Molecular chaperone functions in protein folding and proteostasis.

The biological functions of proteins are governed by their three-dimensional fold. Protein folding, maintenance of proteome integrity, and protein homeostasis (proteostasis) critically depend on a complex network of molecular chaperones. Disruption of proteostasis is implicated in aging and the pathogenesis of numerous degenerative diseases. In the cytosol, different classes of molecular chaperones cooperate in evolutionarily conserved folding pathways. Nascent polypeptides interact cotranslationally with a first set of chaperones, including trigger factor and the Hsp70 system, which prevent premature (mis)folding. Folding occurs upon controlled release of newly synthesized proteins from these factors or after transfer to downstream chaperones such as the chaperonins. Chaperonins are large, cylindrical complexes that provide a central compartment for a single protein chain to fold unimpaired by aggregation. This review focuses on recent advances in understanding the mechanisms of chaperone action in promoting and regulating protein folding and on the pathological consequences of protein misfolding and aggregation.

Soluble Oligomers of PolyQ-Expanded Huntingtin Target a Multiplicity of Key Cellular Factors.

Huntington's disease is one of several neurodegenerative disorders characterized by the aggregation of polyglutamine (polyQ)-expanded mutant protein. How polyQ aggregation leads to cellular dysfunction is not well understood. Here, we analyzed aberrant protein interactions of soluble oligomers and insoluble inclusions of mutant huntingtin using in-cell single molecule fluorescence spectroscopy and quantitative proteomics. We find that the interactome of soluble oligomers is highly complex, with an enrichment of RNA-binding proteins as well as proteins functioning in ribosome biogenesis, translation, transcription, and vesicle transport. The oligomers frequently target proteins containing extended low-complexity sequences, potentially interfering with key cellular pathways. In contrast, the insoluble inclusions are less interactive and associate strongly with protein quality control components, such as Hsp40 chaperones and factors of the ubiquitin-proteasome system. Our results suggest a "multiple hit" model for the pathogenic effects of mutant huntingtin, with soluble forms engaging more extensively in detrimental interactions than insoluble aggregates.

Engineering a polarity-sensitive biosensor for time-lapse imaging of apoptotic processes and degeneration.

Apoptosis is of central importance to many areas of biological research, but there is a lack of methods that permit continuous monitoring of apoptosis or cell viability in a nontoxic and noninvasive manner. Here we report the development of a tool applicable to live-cell imaging that facilitates the visualization of real-time apoptotic changes without perturbing the cellular environment. We designed a polarity-sensitive annexin-based biosensor (pSIVA) with switchable fluorescence states, which allows detection only when bound to apoptotic cells. Using pSIVA with live-cell imaging, we observed dynamic local changes in individual rat neurons during degeneration in vitro and in vivo. Furthermore, we observed that pSIVA binding was reversible and clearly defined the critical period for neurons to be rescued. We anticipate pSIVA can be widely applied to address questions concerning spatiotemporal events in apoptotic processes, its reversibility and the general viability of cells in culture.

A compact beta model of huntingtin toxicity.

Huntington disease results from an expanded polyglutamine region in the N terminus of the huntingtin protein. HD pathology is characterized by neuronal degeneration and protein inclusions containing N-terminal fragments of mutant huntingtin. Structural information is minimal, though it is believed that mutant huntingtin polyglutamine adopts ß structure upon conversion to a toxic form. To this end, we designed mammalian cell expression constructs encoding compact ß variants of Htt exon 1 N-terminal fragment and tested their ability to aggregate and induce toxicity in cultured neuronal cells. In parallel, we performed molecular dynamics simulations, which indicate that constructs with expanded polyglutamine ß-strands are stabilized by main-chain hydrogen bonding. Finally, we found a correlation between the reactivity to 3B5H10, an expanded polyglutamine antibody that recognizes a compact ß rich hairpin structure, and the ability to induce cell toxicity. These data are consistent with an important role for a compact ß structure in mutant huntingtin-induced cell toxicity.

ESCAPE: database for integrating high-content published data collected from human and mouse embryonic stem cells.

High content studies that profile mouse and human embryonic stem cells (m/hESCs) using various genome-wide technologies such as transcriptomics and proteomics are constantly being published. However, efforts to integrate such data to obtain a global view of the molecular circuitry in m/hESCs are lagging behind. Here, we present an m/hESC-centered database called Embryonic Stem Cell Atlas from Pluripotency Evidence integrating data from many recent diverse high-throughput studies including chromatin immunoprecipitation followed by deep sequencing, genome-wide inhibitory RNA screens, gene expression microarrays or RNA-seq after knockdown (KD) or overexpression of critical factors, immunoprecipitation followed by mass spectrometry proteomics and phosphoproteomics. The database provides web-based interactive search and visualization tools that can be used to build subnetworks and to identify known and novel regulatory interactions across various regulatory layers. The web-interface also includes tools to predict the effects of combinatorial KDs by additive effects controlled by sliders, or through simulation software implemented in MATLAB. Overall, the Embryonic Stem Cell Atlas from Pluripotency Evidence database is a comprehensive resource for the stem cell systems biology community. Database URL: http://www.maayanlab.net/ESCAPE

Monitoring apoptosis and neuronal degeneration by real-time detection of phosphatidylserine externalization using a polarity-sensitive indicator of viability and apoptosis.

Applications for noninvasive real-time imaging of apoptosis and neuronal degeneration are hindered by technical limitations in imaging strategies and by existing probes. Monitoring the progression of a cell through apoptosis could provide valuable insight into the temporal events that initiate cell death as well as the potential for rescue of apoptotic cells. We engineered an annexin-based biosensor to function as a polarity-sensitive indicator for viability and apoptosis (known as pSIVA) by binding to externalized phosphatidylserine (PS) exposed on apoptotic cell membranes. Constructed from a structure-based design strategy, pSIVA fluoresces only when bound to PS and remains effectively undetectable in solution. In this paper, we describe protocols for the design, expression, purification and labeling of pSIVA as well as for its application in time-lapse imaging of degenerating neurons in culture; the entire protocol can be completed in 2 weeks. The primary advantage of this method is the flexibility to use pSIVA, in combination with other probes and without perturbing experimental conditions, to explore the cellular mechanisms involved in apoptosis and degeneration in real time.

Effect of pseudorepeat rearrangement on alpha-synuclein misfolding, vesicle binding, and micelle binding.

The pathological and physiological hallmarks of the protein alpha-synuclein (aS) are its misfolding into cytotoxic aggregates and its binding to synaptic vesicles, respectively. Both events are mediated by seven 11-residue amphiphilic pseudorepeats and, most generally, involve a transition from intrinsically unstructured conformations to structured conformations. Based on aS interactions with aggregation-inhibiting small molecules, an aS variant termed shuffled alpha-synuclein (SaS), wherein the first six pseudorepeats had been rearranged, was introduced. Here, the effects of this rearrangement on misfolding, vesicle binding, and micelle binding are examined in reference to aS and beta-synuclein to study the sequence characteristics underlying these processes. Fibrillization correlates with the distinct clustering of residues with high beta-sheet propensities, while vesicle affinities depend on the mode of pseudorepeat interchange and loss. In the presence of micelles, the pseudorepeat region of SaS adopts an essentially continuous helix, whereas aS and beta-synuclein encounter a distinct helix break, indicating that a more homogeneous distribution of surfactant affinities in SaS prevented the formation of an extensive helix break in the micelle-bound state. By demonstrating the importance of the distribution of beta-sheet propensities and by revealing inhomogeneous aS surfactant affinities, the present study provides novel insights into two central themes of synuclein biology.

A helical hairpin region of soluble annexin B12 refolds and forms a continuous transmembrane helix at mildly acidic pH.

Annexins are soluble proteins that are best known for their ability to undergo reversible Ca(2+)-dependent binding to the surface of phospholipid bilayers. Recent studies, however, have shown that annexins also reversibly bind to membranes in a Ca(2+)-independent manner at mildly acidic pH. We investigated the structural changes that occur upon pH-dependent membrane binding by performing a nitroxide scan on the helical hairpin encompassing helices A and B in the fourth repeat of annexin B12. Residues 251-273 of annexin B12 were replaced, one at a time, with cysteine and then labeled with a nitroxide spin label. Electron paramagnetic resonance (EPR) mobility and accessibility analyses of soluble annexin B12 derivatives were in excellent agreement with the known crystal structure of annexin B12. However, EPR studies of annexin B12 derivatives bound to membranes at pH 4.0 indicated major structural changes in the scanned region. The helix-loop-helix structure present in the soluble protein was converted into a continuous transmembrane alpha-helix that was exposed to the hydrophobic core of the bilayer on one side and exposed to an aqueous pore on the other side. Asp-264 was on the hydrophobic membrane-exposed face of the amphipathic transmembrane helix, thereby suggesting that protonation of its carboxylate group stabilized the transmembrane form. Inspection of the amino acid sequence of annexin B12 revealed several other helical hairpin regions that might refold and form continuous amphipathic transmembrane helices in response to protonation of Asp or Glu switch residues on or near the hydrophobic face of the helix.

Calcium- and membrane-induced changes in the structure and dynamics of three helical hairpins in annexin B12.

Annexins are a family of soluble proteins that can undergo reversible Ca(2+)-dependent interaction with the interfacial region of phospholipid membranes. The helical hairpins on the convex face of the crystal structure of soluble annexins are proposed to mediate binding to membranes, but the mechanism is not defined. For this study, we used a site-directed spin labeling (SDSL) experimental approach to investigate Ca(2+) and membrane-induced structural and dynamic changes that occurred in the helical hairpins encompassing three of the four D and E helices of annexin B12. Electron paramagnetic resonance (EPR) parameters were analyzed for the soluble and Ca(2+)-dependent membrane-bound states of the following nitroxide scans of annexin B12: a continuous 24-residue scan of the D and E helices in the third repeat (residues 219-242) and short scans encompassing the D-E loop regions of the first repeat (residues 68-74) and the fourth repeat (300-305). EPR mobility and accessibility parameters of most sites were similar when the protein was in solution or in the membrane-bound state, and both sets of data were consistent with the crystal structure of the protein. However, membrane-induced changes in mobility and accessibility were observed in all three loop regions, with the most dramatic changes noted at sites corresponding to the highly conserved serine and glycine residues in the loops. EPR accessibility parameters clearly established that nitroxide side chains placed at these sites made direct contact with the bilayer. EPR mobility parameters showed that these sites were very mobile in solution, but immobilized on the EPR time scale in the membrane-bound state. Since the headgroup regions of bilayer phospholipids are relatively mobile in the absence of annexins, Ca(2+)-dependent binding of annexin B12 appears to form a complex in which the mobility of the D-E loop region of the protein and the headgroup region of the phospholipid are highly constrained. Possible biological consequences of annexin-induced restriction of membrane mobility are discussed.

The conserved core domains of annexins A1, A2, A5, and B12 can be divided into two groups with different Ca2+-dependent membrane-binding properties.

The hallmark of the annexin super family of proteins is Ca(2+)-dependent binding to phospholipid bilayers, a property that resides in the conserved core domain of these proteins. Despite the structural similarity between the core domains, studies reported herein showed that annexins A1, A2, A5, and B12 could be divided into two groups with distinctively different Ca(2+)-dependent membrane-binding properties. The division correlates with the ability of the annexins to form Ca(2+)-dependent membrane-bound trimers. Site-directed spin-labeling and Forster resonance energy transfer experimental approaches confirmed the well-known ability of annexins A5 and B12 to form trimers, but neither method detected self-association of annexin A1 or A2 on bilayers. Studies of chimeras in which the N-terminal and core domains of annexins A2 and A5 were swapped showed that trimer formation was mediated by the core domain. The trimer-forming annexin A5 and B12 group had the following Ca(2+)-dependent membrane-binding properties: (1) high Ca(2+) stoichiometry for membrane binding ( approximately 12 mol of Ca(2+)/mol of protein); (2) binding to membranes was very exothermic (> -60 kcal/ mol of protein); and (3) binding to bilayers that were in the liquid-crystal phase but not to bilayers in the gel phase. In contrast, the nontrimer-forming annexin A1 and A2 group had the following Ca(2+)-dependent membrane-binding properties: (1) lower Ca(2+) stoichiometry for membrane binding (