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Protein combining

From Wikipedia, the free encyclopedia

Protein combining or protein complementing is a dietary theory for protein nutrition that purports to optimize the biological value of protein intake. According to the theory, individual vegetarian and vegan foods may provide an insufficient amount of some essential amino acids, making protein combining with multiple complementary foods necessary to obtain a meal with "complete protein". However, the terms complete and incomplete are outdated in relation to plant protein. In fact, all plant foods contain all 20 amino acids including the 9 essential amino acids in varying amounts.[1] As of 2016, the position of the Academy of Nutrition and Dietetics is that protein from a variety of plant foods eaten during the course of a day supplies enough of all essential amino acids when caloric requirements are met.[2]

Historically, protein combining was promoted as a method of compensating for supposed protein deficiencies in most vegetables as foods (e.g., rice and beans), found in limiting percentages revealed in their respective amino acid profiles. In the 1970s, the original vegetarian nutrition guidelines became dogma. Though it is undisputed that diverse foods can be thoughtfully combined to make a more nutritious meal, a general consensus has emerged among nutrition scientists and writers contrary the earlier dogma. Studies on essential amino acid contents in plant proteins have shown that vegetarians and vegans typically do not need to complement plant proteins in each meal to reach the desired level of essential amino acids as long as their diets are varied and caloric requirements are met.[3]

Concept

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Protein nutrition is complex because any proteinogenic amino acid may be the limiting factor in metabolism. Mixing livestock feeds can optimize for growth, or minimize cost while maintaining adequate growth. Similarly, human nutrition is subject to Liebig's law of the minimum: The lowest level of one of the essential amino acids will be the limiting factor in metabolism.

If the content of a single indispensable amino acid in the diet is less than the individual’s requirement, then it will limit the utilization of other amino acids and thus prevent the normal rates of synthesis even when the total nitrogen intake level is adequate. Thus the "limiting amino acid" will determine the nutritional value of the total nitrogen or protein in the diet.[4]

Plants are thus rated as protein sources by their limiting amino acids.[5]

Examples of "limiting" amino acids in plant protein

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According to WHO, human need for proteins is 0.66 g per kg of bodyweight per day.[6] A 70 kg person has an estimated protein requirement of 46.2g (70 kg x 0,66 g/kg).

In addition, there is a specific need of essential amino acids quantities. See Essential amino acid#Recommended daily intake for a table of the values; the tables below use a percentage of the requirement.

Rice and chickpeas as protein sources, in 46.2 g of protein (daily requirement)
Amino acid Amount (mg) in rice protein (612g of whole rice)[7] % WHO requirement Amount (mg) in chickpea protein (522g of canned chickpeas)[8] % WHO requirement
Histidine 1236 176% 1274 182%
Isoleucine 2056 146% 1984 141%
Leucine 4021 144% 3294 118%
Lysine 1854 88% 3095 147%
Methionine 1095 156% 606 87%
Phenylalanine 2509 143% 2479 141%
Threonine 1781 169% 1717 163%
Tryptophan 618 220% 444 158%
Valine 2852 156% 1942 106%

In the above examples, neither whole rice nor canned chickpeas have sufficient amounts of all required amino acids when used as the only source of 46.2 g of daily protein. The insufficient amino acid is called the limiting amino acid: lysine in rice and methionine in chickpeas. Consuming the specific quantity for long periods of time might result in deficiency of the amino acid.

Rice and chickpeas as separate protein sources, 50-50 ratio (23.1g each)
Amino acid Amount (mg) in rice protein (~306g of whole rice)[7] Amount in chickpea protein (~261g of canned chickpeas)[8] Combined amount (mg) WHO recommended intake amount (mg), 70 kg % WHO requirement
Histidine 618 637 1255 700 179%
Isoleucine 1028 992 2020 1400 144%
Leucine 2011 1647 3658 2790 131%
Lysine 927 1548 2475 2100 118%
Methionine 548 303 851 700 122%
Phenylalanine 1254 1240 2494 1750 143%
Threonine 891 858 1749 1050 167%
Tryptophan 309 222 531 280 190%
Valine 1426 971 2397 1820 132%

In the above example, the combination of whole rice and canned chickpeas has no limiting amino acids. This means that consuming only rice and chickpeas, in these specific quantities of 306g/day and 261g/day respectively, for long periods of time, would not result in any of the essential amino acid deficiency, at least to the extent they are metabolized at the time.

As the data of the example show, all essential amino acids are found in a specific plant. However, one or more of them may be limiting. For this reason, vegan and vegetarian diets need to be varied in terms of plants consumed.

Plant protein research

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The first biochemist to enter the field was Karl Heinrich Ritthausen, a student of Justus von Liebig. Thomas Burr Osborne continued what Ritthausen started and published The Vegetable Proteins in 1909. Thus Yale University was the early center of protein nutrition, where William Cumming Rose was a student. Osborne also worked to determine the essentials, and later led the Biochemistry Department at the University of Chicago.

When Ritthausen died in 1912, Osborne praised his efforts in biochemistry:

As a result of his later work he proved that wide differences exist between different food proteins; and he was the first to direct attention to this fact, and to discuss its probable bearing on their relative value in nutrition.[9]

Osborne then joined forces with Lafayette Mendel at the Connecticut Agricultural Experiment Station to determine the essential amino acids.

In the 1950s and 1960s, Nevin S. Scrimshaw took this knowledge to India and Guatemala. He designed meals using local vegetables to fight against the scourge of kwashiorkor. In Guatemala he used the combination of cottonseed flour with maize, while in India he combined peanut flour with wheat.[10]

Popularization

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In 1954, Adelle Davis published Let's Eat Right to Keep Fit, which described the importance of combining "incomplete" proteins to make "complete" proteins, and advised that any incomplete proteins not complemented within one hour could not be used by the body.[11]

In 1971, Frances Moore Lappé published Diet for a Small Planet, which explained how essential amino acids might be obtained from complementary sources in vegetarian nutrition. The book became a bestseller :

An extension of a one-page handout that Lappé had circulated among her fellow improvisors in Berkeley, Diet for a Small Planet (1971) soon became the vegetarian text of the ecology movement, selling in the next ten years almost two million copies in three editions and six languages.[12]

Lappé wrote:

Complementary protein combinations make for delicious recipes – they are combinations that formed the basis of the world’s traditional cuisines. We use them naturally in our cooking without even being aware of it. The three most common complementary protein combinations are:
  1. Grains (rice, corn, wheat, barley, etc.) + legumes (peas, beans, lentils)
  2. Grains and milk products
  3. Seeds (Sesame or sunflower) +legumes[13]: 238 

In 1975, both Vogue and American Journal of Nursing carried articles describing the principles and practice of protein combining.[14][15] For a time, The American National Research Council and the American Dietetic Association (ADA) cautioned vegetarians to be sure to combine their proteins.[16]

Protein combining reached the pages of a general chemistry textbook in 1982:

There is an increased possibility of protein deficiency with a strictly vegetable diet, unless the vegetable sources are carefully combined so that they complement one another.

— Stanley E. Manahan, General Applied Chemistry, second edition, page 473

In 1985, the principle of protein combining was explained by J. Rigó:

The biological value of proteins in general, hence also of grain-proteins, is fundamentally determined by the ratio between the essential amino acids to be found in cereals and the requirement of essential amino acids of the living creature, consuming protein...the most important way of raising the biological value ... [is] given by the technique of complementing.[17]

In 2011 PLOS ONE published an article investigating the specifics of protein combining for 1251 plant-based foods. The bases of reference are the amino acids indispensable to human nutrition, and the ideal proportioning of these amino acids in a meal. They explain, "complementation involves consuming two or more foods together to yield an amino acid pattern that is better than the sum of the two foods alone."[18] In contrast to pairings based on food groups, such as pairing a grain with a bean, the investigators reported that pairing by food group was not supported by their work: "Examining the top 100 pairings for each food, we found no consistent pattern of food group-food group pairings."[18]

Criticism

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Protein combining has drawn criticism as an unnecessary complicating factor in nutrition.

In 1981, Frances Moore Lappé changed her position on protein combining from a decade prior in a revised edition of Diet for a Small Planet in which she wrote:

"In 1971 I stressed protein complementarity because I assumed that the only way to get enough protein ... was to create a protein as usable by the body as animal protein. In combating the myth that meat is the only way to get high-quality protein, I reinforced another myth. I gave the impression that in order to get enough protein without meat, considerable care was needed in choosing foods. Actually, it is much easier than I thought.
"With three important exceptions, there is little danger of protein deficiency in a plant food diet. The exceptions are diets very heavily dependent on [1] fruit or on [2] some tubers, such as sweet potatoes or cassava, or on [3] junk food (refined flours, sugars, and fat). Fortunately, relatively few people in the world try to survive on diets in which these foods are virtually the sole source of calories. In all other diets, if people are getting enough calories, they are virtually certain of getting enough protein."[13]: 162 

Necessity of protein combining was not asserted. Rather, the increased biological value of meals where proteins are combined was noted. In a concession, Lappé removed from the second edition "charts that indicate exact proportions of complementary proteins".[13]: 239 

The American Dietetic Association reversed itself in its 1988 position paper on vegetarianism. Suzanne Havala, the primary author of the paper, recalls the research process:

There was no basis for [protein combining] that I could see.... I began calling around and talking to people and asking them what the justification was for saying that you had to complement proteins, and there was none. And what I got instead was some interesting insight from people who were knowledgeable and actually felt that there was probably no need to complement proteins. So we went ahead and made that change in the paper. [Note: The paper was approved by peer review and by a delegation vote before becoming official.]

In 1994, Vernon Young and Peter Pellett published their paper that became the definitive contemporary guide to protein metabolism in humans. It also confirmed that complementing proteins at meals was totally unnecessary. Thus, people who avoid consuming animal protein do not need to be at all concerned about amino acid imbalances from the plant proteins that make up their usual diets.[5]

While many plant proteins are lower in one or more essential amino acids than animal proteins, especially lysine, and to a lesser extent methionine and threonine, eating a variety of plants can serve as a well-balanced and complete source of amino acids.[5]

In 2009, the American Dietetic Association wrote:

Plant protein can meet protein requirements when a variety of plant foods is consumed and energy needs are met. Research indicates that an assortment of plant foods eaten over the course of a day can provide all essential amino acids and ensure adequate nitrogen retention and use in healthy adults, thus, complementary proteins do not need to be consumed at the same meal.[19]

The American Heart Association now states:

You don’t need to eat foods from animals to have enough protein in your diet. Plant proteins alone can provide enough of the essential and non-essential amino acids, as long as sources of dietary protein are varied and caloric intake is high enough to meet energy needs. Whole grains, legumes, vegetables, seeds and nuts all contain both essential and non-essential amino acids. You don’t need to consciously combine these foods (“complementary proteins”) within a given meal.[20]

Some institutions use the Protein Digestibility Corrected Amino Acid Score to assess diets without consideration of protein combining and hence find the use of combinations to be a challenge to their methodology.[citation needed]

References

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  1. ^ Mariotti; Gardner (2019-11-04). "Dietary Protein and Amino Acids in Vegetarian Diets—A Review". Nutrients. 11 (11): 2661. doi:10.3390/nu11112661. ISSN 2072-6643. PMC 6893534. PMID 31690027.
  2. ^ Melina, Vesanto; Craig, Winston; Levin, Susan (2016-12-01). "Position of the Academy of Nutrition and Dietetics: Vegetarian Diets". Journal of the Academy of Nutrition and Dietetics. 116 (12): 1971. doi:10.1016/j.jand.2016.09.025. ISSN 2212-2672. PMID 27886704. S2CID 4984228. PDF
  3. ^ Young, V. R.; Pellett, P. L. (1994-05-01) [1994]. "Plant proteins in relation to human protein and amino acid nutrition". The American Journal of Clinical Nutrition. 59 (5 Suppl). ABSTRACT: 1203S–1212S. doi:10.1093/ajcn/59.5.1203s. ISSN 0002-9165. PMID 8172124.Young, V. R.; Pellett, P. L. (1994-05-01) [1994]. "Plant proteins in relation to human protein and amino acid nutrition" (PDF). The American Journal of Clinical Nutrition. 59 (5 Suppl). FULL ARTICLE - TABLE 11: 1203S–1212S. doi:10.1093/ajcn/59.5.1203s. ISSN 0002-9165. PMID 8172124. Archived from the original (PDF) on 2017-10-13. Retrieved 2017-05-22.
  4. ^ Food and Nutrition Board of Institute of Medicine (2005) Dietary Reference Intakes for Protein and Amino Acids, page 685, from National Academies Press
  5. ^ a b c Young VR, Pellett PL (1994). "Plant proteins in relation to human protein and amino acid nutrition" (PDF). American Journal of Clinical Nutrition. 59 (5 Suppl): 1203S–1212S. doi:10.1093/ajcn/59.5.1203s. PMID 8172124.
  6. ^ Joint WHO/FAO/UNU Expert Consultation (2007). "Protein and amino acid requirements in human nutrition" (PDF). World Health Organization Technical Report Series (935): pag 88 – table 4. ISSN 0512-3054. PMID 18330140.
  7. ^ a b
  8. ^ a b
  9. ^ Osborne, Thomas Burr (1913) "In Memoriam: Heinrich Ritthausen", Biochemical Bulletin 2:338, published by the Columbia University Biochemical Association
  10. ^ Scrimshaw obituary from Massachusetts Institute of Technology
  11. ^ Davis, Adelle (1954). Let's Eat Right to Keep Fit. Harcourt, Brace. ISBN 4-87187-961-5.
  12. ^ Warren Belasco (1989) Appetite for Change: how the counterculture took on the food industry 1966 — 1988, page 56, Pantheon Books ISBN 0394543998
  13. ^ a b c Lappé, Frances Moore (1981) Diet for a Small Planet, ISBN 0-345-32120-0
  14. ^ Judith S. Stern (1975) "How to stay well on a vegetarian diet and save money too!", Vogue 165(2):150,1
  15. ^ Eleanor R. Williams (1975) Making Vegetarian Diets Nutritious, American Journal of Nursing 75(12):2168–73 from JSTOR
  16. ^ Maurer, Donna. (2002). Vegetarianism: Movement or Moment? Philadelphia: Temple University Press. ISBN 1-56639-936-X. p. 37
  17. ^ Rigó, J. (1985) "Nutritional Functions of Cereals", in Amino Acid Composition and Biological Value of Cereal, Radomir Lásztity & Máté Hidvégi editors, International Association for Cereal Chemistry
  18. ^ a b Woolf, P. J.; Fu, L. L.; Basu, A. (2011). Haslam, Niall James (ed.). "VProtein: Identifying Optimal Amino Acid Complements from Plant-Based Foods". PLOS ONE. 6 (4): e18836. Bibcode:2011PLoSO...618836W. doi:10.1371/journal.pone.0018836. PMC 3081312. PMID 21526128.
  19. ^ Craig, WJ; Mangels, AR (July 2009). "Position of the American Dietetic Association: Vegetarian Diets" (PDF). Journal of the American Dietetic Association. 109 (7): 1267–1268. doi:10.1016/j.jada.2009.05.027. PMID 19562864. S2CID 7906168. Retrieved 13 January 2017.
  20. ^ "Vegetarian Diets". 2016-09-26. Archived from the original on 2020-10-01.