Evaluation of transmembrane helix prediction methods using the recently defined NMR structures of the coat proteins from bacteriophages M13 and Pf1

Structure of the genetic code suggested by the hydropathy correlation between anticodons and amino acid residues

The correlation between hydropathies of anticodons and amino acids, detected by other authors utilizing scales of amino acid molecules in solution, was improved with the utilization of scales of amino acid residues in proteins. Three partitions were discerned in the correlation plot with the principal dinucleotides of anticodons (pDiN, excluding the wobble position). (a) The set of outliers of the correlation: Gly-CC, Pro-GG, Ser-GA and Ser-CU. The amino acids are consistently small, hydro-apathetic, stabilizers of protein N-ends, preferred in aperiodic protein conformations and belong to synthetases class II. The pDiN sequences are representative of the homogeneous sector (triplets NRR and NYY), distinguished from the mixed sector (triplets NRY and NYR), that depict a 70% correspondence to the synthetases class II and I, respectively. The triplet pairs proposed to be responsible for the coherence in the set of outliers are of the palindromic kind, where the lateral bases are the same, CCC: GGG and AGA: UCU. This suggests that UCU previously belonged to Ser, adding to other indications that the attribution of Arg to YCU was due to an expansion of the Arg-tRNA synthetase specificity. The other attributions produced two correlation sets. (b) One corresponds to the remaining pDiN of the homogeneous sector, containing both synthetase classes; its regression line overlapped the one formed by the remaining attributions to class II. (c) The other contains the pDiN of the mixed sector and produced steeper slopes, especially with the class I attributions. It is suggested that the correlation was established when the amino acid composition of the protein synthetases became progressively enriched and that the set of outliers were the earliest to have been fixed.

Molecular dynamics simulations on the first two helices of Vpu from HIV-1

Vpu is an 81 amino acid protein of HIV-1 with two phosphorylation sites. It consists of a short N-terminal end traversing the bilayer and a longer cytoplasmic part. The dual functional role of Vpu is attributed to these topological distinct regions of the protein. The first 52 amino acids of Vpu (HV1H2) have been simulated, which are thought to be embedded in a fully hydrated lipid bilayer and to consist of a transmembrane helix (helix-1) connected via a flexible linker region, including a Glu-Tyr-Arg (EYR) motif, with a second helix (helix-2) residing with its helix long axis on the bilayer surface. Repeated molecular dynamics simulations show that Glu-28 is involved in salt bridge formation with Lys-31 and Arg-34 establishing a kink between the two helices. Helix-2 remains in a helical conformation indicating its stability and function as a "peptide float," separating helix-1 from the rest of the protein. This leads to the conclusion that Vpu consists of three functional modules: helix-1, helix-2, and the remaining residues toward the C-terminal end.

Localization and rearrangement modulation of the N-terminal arm of the membrane-bound major coat protein of bacteriophage M13

During infection the major coat protein of the filamentous bacteriophage M13 is in the cytoplasmic membrane of the host Escherichia coli. This study focuses on the configurational properties of the N-terminal part of the coat protein in the membrane-bound state. For this purpose X-Cys substitutions are generated at coat protein positions 3, 7, 9, 10, 11, 12, 13, 14, 15, 17, 19, 21, 22, 23 and 24, covering the N-terminal protein part. All coat protein mutants used are successfully produced in mg quantities by overexpression in E. coli. Mutant coat proteins are labeled and reconstituted into mixed bilayers of phospholipids. Information about the polarity of the local environment around the labeled sites is deduced from the wavelength of maximum emission using AEDANS attached to the SH groups of the cysteines as a fluorescent probe. Additional information is obtained by determining the accessibility of the fluorescence quenchers acrylamide and 5-doxyl stearic acid. By employing uniform coat protein surroundings provided by TFE and SDS, local effects of the backbone of the coat proteins or polarity of the residues could be excluded. Our data suggest that at a lipid to protein ratio around 100, the N-terminal arm of the protein gradually enters the membrane from residue 3 towards residue 19. The hinge region (residues 17-24), connecting the helical parts of the coat protein, is found to be more embedded in the membrane. Substitution of one or more of the membrane-anchoring amino acid residues lysine 8, phenylalanine 11 and leucine 14, results in a rearrangement of the N-terminal protein part into a more extended conformation. The N-terminal arm can also be forced in this conformation by allowing less space per coat protein at the membrane surface by decreasing the lipid to protein ratio. The influence of the phospholipid headgroup composition on the rearrangement of the N-terminal part of the protein is found to be negligible within the range thought to be relevant in vivo. From our experiments we conclude that membrane-anchoring and space-limiting effects are key factors for the structural rearrangement of the N-terminal protein part of the coat protein in the membrane.

Membrane transporters

Carrier-mediated drug transport is relatively unexplored in comparison with passive transcellular and paracellular drug transport. Yet, there is a host of transporter proteins that can be targeted for improving epithelial drug absorption. Generally, these are transport mechanisms for amino acids, dipeptides, monosaccharides, monocarboxylic acids, organic cations, phosphates, nucleosides, and water-soluble vitamins. Among them, the dipeptide transporter mechanism has received the most attention. Dipeptide transporters are H(+)-coupled, energy-dependent transporters that are known to play an essential role in the oral absorption of beta-lactam antibiotics, angiotensin-converting enzyme (ACE) inhibitors, renin inhibitors, and an anti-tumor drug, bestatin. Moreover, several investigators have demonstrated the utility of the dipeptide transporter as a platform for improving the oral bioavailability of drugs such as zidovudine and acyclovir through dipeptide prodrug derivatization. Thus far, at least four proton-coupled peptide transporters have been cloned. The first one cloned was PepT1 from the rabbit small intestine. The focus of this presentation will be structure-function, intracellular trafficking, and regulation of PepT1. Disease, dietary, and possible excipient influences on PepT1 function will also be discussed.

Biopharmaceutics of transmucosal peptide and protein drug administration: role of transport mechanisms with a focus on the involvement of PepT1

Non-invasive delivery of peptide and protein drugs will soon become a reality. This is due partly to a better understanding of the endogenous transport mechanisms, including paracellular transport, endocytosis, and carrier-mediated transport of mucosal routes of peptide and protein drug administration. This paper focuses on work related to the elucidation of structure-function, intracellular trafficking, and regulation of the intestinal dipeptide transporter, PepT1.

Structure, function, and molecular modeling approaches to the study of the intestinal dipeptide transporter PepT1

The proton-coupled intestinal dipeptide transporter, PepT1, has 707 amino acids, 12 putative transmembrane domains (TMD), and is of importance in the transport of nutritional di- and tripeptides and structurally related drugs, such as penicillins and cephalosporins. By using a combination of molecular modeling and site-directed mutagenesis, we have identified several key amino acid residues that effect catalytic transport properties of PepT1. Our molecular model of the transporter was examined by dividing it into four sections, parallel to the membrane, starting from the extracellular side. The molecular model revealed a putative transport channel and the approximate locations of several aromatic and charged amino acid residues that were selected as targets for mutagenesis. Wild type or mutagenized human PepT1 cDNA was transfected into human embryonic kidney (HEK293) cells, and the uptake of tritiated glycylsarcosine [3H]-(Gly-Sar) was measured. Michaelis-Menton analysis of the wild-type and mutated transporters revealed the following results for site-directed mutagenesis. Mutation of Tyr-12 or Arg-282 into alanine has only a very modest effect on Gly-Sar uptake. By contrast, mutation of Trp-294 or Glu-595 into alanine reduced Gly-Sar uptake by 80 and 95%, respectively, and mutation of Tyr-167 reduced Gly-Sar uptake to the level of mock-transfected cells. In addition, preliminary data from fluorescence microscopy following the expression of N-terminal-GFP-labeled PepT1Y167A in HEK cells indicates that the Y167A mutation was properly inserted into the plasma membrane but has a greatly reduced Vmax.

The Helicobacter pylori gene encoding phosphatidylserine synthase: sequence, expression, and insertional mutagenesis

The Helicobacter pylori pss gene, coding for phosphatidylserine synthase (PSS), was cloned and sequenced in this study. A polypeptide of 237 amino acids was deduced from the PSS sequence. H. pylori PSS exhibits significant amino acid sequence identity with the PSS proteins found in the archaebacterium Methanococcus jannaschii, the gram-positive bacterium Bacillus subtilis, and the yeast Saccharomyces cerevisiae but none with its Escherichia coli counterpart. Expression of the putative pss gene in maxicells gave rise to a product of approximately 26 kDa, which is in agreement with the predicted molecular mass of 26,617 Da. A manganese-dependent PSS activity was found in the membrane fractions of the E. coli cells overexpressing the H. pylori pss gene product. This result indicates that this enzyme is a membrane-bound protein, a conclusion which is supported by the fact that the PSS protein contains several local hydrophobic segments which could form transmembrane helices. The pss gene was inactivated with a chloramphenicol acetyltransferase cassette on the plasmid. However, an isogenic pss gene-disrupted mutant of H. pylori UA802 could not be obtained, suggesting that this enzyme plays an essential role in the growth of this organism.

Membrane location of spin-labeled M13 major coat protein mutants determined by paramagnetic relaxation agents

Mutants of the M13 bacteriophage major coat protein containing single cysteine replacements (A25C, V31C, T36C, G38C, T46C, and A49C) in the hydrophobic and C-terminal domains were purified from viable phage. These were used for site-directed spin-labeling to determine the location and assembly of the major coat protein incorporated in bilayer membranes of dioleoylphosphatidylcholine. The membrane location of the spin-labeled cysteine residues was studied with molecular oxygen and Ni2+ ions as paramagnetic relaxation agents preferentially confined to the hydrophobic and aqueous regions, respectively, by using progressive-saturation electron spin resonance (ESR) spectroscopy. The section of the protein around Thr36 is situated at the center of the membrane. Residue Thr46 is placed at the membrane surface in the phospholipid head group region with a short C-terminal section, including Ala49, extending into the aqueous phase. Residue Ala25 is then positioned consistently in the head group region of the apposing lipid monolayer leaflet. These positional assignments are consistent with the observed mobilities of the spin-labeled groups. The outer hyperfine splittings in the ESR spectra decrease from the N-terminal to the C-terminal of the hydrophobic section (residues 25-46), and then drop abruptly in the aqueous phase (residue 49). Additionally, the strong immobilization and low oxygen accessibility of residue 25 are attributed to steric restriction at the hinge region between the transmembrane and N-terminal amphipathic helices. Sequence-specific modulations of the ESR parameters are also observed. Relatively low oxygen accessibilities in the hydrophobic region suggest intermolecular associations of the transmembrane helices, in agreement with saturation transfer ESR studies of the overall protein mobility. Relaxation enhancements additionally reveal a Ni2+ binding site in the N-terminal domain that is consistent with a surface orientation of the amphipathic helix.

Expression of Escherichia coli TehA gives resistance to antiseptics and disinfectants similar to that conferred by multidrug resistance efflux pumps

The genes tehAB located at 32.3 min on the Escherichia coli chromosome were initially identified by their ability to mediate resistance to potassium tellurite (128 micrograms of K2TeO3 per ml) when overexpressed with a high-copy-number plasmid. The genes encode an integral membrane protein (TehA) of 36 kDa with 10 putative transmembrane segments and a second protein (TehB) of 23 kDa. Overexpression of TehAB results in hypersensitivity to dequalinium CI and methyl viologen (paraquat). Expression of TehA alone gives similar hypersensitivity. Overexpression of TehA gave resistance to tetraphenylarsonium CI, ethidium bromide, crystal violet and proflavin. The efflux of ethidium, measured by fluorescence quenching, revealed that TehA transported ethidium at twice the control rate and 10% of the rate of the highly resistant efflux transporter Emr Eco. Addition of tellurite had no effect on ethidium transport. In addition to the ethidium transport assay, a proflavin fluorescence assay which was approximately 200-fold more sensitive was also used. TehA was also found to have proflavin efflux activity. The addition of TeO32- to the proflavin transport assay on TehA caused a 20% increase in transport rate. Both ethidium and proflavin transport were found to be energy dependent.

Local dynamics of the M13 major coat protein in different membrane-mimicking systems

The local environment of the transmembrane and C-terminal domain of M13 major coat protein was probed by site-directed ESR spin labeling when the protein was introduced into three membrane-mimicking systems, DOPC vesicles, sodium cholate micelles, and SDS micelles. For this purpose, we have inserted unique cysteine residues at specific positions in the transmembrane and C-terminal region, using site-directed mutagenesis. Seven viable mutants with reasonable yield were harvested: A25C, V31C, T36C, G38C, T46C, A49C, and S50C. The mutant coat proteins were indistinguishable from wild type M13 coat protein with respect to their conformational and aggregational properties. The ESR data suggest that the amino acid positions 25 and 46 of the coat protein in DOPC vesicles are located close to the membrane-water interface. In this way the lysines at positions 40, 43, and 44 and the phenylalanines at positions 42 and 45 act as hydrophilic and hydrophobic anchors, respectively. The ESR spectra of site specific maleimido spin-labeled mutant coat proteins reconstituted into DOPC vesicles and solubilized in sodium cholate or SDS indicate that the local dynamics of the major coat protein is significantly affected by its structural environment (micellar vs bilayer), location (aqueous vs hydrophobic), and lipid/protein ratio. The detergents SDS and sodium cholate sufficiently well solubilize the major coat protein and largely retain its secondary structure elements. However, the results indicate that they have a poorly defined protein-amphiphilic structure and lipid-water interface as compared to bilayers and thus are not a good substitute for lipid bilayers in biophysical studies.

Sequencing, expression, and genetic characterization of the Helicobacter pylori ftsH gene encoding a protein homologous to members of a novel putative ATPase family

In this study, we isolated and sequenced a Helicobacter pylori gene, designated ftsH, coding for a 632-amino-acid protein which displayed striking similarity throughout its full length to FtsH proteins identified in Escherichia coli, Lactococcus lactis, and Bacillus subtilis. H. pylori FtsH also possessed approximately 200-amino-acid region containing a putative ATPase module which is conserved among members of the AAA protein family (AAA, ATPase associated with diverse cellular activities). The H. pylori ftsH product was overexpressed in E. coli and reacted immunologically with an anti-E. coli FtsH serum (T. Tomoyasu, K. Yamanaka, K. Murata, T. Suzaki, P. Bouloc, A. Kato, H. Niki, S. Hiraga, and T. Ogura, J. Bacteriol. 175:1352-1357, 1993). FtsH was also shown to be present in the membrane fraction of H. pylori, suggesting that it is membrane bound. Disruption of the ftsH gene led to the loss of viability of H. pylori, demonstrating that this gene is essential for cell growth. Overproduction of both H. pylori FtsH and E. coli FtsH together tremendously reduced the growth rate of the E. coli host cells, whereas the growth of the E. coli cells carrying the wild-type E. coli ftsH operon on the chromosome was not significantly affected by overproduction of H. pylori FtsH itself. This result suggests that the abnormal growth of cells results from interaction between H. pylori FtsH and E. coli FtsH.

Accessibility and environment probing using cysteine residues introduced along the putative transmembrane domain of the major coat protein of bacteriophage M13

The major coat protein of the filamentous bacteriophage M13 is located in the inner membrane of host cell Escherichia coli prior to assembly into virions. To identify the transmembrane domain of the coat protein, we have introduced unique cysteine residues along the putative transmembrane domain at position 25, 31, 33, 36, 38, 46, 47, 49, or 50. The mutant major coat protein was solubilized by membrane-mimicking detergents or reconstituted into mixed bilayers of phospholipids. Information about the environmental polarity was deduced from the wavelength of maximum emission, using N-[[(iodoacetyl)-amino)ethyl]-1-sulfonaphthylamine (IAEDANS) attached to the SH groups of the cysteines as a fluorescent probe. Additional information was obtained by determining the accessibility of AEDANS for the fluorescence quencher molecules acrylamide and 5-doxylstearic acid, and the reactivity of the cysteine's sulfhydryl group toward 5,5'-dithiobis(2-nitrobenzoic acid) (DTNB). Our data suggest transmembrane boundaries close to residue 25 and 46, with residue 25 inside the hydrophobic part of the membrane in very close proximity to the membrane-water interface and residue 46 located at the membrane-water interface. Domains of the mutant coat protein which are packed or coated by cholate molecules and various other detergents [except for sodium dodecyl sulfate (SDS)] are at least similarly packed by phospholipid molecules in bilayers. SDS is a good solubilizing detergent but badly mimics the typical nature of a membrane structure. The overall results are interpreted with respect to the established conformation of the coat protein and its membrane anchoring mechanism.

Relationship of subunit 8 of yeast ATP synthase and the inner mitochondrial membrane. Subunit 8 variants containing multiple lysine residues in the central hydrophobic domain retain function

A molecular genetic approach has been used to test the proposition that the central hydrophobic domain of yeast mitochondrial ATP synthase subunit 8 represents a transmembrane stem in contact with the lipid bilayer. The rationale for this approach is the general inability of membrane bilayers to accomodate unshielded charged residues of polypeptide chains. Non-polar residues at several positions within the central hydrophobic domain of subunit 8 were replaced with the positively charged amino acid lysine. This was done in an attempt to disrupt subunit 8 function, and thereby determine the boundaries of the putative transmembrane stem. Each subunit 8 variant was allotopically expressed in vivo as a mitochondrial import precursor encoded by a nuclear gene. It was found that all variants, which included proteins carrying two lysines at various positions in the hydrophobic domain, exhibited the ability to restore growth of subunit-8-deficient cells on the non-fermentable substrate ethanol. This indicated that the function of none of these subunit 8 variants was severely compromised. There was also no detectable change in the proteolipid characteristics of subunit 8, as defined by the chloroform/methanol solubility properties of variant proteins extracted from membranes following import into isolated mitochondria. These data suggest that subunit 8 is located in a hydrophobic niche in the mitochondrial ATP synthase, probably in contact with other protein subunits of the complex. We conclude that the function of subunit 8 does not necessarily require it to be integrated within the inner mitochondrial membrane, in contact with the lipid bilayer. Our findings also suggest that hydropathy plots, indicating hydrophobic domains within polypeptides, cannot reliably be interpreted as transmembrane helices in the absence of independent evidence.

Nucleotide sequence and mutational analysis indicate that two Helicobacter pylori genes encode a P-type ATPase and a cation-binding protein associated with copper transport

A 2.7 kb fragment of Helicobacter pylori UA802 chromosomal DNA was cloned and sequenced. Three open reading frames (designated ORF1, ORF2 and ORF3, respectively) were predicted from the DNA sequence, of which ORF1 and ORF2 appeared to be located within the same operon. The deduced 611-amino-acid sequence of ORF1, a P-type ATPase (designated hpCopA), had striking homology (29-38%) with several bacterial P-type ATPase and contained the potential functional domains conserved in P-type ATPases from various sources ranging from bacterial to human. A protein of 66 amino acids (designated hpCopP) encoded by ORF2 shared extensive sequence similarity with MerP, a periplasmic mercuric ion-transporting protein, and contains the heavy metal-binding motif. Disruption of ORF1 with a chloramphenicol-resistance cassette (CAT) rendered the H. pylori mutants more susceptible to cupric ion than their parental strains, whereas there is no significant alteration of susceptibility to Ni2+, Cd2d+ and Hg2+ between the mutants and the parental strains. The results obtained indicate that ORF1 and ORF2 comprise a cation-transporting system which is associated with copper export out of the H. pylori cells.

Prediction and site-specific mutagenesis of residues in transmembrane alpha-helices of proton-pumping nicotinamide nucleotide transhydrogenases from Escherichia coli and bovine heart mitochondria

Nicotinamide nucleotide transhydrogenase from bovine heart consists of a single polypeptide of 109 kD. The complete gene for this transhydrogenase was constructed, and the protein primary structure was determined from the cDNA. As compared to the previously published sequences of partially overlapping clones, three residues differed: Ala591 (previously Phe), Val777 (previously Glu), and Ala782 (previously Arg). The Escherichia coli transhydrogenase consists of an alpha subunit of 52 kD and a beta subunit of 48 kD. Alignment of the protein primary structure of the bovine trashydrogenase with that of the transhydrogenase from E. coli showed an identity of 52%, indicating similarly folded structures. Prediction of transmembrane-spanning alpha-helices, obtained by applying several prediction algorithms to the primary structures of the revised bovine heart and E. coli transhydrogenases, yielded a model containing 10 transmembrane alpha-helices in both transhydrogenases. In E. coli transhydrogenase, four predicted alpha-helices were located in the alpha subunit and six alpha-helices were located in the beta subunit. Various conserved amino acid residues of the E. coli transhydrogenase located in or close to predicted transmembrane alpha-helixes were replaced by site-specific mutagenesis. Conserved negatively charged residues in predicted transmembrane alpha-helices possibly participating in proton translocation were identified as beta Glu82 (Asp655 in the bovine enzyme) and beta Asp213 (asp787 in the bovine enzyme) located close to the predicted alpha-helices 7 and 9 of the beta subunit. beta Glu82 was replaced by Lys or Gln and beta Asp213 by Asn or His. However, the catalytic as well as the proton pumping activity was retained. In contrast, mutagenesis of the conserved beta His91 residue (His664 in the bovine enzyme) to Ser, Thr, and Cys gave an essentially inactive enzyme. Mutation of alpha His450 (corresponding to His481 in the bovine enzyme) to Thr greatly lowered catalytic activity without abolishing proton pumping. Since no other conserved acidic or basic residues were predicted in transmembrane alpha-helices regardless of the prediction algorithm used, proton translocation by transhydrogenase was concluded to involve a basic rather than an acidic residue. The only conserved cysteine residue, beta Cys260 (Cys834 in the bovine enzyme), located in the predicted alpha-helix 10 of the E. coli transhydrogenase, previously suggested to function as a redox-active dithiol, proved not to be essential, suggesting that redox-active dithiols do not play a role in the mechanism of transhydrogenase.