changes in gross chemical composition … during germination of fenugreek seeds. Food Chem 1986; 22: 193-207.
24. El-Hag N, Haard NF, Morse RE. Influence of sprouting on the digestibility coefficient, trypsin inhibitor and globulin proteins of red kidney beans. J Food Sci 1978; 43: 1874-1875.
25. Palmer R, McIntosh, Pusztai A. The nutritive evaluation of kidney beans: the effect of nutritional value of seed germination and changes in trypsin inhibitor content. J Sci Food Agric 1973; 34: 937.
26. Pusztai A. Metabolism of trypsin-inhibitory proteins in the germinating seeds of kidney bean. Planta 1972; 107: 121-129.
27. Khokhar S, Chauhan BM. Antinutritional factors in moth bean: varietal differences & effects of methods of domestic processing & cooking. J Food Sci 1986; 51: 591-594.
28. Deepinder-Kaur, Kapoor AC. Starch & protein digestibility of rice bean. Food Chem 1990; 38: 263-272.
29. Bau HM, Debry G. Germinated soybean protein products. chemical & nutritional evaluation. J Am Oil Chem Soc 1979; 56: 160-162.
30. Boralker M, Reddy NS. Effect of roasting, germination and fermentation on the digestibility of starch and protein present in soybean. Nutr Rep Intl 1985; 31: 833-836.
31. Desikachar HSR, De SS. Role of inhibitors in soybeans. Science 1947; 106: 421-422.
32. Desikachar HSR, De SS. The tryptic inhibitor and the availability of cystine and methionine in raw and germinated soyabeans. Biochim Biophys Acta 1950; 5: 285-289.
33. Everson G, Steenbock H, Cederquist DC, Parsons HT. The effect of germination, the stage of maturity, and variety upon the nutritive value of soybean protein. J Nutr 1944; 27: 225-229
34. Jimenez MF et al. Biochemical and nutritional studies of germinated soyabeans. Archivos Latino-americanos de Nutrición. 1985; 35: 480-490.
35. Mattingly JP, Bird HR. Effect of heating under various conditions and of sprouting on the nutritive value of soybean oil meal and of soybeans. Poultry Sci 1945; 24: 344-352.
36. Viswanatha T, De SS. Relative availability of cystine and methionine in the raw germinated and autoclaved soybeans…, Indian J Physiol Allied Sci 1951; 5: 51-58.
37. Bednarske W, Tomasik J, Piatkowska B. Processing suitability & nutritive value of field bean seeds after germination. J Sci Food Agric 1985; 36: 745-751.
38. Chattapadhgay H, Bannerjee S. Effect of germination on biological value of proteins and trypsin inhibitor activity of common Indian pulses. Ind J Med Res 1953; 41: 185-189.
39. Fordham JR, Wells CE, Chen LH. Sprouting of seeds and nutrient composition of seeds and sprouts. J Food Sci 1975; 40: 552-556.
40. Kakade ML, Liener IE. In: Recheigh M ed. Man, Food, and Nutrition (CRC Press, Cleveland, 1973) 237-238.
41. Abbey BW, Mark-Balm T. Nutritional quality of weaning foods prepared from composite flours of maize, ungerminated & germinated cowpea. Nutr Re Intl 1988; 38: 519-526.
42. Al-Bakir AY, Sachde AG, Naoum IE. Occurrence and stability of trypsin inhibitors in Iraqi local legumes. J Agric Food Chem 1982; 30: 1184-1185.
43. Bansal KK, Dhindsa KS, Batra VIP. Trypsin inhibitor & hemagglutinin activities in chickpea: effects of heat and germination. J Food Sci Tech 1988; 25: 46-48.
44. Batra VIP. Effects of cooking and germination on hemagglutinin activity in lentil. Ind J Nutr Diet 1987; 24: 15-19.
45. Bressani R, Elias LG. The nutritional role of polyphenols in beans. In: Hulse JH ed. Polyphenols in Cereals and Legumes (IDRC, Ottawa, Canada, 1980) 61-68.
46. Chen LH, Thacker RR, Pan SH. Effect of germination on hemagglutinating activity of pea and bean seeds. Food Sci 1977; 42: 1666-1668.
47. Chrispeels MJ and Baumgartner B. Trypsin inhibitor in mung bean cotyledons. Plant Physiol 1978; 61: 617-623.
48. Deepinder-Kaur, Kapoor AC. Some antinutritional factors in rice bean. Food Chem 1990; 37: 171-179.
49. El-Mahdy AR, El-Sebaiy LA. Changes in phytate & minerals during g ermination & cooking of fenugreek seeds. Food Chem 1982; 9: 149-158.
50. Eskin NAM, Wiebe S. Changes in phytate activity and phytate during germination of two fava bean cultivars. J Food Sci 1983; 48: 270-271.
51. Hobday SM, Thurman DA, Barber DJ. Proteolytic and trypsin inhibitory activities in extracts of germinating pisum sativum seeds. Phytochemistry 1973; 12:1041-1046.
52. Jood S, Chauhan BM, Kapoor AC. Polyphenols of chickpea and black gram…. J Sci Food Agric 1987; 39: 145-149.
53. Kadam SS, Gharpade VM, Adsule RN, Salunkhe DK. Trypsin inhibitor in moth bean: thermal stability and changes during germination and cooking. Plant Food Hum Nutr 1986; 36: 43-46.
54. Kataria A, Chauhan BM, Gandhi S. Effect of domestic processing and cooking on the antinutrients of black gram. Food Chem 1988; 30:149-156.
55. Kataria A, Chauhan BM, Punia D. Antinutrients in black gram and mung bean. Plant Food Hum Nutr 1989; 39: 257-266.
56. Khader V. Nutritional studies on fermented, germinated and baked soybean preparations. J Plant Foods 1983; 5: 31-37.
57. Murray DR ed. Seed Physiology (1980) 102.
58. Nielsen SS, Liener IE. Effect of germination on trypsin inhibitor and hemoagglutinating activities in Phaseolus vulgaris. J Food Sci 1988; 53: 298-301.
59. Ogun PO, Markakis P, Chenoweth W. Effect of processing on certain antinutrients in cowpeas. Food Sci 1989; 54: 1084-1085
60. Sathe SK, et al. Effects of germination on proteins, raffinose oligosaccharides, and antinutritional factors in great northern beans. J Food Sci 1983; 48: 1796-1800.
61. Sattar A, Aha S, Akhtar MA. Effect of irradiation and germination on trypsin inhibitor and protein content of chickpea. Intl J Vit Nutr Res 1990; 60: 402-406.
62. Shekib LA, El-Iraqui SM, Abo-Bakr TM. Studies on amylase inhibitors in some Egyptian legume seeds. Plant Foods for Human Nutrition 1988; 38: 325-332.
63. Trugo LC, et al. Oligosaccharide compostion & trypsin inhibitor activity of P. vulgaris and the effect of germination. Food Chem 1990; 36: 53-61.
64. Wilson KA, Tan-Wilson AL. Characterization of the protease that initiates the degradation of the trypsin inhibitor in germinating mung bean. Plant Physiol 1987; 84: 93-98.
65. Valdebouze P, et al. Content & distribution of trypsin inhibitors and haemegglutinins in some legume seeds. Can J Plant Sci 1980; 60: 695-701.
66. Bender AE. Haemagglutinins in beans. Food Chem 1983; 11: 309-320.
67. Natnl. Res. Council. Inhibitors of Carcinogenesis. In: Diet, Nutrition and Cancer. 358-370.
68. Ramel C. et al. Inhibitors of mutagenesis and their relevance to carcinogenesis. Mutation Res 1986; 168: 47-65.
69. Troll W, Kennedy AR (eds.) Protease Inhibitors as Cancer Chemopreventive Agents (Plenum Press, New York, 1993).
70. Troll W. and Wiesner R. Protease inhibitors: possible anticarcinogens in edible seeds. Prostate 1983; 4: 345-349
71. Wattenberg LW. Inhibition of neoplasia by minor dietary constitutents. Cancer Res (suppl) 1983; 43: 2448s-2453s.
72. Yauclow J, Finlay TH, Kennedy AR, Troll W. Bowman-Birk soybean protease inhibitor as an anticarcinogen. Cancer Res 1983; 43: 2454s-2459s.
73. Moles S and Waterman PG. Stimulatory effects of tannins and cholic acid on tryptic hydrolysis of proteins: ecological implications. J Chem Ecol 1985; 11: 1323-1332.
74. Kakiuchi N. et al. Studies on dental caries prevention by traditional medicines. VIII: Inhibitory effects of various tannins on glucan synthesis by glucosyltransferase from streptococcus mutans. Chem Pharm Bull 1986; 34: 720-725.

Warren Peary is an investigative health journalist. William S. Peavy holds a doctoral degree from Kansas State University in horticultural science. They can be reached at 316 Horton Lane NW, Albuquerque, NM 87114.