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3.4: Protein Quaternary Structure, Prosthetic Groups Chemical Modifications

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    Quaternary structure describes proteins composed of two or more polypeptides. Like tertiary structure, such multimeric proteins are formed by noncovalent interactions and may be stabilized disulfide bonds. Dimers contain two, a trimer three, a tetramer four polypeptides, and so on. Multimers made up of identical subunits are referred to with a prefix of homo- (e.g., a homotetramer). Multimers made up of different subunits are called heteromers.The vertebrate hemoglobin molecule is a heterotetramer, with two \(\alpha\) and two \(\beta\) globins (Figure 3.12).

    Screen Shot 2022-05-12 at 2.45.18 AM.png
    Figure 3.12: The vertebrate hemoglobin molecule, consisting of four globin subunits (two \(\alpha\)− and two \(\beta\)− polypeptides). Each globin is associated with a heme group bound to iron.

    Hemoglobins exemplify the role of organic molecules groups in protein function. To be biologically active, each globin polypeptide must associate with heme (a cyclic organic molecule) with an iron ion at its center. The iron is what reversibly binds oxygen. All kinds of organisms, from bacteria to plants and animals (and even some anaerobes!) contain hemoglobin variants, each with a heme-like molecule. The organic molecules associated with proteins are called prosthetic groups. Other proteins must be bound directly to metal ions (e.g.,magnesium, manganese, and cobalt) to be biologically active.

    136-2 Protein Quaternary Structure & Prosthetic Groups

    CHALLENGE

    Hemoglobins bind and distribute the oxygen required for animal respiration. Anaerobic organisms also have hemoglobin. Why?

    Chemical modifications are posttranslational enzyme-catalyzed events, which are required to make a protein fully functional or to regulate its activity. Many polypeptides are structurally modified by glycosylation (e.g., to make membrane glycoproteins). Others are phosphorylated at one or more specific amino acids in the chain, to regulate their biological activity. These and other modifications account for and enhance the molecular and functional diversity of proteins within and across species.

    This page titled 3.4: Protein Quaternary Structure, Prosthetic Groups Chemical Modifications is shared under a not declared license and was authored, remixed, and/or curated by Gerald Bergtrom.

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