Terminal domains

NifA proteins are of one of two types. One group consists of 02-sensitive NifA proteins, which are found in the rhizobia Bhodobacter and Ae spirillum. These proteins have a proposed iron-binding motif on a linker between the central and C-terminal domains that may form a redox-sensitive... 

CDK2 has two domains, a small (85 residue) amino-terminal domain comprising a single a helix and a five-stranded p sheet and a larger (213 residues) domain that is mainly a-helical (Figure 6.17a). The cofactor in the... 

Figure 6.20 Space-filling diagram illustrating the structural changes of CDK2 upon cyclin binding, (a) The active site is in a cleft between the N-terminal domain (blue) and the C-terminal domain (purple). In the inactive form this site is blocked by the T-loop.

Figure 8.6 The N-terminal domain of lambda repressor, which binds DNA, contains 92 amino acid residues folded into five a helices. Two of these, a2 (blue) and a3 (red) form a helix-turn-hellx motif with a very similar structure to that of lambda Cro shown In Figure 8.4. The complete repressor monomer contains in addition a larger C-termlnal domain. (Adapted from C. Pabo and M. Lewis, Nature 298 443-447, 1982.)...

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. 

Many biochemical and biophysical studies of CAP-DNA complexes in solution have demonstrated that CAP induces a sharp bend in DNA upon binding. This was confirmed when the group of Thomas Steitz at Yale University determined the crystal structure of cyclic AMP-DNA complex to 3 A resolution. The CAP molecule comprises two identical polypeptide chains of 209 amino acid residues (Figure 8.24). Each chain is folded into two domains that have separate functions (Figure 8.24b). The larger N-terminal domain binds the allosteric effector molecule, cyclic AMP, and provides all the subunit interactions that form the dimer. The C-terminal domain contains the helix-tum-helix motif that binds DNA. 

Mondragon, A., et al. Structure of the amino-terminal domain of phage 434 repressor at 2.0 A resolution. 

TBP mutants lacking the N-terminal region are fully functional in promoter binding and stimulation of basal transcription and therefore these two functions must be provided by the C-terminal domain. Furthermore, the C-terminal domain of yeast TBP contains all the functions essential for normal yeast cell growth and for responses to specific transcriptional activators with a net negative charge. This C-terminal domain contains two homologous... 

Figure 9.12 Schematic diagram of the structure of the heterodimeric yeast transcription factor Mat a2-Mat al bound to DNA. Both Mat o2 and Mat al are homeodomains containing the helix-turn-helix motif. The first helix in this motif is colored blue and the second, the recognition helix, is red. (a) The assumed structure of the Mat al homeodomain in the absence of DNA, based on Its sequence similarity to other homeodomains of known structure, (b) The structure of the Mat o2 homeodomain. The C-terminal tail (dotted) is flexible in the monomer and has no defined structure, (c) The structure of the Mat a 1-Mat a2-DNA complex. The C-terminal domain of Mat a2 (yellow) folds into an a helix (4) in the complex and interacts with the first two helices of Mat a2, to form a heterodimer that binds to DNA. (Adapted from B.J. Andrews and M.S. Donoviel, Science 270 251-253, 1995.)...

The polypeptide chain of p53 is divided in three domains, each with its own function (Figure 9.16). Like many other transcription factors, p53 has an N-terminal activation domain followed by a DNA-binding domain, while the C-terminal 100 residues form an oligomerization domain involved in the formation of the p53 tetramers. Mutants lacking the C-terminal domain do not form tetramers, but the monomeric mutant molecules retain their sequence-specific DNA-binding properties in vitro. 

The phosducin polypeptide chmn, of some 240 amino acids, is folded into two domains (Figure 13.16). The N-terminal domain is mostly a-helical and appears to be quite flexible since only a weak electron density is obtained in the structure determination. The actual path of the polypeptide chain from the end of helix to the beginning of helix Ba is tentative due to slight disorder. This region is close to serine 73 at the beginning of Ba, which also becomes disordered on phosphorylation. 

The C-terminal domain of phosducin is a five-stranded mixed p sheet with a helices on both sides, similar to the thioredoxin fold of disulfide iso-merase DsbA described in Chapter 6. Despite significant sequence homology to thioredoxin, the phosducin domain, unlike other members of this family. 

Figure 13.16 Schematic diagram of the phosducin molecule. Helices are blue, p strands are red and loop regions are orange. The structure folds into two separate domains, a N-terminal helical domain and a C-terminal domain that has the thioredoxin fold. Some of the loop regions in the helical domain are not well defined. (Adapted from R. Gaudet et al.. Cell 87 577-588, 1996.)...

In the complex with Gpy the two phosducin domains do not interact with each other, instead they wrap around the edge and the top side of the p propeller, to form an extensive interaction surface (Figure 13.17). The N-terminal domain of phosducin interacts with all of the top loops of the p propeller including part of the surface of Cpythat interacts with Gq (Figures 13.15 and 13.17). This interface between phosducin s N-terminal domain and Gpy clearly precludes association of the latter with Gq. 

In the structure of unphosphorylated phosducin that binds to Gpy, Ser 73 points towards the flexible loop of phosducin and not towards Gpy it is, therefore, accessible on the surface for phosphorylation. Phosphorylation of Ser 73 cannot lead to the direct disruption of the phosducin/GpY interaction. Rather, the structure suggests that phosphorylation may lead to conformational changes in the N-terminal domain of phosducin, especially in the flexible loop region, that could weaken or alter the phosducin/GpY interface. 

A unique feature of the interaction of the hormone and PLR is at the beginning of the F-G loop in the C-terminal domain. In HGR the sequence is Arg-Asn-Ser whereas in PLR it is Asp-His-deletion. This loop interacts with His 18 and Glu 174 of the hormone. In PLR the orientation of this loop is such that the Asp and His residues, in combination with His and Glu from the hormone, form a strong binding site for a zinc atom that links the hormone and the receptor (Figure 13.23b). The presence of zinc increases the affinity of the hormone for the receptor in vitro by a factor of 10,000. As shown by mutagenesis studies His 18 and Glu 174 of the hormone are important for the tight binding to PRL but not to GHR. 

Figure 13.23 The F-G loop in the C-terminal domain of the prolactin receptor is involved in a unique interaction, (a) The F-G loop of the growth hormone receptor (blue) is not involved in any specific interactions with the growth hormone (red), (b) The F-G loop in the prolactin receptor forms a strong zinc-binding site that links the receptor (green) to the hormone (red). (Adapted from W. Somers et at.. Nature 372 478-481, 1994.)...

Figure 14.5 The domain organization of intermediate filament protein monomers. Most intermediate filament proteins share a similar rod domain that is usually about 310 amino acids long and forms an extended a helix. The amino-terminal and carboxy-terminal domains are non-a-helical and vary greatly in size and sequence in different intermediate filaments.

Figure 14.15 Stmcture of the SI fragment of chicken myosin as a Richardson diagram (a) and a space-filling model (b). The two light chains are shown in magenta and yellow. The heavy chain is colored according to three proteolytic fragments produced by trypsin a 25-kDa N-terminal domain (green) a central 50-kDa fragment (red) divided by a cleft into a 50K upper and a 50K lower domain and a 20-kDa C-terminal domain (blue) that links the myosin head to the coiled-coil tail. The 50-kDa and 20-kDa domains both bind actin, while the 25-kDa domain binds ATP. [(b) Courtesy of 1. Rayment.]...

The most remarkable feature of the antibody molecule is revealed by comparing the amino acid sequences from many different immunoglobulin IgG molecules. This comparison shows that between different IgGs the amino-terminal domain of each polypeptide chain is highly variable, whereas the remaining domains have constant sequences. A light chain is thus built up from one amino-terminal variable domain (Vl) and one carboxy-terminal constant domain (Cl), and a heavy chain from one amino-terminal variable domain (Vh), followed by three constant domains (Chi, Ch2. and Chs). 

Figure 17.3 The polypeptide chain of lysozyme fiom hacteiiophage T4 folds into two domains. The N-terminal domain is of the a + P type, built up from two a helices (red) and a four-stranded antiparallel P sheet (green). The C-terminal domain comprises seven short a helices (brown and blue) in a rather irregular arrangement. (The last half of this domain is colored blue for clarity.)...

Figure 18.16 One-dlmenslonal NMR spectra, (a) H-NMR spectrum of ethanol. The NMR signals (chemical shifts) for all the hydrogen atoms In this small molecule are clearly separated from each other. In this spectrum the signal from the CH3 protons Is split Into three peaks and that from the CH2 protons Into four peaks close to each other, due to the experimental conditions, (b) H-NMR spectrum of a small protein, the C-terminal domain of a cellulase, comprising 36 amino acid residues. The NMR signals from many individual hydrogen atoms overlap and peaks are obtained that comprise signals from many hydrogen atoms. (Courtesy of Per Kraulis, Uppsala, from data published in Kraulis et al.. Biochemistry 28 7241-7257, 1989.)...

Figure 18.17 Two-dimensional NMR spectnim of the C-terminal domain of a cellulase. The peaks along the diagonal correspond to the spectrum shown in Figure 18.16b. The off-diagonal peaks in this NOE spectrum represent interactions between hydrogen atoms that are closer than 5 A to each other in space. From such a spectrum one can obtain information on both the secondary and tertiary structures of the protein. (Courtesy of Per Kraulis, Uppsala.)...

Figure 18.20 The two-dimensional NMR spectrum shown in Figure 18.17 was used to derive a number of distance constraints for different hydrogen atoms along the polypeptide chain of the C-terminal domain of a cellulase. The diagram shows 10 superimposed structures that all satisfy the distance constraints equally well. These structures are all quite similar since a large number of constraints were experimentally obtained. (Courtesy of P. Kraulis, Uppsala, from data published in P. Kraulis et ah. Biochemistry 28 7241-7257, 1989, by copyright permission of the American Chemical Society.)...

FIGURE 9.14 Glycophorin A spans the membrane of the hnman erythrocyte via a single ff-helical transmembrane segment. The C-terminns of the peptide, whose sequence is shown here, faces the cytosol of the erythrocyte the N-terminal domain is extracellnlar. Points of attachment of carbohydrate groups are indicated. 

Proteolysis of this precursor yields the active form, aerolysiu, which is responsible for the pathogenic effects of the bacterium in deep wound infectious and diarrheal diseases. Like hemolysin, aerolysiu monomers associate to form heptameric membrane pores. The three /3-strands that contribute to the formation of the heptameric pore are shown in red. The N-terminal domain (residues 1-80, yellow) is a small lobe that protrudes from the rest of the protein. 

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