Single-cell protein

Single-cell protein (SCP) refers to edible unicellular microorganisms. The biomass or protein extract from pure or mixed cultures of algae, yeasts, fungi or bacteria may be used as an ingredient or a substitute for protein-rich foods, and is suitable for human consumption or as animal feeds.

Whereas industrial agriculture is marked by a high water footprint,[1] high land use,[2] biodiversity destruction,[2] general environmental degradation[2] and contributes to climate change by emission of a third of all greenhouse gases,[3] production of SCP does not necessarily exhibit any of these serious drawbacks. As of today, SCP is commonly grown on agricultural waste products, and as such inherits the ecological footprint and water footprint of industrial agriculture. However, SCP may also be produced entirely independent of agricultural waste products through autotrophic growth.[4] Thanks to the high diversity of microbial metabolism, autotrophic SCP provides several different modes of growth, versatile options of nutrients recycling, and a substantially increased efficiency compared to crops.[4]

With the world population reaching 9 billion by 2050, there is strong evidence that agriculture will not be able to meet demand[5] and that there is serious risk of food shortage.[6][7] Autotrophic SCP represents options of fail-safe mass food-production which can produce food reliably even under harsh climate conditions.[4]

History

In 1781, processes for preparing highly concentrated forms of yeast were established. Research on Single Cell Protein Technology started a century ago when Max Delbrück and his colleagues found out the high value of surplus brewer’s yeast as a feeding supplement for animals.[8] During World War I and World War II, yeast-SCP was employed on a large scale in Germany to counteract food shortages during the war. Inventions for SCP production often represented milestones for biotechnology in general: for example, in 1919, Sak in Denmark and Hayduck in Germany invented a method named, “Zulaufverfahren”, (fed-batch) in which sugar solution was fed continuously to an aerated suspension of yeast instead of adding yeast to diluted sugar solution once (batch).[8] In post war period, the Food and Agriculture Organization of the United Nations (FAO) emphasized on hunger and malnutrition problems of the world in 1960 and introduced the concept of protein gap, showing that 25% of the world population had a deficiency of protein intake in their diet.[8] It was also feared that agricultural production would fail to meet the increasing demands of food by humanity. By the mid 60’s, almost quarter of a million tons of food yeast were being produced in different parts of the world and Soviet Union alone produced some 900,000 tons by 1970 of food and fodder yeast.[8]

In the 1960s, researchers at British Petroleum developed what they called "proteins-from-oil process": a technology for producing single-cell protein by yeast fed by waxy n-paraffins, a byproduct of oil refineries. Initial research work was done by Alfred Champagnat at BP's Lavera Oil Refinery in France; a small pilot plant there started operations in March in 1963, and the same construction of the second pilot plant, at Grangemouth Oil Refinery in Britain, was authorized.[9]

The term SCP was coined in 1966 by Carroll L. Wilson of MIT.[10]

The "food from oil" idea became quite popular by the 1970s, with Champagnat being awarded the UNESCO Science Prize in 1976,[11] and paraffin-fed yeast facilities being built in a number of countries. The primary use of the product was as poultry and cattle feed.[12]

The Soviets were particularly enthusiastic, opening large "BVK" (belkovo-vitaminny kontsentrat, i.e., "protein-vitamin concentrate") plants next to their oil refineries in Kstovo (1973)[13][14][15] and Kirishi (1974).[16] The Soviet Ministry of Microbiological Industry had eight plants of this kind by 1989. However, due to concerns of toxicity of alkanes in SCP and pressured by the environmentalist movements, the government decided to close them down, or convert to some other microbiological processes.[16]

Production Process

Single-cell proteins develop when microbes ferment waste materials (including wood, straw, cannery, and food-processing wastes, residues from alcohol production, hydrocarbons, or human and animal excreta).[17] The problem with extracting single-cell proteins from the wastes is the dilution and cost. They are found in very low concentrations, usually less than 5%. Engineers have developed ways to increase the concentrations including centrifugation, flotation, precipitation, coagulation, and filtration, or the use of semi-permeable membranes.

The single-cell protein must be dehydrated to approximately 10% moisture content and/or acidified to aid in storage and prevent spoilage. The methods to increase the concentrations to adequate levels and the de-watering process require equipment that is expensive and not always suitable for small-scale operations. It is economically prudent to feed the product locally and soon after it is produced.

Microorganisms

Microbes employed include:

Advantages

Large-scale production of microbial biomass has many advantages over the traditional methods for producing proteins for food or feed.

  1. Microorganisms have a much higher growth rate (algae: 2–6 hours, yeast: 1–3 hours, bacteria: 0.5–2 hours). This also allows to select for strains with high yield and good nutritional composition quickly and easily compared to breeding.
  2. Whereas large parts of the crop, such as stems, leaves and roots are not edible, single-cell microorganisms can be used entirely. Whereas parts of the edible fraction of crops contains is undigestible, many microorganisms are digestible at a much higher fraction.[4]
  3. Microorganisms usually have a much higher protein content of 30–70% in the dry mass than vegetables or grains.[20] The amino acid profiles of many SCP microorganisms often have excellent nutritional quality, comparable to a hen's egg.
  4. Some microorganisms can build vitamins and nutrients which eukaryotic organisms such as plants cannot produce or not produce in significant amounts, including vitamin B12.
  5. Microorganisms can utilize a broad spectrum of raw materials as carbon sources including alkanes, methanol, methane, ethanol and sugars. What was considered "waste product" often can be reclaimed as nutrients and support growth of edible microorganisms.
  6. Like plants, autotrophic microorganisms are capable to grow on CO2. Some of them, such as bacteria with the Wood–Ljungdahl pathway or the reductive TCA can fix CO2 between 2-3,[21] up to 10 times more efficiently than plants[22] when also considering the effects of photoinhibition.
  7. Some bacteria, such as several homoacetogenic clostridia are capable to perform syngas fermentation. This means they can metabolize synthesis gas, a gas mixture of CO, H2 and CO2 that can be made by gasification of residual intractable biowastes such as lignocellulose.
  8. Some bacteria are diazotrophic, i.e. they can fix N2 from the air and are thus independent of chemical N-fertilizer, whose production, utilization and degradation causes tremendous harm to the environment, deteriorates public health, and fosters climate change.[23]
  9. Many bacteria can utilize H2 for energy supply, using enzymes called hydrogenases. Whereas hydrogenases are normally highly O2-sensitive, some bacteria are capable of performing O2-dependent respiration of H2. This feature allows autotrophic bacteria to grow on CO2 without light at a fast growth rate. Since H2 can be made efficiently by water electrolysis, in a manner of speaking, those bacteria can be "powered by electricity".[4]
  10. Microbial biomass production is independent of seasonal and climatic variations, and can be easily shielded from extreme weather events that are expected to cause crop failures with the ongoing climate-change. Light-independent microorganisms such as yeasts can continue to grow at night.
  11. Cultivation of microorganisms generally has a much lower water footprint than agricultural food production. Whereas the global average blue-green water footprint (irrigation, surface, ground and rain water) of crops reaches about 1800 liters per kg crop[1] due to evaporation, transpiration, drainage and runoff, closed bioreactors producing SCP exhibits none of these causes.
  12. Cultivation of microorganisms does not require fertile soil and therefore does not compete with agriculture. Thanks to the low water requirements, SCP cultivation can even be done in dry climates with infertile soil and may provide a means of fail-safe food supply in arid countries.
  13. Photosynthetic microorganisms can reach a higher solar-energy-conversion efficiency than plants, because in photobioreactors supply of water, CO2 and a balanced light distribution can be tightly controlled.
  14. Unlike agricultural products which are processed towards a desired quality, it is easier with microorganisms to direct production towards a desired quality. Instead of extracting amino acids from soy beans and throwing away half of the plant body in the process, microorganisms can be genetically modified to overproduce or even secrete a particular amino acid. However, in order to keep a good consumer acceptance, it is usually easier to obtain similar results by screening for microorganisms which already have the desired trait or train them via selective adaptation.

Disadvantages

Although SCP shows very attractive features as a nutrient for humans, however there are some problems that deter its adoption on global basis:

References

  1. 1 2 Mekonnen, Mesfin M.; Hoekstra, Arjen Y. (2014-11-01). "Water footprint benchmarks for crop production: A first global assessment". Ecological Indicators. 46: 214–223. doi:10.1016/j.ecolind.2014.06.013.
  2. 1 2 3 Tilman, David (1999-05-25). "Global environmental impacts of agricultural expansion: The need for sustainable and efficient practices". Proceedings of the National Academy of Sciences. 96 (11): 5995–6000. doi:10.1073/pnas.96.11.5995. ISSN 0027-8424. PMC 34218Freely accessible. PMID 10339530.
  3. Vermeulen, Sonja J.; Campbell, Bruce M.; Ingram, John S.I. (2012-01-01). "Climate Change and Food Systems". Annual Review of Environment and Resources. 37 (1): 195–222. doi:10.1146/annurev-environ-020411-130608.
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  7. Wheeler, Tim; Braun, Joachim von (2013-08-02). "Climate Change Impacts on Global Food Security". Science. 341 (6145): 508–513. doi:10.1126/science.1239402. ISSN 0036-8075. PMID 23908229.
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  9. Bamberg, J. H. (2000). British Petroleum and global oil, 1950–1975: the challenge of nationalism. Volume 3 of British Petroleum and Global Oil 1950–1975: The Challenge of Nationalism, J. H. Bamberg British Petroleum series. Cambridge University Press. pp. 426–428. ISBN 0-521-78515-4.
  10. H. W. Doelle (1994). Microbial Process Development. World Scientific. p. 205.
  11. "UNESCO Science Prize: List of prize winners". UNESCO. 2001. Archived from the original on February 10, 2009. Retrieved 2009-07-07. (May have moved to http://unesdoc.unesco.org/images/0011/001111/111158E.pdf )
  12. National Research Council (U.S.). Board on Science and Technology for International Development (1983). Workshop on Single-Cell Protein: summary report, Jakarta, Indonesia, February 1–5, 1983. National Academy Press. p. 40.
  13. Soviet Plant to Convert Oil to Protein for Feed; Use of Yeast Involved, By THEODORE SHABAD. the New York Times, November 10, 1973.
  14. RusVinyl – Summary of Social Issues (EBRD)
  15. Первенец микробиологической промышленности (Microbiological industry's first plant), in: Станислав Марков (Stanislav Markov) «Кстово – молодой город России» (Kstovo, Russia's Young City)
  16. 1 2 KIRISHI: A GREEN SUCCESS STORY? (Johnson's Russia List, Dec. 19, 2002)
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  18. 1 2 Ivarson KC, Morita H (1982). "Single-Cell Protein Production by the Acid-Tolerant Fungus Scytalidium acidophilum from Acid Hydrolysates of Waste Paper.". Appl Environ Microbiol. 43 (3): 643–647. PMC 241888Freely accessible. PMID 16345970.
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  20. 1 2 3 Nasseri, A.T.; Rasoul-Ami, S.; Morowvat, M.H.; Ghasemi, Y. (2011-01-01). "Single Cell Protein: Production and Process". American Journal of Food Technology. 6 (2): 103–116. doi:10.3923/ajft.2011.103.116.
  21. Boyle, Nanette R.; Morgan, John A. (2011-03-01). "Computation of metabolic fluxes and efficiencies for biological carbon dioxide fixation". Metabolic Engineering. 13 (2): 150–158. doi:10.1016/j.ymben.2011.01.005.
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