Refolding SDS-denatured proteins by the addition of amphipathic cosolvents

Sodium dodecyl sulfate (SDS) is a highly effective and widely used protein denaturant. We show that certain amphipathic cosolvents such as 2-methyl-2,4-pentanediol (MPD) can protect proteins from SDS denaturation, and in several cases can refold proteins from the SDS-denatured state. This cosolvent effect is observed with integral membrane proteins and soluble proteins from either the α-helical or the β-sheet structural classes. The SDS/MPD system can be used to study processes involving native protein states, and we demonstrate the reversible thermal denaturation of the outer membrane protein PagP in an SDS/MPD buffer. MPD and related cosolvents can modulate the denaturing properties of SDS, and we describe a simple and effective method to recover refolded, active protein from the SDS-denatured state.     

A micromethod for the quantitation of cellular proteins in Percoll with the Coomassie brilliant blue dye-binding assay

A simple procedure for the determination of cellular proteins in Percoll-containing samples is described. Percoll precipitated when particulate proteins were solubilized by dilution of the samples in a NaOH-Triton X-100 mixture. After centrifugation at high speed (12,000g), the supernatant was assayed for proteins with the Coomassie brilliant blue dye-binding assay. With an automatic spectrophotometer, 50-microliter aliquots gave a linear response between 0 and 3 micrograms of bovine serum albumin. After a fivefold dilution in the alkali-detergent mixture, proteins in samples containing up to at least 60% Percoll can be accurately quantitated on a standard curve prepared in the absence of Percoll. Because the sensitivity of the assay was better than 100 ng, the procedure outlined in this paper can also be used as a general protein micromethod.     

Transfer of silver-stained proteins from polyacrylamide gels to polyvinylidene difluoride membranes.

We have developed a method to transfer proteins from a silver-stained polyacrylamide gel to a polyvinylidene difluoride (Immobilon-P) transfer membrane (Millipore, Bedford, MA). If the silver stained gels are rinsed in 2 x SDS Laemmli sample buffer prior to transfer, almost all proteins can be transferred comparably to non-stained controls. Some proteins stained with silver can be directly transfer, almost all proteins can be transferred comparably to non-stained controls. Some proteins stained with silver can be directly transferred to a single sheet of Immobilon-P without a prior rinse in sample buffer. Most important in the Western blot the antigenicity of the transferred protein is retained in either way. The method described is simple, inexpensive and versatile. A slight modification of the technique permits one to extract minor proteins, or detect their antigenic activities, without contamination of contiguous proteins.     

Semipreparative electrophoresis with prestained proteins.

A simple method for prestaining proteins with Coomassie blue G prior to acrylamidegel electrophoresis is described. Many, although not all, undenatured proteins can be stained. This prestaining technique can be conveniently coupled with a second electrophoresis step, using Sephadex as a supporting medium, to yield isolated protein in about 4 h.     

Sequence analysis reveals how G protein-coupled receptors transduce the signal to the G protein

Sequence entropy-variability plots based on alignments of very large numbers of sequences-can indicate the location in proteins of the main active site and modulator sites. In the previous article in this issue, we applied this observation to a series of well-studied proteins and concluded that it was possible to detect most of the residues with a known functional role. Here, we apply the method to rhodopsin-like G protein-coupled receptors. Our conclusion is that G protein binding is the main evolutionary constraint on these receptors, and that other ligands, such as agonists, act as modulators. The activation of the receptors can be described as a simple, two-step process, and the residues involved in signal transduction can be identified.     

Engineering of Escherichia coli to improve the purification of periplasmic Fab' fragments: changing the pI of the chromosomally encoded PhoS/PstS protein

Escherichia coli is a widely used host for the heterologous expression of proteins of therapeutic and commercial interest. The scale and speed at which it can be cultured can result in the rapid generation of large quantities of product. However, to achieve low costs of production a simple and robust purification process is also required. The general factors that impact on the cost of a purification process are the scale at which a process can be performed, the cost of the purification matrix, and the number and complexity of the chromatographic steps employed. Purification of Fab' fragments of antibodies from the periplasm of E. coli using ion exchange chromatography can result in the co-purification of E. coli host proteins having similar functional pI: such as the periplasmic phosphate binding protein, PhoS/PstS. In such circumstances, an additional chromatographic step is required to separate Fab' from PhoS. Here, we change the functional pI of the chromosomally encoded PhoS/PstS to effect its non-purification with Fab' fragments, enabling the removal of an entire chromatographic step. This exemplifies the strategy of the modification of host proteins with the aim of simplifying the production of heterologous proteins.     

Beyond the random coil: stochastic conformational switching in intrinsically disordered proteins

Intrinsically disordered proteins (IDPs) participate in critical cellular functions that exploit the flexibility and rapid conformational fluctuations of their native state. Limited information about the native state of IDPs can be gained by the averaging over many heterogeneous molecules that is unavoidable in ensemble approaches. We used single molecule fluorescence to characterize native state conformational dynamics in five synaptic proteins confirmed to be disordered by other techniques. For three of the proteins, SNAP-25, synaptobrevin and complexin, their conformational dynamics could be described with a simple semiflexible polymer model. Surprisingly, two proteins, neuroligin and the NMDAR-2B glutamate receptor, were observed to stochastically switch among distinct conformational states despite the fact that they appeared intrinsically disordered by other measures. The hop-like intramolecular diffusion found in these proteins is suggested to define a class of functionality previously unrecognized for IDPs.     

Topology, stability, sequence, and length: defining the determinants of two-state protein folding kinetics

The fastest simple, single domain proteins fold a million times more rapidly than the slowest. Ultimately this broad kinetic spectrum is determined by the amino acid sequences that define these proteins, suggesting that the mechanisms that underlie folding may be almost as complex as the sequences that encode them. Here, however, we summarize recent experimental results which suggest that (1) despite a vast diversity of structures and functions, there are fundamental similarities in the folding mechanisms of single domain proteins and (2) rather than being highly sensitive to the finest details of sequence, their folding kinetics are determined primarily by the large-scale, redundant features of sequence that determine a protein's gross structural properties. That folding kinetics can be predicted using simple, empirical, structure-based rules suggests that the fundamental physics underlying folding may be quite straightforward and that a general and quantitative theory of protein folding rates and mechanisms (as opposed to unfolding rates and thus protein stability) may be near on the horizon.     

Loop-closure events during protein folding: rationalizing the shape of Phi-value distributions

In the past years, the folding kinetics of many small single-domain proteins has been characterized by mutational Phi-value analysis. In this article, a simple, essentially parameter-free model is introduced which derives folding routes from native structures by minimizing the entropic loop-closure cost during folding. The model predicts characteristic folding sequences of structural elements such as helices and beta-strand pairings. Based on few simple rules, the kinetic impact of these structural elements is estimated from the routes and compared to average experimental Phi-values for the helices and strands of 15 small, well-characterized proteins. The comparison leads on average to a correlation coefficient of 0.62 for all proteins with polarized Phi-value distributions, and 0.74 if distributions with negative average Phi-values are excluded. The diffuse Phi-value distributions of the remaining proteins are reproduced correctly. The model shows that Phi-value distributions, averaged over secondary structural elements, can often be traced back to entropic loop-closure events, but also indicates energetic preferences in the case of a few proteins governed by parallel folding processes.     

On the calculation of electrostatic interactions in proteins

In this paper we present a classical treatment of electrostatic interactions in proteins. The protein is treated as a region of low dielectric constant with spherical charges embedded within it, surrounded by an aqueous solvent of high dielectric constant, which may contain a simple electrolyte. The complete analysis includes the effects of solvent screening, polarization forces, and self energies, which are related to solvation energies. Formulae, and sample calculations of forces and energies, are given for the special case of a spherical protein. Our analysis and model calculations point out that any consistent treatment of electrostatic interactions in proteins should account for the following. Solvent polarization is an important factor in the calculation of pairwise electrostatic interactions. Solvent polarization substantially affects both electrostatic energies and forces acting upon charges. No simple expression for the effective dielectric constant, Deff, can generally be valid, since Deff is a sensitive function of position. Solvent screening of pairwise interactions involving dipolar groups is less effective than the screening of charges. In fact for many interactions involving dipoles, solvent screening can be essentially ignored. The self energy of charges makes a large contribution to the total electrostatic energy of a protein. This must be compensated by specific interactions with other groups in the protein. Strategies for applying our analysis to proteins whose structures are known are discussed.     

The components of the Saccharomyces cerevisiae mannosyltransferase complex M-Pol I have distinct functions in mannan synthesis

The yeast Saccharomyces cerevisiae processes N-linked glycans in the Golgi apparatus in two different ways. Whereas most of the proteins of internal membranes receive a simple core-type structure, a long branched polymer termed mannan is attached to the glycans of many of the proteins destined for the cell wall. The first step in mannan synthesis is the initiation and extension of an alpha-1,6-linked polymannose backbone. This requires the sequential action of two enzyme complexes, mannan polymerases (M-Pol) I and II. M-Pol I contains the proteins Mnn9p and Van1p, although the stoichiometry and individual contributions to enzyme action are unclear. We report here that the two proteins are each present as a single copy in the complex. Both proteins contain a DXD motif found in the active site of many glycosyltransferases, and mutations in this motif in Mnn9p or Van1p reveal that both proteins contribute to mannose polymerization. However, the effects of these mutations on both the in vivo and in vitro activity are distinct, suggesting that the two proteins may have different roles in the complex. Finally, we show that a simple glycoprotein based on hen egg lysozyme can be used as a substrate for modification by purified M-Pol I in vitro.     

Isolation of specific RNA-binding proteins using the streptomycin-binding RNA aptamer

Here we report a simple and cheap one-step affinity purification protocol for isolating RNAs or proteins that interact with selected functional RNAs. The streptomycin-binding aptamer, termed 'StreptoTag,' is embedded in or fused to either end of any RNA of interest. The resulting hybrid RNA can then be immobilized on a streptomycin affinity matrix. When a complex protein mixture or total cellular lysate is applied to the matrix, subsequent elution with free streptomycin allows efficient recovery of specific ribonucleoprotein or RNA-RNA complexes. The method was successfully used to purify yeast and phage RNA-binding proteins and group II intron, viral and bacterial noncoding RNA (ncRNA)-binding proteins. The selective enrichment of bacterial mRNAs that bind ncRNAs has also been demonstrated. Once the affinity matrix, the RNA construct and the protein extracts have been prepared, the experimental procedure can be performed in 1-2 h.     

A fluorescamine-based sensitive method for the assay of proteinases, capable of detecting the initial cleavage steps of a protein.

The properties of the reaction of fluorescamine with proteins are the basis for the development of a sensitive, general and simple method for the assay of proteolytic activities. More importantly, the assay measures the initial step(s) of proteolytic attack, making it specially suitable for the examination of the controlling factors that regulate proteolytic degradation and/or the detection of 'specific' proteinases. The method allows the simple determination of the general parameters of enzyme action, V and Km, using proteins, i.e. the physiological substrates of the proteinases. The more appropriate proteins to be used as substrates are the N-amino-terminally blocked ones. Many proteins fulfill this requirement. If the particular protein whose degradation has to be studied lacks this modification, three different approaches can be used to study its degradation: (a) the accumulation of N-amino termini in excess over that of the intact substrate; (b) a gel filtration/continuous method and (c) the chemical blockage of its amino groups. The particular advantages of each of these approaches are discussed.     

The use of ninhydrin as a reagent for the reversible modification of arginine residues in proteins.

A simple technique was developed for the specific reversible modification of guanidino groups in proteins involving reaction with ninhydrin. The extent of the reaction is easily determined non-destructively by spectrophotometric analysis. The reagent can also be used for the titration of sterically unhindered thiol groups in proteins.     

Slow diffusion of proteins in the yeast plasma membrane allows polarity to be maintained by endocytic cycling

Many cells show a polarized distribution of some plasma membrane proteins, which may be maintained either by a diffusion barrier or kinetically: as first demonstrated in fibroblasts, locally exocytosed proteins will remain polarized if they are endocytosed and recycled before they can diffuse to equilibrium. In yeast, actin cables direct exocytosis to the bud and to the tips of polarized mating intermediates termed shmoos. A septin ring at the bud neck retains some proteins, but shmoos lack this. Here, we show that the exocytic SNARE Snc1 is kinetically polarized. It is concentrated at bud and shmoo tips, and this requires its endocytosis. Kinetic polarization is possible in these small cells because proteins diffuse much more slowly in the yeast plasma membrane than would be expected from measurements in animal cells. Slow diffusion requires neither the cell wall nor polymerized actin, but it is affected in the ergosterol synthesis mutant erg6. Other proteins also require endocytosis for efficient polarization, and the plasma membrane SNARE Sso1 can be polarized merely by appending an endocytic signal. Thus, despite their small size, yeast cells can use localized exocytosis and endocytic recycling as a simple mechanism to maintain polarity.     

Prediction of the absolute aggregation rates of amyloidogenic polypeptide chains

Protein aggregation is associated with a variety of pathological conditions, including Alzheimer's and Creutzfeldt-Jakob diseases and type II diabetes. Such degenerative disorders result from the conversion of the normal soluble state of specific proteins into aggregated states that can ultimately form the characteristic amyloid fibrils found in diseased tissue. Under appropriate conditions it appears that many, perhaps all, proteins can be converted in vitro into amyloid fibrils. The aggregation propensities of different polypeptide chains have, however, been observed to vary substantially. Here, we describe an approach that uses the knowledge of the amino acid sequence and of the experimental conditions to reproduce, with a correlation coefficient of 0.92 and over five orders of magnitude, the in vitro aggregation rates of a wide range of unstructured peptides and proteins. These results indicate that the formation of protein aggregates can be rationalised to a considerable extent in terms of simple physico-chemical parameters that describe the properties of polypeptide chains and their environment.     

Detecting cryptically simple protein sequences using the SIMPLE algorithm

MOTIVATION: Low-complexity or cryptically simple sequences are widespread in protein sequences but their evolution and function are poorly understood. To date methods for the detection of low complexity in proteins have been directed towards the filtering of such regions prior to sequence homology searches but not to the analysis of the regions per se. However, many of these regions are encoded by non-repetitive DNA sequences and may therefore result from selection acting on protein structure and/or function. RESULTS: We have developed a new tool, based on the SIMPLE algorithm, that facilitates the quantification of the amount of simple sequence in proteins and determines the type of short motifs that show clustering above a certain threshold. By modifying the sensitivity of the program simple sequence content can be studied at various levels, from highly organised tandem structures to complex combinations of repeats. We compare the relative amount of simplicity in different functional groups of yeast proteins and determine the level of clustering of the different amino acids in these proteins. AVAILABILITY: The program is available on request or online at http://www.biochem.ucl.ac.uk/bsm/SIMPLE.     

Simple sequences are rare in the Protein Data Bank

A simple sequence is abundant in the proteins that have been sequenced to date. But unusual protein features, such as a simple sequence, are not present in the same high frequency within structural databases. A subset of these simple sequences, a group with a highly repetitive nature has been shown to be abundant in eukaryotes but not in prokaryotes. In this study, an examination of the eukaryotic proteins in the Protein Data Bank (PDB) has revealed a large deficiency of low complexity, highly repetitive protein repeats. Through simulated databases of similar samples of eukaryotic proteins taken from the National Center for Biotechnology Information (NCBI) database, it is shown that the PDB contains a significantly less highly repetitive, simple sequence than artificial databases of similar composition randomly derived from NCBI. When the structural data for those few PDB sequences that did contain a highly repetitive simple sequence is examined in detail, it is found that in most cases the tertiary structure is unknown for the regions consisting of a simple sequence. This lack of a simple sequence both in the PDB database and in the structural information suggests that this type of simple sequence may produce disordered structures that make structural characterization difficult.     

Hacking the Code of Amyloid Formation

Many research efforts in the last years have been directed towards understanding the factors determining protein misfolding and amyloid formation. Protein stability and amino acid composition have been identified as the two major factors in vitro. The research of our group has been focused on understanding the relationship between amino acid sequence and amyloid formation. Our approach has been the design of simple model systems that reproduce the biophysical properties of natural amyloids. An amyloid sequence pattern was extracted that can be used to detect amyloidogenic hexapeptide stretches in proteins. We have added evidence supporting that these amyloidogenic stretches can trigger amyloid formation by non-amyloidogenic proteins. Some experimental results in other amyloid proteins will be analyzed under the conclusions obtained in these studies. Our studies together with evidences from other groups suggest that amyloid formation is the result of the interplay between a decrease of protein stability, and the presence of highly amyloidogenic regions in proteins. As many of these results have been obtained in vitro, the challenge for the next years will be to demonstrate their validity in in vivo systems.