Protein Flexibility Facilitates Quaternary Structure Assembly and Evolution

The intrinsic flexibility of proteins allows them to undergo large conformational fluctuations in solution or upon interaction with other molecules. Proteins also commonly assemble into complexes with diverse quaternary structure arrangements. Here we investigate how the flexibility of individual protein chains influences the assembly and evolution of protein complexes. We find that flexibility appears to be particularly conducive to the formation of heterologous (i.e., asymmetric) intersubunit interfaces. This leads to a strong association between subunit flexibility and homomeric complexes with cyclic and asymmetric quaternary structure topologies. Similarly, we also observe that the more nonhomologous subunits that assemble together within a complex, the more flexible those subunits tend to be. Importantly, these findings suggest that subunit flexibility should be closely related to the evolutionary history of a complex. We confirm this by showing that evolutionarily more recent subunits are generally more flexible than evolutionarily older subunits. Finally, we investigate the very different explorations of quaternary structure space that have occurred in different evolutionary lineages. In particular, the increased flexibility of eukaryotic proteins appears to enable the assembly of heteromeric complexes with more unique components.     

Distinct contributions of T1R2 and T1R3 taste receptor subunits to the detection of sweet stimuli

Animals utilize hundreds of distinct G protein-coupled receptor (GPCR)-type chemosensory receptors to detect a diverse array of chemical signals in their environment, including odors, pheromones, and tastants. However, the molecular mechanisms by which these receptors selectively interact with their cognate ligands remain poorly understood. There is growing evidence that many chemosensory receptors exist in multimeric complexes, though little is known about the relative contributions of individual subunits to receptor functions. Here, we report that each of the two subunits in the heteromeric T1R2:T1R3 sweet taste receptor binds sweet stimuli though with distinct affinities and conformational changes. Furthermore, ligand affinities for T1R3 are drastically reduced by the introduction of a single amino acid change associated with decreased sweet taste sensitivity in behaving mice. Thus, individual T1R subunits increase the receptive range of the sweet taste receptor, offering a functional mechanism for phenotypic variations in sweet taste.     

Inactivation and reactivation of proteins (enzymes)

The molecular mechanisms of protein inactivation, i.e. aggregation, thiol-disulphide exchange, alteration of the primary structure, dissociation of cofactor molecules from the active centre, dissociation of the oligomeric proteins into subunits and conformational changes have been analysed. All these mechanisms are closely interrelated during inactivation of proteins. However, in many cases, the conformational changes accompany and trigger other inactivation processes. Reactivation of irreversibly inactivated proteins is·discussed. Reactivation can be successful when inactivation has been caused by aggregation, modification of SH-groups (or S-S bonds) or as a consequence of irreversible conformational changes.     

Role and regulation of prolyl hydroxylase domain proteins

Oxygen-dependent hydroxylation of hypoxia-inducible factor (HIF)-alpha subunits by prolyl hydroxylase domain (PHD) proteins signals their polyubiquitination and proteasomal degradation, and plays a critical role in regulating HIF abundance and oxygen homeostasis. While oxygen concentration plays a major role in determining the efficiency of PHD-catalyzed hydroxylation reactions, many other environmental and intracellular factors also significantly modulate PHD activities. In addition, PHDs may also employ hydroxylase-independent mechanisms to modify HIF activity. Interestingly, while PHDs regulate HIF-alpha protein stability, PHD2 and PHD3 themselves are subject to feedback upregulation by HIFs. Functionally, different PHD isoforms may differentially contribute to specific pathophysiological processes, including angiogenesis, erythropoiesis, tumorigenesis, and cell growth, differentiation and survival. Because of diverse roles of PHDs in many different processes, loss of PHD expression or function triggers multi-faceted pathophysiological changes as has been shown in mice lacking different PHD isoforms. Future investigations are needed to explore in vivo specificity of PHDs over different HIF-alpha subunits and differential roles of PHD isoforms in different biological processes.     

Selectivity, cooperativity, and reciprocity in the interactions between the delta-opioid receptor, its ligands, and G-proteins

A better understanding of signal transduction mechanisms is of critical importance. Methodologies that allow studies to be done while receptors are incorporated into lipid bilayers are advantageous. One such technique is plasmon-waveguide resonance (PWR) spectroscopy, which can follow changes in conformation accompanying protein-ligand, protein-protein, and protein-lipid interactions occurring in G-protein-coupled receptors in real time with high sensitivity and without the need for molecular labeling. Here we investigated several aspects of human delta-opioid receptor (hDOR)-G-protein interactions: 1) the effect of different types of agonists on the interaction with individual G-protein subtypes; 2) the affinities of the separate G-protein alpha and betagamma subunits to different ligand-occupied states of the receptor; and 3) the effect of the presence of the G-protein on the interactions of the ligand with the receptor. To accomplish this we have incorporated the receptor into a solid supported lipid bilayer in the presence of ligand or G-protein and monitored the PWR spectral changes induced by the reciprocal G-protein or ligand interactions. We found a high degree of selectivity in the interactions of different agonist-bound states of the receptor with the different G-protein subtypes. This has important implications for agonist-directed trafficking and selective drug design. Studies with the separated alpha and betagamma subunits show that cooperativity exists in these interactions. The high affinities of the separated subunits to the receptor point to the possibility of independent promotion of specific signaling events. The presence of G-proteins increased the affinity of agonists to the hDOR, and caused faster binding kinetics and different ligand-induced conformational changes. Because ligand also influences G-protein binding, reciprocity exists between these two binding processes.     

Statics of the Ribosomal Exit Tunnel: Implications for Cotranslational Peptide Folding, Elongation Regulation, and Antibiotics Binding

A sophisticated interplay between the static properties of the ribosomal exit tunnel and its functional role in cotranslational processes is revealed by constraint counting on topological network representations of large ribosomal subunits from four different organisms. As for the global flexibility characteristics of the subunit, the results demonstrate a conserved stable structural environment of the tunnel. The findings render unlikely that deformations of the tunnel move peptides down the tunnel in an active manner. Furthermore, the stable environment rules out that the tunnel can adapt widely so as to allow tertiary folding of nascent chains. Nevertheless, there are local zones of flexible nucleotides within the tunnel, between the peptidyl transferase center and the tunnel constriction, and at the tunnel exit. These flexible zones strikingly agree with previously identified folding zones. As for cotranslational elongation regulation, flexible residues in the β-hairpin of the ribosomal L22 protein were verified, as suggested previously based on structural results. These results support the hypothesis that L22 can undergo conformational changes that regulate the tunnel voyage of nascent polypeptides. Furthermore, rRNA elements, for which conformational changes have been observed upon interaction of the tunnel wall with a nascent SecM peptide, are less strongly coupled to the subunit core. Sequences of coupled rigid clusters are identified between the tunnel and some of these elements, suggesting signal transmission by a domino-like mechanical coupling. Finally, differences in the flexibility of the glycosidic bonds of bases that form antibiotics-binding crevices within the peptidyl transferase center and the tunnel region are revealed for ribosomal structures from different kingdoms. In order to explain antibiotics selectivity, action, and resistance, according to these results, differences in the degrees of freedom of the binding regions may need to be considered.     

Flexibility, diversity, and cooperativity: pillars of enzyme catalysis

This brief review discusses our current understanding of the molecular basis of enzyme catalysis. A historical development is presented, beginning with steady state kinetics and progressing through modern fast reaction methods, nuclear magnetic resonance, and single-molecule fluorescence techniques. Experimental results are summarized for ribonuclease, aspartate aminotransferase, and especially dihydrofolate reductase (DHFR). Multiple intermediates, multiple conformations, and cooperative conformational changes are shown to be an essential part of virtually all enzyme mechanisms. In the case of DHFR, theoretical investigations have provided detailed information about the movement of atoms within the enzyme-substrate complex as the reaction proceeds along the collective reaction coordinate for hydride transfer. A general mechanism is presented for enzyme catalysis that includes multiple intermediates and a complex, multidimensional standard free energy surface. Protein flexibility, diverse protein conformations, and cooperative conformational changes are important features of this model.     

Chemical and NADH-induced, ROS-dependent, cross-linking between subunits of complex I from Escherichia coli and Thermus thermophilus

Complex I of respiratory chains transfers electrons from NADH to ubiquinone, coupled to the translocation of protons across the membrane. Two alternative coupling mechanisms are being discussed, redox-driven or conformation-driven. Using "zero-length" cross-linking reagent and isolated hydrophilic domains of complex I from Escherichia coli and Thermus thermophilus, we show that the pattern of cross-links between subunits changes significantly in the presence of NADH. Similar observations were made previously with intact purified E. coli and bovine complex I. This indicates that, upon reduction with NADH, similar conformational changes are likely to occur in the intact enzyme and in the isolated hydrophilic domain (which can be used for crystallographic studies). Within intact E. coli complex I, the cross-link between the hydrophobic subunits NuoA and NuoJ was abolished in the presence of NADH, indicating that conformational changes extend into the membrane domain, possibly as part of a coupling mechanism. Unexpectedly, in the absence of any chemical cross-linker, incubation of complex I with NADH resulted in covalent cross-links between subunits Nqo4 (NuoCD) and Nqo6 (NuoB), as well as between Nqo6 and Nqo9. Their formation depends on the presence of oxygen and so is likely a result of oxidative damage via reactive oxygen species (ROS) induced cross-linking. In addition, ROS- and metal ion-dependent proteolysis of these subunits (as well as Nqo3) is observed. Fe-S cluster N2 is coordinated between subunits Nqo4 and Nqo6 and could be involved in these processes. Our observations suggest that oxidative damage to complex I in vivo may include not only side-chain modifications but also protein cross-linking and degradation.     

RIC-3 and nicotinic acetylcholine receptors: biogenesis, properties, and diversity

Nicotinic acetylcholine receptors (nAChRs) belong to a diverse and widely expressed family of ion channels. These receptors are pentamers assembled from multiple combinations of subunits, with different subunit compositions producing receptors having different properties and functions. The diverse functions of nAChRs include an essential role in excitation of skeletal muscles and many modulatory roles throughout the central nervous system. Nicotinic receptors are also implicated in a number of brain pathologies such as epilepsy, schizophrenia, and Alzheimer's disease. Thus, it is important to understand the cellular mechanisms controlling both the numbers and the properties of surface expressed nAChRs. Genetic analysis in Caenorhabditis elegans identified a number of proteins specifically needed for biogenesis of nAChRs. Among these proteins is RIC-3, a member of a family of proteins having conserved structure and function. RIC-3 influences both surface expression and properties of nAChRs and its effects are subtype specific. Here we suggest that receptor-specific chaperones such as RIC-3 may play important roles in controlling receptor diversity by selectively regulating surface expression of nAChRs having specific subunit compositions.     

Processing, shedding, and endocytosis of membrane type 1-matrix metalloproteinase (MT1-MMP)

Matrix metalloproteinases (MMPs) are multidomain zinc-dependent proteolytic enzymes that play pivotal roles in many normal and pathological processes. Some members of the MMP family are anchored to the plasma membrane via specialized domains and thus are perfectly suited for pericellular proteolysis. Membrane-anchoring also confers the membrane type-MMPs (MT-MMPs) a unique and complex array of regulatory processes that endow cells with the ability to control MT-MMP-dependent proteolytic activity independently of the levels of endogenous protease inhibitors. Emerging evidence indicates that mechanisms as diverse as autocatalytic processing, ectodomain shedding, homodimerization and internalization can all contribute to the modulation of MT-MMP activity on the cell surface. How these distinct processes interact to attain the optimal level of enzyme activity in a particular setting and the molecular signals that trigger them constitute a new paradigm in MMP regulation. This review will discuss the recent findings concerning these diverse regulatory mechanisms in the context of MT1-MMP (MMP-14).     

环核苷酸门控离子通道门控的分子机理

环核苷酸门控离子通道(CNG)最广泛地分布于神经细胞。近年来关于 CNG 通道门控的分子机制的研究取得了很大的进步。研究表明, CNG 通道的组成及组装影响通道的特性及门控。近年来有关 CNG 突变体的研究及半胱氨酸残基亲和性的分析表明, 环核苷酸首先结合到 CNG 通道 C 端的环核苷酸结合域(CNBD)上引起 CNBD 空间构像改变, 然后 4 个亚单元发生空间构像的协调改变, CNG 通道开放。本文详细讨论了 CNG 通道的门控机制、各亚单元之间的相互作用、组装的过程及其空间构想的变化, 为 CNG 通道的进一步研究, 尤其是离子通道疾病方面提供理论指导。     

X-ray solution scattering (SAXS) combined with crystallography and computation: defining accurate macromolecular structures, conformations and assemblies in solution

Crystallography supplies unparalleled detail on structural information critical for mechanistic analyses; however, it is restricted to describing low energy conformations of macromolecules within crystal lattices. Small angle X-ray scattering (SAXS) offers complementary information about macromolecular folding, unfolding, aggregation, extended conformations, flexibly linked domains, shape, conformation, and assembly state in solution, albeit at the lower resolution range of about 50 A to 10 A resolution, but without the size limitations inherent in NMR and electron microscopy studies. Together these techniques can allow multi-scale modeling to create complete and accurate images of macromolecules for modeling allosteric mechanisms, supramolecular complexes, and dynamic molecular machines acting in diverse processes ranging from eukaryotic DNA replication, recombination and repair to microbial membrane secretion and assembly systems. This review addresses both theoretical and practical concepts, concerns and considerations for using these techniques in conjunction with computational methods to productively combine solution scattering data with high-resolution structures. Detailed aspects of SAXS experimental results are considered with a focus on data interpretation tools suitable to model protein and nucleic acid macromolecular structures, including membrane protein, RNA, DNA, and protein-nucleic acid complexes. The methods discussed provide the basis to examine molecular interactions in solution and to study macromolecular flexibility and conformational changes that have become increasingly relevant for accurate understanding, simulation, and prediction of mechanisms in structural cell biology and nanotechnology.     

Exploring the range of protein flexibility, from a structural proteomics perspective

Changes in protein conformation play a vital role in biochemical processes, from biopolymer synthesis to membrane transport. Initial systematizations of protein flexibility, in a database framework, concentrated on the movement of domains and linkers. Movements were described in terms of simple sliding and hinging mechanisms of individual secondary structural elements. Recently, the accelerated pace and sophistication of methods for structural characterization of proteins has allowed high-resolution studies of increasingly complex assemblies and conformational changes. New data emphasize a breadth of possible structural mechanisms, particularly the ability to drastically alter protein architecture and the native flexibility of many structures.     

The nomenclature and conformational analysis of lipids and lipid analogues

Lipids form an essential part of the biomembrane and it is of paramount importance to study their conformational aspects. It is found that the present methods of nomenclature for lipids are totally inadequate for describing these diverse amphipathic molecules. Further the existing methods are incompatible in terms of assignment of the absolute configuration. A systematic method for the naming of lipids which is rationally extendible to a wide class of amphipaths is described. The conformational features of the natural glycerolipids as well as a synthetic amphipath containing a glutamic acid moiety known to undergo interesting phase transitions, have been examined in detail using the framework of the current nomenclature system. The implications of the conformational flexibility of these molecules on assemblies of these systems is touched upon.     

Mammalian Kidney Development: Principles,Progress, and Projections

The mammalian kidney is a vital organ with considerable cellular complexity and functional diversity. Kidney development is notable for requiring distinct but coincident tubulogenic processes involving reciprocal inductive signals between mesenchymal and epithelial progenitor compartments. Key molecular pathways mediating these interactions have been identified. Further, advances in the analysis of gene expression and gene activity, coupled with a detailed knowledge of cell origins, are enhancing our understanding of kidney morphogenesis and unraveling the normal processes of postnatal repair and identifying disease-causing mechanisms. This article focuses on recent insights into central regulatory processes governing organ assembly and renal disease, and predicts future directions for the field.     

Condensins: organizing and segregating the genome

Condensins are multi-subunit protein complexes that play a central role in mitotic chromosome assembly and segregation. The complexes contain 'structural maintenance of chromosomes' (SMC) ATPase subunits, and induce DNA supercoiling and looping in an ATP-hydrolysis-dependent manner in vitro. Vertebrate cells have two different condensin complexes, condensins I and II, each containing a unique set of regulatory subunits. Condensin II participates in an early stage of chromosome condensation within the prophase nucleus. Condensin I gains access to chromosomes only after the nuclear envelope breaks down, and collaborates with condensin II to assemble metaphase chromosomes with fully resolved sister chromatids. The complexes also play critical roles in meiotic chromosome segregation and in interphase processes such as gene repression and checkpoint responses. In bacterial cells, ancestral forms of condensins control chromosome dynamics. Dissecting the diverse functions of condensins is likely to be central to our understanding of genome organization, stability and evolution.