Structure requirement and identification of a cryptic cleavage site in the mitochondrial processing of a plant F1-ATPase beta-subunit presequence

We sought to determine the structural features involved in the processing of the mitochondrial F1-ATPase beta-subunit (F1beta) presequence (54 residues) from Nicotiana plumbaginifolia. The cleavage efficiency of F1beta presequence mutants linked to the green fluorescent protein (GFP) was evaluated in vivo in tobacco by in situ microscopy and Western blotting. The residue at position -1 (Tyr) was required to be an aromatic residue and the residue at position +2 (Thr) was found to be important for F1beta processing, while, unexpectedly, changing the distal (Arg-15) and proximal (Arg-5) arginine residues did not strongly reduce processing. In addition, results also supported the requirement of a helical structure around the cleavage position. Sequencing of the mature form of a precursor containing the first 30 residues of the F1beta presequence linked to GFP revealed the presence of a cryptic cleavage site between residues 26 and 27, which showed the features of a classical mitochondrial processing site, suggesting dual processing of the F1beta presequence. In vitro processing confirmed these data and showed that processing was sensitive to o-phenanthroline, thus catalyzed by mitochondrial processing peptidase.     

Mutagenesis and computer modelling approach to study determinants for recognition of signal peptides by the mitochondrial processing peptidase

Determinants for the recognition of a mitochondrial presequence by the mitochondrial processing peptidase (MPP) have been investigated using mutagenesis and bioinformatics approaches. All plant mitochondrial presequences with a cleavage site that was confirmed by experimental studies can be grouped into three classes. Two major classes contain an arginine residue at position -2 or -3, and the third class does not have any conserved arginines. Sequence logos revealed loosely conserved cleavage motifs for the first two classes but no significant amino acid conservation for the third class. Investigation of processing determinants for a class III precursor, Nicotiana plumbaginifolia F1beta precursor of ATP synthase (pF1beta), was performed using a series of pF1beta presequence mutants and mutant presequence peptides derived from the C-terminal portion of the presequence. Replacement of -2 Gln by Arg inhibited processing, whereas replacement of either the most proximally located -5 Arg or -15 Arg by Leu had only a low inhibitory effect. The C-terminal portion of the pF1beta presequence forms a helix-turn-helix structure. Mutations disturbing or prolonging the helical element upstream of the cleavage site inhibited processing significantly. Structural models of potato MPP and the C-terminal pF1beta presequence peptide were built by homology modelling and empirical conformational energy search methods, respectively. Molecular docking of the pF1beta presequence peptide to the MPP model suggested binding of the peptide to the negatively charged binding cleft formed by the alpha-MPP and beta-MPP subunits in close proximity to the H111XXE114H115X(116-190)E191 proteolytic active site on beta-MPP. Our results show for the first time that the amino acid at the -2 position, even if not an arginine, as well as structural properties of the C-terminal portion of the presequence are important determinants for the processing of a class III precursor by MPP.     

Recognition of mitochondrial protein precursor lacking arginine at position -2 by mitochondrial processing peptidase: processing of bovine cytochrome P450(SCC) precursor

Mitochondrial processing peptidase (MPP) specifically cleaves off the N-terminal presequence of the mitochondrial protein precursor. Previous studies demonstrated that Arg at position -2 from the cleavage site, which is found among many precursors, plays a critical role in recognition by MPP. We analyzed the structural elements of bovine cytochrome P450 side-chain cleavage enzyme precursor [pre-P450(SCC)], which has Ala at position -2, for recognition by MPP. Replacement of Ala position -2 of pre-P450(SCC) with Arg resulted in an increase in the cleavage rate. Replacement with Gly caused a reduction in the cleavage rate and the appearance of an additional cleavage site downstream of the authentic site. A pre-P450(SCC) mutant with Met at position -2 retained cleavage efficiency equal to that of the wild type. These results indicate that -2 Ala of pre-P450(SCC) is recognized by MPP as a determinant for precise cleavage, and that the amino acid at -2 is required to have a straight methylene chain for interaction with the S(2) site. The preference for distal basic residues, a hydrophobic residue at +1, and hydroxyl residues at +2 and +3, was almost the same as those of the precursors with Arg at -2, indicating that the recognition mechanism of pre-P450(SCC) by MPP is essentially the same as that of the precursors with Arg at position -2.     

A proposed common structure of substrates bound to mitochondrial processing peptidase

Mitochondrial processing peptidase (MPP), a metalloendopeptidase consisting of alpha- and beta-subunits, specifically cleaves off the N-terminal presequence of the mitochondrial protein precursor. Structural information of the substrate bound to MPP was obtained using fluorescence resonance energy transfer (FRET) measurement. A series of the peptide substrates, which have distal arginine residues required for effective cleavage at positions -7, -10, -14, and -17 from the cleavage site, were synthesized and covalently labeled with 7-diethyl aminocoumarin-3-carboxylic acid at the N termini and N,N'-dimethyl-N-(iodoacetyl)-N'-(7-nitrobenz-2-oxa-1,3-diazol-4-yl)ethylenediamine (IANBD) at position +4, as fluorescent donor and acceptor, respectively. When the peptides were bound to MPP, substantially the same distances were obtained between the two probes, irrespective of the length of the intervening sequence between the two probes. When 7-diethylamino-3-(4'-maleimidyl phenyl)-4-methyl coumarin was introduced into a single cysteine residue in beta-MPP as a donor and IANBD was coupled either at the N terminus or the +4 position of the peptide substrate as an acceptor, intermolecular FRET measurements also demonstrated that distances of the donor-acceptor pair were essentially the same among the peptides with different lengths of intervening sequences. The results indicate that the N-terminal portion and the portion around the cleavage site of the presequence interact with specific sites in the MPP molecule, irrespective of the length of the intervening sequence between the two portions, suggesting the structure of the intervening sequence is flexible when bound to the MPP.     

Eukaryotic precursor proteins are processed by Escherichia coli outer membrane protein OmpP.

A new specific endopeptidase that cleaves eukaryotic precursor proteins has been found in Escherichia coli K but not in E. coli B strains. After purification, protein sequencing and Western blotting, the endopeptidase was shown to be identical with E. coli outer membrane protein OmpP [Kaufmann, A., Stierhof, Y.-D. & Henning, U. (1994) J. Bacteriol. 176, 359-367]. Further characterization of enzymatic properties of the new peptidase was performed. Comparison of the cleavage specificities of the newly found endopeptidase and that of rat mitochondrial processing peptidase (MPP) showed that patterns of proteolytic cleavage on the investigated precursor proteins by both enzymes are similar. By using three mitochondrial precursor proteins, the specificity assigned to OmpP previously, a cleavage position between two basic amino-acid residues, was extended to a three amino-acid recognition sequence. Positions +1 to +3 of this extended recognition site consist of an amino-acid residue with a small aliphatic side chain such as alanine or serine, a large hydrophobic residue such as leucine or valine followed by an arginine residue. Additionally, structural motifs of the substrate seem to be required for OmpP cleavage.     

Defective propeptide processing of blood clotting factor IX caused by mutation of arginine to glutamine at position -4

Blood clotting factor IX is synthesized as a precursor polypeptide that would be expected to be proteolytically cleaved in at least two positions during maturation to remove the prepeptide and propeptide regions. We show that a point mutation causing hemophilia B changes the amino acid at position -4 in the propeptide region of factor IX from an arginine to a glutamine, which results in the expression of a stable longer protein with 18 additional amino acids of the N-terminal propeptide region still attached. This suggests that in the normal maturation of factor IX the signal peptidase cleaves the peptide bond between amino acid residues -18 and -19, generating an unstable profactor IX intermediate. Further proteolytic processing to the mature factor IX depends on the arginine residue at -4. The significance of the homologous arginine residue in other processed proteins is discussed.     

Crystal structures of mitochondrial processing peptidase reveal the mode for specific cleavage of import signal sequences

BACKGROUND: Mitochondrial processing peptidase (MPP) is a metalloendopeptidase that cleaves the N-terminal signal sequences of nuclear-encoded proteins targeted for transport from the cytosol to the mitochondria. Mitochondrial signal sequences vary in length and sequence, but each is cleaved at a single specific site by MPP. The cleavage sites typically contain an arginine at position -2 (in the N-terminal portion) from the scissile peptide bond in addition to other distal basic residues, and an aromatic residue at position +1. Mitochondrial import machinery recognizes amphiphilic helical conformations in signal sequences. However, it is unclear how MPP specifically recognizes diverse presequence substrates. RESULTS: The crystal structures of recombinant yeast MPP and a cleavage-deficient mutant of MPP complexed with synthetic signal peptides have been determined. MPP is a heterodimer; its alpha and beta subunits are homologous to the core II and core I proteins, respectively, of the ubiquinol-cytochrome c oxidoreductase complex. Crystal structures of two different synthetic substrate peptides cocrystallized with the mutant MPP each show the peptide bound in an extended conformation at the active site. Recognition sites for the arginine at position -2 and the +1 aromatic residue are observed. CONCLUSIONS: MPP bound two mitochondrial import presequence peptides in extended conformations in a large polar cavity. The presequence conformations differ from the amphiphilic helical conformation recognized by mitochondrial import components. Our findings suggest that the presequences adopt context-dependent conformations through mitochondrial import and processing, helical for recognition by mitochondrial import machinery and extended for cleavage by the main processing component.     

Determination of the cleavage site of the presequence by mitochondrial processing peptidase on the substrate binding scaffold and the multiple subsites inside a molecular cavity

Mitochondrial processing peptidase (MPP) recognizes a large variety of basic presequences of mitochondrial preproteins and cleaves the single site, often including arginine, at the -2 position (P(2)). To elucidate the recognition and specific processing of the preproteins by MPP, we mutated to alanines at acidic residues conserved in a large internal cavity formed by the MPP subunits, alpha-MPP and beta-MPP, and analyzed the processing efficiencies for various preproteins. We report here that alanine mutations at a subsite in rat beta-MPP interacting with the P(2) arginine cause a shift in the processing site to the C-terminal side of the preprotein. Because of reduced interactions with the P(2) arginine, the mutated enzymes recognize not only the N-terminal authentic cleavage site with P(2) arginine but also the potential C-terminal cleavage site without a P(2) arginine. In fact, it competitively cleaves the two sites of the preprotein. Moreover, the acidified site of alpha-MPP, which binds to the distal basic site in the long presequence, recognized the authentic P(2) arginine as the distal site in compensation for ionic interaction at the proximal site in the mutant MPP. Thus, MPP seems to scan the presequence from beta- to alpha-MPP on the substrate binding scaffold inside the MPP cavity and finds the distal and P(2) arginines on the multiple subsites on both MPP subunits. A possible mechanism for substrate recognition and cleavage is discussed here based on the notable character of a subsite-deficient mutant of MPP in which the substrate specificity is altered.     

Processing of the dual targeted precursor protein of glutathione reductase in mitochondria and chloroplasts

Pea glutathione reductase (GR) is dually targeted to mitochondria and chloroplasts by means of an N-terminal signal peptide of 60 amino acid residues. After import, the signal peptide is cleaved off by the mitochondrial processing peptidase (MPP) in mitochondria and by the stromal processing peptidase (SPP) in chloroplasts. Here, we have investigated determinants for processing of the dual targeting signal peptide of GR by MPP and SPP to examine if there is separate or universal information recognised by both processing peptidases. Removal of 30 N-terminal amino acid residues of the signal peptide (GRDelta1-30) greatly stimulated processing activity by both MPP and SPP, whereas constructs with a deletion of an additional ten amino acid residues (GRDelta1-40) and deletion of 22 amino acid residues in the middle of the GR signal sequence (GRDelta30-52) could be cleaved by SPP but not by MPP. Numerous single mutations of amino acid residues in proximity of the cleavage site did not affect processing by SPP, whereas mutations within two amino acid residues on either side of the processing site had inhibitory effect on processing by MPP with a nearly complete inhibition for mutations at position -1. Mutation of positively charged residues in the C-terminal half of the GR targeting peptide inhibited processing by MPP but not by SPP. An inhibitory effect on SPP was detected only when double and triple mutations were introduced upstream of the cleavage site. These results indicate that: (i) recognition of processing site on a dual targeted GR precursor differs between MPP and SPP; (ii) the GR targeting signal has similar determinants for processing by MPP as signals targeting only to mitochondria; and (iii) processing by SPP shows a low level of sensitivity to single mutations on targeting peptide and likely involves recognition of the physiochemical properties of the sequence in the vicinity of cleavage rather than a requirement for specific amino acid residues.     

Analysis of N-terminal processing of hepatitis C virus nonstructural protein 2.

We determined the partial amino (N)-terminal amino acid sequence of hepatitis C virus p21 (nonstructural protein 2 [NS2]). Cleavage at the p21 (NS2) N terminus depended on the presence of microsomal membranes. The amino-terminal position of p21 (NS2) was assigned to amino acid 810 of the hepatitis C virus strain IIJ precursor polyprotein. Mutation of the alanine residue at position P1 of the putative cleavage site inhibited membrane-dependent processing. This alteration in processing together with the fact that hydrophobic amino acid residues are clustered upstream of the putative cleavage site suggested the involvement of a signal peptidase(s) in the cleavage. Furthermore, mutation analysis of this possible cleavage site revealed the presence of another microsome membrane-dependent cleavage site upstream of the N terminus of p21 (NS2).     

Effect of amino acid substitutions at the signal peptide cleavage site of the Escherichia coli major outer membrane lipoprotein

The requirement for the glycine residue at the COOH terminus of the signal peptide of the precursor of the major Escherichia coli outer membrane lipoprotein was examined. Using oligonucleotide-directed site-specific mutagenesis, this residue was replaced by residues of increasing side chain size. Substitution by serine had no effect on the modification or processing of the prolipoprotein. Substitution by valine or leucine resulted in the accumulation of the unmodified precursor, whereas threonine substitution resulted in slow lipid modification and no detectable processing of the lipid modified precursor. The results indicate that serine is the upper limit on size for the residue at the cleavage site. Larger residues at this position prevent the action of both the glyceride transferase and signal peptidase II enzymes, indicating that the cleavage site residue plays a role in events prior to proteolytic cleavage. The upper limit on size of the cleavage site residue is similar to that found for exported proteins cleaved by signal peptidase I, as well as eucaryotic exported proteins. The possibility that the cleavage site residue may have a role other than active site recognition by the signal peptidase is discussed.     

Glu(191) and Asp(195) in rat mitochondrial processing peptidase beta subunit are involved in effective cleavage of precursor protein through interaction with the proximal arginine

Mitochondrial processing peptidase (MPP), consisting of alpha and beta subunits, recognizes a large variety of N-terminal extension peptides of mitochondrial precursor proteins, and generally cleaves a single site of the peptide including arginine at the -2 position (P(2)). We obtained evidence that Glu(191) and Asp(195) of rat beta subunit interact with P(2) arginine of precursor protein through ionic and hydrogen bonds, respectively, using recombinant MPP. Mutation to alanines at Glu(191) and Asp(195) reduced processing activity toward precursors with P(2) arginine, but resulted in no loss of activity toward P(2) alanine precursors. Charge-complementary mutation demonstrated that MPP variants with beta Arg(191) exhibited compensatory processing activity for the precursor with acidic residue at the P(2) position. Thus, Glu(191) and Asp(195) are substrate-binding sites required for cleavage of extension peptides through interaction with P(2) arginine.     

Targeting of pre-ornithine transcarbamylase to mitochondria: definition of critical regions and residues in the leader peptide

The cytoplasmically synthesized precursor of the mitochondrial matrix enzyme, ornithine transcarbamylase (OTC), is directed to mitochondria by its amino-terminal leader peptide. To define the critical residues and/or regions in the OTC leader peptide, we have synthesized OTC precursors with alterations in the leader portion. Analysis of deletions reveals that the middle portion of the 32 residue leader peptide is absolutely required for both mitochondrial uptake and proteolytic processing, whereas NH2-terminal and penultimate COOH-terminal portions are not. Analysis of precursors with single substitutions revealed complete loss of function when arginine 23 was substituted with glycine. Additional substitutions suggested that the critical role of this arginine residue may be mediated by participation in a local secondary structure, very likely an alpha-helix, which is proposed to be an essential element in the midportion of the leader peptide.     

Mutation of a neutral amino acid in the transit peptide of rat mitochondrial malate dehydrogenase abolishes binding and import

We have investigated the function of a leucine residue in the transit peptide of the rat mitochondrial malate dehydrogenase precursor using in vitro mutagenesis. Amino acid replacement of leucine 13 with glutamic acid and asparagine abolished import into mitochondria, while substitutions with proline, histidine, and arginine severely diminished uptake. In contrast, glutamine, tyrosine, valine, and alanine replacement resulted in normal levels of import, suggesting that there is a requirement for an uncharged residue at this position. Mutants involving rearrangements of the native sequence at positions 12-14 were imported as efficiently as the wild-type mitochondrial malate dehydrogenase, indicating that there was not an obligatory order of amino acid residues. However, deletion of leucine 13 resulted in diminished import. Binding studies with isolated mitochondria revealed that several position 13 mutants were deficient in binding to the mitochondrial surface, accounting for the reduced import of these proteins. This impairment could be distinguished from the effects due to decreased positive charge. We conclude that while translocation depends on the net positive charge, binding to the mitochondrial surface is mediated by uncharged residues within the transit peptides of mitochondrial precursor proteins.     

Import of rat ornithine transcarbamylase precursor into mitochondria: two-step processing of the leader peptide

The mitochondrial matrix enzyme ornithine transcarbamylase (OTC) is synthesized on cytoplasmic polyribosomes as a precursor (pOTC) with an NH2-terminal extension of 32 amino acids. We report here that rat pOTC synthesized in vitro is internalized and cleaved by isolated rat liver mitochondria in two, temporally separate steps. In the first step, which is dependent upon an intact mitochondrial membrane potential, pOTC is translocated into mitochondria and cleaved by a matrix protease to a product designated iOTC, intermediate in size between pOTC and mature OTC. This product is in a trypsin-protected mitochondrial location. The same intermediate-sized OTC is produced in vivo in frog oocytes injected with in vitro-synthesized pOTC. The proteolytic processing of pOTC to iOTC involves the removal of 24 amino acids from the NH2 terminus of the precursor and utilizes a cleavage site two residues away from a critical arginine residue at position 23. In a second cleavage step, also catalyzed by a matrix protease, iOTC is converted to mature OTC by removal of the remaining eight residues of leader sequence. To define the critical regions in the OTC leader peptide required for these events, we have synthesized OTC precursors with alterations in the leader. Substitution of either an acidic (aspartate) or a "helix-breaking" (glycine) amino acid residue for arginine 23 of the leader inhibits formation of both iOTC and OTC, without affecting translocation. These mutant precursors are cleaved at an otherwise cryptic cleavage site between residues 16 and 17 of the leader. Interestingly, this cleavage occurs at a site two residues away from an arginine at position 15. The data indicate that conversion of pOTC to mature OTC proceeds via the formation of a third discrete species: an intermediate-sized OTC. The data suggest further that, in the rat pOTC leader, the essential elements required for translocation differ from those necessary for correct cleavage to either iOTC or mature OTC.     

Identification of amino acids in the leader peptide of Methanococcus voltae preflagellin that are important in posttranslational processing

Archaeal flagellins are made initially as preproteins with short, positively charged leader peptides. Analysis of all available archaeal preflagellin sequences indicates that the -1 position is always held by a glycine while the -2 and -3 positions are almost always held by charged amino acids. To evaluate the importance of these and other amino acids in the leader peptides of archaeal flagellins for processing by a peptidase, Methanococcus voltae mutant FlaB2 preflagellin genes were generated by PCR and the proteins tested in a methanogen preflagellin peptidase assay that detects the removal of the leader peptide from preflagellin. When the -1 position was changed from glycine to other amino acids tested, no cleavage was observed by the peptidase, with the exception of a change to alanine at which poor, partial processing was observed. Amino acid substitutions at the -2 lysine position resulted in a complete loss of processing by the peptidase, while changes at the -3 lysine resulted in partial processing. A mutant preflagellin with a leader peptide shortened from 12 amino acids to 6 amino acids was not processed. When the invariant glycine residue present at position +3 was changed to a valine, no processing of this mutant preflagellin was observed. The identification of critical amino acids in FlaB2 required for proper processing suggests that a specific preflagellin peptidase may cleave archaeal flagellins by recognition of a conserved sequence of amino acids.     

Isolation and characterization of a complementary DNA for the nuclear-coded precursor of the beta-subunit of bovine mitochondrial F1-ATPase

We have isolated a cDNA clone encoding the precursor of the beta-subunit of the bovine heart mitochondrial F1-ATPase. Two probes were used to isolate this precursor from a bovine heart cDNA library. One probe was a mixed-sequence oligonucleotide directed against a portion of the amino acid sequence of the mature protein, and the other probe was the F1-ATPase beta-subunit gene from Saccharomyces cerevisiae. Determination of the nucleotide sequence of this cDNA reveals that it contains a 1584-nucleotide-long open reading frame that encodes the complete mature beta-subunit protein and a 48 amino acid long NH2-terminal extension. This amino-terminal presequence contains four basic arginine residues, one acidic glutamic acid residue, four polar uncharged serine residues, and five proline residues. Southern blot hybridization analyses suggest that the bovine F1-ATPase beta-subunit precursor is encoded by a single genetic locus. RNA blot hybridization analyses reveal a single mRNA species of approximately 1.9 kilobases from both bovine liver and heart.     

Mitochondrial protein turnover: role of the precursor intermediate peptidase Oct1 in protein stabilization

Most mitochondrial proteins are encoded in the nucleus as precursor proteins and carry N-terminal presequences for import into the organelle. The vast majority of presequences are proteolytically removed by the mitochondrial processing peptidase (MPP) localized in the matrix. A subset of precursors with a characteristic amino acid motif is additionally processed by the mitochondrial intermediate peptidase (MIP) octapeptidyl aminopeptidase 1 (Oct1), which removes an octapeptide from the N-terminus of the precursor intermediate. However, the function of this second cleavage step is elusive. In this paper, we report the identification of a novel Oct1 substrate protein with an unusual cleavage motif. Inspection of the Oct1 substrates revealed that the N-termini of the intermediates typically carry a destabilizing amino acid residue according to the N-end rule of protein degradation, whereas mature proteins carry stabilizing N-terminal residues. We compared the stability of intermediate and mature forms of Oct1 substrate proteins in organello and in vivo and found that Oct1 cleavage increases the half-life of its substrate proteins, most likely by removing destabilizing amino acids at the intermediate's N-terminus. Thus Oct1 converts unstable precursor intermediates generated by MPP into stable mature proteins.     

Factors governing nonoverlapping substrate specificity by mitochondrial inner membrane peptidase

At least three peptidases are involved in cleaving presequences from imported mitochondrial proteins. One of the peptidase, the inner membrane peptidase, has two catalytic subunits, Imp1p and Imp2p, which are structurally related but functionally distinct in the yeast Saccharomyces cerevisiae. Whereas both subunits are members of the type I signal peptidase family, they exhibit nonoverlapping substrate specificities. A clue to the substrate specificity mechanism has come from our discovery of the importance not only of the -1 and -3 residues in the signal peptides cleaved by Imp1p and Imp2p but also the +1 cargo residues attached to the signal peptides. We specifically find that Imp1p prefers substrates having a negatively charged residue (Asp or Glu) at the +1 position, whereas Imp2p prefers substrates having the Met residue at the +1 position. We further suggest that the conformation of the cargo is important for substrate recognition by Imp2p. A role for the cargo in presequence recognition distinguishes Imp1p and Imp2p from other type I signal peptidases.     

Effect of point mutations in the native simian virus 40 tumor antigen, and in synthetic peptides corresponding to the H-2Db-restricted epitopes, on antigen presentation and recognition by cytotoxic T lymphocyte clones.

The effects on CTL recognition of individual amino acid substitutions within epitopes I, II, and III of SV40 tumor Ag (T Ag) were examined. Epitope I spans amino acids 207 to 215, and epitope II/III is within residues 223 to 231 of SV40 T Ag. An amino acid substitution at position 207 (Ala----Val) or 214 (Lys----Glu) of SV40 T Ag expressed in transformed cells resulted in loss of epitope I, recognized by CTL clone Y-1. The amino acid substitution at residue 214 in the corresponding synthetic peptide, LT207-215(214-Lys----Glu), also led to loss of recognition by CTL clone Y-1. The recognition, by CTL clone Y-1, of peptides LT207-215 and LT207-217 with an Ala----Val substitution at position 207 was severely affected. Peptides LT205-215 and LT205-219 with the Ala----Val substitution at residue 207 were, however, recognized by CTL clone Y-1, suggesting that residues 205 and 206 may be involved in presentation of site I. Alteration of residue 224 (Lys----Glu) in the native T Ag resulted in loss of recognition by both CTL clones Y-2 and Y-3. However, a peptide corresponding to epitope II/III with an identical amino acid substitution at residue 224 provided a target for CTL clone Y-3 but not clone Y-2. A change of Lys----Gln at residue 224 in both the native protein and a synthetic peptide caused loss of recognition by CTL clone Y-2 but not CTL clone Y-3. Further, an amino acid substitution of Lys----Arg at position 224 of the native T Ag decreased recognition of epitope II/III by CTL clones Y-2 and Y-3 but had no effect on recognition of a synthetic peptide bearing the same substitution. These results indicate that the mutagenesis approach, resulting in identical amino acid substitutions in the native protein and in the synthetic peptides, may provide insight into the role of individual residues in the processing, presentation, and recognition of CTL recognition epitopes.