Proteins mediate transmission of signals along intercellular and intracellular pathways and between the exterior and the interior of a cell. The dynamic properties of signaling proteins are crucial to their functions. We discuss emerging paradigms for the role of protein dynamics in signaling. A central tenet is that proteins fluctuate among many states on evolutionarily selected energy landscapes. Upstream signals remodel this landscape, causing signaling proteins to transmit information to downstream partners. New methods provide insight into the dynamic properties of signaling proteins at the atomic scale. The next stages in the signaling hierarchyhow multiple signals are integrated and how cellular signaling pathways are organized in space and time-present exciting challenges for the future, requiring bold multidisciplinary approaches.Transmission of signals between cells, within cells, and from the extracellular environment to the cellular interior is essential to life. In recent years, we have gained tremendous knowledge of the interacting networks that act as communication pathways for cellular signaling, culminating with extensive maps of "interactomes" based on genetic and physical interaction data [e.g., (1)]. Yet we know far less about how signals are passed from one component of a network to another. This puzzle can be viewed at the level of the protein machines that make up signaling networks: How does information, generally mediated by a binding interaction or a covalent modification, get relayed to the downstream member of the pathway?It is increasingly apparent that signaling relies on the intrinsic dynamic properties of proteins and that proteins relay signals by shifting among different fluctuating energy states in response to one or more inputs. This emerging view of signaling raises many compelling questions: What is the genetic information that encodes the functionally productive dynamic properties of a protein? How do individual protein domains cooperate to form signaling pathways? How are signals integrated in multicomponent interconnecting networks? How do the dynamics of signaling proteins ultimately determine the response times of cells to signals and the time scales for signal propagation? We are beginning to develop the methods and principles to address these questions, but many challenges lie ahead. Our ability to develop therapeutic modulators of signaling and to reengineer cellular communication pathways will rely on progress in this fascinating but complex arena.The intrinsic motions of proteins are determined by the covalent and noncovalent restraining forces that hold them together. The result is a symphony of dynamic modes oscillating at frequencies from picoseconds to milliseconds or even seconds. Tweaking a protein by a binding interaction or chemical modification alters this symphony, either gently changing its pitch or abruptly shifting the collective harmony. Just as the ability of a protein to fold is now understood to be best described by an "energy landscape," w...
The Hsp70 family of molecular chaperones provides a well defined and experimentally powerful model system for understanding allosteric coupling between different protein domains.New extensions to the statistical coupling analysis (SCA) method permit identification of a group of co-evolving amino-acid positions—a sector—in the Hsp70 that is associated with allosteric function.Literature-based and new experimental studies support the notion that the protein sector identified through SCA underlies the allosteric mechanism of Hsp70.This work extends the concept of protein sectors by showing that two non-homologous protein domains can share a single sector when the underlying biological function is defined by the coupled activity of the two domains.
SummaryMolecular evolution has focused on the divergence of molecular functions, yet we know little about how structurally distinct protein folds emerge de novo. We characterized the evolutionary trajectories and selection forces underlying emergence of β-propeller proteins, a globular and symmetric fold group with diverse functions. The identification of short propeller-like motifs (<50 amino acids) in natural genomes indicated that they expanded via tandem duplications to form extant propellers. We phylogenetically reconstructed 47-residue ancestral motifs that form five-bladed lectin propellers via oligomeric assembly. We demonstrate a functional trajectory of tandem duplications of these motifs leading to monomeric lectins. Foldability, i.e., higher efficiency of folding, was the main parameter leading to improved functionality along the entire evolutionary trajectory. However, folding constraints changed along the trajectory: initially, conflicts between monomer folding and oligomer assembly dominated, whereas subsequently, upon tandem duplication, tradeoffs between monomer stability and foldability took precedence.
The 70-kDa heat shock proteins (Hsp70s) function as molecular chaperones through the allosteric coupling of their nucleotide-and substrate-binding domains, the structures of which are highly conserved. In contrast, the roles of the poorly structured, variable length C-terminal regions present on Hsp70s remain unclear. In many eukaryotic Hsp70s, the extreme C-terminal EEVD tetrapeptide sequence associates with co-chaperones via binding to tetratricopeptide repeat domains. It is not known whether this is the only function for this region in eukaryotic Hsp70s and what roles this region performs in Hsp70s that do not form complexes with tetratricopeptide repeat domains. We compared C-terminal sequences of 730 Hsp70 family members and identified a novel conservation pattern in a diverse subset of 165 bacterial and organellar Hsp70s. Mutation of conserved C-terminal sequence in DnaK, the predominant Hsp70 in Escherichia coli, results in significant impairment of its protein refolding activity in vitro without affecting interdomain allostery, interaction with co-chaperones DnaJ and GrpE, or the binding of a peptide substrate, defying classical explanations for the chaperoning mechanism of Hsp70. Moreover, mutation of specific conserved sites within the DnaK C terminus reduces the capacity of the cell to withstand stresses on protein folding caused by elevated temperature or the absence of other chaperones. These features of the C-terminal region support a model in which it acts as a disordered tether linked to a conserved, weak substrate-binding motif and that this enhances chaperone function by transiently interacting with folding clients.The ubiquitously distributed Hsp70 family of molecular chaperones shepherd newly synthesized polypeptide chains, protect cells from stress-induced protein aggregation, assist in protein translocation across membranes, and regulate assembly and disassembly of macromolecular complexes. These physiological functions are accomplished by a two-domain allosteric mechanism in which cycles of ATP binding and hydrolysis in the N-terminal nucleotide-binding domain (NBD) 2 control the binding and release of hydrophobic polypeptide segments in the substrate-binding domain (SBD) (1-3). Although we have gained an increasingly detailed picture of this allosteric transition in Hsp70 chaperones and modes of substrate interaction (4 -7), it is striking that there is much less known about the function of the extreme C-terminal unstructured region (Fig. 1). Binding of the C-terminal region of mammalian Hsc70 to substrate was suggested in earlier work (8, 9), and more recently, the C-terminal segment of eukaryotic cytoplasmic Hsp70s was found to contain a conserved tetratricopeptide repeat (TPR) domain interaction motif that mediates binding with Chip, Hip, or Hop co-chaperones that facilitate the assembly of a variety of Hsp70 complexes (3). Even though bacteria lack homologs of these Hsp70-interacting TPR domain proteins, many, including the extensively characterized E. coli Hsp70 DnaK, have a disord...
Glycosaminoglycans (GAGs) play a widespread role in embryonic development, as deletion of enzymes that contribute to GAG synthesis lead to deficiencies in cell migration and tissue modelling. Despite the biochemical and structural characterization of individual protein/GAG interactions, there is no concept available that links the molecular mechanisms of GAG/protein engagements to tissue development. Here, we focus on the role of GAG polymers in mediating interactions between cell surface receptors and their ligands. We categorize several switches that lead to ligand activation, inhibition, selection and addition, based on recent structural studies of select receptor/ligand complexes. Based on these principles, we propose that individual GAG polymers may affect several receptor pathways in parallel, orchestrating a cellular response to an environmental cue. We believe that it is worthwhile to study the role of GAGs as molecular switches, as this may lead to novel drug candidates to target processes such as angiogenesis, neuroregeneration and tumour metastasis.
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