Complete protein
View on Wikipediafrom Wikipedia
A complete protein or whole protein is a food source of protein that contains an adequate proportion of each of the nine essential amino acids necessary in the human diet.[1][2][3][4][5]
Concept
[edit]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.[6]
Protein sources are thus rated by their limiting amino acids.[7]
Most people eat a varied diet with multiple sources of protein. Incomplete sources can complement each other and become complete when combined.[8] Combining does not need to happen for every single meal: so long as the diet is varied and meets caloric needs, even vegans and vegetarians – people who tend to have more "incomplete protein" in their diet – can easily meet their amino acid needs. In other words, most people do not need to consider the completeness of proteins of single foods.[9]
Amino acid profile
[edit]The following table lists the optimal profile of the nine essential amino acids in the human diet, which comprises complete protein, as recommended by the US Institute of Medicine's Food and Nutrition Board. The foodstuffs listed for comparison show the essential amino acid content per unit of the total protein of the food; 100g of spinach, for example, only contains 2.9g of protein (6% Daily Value), and of that protein 1.36% is tryptophan.[2][10](note that the examples have not been corrected for digestibility)
| Essential amino acid | mg/g of protein | percentage of total protein | raw, whole chicken egg[11] | quinoa[12] | raw spinach[13] |
|---|---|---|---|---|---|
| Tryptophan | 7 | 0.7% | 1.33% | 1% | 1.36% |
| Threonine | 27 | 2.7% | 4.42% | 3.2% | 4.27% |
| Isoleucine | 25 | 2.5% | 5.34% | 4.2% | 5.14% |
| Leucine | 55 | 5.5% | 8.65% | 7.3% | 7.8% |
| Lysine | 51 | 5.1% | 7.27% | 6.1% | 6.08% |
| Methionine+Cystine | 25 | 2.5% | 5.18% | 2.7%+1.3% | 1.85%+1.22% |
| Phenylalanine+Tyrosine | 47 | 4.7% | 9.39% | 4.3%+3.6% | 4.51%+3.78% |
| Valine | 32 | 3.2% | 6.83% | 5% | 5.63% |
| Histidine | 18 | 1.8% | 2.45% | 3.1% | 2.24% |
| Total | 287 | 28.7% | 50.86% | 41.8% | 43.88% |
Total adult daily intake
[edit]The second column in the following table shows the amino acid requirements of adults as recommended by the World Health Organization[14] calculated for a 62 kg (137 lb) adult. Recommended Daily Intake is based on 2,000 kilocalories (8,400 kJ) per day,[15] which could be appropriate for a 70 kg (150 lb) adult.
| Essential amino acid | Required mg/day for a 62 kg (137 lb) adult |
|---|---|
| Tryptophan | 248 |
| Threonine | 930 |
| Isoleucine | 1240 |
| Leucine | 2418 |
| Lysine | 1860 |
| Methionine+Cystine | 930 |
| Phenylalanine+Tyrosine | 1550 |
| Valine | 1612 |
| Histidine | 620 |
| Total | 11,408 milligrams (11.408 g) |
| Total Protein | 46 to 56 grams (46,000 to 56,000 mg) |
See also
[edit]References
[edit]- ^ "Protein in diet". Medline Plus Medical Encyclopedia. U.S. National Library of Medicine and National Institute of Health. September 2, 2003. Retrieved 2006-10-28.
- ^ a b Dietary Reference Intakes for Energy, Carbohydrate, Fiber, Fat, Fatty Acids, Cholesterol, Protein, and Amino Acids. Food and Nutrition Board of Institute of Medicine, National Academies Press. 2005. p. 691. doi:10.17226/10490. ISBN 978-0-309-08525-0.
- ^ "All About the Protein Foods Group". US Department of Agriculture. 3 November 2017. Retrieved 20 May 2018.
- ^ Mariotti, François; Gardner, Christopher D. (Nov 2019). "Dietary Protein and Amino Acids in Vegetarian Diets—A Review". Nutrients. 11 (11): 2661. doi:10.3390/nu11112661. PMC 6893534. PMID 31690027.
- ^ Young, VR; Pellett, PL (May 1994). "Plant proteins in relation to human protein and amino acid nutrition". The American Journal of Clinical Nutrition. 59 (5 Suppl): 1203S–1212S. doi:10.1093/ajcn/59.5.1203S. PMID 8172124.
- ^ Food and Nutrition Board of Institute of Medicine (2005) Dietary Reference Intakes for Protein and Amino Acids, page 685, from National Academies Press
- ^ 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.
- ^ "What's a Complete Protein and Should You Care?". Cleveland Clinic. Retrieved 2024-04-19.
- ^ 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
- ^ "Protein quality". Conde Nast, Nutritiondata.com. 2018. Retrieved 13 April 2020.
- ^ "Egg, whole, raw, fresh, nutrition facts per 100 grams". Conde Nast, Nutritiondata.com. 2018. Retrieved 13 April 2020.
- ^ "Quinoa, cooked, nutrition facts per 100 grams". Conde Nast, Nutritiondata.com. 2018. Retrieved 13 April 2020.
- ^ "Spinach, raw, nutrition facts per 100 grams". Conde Nast, Nutritiondata.com. 2018. Retrieved 13 April 2020.
- ^ "Protein and Amino Acid Requirements in Human Nutrition" (PDF). World Health Organization. 2007. Retrieved January 21, 2021.
- ^ "Guidance for Industry: A Food Labeling Guide". U.S. Food & Drug Administration. US FDA. Archived from the original on 2017-10-31. Retrieved 14 January 2017.
Complete protein
View on Grokipediafrom Grokipedia
Fundamentals
Definition
A complete protein is a source of protein that contains an adequate proportion of each of the nine essential amino acids required by humans for protein synthesis, tissue repair, and other metabolic functions.[4] These essential amino acids—histidine, isoleucine, leucine, lysine, methionine, phenylalanine, threonine, tryptophan, and valine—cannot be synthesized by the human body and must be obtained through the diet.[4] Complete proteins thus provide all these amino acids in proportions sufficient to support optimal health without supplementation from other sources.[2] In contrast, incomplete proteins lack one or more essential amino acids in sufficient quantities, making them unable to fully meet human nutritional needs on their own.[4] Such proteins, often found in single plant-based foods, require strategic dietary combinations—such as pairing grains with legumes—to achieve a balanced intake of all essential amino acids.[2] This distinction underscores the importance of dietary variety, particularly for those relying on plant sources, to ensure complete protein adequacy.[4] The concept of complete proteins originated in early 20th-century nutrition science, with the term first appearing in 1918 when John Harvey Kellogg described soybean protein as "complete" for its ability to substitute for animal proteins.[5] It gained rigorous scientific foundation in the 1930s through the work of William C. Rose, who identified and quantified the essential amino acids via experiments on nitrogen balance and growth in rats and humans, establishing that diets must supply these specific amino acids for protein completeness.[6]Essential amino acids
Essential amino acids are those that the human body cannot synthesize de novo and must obtain from the diet to support protein synthesis and other metabolic functions. There are nine such amino acids: histidine, isoleucine, leucine, lysine, methionine, phenylalanine, threonine, tryptophan, and valine.[7] Each essential amino acid has distinct chemical properties determined by its side chain (R-group), which influences its polarity, charge, and interactions in proteins. Histidine features a basic imidazole ring in its side chain, allowing it to act as a proton donor or acceptor in enzymatic reactions. Isoleucine and valine possess aliphatic, branched hydrophobic side chains, contributing to the hydrophobic cores of proteins, while leucine shares a similar branched-chain structure but with an isobutyl group. Lysine has a basic, long side chain ending in a positively charged amino group, enabling ionic interactions. Methionine contains a sulfur atom in a thioether linkage within its hydrophobic side chain. Phenylalanine and tryptophan are aromatic, with phenylalanine bearing a benzene ring and tryptophan an indole ring, both promoting hydrophobic and π-π stacking interactions. Threonine includes a polar hydroxyl group on its side chain, facilitating hydrogen bonding.[8][7] These amino acids play critical physiological roles beyond basic protein building. Histidine is vital for the active sites of many enzymes, such as in hemoglobin for oxygen transport, and serves as a precursor to histamine, which mediates immune responses and gastric acid secretion. Isoleucine, leucine, and valine—collectively known as branched-chain amino acids (BCAAs)—are key for muscle protein synthesis and energy production during exercise; leucine particularly activates the mTOR pathway to stimulate muscle growth, while isoleucine and valine support tissue repair and metabolic regulation. Lysine is essential for collagen and carnitine synthesis, aiding connective tissue formation and fatty acid metabolism, respectively. Methionine functions as a methyl donor via S-adenosylmethionine, supporting DNA methylation and detoxification processes. Phenylalanine is a precursor to tyrosine, which is further converted to neurotransmitters like dopamine and norepinephrine. Threonine contributes to mucin production for gut barrier function and immune cell proliferation. Tryptophan is the sole precursor to serotonin, regulating mood, sleep, and appetite, and also to niacin, a component of NAD+ for energy metabolism.[7][9][10] Daily requirements for essential amino acids are expressed in milligrams per kilogram of body weight per day (mg/kg/d) for healthy adults, based on nitrogen balance and indicator amino acid oxidation studies. These values ensure adequate provision for maintenance and minimal growth without excess. The following table summarizes the average requirements from the 2007 FAO/WHO/UNU expert consultation:| Amino Acid | Requirement (mg/kg/d) |
|---|---|
| Histidine | 10 |
| Isoleucine | 20 |
| Leucine | 39 |
| Lysine | 30 |
| Methionine + Cysteine | 15 |
| Phenylalanine + Tyrosine | 25 |
| Threonine | 15 |
| Tryptophan | 4 |
| Valine | 26 |
Composition and Assessment
Amino acid profile
The ideal amino acid profile for a complete protein aligns with the reference pattern established by the Food and Agriculture Organization (FAO) and World Health Organization (WHO), which specifies the proportions of the nine essential amino acids required to meet human nutritional needs for protein synthesis and maintenance. This pattern, updated in 2013 for individuals over 3 years of age, serves as a benchmark to evaluate whether a protein source provides balanced essential amino acids without deficiencies. For instance, leucine is required at about 61 mg per gram of protein, reflecting its critical role in muscle protein synthesis. The following table summarizes the FAO/WHO 2013 reference pattern for essential amino acids (in mg/g protein):| Amino Acid | Reference Value (mg/g protein) |
|---|---|
| Histidine | 16 |
| Isoleucine | 30 |
| Leucine | 61 |
| Lysine | 48 |
| Methionine + Cysteine | 23 |
| Phenylalanine + Tyrosine | 41 |
| Threonine | 25 |
| Tryptophan | 6.6 |
| Valine | 40 |
Protein quality metrics
Protein quality metrics provide standardized ways to assess the nutritional value of proteins, particularly whether they qualify as complete by meeting human essential amino acid needs while accounting for digestibility. These metrics evolved from early chemical analyses to more comprehensive evaluations incorporating biological utilization. The Chemical Score is a foundational metric that evaluates protein quality solely based on its amino acid profile compared to a reference pattern of human requirements, without considering digestibility. It is calculated as the ratio of the limiting essential amino acid in the test protein to that in the reference protein, expressed as a percentage. This method, originating from early 20th-century nutritional research, highlights deficiencies in specific amino acids but underestimates overall bioavailability. The Protein Digestibility Corrected Amino Acid Score (PDCAAS) builds on the Chemical Score by incorporating true fecal digestibility, offering a more practical assessment for food labeling and regulation. PDCAAS is computed as the product of the lowest amino acid score (from the Chemical Score) and the protein's digestibility percentage, with values capped at 1.0 (or 100%) to prevent overestimation. For example, animal proteins like eggs, milk, and meat typically score near 1.0, while some plant proteins like soy (0.91), quinoa (0.85), and buckwheat (0.54-0.63) score lower; chia seeds contain all essential amino acids and are often considered complete but have a PDCAAS around 0.3-0.66 due to digestibility issues.[17][18][19] Adopted by the FAO/WHO in 1991 and by the FDA in 1994 for nutrition labeling, PDCAAS was widely used until the introduction of newer methods, as it balances amino acid adequacy with absorption efficiency. In 2013, the FAO introduced the Digestible Indispensable Amino Acid Score (DIAAS) as an improved metric to replace PDCAAS, emphasizing ileal digestibility for greater accuracy in amino acid availability. DIAAS is defined as:
\text{DIAAS} = 100 \times \frac{\text{digestible amount of the limiting indispensable [amino acid](/page/Amino_acid) in the test protein}}{\text{reference requirement for that [amino acid](/page/Amino_acid)}}
Unlike PDCAAS, DIAAS does not cap scores at 100%, allowing values above this threshold for superior proteins, and uses age-specific reference patterns. This approach better reflects true protein utilization, particularly for plant-based sources, though it requires more advanced assays like ileal digesta collection.[20]
Another traditional metric is the Biological Value (BV), which measures the proportion of absorbed nitrogen retained for body protein synthesis, typically assessed via nitrogen balance studies in humans or animals. BV is expressed as:
Developed in the mid-20th century, BV provides insight into overall protein efficiency but is labor-intensive and influenced by factors beyond amino acid composition, such as anti-nutritional factors. It has largely been supplanted by amino acid-based scores for routine evaluations.[21]
Despite their advancements, these metrics have limitations: PDCAAS can overestimate quality due to its truncation at 1.0 and reliance on fecal digestibility, which includes microbial contributions not available to the host; DIAAS addresses ileal endpoints for precision but demands costly, invasive measurements, limiting its widespread adoption. Both highlight the importance of combining amino acid profiles with digestibility for determining complete protein status.[20]