Two dimensional diffusion of small molecules on protein surfaces: an EPR study of the restricted translational diffusion of protein-bound spin labels

Heisenberg spin exchange rates and dipole-dipole spin lattice relaxation rates for deuterated ¹⁴N- and ¹⁵N-spin labels bound selectively to the histidine His15 and to the lysines Lys13, 96, 97 of the lysozyme molecule have been determined with the aid of electron spin resonance spectroscopy. The results can be interpreted in terms of a two dimensional translational diffusion of the nitroxide tips of the spin labels along the protein surface within restricted surface areas. The spin labels are regarded as models for long amino acid side chains and as probes for the dynamics of protein and water in the vicinity of the protein surface. The translational diffusion coefficient DP_II is reduced by a factor of between six and thirty compared to the value of D found for the spin labels in bulk water, its value for T = 295 K is given by (1.3±0.6)·10^–10m²s^–1 D (2.4±0.3) 10^–11 m²s^–1. Offprint requests to: H.-J. Steinhoff     

Using small molecules to target protein phosphatases

The site specific functionalization of phosphate groups with amino acid side chains of substrate proteins represents one of the most important regulatory mechanisms of biological systems. Phosphorylation and dephosphorylation are reversibly catalyzed by protein kinases and protein phosphatases, and the aberrant regulation of these enzymes is associated with the onset and progression of various disease states such as cancer, diabetes, neurodegenerative and autoimmune disorders, making these proteins attractive targets for drug discovery. Here we report on strategies currently explored for the identification and development of various inhibitors directed against clinically relevant phosphatases. While over the last years, inhibition of phosphorylation has evolved into a key strategy in targeted therapies, the development of clinically relevant phosphatase inhibitors still faces major bottlenecks and is often plagued by limited selectivity and unfavorable pharmacokinetics. The reader will gain a better understanding of the importance of the field and its current limitations.     

Measuring the translational diffusion coefficients of small DNA molecules by capillary electrophoresis

The apparent translational diffusion coefficients of four 20 base pair (bp) DNA oligonucleotides with different sequences have been measured by capillary electrophoresis, using the stopped migration method. The diffusion coefficients of the four oligomers were equal within experimental error, and averaged (120 +/- 10) x 10(-8) cm(2) s(-1) in 40 mM Tris-acetate-EDTA buffer at 25 degrees C. Since this value is nearly identical to the translational diffusion coefficient determined for a different 20-bp oligomer using other methods, the stopped migration method can accurately measure the diffusion coefficients of small DNA oligomers. The apparent diffusion coefficient of a 118-bp DNA restriction fragment was also measured by the stopped migration method. However, the observed value was approximately 25% larger than expected from other measurements, possibly because the diffusion coefficients of larger DNA molecules are somewhat dependent on the ionic strength of the solution.     

Identification and validation of protein targets of bioactive small molecules

Identification and validation of protein targets of bioactive small molecules is an important problem in chemical biology and drug discovery. Currently, no single method is satisfactory for this task. Here, we provide an overview of common methods for target identification and validation that historically were most successful. We have classified for the first time the existing methods into two distinct and complementary types, the 'top-down' and 'bottom-up' approaches. In a typical top-down approach, the cellular phenotype is used as a starting point and the molecular target is approached through systematic narrowing down of possibilities by taking advantage of the detailed existing knowledge of cellular pathways and processes. In contrast, the bottom-up approach entails the direct detection and identification of the molecular targets using affinity-based or genetic methods. A special emphasis is placed on target validation, including correlation analysis and genetic methods, as this area is often ignored despite its importance.     

Quenching of room temperature protein phosphorescence by added small molecules

A number of molecular agents that can efficiently quench the room temperature phosphorescence of tryptophan were identified, and their ability to quench the phosphorescence lifetime of tryptophan in nine proteins was examined. For all quenchers, the quenching efficiency generally follows the same sequence, namely, N-acetyltryptophanamide (NATA) greater than parvalbumin approximately lactoglobulin approximately ribonuclease T1 greater than liver alcohol dehydrogenase greater than aldolase greater than Pronase approximately edestin greater than azurin greater than alkaline phosphatase. Quenching rate constants for O2 and CO are relatively insensitive to protein differences, while H2S and CS2 are somewhat more sensitive. These small molecule agents appear to act by penetrating into the proteins. However, penetration to truly buried tryptophans is less favorable than previously suggested; in five proteins studied, quenching efficiency by O2 is 20-1000 times lower than for NATA, and up to 10(5) lower for H2S and CS2. Larger and more polar quenchers--including organic thiols, conjugated ketones and amides, and anionic species--were also studied. The efficiency of these quenchers does not correlate with quencher size or polarity, the quenching reaction has low energy of activation, and quenching rates are insensitive to solvent viscosity. These results indicate that the larger quenchers do not approach the buried tryptophans by penetrating into the proteins, even on the long phosphorescence time scale, and are also inconsistent with a mechanism in which quencher encounter with the tryptophan occurs in free solution, as in a protein-opening reaction. The results obtained suggest that the quenching process involves a long-range radiationless transfer.(ABSTRACT TRUNCATED AT 250 WORDS)     

Simulation for diffusion behaviour of molecules in nanopattern-supported lipid bilayers based on random walk theory

In both the scientific and the technological approach, molecular manipulation with microscopic obstacles is of great importance. Recently, the application of a self-spreading lipid bilayer has attracted growing interest for its ability to transport any molecule in any desired direction. In this paper, we propose a new model, which imitates a self-spreading lipid bilayer on a substrate with metallic nanobarriers, to simulate the diffusion behaviours of molecules within it based on the random walk (RW) theory. The barriers are designed as Jones Tsai's experiments. The barrier's length, width, spacing, gap and interaction energy with molecules are investigated in this paper. The mean square displacement and diffusion coefficients (D) were calculated based on our simulation results. The results show that our simulation is consistent with the experiments. Comparing with the experimental techniques, this simulation work has improved the time- and space-resolution. Furthermore, it can simulate in rather long time-scale. Our RW models are expected to provide theoretical foundation for single molecular observation of hop diffusion in a lipid bilayer with metallic nanogates.     

Intein-mediated, in vitro and in vivo protein modifications with small molecules

We review intein-mediated approaches for the site-specific modifications of proteins and highlight their applications in (1) the site-specific in vitro and in vivo biotinylation of proteins for protein arrays and (2) the site-specific in vivo labeling of proteins in living cells.     

Identification of small molecules that modify the protein folding activity of heat shock protein 70

Molecular chaperones, such as heat shock protein 70 (Hsp70) and its bacterial ortholog DnaK, play numerous important roles in protein folding. In vitro, this activity can be observed by incubating purified chaperones with denatured substrates and measuring the recovery of properly folded protein. In an effort to rapidly identify small molecules that modify this folding activity, we modified an existing method for use in 96-well plates. In this assay, denatured firefly luciferase was treated with a mixture of DnaK and prospective chemical modulators. The luminescence of refolded luciferase was used to follow the reaction progress, and counterscreens excluded compounds that target luciferase; thus, hits from these screens modify protein folding via their effects on the function of the chaperone machine. Using this platform, we screened a pilot chemical library and found five new inhibitors of DnaK and one compound that promoted folding. These chemical probes may be useful in studies aimed at understanding the many varied roles of chaperones in cellular protein folding. Moreover, this assay provides the opportunity to rapidly screen for additional compounds that might regulate the folding activity of Hsp70.     

Determining the conductance of the SecY protein translocation channel for small molecules

The channel formed by the SecY complex must maintain the membrane barrier for ions and other small molecules during the translocation of membrane or secretory proteins. We have tested the permeability of the channel by using planar bilayers containing reconstituted purified E. coli SecY complex. Wild-type SecY complex did not show any conductance for ions or water. Deletion of the "plug," a short helix normally located in the center of the SecY complex, or modification of a cysteine introduced into the plug resulted in transient channel openings; a similar effect was seen with a mutation in the pore ring, a constriction in the center of the channel. Permanent channel opening occurred when the plug was moved out of the way by disulfide-bridge formation. These data show that the resting channel on its own forms a barrier for small molecules, with both the pore ring and the plug required for the seal; channel opening requires movement of the plug.     

Diffusion nuclear magnetic resonance spectroscopy detects substoichiometric concentrations of small molecules in protein samples

Small molecules are difficult to detect in protein solutions, whether they originate from elution during affinity chromatography (e.g., imidazole, lactose), buffer exchange (Tris), stabilizers (e.g., β-mercaptoethanol, glycerol), or excess labeling reagents (fluorescent reagents). Mass spectrometry and high-pressure liquid chromatography (HPLC) often require substantial efforts in optimization and sample manipulation to provide sufficient sensitivity and reliability for their detection. One-dimensional (1D) ¹H nuclear magnetic resonance (NMR) could, in principle, detect residual amounts of small molecules in protein solutions down to equimolecular concentrations with the protein. However, at lower concentrations, the NMR signals of the contaminants can be hidden in the background spectrum of the protein. As an alternative, the 1D diffusion difference protocol used here is feasible. It even improves the detection level, picking up NMR signals from small-molecule contaminants at lower concentrations than the protein itself. We successfully observed 30 μM imidazole in the presence of four different proteins (1-1.5 mg/ml, 6-66 kDa, 25-250 μM) by 1D diffusion-ordered spectroscopy (DOSY) difference and 1-h total acquisition time. Of note, imidazole was not detected in the corresponding 1D ¹H NMR spectra. This protocol can be adapted to different sample preparation procedures and NMR acquisition methods with minimal manipulation in either deuterated or nondeuterated buffers.     

Protein fluorescence quenching by small molecules: protein penetration versus solvent exposure

Experiments were done to test the thesis that acrylamide and similar small molecules can penetrate into proteins on a nanosecond time scale. The approach taken was to measure the pattern of fluorescence quenching exhibited by quenching molecules differing in molecular character (size, polarity, charge) when these are directed against protein tryptophans that cover the whole range of tryptophan accessibility. If quenching involves protein penetration and internal quencher migration, one expects that larger quenchers and more polar quenchers should display lesser quenching. In fact, no significant dependence on quencher character was found. For proteins that display measurable quenching, the disparate quenchers studied display very similar quenching rate constants when directed against any particular protein tryptophan. For several proteins having tryptophans known to be buried, no quenching occurs. These results are not consistent with the view that the kinds of small molecules studied can quite generally penetrate into and diffuse about within proteins at near-diffusion-limited rates. Rather the results suggest that when quenching is observed, the pathway involves encounters with tryptophans that are partially exposed at the protein surface. Available crystallographic results support this conclusion.     

Partitioning and diffusion of large molecules in fibrous structures

This paper consists of three parts. In the first part we present diffusion and partition coefficients of proteins in agarose that were measured with gel permeation chromatography. In the second part we present a partition model which includes the effects of solute concentration and of cosolutes. In the third part we modify and extend Ogston’s diffusion equation to account for the effects of solute and fiber flexibility, solute concentration and cosolutes. We find good agreement between the proposed models and data from the literature.     

A directed approach for engineering conditional protein stability using biologically silent small molecules

The ability to regulate the function of specific proteins using cell-permeable molecules can be a powerful method for interrogating biological systems. To bring this type of "chemical genetic" control to a wide range of proteins, we recently developed an experimental system in which the stability of a small protein domain expressed in mammalian cells depends on the presence of a high affinity ligand. This ligand-dependent stability is conferred to any fused partner protein. The FK506- and rapamycin-binding protein (FKBP12) has been the subject of extensive biophysical analyses, including both kinetic and thermodynamic studies of the wild-type protein as well as dozens of mutants. The goal of this study was to determine if the thermodynamic stabilities (DeltaDeltaG(U-F)) of various amino acid substitutions within a given protein are predictive for engineering additional ligand-dependent destabilizing domains. We used FKBP12 as a model system and found that in vitro thermodynamic stability correlates weakly with intracellular degradation rates of the mutants and that the ability of a given mutation to destabilize the protein is context-dependent. We evaluated several new FKBP12 ligands for their ability to stabilize these mutants and found that a cell-permeable molecule called Shield-1 is the most effective stabilizing ligand. We then performed an unbiased microarray analysis of NIH3T3 cells treated with various concentrations of Shield-1. These studies show that Shield-1 does not elicit appreciable cellular responses.     

Understanding organellar protein folding capacities and assessing their pharmacological modulation by small molecules

Dysfunctional organellar protein quality control machinery leads to protein misfolding associated cardiovascular, neurodegenerative, metabolic and secretory disorders. To understand organellar homeostasis, suitable tools are required which can sense changes in their respective protein folding capacity upon exposure to environmental and pharmacological perturbations. Herein, we have assessed protein folding capacity of cellular organelles using a metastable sensor selectively targeted to cytosol, nucleus, mitochondria, endoplasmic reticulum, golgi and peroxisomes. Microscopy and biochemical data revealed that these sensors report both acute and organelle-specific cellular insults. It also provided insights into contrasting refolding capacities of cellular organelles to recover from proteotoxic challenges. Further, we used these metastable sensors to evaluate pharmacological modulation of organellar protein folding capacity by small molecules. We observed pyrazole based scaffolds increased organellar protein folding capacity through upregulation of chaperones, mainly HSP90 and its co-chaperone HOP which coordinate refolding of misfolded/aggregated species. Overall, our data highlights the potential use of organelle-specific metastable sensors to understand protein folding capacity of sub-cellular compartments and assess pharmacological correction of their proteostasis imbalance. This study also provides additional avenue for use of these organelle-specific metastable sensors in drug discovery programs for identification of novel pharmacophores and drug repositioning of promising scaffolds for protein conformational diseases associated with different cellular organelles.