The useful physiological properties of yeast have led to their use in the field of
biotechnology.
Fermentation of sugars by yeast is the oldest and largest application of this technology. Many types of yeasts are used for making many foods:
baker's yeast in bread production, brewer's yeast in
beer fermentation, and yeast in wine fermentation and for
xylitol production. Top-cropping yeasts are so called because they form a foam at the top of the
wort during fermentation. An example of a top-cropping yeast is
Saccharomyces cerevisiae, sometimes called an "ale yeast". The most common top-cropping brewer's yeast,
S. cerevisiae, is the same species as the common baking yeast.
Baking Yeast, most commonly
S. cerevisiae, is used in baking as a
leavening agent, converting the
fermentable sugars present in dough into
carbon dioxide. This causes the dough to expand or rise as gas forms pockets or bubbles. When the dough is baked, the yeast dies and the air pockets "set", giving the baked product a soft and spongy texture. The use of potatoes, water from potato boiling,
eggs, or sugar in a bread dough accelerates the growth of yeast. Most yeasts used in baking are of the same species common in alcoholic fermentation. In addition,
Saccharomyces exiguus (also known as
S. minor), a wild yeast found on plants, fruits, and grains, is occasionally used for baking. In breadmaking, the yeast initially respires aerobically, producing carbon dioxide and water. When the oxygen is depleted,
fermentation begins, producing ethanol as a waste product; however, this evaporates during baking. In the solution, active yeast will foam and bubble as it ferments the sugar into ethanol and carbon dioxide. Some recipes refer to this as
proofing the yeast, as it "proves" (tests) the viability of the yeast before the other ingredients are added. When a
sourdough starter is used, flour and water are added instead of sugar; this is referred to as proofing the
sponge. When yeast is used for making bread, it is mixed with
flour, salt, and warm water or milk. The dough is
kneaded until it is smooth, and then left to rise, sometimes until it has doubled in size. The dough is then shaped into loaves. Some bread doughs are knocked back after one rising and left to rise again (this is called
dough proofing) and then baked. A longer rising time gives a better flavor, but the yeast can fail to raise the bread in the final stages if it is left for too long initially.
Bioremediation Some yeasts can find potential application in the field of
bioremediation. One such yeast,
Yarrowia lipolytica, is known to degrade
palm oil mill
effluent,
TNT (an explosive material), and other
hydrocarbons, such as
alkanes,
fatty acids, fats and oils. •
Yeast extract, made from the intracellular contents of yeast and used as
food additives or
flavours. The general method for making yeast extract for food products such as
Vegemite and
Marmite on a commercial scale is
heat autolysis, i.e. to add salt to a suspension of yeast, making the solution hypertonic, which leads to the cells' shrivelling up. This triggers
autolysis, wherein the yeast's
digestive enzymes break their own
proteins down into simpler compounds, a process of self-destruction. The dying yeast cells are then heated to complete their breakdown, after which the husks (yeast with thick cell walls that would give poor texture) are removed. Yeast autolysates are used in
Vegemite and
Promite (Australia);
Marmite (the United Kingdom); the unrelated
Marmite (New Zealand);
Vitam-R (Germany); and
Cenovis (
Switzerland). •
Nutritional yeast, which is whole dried, deactivated yeast cells, usually
S. cerevisiae. Usually in the form of yellow flake or powder, its nutty and umami flavor makes it a vegan substitute for
cheese powder. Nutritional yeast in particular is naturally low in fat and
sodium and a source of protein and vitamins as well as other minerals and
cofactors required for growth. Many brands of nutritional yeast and yeast extract spreads, though not all, are fortified with
vitamin B12, which is produced separately by
bacteria. Yeast cell walls are used as a source of
dietary fiber. Specifically, the glucan part is marketed as "yeast
β-glucan" and the mannan part is further processed into
mannan-oligosaccharide (MOS).
Probiotics Some
probiotic supplements use the yeast
S. boulardii to maintain and restore the natural flora in the
gastrointestinal tract.
S. boulardii has been shown to reduce the symptoms of acute
diarrhea, and
PomBase.
Genetically engineered biofactories Various yeast species have been genetically engineered to efficiently produce various drugs, a technique called
metabolic engineering.
S. cerevisiae is easy to genetically engineer; its physiology, metabolism and genetics are well known, and it is amenable for use in harsh industrial conditions. A wide variety of chemical in different classes can be produced by engineered yeast, including
phenolics,
isoprenoids,
alkaloids, and
polyketides. About 20% of
biopharmaceuticals are produced in
S. cerevisiae, including
insulin,
vaccines for
hepatitis, and
human serum albumin. == Pathogenic yeasts ==