Construction and in vivo analysis of new split lactose permeases

Assembling a Correctly Folded and Functional Heptahelical Membrane Protein by Protein Trans-splicing

Protein trans-splicing using split inteins is well established as a useful tool for protein engineering. Here we show, for the first time, that this method can be applied to a membrane protein under native conditions. We provide compelling evidence that the heptahelical proteorhodopsin can be assembled from two separate fragments consisting of helical bundles A and B and C, D, E, F, and G via a splicing site located in the BC loop. The procedure presented here is on the basis of dual expression and ligation in vivo. Global fold, stability, and photodynamics were analyzed in detergent by CD, stationary, as well as time-resolved optical spectroscopy. The fold within lipid bilayers has been probed by high field and dynamic nuclear polarization-enhanced solid-state NMR utilizing a (13)C-labeled retinal cofactor and extensively (13)C-(15)N-labeled protein. Our data show unambiguously that the ligation product is identical to its non-ligated counterpart. Furthermore, our data highlight the effects of BC loop modifications onto the photocycle kinetics of proteorhodopsin. Our data demonstrate that a correctly folded and functionally intact protein can be produced in this artificial way. Our findings are of high relevance for a general understanding of the assembly of membrane proteins for elucidating intramolecular interactions, and they offer the possibility of developing novel labeling schemes for spectroscopic applications.

Biosynthesis and NMR-studies of a double transmembrane domain from the Y4 receptor, a human GPCR

The human Y4 receptor, a class A G-protein coupled receptor (GPCR) primarily targeted by the pancreatic polypeptide (PP), is involved in a large number of physiologically important functions. This paper investigates a Y4 receptor fragment (N-TM1-TM2) comprising the N-terminal domain, the first two transmembrane (TM) helices and the first extracellular loop followed by a (His)(6) tag, and addresses synthetic problems encountered when recombinantly producing such fragments from GPCRs in Escherichia coli. Rigorous purification and usage of the optimized detergent mixture 28 mM dodecylphosphocholine (DPC)/118 mM% 1-palmitoyl-2-hydroxy-sn-glycero-3-[phospho-rac-(1-glycerol)] (LPPG) resulted in high quality TROSY spectra indicating protein conformational homogeneity. Almost complete assignment of the backbone, including all TM residue resonances was obtained. Data on internal backbone dynamics revealed a high secondary structure content for N-TM1-TM2. Secondary chemical shifts and sequential amide proton nuclear Overhauser effects defined the TM helices. Interestingly, the properties of the N-terminal domain of this large fragment are highly similar to those determined on the isolated N-terminal domain in the presence of DPC micelles.

Molecular and cellular approaches for the detection of protein-protein interactions: latest techniques and current limitations

Homotypic and heterotypic protein interactions are crucial for all levels of cellular function, including architecture, regulation, metabolism, and signaling. Therefore, protein interaction maps represent essential components of post-genomic toolkits needed for understanding biological processes at a systems level. Over the past decade, a wide variety of methods have been developed to detect, analyze, and quantify protein interactions, including surface plasmon resonance spectroscopy, NMR, yeast two-hybrid screens, peptide tagging combined with mass spectrometry and fluorescence-based technologies. Fluorescence techniques range from co-localization of tags, which may be limited by the optical resolution of the microscope, to fluorescence resonance energy transfer-based methods that have molecular resolution and can also report on the dynamics and localization of the interactions within a cell. Proteins interact via highly evolved complementary surfaces with affinities that can vary over many orders of magnitude. Some of the techniques described in this review, such as surface plasmon resonance, provide detailed information on physical properties of these interactions, while others, such as two-hybrid techniques and mass spectrometry, are amenable to high-throughput analysis using robotics. In addition to providing an overview of these methods, this review emphasizes techniques that can be applied to determine interactions involving membrane proteins, including the split ubiquitin system and fluorescence-based technologies for characterizing hits obtained with high-throughput approaches. Mass spectrometry-based methods are covered by a review by Miernyk and Thelen (2008; this issue, pp. 597-609). In addition, we discuss the use of interaction data to construct interaction networks and as the basis for the exciting possibility of using to predict interaction surfaces.

Evolutionarily related insertion pathways of bacterial, mitochondrial, and thylakoid membrane proteins

The inner membranes of eubacteria and mitochondria, as well as the chloroplast thylakoid membrane, contain essential proteins that function in oxidative phosphorylation and electron transport processes or in photosynthesis. Because most of the organellar proteins are nuclear encoded, they are synthesized in the cytoplasm and subsequently imported into the organelle before they are inserted into the membrane. This review focuses on the pathways of protein insertion into the inner membrane of eubacteria and mitochondria and into the chloroplast thylakoid membrane. In many respects, insertion of proteins into the inner membrane of bacteria is a process similar to that used by proteins of the thylakoid membrane. In both of these systems a signal recognition particle (SRP) and a SecYE-translocase are involved, as in translocation into the endoplasmic reticulum. The pathway of proteins into the mitochondrial membranes appears to be different in that it involves no SecYE-like components. A conservative pathway, recently identified in mitochondria, involves the Oxa1 protein for the insertion of proteins from the matrix. The presence of Oxa1 homologues in eubacteria and chloroplasts suggests that this pathway is evolutionarily conserved.

Helical membrane protein folding, stability, and evolution

Helical membrane protein folding and oligomerization can be usefully conceptualized as involving two energetically distinct stages-the formation and subsequent side-to-side association of independently stable transbilayer helices. The interactions of helices with the bilayer, with prosthetic groups, and with each other are examined in the context of recent evidence. We conclude that the two-stage concept remains useful as an approach to simplifying discussions of stability, as a framework for folding concepts, and as a basis for understanding membrane protein evolution.

The central cytoplasmic loop of the major facilitator superfamily of transport proteins governs efficient membrane insertion

Deletion of 5 residues (Delta5) from the central cytoplasmic loop of the lactose permease of Escherichia coli has no significant effect on expression or activity, whereas Delta12 leads to increased rates of permease turnover after membrane insertion and decreased transport activity, and Delta20 abolishes insertion and activity. By expressing Delta12 or Delta20 in two halves, both expression and activity are restored to levels approximating wild type. Replacing deleted residues with random hydrophilic amino acids also leads to full recovery. However, introduction of hydrophobic residues decreases expression and activity in a context-dependent manner. Thus, a minimum length of the central cytoplasmic loop is vital for proper insertion, stability, and efficient transport activity, because of constraints at the cytoplasmic ends of helices VI and VII. Furthermore, the results are consistent with the idea that the middle cytoplasmic loop provides a temporal delay between insertion of the first six helices into the membrane before insertion of the second six helices.

The glucose transporter of the Escherichia coli phosphotransferase system: linker insertion mutants and split variants

The IICB(Glc) subunit of the glucose transporter acts by a mechanism which couples vectorial translocation with phosphorylation of the substrate. It contains 8 transmembrane segments connected by 4 periplasmic, 2 short, 1 long (80 residues), cytoplasmic loops and an independently folding cytoplasmic domain at the C-terminus. Random DNase I cleavage, EcoRI linker insertion, and screening for transport-active mutants afforded 12 variants with between 46% and 116% of wild-type sugar phosphorylation activity. They carried inserts of up to 29 residues and short deletions in periplasmic loops 1, 2, and 3, in the long cytoplasmic loop 3, and in the linker region between the membrane spanning IIC(Glc) and the cytoplasmic IIB(Glc) domains. Disruption of the gene at the sites of linker insertion decreased the expression level and diminished phosphotransferase activity to between 7% and 32%. IICB(Glc) with a discontinuity in the cytoplasmic loop was purified to homogeneity as a stable complex. It was active only if encoded by a dicistronic operon but not if encoded by two genes on two different replicons, suggesting that spatial proximity of the nascent polypeptide chains is important for folding and membrane assembly.

Folding and activity of circularly permuted forms of a polytopic membrane protein

The transmembrane subunit of the Glc transporter (IICB(Glc)), which mediates uptake and concomitant phosphorylation of glucose, spans the membrane eight times. Variants of IICB(Glc) with the native N and C termini joined and new N and C termini in the periplasmic and cytoplasmic surface loops were expressed in Escherichia coli. In vivo transport/in vitro phosphotransferase activities of the circularly permuted variants with the termini in the periplasmic loops 1 to 4 were 35/58, 32/37, 0/3, and 0/0% of wild type, respectively. The activities of the variants with the termini in the cytoplasmic loops 1 to 3 were 0/25, 0/4 and 24/70, respectively. Fusion of alkaline phosphatase to the periplasmic C termini stabilized membrane integration and increased uptake and/or phosphorylation activities. These results suggest that internal signal anchor and stop transfer sequences can function as N-terminal signal sequences in a circularly permuted alpha-helical bundle protein and that the orientation of transmembrane segments is determined by the amino acid sequence and not by the sequential appearance during translation. Of the four IICB(Glc) variants with new termini in periplasmic loops, only the one with the discontinuity in loop 4 is inactive. The sequences of loop 4 and of the adjacent TM7 and TM8 are conserved in all phosphoenolpyruvate-dependent carbohydrate:phosphotransferase system transporters of the glucose family.

Location of helix III in the lactose permease of Escherichia coli as determined by site-directed thiol cross-linking

The six N-terminal transmembrane helices (N(6)) and the six C-terminal transmembrane helices (C(6)) in the lactose permease of Escherichia coli, each containing a single Cys residue, were coexpressed, and cross-linking was studied. The proximity of paired Cys residues in helices III (position 78, 81, 84, 86, 87, 88, 90, 93, or 96) and VII (position 227, 228, 231, 232, 235, 238, 239, 241, 243, 245, or 246) was examined by using iodine or two rigid homobifunctional thiol-specific cross-linking reagents with different lengths [N,N'-o-phenylenedimaleimide (o-PDM; 6 A) and N, N'-p-phenylenedimaleimide (p-PDM; 10 A)]. Cys residues in the periplasmic half of helix III (position 87, 93, or 96) cross-link to Cys residues in the periplasmic half of helix VII (position 235, 238, 239, 241, or 245). In contrast, no cross-linking is evident with paired Cys residues near the cytoplasmic ends of helices III (position 78 or 81) and VII (position 227, 228, 213, 232, or 235). Therefore, the periplasmic halves of helices III and VII are in close proximity, and the helices tilt away from each other toward the cytoplasmic face of the membrane. On the basis of the findings, a modified helix packing model for the permease is presented.

Proximity relationships between helices I and XI or XII in the lactose permease of Escherichia coli determined by site-directed thiol cross-linking

The lactose permease of Escherichia coli was expressed in two fragments (split permease), each with a Cys residue, and cross-linking was studied. Split permease with a discontinuity in either loop II/III (N2C10permease) or loop VI/VII (N6C6permease) was used. Proximity of multiple pairs of Cys residues in helices I and XI or XII was examined by using three homobifunctional thiol-specific cross-linking reagents of different lengths and flexibilities (6 A, rigid; 10 A, rigid; 16 A, flexible) or iodine. Cys residues in the periplasmic half of helix I cross-link to Cys residues in the periplasmic half of helix XI. In contrast, no cross-linking is evident with paired Cys residues near the cytoplasmic ends of helices I and XI. Therefore, the periplasmic halves of helices I and XI are in close proximity, and the helices tilt away from each other towards the cytoplasmic face of the membrane. Cross-linking is also found with paired Cys residues near the middle of helices I and XII, but not with paired Cys residues near either end of the helices. Thus, helices I and XII are in close proximity only in the approximate middle of the membrane. Based on the findings, a modified helix packing model is proposed.

Helix packing in the lactose permease of Escherichia coli determined by site-directed thiol cross-linking: helix I is close to helices V and XI

Coexpression of lacY gene fragments encoding the first two transmembrane domains and the remaining 10 transmembrane domains complement in the membrane and catalyze active lactose transport [Wrubel, W., Stochaj, U., et al. (1990) J. Bacteriol. 172, 5374-5381]. Accordingly, a plasmid encoding contiguous, nonoverlapping permease fragments with a discontinuity in the cytoplasmic loop between helices II and III (loop II/III) was constructed (N2C10 permease). When Phe27 (helix I) is replaced with Cys, cross-linking is observed with two native Cys residues, Cys148 (helix V) and Cys355 (helix XI). Cross-linking of a Cys residue at position 27 to Cys148 occurs with N,N'-o-phenylenedimaleimide (o-PDM; rigid 6 A), with N,N'-p-phenylenedimaleimide (p-PDM; rigid 10 A), or with 1,6-bis(maleimido)hexane (BMH; flexible 16 A). On the other hand, with the Phe27-->Cys/Cys355 pair, cross-linking is observed with p-PDM or BMH but not o-PDM. In neither case is cross-linking observed with iodine. It is suggested that a Cys residue at position 27 is within 6-10 A from Cys148 and about 10 A from Cys355. The results provide evidence for proximity between helix I and helices V or XI in the tertiary structure of the permease. In addition, the findings are consistent with other results [Venkatesan, P., Kaback, H. R. (1998) Proc. Natl. Acad. Sci. U.S.A. 95, 9802-9807] indicating that Glu126 (helix IV) and Arg144 (helix V) are within the membrane, rather than at the membrane-water interface on the cytoplasmic face.

Transmembrane helix tilting and ligand-induced conformational changes in the lactose permease determined by site-directed chemical crosslinking in situ

The N-terminal six transmenbrane helices (N6) and the C-terminal six transmembrane helices (C6) of the lactose permease of Escherichia coli, each with a Cys residue, were co-expressed independently, and crosslinking was studied. Proximity of paired Cys residues in helices II (position 49, 52, 53, 56, 57, 60, 63 or 67) and VII (position 227, 230, 231, 234, 238, 241, 242 or 245) or XI (position 350, 353, 354, 357, 361 or 364) was examined by using two homobifunctional thiol-specific crosslinking agents of different lengths (6 or 10 A). The results demonstrate that a Cys residue placed in the periplasmic half of helix II (position 49, 52, 53 or 57) crosslinks to Cys residues in the periplasmic half of helix VII (position 241, 242 or 245). In contrast, no crosslinking is evident with paired-Cys residues in the cytoplasmic halves of helices II (position 60, 63 or 67) and VII (position 227, 230, 231, 234 or 238). Remarkably, a Cys residue in the cytoplasmic half of helix II (position 60, 63 or 67) crosslinks with a Cys residue in the cytoplasmic half of helix XI (position 350, 353 or 354), while paired-Cys residues at positions in the periplasmic halves of the two helices do not crosslink. Therefore, helix II is tilted in such a manner that the periplasmic end is close to helix VII, and the cytoplasmic end is close to helix XI. Furthermore, ligand-binding alters the crosslinking efficiency of paired-Cys residues in helices II and VII or XI, indicating that both interfaces are conformationally active. The results are consistent with the conclusion that ligand-binding induces a scissors-like movement of helices II and VII that increases interhelical distance by 3 to 4 A at the periplasmic ends and decreases the distance by 3 to 4 A at the approximate middle of the two transmembrane helices.

Ligand-induced changes in periplasmic loops in the lactose permease of Escherichia coli

N- and C-terminal halves of lactose permease, each with a single-Cys residue in a periplasmic loop, were coexpressed, and cross-linking was studied in the presence or absence of ligand. A Cys residue at position 36 between transmembrane helices I and II (loop I/II) forms a disulfide spontaneously with a Cys residue at position 253, 254, 255, or 256 in loop VII/VIII. Moreover, in the presence of o-phenanthroline-copper, a Cys residue at position 42 in loop I/II forms a disulfide with a Cys residue at position 253, 254, 257, or 258 in loop VII/VIII. Changes in the rate of cross-linking are also observed in the presence of substrate, suggesting that ligand binding induces movement between loops I/II and VII/VIII such that positions 253-256 are brought closer to position 36 or 42, while positions 257 and 258 move away from position 42.

Helix packing in polytopic membrane proteins: the lactose permease of Escherichia coli

Recent advances in protein engineering have facilitated the development of alternative approaches to determine helix packing in polytopic membrane proteins. Using the lac permease as a paradigm, several site-directed biophysical and biochemical techniques are described which should be generally applicable.

Helix proximity and ligand-induced conformational changes in the lactose permease of Escherichia coli determined by site-directed chemical crosslinking

N and C-terminal halves of lactose permease, each with a single-Cys residue, were co-expressed, and crosslinking was studied. Iodine or N,N'-o-phenylenedimaleimide (o-PDM; rigid 6 A), crosslinks Asn245 Cys (helix VII) and Ile52 --> Cys or Ser53 --> Cys (helix II). N,N'-p-phenylenedimaleimide (p-PDM; rigid 10 A) crosslinks the 245/53 Cys pair weakly, but does not crosslink 245/52, and 1,6-bis-maleimidohexane (BMH; flexible 16 A) crosslinks both pairs less effectively than o-PDM. Thus, 245 is almost equidistant from 52 and 53 by up to about 6 A. BMH or p-PDM crosslinks Gln242 --> Cys and Ser53 --> Cys, but o-PDM is ineffective, indicating that distance varies by up to 10 A. Ligand binding increases crosslinking of 245/53 with p-PDM or BMH, has little effect with o-PDM and decreases iodine crosslinking. Similar effects are observed with 245/52. Ligand increases 242/53 crosslinking with p-PDM or BMH, but no crosslinking is observed with o-PDM. Therefore, ligand induces a translational or scissors-like displacement of the helices by 3-4 A. Crosslinking 245/53 inhibits transport indicating that conformational flexibility is important for function.

A general method for determining helix packing in membrane proteins in situ: helices I and II are close to helix VII in the lactose permease of Escherichia coli

It was previously shown that coexpression of the lactose permease of Escherichia coli in two contiguous fragments leads to functional complementation. We demonstrate here that site-directed thiol crosslinking of coexpressed permease fragments can be used to determine helix proximity in situ without the necessity of purifying the permease. After coexpression of the six N-terminal (N6) and six C-terminal (C6) transmembrane helices, each with a single Cys residue, crosslinking was carried out in native membranes and assessed by the mobility of anti-C-terminal-reactive polypeptides on immunoblots. A Cys residue at position 242 or 245 (helix VII) forms a disulfide with a Cys residue at either position 28 or 29 (helix I), but not with a Cys residue at position 27, which is on the opposite face of helix I, thereby indicating that the face of helix I containing Pro-28 and Phe-29 is close to helix VII. Similarly, a Cys residue at position 242 or 245 (helix VII) forms a disulfide with a Cys residue at either position 52 or 53 (helix II), but not with a Cys residue at position 54. Furthermore, low-efficiency crosslinking is observed between a Cys residue at position 52 or 53 and a Cys residue at position 361 (helix XI). The results indicate that helix VII lies in close proximity to both helices I and II and that helix II is also close to helix XI. The method should be applicable to a number of different polytopic membrane proteins.

Purification and functional characterization of the C-terminal half of the lactose permease of Escherichia coli

The lactose permease has been expressed in contiguous, non-overlapping polypeptide fragments containing the N-terminal (N6) and C-terminal (C6) transmembrane domains of the protein [Bibi, E., & Kaback, H. R. (1990) Proc. Natl. Acad. Sci. U.S.A. 87, 4325; Zen, K., et al. (1994) Biochemistry 33, 8198]. When expressed individually, N6 and C6 are unstable and do not catalyze active transport. However, when expressed simultaneously, the polypeptides stabilize each other and form a complex that catalyzes active lactose transport. Moreover, a deletion construct containing the first transmembrane domain and the six C-terminal transmembrane domains mediates downhill lactose translocation [Bibi et al. (1991) proc. Natl. Acad. Sci. U.S.A. 88, 7271]. Here we report that C6 can be expressed independently in a relatively stable form that binds monoclonal antibodies 4B1 and 4B11, which interact with conformationally dependent epitopes on the periplasmic and cytoplasmic surfaces of the membrane, respectively. In addition, C6 retains the ability to catalyze lactose translocation down a concentration gradient in a specific manner. Finally, as observed with full-length Val331Cys permease, beta-D-galactopyranosyl 10thio-beta-D-galactopyranoside quenches the fluorescence of 2-(4'-maleimidylanilino)naphthalene- 6-sulfonic acid (MIANS)- labeled C6 with a single-Cys residue in place of Val331, exhibiting as apparent Kd of 0.2 mM. Unlike full-length Val331Cys permease, however, ligand does not induce a chance in the position of the emission maximum of MIANS-labeled C6(Val331Cys) permease not in the reactivity of C6 (Val331Cys) permease with MINAS. the results indicate that C6 retains a conformation similar to that on the native permease and that most of the structure required of high-affinity binding and substrate translocation is located in the C-terminal half of the molecule.

Engineering membrane proteins

Much of the research on integral membrane proteins mirrors that on soluble proteins; however, membrane protein engineering also has its own ends and means, many of which take advantage of the peculiar situation of membrane proteins, whose chains are distributed between one lipidic and two aqueous phases. Extramembrane loops have been shortened, cut, or elongated with segments forming proteolytic cleavage sites, foreign epitopes, extra transmembrane segments, or even whole proteins, with the aim of facilitating purification, biochemical/biophysical studies, or crystallogenesis. Transmembrane alpha-helices have been deleted, duplicated, exchanged, transported into a foreign context or replaced with synthetic peptides, in order to both understand their integration into, and assembly in, the membrane and unravel their functional role. Insertion of cysteine residues has been the basis for a great diversity of experiments, ranging from the exploration of secondary, tertiary and quaternary structures of the transmembrane region to the creation of anchoring points for reporter molecules. Chemical engineering--the synthesis of protein fragments or even of whole proteins--offers particularly exciting new prospects, given the small size of folding domains in alpha-helical membrane proteins. Membrane protein engineering is rapidly developing its own agenda of questions and tool chest of techniques.