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Rennet



Rennet (pronounced /ˈrɛnɪt/) is a natural complex of enzymes produced in any mammalian stomach to digest the mother's milk. Rennet contains a proteolytic enzyme (protease) that coagulates the milk, causing it to separate into solids (curds) and liquid (whey). The active enzyme in rennet is called rennin or chymosin (EC 3.4.23.4) but there are also other important enzymes in it, e.g., pepsin or lipase. There are non-animal sources for rennet substitutes.

Contents

Uses

The chief use of rennet is in the making of cheese, curd, and junket. Chymosin reacts specifically with κ-casein, cleaving the protein between the amino acids phenylalanine(105) and methionine (106), producing two fragments. The soluble fragment (residues 106-169), which becomes part of the whey, is known as glyco macro peptide and contains the glycosylation sites for κ-casein. The other component (residues 1-105) is insoluble, and in the presence of calcium ions causes the coagulation of the casein micelles to form a curd.

Production of natural calf rennet

Natural calf rennet is extracted from the inner mucosa of the fourth stomach chamber (the abomasum) of young calves. These stomachs are a by-product of veal production. If rennet is extracted from older calves (grass-fed or grain-fed) the rennet contains less or no chymosin but a high level of pepsin and can only be used for special types of milk and cheeses. As each ruminant produces a special kind of rennet to digest the milk of its own mother, there are milk-specific rennets available, such as kid-goat rennet especially for goat's milk and lamb-rennet for sheep-milk. Rennet or digestion enzymes from other animals, like swine-pepsin, are not used in cheese production. (Swine-pepsin is, however, used in the analysis of disulfide bonds of proteins.)

Traditional method

Dried and cleaned stomachs of young calves are sliced into small pieces and then put into saltwater or whey, together with some vinegar or wine to lower the pH of the solution. After some time, (overnight or several days) the solution is filtered. The crude rennet that remains in the filtered solution can then be used to coagulate milk. About 1 gram of this solution can normally coagulate 2000 to 4000 grams of milk.

Today this method is used only by traditional cheese-makers in central Europe: Switzerland, Jura, France, Romania and Alp-Sennereien in Austria.

Modern method

Deep-frozen stomachs are milled and put into an enzyme-extracting solution. The crude rennet extract is then activated by adding acid – the enzymes in the stomach are produced in an inactive pre-form and are activated by the stomach acid. After neutralisation of the acid, the rennet extract is filtered in several stages and concentrated until reaching the required potency: about 1:15000 (1 kg of rennet would have the ability to coagulate 15000 litres of milk).

In 1 kg of rennet extract there are about 0.7 grams of active enzymes and no other organic material – the rest is water and salt and sometimes sodium benzoate, E211, 0.5% - 1% for preservation. Typically, 1 kg of cheese contains about 0.0003 grams of rennet enzymes.

Alternative coagulants

Because of the limited availability of proper stomachs for rennet production, cheesemakers have always looked for other ways to coagulate the milk. Artificial coagulants are a useful alternative, especially for cheap or lower-quality cheeses.

As the proper coagulation is done by enzymatic activity, the task was to find enzymes for cleaving the casein that would result in a taste and texture similar to animal-based rennet.

Vegetable rennet

Many plants have coagulating properties. Some examples include fig tree bark, nettles, thistles, mallow, and Creeping Charlie. Enzymes from thistle or cynara is used in some traditional cheese production in the Mediterranean.

These real vegetable rennets are also suitable for vegetarians. Vegetable rennet might be used in the production of kosher cheeses but nearly all kosher cheeses are produced with either microbial rennet or GM rennet. Worldwide, there is no industrial production for vegetable rennet. Commercial so-called vegetable rennets usually contain rennet from the mold Mucor miehei - see microbial rennet below.

Microbial rennet

Some molds, such as Rhizomucor miehei are able to produce proteolytic enzymes. These molds are produced in a fermenter and then especially concentrated and purified to avoid contamination with unpleasant side products of the mold growth. At the present state of scientific research, governmental food safety organizations such as the EFSA deny QPS (Qualified Presumption of Safety) status to enzymes produced especially by these molds.

The flavor and taste of cheeses produced with microbial rennets tend towards some bitterness, especially after longer maturation periods.[1] These so-called "microbial rennets" are suitable for vegetarians, provided no animal-based alimentation was used during the production.

Genetically engineered rennet

Because of the above imperfections of microbial rennets, some producers sought further replacements of natural rennet. With the development of genetic engineering, it suddenly became possible to use calf-genes to modify some bacteria, fungus or yeast to make them produce chymosin. Chymosin produced by genetically modified organisms was the first artificially produced enzyme to be registered and allowed by the FDA in the USA. In 1999, about 60% of U.S. hard cheese was made with genetically engineered chymosin[2]. One example of a commercially available genetically engineered rennet is Chymax, created by Pfizer.

Today the most widely-used genetically engineered rennet is produced by the fungus Aspergillus niger. The problems of destroying the aflatoxins or the antibiotic-resistant marker genes seem to be solved.

Cheese production with genetically engineered rennet is similar to production with natural calf rennet. Genetic rennet contains only one of the known main chymosin types – either type A or type B. Other chymosin types found in natural rennet do not exist in genetic rennet. This is also the reason why special analysis can determine what kind of coagulant has been used by analyzing what bonds have and haven't been cleaved.

Often a mixture of genetically engineered chymosin and natural pepsin is used to imitate the complexity of natural rennet and to get the same results in coagulation and in development of flavour and taste.

The so-called "GM rennets" are suitable for vegetarians if there was no animal based alimentation used during the production in the fermenter—but only for vegetarians who are not opposed to GM-derived foods.

Acid coagulation

Milk can also be coagulated by adding some acid, e.g. citric acid. This form of coagulation is sometimes used in cheap mozzarella production without maturation of the cheese. Paneer is also made this way. The acidification can also come from bacterial fermentation such as in cultured milk.

See also

  • Pepsin
  • A recipe for homemade Quark without rennet

References

  1. ^ Samson Agboola, Shaojiang Chen, and Jian Zhao (2004). "Formation of bitter peptides during ripening of ovine milk cheese made with different coagulants" (in English, French). Lait 84: 567–578. EDP Sciences. doi:10.1051/lait:2004032. Retrieved on 2007-12-31. “The concentration of bitter peptides (those with a molecular size of 165-6500 g·mol-1) was highest in cheese made with microbial coagulant and lowest in cheese made with calf rennet. Cheese made with microbial coagulant was perceived to be the most bitter by the sensory panel, followed by calf and cardoon coagulant cheeses.”
  2. ^ "Food Biotechnology in the United States: Science, Regulation, and Issues". U.S. Department of State. Retrieved on 2006-08-14.
  • Carroll, Ricki. Making Cheese, Butter, & Yogurt. Storey Publishing 2003.
  • "Biotechnology and Food: Leader and Participant Guide," publication no. 569, produced by North Central Regional Extension. Printed by Cooperative Extension Publications, University of Wisconsin-Extension, Madison, WI, 1994. Publication date: 1994.
  • Tom Zinnen, biotechnology specialist, University of Wisconsin-Extension and UW Biotechnology Center, UW-Madison; and Jane Voichick, professor, Nutritional Sciences, UW-Madison and UW- Extension.
 
This article is licensed under the GNU Free Documentation License. It uses material from the Wikipedia article "Rennet". A list of authors is available in Wikipedia.
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