Proper lateral dimerization of the transmembrane domains of receptor tyrosine kinases is required for biochemical signal transduction across the plasma membrane. The spatial structure of the dimeric transmembrane domain of the growth factor receptor ErbB2 embedded into lipid bicelles was obtained by solution NMR, followed by molecular dynamics relaxation in an explicit lipid bilayer. ErbB2 transmembrane segments associate in a right-handed ␣-helical bundle through the N-terminal tandem GG4-like motif Thr 652 -X 3 -Ser 656 -X 3 -Gly 660 , providing an explanation for the pathogenic power of some oncogenic mutations.The epidermal growth factor receptor (or ErbB) family is an important class of receptor tyrosine kinases involved in transmission of biochemical signals governing cell fate (1). Four human ErbB family members form numerous homo-and heterodimer combinations and bind different epidermal growth factor-related ligands, thus performing diverse functions in a complex signaling network (2). The binding of peptide growth factors to the extracellular domain of the receptor triggers the dimerization of receptor monomers or a change in the relative orientation of monomers in preformed receptor dimers, leading to autophosphorylation of tyrosine residues in the cytoplasmic kinase domain (3, 4). Biochemical and genetic studies have revealed that the single-helix transmembrane (TM) 3 domains of ErbB play an active role in the dimerization process and associate strongly in the absence of extracellular ligand-binding and cytoplasmic kinase domains (5, 6). Mutational analysis assumed that the dimerization involves consensus small-X 3 -small (so-called GG4-like) motifs, formed by residues with small side chains allowing tight helix packing (7-9). Receptor tyrosine kinase TM sequences often contain several remote GG4-like motifs, suggesting the ability of their TM domains to adopt more than one conformation, e.g. upon so-called rotation-coupled activation of the receptor (4, 10, 11). Recent molecular modeling and solid-state NMR studies performed to predict the spatial structures of the dimeric TM domains of the human ErbB2 receptor and its rat homolog have disclosed two possible dimer conformations with interfaces located at either the N or C terminus of the ␣-helical TM segment, employing different GG4-like motifs for dimerization (7,(11)(12)(13). Nevertheless, an experimental spatial structure of the dimeric TM domain for ErbB2 as well as for any other receptor tyrosine kinase family members has not been reported so far.Here, we present the high resolution structure of the homodimeric ErbB2 TM domain in a membrane-mimicking lipid environment solved by a heteronuclear NMR technique combined with molecular dynamics (MD) relaxation in an explicit membrane. Our results distinguish one of the potential conformations of the homodimer, which can be ascribed to the active state of the tyrosine kinase. On the basis of the analysis of the local conformation of the dimerization interface, we propose a molecular mechanism of actio...
It is proposed to convert nuclear Overhauser effects (NOEs) into relatively precise distances for detailed structural studies of proteins. To this purpose, it is demonstrated that the measurement of NOE buildups between amide protons in perdeuterated human ubiquitin using a designed (15)N-resolved HMQC-NOESY experiment enables the determination of (1)H(N)-(1)H(N) distances up to 5 A with high accuracy and precision. These NOE-derived distances have an experimental random error of approximately 0.07 A, which is smaller than the pairwise rmsd (root-mean-square deviation) of 0.24 A obtained with corresponding distances extracted from either an NMR or an X-ray structure (pdb codes: 1D3Z and 1UBQ), and also smaller than the pairwise rmsd between distances from X-ray and NMR structures (0.15 A). Because the NOE contains both structural and dynamical information, a comparison between the 3D structures and NOE-derived distances may also give insights into through-space dynamics. It appears that the extraction of motional information from NOEs by comparison to the X-ray structure or the NMR structure is challenging because the motion may be masked by the quality of the structures. Nonetheless, a detailed analysis thereof suggests motions between beta-strands and large complex motions in the alpha-helix of ubiquitin. The NOE-derived motions are, however, of smaller amplitude and possibly of a different character than those present in a 20 ns molecular dynamic simulation of ubiquitin in water using the GROMOS force field. Furthermore, a recently published set of structures representing the conformational distribution over time scales up to milliseconds (pdb: 2K39) does not satisfy the NOEs better than the single X-ray structure. Hence, the measurement of possibly thousands of exact NOEs throughout the protein may serve as an excellent probe toward a correct representation of both structure and dynamics of proteins.
Based on the 1 H-15 N NMR spectroscopy data, the three-dimensional structure and internal dynamic properties of ribosomal protein L7 from Escherichia coli were derived. The structure of L7 dimer in solution can be described as a set of three distinct domains, tumbling rather independently and linked via flexible hinge regions. The dimeric N-terminal domain (residues 1-32) consists of two antiparallel ␣-␣-hairpins forming a symmetrical four-helical bundle, whereas the two identical C-terminal domains (residues 52-120) adopt a compact ␣/-fold. There is an indirect evidence of the existence of transitory helical structures at least in the first part (residues 33-43) of the hinge region. Combining structural data for the ribosomal protein L7/L12 from NMR spectroscopy and x-ray crystallography, it was suggested that its hinge region acts as a molecular switch, initiating "ratchet-like" motions of the L7/L12 stalk with respect to the ribosomal surface in response to elongation factor binding and GTP hydrolysis. This hypothesis allows an explanation of events observed during the translation cycle and provides useful insights into the role of protein L7/L12 in the functioning of the ribosome.
Antimicrobial peptides (AMPs) are ubiquitous agents that play a crucial role in the host defense systems of bacteria, fungi, plants and animals [1][2][3]. In higher vertebrates, these peptides work in synergy with the adaptive immune system and form the basis of 'so-called' innate immunity [2]. At the same time, AMPs of plants provide one of the major barriers for invading pathogens and significantly enhance the Cyclotides are a family of bioactive plant peptides that are characterized by a circular protein backbone and three conserved tightly packed disulfide bonds. The antimicrobial and hemolytic properties of cyclotides, along with the relative hydrophobicity of the peptides, point to the biological membrane as a target for cyclotides. To assess the membrane-induced conformation and orientation of cyclotides, the interaction of the Mo¨bius cyclotide, kalata B1, from the African perennial plant Oldenlandia affinis, with dodecylphosphocholine micelles was studied using NMR spectroscopy. Under conditions where the cyclotide formed a well-defined complex with micelles, the spatial structure of kalata B1 was calculated from NOE and J couplings data, and the model for the peptide-micelle complex was built using 5-and 16-doxylstearate relaxation probes. The binding of divalent cations to the peptide-micelle complex was quantified by Mn 2+ titration. The results show that the peptide binds to the micelle surface, with relatively high affinity, via two hydrophobic loops (loop 5, Trp19-Val21; and loop6, Leu27-Val29). The charged residues (Glu3 and Arg24), along with the cation-binding site (near Glu3) are segregated on the other side of the molecule and in contact with polar head groups of detergent. The spatial structure of kalata B1 is only slightly changed during incorporation into micelles and represents a distorted triple-stranded b-sheet cross-linked by a cystine knot. Detailed structural analysis and comparison with other knottins revealed structural conservation of the two-disulfide motif in cyclic and acyclic peptides. The results thus obtained provide the first model for interaction of cyclotides with membranes and permit consideration of the cyclotides as membrane-active cationic antimicrobial peptides.
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