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Dimers lambda repressor protein

The fundamental unit of tertiary structure is the domain. A domain is defined as a polypeptide chain or a part of a polypeptide chain that can fold independently into a stable tertiary structure. Domains are also units of function. Often, the different domains of a protein are associated with different functions. For example, in the lambda repressor protein, discussed in Chapter 8, one domain at the N-terminus of the polypeptide chain binds DNA, while a second domain at the C-terminus contains a site necessary for the dimerization of two polypeptide chains to form the dimeric repressor molecule. [Pg.29]

Superficially, the lambda repressor protein is very different from lambda Cro. The polypeptide chain is much larger, 236 amino acids, and is composed of two domains that can be released as separate fragments by mild proteolysis. In repressor the domain responsible for dimerization is separate from the... [Pg.132]

In spite of the absence of the C-terminal domains, the DNA-binding domains of lambda repressor form dimers in the crystals, as a result of interactions between the C-terminal helix number 5 of the two subunits that are somewhat analogous to the interactions of the C-terminal p strand 3 in the Cro protein (Figure 8.7). The two helices pack against each other in the normal way with an inclination of 20° between the helical axes. The structure of the C-terminal domain, which is responsible for the main subunit interactions in the intact repressor, remains unknown. [Pg.133]

Detailed analysis of the lambda repressor led to the important concept that transcription regulatory proteins have several functional domains. For example, lambda repressor binds to DNA with high affinity. Repressor monomers form dimers, dimers interact with each other, and repressor interacts with RNA polymerase. The protein-DNA interface and the three protein-protein interfaces all involve separate and distinct domains of the repressor molecule. As will be noted below (see Figure 39—17), this is a characteristic shared by most (perhaps all) molecules that regulate transcription. [Pg.383]

Fig. 7. Water at protein-DNA interfaces. Four protein-DNA complexes are shown with the DNA placed in front of the molecular surface of the protein, colored according to the electrostatic potential (red, negative blue, positive). The complexes are with the lambda repressor dimer (limb) three zinc fingers from the Zif268 transcription factor (laay) the human TATA box-binding protein (Icdw) and the dimeric E2 domain of papilloma virus (2bop). Red spheres represent interface water molecules. Figure taken from Nadassy et al. (1999) and drawn with GRASP (see web sites). Fig. 7. Water at protein-DNA interfaces. Four protein-DNA complexes are shown with the DNA placed in front of the molecular surface of the protein, colored according to the electrostatic potential (red, negative blue, positive). The complexes are with the lambda repressor dimer (limb) three zinc fingers from the Zif268 transcription factor (laay) the human TATA box-binding protein (Icdw) and the dimeric E2 domain of papilloma virus (2bop). Red spheres represent interface water molecules. Figure taken from Nadassy et al. (1999) and drawn with GRASP (see web sites).
See other pages where Dimers lambda repressor protein is mentioned: [Pg.381]    [Pg.137]    [Pg.142]    [Pg.380]    [Pg.1611]    [Pg.1622]    [Pg.215]    [Pg.698]    [Pg.709]    [Pg.677]    [Pg.688]    [Pg.141]   
See also in sourсe #XX -- [ Pg.380 , Pg.381 ]



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