Chapter 6: Protein Function

Back to chapter

6.4:

Cofaktoren und Coenzyme

JoVE Central
Cell Biology

Se requiere una suscripción a JoVE para ver este contenido. Inicie sesión o comience su prueba gratuita.

JoVE Central Cell Biology

Cofactors and Coenzymes

Vídeo anterior
6.3: Conserved Binding Sites

Siguiente video
6.5: Cooperative Allosteric Transitions

Idiomas

Compartir

English العربية 中文 Nederlands français Deutsch עברית italiano 日本語 한국어 português русский español Türkçe

Some enzymes associate with non-protein molecules or cofactors to enhance their catalytic activity. The chemically active enzyme-cofactor complex is called a holoenzyme and the enzyme alone is called an apoenzyme. Cofactors can be present as inorganic metal ions such as the zinc ion in carbonic anhydrase or as organic molecules called coenzymes such as NAD+, coenzyme A and others. Some cofactors, called prosthetic groups, are covalently bonded to apoenzymes. For example, in hemoglobin, the heme group, a porphyrin with a central iron ion, is associated with protein chains through covalent bonding, hydrogen bonding, and extensive hydrophobic interactions. In contrast, cofactors that are transiently bound to enzymes act as cosubstrates. For example, NAD+ , a coenzyme for alcohol dehydrogenase, helps oxidize alcohol to aldehyde and gets reduced to NADH. NADH dissociates once the reaction is complete and is reoxidized to NAD+ for the next reaction cycle.

6.4:

Cofaktoren und Coenzyme

Enzymes are proteins made of amino acids. The functional group of each constituent amino acid catalyzes a wide variety of chemical reactions via ionic interactions or acid-base reactions. However, amino acids cannot catalyze oxidation-reduction and group transfer reactions and need to be aided by non-protein components called cofactors. Cofactors are also referred to as the chemical teeth of an enzyme.

Cofactors can be metallic ions or organic molecules called coenzymes. These types of helper molecule can bind covalently to an enzyme as prosthetic groups or transiently as co-substrates.

Cofactors are present in ~30% of mature proteins. They are frequently incorporated into an enzyme as it is folded and involved in its catalytic activity. Magnesium is an essential cofactor for over 300 enzymes in the human body, including DNA polymerase. In this case, the magnesium ion helps form the phosphodiester bond on the DNA backbone. Iron, copper, cobalt, and manganese are other common cofactors.

Many vitamins are coenzymes, such as biotin of the vitamin B family. It is essential in various enzymes that transfer carbon dioxide from one molecule to another. Apart from biotin, NAD⁺, a derivative of Vitamin B3 and retinol or vitamin A, are some other examples of cofactors essential to our body and must be ingested in our diet, as they cannot be made by the human cells.

Suggested Reading

Donald Voet and Judith G Voet Biochemistry. 4th ed. JOHN WILEY & SONS, INC. 2011. Pp 473-474
Nelson and Cox, Lehninger, Principles Of Biochemistry, 7th ed. W.H. Freeman and Company, 2016. Pp 513