Characterization of loops of the yeast mitochondrial ADP/ATP carrier facing the cytosol by site-directed mutagenesis

To characterize structural features of the regions of the yeast type 2 ADP/ATP carrier (yAAC2) facing the cytosol, we prepared its Cys-less mutant, in which all four cysteine residues were replaced by alanine residues. The Cys-less mutant functioned like native yAAC2, showing that the cysteine residues are not essential. We then prepared cysteine mutants by substituting Ser(21) in the putative N-terminal region, Ala(124) and Ser(222) in the first and second loops facing cytosol, respectively, and Leu(312) in the C-terminal region of the Cys-less mutant for cysteine and examined the labeling of the substituted cysteine residues of the mutants with the membrane-impermeable SH reagent eosin-5-maleimide (EMA) from the cytosol. EMA labeled all the mutants, showing that all regions containing mutated residues faced the cytosolic side. The effects of transport inhibitors on EMA labeling were also examined. From the results, the location and conformation of the region around mutated residues were discussed.     

The structure of the second cytosolic loop of the yeast mitochondrial ADP/ATP carrier AAC2 is dependent on the conformational state

To detect structural changes in the second cytosolic loop of the mitochondrial ADP/ATP carrier of Saccharomyces cerevisiae AAC2, we prepared 20 single cysteine mutants by replacing each amino acid in the S213 to L232 region. All single cysteine mutants were fully functional, because they could restore growth on glycerol of a yeast strain lacking functional ADP/ATP carriers. First, these single-Cys mutants were treated with carboxyatractyloside to lock the carrier in the cytosolic state or with bongkrekic acid to generate the matrix state, and then with the membrane-impermeable SH reagent eosin-5-maleimide (EMA) to probe accessibility. The amino acid residues S213C, L214C, F231C and L232C were not labeled, indicating that these 4 residues must have been buried in the membrane, whereas the region between residues K215 and S230 is accessible to labeling and must, therefore, have protruded into the aqueous phase. Residue L218C showed strong resistance against EMA labeling regardless of the state of the carrier, but the reason for such behavior is unclear. On the contrary, the labeling of the residues between F227C and S230C was strongly dependent on the state of the carrier. Thus, the C-terminal region of the second cytosolic loop in AAC2 changes its environment when the carrier cycles between the matrix and cytosolic state.     

Cysteine labeling studies detect conformational changes in region 106-132 of the mitochondrial ADP/ATP carrier of Saccharomyces cerevisiae

To know the structural and functional features of the cytosolic-facing first loop (LC1) including its surrounding region of the mitochondrial ADP/ATP carrier (AAC), we prepared 27 mutants, in which each amino acid residue between residues 106 and 132 of the yeast type 2 AAC (yAAC2) was replaced by a cysteine residue. For mutant preparation, we used a Cys-less AAC mutant, in which all four intrinsic cysteine residues were substituted with alanine residues, as a template [Hatanaka, T., Kihira, Y., Shinohara, Y., Majima, E., and Terada, H. (2001) Biochem. Biophys. Res. Commun. 286, 936-942]. From the labeling intensities of the membrane-impermeable SH-reagent eosin-5-maleimide (EMA), sequence Lys(108)-Phe(127) was suggested to constitute the LC1. The N-terminal half of this region (Lys(108)-Phe(115)) was suggested to change its location from the cytosol to a region close to the membrane on conversion from the c-state to the m-state in association with disruption or unwinding of its alpha-helical structure, whereas the C-terminal half region (Gly(116)-Phe(127)) was considered to extrude essentially into the cytosol, while keeping its alpha-helical structure. Hence, the conformation of m-state LC1 is greatly different from that of c-state LC1. Possibly the LC1 changes its location between the membranous region and the cytosol during ADP/ATP transport. Lys(108) in the LC1 of the yAAC2 was found to be associated with binding of the transport substrates, and its -NH(3)(+) moiety, to be of importance for the transport function. On the basis of these results, possible roles of the conformational changes of the LC1 in the transport activity are discussed.     

Involvement of the C-terminal region of yeast proteinase B inhibitor 2 in its inhibitory action

Yeast proteinase B inhibitor 2 (YIB2), which is composed of 74 amino acid residues, is an unusual serine protease inhibitor, since it lacks disulfide bonds. To identify its reactive site for proteases, we constructed an expression system for a synthetic YIB2 gene and then attempted to change the inhibitory properties of YIB2 by amino acid replacements. The purified wild-type YIB2 inhibited the activity of subtilisin BPN', a protein homologous to yeast proteinase B, although its binding ability was not strong, and a time-dependent decrease in its inhibitory activity was observed, demonstrating that wild-type YIB2 behaves as a temporary inhibitor when subtilisin BPN' is the target protease. Since YIB2 exhibits sequence homology to the propeptide of subtilisin, which inhibits a cognate protease using its C-terminal region, we replaced the six C-termi nal residues of YIB2 with those of the propeptide of subtilisin BPN' to make the mutant YIB2m1. This mutant exhibited markedly increased inhibitory activity toward subtilisin BPN' without a time-dependent decrease in its inhibitory activity. Replacement of only the C-terminal Asn of YIB2 by Tyr, or deletion of the C-terminal Tyr of YIB2m1, inhibited subtilisin, but the ability of these mutants to bind subtilisin and their resistance to proteolytic attack were weaker than those of YIB2m1, indicating that the C-terminal residue contributes to the interaction with the protease to a greater extent than the preceding five residues and that the resistance of YIB2 to proteolyic attack is closely related to its ability to bind a protease. These results demonstrate that YIB2 is a unique protease inhibitor that involves its C-terminal region in the interaction with the protease.     

Twisting of the second transmembrane alpha-helix of the mitochondrial ADP/ATP carrier during the transition between two carrier conformational states

To investigate the structural and functional features of the second alpha-helical transmembrane segment (TM2) of the mitochondrial ADP/ATP carrier (AAC), we adopted cysteine scanning mutagenesis analysis. Single-cysteine mutations of yeast AAC were systematically introduced at residues 98-106 in TM2, and the mutants were treated with the fluorescent SH reagent eosin-5-maleimide (EMA). EMA modified different amino acid residues of alpha-helical TM2 between the two distinct carrier conformations, called the m-state and the c-state, in which the substrate recognition site faces the matrix and cytosol, respectively. When amino acids in the helix were projected on a wheel plot, these EMA-modified amino acids were observed at distinct sides of the wheel. Since the SH reagent specifically modified cysteine in the water-accessible environment, these results indicate that distinct helical surfaces of TM2 faced the water-accessible space between the two conformations, possibly as a result of twisting of this helix. In the recently reported crystal structure of bovine AAC, several amino acids faced cocrystallized carboxyatractyloside (CATR), a specific inhibitor of the carrier. These residues correspond to those modified with EMA in the yeast carrier in the c-state. Since the binding site of CATR is known to overlap that of the transport substrate, the water-accessible space was thought to be a substrate transport pathway, and hence, the observed twisting of TM2 between the m-state and the c-state may be involved in the process of substrate translocation. On the basis of the results, the roles of TM2 in the transport function of AAC were discussed.     

Escherichia coli methionyl-tRNA formyltransferase: role of amino acids conserved in the linker region and in the C-terminal domain on the specific recognition of the initiator tRNA

The formylation of initiator methionyl-tRNA by methionyl-tRNA formyltransferase (MTF) is important for the initiation of protein synthesis in eubacteria. We are studying the molecular mechanisms of recognition of the initiator tRNA by Escherichia coli MTF. MTF from eubacteria contains an approximately 100-amino acid C-terminal extension that is not found in the E. coli glycinamide ribonucleotide formyltransferase, which, like MTF, use N(10)-formyltetrahydrofolate as a formyl group donor. This C-terminal extension, which forms a distinct structural domain, is attached to the N-terminal domain through a linker region. Here, we describe the effect of (i) substitution mutations on some nineteen basic, aromatic and other conserved amino acids in the linker region and in the C-terminal domain of MTF and (ii) deletion mutations from the C-terminus on enzyme activity. We show that the positive charge on two of the lysine residues in the linker region leading to the C-terminal domain are important for enzyme activity. Mutation of some of the basic amino acids in the C-terminal domain to alanine has mostly small effects on the kinetic parameters, whereas mutation to glutamic acid has large effects. However, the deletion of 18, 20, or 80 amino acids from the C-terminus has very large effects on enzyme activity. Overall, our results support the notion that the basic amino acid residues in the C-terminal domain provide a positively charged channel that is used for the nonspecific binding of tRNA, whereas some of the amino acids in the linker region play an important role in activity of MTF.     

C-terminal region regulates the functional expression of human noradrenaline transporter splice variants

The NET [noradrenaline (norepinephrine) transporter], an Na+/Cl--dependent neurotransmitter transporter, has several isoforms produced by alternative splicing in the C-terminal region, each differing in expression and function. We characterized the two major isoforms of human NET, hNET1, which has seven C-terminal amino acids encoded by exon 15, and hNET2, which has 18 amino acids encoded by exon 16, by site-directed mutagenesis in combination with NE (noradrenaline) uptake assays and cell surface biotinylation. Mutants lacking one third or more of the 24 amino acids encoded by exon 14 exhibited neither cell surface expression nor NE uptake activity, with the exception of the mutant lacking the last eight amino acids of hNET2, whose expression and uptake resembled that of the WT (wild-type). A triple alanine replacement of a candidate motif (ENE) in this region mimicked the influences of the truncation. Deletion of either the last three or another four amino acids of the C-terminus encoded by exon 15 in hNET1 reduced the cell surface expression and NE uptake, whereas deletion of all seven residues reduced the transport activity but did not affect the cell surface expression. Replacement of RRR, an endoplasmic reticulum retention motif, by alanine residues in the C-terminus of hNET2 resulted in a similar expression and function compared with the WT, while partly recovering the effects of the mutation of ENE. These findings suggest that in addition to the function of the C-terminus, the common proximal region encoded by exon 14 regulates the functional expression of splice variants, such as hNET1 and hNET2.     

Role of paired basic residues of protein C-termini in phospholipid binding

It is a well known phenomenon that the occurrence of several distinct amino acids at the C-terminus of proteins is non-random. We have analysed all Saccharomyces cerevisiae proteins predicted by computer databases and found lysine to be the most frequent residue both at the last (-1) and at the penultimate amino acid (-2) positions. To test the hypothesis that C-terminal basic residues efficiently bind to phospholipids we randomly expressed GST-fusion proteins from a yeast genomic library. Fifty-four different peptide fragments were found to bind phospholipids and 40% of them contained lysine/arginine residues at the (-1) or (-2) positions. One peptide showed high sequence similarity with the yeast protein Sip18p. Mutational analysis revealed that both C-terminal lysine residues of Sip18p are essential for phospholipid-binding in vitro. We assume that basic amino acid residues at the (-1) and (-2) positions in C-termini are suitable to attach the C-terminus of a given protein to membrane components such as phospholipids, thereby stabilizing the spatial structure of the protein or contributing to its subcellular localization. This mechanism could be an additional explanation for the C-terminal amino acid bias observed in proteins of several species.     

Functional expression of the tandem-repeated homodimer of the mitochondrial ADP/ATP carrier in Saccharomyces cerevisiae.

The mitochondrial ADP/ATP carrier (AAC) is believed to function as a dimer. To characterize the oligomeric state of the yeast type 2 AAC (yAAC2), we tried to express its tandem-repeated homodimer, in which the C-terminus of the first repeat was fused to the N-terminus of the second repeat, in yeast mitochondria. The tandem dimer was expressed in the mitochondrial membrane at the same level as that of yAAC2, being inserted into the mitochondrial membrane as in yAAC2, and it showed very similar transport activity to that of yAAC2. It was suggested that the two carrier molecules in a dimeric form are located in the membrane facing each other in the same orientation.     

The molecular neighborhood of subunit 8 of yeast mitochondrial F1F0-ATP synthase probed by cysteine scanning mutagenesis and chemical modification

The detailed membrane topography and neighboring polypeptides of subunit 8 in yeast mitochondrial ATP synthase have been determined using a combination of cysteine scanning mutagenesis and chemical modification. 46 single cysteine substitution mutants encompassing the length of the subunit 8 protein were constructed by site-directed mutagenesis. Expression of each cysteine variant in yeast lacking endogenous subunit 8 restored respiratory phenotype to cells and had little measurable effect on ATP hydrolase function. The exposure of each introduced cysteine residue to the aqueous environment was assessed in isolated mitochondria using the fluorescent thiol-modifying probe fluorescein 5-maleimide. The first 14 and last 13 amino acids of subunit 8 were accessible to fluorescein 5-maleimide in osmotically lysed mitochondria and are thus extrinsic to the lipid bilayer, indicating a 21-amino acid transmembrane span. The C-terminal region of subunit 8 was partially occluded by other ATP synthase subunits, especially in a small region surrounding Val-40 that was demonstrated to play an important role in maintaining the stability of the F(1)-F(0) interaction. Cross-linking using heterobifunctional reagents revealed the proximity of subunit 8 to subunits b, d, and f in the matrix and to subunits b, f, and 6 in the intermembrane space. A disulfide bridge was also formed between subunit 8(F7C) or (M10C) and residue Cys-23 of subunit 6, demonstrating a close interaction between these two hydrophobic membrane subunits and confirming the location of the N termini of each in the intermembrane space. We conclude that subunit 8 is an integral component of the stator stalk of yeast mitochondrial F(1)F(0)-ATP synthase.     

S-farnesylation and methyl esterification of C-terminal domain of yeast RAS2 protein prior to fatty acid acylation

Posttranslational processing/modification is required for membrane localization and activation of ras proteins. In the case of yeast RAS2 protein, we have reported that the process starts with the removal of the initiator methionine followed by polyisoprenylation, removal of 3 amino acid residues from the C terminus, methyl esterification, and fatty acid acylation (Fujiyama, A., and Tamanoi, F. (1990) J. Biol. Chem. 265, 3362-3368). In this study, we demonstrate that polyisoprenylation and methyl esterification of the cysteine residue in the C-terminal domain of the RAS2 protein are involved in the conversion process from precursor form to intermediate form. The polyisoprenoid moiety attached to the RAS2 protein was identified as a 15-carbon farnesyl group through two independent experiments: the release of S-farnesylcysteine with carboxypeptidase Y from the RAS2 protein, and the recovery of radioactive farnesol through methyliodide treatment of the RAS2 protein purified from yeast cells labeled with [3H]mevalonic acid. The farnesyl group attached to the RAS2 protein was detected predominantly in the C-terminal peptide, SGSGGCC, both in the intermediate and in the fatty acid acylated RAS2 protein. The C-terminal cysteine of the intermediate protein is also modified by methyl esterification in a nearly stoichiometric manner.     

Partial sequence data for the L-(+)-lactate dehydrogenase from Streptococcus cremoris US3 including the amino acid sequences around the single cysteine residue and at the N-terminus

The following amino acid sequence information has been determined for the fructose 1,6-bisphosphate-dependent lactate dehydrogenase from Streptococcus cremoris US3: the C-terminal amino acid, the N-terminal sequence of the first 20 amino acids and the sequence of a 53-residue tryptic peptide containing the only cysteine residue in the protein. The enzyme was cleaved by alkali at the cysteine residue following reaction first with 5,5'-dithiobis(2-nitrobenzoic acid) and then with K14CN. This treatment yielded two cleavage products as well as some higher polymers and some uncleaved enzyme. The radioactive cleavage product was purified and its size indicated that the cysteine residue is 80 residues from the C-terminus. Comparisons of the sequences determined for the S. cremoris enzyme with those already known for dogfish lactate dehydrogenase indicate that the two enzymes are only distantly related since the sequence homology between them is limited and of borderline statistical significance.     

Side-chain anchoring strategy for solid-phase synthesis of peptide acids with C-terminal cysteine

Many naturally occurring peptide acids, e.g., somatostatins, conotoxins, and defensins, contain a cysteine residue at the C-terminus. Furthermore, installation of C-terminal cysteine onto epitopic peptide sequences as a preliminary to conjugating such structures to carrier proteins is a valuable tactic for antibody preparation. Anchoring of N(alpha)-Fmoc, S-protected C-terminal cysteine as an ester onto the support for solid-phase peptide synthesis is known to sometimes occur in low yields, has attendant risks of racemization, and may also result in conversion to a C-terminal 3-(1-piperidinyl)alanine residue as the peptide chain grows by Fmoc chemistry. These problems are documented for several current strategies, but can be circumvented by the title anchoring strategy, which features the following: (a). conversion of the eventual C-terminal cysteine residue, with Fmoc for N(alpha)-amino protection and tert-butyl for C(alpha)-carboxyl protection, to a corresponding S-xanthenyl ((2)XAL(4)) preformed handle derivative; and (b). attachment of the resultant preformed handle to amino-containing supports. This approach uses key intermediates that are similar to previously reported Fmoc-XAL handles, and builds on earlier experience with Xan and related protection for cysteine. Implementation of this strategy is documented here with syntheses of three small model peptides, as well as the tetradecapeptide somatostatin. Anchoring occurs without racemization, and the absence of 3-(1-piperidinyl)alanine formation is inferred by retention of chains on the support throughout the cycles of Fmoc chemistry. Fully deprotected peptides, including free sulfhydryl peptides, are released from the support in excellent yield by using cocktails containing a high concentration (i.e., 80-90%) of TFA plus appropriate thiols or silanes as scavengers. High-yield release of partially protected peptides is achieved by treatment with cocktails containing a low concentration (i.e., 1-5%) of TFA. In peptides with two cysteine residues, the corresponding intramolecular disulfide-bridged peptide is obtained by either (a). oxidation, in solution, of the dithiol product released by acid; (b). simultaneous acidolytic cleavage and disulfide formation, achieved by addition of the mild oxidant DMSO to the cleavage cocktail; or (c). concomitant cleavage/cooxidation (involving a downstream S-Xan protected cysteine), using reagents such as iodine or thallium tris(trifluoroacetate) in acetic acid.     

Functional and structural role of amino acid residues in the even-numbered transmembrane alpha-helices of the bovine mitochondrial oxoglutarate carrier

The mitochondrial oxoglutarate carrier exchanges cytosolic malate for 2-oxoglutarate from the mitochondrial matrix. Orthologs of the carrier have a high degree of amino acid sequence conservation, meaning that it is impossible to identify residues important for function on the basis of this criterion alone. Therefore, each amino acid residue in the transmembrane alpha-helices H2 and H6 was replaced by a cysteine in a functional mitochondrial oxoglutarate carrier that was otherwise devoid of cysteine residues. The effects of the cysteine replacement and subsequent modification by sulfhydryl reagents on the initial uptake rate of 2-oxoglutarate were determined. The results were evaluated using a structural model of the oxoglutarate carrier. Residues involved in inter-helical and lipid bilayer interactions tolerate cysteine replacements or their modifications with little effect on transport activity. In contrast, the majority of cysteine substitutions in the aqueous cavity had a severe effect on transport activity. Residues important for function of the carrier cluster in three regions of the transporter. The first consists of residues in the [YWLF]- [KR]-G-X-X-P sequence motif, which is highly conserved in all members of the mitochondrial carrier family. The residues may fulfill a structural role as a helix breaker or a dynamic role as a hinge region for conformational changes during translocation. The second cluster of important residues can be found at the carboxy-terminal end of the even-numbered transmembrane alpha-helices at the cytoplasmic side of the carrier. Residues in H6 at the interface with H1 are the most sensitive to mutation and modification, and may be essential for folding of the carrier during biogenesis. The third cluster is at the midpoint of the membrane and consists of residues that are proposed to be involved in substrate binding.     

Characterization of a self-splicing mini-intein and its conversion into autocatalytic N- and C-terminal cleavage elements: facile production of protein building blocks for protein ligation

The determinants governing the self-catalyzed splicing and cleavage events by a mini-intein of 154 amino acids, derived from the dnaB gene of Synechocystis sp. were investigated. The residues at the splice junctions have a profound effect on splicing and peptide bond cleavage at either the N- or C-terminus of the intein. Mutation of the native Gly residue preceding the intein blocked splicing and cleavage at the N-terminal splice junction, while substitution of the intein C-terminal Asn154 resulted in the modulation of N-terminal cleavage activity. Controlled cleavage at the C-terminal splice junction involving cyclization of Asn154 was achieved by substitution of the intein N-terminal cysteine residue with alanine and mutation of the native C-extein residues. The C-terminal cleavage reaction was found to be pH-dependent, with an optimum between pH6.0 and 7.5. These findings allowed the development of single junction cleavage vectors for the facile production of proteins as well as protein building blocks with complementary reactive groups. A protein sequence was fused to either the N-terminus or C-terminus of the intein, which was fused to a chitin binding domain. The N-terminal cleavage reaction was induced by 2-mercaptoethanesulfonic acid and released the 43kDa maltose binding protein with an active C-terminal thioester. The 58kDa T4 DNA ligase possessing an N-terminal cysteine was generated by a C-terminal cleavage reaction induced by pH and temperature shifts. The intein-generated proteins were joined together through a native peptide bond. This intein-mediated protein ligation approach opens up novel routes in protein engineering.     

Identification of the carboxyl-terminal membrane-anchoring region of HPC-1/syntaxin 1A with the substituted-cysteine-accessibility method and monoclonal antibodies

HPC-1/syntaxin 1A is a member of the syntaxin family, and functions at the plasma membrane during membrane fusion as the target-soluble N-ethylmaleimide-sensitive factor-attachment protein receptor (t-SNARE). We identified the membrane-anchoring region of HPC-1/syntaxin 1A, and examined its role in anchoring of a protein to the plasma membrane. A series of mutants was created from a cysteine-less mutant of HPC-1/syntaxin 1A by substitution of each residue at the C-terminus with cysteine. The accessibility of the thiol-groups in each mutant was analyzed in vivo. The cysteine (C145) within the N-terminal cytosolic segment was labeled, but not that at C271 or C272, or any of those introduced at the C-terminus. The addition of additional residues to the C-terminal tail of HPC-1/syntaxin 1A allowed labeling by thiol-specific reagents. A monoclonal antibody directed against the C-terminal tail peptide did not react with the protein located at the plasma membrane. In addition, subcellular fractionation and immunocytochemical analyses with various transmembrane mutants showed that the C-terminal tail comprising eight amino acids is essential for anchoring of HPC-1/syntaxin 1A to the plasma membrane. These results indicate that the C-terminal membrane-anchoring region, which comprises 23 amino acids, does not traverse the lipid-bilayer and that the C-terminal tail is essential for anchoring of HPC-1/syntaxin 1A to the plasma membrane.