Substrate specificity of gamma-secretase and other intramembrane proteases.

Gamma-Secretase is a promiscuous protease that cleaves bitopic membrane proteins within the lipid bilayer. Elucidating both the mechanistic basis of gamma-secretase proteolysis and the precise factors regulating substrate identification is important because modulation of this biochemical degradative process can have important consequences in a physiological and pathophysiological context. Here, we briefly review such information for all major classes of intramembranously cleaving proteases (I-CLiPs), with an emphasis on gamma-secretase, an I-CLiP closely linked to the etiology of Alzheimer's disease. A large body of emerging data allows us to survey the substrates of gamma-secretase to ascertain the conformational features that predispose a peptide to cleavage by this enigmatic protease. Because substrate specificity in vivo is closely linked to the relative subcellular compartmentalization of gamma-secretase and its substrates, we also survey the voluminous body of literature concerning the traffic of gamma-secretase and its most prominent substrate, the amyloid precursor protein.

Mutations of peripheral myelin protein 22 result in defective trafficking through mechanisms which may be common to diseases involving tetraspan membrane proteins.

Phenotypes of several heritable disorders including forms of hearing loss, myelin diseases, hypomagnesemia, and cataracts are linked to missense mutations in single alleles encoding membrane proteins having four transmembrane spans. In some cases, the mutant proteins exhibit dominant negative or gain-of-function behavior whereby heterozygous coexpression of mutant and wild-type genes leads to more serious pathology than is the case for individuals in which only a single wild-type allele is expressed. An example is found in the relationship of peripheral myelin protein 22 (PMP22) to Charcot-Marie-Tooth disease (CMTD) type 1A. A number of disease-linked PMP22 mutants fail to undergo normal trafficking beyond the endoplasmic reticulum or intermediate compartment to reach the cell surface. Moreover, recent evidence suggests that pathology resulting from this mistrafficking-based loss of function may also be augmented by the ability of some mutants to disrupt normal trafficking of the product of the wild-type PMP22 allele. The basis for this phenomenon appears to be the heterodimerization of trafficking-incompetent mutants with wild-type PMP22, such that both the wild-type protein and the mutant forms are retained early in the secretory pathway. The full cellular and structural biological details of these observations remain to be elucidated. However, the model suggested by the existing data regarding the relationship of PMP22 to CMTD may be useful to explain phenotypes of several other diseases involving other tetraspan membrane proteins and to facilitate predictions regarding previously undetected disease-protein linkages.

Kinetic study of folding and misfolding of diacylglycerol kinase in model membranes.

Despite the relevance of membrane protein misfolding to a number of common diseases, our understanding of the folding and misfolding of membrane proteins lags well behind soluble proteins. Here, the overall kinetics of membrane insertion and folding of the homotrimeric integral membrane protein diacylglycerol kinase (DAGK) is addressed. DAGK was purified into lipid/detergent-free urea and guanidinium solutions and subjected to general structural characterization. In urea, the enzyme was observed to be monomeric but maintained considerable tertiary structure. In guanidinium, it was also monomeric but exhibited much less tertiary structure. Aliquots of these DAGK stock solutions were diluted 200-fold into lipid vesicles or into detergent/lipid mixed micelles, and the rates and efficiencies of folding/insertion were monitored. Reactions were also carried out in which micellar DAGK solutions were diluted into vesicular solutions. Productive insertion of DAGK from denaturant solutions into mixed micelles occurred much more rapidly than into lipid vesicles, suggesting that bilayer transversal represents the rate-limiting step for DAGK assembly in vesicles. The efficiency of productive folding/insertion into vesicles was highest in reactions initiated with micellar DAGK stock solutions (where DAGK maintains a nativelike fold and oligomeric state) and lowest in reactions starting with guanidinium stocks (where DAGK is an unfolded monomer). Moreover, the final ratio of irreversibly misfolded DAGK to reversibly misfolded enzyme was highest following reactions initiated with guanidinium stock solutions and lowest when micellar stocks were used. Finally, it was also observed that very low concentrations of detergents were able to both enhance the bilayer insertion rate and suppress misfolding.

Use of amphipathic polymers to deliver a membrane protein to lipid bilayers.

Data are presented which suggest that a class of amphiphilic polymers known as 'amphipols' may serve as a vehicle for delivering complex integral membrane proteins into membranes. The integral membrane protein diacylglycerol kinase (DAGK) was maintained in soluble form by either of two different amphipols. Small aliquots of these solutions were added to pre-formed lipid vesicles and the appearance of DAGK catalytic activity was monitored as an indicator of the progress of productive protein insertion into the bilayers. For one of the two amphipols tested, DAGK was observed to productively transfer from its amphipol complex into vesicles with moderate efficiency. Results were not completely clear for the other amphipol.

Conformationally specific misfolding of an integral membrane protein.

Membrane protein misfolding is related to the etiology of many diseases, but is poorly understood, particularly from a structural standpoint. This study focuses upon misfolding of a mutant form of diacylglycerol kinase (s-DAGK), a 40 kDa homotrimeric protein having nine transmembrane segments. Preparations of s-DAGK sometimes contain a kinetically trapped misfolded population, as evidenced by lower-than-expected enzyme activity (with no accompanying change in substrate K(m)) and by the appearance of a second band in electrophoresis gels. Misfolding of s-DAGK may take place during cellular overexpression, but can also be reproduced using the purified enzyme. TROSY NMR spectra of s-DAGK as a 100 kDa complex with detergent micelles exhibit a single additional set of resonances from the misfolded form, indicating a single misfolded conformational state. The relative intensities of these extra resonances correlate with the percent reduction in enzyme activity below the maximum observed for fully folded s-DAGK. Misfolded s-DAGK exhibits a modest difference in its far-UV CD spectrum compared to the folded enzyme, consistent with a small degree of variance in secondary structural content between the two forms. However, differences in NMR chemical shift dispersion and temperature-dependent line widths exhibited by folded and misfolded s-DAGK support the notion that they represent very different structural states. Cross-linking experiments indicate that both the correctly folded enzyme and the kinetically trapped misfolded form are homotrimers. This work appears to represent the first documentation of conformationally specific misfolding of an integral membrane protein.

Customizing model membranes and samples for NMR spectroscopic studies of complex membrane proteins.

Both solution and solid state nuclear magnetic resonance (NMR) techniques for structural determination are advancing rapidly such that it is possible to contemplate bringing these techniques to bear upon integral membrane proteins having multiple transmembrane segments. This review outlines existing and emerging options for model membrane media for use in such studies and surveys the special considerations which must be taken into account when preparing larger membrane proteins for NMR spectroscopic studies.

Misfolding of membrane proteins in health and disease: the lady or the tiger?

Protein misfolding is increasingly recognized as a factor in many diseases, including cystic fibrosis, Parkinson's, Alzheimer's and atherosclerosis. Many proteins involved in misfolding-based pathologies are membrane-associated, such that the bilayer may play roles in normal and aberrant folding. It can be argued that the in vivo partitioning of eukaryotic membrane proteins between folding and misfolding pathways is under kinetic control. Moreover, the balance between these pathways can be surprisingly delicate.

Functionality of a membrane protein in bicelles.

Bicelles are bilayered discoidal lipid-detergent assemblies which are useful as model membranes. To date, there has been no direct demonstration of functional viability for an integral membrane protein reconstituted into bicelles. In this contribution, the catalytic activity of diacylglycerol kinase (DAGK) was measured following reconstitution into several different bicelle systems and compared to activities measured in traditional mixed micelles and vesicles. For the most optimal bicelle systems tested, DAGK activities approached those observed in mixed micelles or vesicles. For some other bicellar mixtures tested, activities were much lower, with steady-state kinetic data indicating reduced V(max) rather than perturbations in substrate K(m). Catalytically, DAGK showed a strong preference for bicelles containing 3-(cholamidopropyl)dimethylammonio-2-hydroxy-1-propanesulfonate (CHAPSO) as the detergentcomponent relative to short-chained phosphatidylcholine.DAGK also exhibited a preference for dimyristoylphosphatidylcholine or dipalmitoylphosphatidylcholine bicelles relative to those of dilauroylphosphatidylcholine.

Thiol modification of diacylglycerol kinase: dependence upon site membrane disposition and reagent hydrophobicity.

Reaction rates were determined between disulfide reagents of varying hydrophobicity and single-cysteine mutants of diacylglycerol kinase, an integral membrane protein. Polar reagents reacted most rapidly with surface-exposed sites. However, a very non-polar reagent also reacted more rapidly with exposed cysteines than with membrane sites. Moreover, this non-polar reagent usually reacted more slowly with membrane sites than did more polar reagents. These results are consistent with the notion that disulfide exchange reactions involving buried cysteines of diacylglycerol kinase are very slow in the membrane interior, such that the competing rates of reactions which occur when normally buried cysteine sites make motional excursions to hydrated regions of the interface can be significant.

Mapping the oligomeric interface of diacylglycerol kinase by engineered thiol cross-linking: homologous sites in the transmembrane domain.

This work represents the first stage of thiol-based cross-linking studies to map the oligomeric interface of the homotrimeric membrane protein diacylglycerol kinase (DAGK). A total of 53 single-cysteine mutants spanning DAGK's three transmembrane segments and the first part of a cytoplasmic domain were purified and subjected to catalytic oxidation in mixed micelles. Four mutants (A52C, I53C, A74C, and I75C) were observed to undergo intratrimer disulfide bond formation between homologous sites on adjacent subunits. To establish whether the homologous sites are proximal in the ground-state conformation of DAGK or whether the disulfide bonds formed as a result of motions that brought normally distal sites into transient proximity, additional cross-linking experiments were carried out in three different milieus of varying fluidity [mixed micelles, 1-palmitoyl-2-oleoyl-sn-glycero-3-phosphocholine (POPC) vesicles, and Escherichia coli membranes]. Cross-linking experiments included disulfide bond formation under three different catalytic conditions [Cu(II)-phenanthroline oxidation, I(2) oxidation, and thionitrobenzoate-based thiol exchange] and reactions with a set of bifunctional thiol-reactive chemical cross-linkers presenting two different reactive chemistries and several spacer lengths. On the basis of these studies, residues 53 and 75 are judged to be in stable proximity within the DAGK homotrimer, while position 52 appears to be more distal and forms disulfide bonds only as a result of protein motions. Results for position 74 were ambiguous. In lipid vesicles and mixed micelles DAGK appears to execute motions that are not present in native membranes, with mobility also being higher for DAGK in mixed micelles than in POPC vesicles.

NMR-Based amide hydrogen-deuterium exchange measurements for complex membrane proteins: development and critical evaluation.

A method for measuring site-specific amide hydrogen-deuterium exchange rates for membrane proteins in bilayers is reported and evaluated. This method represents an adaptation and extension of the approach of Dempsey and co-workers (Biophys. J. 70, 1777-1788 (1996)) and is based on reconstituting (15)N-labeled membrane proteins into phospholipid bilayers, followed by lyophilization and rehydration with D(2)O or H(2)O (control). Following incubation for a time t under hydrated conditions, samples are again lyophilized and then solubilized in an organic solvent system, where (1)H-(15)N HSQC spectra are recorded. Comparison of spectra from D(2)O-exposed samples to spectra from control samples yields the extent of the H-D exchange which occurred in the bilayers during time t. Measurements are site specific if specific (15)N labeling is used. The first part of this paper deals with the search for a suitable solvent system in which to solubilize complex membrane proteins in an amide "exchange-trapped" form for NMR quantitation of amide peak intensities. The second portion of the paper documents application of the overall procedure to measuring site-specific amide exchange rates in diacylglycerol kinase, a representative integral membrane protein. Both the potential usefulness and the significant limitations of the new method are documented.

Reconstitutive refolding of diacylglycerol kinase, an integral membrane protein.

While the formation of kinetically trapped misfolded structural states by membrane proteins is related to a number of diseases, relatively few studies of misfolded membrane proteins in their purified state have been carried out and few methods for refolding such proteins have been reported. In this paper, misfolding of the trimeric integral membrane protein diacylglycerol kinase (DAGK) is documented and a method for refolding the protein is presented; 65 single-cysteine mutants of DAGK were examined. A majority were found to have lower-than-expected activities when purified into micellar solutions, with additional losses in activity often being observed following membrane reconstitution. A variety of evidence indicates that the low activities observed for most of these mutants results from kinetically based misfolding of the protein, with misfolding often being manifested by the formation of aberrant oligomeric states. A method referred to as "reconstitutive refolding" for correcting misfolded DAGK is presented. This method is based upon reconstituting DAGK into multilamellar POPC vesicles by dialyzing the detergent dodecylphosphocholine out of mixed micellar mixtures. For 55 of the 65 mutants tested, there was a gain of DAGK activity during reconstitutive refolding. In 33 of these cases, the gain in activity was greater than 2-fold. The refolding results for cysteine replacement mutants at DAGK sites known to be highly conserved provide teleological insight into whether sites are conserved, because they are critical for catalysis, for maintenance of the proper folding pathway, or for some other reason.

On choosing a detergent for solution NMR studies of membrane proteins.

Translational diffusion coefficients and catalytic activities were measured for the integral membrane protein diacylglycerol kinase (DAGK) in a variety of types of detergent micelles. Despite the structural diversity of the detergents examined, the translational diffusion coefficients observed for DAGK spanned a fairly limited range of values: 2.7 to 4.7 (x10(-7) cm2/s). No general correlation was observed between the diffusion coefficients for the detergent-DAGK aggregates and the sizes of the corresponding protein-free micelles. These results indicate that the effective molecular weights of the DAGK-detergent aggregates were determined more by the structural properties of the protein than by the properties of the detergents. The catalytic activity of DAGK in detergents having medium-length alkyl chains such as dodecylphosphocholine or decylmaltoside was usually observed to be substantially higher than in short-chain detergents such as octylphosphocholine or octylglucoside. Taken together, the diffusion and activity results indicate that medium-chain detergents are generally preferred for use in NMR studies of complex membrane proteins because they are no worse than short-chained detergents in terms of increasing the effective molecular weight of the protein of interest while they are considerably better at maintaining native-like protein conformation. Among the 10 detergents examined, only sodium dodecylsulfate was observed to be unable to support DAGK activity under any conditions examined, suggest that this well-known protein denaturant should be used with care in studies of complex membrane proteins.

A membrane setting for the sorting motifs present in the adenovirus E3-13.7 protein which down-regulates the epidermal growth factor receptor.

The adenovirus E3-13.7 protein interferes with endosomal protein sorting to down-regulate the epidermal growth factor receptor and related tyrosine kinase receptors. The cytoplasmic C terminus of this protein contains three protein sorting motifs which are related to the function of E3-13.7. In this study, the structure of a 23-residue polypeptide corresponding to this domain was examined using solution NMR and CD spectroscopic methods. The peptide was observed to exist in a mostly random structural state in aqueous solution but underwent high affinity association with dodecylphosphocholine micelles, where it adopted an ordered structure. The affinity of this peptide for the micellar surface and the structure of the bound peptide were independent of pH variation, surface charge, or attachment of a myristoyl anchor to the N-terminal. Studies with phospholipid vesicles suggested that the micellar structural results can be extrapolated to a true lipid bilayer. On the micellar surface all three sorting motifs are closely associated with the water/apolar interface: 72-YLRH and 87-LL lie within interfacial amphipathic helices, while 76-HPQY is non-helical and dimples just above the surface. These results contribute to the development of an understanding of the basis for specificity in recognition of sorting motifs by components of the cellular protein trafficking machinery.

Escherichia coli diacylglycerol kinase is an evolutionarily optimized membrane enzyme and catalyzes direct phosphoryl transfer.

In this contribution the kinetic mechanism and substrate specificity of Escherichia coli diacylglycerol kinase were examined. Steady state kinetic studies were carried out under mixed micellar conditions using a novel continuous coupled assay system. The kinetic data were consistent with a random equilibrium mechanism, implying that diacylglycerol kinase catalyzes direct phosphoryl transfer from MgATP to diacylglycerol. This was supported by failure to detect an enzyme-phosphate covalent intermediate and by the observation that the bisubstrate analog adenosine 5'-tetraphosphoryl-3-O-(1,2-dihexanoyl)-sn-glycerol inhibits the enzyme (Ki << Km,DAG). While diacylglycerol kinase's kcat/Km is modest compared with the efficiency of many water-soluble enzymes, the enzyme nevertheless appears to be an evolutionarily optimized biocatalyst in the sense that its chemical reaction rate approaches the substrate diffusion-controlled limit. The in vivo rate-limiting step of DAGK's reaction appears to be, in part, the transbilayer diffusion of diacylglycerol from the outer leaflet to the inner leaflet of the cytoplasmic membrane where DAGK's active site is located. DAGK was observed to maintain a high nucleotide substrate specificity, with most of this specificity being expressed in the form of reductions in kcat for ATP analogs.

Escherichia coli diacylglycerol kinase: a case study in the application of solution NMR methods to an integral membrane protein.

Diacylglycerol kinase (DAGK) is a 13-kDa integral membrane protein that spans the lipid bilayer three times and which is active in some micellar systems. In this work DAGK was purified using metal ion chelate chromatography, and its structural properties in micelles and organic solvent mixtures studies were examined, primarily to address the question of whether the structure of DAGK can be determined using solution NMR methods. Cross-linking studies established that DAGK is homotrimeric in decyl maltoside (DM) micelles and mixed micelles. The aggregate detergent-protein molecular mass of DAGK in both octyl glucoside and DM micelles was determined to be in the range of 100-110 kDa-much larger than the sum of the molecular weights of the DAGK trimers and the protein-free micelles. In acidic organic solvent mixtures, DAGK-DM complexes were highly soluble and yielded relatively well-resolved NMR spectra. NMR and circular dichroism studies indicated that in these mixtures the enzyme adopts a kinetically trapped monomeric structure in which it irreversibly binds several detergent molecules and is primarily alpha-helical, but in which its tertiary structure is largely disordered. Although these results provide new information regarding the native oligomeric state of DAGK and the structural properties of complex membrane proteins in micelles and organic solvent mixtures, the results discourage the notion that the structure of DAGK can be readily determined at high resolution with solution NMR methods.

Escherichia coli diacylglycerol kinase is an alpha-helical polytopic membrane protein and can spontaneously insert into preformed lipid vesicles.

Escherichia coli diacylglycerol kinase (DAGK) is a 13.2 kDa enzyme which spans the cytoplasmic membrane three times. Functional DAGK was purified to homogeneity using a polyhistidine tag and Ni(II)-chelate chromatography. Transmission Fourier transform infrared spectroscopy (FT-IR) of DAGK in phosphatidylcholine multilayers led to the conclusion that > or = 90 of DAGK's native 121 residues are alpha-helical, consistent with a model in which DAGK consists of two amphipathic alpha-helices and three transmembrane helices. Polarized attenuated total reflection FT-IR studies of DAGK in oriented multilamellae yielded data consistent with a topological arrangement in which the three transmembrane helices are well-aligned with the bilayer normal while the two amphipathic helices are approximately parallel with the membrane plane. The ability of DAGK to spontaneously insert into preformed lipid vesicles was examined using a novel assay system involving DAGK-catalyzed phosphorylation of a fluorescently tagged diacylglycerol. When micellar DAGK is diluted into L alpha-phase vesicles spontaneous insertion of the enzyme is fairly efficient (ca. 30%). DAGK refolding and insertion from delipidated urea-solubilized DAGK into lipid vesicles is also modestly efficient (3.8 +/- 2.1%) above the gel to liquid crystalline phase transition temperature. The insertion studies indicate that the difference in energy barriers (delta delta G++) between pathways leading to catalytically productive folding and insertion of DAGK relative to unproductive pathways is < 4 kcal/mol. However, additional studies carried out with mutant forms of DAGK indicated that the differences between refolding/insertion pathways for DAGK in vivo and in vitro can be significant.

Structural basis for actomyosin chemomechanical transduction by non-nucleoside triphosphate analogues.

Methylation of 2-[(2,4-dinitrophenyl)amino]ethyl triphosphate (dNOTP) was found to abolish its ability to support actin sliding in the in vitro motility assay. A comparative study of the interaction of myosin subfragment 1 (S1) and actoS1 with methylated (MdNOTP) and non-methylated dNOTP was undertaken. Both analogues were shown to be substrates for S1 NTPase in the presence of K+/EDTA, Ca2+, or Mg2+, although their rates of hydrolysis in the presence of the divalent cations were significantly greater than that occurring for ATP. However, actin had only a marginal effect on the rate of hydrolysis of MdNOTP, in sharp contrast to its effect on the hydrolysis of dNOTP and ATP which were quite similar. Moreover, while dNODP is able to form stable ternary S1 complexes with orthovanadate (Vi) or berylium fluoride (BeFx), whose formation results in increased thermal stability of S1, the methylated diphosphate analogue was unable to do so. These differences can be related to methylation-induced changes in the conformation of dNOTP indicated by molecular-modeling approaches. These studies suggest that methylation prevents the specific interaction of the aryl ring of dNOTP with S1 in the adenine binding region necessary for the formation of the force-producing intermediate (M. D. P*) during the S1 Mg(2+)-NTPase cycle.

Reconstitution of membrane proteins into lipid-rich bilayered mixed micelles for NMR studies.

This paper describes a study undertaken to assess the possibility and practical consequences of reconstituting integral and peripheral membrane proteins into bilayered discoidal mixed micelles ("bicelles") composed of dimyristoylphosphatidylcholine and smaller amounts of either CHAPSO or short-chain phosphatidylcholine. The amphiphilic assemblies in these mixtures are uniquely suited for use in NMR structural studies because they can be magnetically oriented with experimentally-tunable system order. The first step of this study was to test about 15 membrane-associating polypeptides and proteins for their ability to interfere with magnetic orientation of the bicellar assemblies. A variety of results were obtained ranging from no perturbation to a complete disruption of orientation. Second, the suitability of bicelles as mimics of natural bilayers was tested by reconstituting diacylglycerol kinase, an integral membrane enzyme. The kinase was observed to be functional and completely stable for at least 24 h when incubated at 38 degrees C in bicelles. Third, the NMR spectra from a number of bicelle-reconstituted proteins were examined. In some cases, 13C NMR resonances from reconstituted proteins were extremely broad and asymmetric. In other cases, resonances from reconstituted proteins were moderately broad, but much less so than resonances from proteins reconstituted into multilayers oriented by mechanical methods. In the cases of two surface-associating proteins (cytochrome c and leucine enkephalin), oriented sample 13C NMR spectra of extremely high resolution were obtained. For these proteins it was also demonstrated that the experimentally variable order of the bicellar assemblies could be exploited to provide a means of screening for detergent-specific structural perturbations, for making spectral assignments, and for measuring chemical shift anisotropies and dipolar couplings. Taken as a whole, these results indicate that bicelles may be uniquely and effectively employed as model membranes to facilitate NMR structural studies of many, but not all, membrane proteins.