Towards crystallization of hydrophobic myelin glycoproteins: P0 and PASII/PMP22

The preparation of a pure and homogeneous protein sample at proper concentration is a prerequisite for success when attempting their crystallization for structural determination. The detergents suitable for solubilization particularly of membrane proteins are not always the best for crystallization. Myelin of the peripheral nervous system of vertebrates is the example of a membrane for which neutral or "gentle" detergents are not even strong enough to solubilize its proteins. In contrast, sodium- or lithium-dodecyl sulfate is very effective. We solubilized myelin membrane in 2%(w/v) sodium dodecyl sulfate, followed by chromatographic purification of the hydrophobic myelin glycoproteins P0 and PASII/PMP22, and finally, we have exchanged the sodium dodecyl sulfate bound to protein for other neutral detergents using ceramic hydroxyapatite column. Theoretically, we should easily exchange sodium dodecyl sulfate for any neutral detergent, but for some of them, the solubility of myelin glycoproteins is low. To monitor the potential variability in the secondary structure of glycoproteins, we have used circular dichroism. Sodium dodecyl sulfate seems to be the appropriate detergent for the purpose of purification of very hydrophobic glycoproteins, since it can be easily exchanged for another neutral detergent.     

Detergents for the stabilization and crystallization of membrane proteins

The use of detergents for the structural study of membrane proteins is discussed with an emphasis on practical issues relating to membrane solubilization, protein aggregation, detergent purity and detergent quantitation. Detergents are useful reagents as mimics of lipid bilayers because of their self-assembling properties, but as a result, they have complex properties in solution. It can be difficult to maintain a solubilized membrane protein in a native conformational state, and the non-specific aggregation of detergent-solubilized proteins is a common problem. Empirical "stability screens" can be helpful in choosing which detergents, and which detergent concentrations, may be optimal for a given system.     

Sequence hydropathy dominates membrane protein response to detergent solubilization

The ability to predict from amino acid sequence how membrane protein structures will respond to detergent solubilization would significantly facilitate experimental characterization of these molecules. Here we have investigated and compared the response to solubilization by the "mild" n-dodecyl-β-d-maltoside (DDM) and "harsh" sodium dodecyl sulfate (SDS) of wild-type and point mutant "hairpin" (helix-loop-helix) membrane proteins derived from the third and fourth TM segments of the human cystic fibrosis transmembrane conductance regulator (CFTR) and the intervening extracellular loop. Circular dichroism spectroscopy, size-exclusion chromatography, and pyrene fluorescence spectroscopy were used to evaluate the secondary structures, hairpin-detergent complex excluded volumes, and hairpin compactness of the detergent-solubilized sequences. Sequence hydrophobicity is found to be the dominant factor dictating membrane protein response to detergent solubilization by DDM and SDS, with hairpin secondary structure exquisitely sensitive to mutation when DDM is used for solubilization. DDM and SDS differ principally in their ability to promote approach of TM segment ends, although hairpin compactness remains sensitive to point mutations. Our overall findings suggest that protein-protein and protein-detergent interactions are determined concomitantly, with the net hydropathy of residues exposed to detergent dominating the observed properties of the solubilized protein.     

Membrane protein solubilization: recent advances and challenges in solubilization of serotonin1A receptors

Solubilization of integral membrane proteins is a process in which the proteins and lipids that are held together in native membranes are suitably dissociated in a buffered detergent solution. The controlled dissociation of the membrane results in formation of small protein and lipid clusters that remain dissolved in the aqueous solution. Effective solubilization and purification of membrane proteins, especially heterologously-expressed proteins in mammalian cells in culture, in functionally active forms represent important steps in understanding structure-function relationship of membrane proteins. In this review, critical factors determining functional solubilization of membrane proteins are highlighted with the solubilization of the serotonin 1A receptor taken as a specific example.     

Short-chain phospholipids as detergents

The physico-chemical properties of short-chain phosphatidylcholine are reviewed to the extent that its biological activity as a mild detergent can be rationalized. Long-chain diacylphosphatidylcholines are typical membrane phospholipids that form preferentially smectic lamellar phases (bilayers) when dispersed in water. In contrast, the preferred phase of the short-chain analogues dispersed in excess water is the micellar phase. The preferred conformation and the dynamics of short-chain phosphatidylcholines in the monomeric and micellar state present in H(2)O are discussed. The motionally averaged conformation of short-chain phosphatidylcholines is then compared to the single-crystal structures of membrane lipids. The main conclusion emerging is that in terms of preferred conformation and motional averaging short-chain phosphatidylcholines closely resemble their long-chain analogues. The dispersing power of short-chain phospholipids is emphasized in the second part of the review. Evidence is presented to show that this class of compounds is superior to most other detergents used in the solubilization of membrane proteins and the reconstitution of the solubilized proteins to artificial membrane systems (proteoliposomes). The prominent feature of the solubilization/reconstitution of integral membrane proteins by short-chain PC is the retention of the native protein structure and hence the protein function. Due to their special detergent-like properties, short-chain PC lend themselves very well not only to membrane solubilization but also to the purification of integral membrane proteins. The retention of the native protein structure in the solubilized state, i.e. in mixed micelles consisting of the integral membrane protein, intrinsic membrane lipids and short-chain PC, is rationalized. It is hypothesized that short-chain PC interacts primarily with the lipid bilayer of a membrane and very little if at all with the membrane proteins. In this way, the membrane protein remains associated with its preferred intrinsic membrane lipids and retains its native structure and its function.     

Structural characteristics and refolding of in vivo aggregated hyperthermophilic archaeon proteins

Several recombinant proteins in inclusion bodies expressed in Escherichia coli have been measured by Fourier transform infrared and solid-state nuclear magnetic resonance spectra to provide the secondary structural characteristics of the proteins from hyperthermophilic archaeon Pyrococcus horikoshii OT3 (hyperthermophilic proteins) in inclusion bodies. The beta-strand-rich single chain Fv fragment (scFv) and alpha-helix-rich interleukin (IL)-4 lost part of the native-like secondary structure in inclusion bodies, while the inclusion bodies composed of the hyperthermophilic proteins of which the native form is alpha-helix rich, are predominated by alpha-helix structure. Further, the secondary structure of the recombinant proteins solubilized from inclusion bodies by detergent or denaturant was observed by circular dichroism (CD) spectra. The solubilization induced the denaturation of the secondary structure for scFv and IL-4, whereas the solubilized hyperthermophilic proteins have retained the alpha-helix structure with the CD properties resembling those of their native forms. This indicates that the hyperthermophilic proteins form native-like secondary structure in inclusion bodies. Refolding of several hyperthermophilic proteins from in vivo aggregated form without complete denaturation could be accomplished by solubilization with lower concentration (e.g. 2 M) of guanidine hydrochloride and removal of the denaturant via stepwise dialysis. This supports the existence of proteins with native-like structure in inclusion bodies and suggests that non-native association between the secondary structure elements leads to in vivo aggregation. We propose a refolding procedure on the basis of the structural properties of the aggregated archaeon proteins.     

An improved tripod amphiphile for membrane protein solubilization

Intrinsic membrane proteins represent a large fraction of the proteins produced by living organisms and perform many crucial functions. Structural and functional characterization of membrane proteins generally requires that they be extracted from the native lipid bilayer and solubilized with a small synthetic amphiphile, for example, a detergent. We describe the development of a small molecule with a distinctive amphiphilic architecture, a "tripod amphiphile," that solubilizes both bacteriorhodopsin (BR) and bovine rhodopsin (Rho). The polar portion of this amphiphile contains an amide and an amine-oxide; small variations in this polar segment are found to have profound effects on protein solubilization properties. The optimal tripod amphiphile extracts both BR and Rho from the native membrane environments and maintains each protein in a monomeric native-like form for several weeks after delipidation. Tripod amphiphiles are designed to display greater conformational rigidity than conventional detergents, with the long-range goal of promoting membrane protein crystallization. The results reported here represent an important step toward that ultimate goal.     

Enhanced solubilization of membrane proteins by alkylamines and polyamines

Around 25% of proteins in living organisms are membrane proteins that perform many critical functions such as synthesis of biomolecules and signal transduction. Membrane proteins are extracted from the lipid bilayer and solubilized with a detergent for biochemical characterization; however, their solubilization is an empirical technique and sometimes insufficient quantities of proteins are solubilized in aqueous buffer to allow characterization. We found that addition of alkylamines and polyamines to solubilization buffer containing a detergent enhanced solubilization of membrane proteins from microsomes. The solubilization of polygalacturonic acid synthase localized at the plant Golgi membrane was enhanced by up to 9.9‐fold upon addition of spermidine to the solubilization buffer. These additives also enhanced the solubilization of other plant membrane proteins localized in other organelles such as the endoplasmic reticulum and plasma membrane as well as that of an animal Golgi‐localized membrane protein. Thus, addition of alkylamines and polyamines to solubilization buffer is a generally applicable method for effective solubilization of membrane proteins. The mechanism of the enhancement of solubilization is discussed.     

Isolation of an integral membrane glycoprotein by chloroform-methanol extraction and C3-reversed-phase high-performance liquid chromatography

Methodology is presented for the isolation of integral membrane proteins and applied to the purification of the major myelin glycoprotein, P0. This isolation scheme depends on the detergent solubilization of an isoosmotically extracted membrane fraction from sciatic nerve endoneurium, followed by the removal of lipids and detergent by chloroform/methanol extraction. The resulting membrane proteins are readily dissolved in acetic acid/water (1/1) and directly analyzed by reversed-phase high-performance liquid chromatography. The hydrophobic nature of the intrinsic membrane protein mixture results in strong binding to a C8 stationary phase, leading to poor resolution and yields. These problems can be eliminated by employing a C3 alkylsilane column, thereby allowing separation of the protein components and the isolation of P0. The purified P0 has an amino-terminal sequence that matches that predicted from nucleotide sequencing, and the glycoprotein contains the expected amount of sialic acid. This latter finding indicates that the isolation procedure is not detrimental to the complex-type oligosaccharide structure of P0 and should make the methodology readily applicable to the purification of other integral membrane proteins and glycoproteins.     

Membrane proteins, lipids and detergents: not just a soap opera

Studying membrane proteins represents a major challenge in protein biochemistry, with one of the major difficulties being the problems encountered when working outside the natural lipid environment. In vitro studies such as crystallization are reliant on the successful solubilization or reconstitution of membrane proteins, which generally involves the careful selection of solubilizing detergents and mixed lipid/detergent systems. This review will concentrate on the methods currently available for efficient reconstitution and solubilization of membrane proteins through the use of detergent micelles, mixed lipid/detergent micelles and bicelles or liposomes. We focus on the relevant molecular properties of the detergents and lipids that aid understanding of these processes. A significant barrier to membrane protein research is retaining the stability and function of the protein during solubilization, reconstitution and crystallization. We highlight some of the lessons learnt from studies of membrane protein folding in vitro and give an overview of the role that lipids can play in stabilizing the proteins.     

去污剂的性质及其在膜蛋白结构生物学中的应用

膜蛋白在诸多生物过程,如呼吸作用、光合作用、信号识别和分子转运等方面发挥着重要作用,近年来,去污剂的快速发展,在一定程度上极大地推动了膜蛋白研究的进展。去污剂广泛应用于膜蛋白的提取、增溶、纯化、理化性质及结构研究,然而如何选择合适的去污剂往往是一项复杂的任务。本文从以下两个方面入手系统地描述了去污剂的重要理化性质及其在膜蛋白结构功能研究中的应用,（1）去污剂结构及其对去污剂性质和水溶性的影响,去污剂形成胶束的条件及影响去污剂胶束形成的其他因素。希望这些关于去污剂的基本性质和参数的介绍,可以为相关科研工作者选用去污剂提供一个理论依据。（2）去污剂抽提膜蛋白的流程和注意细节,去污剂对膜蛋白纯化时分子量测定的影响,膜蛋白研究中去污剂的置换与去除,膜蛋白结构、功能研究案例归纳。希望这些应用细节、课题研究,可以为相关科研工作者研究膜蛋白结构功能时提供一个经验借鉴。     

去污剂的性质及其在膜蛋白结构生物学中的应用

膜蛋白在诸多生物过程,如呼吸作用、光合作用、信号识别和分子转运等方面发挥着重要作用,近年来,去污剂的快速发展,在一定程度上极大地推动了膜蛋白研究的进展。去污剂广泛应用于膜蛋白的提取、增溶、纯化、理化性质及结构研究,然而如何选择合适的去污剂往往是一项复杂的任务。本文从以下两个方面入手系统地描述了去污剂的重要理化性质及其在膜蛋白结构功能研究中的应用,（1）去污剂结构及其对去污剂性质和水溶性的影响,去污剂形成胶束的条件及影响去污剂胶束形成的其他因素。希望这些关于去污剂的基本性质和参数的介绍,可以为相关科研工作者选用去污剂提供一个理论依据。（2）去污剂抽提膜蛋白的流程和注意细节,去污剂对膜蛋白纯化时分子量测定的影响,膜蛋白研究中去污剂的置换与去除,膜蛋白结构、功能研究案例归纳。希望这些应用细节、课题研究,可以为相关科研工作者研究膜蛋白结构功能时提供一个经验借鉴。     

Myelin glycosphingolipid/cholesterol-enriched microdomains selectively sequester the non-compact myelin proteins CNP and MOG

Plasma membranes are complex arrays of protein and lipid subdomains. Detergent-insoluble, glycosphingolipid/cholesterol-enriched micro-domains (DIGCEMs) have been implicated in protein sorting and/or as sites for signaling cascades in the plasma membrane. We previously identified the presence of DIGCEMs in oligodendrocytes in culture and purified myelin and characterized a novel DIGCEM-associated tetraspan protein, MVP17/rMAL (Kim et al. (1995) Journal of Neuroscience Research 42, 413–422). We have now analyzed the association of known myelin proteins with DIGCEMs in order to provide a better understanding of their roles during myelin biogenesis. We used four well-established criteria to identify myelin DIGCEM-associated proteins: insolubility in a non-ionic detergent Triton X-100 at low temperature (4°C), flotation of the insoluble complexes to low density fractions in sucrose gradients, and TX-100 solubilization at 37°C, or at 4°C following treatment with the cholesterol-binding detergent saponin. We demonstrate that these proteins fall into four distinct groups. Although all tested proteins could be floated to a low-density fraction, proteolipid protein (PLP), myelin basic protein (MBP) and myelin associated glycoprotein (MAG) were solubilized by the detergent extraction, and connexin32 (Cx32) and oligodendrocyte-specific protein (OSP) met only some of the criteria for DIGCEMs. Only the non-compact myelin proteins 2′,3′-cyclic nucleotide 3′-phosphodiesterase (CNP) and myelin/oligodendrocyte glycoprotein (MOG) satisfied all four criteria for DIGCEM-associated proteins. Significantly, only ～40% of CNP and MOG were selectively associated with DIGCEMs. This suggests that they may have both non-active “soluble”, and functionally active DIGCEM-associated, forms in the membrane, consistent with current views that DIGCEMs provide platforms for bringing together and activating components of the signal transduction apparatus. We therefore propose that CNP and MOG may have unique roles among the major myelin proteins in signaling pathways mediated by lipid-protein microdomains formed in myelin.     

The mechanism of detergent solubilization of liposomes and protein-containing membranes.

The present study explores intermediate stages in detergent solubilization of liposomes and Ca2+-ATPase membranes by sodium dodecyl sulfate (SDS) and medium-sized ( approximately C12) nonionic detergents. In all cases detergent partitioning in the membranes precedes cooperative binding and solubilization, which is facilitated by exposure to detergent micelles. Nonionic detergents predominantly interact with the lipid component of Ca2+-ATPase membranes below the CMC (critical micellar concentration), whereas SDS extracts Ca2+-ATPase before solubilization of lipid. At the transition to cooperative binding, n-dodecyl octaethylene glycol monoether (C12E8), Triton X-100, and dodecyldimethylamine oxide induce fusion of small unilamellar liposomes to larger vesicles before solubilization. Solubilization of Ca2+-ATPase membranes is accompanied by membrane fragmentation and aggregation rather than vesicle fusion. Detergents with strongly hydrophilic heads (SDS and beta-D-dodecylmaltoside) only very slowly solubilize liposomal membranes and do not cause liposome fusion. These properties are correlated with a slow bilayer flip-flop. Our data suggest that detergent solubilization proceeds by a combination of 1) a transbilayer attack, following flip-flop of detergent molecules across the lipid bilayer, and 2) extraction of membrane components directly by detergent micelles. The present study should help in the design of efficient solubilization protocols, accomplishing the often delicate balance between preserving functional properties of detergent sensitive membrane proteins and minimizing secondary aggregation and lipid content.     

Spectrophotometric method for quantitative determination of nonionic, ionic and zwitterionic detergents

Detergents serve as means of solubilizing biological membranes and thus play an important role in purification and characterization of membrane proteins. We report here a simple method to estimate the amount of detergent bound to a protein or present in an aqueous solution. The method is based on the turbidity caused by the addition of a detergent to triolein. Detergent bound to an integral membrane protein, lysophosphatidic acid acyltransferase, was separated by native gel electrophoresis and the amount of detergent bound to the same was estimated. This method is applicable for Triton X-100, sodium dodecyl sulfate and zwitterionic detergent, and was validated in the presence of reagents commonly used in membrane protein solubilization and purification.     

A comparative spectroscopic and kinetic study of photoexcitations in detergent-isolated and membrane-embedded LH2 light-harvesting complexes

Integral membrane proteins constitute more than third of the total number of proteins present in organisms. Solubilization with mild detergents is a common technique to study the structure, dynamics, and catalytic activity of these proteins in purified form. However beneficial the use of detergents may be for protein extraction, the membrane proteins are often denatured by detergent solubilization as a result of native lipid membrane interactions having been modified. Versatile investigations of the properties of membrane-embedded and detergent-isolated proteins are, therefore, required to evaluate the consequences of the solubilization procedure. Herein, the spectroscopic and kinetic fingerprints have been established that distinguish excitons in individual detergent-solubilized LH2 light-harvesting pigment-protein complexes from them in the membrane-embedded complexes of purple photosynthetic bacteria Rhodobacter sphaeroides. A wide arsenal of spectroscopic techniques in visible optical range that include conventional broadband absorption-fluorescence, fluorescence anisotropy excitation, spectrally selective hole burning and fluorescence line-narrowing, and transient absorption-fluorescence have been applied over broad temperature range between physiological and liquid He temperatures. Significant changes in energetics and dynamics of the antenna excitons upon self-assembly of the proteins into intracytoplasmic membranes are observed, analyzed, and discussed. This article is part of a Special Issue entitled: Photosynthesis Research for Sustainability: from Natural to Artificial.     

Variation of the Detergent-Binding Capacity and Phospholipid Content of Membrane Proteins When Purified in Different Detergents

Purified membrane proteins are ternary complexes consisting of protein, lipid, and detergent. Information about the amounts of detergent and endogenous phospholipid molecules bound to purified membrane proteins is largely lacking. In this systematic study, three model membrane proteins of different oligomeric states were purified in nine different detergents at commonly used concentrations and characterized biochemically and biophysically. Detergent-binding capacities and phospholipid contents of the model proteins were determined and compared. The insights on ternary complexes obtained from the experimental results, when put into a general context, are summarized as follows. 1), The amount of detergent and 2) the amount of endogenous phospholipids bound to purified membrane proteins are dependent on the size of the hydrophobic lipid-accessible protein surface areas and the physicochemical properties of the detergents used. 3), The size of the detergent and lipid belt surrounding the hydrophobic lipid-accessible surface of purified membrane proteins can be tuned by the appropriate choice of detergent. 4), The detergents n-nonyl-β-D-glucopyranoside and Cymal-5 have exceptional delipidating effects on ternary complexes. 5), The types of endogenous phospholipids bound to membrane proteins can vary depending on the detergent used for solubilization and purification. 6), Furthermore, we demonstrate that size-exclusion chromatography can be a suitable method for estimating the molecular mass of ternary complexes. The findings presented suggest a strategy to control and tune the numbers of detergent and endogenous phospholipid molecules bound to membrane proteins. These two parameters are potentially important for the successul crystallization of membrane proteins for structure determination by crystallographic approaches.     

Solubilization of isolated central-nervous-system myelin preparations by the amniotic detergent sodium dodecyl sulphate.

The mechanism for the solubilization of isolated central-nervous-system myelin by sodium dodecyl sulphate was studied in detail. The release of protein and phospholipid to the 100000 g x 1 h supernatant fraction is dependent on the total amount of detergent relative to the amount of membrane present and on the ionic strength of the solubilization system. Gel-filtration analysis of supernatant fractions indicate that at suboptimal concentrations of detergent these contain lipid-protein complexes. The complete dissociation of the individual protein components from lipid is dependent on the total amount of sodium dodecyl sulphate present in the system. The results indicate that for the analysis of membrane components in sodium dodecyl sulphate it is essential that sufficient detergent is present.     

Maltose-neopentyl glycol (MNG) amphiphiles for solubilization, stabilization and crystallization of membrane proteins

The understanding of integral membrane protein (IMP) structure and function is hampered by the difficulty of handling these proteins. Aqueous solubilization, necessary for many types of biophysical analysis, generally requires a detergent to shield the large lipophilic surfaces of native IMPs. Many proteins remain difficult to study owing to a lack of suitable detergents. We introduce a class of amphiphiles, each built around a central quaternary carbon atom derived from neopentyl glycol, with hydrophilic groups derived from maltose. Representatives of this maltose-neopentyl glycol (MNG) amphiphile family show favorable behavior relative to conventional detergents, as manifested in multiple membrane protein systems, leading to enhanced structural stability and successful crystallization. MNG amphiphiles are promising tools for membrane protein science because of the ease with which they may be prepared and the facility with which their structures may be varied.     

Production and biophysical characterization of the CorA transporter from Methanosarcina mazei

We report here a general strategy to overproduce and characterize membrane transporters. To illustrate our approach, we selected one member of the CorA transporter family among four tested that belonged to different species. This approach is transposable to other membrane proteins and involves the following steps: (i) cloning by homologous recombination, (ii) high-throughput expression screening, (iii) fermenter-based large-scale production, (iv) high-throughput detergent solubilization screening, (v) protein purification, (vi) multiangle static light scattering/refractometry characterization of purified proteins, (vii) circular dichroism spectroscopy, and (viii) detergent concentration measurements by Fourier transform infrared (FT-IR) spectroscopy. Methanosarcina mazei CorA was expressed in milligram quantities and purified (> 95% pure). n-Dodecyl-β-d-maltopyranoside (DDM) retained the pentameric native structure of this transporter; thus, we selected it as working detergent. Furthermore, we measured the detergent concentration in our purified and concentrated protein sample by FT-IR to maintain it as low as possible. Our strategy can be adapted to many structural biology approaches as well as for study of single membrane proteins in a variety of conditions.