Difference between revisions of "Fermentation" - New World Encyclopedia

In biochemistry, fermentation is an enzyme-catalyzed, energy-generating process in which organic compounds act as both donors and acceptors of electrons. Fermentation can occur in the absence of oxygen, and the term can also be defined as the pathway in cells by which fuel molecules are broken down anaerobically.

Fermentation is thought to have been the primary means of energy production in earlier organisms before oxygen was at high concentration in the atmosphere; thus, it would represent a more ancient form of energy production in cells than aerobic respiration.

Sugars are the common substrate of fermentation, and typical examples of fermentation products are ethanol, lactic acid, and hydrogen. However, more exotic compounds can be produced, such as butyric acid and acetone.

Glycolysis is an important type of fermentation that is common to muscle cells, yeast, some bacteria, and plants. In glycolysis, the six-carbon sugar glucose (Glc) is oxidized to two molecules of pyruvic acid (Pyr), yielding a small net gain of chemical energy (ATP) to power cellular function. In the absence of oxygen, there are two main pathways for the pyruvate end-product:

• Ethanol fermentation (performed by yeast and some types of bacteria) breaks the pyruvate down into ethanol and carbon dioxide. Yeast famously carries out fermentation in the production of ethanol in beer, wine, and other alcoholic beverages.
• Lactic acid fermentation breaks down the pyruvate into lactic acid. It occurs in some bacteria and fungi – for example, lactic acid fermentation occurs in the production of yogurt when bacteria convert lactose into lactic acid, giving yogurt its sour taste. In vertebrates, during periods of intense exercise, cellular respiration may deplete oxygen in the muscles faster than it can be replenished. The shift to glycolysis produces lactic acid, which is associated with an accompanying burning sensation in muscles.

In an industrial context, the term fermentation is used more broadly to refer to the bulk growth of microorganisms on a growth medium. There are many microbiological processes that occur in the presence of air (‘’aerobically’’) while yielding incomplete oxidation products. Examples include the formation of acetic acid (vinegar) from alcohol by vinegar bacteria, and of citric acid from sugar by certain molds (such as ‘’Aspergillus niger’’). These microbial processes have gained industrial importance, and are often referred to as fermentations, although they do not conform to Louis Pasteur's concept of fermentation as a decomposition in the absence of air.

Fermentation in biochemistry

Reactions

The reactions of fermentation vary according to the fuel molecule and end-product involved. In the chemical equation below, the sugar is glucose (C₆H₁₂O₆), and the end-product is ethanol (2C₂H₅OH). Chemical Equation

C₆H₁₂O₆ → 2C₂H₅OH + 2CO₂ + 2 ATP (Energy Released:118 kJ mol⁻¹)

The equation can be written verbally as follows:

Sugar (glucose, fructose, or sucrose) → Alcohol (ethanol) + Carbon Dioxide + Energy (ATP)

Energy yield

In its strictest sense, fermentation (formerly called zymosis) is the anaerobic metabolic breakdown of a nutrient molecule, such as glucose, without net oxidation. Fermentation does not release all the available energy in a molecule; it merely allows glycolysis (a process that yields two ATP per glucose) to continue by replenishing reduced coenzymes.

Fermentation products contain chemical energy (they are not fully oxidized) but are considered waste products since they cannot be metabolized further without the use of oxygen (or other more highly-oxidized electron acceptors). A consequence is that the production of ATP by fermentation is less efficient than oxidative phosphorylation, where pyruvate is fully oxidized to carbon dioxide. Fermentation produces two ATP molecules per molecule of glucose compared to approximately 36 ATP yielded by aerobic respiration.

Aerobic glycolysis is a method employed by muscle cells for the production of lower-intensity energy over a longer period of time when oxygen is plentiful. Under low-oxygen conditions, however, vertebrates use the less-efficient but faster anaerobic glycolysis to produce ATP. While fermentation is helpful during short, intense periods of exertion, it is not sustained over extended periods in complex aerobic organisms. In humans, for example, lactic acid fermentation provides energy for a period ranging from 30 seconds to 2 minutes.

Although human metabolism is primarily aerobic, in the partial or complete absence of oxygen (for example, in overworked muscles that are starved of oxygen or in infarcted heart muscle cells), pyruvate can be converted to the waste product lactate, donating its hydrogen to pyruvate. (The lactic-acid buildup in our muscles causes "the burn" we associate with intense exercise.) This reaction, which is an example of a fermentation, is a solution to maintaining the metabolic flux through glycolysis in the absence of oxygen or when oxygen levels are low.

The final step of fermentation, the conversion of pyruvate to fermentation end-products, does not produce energy. However, it is critical for an anaerobic cell since it regenerates nicotinamide adenine dinucleotide (NAD⁺), which is required to sustain the flow through the glycolytic pathway in anaerobic conditions.

Products

Depending on which organism it is taking place in, fermentation may yield lactate, acetic acid, ethanol, or other reduced metabolites.

There are several types of fermentations in which pyruvate and NADH are anaerobically metabolized to yield any of a variety of products with an organic molecule acting as the final hydrogen acceptor. For example, the bacteria involved in making yogurt simply reduce pyruvate to lactic acid. In organisms such as brewers' yeast, a carboxyl group is first removed from pyruvate to form acetaldehyde and carbon dioxide; the acetaldehyde is then reduced to yield ethanol and NAD⁺. Anaerobic bacteria are capable of using a wide variety of compounds other than oxygen as terminal electron acceptors.

Vinegar (acetic acid) is the direct result of bacterial metabolism (Bacteria need oxygen to convert the acetic acid to alcohol.). In milk, the acid coagulates the casein, producing curds. In pickling, the acid preserves the food from pathogenic and putrefactive bacteria.

Fermentation in food production

Grapes covered in yeast growth observable as a white film, also known as the "blush".

Fermentation typically refers to the conversion of sugar to alcohol using yeast under anaerobic conditions. A more general definition of fermentation is the chemical conversion of carbohydrates into alcohols or acids. The process is used to produce wine, beer, and vinegar, but fermentation is also employed in preservation to create lactic acid in sour foods, such as pickled cucumbers, kimchi and yogurt. Bacteria, often in combination with yeasts and molds, are used in the preparation of fermented foods such as cheese, pickles, soy sauce, sauerkraut, vinegar, wine, and yogurt.

According to Steinkraus (1995), food fermentation serves five main purposes:

1. Enrichment of the diet through development of a diversity of flavors, aromas, and textures in food substrates.
2. Preservation of substantial amounts of food through lactic acid, alcohol, acetic acid, and alkaline fermentations.
3. Biological enrichment of food substrates with protein, essential amino acids, essential fatty acids, and vitamins.
4. Detoxification during food-fermentation processing.
5. A decrease in cooking times and fuel requirements.

Food can be preserved by fermentation, since fermentation uses up food energy and can make conditions unsuitable for undesirable microorganisms. For example, in pickling the acid produced by the dominant bacteria inhibit the growth of all other microorganisms.

Relation between food fermentation and advances in biochemistry

Although the biochemistry of fermentation was fully elaborated only in the 20th century, alcoholic fermentation is a process that has been practiced since antiquity. By 1500 B.C.E., the production of beer from germinating cereals (malt) and the preparation of wines from crushed grapes were established arts in most of the Middle East. Much of modern biochemistry as a scientific discipline, particularly the study of enzymes, has emerged directly from an earlier interest in the fermentation process in the production of food and beverages. One of the earliest laboratories established for the study of biochemistry was the Carlsberg Laboratory founded in Copenhagen in 1875 and financed by the brewing family of Jacob Christian Jacobsen. The species of yeast used to make pale lager (Saccharomyces carlsbergensis) was isolated at the Laboratory and named after it; The concept of pH was developed there, and its members made significant advances in protein chemistry.

History

French chemist Louis Pasteur was the first zymologist, when in 1857 he connected yeast to fermentation. Pasteur demonstrated that the fermentation process is caused by the growth of microorganisms, and that the growth of microorganisms in nutrient broths is not due to spontaneous generation (explain).

He exposed boiled broths to air in vessels that contained a filter to prevent all particles from passing through to the growth medium, and even in vessels with no filter at all, with air being admitted via a long tortuous tube that would not allow dust particles to pass. Nothing grew in the broths; therefore, the living organisms that grew in such broths came from outside, as spores on dust, rather than spontaneously generated within the broth. Thus, Pasteur dealt the death blow to the theory of spontaneous generation and supported germ theory.

Pasteur in the 19th century used the term fermentation in a narrow sense to describe the changes brought about by yeasts and other microorganisms growing in the absence of air (anaerobically); he also recognized that ethyl alcohol and carbon dioxide are not the only products of fermentation. Pasteur originally defined fermentation as respiration without air. Pasteur performed careful research and concluded, "I am of the opinion that alcoholic fermentation never occurs without simultaneous organization, development and multiplication of cells.... If asked, in what consists the chemical act whereby the sugar is decomposed ... I am completely ignorant of it."

The German Eduard Buchner, winner of the 1907 Nobel Prize in chemistry, later determined that fermentation was actually caused by a yeast secretion that he termed zymase. The experiment for which Buchner won the Nobel Prize consisted of producing a cell-free extract of yeast cells and showing that this "press juice" could ferment sugar. This dealt yet another blow to vitalism by showing that the presence of living yeast cells was not needed for fermentation. Along with his brother Hans, Eduard Buchner demonstrated for the first time that fermentation could occur outside living cells.

Need to reword: In the 1920s, it was discovered that extracts of muscle catalyze, in the absence of air, the formation of lactate from glucose and that the same intermediate compounds formed in the fermentation of grain are produced by muscle. This discovery revealed an underlying unity in biochemistry: fermentation reactions are not peculiar to the action of yeast but also occur in many other instances of glucose utilization. Elucidation of the glycolytic pathway by 1940 involved pioneering efforts of Gustav Embden, Otto Meyerhof, Carl Neuberg, Jacob Parnas, Otto Warburg, and Gerty and Carl Cori.

Related Topics

Fermented foods by region

• Worldwide: alcohol, wine, vinegar, olives, yogurt, bread
• Asia
  • East and Southeast Asia: amazake, asinan, bai-ming, belacan, burong mangga, dalok, doenjang (된장), douchi, jeruk, lambanog, kimchi (김치), kombucha, leppet-so, narezushi, miang, miso, nata de coco, nata de pina, natto, naw-mai-dong, pak-siam-dong, paw-tsaynob in snow (雪裡蕻), prahok, sake, seokbakji, soy sauce, stinky tofu, szechwan cabbage (四川泡菜), tai-tan tsoi, takuan, tape, tempeh, totkal kimchi, yen tsai (醃菜), zha cai (榨菜)
  • Central Asia: kumis (mare milk), kefir, shubat (camel milk)
  • India: achar, appam, dosa, dhokla, dahi, gundruk, idli, mixed pickle
• Africa: garri, hibiscus seed, hot pepper sauce, injera, lamoun makbouss, laxoox, mauoloh, msir, mslalla, oilseed, ogi, ogili, ogiri
• Americas: cheese, chicha, elderberry wine, kombucha, pickling (pickled vegetables), sauerkraut, lupin seed, oilseed, chocolate, vanilla, tabasco, tibicos
• Middle East: kushuk, lamoun makbouss, mekhalel, torshi, boza
• Europe: cheese, rakfisk, sauerkraut, surströmming, soured milk products such as quark, kefir, filmjölk, crème fraîche, smetana, skyr, mead elderberry wine.
• Oceania: poi, kaanga pirau (rotten corn)

References

ISBN links support NWE through referral fees

• Steinkraus, K. H., Ed. 1995. Handbook of Indigenous Fermented Foods. New York, NY: Marcel Dekker, Inc.
• Stryer, L. 1995. Biochemistry, 4th edition. New York, NY: W.H. Freeman.