A critical evaluation of the hydropathy profile of membrane proteins

New membrane-preference scales are introduced for categories of membrane proteins with different functions. A statistical analysis is carried out with several scales to verify the relative accuracy in the prediction of the transmembrane segments of polytopic membrane proteins. The correlation between some of the scales most used and those calculated here provides criteria for selecting the most appropriate methods for a given type of protein. The parameters used in the evaluation of the hydropathy profiles have been carefully ascertained in order to develop a reliable methodology for hydropathy analysis. Finally, an integrated hydropathy analysis using different methods has been applied to several sequences of related proteins. The above analysis indicates that (a) microsomal cytochrome P450 contains only one hydrophobic region at the N-terminus that is consistently predicted to transverse the membrane: (b) only four of the six or seven putative transmembrane helices of cytochrome oxidase subunit III are predicted and correspond to helices I, III, V and VI of the previous nomenclature; (c) the product of the mitochondrial ATPase-6 gene (or the chloroplast ATPase-IV gene) of F0-F1-ATPase shows that helix IV is not consistently predicted to traverse the membrane, suggesting a four-helix model for this family of proteins.     

A simple method for predicting transmembrane alpha helices with better accuracy.

The prediction of a protein's structure from its amino acid sequence has been a long-standing goal of molecular biology. In this work, a new set of conformational parameters for membrane spanning alpha helices was developed using the information from the topology of 70 membrane proteins. Based on these conformational parameters, a simple algorithm has been formulated to predict the transmembrane alpha helices in membrane proteins. A FORTRAN program has been developed which takes the amino acid sequence as input and gives the predicted transmembrane alpha-helices as output. The present method correctly identifies 295 transmembrane helical segments in 70 membrane proteins with only two overpredictions. Furthermore, this method predicts all 45 transmembrane helices in the photosynthetic reaction center, bacteriorhodopsin and cytochrome c oxidase to an 86% level of accuracy and so is better than all other methods published to date.     

Prediction and comparison of the haem-binding sites in membrane haemoproteins

This article contains a comparative review of the structural properties of membrane haemoproteins, with particular emphasis on the possible similarities of the haem-binding peptides. A procedure is suggested for identifying the peptides which may bind membrane-buried haems on the basis of the primary sequences of the proteins. The integration of this procedure with the information deduced by refined hydropathy analysis indicates that the basic structural model for the haemoproteins which interact with quinones may be a transmembrane helical bundle containing the haem(s) at its centre. Structural similarities exist in the sequence of hydrophobic segments that are predicted to bind the membrane-buried haems of b-cytochromes which interact with quinones. The predicted haem-binding sites show similarities also with the peptides that bind the non-haem iron in the bacterial reaction centres, and this may be correlated to the common function of interacting with quinones and their intermediates. The analysis of the amino-acid composition of the proposed ligand peptides in the membrane haemoproteins examined has provided a molecular rationale for explaining the highly anisotropic low-spin EPR signal which is characteristic of many membrane-bound b-cytochromes.     

Calculation of the three-dimensional structure of Saccharomyces cerevisiae cytochrome b inserted in a lipid matrix

Cytochrome b is an integral membrane protein, which forms the core of the ubiquinol-cytochrome c oxidoreductase (cytochrome bc1) complex. A computer-aided three-dimensional modeling procedure was carried out in four steps. First, the candidate hydrophobic helices were searched for throughout the protein primary sequence by a computer procedure based upon the method of Eisenberg; second, a secondary helical structure was imposed to the transmembrane peptides; third, the helical segments at a lipid-water interface were oriented, and finally the possible interactions between helices with similar properties were investigated. This procedure enabled the identification of nine hydrophobic segments, of which eight are membrane-spanning helices while one has amphipathic properties. Three hydrophilic receptor-binding domains were also identified. Based upon their hydrophobicity profiles, the transmembrane helices could be associated in pairs inside the lipid bilayer. In our folding model proposed for cytochrome b, all mutation sites are not only located on the same side of the membrane but are also in close proximity in the three-dimensional structure. Inhibitor resistance mutational sites which were recently characterized (di Rago, J.-P., and Colson, A.-M. (1988) J. Biol. Chem. 263, 12564-12570) have been located on this model. Moreover, the receptor-binding domains and the mutation sites are close neighbors in the three-dimensional spatial representation.     

Membrane topology of the beta-subunit of the oxaloacetate decarboxylase Na+ pump from Klebsiella pneumoniae.

The topology of the beta-subunit of the oxaloacetate Na+ pump (OadB) was probed with the alkaline phosphatase (PhoA) and beta-galactosidase (lacZ) fusion technique. Additional evidence for the topology was derived from amino acid alignments and comparative hydropathy profiles of OadB with related proteins. Consistent results were obtained for the three N-terminal and the six C-terminal membrane-spanning alpha-helices. However, the two additional helices that were predicted by hydropathy analyses between the N-terminal and C-terminal blocks did not conform with the fusion results. The analyses were therefore extended by probing the sideness of various engineered cysteine residues with the membrane-impermeant reagent 4-acetamido-4'-maleimidylstilbene-2, 2'-disulfonate. The results were in accord with those of the fusion analyses, suggesting that the protein folds within the membrane by a block of three N-terminal transmembrane segments and another one with six C-terminal transmembrane segments. The mainly hydrophobic connecting segment is predicted not to traverse the membrane fully, but to insert in an undefined manner from the periplasmic face. According to our model, the N-terminus is at the cytoplasmic face and the C-terminus is at the periplasmic face of the membrane.     

Hydrophobicity and prediction of the secondary structure of membrane proteins and peptides.

Reliability of the hydropathy method to predict the formation of membrane-spanning alpha-helices by integral membrane proteins and peptides whose structure is known from X-ray crystallography is analysed. It is shown that Kyte-Doolittle hydropathy plots do not predict accurately 22 transmembrane alpha-helices in the reaction centres (RC) of the photosynthetic bacteria Rhodopseudomonas viridis and Rhodobacter sphaeroides (R-26). The accuracy of prediction for these proteins was improved using an optimised Kyte-Doolittle hydrophobicity scale. However, this hydrophobicity scale did not improve the predictions for the alphabeta-peptides of the B800-850 (LH2) complexes of the photosynthetic bacteria Rhodopseudomonas acidophila and Rhodospirillum molischianum, which were excluded from the optimisation procedure. The best and worst predictions of membrane-spanning alpha-helices for the RC proteins and LH2 peptides, respectively, were obtained with a propensity scale (PRC) calculated from the amino acid sequences and X-ray data for the RC proteins. A propensity scale (PLH) obtained using the amino acid sequences and X-ray data for the alphabeta-peptides of the LH2 complexes did not give an acceptable prediction of the transmembrane segments in the LH2 peptides; moreover, it markedly contradicted the PRC scale. Amino acids have been concluded to have no significant preference to localisation in transmembrane segments. Therefore, the predictive ability of the hydropathy methodology appears to be limited: the number of transmembrane segments can be correctly calculated for the best case only, and the lengths and positions of membrane-spanning alpha-helices in a protein amino acid sequence can not be predicted exactly.     

The structure of the dihaem cytochrome b of fumarate reductase in Wolinella succinogenes: circular dichroism and sequence analysis studies

The fumarate reductase from Wolinella succinogenes contains two haem groups with markedly different midpoint potentials (-20 mV and -200 mV). The enzyme is made up of three subunits, the lipophilic one of which (cytochrome b) ligates the haems. Circular dichroism (CD) spectroscopy has been applied to the reductase in order to obtain information on the structure of the haems and of their environment. This approach is integrated with amino acid sequence comparison of the cytochrome b with other quinone-reacting membrane haemoproteins for predicting the axial ligands of the haems as well as their location relative to the membrane. The following results have been obtained: (1) the CD spectra in the Soret region show exciton coupling indicating haem-haem interaction, which is particularly evident in the reduced state and disappears upon denaturation of the enzyme; (2) The apoprotein of cytochrome b is predicted to consist of five hydrophobic helices (helices A-D and cd), four of which should span the membrane. Helices A, B, C and cd contain a histidine residue each which possibly forms one of the ligands of the haems. It is proposed that haem b (-20 mV) is ligated by H44 and H93, and haem b (-200 mV) by H143 and H182.     

Beta-galactosidase gene fusions as probes for the cytoplasmic regions of subunits I and II of the membrane-bound cytochrome d terminal oxidase from Escherichia coli

The cytochrome d terminal oxidase complex is a component of the aerobic respiratory chain of Escherichia coli. This enzyme catalyzes the oxidation of ubiquinol-8 within the cytoplasmic membrane and the reduction of molecular oxygen to water along with the concomitant generation of a proton-motive force across the membrane. Previous studies have established that the oxidase is composed of one copy of each of two subunits (I and II), and contains four heme prosthetic groups. The hydropathy profiles of the amino acid sequences suggest that each subunit has multiple transmembrane-spanning helical segments. The goal of the current work is to obtain experimental information about which portions of the two polypeptide chains are facing the cytoplasm. This is part of an effort to determine the topological folding of the two subunits across the membrane. A number of random gene fusions were generated in vitro which encode hybrid proteins in which the amino-terminal portion is provided by one of the two subunits of the oxidase, and the carboxyl-terminal portion is beta-galactosidase. Studies from other systems have indicated that the only hybrid proteins which will manifest high beta-galactosidase specific activity and be membrane-bound will be those where the fusion junction is in a region of the cytochrome polypeptides facing the cytoplasm. Fusions were obtained in eight positions within subunit I and 11 positions within subunit II. These identified four cytoplasmic-facing regions within subunit II, consistent with its hydropathy profile showing eight transmembrane helices. The data with subunit I are less conclusive.     

Membrane topology screen of secondary transport proteins in structural class ST[3] of the MemGen classification. Confirmation and structural diversity

The MemGen structural classification of membrane proteins groups families of proteins by hydropathy profile alignment. Class ST[3] of the MemGen classification contains 32 families of transporter proteins including the IT superfamily. Transporters from 19 different families in class ST[3] were evaluated by the TopScreen experimental topology screening method to verify the structural classification by MemGen. TopScreen involves the determination of the cellular disposition of three sites in the polypeptide chain of the proteins which allows for discrimination between different topology models. For nearly all transporters at least one of the predicted localizations is different in the models produced by MemGen and predictor TMHMM. Comparison to the experimental data showed that in all cases the prediction by MemGen was correct. It is concluded that the structural model available for transporters of the [st324]ESS and [st326]2HCT families is also valid for the other families in class ST[3]. The core structure of the model consists of two homologous domains, each containing 5 transmembrane segments, which have an opposite orientation in the membrane. A reentrant loop is present in between the 4th and 5th segments in each domain. Nearly all of the identified and experimentally confirmed structural variations involve additions of transmembrane segments at the boundaries of the core model, at the N- and C-termini or in between the two domains. Most remarkable is a domain swap in two subfamilies of the [st312]NHAC family that results in an inverted orientation of the proteins in the membrane.     

Subunit IV (Mr = 14,384) of the cytochrome b-c1 complex from Rhodobacter sphaeroides. Cloning, DNA sequencing, and ubiquinone binding domain.

The Rhodobacter sphaeroides gene encoding subunit IV of the cytochrome b-c1 complex (fbcQ) was cloned and sequenced. The fbcQ cistron is 372 base pairs long and encodes 124 amino acid residues. The molecular mass of subunit IV, deduced from the nucleotide sequence, is 14,384 Da. A hydropathy plot of the predicted amino acid sequence revealed only one transmembrane helix; it is near the C-terminal end. The 3-azido-2-methyl-5-methoxy-6-(3,7-dimethyl[3H]octyl)-1,4-benzoquinone ([3H]azido-Q)-labeled subunit IV was isolated from the [3H]-azido-Q-treated cytochrome b-c1 complex. A ubiquinone-binding peptide was obtained by digesting the labeled subunit IV with V8 protease followed by high performance liquid chromatography separation. Amino acid analysis and partial N-terminal sequencing of this ubiquinone-binding peptide revealed that it corresponded to residues 77-124 of subunit IV. Based on the hydropathy profile and predicted tendency to form alpha-helices and beta-sheets, we propose a structural model for subunit IV. In this model the ubiquinone-binding domain is located near the surface of the membrane.     

NMR structure determination of a membrane protein with two transmembrane helices in micelles: MerF of the bacterial mercury detoxification system

The three-dimensional backbone structure of a membrane protein with two transmembrane helices in micelles was determined using solution NMR methods that rely on the measurement of backbone (1)H-(15)N residual dipolar couplings (RDCs) from samples of two different constructs that align differently in stressed polyacrylamide gels. Dipolar wave fitting to the (1)H-(15)N RDCs determines the helical boundaries based on periodicity and was utilized in the generation of supplemental dihedral restraints for the helical segments. The (1)H-(15)N RDCs and supplemental dihedral restraints enable the determination of the structure of the helix-loop-helix core domain of the mercury transport membrane protein MerF with a backbone RMSD of 0.58 A. Moreover, the fold of this polypeptide demonstrates that the two vicinal pairs of cysteine residues, shown to be involved in the transport of Hg(II) across the membrane, are exposed to the cytoplasm. This finding differs from earlier structural and mechanistic models that were based primarily on the somewhat atypical hydropathy plot for MerF and related transport proteins.     

The X-ray Structure of NccX from Cupriavidus metallidurans 31A Illustrates Potential Dangers of Detergent Solubilization When Generating and Interpreting Crystal Structures of Membrane Proteins

The x-ray structure of NccX, a type II transmembrane metal sensor, from Cupriavidus metallidurans 31A has been determined at a resolution of 3.12 Å. This was achieved after solubilization by dodecylphosphocholine and purification in the presence of the detergent. NccX crystal structure did not match the model based on the extensively characterized periplasmic domain of its closest homologue CnrX. Instead, the periplasmic domains of NccX appeared collapsed against the hydrophobic transmembrane segments, leading to an aberrant topology incompatible with membrane insertion. This was explained by a detergent-induced redistribution of the hydrophobic interactions among the transmembrane helices and a pair of hydrophobic patches keeping the periplasmic domains together in the native dimer. Molecular dynamics simulations performed with the full-length protein or with the transmembrane segments were used along with in vivo homodimerization assays (TOXCAT) to evaluate the determinants of the interactions between NccX protomers. Taken as a whole, computational and experimental results are in agreement with the structural model of CnrX where a cradle-shaped periplasmic metal sensor domain is anchored into the inner membrane by two N-terminal helices. In addition, they show that the main determinant of NccX dimerization is the periplasmic soluble domain and that the interaction between transmembrane segments is highly dynamic. The present work introduces a new crystal structure for a transmembrane protein and, in line with previous studies, substantiates the use of complementary theoretical and in vivo investigations to rationalize a three-dimensional structure obtained in non-native conditions.     

The Transmembrane Helices of Beef Heart Cytochrome Oxidase

The locations of the transmembrane helices in the 12 subunits of beef heart cytochrome oxidase were predicted with a modified form of the von Heijne-Blomberg hydrophobicity scale. Based on ~20 residues per transmembrane helix, about 480 of the estimated 660 helical residues (36.8% of 1,793 total residues) are expected to be in transmembrane helices that have their axes tilted by a small angle α from the normal to the plane of the membrane. This angle is calculated to be ~30°, based on the observed overall tilt angle θ of 39° obtained from circular dichroism (CD) measurements on multilamellar films, or about 25°, based on the observed tilt angle θ of 36° obtained from the infrared linear dichroism of films. For 21 residues per transmembrane helix, the calculated values of α become 32° and 28°, respectively, depending upon the value of θ used. Thus, a transmembrane helical tilt angle of ~30° accounts for the predicted transmembrane stretches in cytochrome oxidase if 20-21 residues are sufficient to span the membrane. Additional helical residues in the lipid head region may deviate by a larger angle from the normal to the plane of the membrane in cytochrome oxidase.     

Membrane topology of Escherichia coli diacylglycerol kinase.

The topology of Escherichia coli diacylglycerol kinase (DAGK) within the cytoplasmic membrane was elucidated by a combined approach involving both multiple aligned sequence analysis and fusion protein experiments. Hydropathy plots of the five prokaryotic DAGK sequences available were uniform in their prediction of three transmembrane segments. The hydropathy predictions were experimentally tested genetically by fusing C-terminal deletion derivatives of DAGK to beta-lactamase and beta-galactosidase. Following expression, the enzymatic activities of the chimeric proteins were measured and used to determine the cellular location of the fusion junction. These studies confirmed the hydropathy predictions for DAGK with respect to the number and approximate sequence locations of the transmembrane segments. Further analysis of the aligned DAGK sequences detected probable alpha-helical N-terminal capping motifs and two amphipathic alpha-helices within the enzyme. The combined fusion and sequence data indicate that DAGK is a polytopic integral membrane protein with three transmembrane segments with the N terminus of the protein in the cytoplasm, the C terminus in the periplasmic space, and two amphipathic helices near the cytoplasmic surface.     

Monte Carlo simulations of tBid association with the mitochondrial outer membrane

Bid, a BH3-only pro-apoptopic member of the BCL-2 protein family, regulates cell death at the level of mitochondrial cytochrome c efflux. Bid consists of 8 α-helices (H1–H8, respectively) and is soluble cytosolic protein in its native state. Proteolysis of the N-terminus (encompassing H1 and H2) of Bid by caspase 8 in apoptosis yields activated “tBid” (truncated Bid), which translocates to the mitochondria and induces the efflux of cytochrome c. The release of cytochrome c from mitochondria to the cytosol constitutes a critical control point in apoptosis that is regulated by interaction of tBid protein with mitochondrial membrane. tBid displays structural homology to channel-forming bacterial toxins, such as colicins or transmembrane domain of diphtheria toxin. By analogy, it has been hypothesized that tBid would unfold and insert into the lipid bilayer of the mitochondria outer membrane (MOM) upon membrane association. However, it has been shown recently that unlike colicins and the transmembrane domain of diphtheria toxin, tBid binds to the lipid bilayer maintaining α-helical conformation of its helices without adopting a transmembrane orientation by them. Here, the mechanism of the association of tBid with the model membrane mimicking the mitochondrial membrane is studied by Monte Carlo simulations, taking into account the underlying energetics. A novel two-stage hierarchical simulation protocol combining coarse-grained discretization of conformational space with subsequent refinements was applied which was able to generate the protein conformation and its location in the membrane using modest computational resources. The simulations show that starting from NMR-established conformation in the solution, the protein associates with the membrane without adopting the transmembrane orientation. The configuration (conformation and location) of tBid providing the lowest free energy for the system protein/membrane/solvent has been obtained. The simulations reveal that tBid upon association with the membrane undergoes significant conformational changes primarily due to rotations within the loops between helices H4 and H5, H6 and H7, H7 and H8. It is established that in the membrane-bound state of tBid-monomer helices H3 and H5 have the locations exposed to the solution, helices H6 and H8 are partly buried and helices H4 and H7 are buried into the membrane at shallow depth. The average orientation of tBid bound to the membrane in the most stable configuration reported here is in satisfactory agreement with the evaluations obtained by indirect experimental means. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Two isoforms of PSAP/MTCH1 share two proapoptotic domains and multiple internal signals for import into the mitochondrial outer membrane

Presenilin 1-associated protein (PSAP) was first identified as a protein that interacts with presenilin 1. It was later reported that PSAP is a mitochondrial protein that induces apoptosis when overexpressed in cultured cells. PSAP is also known as mitochondrial carrier homolog 1 (Mtch1). In this study, we show that there are two proapoptotic PSAP isoforms generated by alternative splicing that differ in the length of a hydrophilic loop located between two predicted transmembrane domains. Using RT-PCR and Western blot assays, we determined that both isoforms are expressed in human and rat tissues as well as in culture cells. Our results indicate that PSAP is an integral mitochondrial outer membrane protein, although it contains a mitochondrial carrier domain conserved in several inner membrane carriers, which partially overlaps one of the predicted transmembrane segments. Deletion of this transmembrane segment impairs mitochondrial import of PSAP. Replacement of this segment with each of two transmembrane domains, with opposite membrane orientations, from an unrelated protein indicated that one of them allowed mitochondrial localization of the PSAP mutant, whereas the other one did not. Our interpretation of these results is that PSAP contains multiple mitochondrial targeting motifs dispersed along the protein but that a transmembrane domain in the correct position and orientation is necessary for membrane insertion. The amino acid sequence within this transmembrane domain may also be important. Furthermore, two independent regions in the amino terminal side of the protein are responsible for its proapoptotic activity. Possible implications of these findings in PSAP function are discussed. presenilin 1-associated protein-mitochondrial carrier homolog 1; mitochondria; apoptosis; presenilin; Alzheimer's disease     

A structural model of the acetylcholine receptor channel based on partition energy and helix packing calculations.

A structural model of the transmembrane portion of the acetylcholine receptor was developed from sequences of all its subunits by using transfer energy calculations to locate transmembrane alpha-helices and to calculate which helical side chains should be in contact with water inside the channel, with portions of other transmembrane helices, or with lipid hydrocarbon chains. "Knobs-into-holes" side chain packing calculations were used with other factors to stack the transmembrane alpha-helices together. In the model each subunit has the following structures in order along the sequence from the NH2 terminus: a large extracellular domain of undetermined structure, a short apolar alpha-helix that lies on the extracellular lipid surface of the membrane; three apolar transmembrane alpha-helices (I, II, and III), a cytoplasmic domain of undetermined structure, an amphipathic transmembrane alpha-helix (L) that forms the channel lining, a short extracellular alpha-helix, another apolar transmembrane alpha-helix (IV), and a small cytoplasmic domain formed by the COOH-terminal end of the chain. Three concentric layers form the pore. A bundle of five amphipathic L helices forms the channel lining. This bundle is surrounded by a bundle of 10 alternating II and III helices. Helices I and IV cover portions of the outer surface of the bundle formed by helices II and III. Positions of disulfide bridges are predicted and a mechanism for opening and closing conformational changes is proposed that requires tilting transmembrane helices and possibly a thiol-disulfide interchange reaction.     

Identification and Characterization of Unique Proline-rich Peptides Binding to the Mitochondrial Fission Protein hFis1

Mammalian mitochondrial fission requires at least two proteins, hFis1 and the dynamin-like GTPase DLP1/Drp1. The mitochondrial protein hFis1 is anchored at the outer membrane by a C-terminal transmembrane domain. The cytosolic domain of hFis1 contains six α helices [α1–α6] out of which [α2–α5] form tetratricopeptide repeat (TPR)-like motifs. DLP1 and possibly other proteins are thought to interact with the hFis1 TPR region during the fission process. It has also been suggested that the α1-helix regulates protein-protein interactions at the TPR. We performed random peptide phage display screening using the hFis1[α2–α6] as the target and identified ten different peptide sequences. Phage ELISA using mutant hFis1 indicates that the peptide binding requires the α2 and α3 helices and the intact TPR structure. Competition experiments and surface plasmon resonance analyses confirmed that a subset of free peptides enriched with proline residues directly bind to the target. Two of these peptides bind to the α1-containing intact cytosolic domain of hFis1 with decreased affinity. Peptide microinjection into cells abolished the mitochondrial swelling induced by overexpression of α1-deleted hFis1, and significantly decreased cytochrome c release from mitochondria upon apoptotic induction. Our data demonstrate that hFis1 can bind to multiple amino acid sequences selectively, and that the TPR constitutes the main binding region of hFis1, providing a first insight into the hFis1 TPR as a potential therapeutic target.     

Classification of α-Helical Membrane Proteins Using Predicted Helix Architectures

Despite significant methodological advances in protein structure determination high-resolution structures of membrane proteins are still rare, leaving sequence-based predictions as the only option for exploring the structural variability of membrane proteins at large scale. Here, a new structural classification approach for α-helical membrane proteins is introduced based on the similarity of predicted helix interaction patterns. Its application to proteins with known 3D structure showed that it is able to reliably detect structurally similar proteins even in the absence of any sequence similarity, reproducing the SCOP and CATH classifications with a sensitivity of 65% at a specificity of 90%. We applied the new approach to enhance our comprehensive structural classification of α-helical membrane proteins (CAMPS), which is primarily based on sequence and topology similarity, in order to find protein clusters that describe the same fold in the absence of sequence similarity. The total of 151 helix architectures were delineated for proteins with more than four transmembrane segments. Interestingly, we observed that proteins with 8 and more transmembrane helices correspond to fewer different architectures than proteins with up to 7 helices, suggesting that in large membrane proteins the evolutionary tendency to re-use already available folds is more pronounced.     

The uncoupling protein from brown fat mitochondria is related to the mitochondrial ADP/ATP carrier. Analysis of sequence homologies and of folding of the protein in the membrane.

We report here, for the first time, the primary structure of uncoupling protein as established by amino acid sequencing. Like the ADP/ATP carrier, this protein has a tripartite structure comprising three similar sequences of approximately 100 residues each. These six 'repeats' exhibit striking conservation of several residues, in particular glycine and proline, at possible structurally strategic positions. Although the two proteins differ strongly in their amino acid composition, their sequences are distantly homologous. Three membrane-spanning alpha-helices can be deduced from hydropathy plots. A modified plot accounting for amphiphilic helices indicates 5-6 such alpha-segments. In addition an amphiphilic beta-strand of membrane-spanning length can be discerned. The tripartite sequence structure is also distinctly reflected in the hydropathy distribution. Based on the membrane disposition of the segments of the ADP/ATP carrier, a model for the transmembrane folding path of the polypeptide chain of the uncoupling protein is proposed.