Arrangement of subunit IV in beef heart cytochrome c oxidase probed by chemical labeling and protease digestion experiments

The arrangement of subunit IV in beef heart cytochrome c oxidase has been explored by chemical labeling and protease digestion studies. This subunit has been purified from four samples of cytochrome c oxidase that had been reacted with N-(4-azido-2-nitrophenyl)-2-aminoethyl[35S]-sulfonate (NAP-taurine), diazobenzene[35S]sulfonate, 1-myristoyl-2-[12-[(4-azido-2-nitrophenyl)amino]lauroyl]-sn-glycero-3- [14C]phosphocholine (I), and 1-palmitoyl-2-(2-azido-4-nitrobenzoyl)-sn-glycero-3-[3H]phosphocholine (II), respectively. The labeled polypeptide was then fragmented by cyanogen bromide, at arginyl side chains with trypsin (after maleylation), and the distribution of the labeling within the sequence was analyzed. The N-terminal part of subunit IV (residues 1-71) was shown to be heavily labeled by water-soluble, lipid-insoluble reagents but not by the phospholipid derivatives. These latter reagents labeled only in the region of residues 62-122, containing the long hydrophobic and putative membrane-spanning stretch. Trypsin cleavage of native cytochrome c oxidase complex at pH 8.2 was shown to clip the first seven amino acids from subunit IV. This cleavage was found to occur in submitochondrial particles but not in mitochondria or mitoplasts. These results are interpreted to show that subunit IV is oriented with its N terminus on the matrix side of the mitochondrial inner membrane and spans the membrane with the extended sequence of hydrophobic lipid residues 79-98 buried in the bilayer.     

Hydrophilic C-terminal domain of the Escherichia coli mannitol permease: phosphorylation, functional independence, and evidence for intersubunit phosphotransfer

The mannitol-specific enzyme II (mannitol permease) of the Escherichia coli phosphotransferase system (PTS) catalyzes the concomitant transport and phosphorylation of D-mannitol. Previous studies have shown that the mannitol permease (637 amino acid residues) consists of 2 structural domains of roughly equal size: an N-terminal, hydrophobic, membrane-bound domain and a C-terminal, hydrophilic, cytoplasmic domain. The C-terminal domain can be released from the membrane by mild proteolysis of everted membrane vesicles [Stephan, M.M., & Jacobson, G.R. (1986) Biochemistry 25, 8230-8234]. In this report, we show that phosphorylation of the intact permease by [32P]HPr (a general phosphocarrier protein of the PTS) followed by tryptic separation of the two domains resulted in labeling of only the C-terminal domain. Phosphorylation of the C-terminal domain occurred even in the complete absence of the N-terminal domain, showing that the former contains most, if not all, of the critical residues comprising the interaction site for phospho-HPr. The phosphorylated C-terminal domain, however, could not transfer its phospho group to mannitol, suggesting that the N-terminal domain is necessary for mannitol binding and/or phosphotransfer from the enzyme to the sugar. The elution profile of the C-terminal domain after molecular sieve chromatography showed that the isolated domain is monomeric, unlike the native permease which is likely a dimer in the membrane. Experiments employing a deletion mutation of the mtlA gene, which encodes a protein lacking the first phosphorylation site in the C-terminal domain (His-554) but retaining the second phosphorylation site (Cys-384), demonstrated that a phospho group could be transferred from phospho-HPr to Cys-384 of the deletion protein, and then to mannitol, only in the presence of the full-length permease.(ABSTRACT TRUNCATED AT 250 WORDS)     

Identifying regions of membrane proteins in contact with phospholipid head groups: covalent attachment of a new class of aldehyde lipid labels to cytochrome c oxidase

A series of amine-specific reagents based on the benzaldehyde reactive group have been synthesized, characterized, and used to study beef heart cytochrome c oxidase reconstituted in phospholipid bilayers. The series contained three classes of reagents: lipid-soluble phosphodiesters having a single hydrocarbon chain, phospholipid analogues, and a water-soluble benzaldehyde. All reagents were either radiolabeled or spin-labeled or both. The Schiff bases formed by these benzaldehydes with amines were found to be reversible until the addition of the reducing agent sodium cyanoborohydride, whereas attachment of lipid-derived aliphatic aldehydes was not readily reversible in the absence of the reducing agent. The benzaldehyde group provides a convenient method of controlling and delaying permanent attachment to integral membrane proteins until after the reconstitution steps. This ensures that the lipid analogues are located properly to identify amine groups at the lipid-protein interface rather than reacting indiscriminately with amines of the hydrophilic domains of the protein. The benzaldehyde lipid labels attach to cytochrome c oxidase with high efficiency. Typically, 20% of the amount of lipid label present was covalently attached to the protein, and the number of moles of label incorporated per mole of protein ranged from 1 to 6, depending on the molar ratios of label, lipid, and protein. The efficiency of labeling by the water-soluble benzaldehyde was much less than that observed for any of the lipid labels because of dilution effects, but equivalent levels of incorporation were achieved by increasing the label concentration. Electron spin resonance spectra of a nitroxide-containing phospholipid analogue covalently attached to reconstituted cytochrome c oxidase exhibited a large motion-restricted component, which is characteristic of spin-labeled lipids in contact with the hydrophobic surfaces of membrane proteins. The line shape and splittings were similar for covalently attached label and label free to diffuse and contact the protein molecules in the bilayer, providing independent evidence that the coupling occurs at the protein-lipid interface. The distribution of the benzaldehyde reagents attached to the polypeptide components of cytochrome c oxidase was examined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The labeling pattern observed for the lipid analogues was not affected by the presence of the nitroxide moiety on the acyl chains but was dependent on the molar ratio of labeling reagent to protein.(ABSTRACT TRUNCATED AT 400 WORDS)     

Molecular cloning of the C-terminal domain of Escherichia coli D-mannitol permease: expression, phosphorylation, and complementation with C-terminal permease deletion proteins.

We have subcloned a portion of the Escherichia coli mtlA gene encoding the hydrophilic, C-terminal domain of the mannitol-specific enzyme II (mannitol permease; molecular mass, 68 kilodaltons [kDa]) of the phosphoenolpyruvate-dependent carbohydrate phosphotransferase system. This mtlA fragment, encoding residues 379 to 637 (residue 637 = C terminus), was cloned in frame into the expression vector pCQV2 immediately downstream from the lambda pr promoter of the vector, which also encodes a temperature-sensitive lambda repressor. E. coli cells carrying a chromosomal deletion in mtlA (strain LGS322) and harboring this recombinant plasmid, pDW1, expressed a 28-kDa protein cross-reacting with antipermease antibody when grown at 42 degrees C but not when grown at 32 degrees C. This protein was relatively stable and could be phosphorylated in vitro by the general phospho-carrier protein of the phosphotransferase system, phospho-HPr. Thus, this fragment of the permease, when expressed in the absence of the hydrophobic, membrane-bound N-terminal domain, can apparently fold into a conformation resembling that of the C-terminal domain of the intact permease. When transformed into LGS322 cells harboring plasmid pGJ9-delta 137, which encodes a C-terminally truncated and inactive permease (residues 1 to ca. 480; molecular mass, 51 kDa), pDW1 conferred a mannitol-positive phenotype to this strain when grown at 42 degrees C but not when grown at 32 degrees C. This strain also exhibited phosphoenolpyruvate-dependent mannitol phosphorylation activity only when grown at the higher temperature. In contrast, pDW1 could not complement a plasmid encoding the complementary N-terminal part of the permease (residues 1 to 377). The pathway of phosphorylation of mannitol by the combined protein products of pGJ9-delta 137 and pDPW1 was also investigated by using N-ethylmaleimide to inactivate the second phosphorylation sites of these permease fragments (proposed to be Cys-384). These results are discussed with respect to the domain structure of the permease and its mechanism of transport and phosphorylation.     

Labeling of the ATP synthase of Escherichia coli from the head-group region of the lipid bilayer

The isolated and membrane-bound forms of the adenosinetriphosphatase of Escherichia coli (ECF1 and ECF1F0, respectively) have been reacted with two lysine-specific reagents, sodium hexadecyl 4-[3H]formylphenyl phosphate (HFPP) and sodium methyl 4-[3H]formylphenyl phosphate (MFPP), and with the photoreactive reagent 1,2-[3H]dipalmitoyl-sn-glycerol 3-[[[(4-azido-2-nitrophenyl)amino]ethyl]-phosphate] (arylazidoPE). HFPP and arylazidoPE are amphipathic molecules, inserting by their hexadecyl moieties (one and two chains, respectively) into the lipid bilayer, with the reactive groups intercalated among the phospholipid head groups. MFPP is the water-soluble analogue of HFPP. The labeling patterns of ECF1F0 obtained with HFPP and arylazidoPE were very similar; in both cases the a and b subunits of the F0 part were the most heavily labeled polypeptides of the complex. Models of subunit a, arranged in six transmembrane helices, place most of the lysines in the head-group region, available for reaction with HFPP. Subunits alpha and beta of the ECF1 part were very poorly labeled in comparison to the a and b subunits, together incorporating only 4% as much HFPP and 7.5% as much arylazidoPE as the two F0 subunits together on a protein mass basis. Trypsin cleavage studies localized any labeling of the alpha subunit by arylazidoPE to the N-terminal 15 residues of this polypeptide. When MFPP was used, the alpha and beta subunits were very much more reacted than the F0 subunits. This implies that most of the mass of the alpha and beta subunits in ECF1F0 is above the membrane and not in contact with the bilayer surface.(ABSTRACT TRUNCATED AT 250 WORDS)     

A pH-induced increase in hydrophobicity as a possible step in the penetration of colicin E3 through bacterial membranes

Exposure to low pH triggers an increase in the hydrophobicity of the colicin E3 molecule. Using a [3H] Triton X-100 binding assay we have shown that the amount of detergent (at supramicellar concentrations) associated with colicin E3 increased dramatically at pH 3.8 and below. Interaction of colicin E3 with asolectin vesicles was monitored by following its cross-linking with two different photoactivatable radioactive phospholipid analogues. At neutral pH colicin E3 was cross-linked with the phospholipid probing the membrane surface whereas at pH 4.5 and below, the bacteriocin reacted with the phospholipid probing the hydrophobic core of the bilayer. With the use of phase partitioning of proteins in Triton X-114 it was shown that at acidic pH whole colicin E3 and its immunity protein segregated in the detergent phase. After trypsin digestion of the colicin-immunity complex, the N-terminal portion of E3 (T1) and the immunity partitioned in the detergent phase at low pH. In contrast, the enzymic domain of the colicin (T2) remained in the aqueous phase and was recovered in a highly active form as a consequence of its dissociation from the immunity protein. These results are discussed in relation to the mechanism of entry of colicin E3 into bacterial cells.     

Mapping the lipid-exposed regions in the Torpedo californica nicotinic acetylcholine receptor.

To identify regions of the Torpedo nicotinic acetylcholine receptor (AchR) interacting with membrane lipid, we have used 1-azidopyrene (1-AP) as a fluorescent, photoactivatable hydrophobic probe. For AchR-rich membranes equilibrated with 1-AP, irradiation at 365 nm resulted in covalent incorporation in all four AchR subunits with each of the subunits incorporating approximately equal amounts of label. To identify the regions of the AchR subunits that incorporated 1-AP, subunits were digested with Staphylococcus aureus V8 protease and trypsin, and the resulting fragments were separated by SDS-PAGE followed by reverse-phase high-performance liquid chromatography. N-terminal sequence analysis identified the hydrophobic segments M1, M3, and M4 within each subunit as containing the sites of labeling. The labeling pattern of 1-AP in the alpha-subunit was compared with that of another hydrophobic photoactivatable probe, 3-trifluoromethyl-3-(m-[125I]iodophenyl)diazirine ([125I]TID). The nonspecific component of [125I]TID labeling [White, B., Howard, S., Cohen, S. G., & Cohen, J.B. (1991) J. Biol. Chem. 266, 21595-21607] was restricted to the same regions as those labeled by 1-AP. The [125I]TID residues labeled in the hydrophobic segment M4 were identified as Cys-412, Met-415, Cys-418, Thr-422, and Val-425. The periodicity and distribution of labeled residues establish that the M4 region is alpha-helical in nature and indicate that M4 presents a broad face to membrane lipid.     

Membrane interaction of Escherichia coli hemolysin: flotation and insertion-dependent labeling by phospholipid vesicles

The 1,024-amino-acid acylated hemolysin of Escherichia coli subverts host cell functions and causes cell lysis. Both activities require insertion of the toxin into target mammalian cell membranes. To identify directly the principal toxin sequences dictating membrane binding and insertion, we assayed the lipid bilayer interaction of native protoxin, stably active toxin, and recombinant peptides. Binding was assessed by flotation of protein-liposome mixtures through density gradients, and insertion was assessed by labeling with a photoactivatable probe incorporated into the target lipid bilayer. Both the active acylated hemolysin and the inactive unacylated protoxin were able to bind and also insert. Ca(2+) binding, which is required for toxin activity, did not influence the in vitro interaction with liposomes. Three overlapping large peptides were expressed separately. A C-terminal peptide including residues 601 to 1024 did not interact in either assay. An internal peptide spanning residues 496 to 831, including the two acylation sites, bound to phospholipid vesicles and showed a low level of insertion-dependent labeling. In vitro acylation had no effect on the bilayer interaction of either this peptide or the full-length protoxin. An N-terminal peptide comprising residues 1 to 520 also bound to phospholipid vesicles and showed strong insertion-dependent labeling, ca. 5- to 25-fold that of the internal peptide. Generation of five smaller peptides from the N-terminal region identified the principal determinant of lipid insertion as the hydrophobic sequence encompassing residues 177 to 411, which is conserved among hemolysin-related toxins.     

Membrane topology of light-harvesting protein B870-alpha of Rhodospirillum rubrum G-9+. Amino acid residues in contact with the lipid bilayer as inferred from labeling with photogenerated carbenes

The amino acid residues of the light-harvesting protein B870-alpha of Rhodospirillum rubrum G-9+ that in the chromatophore membranes are in contact with the lipid phase were identified by hydrophobic photolabeling. Three reagents have been used which all contained the trifluoromethyldiazirinylphenyl group as a photo-sensitive precursor of a carbene but which otherwise differed in shape, molecular structure, and in the way they interact with membranes. 3-Trifluoromethyl-3-(m-[125I]iodophenyl)diazirine is a highly lipid-soluble compound, 11-[4-[(trifluoromethyl)diazirinyl]-phenyl]-[10-3H] 9-oxaundecanoic acid is an analogue of a fatty acid, and 1-palmitoyl-2-[11-[(trifluoromethyl)diaziri-nyl] phenyl]-[10-3H]9-oxaundecanoyl]-sn-glycero-3-phosphorylcholine one of a lecithin. Following labeling of chromatophores with these reagents, B870-alpha was isolated and subjected to (solid phase) Edman degradations in order to determine individual amino acid residues labeled. The main features of these results are as follows. 1) Labeling occurred both within the N-terminal segment (residues 1-8) and within the predominantly hydrophobic transmembrane stretch (residues 14-33). 2) Label distribution patterns within segments are indicative of helical structures to which the reagents had access to one face only of the cylindrical envelopes. 3) With regard to the transmembrane segment, the label distribution patterns were similar for all reagents whereas striking differences were noticed within the N-terminal portion. The labeling patterns are consistent with previous models proposing tight association of the transmembrane helix with that of the B870-beta chain. They also suggest that the N-terminal segment forms an amphipathic helix which interacts with the water-lipid interface of the membrane.     

A PEST-like sequence in the N-terminal cytoplasmic domain of Saccharomyces maltose permease is required for glucose-induced proteolysis and rapid inactivation of transport activity

Maltose permease is required for maltose transport into Saccharomyces cells. Glucose addition to maltose-fermenting cells causes selective delivery of this integral plasma membrane protein to the yeast vacuole via endocytosis for degradation by resident proteases. This glucose-induced degradation is independent of the proteasome but requires ubiquitin and certain ubiquitin conjugating enzymes. We used mutation analysis to identify target sequences in Mal61/HA maltose permease involved in its selective glucose-induced degradation. A nonsense mutation was introduced at codon 581, creating a truncated functional maltose permease. Additional missense mutations were introduced into the mal61/HA-581NS allele, altering potential phosphorylation and ubiquitination sites. No significant effect was seen on the rate of glucose-induced degradation of these mutant proteins. Deletion mutations were constructed, removing residues 2-30, 31-60, 61-90, and 49-78 of the N-terminal cytoplasmic domain, as well as a missense mutation of a dileucine motif. Results indicate that the proline-, glutamate-, aspartate-, serine-, and threonine-rich (PEST) sequence found in the N-terminal cytoplasmic domain, particularly residues 49-78, is required for glucose-induced degradation of Mal61/HAp and for the rapid glucose-induced inactivation of maltose transport activity. The decreased rate of glucose-induced degradation correlates with a decrease in the level of glucose-induced ubiquitination of the DeltaPEST mutant permease. In addition, newly synthesized mutant permease proteins lacking residues 49-78 or carrying an alteration in the dileucine motif, residues 69 and 70, are resistant to glucose-induced inactivation of maltose transport activity. This N-terminal PEST-like sequence is the target of both the Rgt2p-dependent and the Glc7p-Reg1p-dependent glucose signaling pathways.     

Formaldehyde and photoactivatable cross-linking of the periplasmic binding protein to a membrane component of the histidine transport system of Salmonella typhimurium

The histidine permease of Salmonella typhimurium consists of four protein components, one located in the periplasm and three in the cytoplasmic membrane. Genetic evidence indicated that the periplasmic protein interacts with the membrane proteins during transport. We have utilized two different methods to demonstrate that the periplasmic protein cross-links specifically to one of the membrane components, the Q protein. Formaldehyde, a water-soluble permeant molecule was used in vivo. Sulfosuccinimidyl 6-(4'-azido-2'-nitrophenylamino)hexanoate, a photoactivatable cross-linking reagent, was used in vitro in a reconstituted membrane vesicle system. Furthermore, we show that a mutant periplasmic protein, capable of binding substrate but not transporting it, is defective in cross-linking to the membrane protein, indicating this interaction to be a crucial step in the mechanism of transport.     

Localization of the strychnine binding site on the 48-kilodalton subunit of the glycine receptor

Amino acid residues that participate in antagonist binding to the strychnine-sensitive glycine receptor (GlyR) have been identified by selectively modifying functional groups with chemical reagents. Moreover, a region directly involved with strychnine binding has been localized in the 48-kDa subunit of this receptor by covalent labeling and proteolytic mapping. Modification of tyrosyl or arginyl residues promotes a marked decrease of specific [3H]strychnine binding either to rat spinal cord plasma membranes or to the purified GlyR incorporated into phospholipid vesicles. Occupancy of the receptor by strychnine, but not by glycine, completely protects from the inhibition caused by chemical reagents. Furthermore, these tyrosine- or arginine-specific reagents decrease the number of binding sites (Bmax) for [3H]strychnine binding without affecting the affinity for the ligand (Kd). These observations strongly suggest that such residues are present at, or very close to, the antagonist binding site. In order to localize the strychnine binding domain within the GlyR, purified and reconstituted receptor preparations were photoaffinity labeled with [3H]strychnine. The radiolabeled 48-kDa subunit was then digested with specific chemical proteolytic reagents, and the peptides containing the covalently bound radioligand were identified by fluorography after gel electrophoresis. N-Chlorosuccinimide treatment of [3H]strychnine-labeled 48K polypeptide yielded a single labeled peptide of Mr approximately 7300, and cyanogen bromide gave a labeled peptide of Mr 6200.(ABSTRACT TRUNCATED AT 250 WORDS)     

Rat brain hexokinase: the hydrophobic N-terminus of the mitochondrially bound enzyme is inserted in the lipid bilayer

Mitochondrially bound rat brain hexokinase was labeled with the photoactivatable reagent, 3-(trifluoromethyl)-3-(m-[125I]iodophenyl)diazirine. This highly hydrophobic reagent is strongly partitioned into the hydrophobic environment of the membrane core, and thus selectively labels segments of a protein that penetrate this region of the membrane. Labeling of hexokinase was shown to be restricted to the N-terminal region of the molecule. Approximately 80% of the radiolabel was removed by treatment of the enzyme with chymotrypsin, which preferentially cleaves a hydrophobic 9-residue sequence at the extreme N-terminus of the enzyme, and it is considered likely that the remaining 20% was associated with two additional hydrophobic residues, immediately adjacent to this segment but not susceptible to cleavage by chymotrypsin. Labeling of the enzyme was shown to be dependent on maintenance of the association with the membrane. These results are consistent with a model in which binding of hexokinase involves insertion of an 11-residue hydrophobic N-terminal "tail," possibly existing in alpha-helical secondary structure, into the hydrophobic core of the membrane.     

Interaction of the cytoskeletal component vinculin with bilayer structures analyzed with a photoactivatable phospholipid

The cytoskeletal component vinculin has been proposed to act as an actin-plasma membrane linker. In order to demonstrate a possible direct interaction of vinculin with bilayers, photolabeling with a phospholipid generating a highly reactive carbene was used. This phosphatidylcholine analogue (1-palmitoyl-2-[10-[4-[(trifluoromethyl)diazirinyl]phenyl]-[3H] 9-oxaundecanoyl]-sn-glycero-3-phosphocholine), with the photoactivatable diazirine group on its apolar portion, has been shown to label selectively membrane-embedded domains of membrane proteins. Vinculin is significantly labeled upon incubation and photolysis with liposomes containing trace amounts of this photoactivatable phospholipid, but only when the liposomes also contain acidic phospholipids. Labeling of vinculin is markedly increased (5-17-fold) by all acidic phospholipids tested so far (30%, w/w), compared to labeling in neutral phospholipids. Labeling is high at low ionic strength, but significant vinculin labeling can still be observed at physiological salt concentrations and acidic phospholipid content of the membrane. Our results provide evidence that vinculin inserts into the hydrophobic part of the bilayer by interacting with acidic phospholipids. A similar interaction may be of importance in vivo.     

Analysis of the membrane-interacting domain of the sea urchin sperm adhesive protein bindin

We have investigated the domain of the bindin polypeptide that selectively associates with gel-phase phospholipid vesicles. We found that small trypsin fragments of bindin retain the ability to selectively associate with gel-phase vesicles. The primary amino acid sequence of bindin suggests that these peptides are derived from the central portion of the polypeptide between residues 77 and 126, which is the most hydrophobic region of bindin. We have also employed 3-(trifluoromethyl)-3-(m-[125I]iodophenyl)diazirine (TID) and novel, radioiodinated, photoactivatable derivatives of the polar head group of phosphatidylethanolamine (ASD-PE and ASA-PE) to identify membrane-associated polypeptide segments after the transfer of radiolabel from the probe to the bindin polypeptide. After photolysis, bindin was selectively labeled only from probes incorporated in gel-phase vesicles. The labeling of bindin was much more efficient from the head group probes ASA-PE and ASD-PE (8 and 2% of the total label, respectively) in comparison to the hydrophobic probe TID (less than 0.02% of the total label), suggesting that bindin is localized within the polar part of the bilayer. Protease mapping experiments with V8 protease, trypsin, and endoprotease Lys-C suggest that some of the probe label is distributed along the amino-terminal portion of bindin between residues 1 and 76 and the rest of the label is restricted to the segments between residues 77 and 126 which also selectively bind to gel-phase vesicles. The carboxyl-terminal portion of bindin between residues 127 and 236 is not labeled.     

Reconstitution of an active lactose carrier in vivo by simultaneous synthesis of two complementary protein fragments.

Escherichia coli lactose permease mediates the proton-driven translocation of galactosides across the cytoplasmic membrane. To define regions important for membrane insertion as well as for biological function, we constructed plasmids encoding different portions of the lactose carrier. Among several lacY deletions, two were obtained that encoded mutant proteins with complementary amino acid sequences. The truncated polypeptide Y71/1 (amino acid residues 1 to 71) comprises the first two alpha-helices predicted for the intact protein, and polypeptide delta Y4-69 carries an internal deletion of this region. Regulated coexpression of these lacY-DNA segments governed by separate but identical lacOP control regions resulted in functional complementation with the following characteristics. (i) Simultaneous synthesis of both incomplete proteins restored transport activity in transport-negative cells, measured as accumulation of [14C]lactose. (ii) Under complementing conditions, but not in the absence of the smaller N-terminal protein, specific radiolabeling of the larger polypeptide by N-ethylmaleimide was prevented by substrate. (iii) The presence of the complementing N-terminal polypeptide was also required for the detection of the larger C-terminal protein by antibodies directed against the C terminus of lactose permease, indicating a stabilizing effect contributed by the smaller N-terminal fragment. Thus, coexpression of lacY mutant genes encoding two nonoverlapping portions of the lactose carrier resulted in reconstitution of a two-subunit protein in the cytoplasmic membrane exhibiting biological properties of intact lactose permease.     

Truncated forms of Escherichia coli lactose permease: models for study of biosynthesis and membrane insertion.

Using in vitro DNA manipulations, we constructed different lacY alleles encoding mutant proteins of the Escherichia coli lactose carrier. With respect to structural models developed for lactose permease, the truncated polypeptides represent model systems containing approximately one, two, four, and five of the N-terminal membrane-spanning alpha-helices. In addition, a protein carrying a deletion of predicted helices 3 and 4 was obtained. The different proteins were radiolabeled in plasmid-bearing E. coli minicells and were found to be stably integrated into the lipid bilayer. The truncated polypeptides of 50, 71, 143, and 174 N-terminal amino acid residues resembled the wild-type protein in their solubilization characteristics, whereas the mutant protein carrying an internal deletion of amino acid residues 72 to 142 of the lactose carrier behaved differently. Minicell membrane vesicles containing truncated proteins comprising amino acid residues 1 to 143 or 1 to 174 were subjected to limited proteolysis. Upon digestion with proteases of different specificities, the same characteristic fragment that was also produced from the membrane-associated wild-type protein was found to accumulate under these conditions. It has previously been shown to contain the intact N terminus of lactose permease. This supports the idea of an independent folding and membrane insertion of this segment even in the absence of the C-terminal part of the molecule. The results suggest that the N-terminal region of the lactose permease represents a well-defined structural domain.     

Photoactivatable Reagents Based on Aryl(trifluoromethyl)diazirines: Synthesis and Application for Studying Nucleic Acid–Protein Interactions

Recent data on the synthesis of photoactivatable derivatives of nucleic acids and proteins on the basis of aryl(trifluoromethyl)diazirines—analogs of nucleosides, nucleotides, oligonucleotides, as well as amino acids and peptides—are reviewed. The synthesis of bi- and polyfunctional photoactivatable reagents, including those containing a cleavable function, designed for postsynthetic modification of biopolymers is described. Data are given on the use of the photoactivatable derivatives for studying nucleic acid–protein interactions by the method of photoaffinity labeling. Special consideration is paid to the results obtained by the authors" team in cooperation with other researchers as well as graduate students of the Chemistry of Natural Products Chair, Chemical Faculty, Moscow State University and destined to solve various scientific tasks in the domain of nucleic acid–protein recognition with the use of photoaffinity crosslinking.     

Labeling of individual amino acid residues in the membrane-embedded F0 part of the F1 F0 ATP synthase from Neurospora crassa. Influence of oligomycin and dicyclohexylcarbodiimide

Three F0 subunits and the F1 subunit beta of the ATP synthase from Neurospora crassa were labeled with the lipophilic photoactivatable reagent 3-(trifluoromethyl)-3-(m-[125I]iodophenyl)diazirine ([125I]TID). In the proteolipid subunit which was the most heavily labeled polypeptide labeling was confined to five residues at the NH2-terminus and five residues at the C-terminus of the protein. Labeling occurred at similar positions compared with the homologous protein (subunit c) in the ATP synthase from Escherichia coli, indicating a similar structure of the proteolipid subunits in their respective organisms. The inhibitors oligomycin and dicyclohexylcarbodiimide did not change the pattern of accessible surface residues in the proteolipid, suggesting that neither inhibitor induces gross conformational changes. However, in the presence of oligomycin, the extent of labeling in some residues was reduced. Apparently, these residues provide part of the binding site for the inhibitor. After reaction with dicyclohexylcarbodiimide an additional labeled amino acid was found at position 65 corresponding to the invariant carbodiimide-binding glutamic acid. These results and previous observations indicate that the carboxyl side chain of Glu-65 is located at the protein-lipid interphase. The idea is discussed that proton translocation occurs at the interphase between different types if F0 subunits. Dicyclohexylcarbodiimide or oligomycin might disturb this essential interaction between the F0 subunits.