Increased efficiency of folding and peptide loading of mutant MHC class I molecules.

Class I molecules, encoded by diverse alleles at several loci of the major histocompatibility complex (MHC) are assembled in the endoplasmic reticulum (ER) from heavy chain, beta2 microglobulin and peptide in association with accessory proteins of the peptide loading complex. We show here, that mutations in the alpha2 domain (Q115A; D122A) of the human class I allele HLA-A2 cause a lack of apparent association with the loading complex and a faster assembly. Despite the drastically reduced association with the TAP loading complex, i. e. less than 20 % of HLA-A2 expressed in the cells can be co-precipitated with either TAP, calreticulin or tapasin, the mutant proteins are expressed on the cell surface in a stable conformation, and bind a complex set of peptides almost identical to that of wild-type HLA-A2. Furthermore, the mutant class I molecules are more rapidly exported from the ER than wild-type HLA-A2 and undergo faster maturation. The mutation Q115A does not destroy a binding site for the loading complex as this HLA-A2 mutant associates with the loading complex when peptide supply is limited. The association of class I molecules with the TAP-associated loading complex appears to be a reflection of how quickly the stable conformation is gained.

Assembly of MHC class I molecules with biosynthesized endoplasmic reticulum-targeted peptides is inefficient in insect cells and can be enhanced by protease inhibitors.

To study the requirements for assembly of MHC class I molecules with antigenic peptides in the endoplasmic reticulum (ER), we studied Ag processing in insect cells. Insects lack a class I recognition system, and their cells therefore provide a "blank slate" for identifying the proteins that have evolved to facilitate assembly of class I molecules in vertebrate cells. H-2Kb heavy chain, mouse beta 2-microglobulin, and an ER-targeted version of a peptide corresponding to Ova(257-264) were expressed in insect cells using recombinant vaccinia viruses. Cell surface expression of Kb-OVA(257-264) complexes was quantitated using a recently described complex-specific mAb (25-D1.16). Relative to TAP-deficient human cells, insect cells expressed comparable levels of native, peptide-receptive cell surface Kb molecules, but generated cell surface Kb-OVA(257-264) complexes at least 20-fold less efficiently from ER-targeted peptides. The inefficient assembly of Kb-OVA(257-264) complexes in the ER of insect cells cannot be attributed solely to a requirement for human tapasin, since first, human cells lacking tapasin expressed endogenously synthesized Kb-OVA(257-264) complexes at levels comparable to tapasin-expressing cells, and second, vaccinia virus-mediated expression of human tapasin in insect cells did not detectably enhance the expression of Kb-OVA(257-264) complexes. The assembly of Kb-OVA(257-264) complexes could be greatly enhanced in insect but not human cells by a nonproteasomal protease inhibitor. These findings indicate that insect cells lack one or more factors required for the efficient assembly of class I-peptide complexes in vertebrate cells and are consistent with the idea that the missing component acts to protect antigenic peptides or their immediate precursors from degradation.

A critical role for tapasin in the assembly and function of multimeric MHC class I-TAP complexes.

Newly assembled major histocompatibility complex (MHC) class I molecules, together with the endoplasmic reticulum chaperone calreticulin, interact with the transporter associated with antigen processing (TAP) through a molecule called tapasin. The molecular cloning of tapasin revealed it to be a transmembrane glycoprotein encoded by an MHC-linked gene. It is a member of the immunoglobulin superfamily with a probable cytoplasmic endoplasmic reticulum retention signal. Up to four MHC class I-tapasin complexes were found to bind to each TAP molecule. Expression of tapasin in a negative mutant human cell line (220) restored class I-TAP association and normal class I cell surface expression. Tapasin expression also corrected the defective recognition of virus-infected 220 cells by class I-restricted cytotoxic T cells, establishing a critical functional role for tapasin in MHC class I-restricted antigen processing.

Roles for calreticulin and a novel glycoprotein, tapasin, in the interaction of MHC class I molecules with TAP.

Assembly of MHC class I-beta 2 microglobulin (beta 2m) dimers in the endoplasmic reticulum involves two chaperones. Calnexin has previously been shown to interact with free class I heavy chains. Here, we show that the related chaperone, calreticulin, binds human class I-beta 2m dimers prior to peptide loading. Calreticulin remains associated with at least a subset of class I molecules when they, in turn, bind to TAP. Further evidence suggests that the interaction of class I-beta 2m dimers with TAP occurs via a novel uncharacterized 48 kDa glycoprotein, tapasin, which can bind independently to TAP and class I-beta 2m-calreticulin complexes. Tapasin is absent from the mutant cell line .220, in which class I-TAP association and peptide loading is defective.

The protease inhibitor, N-acetyl-L-leucyl-L-leucyl-leucyl-L-norleucinal, decreases the pool of major histocompatibility complex class I-binding peptides and inhibits peptide trimming in the endoplasmic reticulum.

N-acetyl-L-leucyl-L-leucyl-L-norleucinal, (LLnL), which inhibits proteasomes in addition to other proteases, was found to prolong the association of major histocompatibility complex class I molecules with the transporters associated with antigen processing (TAP), and to slow their transport out of the endoplasmic reticulum (ER). LLnL induced a reversible accumulation of ubiquitinated proteins and changed the spectrum of peptides bound by class I molecules. These effects can probably be attributed to proteasome inhibition. Unexpectedly, in the TAP-deficient cell line .174, the rate of intracellular transport of human histocompatibility leukocyte antigen (HLA) A2 was also reduced by LLnL, and the generation of most HLA-A2-associated signal sequence peptides was inhibited. The inhibition of HLA-A2 transport in .174 cells was found to be less sensitive to LLnL than in wild-type cells, and a similar difference was found for a second protease inhibitor, benzyloxycarbonyl-L-leucyl-L-leucyl-L-phenylalanilal. These data suggest that under some conditions such inhibitors can block trimming of peptides by an ER peptidase in addition to inhibiting cytosolic peptide generation.

Characteristics of peptide and major histocompatibility complex class I/beta 2-microglobulin binding to the transporters associated with antigen processing (TAP1 and TAP2).

The transporter proteins associated with antigen processing (TAP proteins) transport antigenic peptides across the endoplasmic reticulum membrane where they can assemble with newly synthesized major histocompatibility complex (MHC) class I/beta 2-microglobulin (beta 2m) dimers. We have shown previously that TAP possesses a peptide-recognition site with broad specificity and that MHC class I/beta 2m dimers physically associate with TAP. Here, we further characterize the nature of the peptide-binding site on TAP, and the site of interaction of TAP with MHC class I/beta 2m dimers. TAP photoaffinity labeling experiments revealed that both TAP1 and TAP2 are photolabeled by two distinct photopeptide analogues, suggesting that elements of both TAP1 and TAP2 compose the peptide-recognition site. TAP photolabeling analysis on transfectant cell lines that express TAP1 and TAP2 both individually and together revealed that efficient formation of the peptide-binding site occurs only when TAP1 and TAP2 are coexpressed, which correlates with the finding that peptide translocation via TAP occurs only in the presence of both TAP1 and TAP2. These data strongly support the notion that TAP functions as a heterodimer. MHC class I/beta 2m dimers were shown to associate with individual TAP1 chains but were not detectable with individual TAP2 chains. This result suggests that the site of interaction for MHC class I/beta 2m dimers with TAP is on TAP1.

MHC class I/beta 2-microglobulin complexes associate with TAP transporters before peptide binding.

Major histocompatibility complex class I molecules bind antigenic peptides in the endoplasmic reticulum (ER) and transport them to the cell surface for recognition by cytotoxic T lymphocytes. The peptides are predominantly generated from cytoplasmic proteins, probably by the action of the multicatalytic proteinase complex, or proteasome. They are transported into the ER by the transporters associated with antigen processing (TAP), a complex formed from two subunits, TAP.1 and TAP.2 (refs 3-5). Here we show that the TAP molecules are intimately involved in the assembly of the class I/beta 2-microglobulin (beta 2m) peptide complex. Free class I heavy chains are associated in the ER with the chaperone calnexin. In human B-cell lines, however, class I/beta 2m dimers in the ER are physically associated with TAP molecules rather than calnexin. Our results suggest that calnexin mediates class I/beta 2m dimerization, and subsequent binding of the dimers to TAP molecules facilitates their association with TAP-transported peptides.

Assembly and transport of class I MHC-peptide complexes.

Peptides that are presented to T-cells by class I major histocompatibility complex molecules are derived from cytosolic proteins. They are generated in the cytosol and translocated into the endoplasmic reticulum (ER) by the transporters associated with antigen processing (TAP molecules). Competition experiments suggest that TAP molecules can specifically translocate a wide range of peptides from 8-13 amino acids long; longer peptides are less likely to be transported. A photoactivatable peptide derivative has been used to demonstrate that competition for transport into the ER reflects competition for a specific peptide-binding site on the TAP molecule. Class I molecules bind the translocated peptides in the ER thereby allowing their transport to the cell surface. The assembly of the class I-peptide complex in the ER is tightly regulated. The evidence suggests that class I heavy chains first dimerize with beta 2-microglobulin in a process mediated by the chaperone calnexin. The class I-beta 2-microglobulin dimer then physically associates with TAP molecules and is released for transport when it binds a peptide.

Role of hapten-anchoring peptides in defining hapten-epitopes for MHC-restricted cytotoxic T cells. Cross-reactive TNP-determinants on different peptides.

Synthetic hapten-peptide conjugates selectively modify cell-bound MHC class I molecules in a haplotype-specific way. We investigated the contribution of the carrier peptides to the structural specificity of T cell-antigenic TNP epitopes, using different H-2Kb-binding TNP-peptides and a collection of TNP/Kb-specific CTL clones. Adjustment of peptide sequences to the proposed Kb-specific "motif" (octamers with F or Y and L in positions 5 and 8, respectively) enhanced Kb-binding and antigenicity by many orders of magnitude. Moreover, several clones reacted to peptides, containing the "motif" and TNP-lysine in position 4 but were otherwise unrelated by sequence. TNP in other positions was not recognized by these cells, but other CTL reacted to TNP in position 7. This points to the positioning of hapten determinants within the MHC binding groove as a major role of the anchoring peptide. However, determination of the limiting amounts of TNP peptides that elicit antigenicity or inhibit other Kb-restricted CTL reactions revealed that TCR also recognize variations in the sequences of carrier peptides. This contribution is low for TNP in position 4 but high in position 7, indicating lysine in position 4 as a particularly dominant and cross-reactive hapten-anchoring site in Kb-associated peptides. This implies that cell modification with lysine-reactive TNP reagents results in immunodominant, highly repetitive TNP epitopes, which may explain the strong antigenicity and the allergenic properties of TNP, as well as the restricted TCR repertoire directed against this hapten. Our data further recommend hapten peptides for general studies of TCR-Ag interactions because in contrast to pure protein Ag, hapten epitopes tolerate substantial structural variations in the MHC-anchoring peptide, and can be located by hapten-specific antibodies.

Peptide-conjugated hapten groups are the major antigenic determinants for trinitrophenyl-specific cytotoxic T cells.

Several trinitrophenyl (TNP)-specific mouse cytotoxic T cell (CTL) clones recognize TNP-conjugated peptides in association with class I MHC molecules ('hapten-peptide determinants'). However, cell modification with trinitrobenzene sulfonic acid (TNBS) also leads to the formation of TNP determinants covalently attached to MHC molecules ('altered self'). To determine the importance of 'peptide' versus 'altered self' determinants, we used the mutant cell line RMA-S which expresses peptide-free ('empty') Kb and Db molecules at 26 degrees C. Additionally, we stabilized Kb molecules on RMA-S cells at 37 degrees C using the Kb binding heptapeptide N53-59 derived from the vesicular stomatitis virus nucleoprotein. Lacking lysine, this peptide remains unmodified by TNBS and, therefore, only allows the formation of 'altered self' TNP determinants on occupied Kb molecules. RMA-S targets, pretreated or untreated with N53-59, upon TNBS modification were only lysed poorly or not at all by four different TNP-specific CTL. In contrast, all of these clones efficiently lysed TNBS-treated, unmutated RMA cells, and three of them strongly reacted with RMA or RMA-S cells in the presence of tryptic TNP-BSA peptides. Moreover, the clone unreactive for TNP-BSA peptides also recognized TNP self-peptides extracted from TNBS-treated syngeneic spleen cells. Taken together, these data clearly show that TNP residues linked to MHC via associated peptides but not by covalent bondage represent the dominant antigenic epitopes for class I MHC-restricted, hapten-specific T cells.

Synthetic peptides anchor T cell-specific TNP epitopes to MHC antigens.

Several TNP-specific, H-2Kb-restricted mouse CTL clones were identified which specifically lysed target cells in the presence of tryptic digests of TNP-modified BSA. Glutaraldehyde fixation of cells revealed that the tryptic fragments did not require further cellular processing. Chromatographic fractionation of digested TNP-BSA identified the peptide TNP-BSA222-231, containing a TNP-modified lysine at BSA position 227, as the antigenic entity. The corresponding synthetic peptide was immunologically cross-reactive with the digest. All clones reactive with TNP-BSA222-231 cross-reacted with a similar peptide from mouse serum albumin (TNP-MSA126-135), favoring the assumption that TNP-BSA222-231 represents an artificial determinant, cross-reacting with some as yet unidentified, TNP-modified, Kb-associated self-peptides. Some of our clones also cross-reacted with tryptic digests of TNP-OVA or TNP-keyhole limpet hemocyanin. We interpret these findings to indicate that 1) a significant proportion of hapten (TNP) determinants for T cells are anchored to MHC via peptides; and 2) the amino acid sequence of these peptides may only partly define the specificity of the T cell-relevant hapten epitope, implying a particularly repetitive nature of these determinants. The production of T cell-antigenic hapten-peptide conjugates will hopefully open new roads to study immune responses to environmental allergens.

Antigen contact sites in class I major histocompatibility complex-restricted, trinitrophenyl-specific T cell receptors.

Cloned trinitrophenyl (TNP)-specific cytotoxic T cells (CTL) were obtained from mice transgenic for the beta chain of the antigen-specific receptor (TcR) of a Kb-restricted, TNP-specific CTL clone (BT7.4.1). The transgene-expressing CTL, specific for TNP/Kb were found to select for TcR alpha chains highly similar to that of the transgene donor clone BT7.4.1. In that way, two clones (II/7 and III/1) were identified whose TcR differed from the BT7.4.1 receptor only in their N alpha- and J alpha-sequences, i.e. within the third complementarity-determining regions of their alpha chains (CDR3 alpha). Moreover, the TcR of clones II/7 and III/1 had both rearranged the same J alpha element, thus differing from each other by only two amino acids in their V alpha/J alpha junctional regions. Functionally, however, clone III/1 exhibited unique cytolytic specificities for synthetic, Kb-binding TNP-peptides as well as for chemically TNP-modified allogeneic (H-2k) target cells. These findings demonstrate that (a) similar to "conventional" peptide antigens, synthetic hapten-peptide determinants are contacted by CDR3 alpha-determined amino acids of the TcR and (b) in contrast to current models, CDR alpha also appears to influence the major histocompatibility complex restriction specificity of a given TcR.

Predominant T cell receptor gene elements in TNP-specific cytotoxic T cells.

H-2b class I-restricted, TNP-specific CTL clones were obtained by limiting dilution cloning of either short term polyclonal CTL lines or spleen cells of TNP-immunized mice directly ex vivo. Sequence analyses of mRNA coding for TCR alpha- and beta-chains of 11 clones derived from CTL lines from individual C57BL/6 mice revealed that all of them expressed unique but clearly nonrandom receptor structures. Five alpha-chains (45%) employed V alpha 10 gene elements, and four of those (36%) were associated with J beta 2.6-expressing beta-chains. The alpha-chains from these four TCR, moreover, contained an acidic amino acid in position 93 of their N or J region-determined sequences. Clones isolated directly from spleen cells carried these types of receptors at lower frequency, 27% V alpha 10 and 19% J beta 2.6, indicating that bulk in vitro cultivation on Ag leads to selection for these particular receptors. However, even in TNP-specific CTL cloned directly ex vivo, V alpha 10 usage was increased about fivefold over that in Ag-independently activated T cells in H-2b mice (4 to 5%). The selection for V alpha 10/J beta 2.6-expressing cells was obtained repeatedly in other TNP-specific CTL lines from C57BL/6 mice but not in FITC-specific CTL from the same strain or in TNP-specific CTL lines from B10.BR (H-2k) or B10.D2 (H-2d) mice. We conclude from this (a) that the selection for V alpha 10/J beta 2.6+ T cells is driven by the complementarity of these receptors to a combination of TNP and MHC epitopes and (b) that predominant receptor structures reflect the existence of a surprisingly limited number of "T cell-relevant" hapten determinants on the surface of covalently TNP-modified cells.

Prenyl lipid and fatty-acid synthesis in isolatedAcetabularia chloroplasts.

A gentle procedure allowed the isolation of intact and highly active chloroplasts from the unicellular green algaAcetabularia mediterranea. These chloroplasts incorporated carbon from NaH(14)CO3 into fatty acids and prenyl lipids at a rate of about 20-50 nmol carbon· (mg chlorophyll)(-1)·h(-1). Most of the fatty acids formed in vitro were esterified in galactolipids. The main prenyl lipids synthesized were the chlorophyll side chain, intermediates of the carotenogenic path, α-and ß-carotene, as well as lutein. Large amounts of [1-(14)C]acetate were incorporated, but exclusively into fatty acids.Isopentenyl diphosphate was a good substrate for prenyl-lipid formation in hypotonically treated chloroplasts. The envelope of intact chloroplasts, however, was impermeable to this compound. Intermediates of the mevalonate pathway were not accepted as precursors under conditions whereisopentenyl diphosphate was well incorporated. The results show that the lipid biosynthetic pathways in the plastids ofAcetabularia, a member of the ancient family of Dasycladaceae, are very similar to those in higher-plant plastids.