Two different biosynthetic pathways for the secretion of Qa region-associated class I antigens by mouse lymphocytes

The extracellular N terminus of the endothelin B (ETB) receptor is cleaved by a metalloprotease in an agonist-dependent process

The extracellular N terminus of the endothelin B (ET(B)) receptor is susceptible to limited proteolysis (cleavage at R64 downward arrow S65), but the regulation and the functional consequences of the proteolysis remain elusive. We analyzed the ET(B) receptor or an ET(B)-GFP fusion protein stably or transiently expressed in HEK293 cells. After incubation of cells at 4 degrees C, only the full-length ET(B) receptor was detected at the cell surface. However, when cells were incubated at 37 degrees C, N-terminal cleavage was observed, provided endothelin 1 was present during the incubation. Cleavage was not inhibited by internalization inhibitors (sucrose, phenylarsine oxide). However, in cells incubated with both internalization inhibitors and metalloprotease inhibitors (batimastat, inhibitor of TNFalpha-convertase) or metal chelators (EDTA, phenanthroline), the cleavage was blocked, indicating that metalloproteases cleave the agonist-occupied ET(B) receptor at the cell surface. Functional analysis of a mutant ET(B) receptor lacking the first 64 amino acids ([Delta2-64]ET(B) receptor) revealed normal functional properties, but a 15-fold reduced cell surface expression. The results suggest a role of the N-terminal proteolysis in the regulation of cell surface expression of the ET(B) receptor. This is the first example of a multispanning membrane protein, which is cleaved by a metalloprotease, but retains its functional activity and overall structure.

Transmodulation of cell surface regulatory molecules via ectodomain shedding

Cell responses to exogenous stimuli often result in a rapid decrease of cell surface density of a wide range of diverse regulatory proteins, receptor and adhesion molecules in particular. This decrease may occur in a ligand-dependent fashion (down-regulation), following endocytosis and degradation by lysosomal proteases, or by down-modulation, where molecules are targeted by endoproteases directly on cell surface. These proteases are recruited by trans-modulating agents, different from ligand, which act via their own receptors and the related intracellularly-generated signals. Endoproteolytic activity determines the release of large portions (shedding) of substrate proteins, called ectodomains, which are usually not ligand-bound, and therefore represent biologically-active molecules. Ectodomain shedding is involved in a number of pathophysiological processes, such as inflammation, cell degeneration and apoptosis, and oncogenesis. Common features of the process, such as the involvement of protein kinase C and of transmembrane metalloproteases, have been identified. In this review, we summarize basic concepts on down-modulation and ectodomain shedding, and provide an update of the issue with respect to: (i) new entries to the list of molecules found involved in the process; (ii) current views about the upstream control of shedding, i.e. the pathways linking the signals triggered by the trans-modulating agents to the activation of endoproteolytic activity on the cell surface.

Two distinct forms of soluble MHC class I molecules synthesized by different mechanisms in normal rat cells in vitro

Rat soluble MHC class I synthesis was studied at both RNA and protein levels to determine whether multiple forms of soluble MHC class I molecules are produced by different mechanisms. RT-PCR and sequencing of MHC class I transcripts identified an alternatively spliced nonclassical MHC class I gene product, lacking both exon 5 and 6, in both spleen and liver. Immunoprecipitation and SDS-PAGE identified two distinct soluble MHC class I proteins in both splenocyte- and hepatocyte-culture supernatants. The 36Kd classical soluble MHC class I protein (RT1.Aa) was precipitated by both allele-specific (MN4.91.6, R3/13, R2/15S) and pan-reactive (OX18) mAbs. The 39Kd non-RT1.A soluble MHC class I protein was precipitated only by OX18. The production of soluble RT1.Aa was inhibited by a metalloproteinase inhibitor, but not by serine/thiol protease inhibitors. None of these protease inhibitors interfered with the soluble non-RT1.A production, suggesting that it might be derived from an alternatively spliced MHC class I transcript. The soluble non-RT1.A was always associated with beta2m. However, soluble RT1.Aa molecule was cleaved in beta2m-free form and was reassociated with beta2m in culture supernatants. Thus two soluble MHC class I molecules, classical (36Kd RT1.Aa) and nonclassical (the alternatively spliced transcript), were produced from rat cells. Alternative splicing led to the nonclassical soluble MHC class I synthesis. Proteolytic cleavage by metalloproteinase led to the classical soluble MHC class I synthesis.

Membrane protein secretases

A diverse range of membrane proteins of Type 1 or Type II topology also occur as a circulating, soluble form. These soluble forms are often derived from the membrane form by proteolysis by a group of enzymes referred to collectively as 'secretases' or 'sheddases'. The cleavage generally occurs close to the extracellular face of the membrane, releasing physiologically active protein. This secretion process also provides a mechanism for down-regulating the protein at the cell surface. Examples of such post-translational proteolysis are seen in the Alzheimer's amyloid precursor protein, the vasoregulatory enzyme angiotensin converting enzyme, transforming growth factor-alpha, the tumour necrosis factor ligand and receptor superfamilies, certain cytokine receptors, and others. Since the proteins concerned are involved in pathophysiological processes such as neurodegeneration, apoptosis, oncogenesis and inflammation, the secretases could provide novel therapeutic targets. Recent characterization of these individual secretases has revealed common features, particularly sensitivity to certain metalloprotease inhibitors and upregulation of activity by phorbol esters. It is therefore likely that a closely related family of metallosecretases controls the surface expression of multiple integral membrane proteins. Current knowledge of the various secretases are compared in this Review, and strategies for cell-free assays of such proteases are outlined as a prelude to their ultimate purification and cloning.

Analysis of T-cell hybridomas with an unusual MHC class II-dependent ligand specificity

We have characterized two unusual T-cell hybridomas, 1E3 and 3B8, from H-2k mice immunized with I-Ab-transfected L cells (H-2k), that are stimulated by L cells transfected with I-Ab, I-Ak or I-Eb, but not by non-transfected L cells. These hybridomas could not be stimulated by spleen cells from H-2i3, H-2k, H-2b or H-2d mice. Monoclonal anti-I-A antibodies did not block their responses, suggesting that mouse major histocompatibility complex (MHC) class II molecules may be peptide donors rather than restriction elements for them. The stimulation of these hybridomas by fibroblast targets was not blocked by an anti-H-2kk, Dk-specific monoclonal antibody. Lipopolysaccharide (LPS)-activated splenic and peritoneal exudate cells from H-2k, H-2d, H-2i3, H-2b as well as beta 2-microglobulin-deficient, TAP-1-deficient and I-A alpha-deficient H-2b mice stimulated these hybridomas. LPS could also activate a macrophage cell line, but not a B-cell line, to become stimulatory for 1E3. A rat antiserum against untransfected L cells specifically and significantly blocked the response of 1E3. Thus, 1E3 may recognize a conserved murine MHC class II peptide loaded in a TAP-1-independent fashion on a non-classical, monomorphic, beta 2-microglobulin-independent restriction element.

A physical map of the Q region of B1O.P

The murine class I MHC Q region is part of a large complex multigene family whose members have various peptide binding functions. The structure of the Q region is complex, varying extensively in the b, d, k, and q haplotypes so far examined. To better understand the structural heterogeneity, we examined the Q region of B 10.P, a strain whose immunological characteristics are distinct from other haplotypes. A total of 89 cosmids were isolated from genomic DNA. The B 10.P Q region was found to contain seven genes in a 190-kb cluster linked to DP and two additional Q genes in a separate 55-kb cluster. The gene arrangement in this haplotype was unique and did not correspond to any other haplotype; this underscores the complexity of chromosomal structure in this region. In addition to the Q region clusters, Tla region was tentatively aligned in five clusters spanning approximately 300 kb. One 37-kb M region cosmid was also identified.

An enzyme immunoassay for rat soluble MHC class I molecules (RT1a) and the release of soluble class I from mitogenically stimulated mononuclear cells

Soluble MHC class I antigens can be detected in the serum of humans and various animals and appear in the circulation shortly after liver transplantation. The precise role of these antigens is currently uncertain, but soluble MHC class I may be involved in immunomodulation. We have developed an enzyme linked immunosorbent assay for soluble rat MHC class I (RT1a) molecules and monitored the kinetics of antigen release following in vitro stimulation of splenic mononuclear cells. A 4 day DA splenocyte Con A supernatant provided a source of soluble class I antigens and was arbitrarily assigned a concentration of 1000 units/ml. Ninety six well plates were coated with a rat RT1a-specific mAb (MN4-91-6) and soluble class I binding was detected using a biotinylated mAb reactive with a monomorphic region of the rat MHC class I molecule (OX18) followed by a streptavidin-alkaline phosphatase conjugate and substrate. The intra- and interassay variations were typically less than 5% and 10% respectively, to give a working range for the assay of between 62.5 and 1000 units/ml. Mitogenic stimulation led to a progressive increase in soluble class I levels in culture supernatants. This assay will be valuable in differentiating recipient and graft responses following experimental organ transplantation.

Dimerization of soluble major histocompatibility complex-peptide complexes is sufficient for activation of T cell hybridoma and induction of unresponsiveness

Major histocompatibility complex (MHC) class I molecules are cell-surface proteins that present peptides to CD8+ T cells. These peptides are mostly derived from endogenously synthesized protein. Recombinant, soluble MHC class I molecules were produced, purified, and loaded homogeneously with synthetic peptide. These MHC-peptide complexes were used to activate a T cell hybridoma. While monomers of MHC-peptide bound to the T cell, they showed no stimulatory activity. Dimers fully triggered the T cell hybridoma to secrete interleukin 2. This response was followed by a state in which the T cell was refractory to restimulation as a result of defective signal transduction through the T cell receptor.

Signals delivered via the Qa-2 molecule can synergize with limiting anti-CD3-induced signals to cause T lymphocyte activation

Qa-2 is a glycolipid anchored, MHC encoded class I molecule expressed at high levels on all murine peripheral T lymphocytes. Anti-Qa-2 antibodies have previously been found to stimulate T cells to proliferate in the presence of crosslinking antibody and PMA. We have examined the effect of anti-Qa-2 antibodies on T cells stimulated with a suboptimal concentration of immobilized anti-CD3. When anti-Qa-2 antibodies were co-immobilized with limiting anti-CD3, in the absence of PMA, a clear augmentation of T cell proliferation was seen. Interestingly, the co-stimulatory anti-Qa-2 antibodies could be directed against epitopes mapped to either the alpha 3 or the alpha 1/alpha 2 Qa-2 domains. As was the case with activation induced by soluble/crosslinked anti-Qa-2 antibodies plus PMA, CD8+ T cells were less able to be costimulated with anti-Qa-2 antibodies than CD4+ cells. Surprisingly, Ca2+ mobilization was only seen when two anti-Qa-2 antibodies reactive to separate structural domains were co-crosslinked on the surface of Indo-1 loaded T cells with a suboptimal concentration of anti-CD3. Collectively these results raise questions regarding the mechanism of Qa-2 mediated signaling and its potential role in T cell activation.

Cytotoxic T lymphocyte precursor cells specific for the major histocompatibility complex class I-like antigen, Qa-2, require CD4+ T cells to become primed in vivo and to differentiate into effector cells in vitro

Experiments were performed to determine whether CD4+ T cells are required for the generation of cytotoxic T lymphocytes (CTL) specific for the nonpolymorphic major histocompatibility complex (MHC) class I-like antigen, Qa-2. Splenic T cells from BALB/cBy (Qa-2b) mice that had been immunized with irradiated BALB/cJ (Qa-2a) splenocytes generated CTL following in vitro stimulation with BALB/cJ splenocytes. These CTL lysed all Qa-2+, but not Qa-2- targets, regardless of the H-2 haplotypes of target cells or their non-MHC backgrounds. This apparent MHC class I-unrestricted recognition of Qa-2 antigen was confirmed using Qa-2-specific CTL clones. The Qa-2-primed CTL precursor cells (CTLp) and CTL were found to be CD8+ T cells. Primed splenocytes depleted of CD4+ T cells prior to culture failed to generate CTL, but addition of lymphokines to the culture restored the CTL generation. Stimulation of primed splenic T cells with irradiated Qa-2+ T blast cells, instead of splenocytes or B blast cells, led to little to no CTL generation, suggesting that MHC class II molecules are involved in the presentation of Qa-2 antigen to CD4+ T cells. This was also supported by the results of experiments using Qa-2+, class II- thymoma cells of BALB/c origin. Stimulation of the thymoma-primed splenic T cells with the mitomycin C-treated thymoma cells resulted in no generation of anti-Qa-2 CTL, despite the fact that high levels of CTL specific for minor histocompatibility (H) antigens and H-2d were generated by immunizing the corresponding allogeneic hosts with the thymoma. However, the addition of lymphokines rendered thymoma-primed T cells capable of generating anti-Qa-2 CTL. Both CD4+ and CD8+ T cell populations, isolated from the BALB/cJ splenocyte-primed responder cells, proliferated in vitro in response to the Qa-2+ splenocytes, suggesting that Qa-2-reactive CD4+ T cells were present in the immunized mice. Depletion of CD4+ T cells from thymectomized BALB/cBy mice with anti-L3T4 monoclonal antibodies markedly reduced, but did not eliminate anti-Qa-2 CTL generation. In contrast, depletion of CD8+ T cells led to a complete abrogation of the CTL response. Addition of lymphokines to the culture of responder cells depleted of either T cell subset did not restore their reactivity. It is concluded that anti-Qa-2 CTLp need "help" from CD4+ T cells to become primed in vivo. Furthermore, primed CTLp also need "help" or lymphokines provided by CD4+ T cells to differentiate into effector CTL in vitro.(ABSTRACT TRUNCATED AT 400 WORDS)

Soluble HLA class I antigen secretion by normal lymphocytes: relationship with cell activation and effect of interferon-gamma

HLA class I antigens are thought to be integral membrane proteins. However, soluble forms of these molecules have been detected. Our laboratory has recently shown that the predominant form of these soluble proteins present in human serum, spleen tissue and culture supernatant of activated lymphocytes exhibits molecular weight and structure similar to classical HLA class I antigens, but lacks HLA A or B polymorphic determinants. In the present study, the secretion of such soluble proteins by lymphocytes has been further explored. Phytohaemagglutinin-stimulated normal lymphocytes secrete considerable quantities of soluble HLA (sHLA) class I proteins. This secretion seems to be a general property of lymphocytes, since activation of T as well as B cells by appropriate mitogens equally induce sHLA I secretion. Lymphocytes require RNA and protein synthesis, but not DNA synthesis, for the secretion to occur. Kinetic studies reveal that maximal sHLA I secretion precedes the peak of DNA synthesis by 24 h. In vitro stimulation with antigens or alloantigens also provokes sHLA I secretion. Moreover, this phenomenon has also been detected for in vivo-activated lymphocytes, as enhanced spontaneous sHLA I secretion was observed in cultures of low-density blastic B and T cells, and of blood lymphocytes obtained from normal subjects who had received a booster immunization 5 days earlier. Interferon-gamma (IFN-gamma) increases the expression of membrane-bound class I antigens but does not induce any sHLA I secretion, suggesting that both molecules are under different regulatory mechanisms. Our results indicate that human lymphocytes, upon stimulation, actively secrete considerable amounts of a soluble form of these biologically relevant proteins.

Biochemical nature of an Fc mu receptor on human B-lineage cells

An IgM-binding protein of approximately 60 kD has been identified on activated B cells, but not on resting and activated T cells, monocytes, or granulocytes. Here, we characterize this IgM-binding protein as a receptor for the Fc portion (CH3 and/or CH4 domains) of IgM molecules (Fc microR). The Fc microR can be expressed as a cell surface activation antigen throughout the pre-B and B cell stages in differentiation. Receptor expression is not directly linked with IgM production, as both mu- pre-B cells and isotype-switched B cells may express the Fc microR. The receptor molecules produced by both pre-B and B cells are identical in size and are characterized as an acidic sialoglycoprotein with O-linked, but no N-linked, oligosaccharide. The Fc microR is anchored to the surface of B-lineage cells via a glycosyl phosphatidylinositol linkage. The Fc microR is thus the third member of a family of Fc receptors expressed on B-lineage cells, and its preferential expression on activated B cells suggests a potential role in the response to antigens.

Identification of glycosylphosphatidylinositol-specific phospholipases C in mouse brain membranes

Using the membrane form of variant surface glycoprotein from Trypanosoma equiperdum labelled with [3H]myristate as a substrate, we identified two glycosylphosphatidylinositol phospholipase C enzymic activities in mouse brain. These activities were associated with particulate membrane fractions. They were characterized by their pH activity maxima and sensitivity to activators and ion chelators. One of the activities was maximal at acidic pH, stimulated by butanol, sensitive to cation chelator and insensitive to manganese. The activity of the other was maximal at neutral pH, stimulated by the detergent deoxycholate and independent of the presence of cation chelator or calcium. On membrane subfractionation, the acidic butanol-stimulated activity was found mainly associated with the lysosomal compartment, whereas the neutral deoxycholate-stimulated activity sediments with the myelin and plasma membrane compartment. These activities could be differentiated from particulate phosphatidylinositol phospholipases C, whose acidic lysosomal form is sensitive to manganese and insensitive to cation chelator or butanol, whereas the deoxycholate-activated enzymes are Ca2(+)-dependent.

Expression of the Q8/9d gene by T cells of the mouse

The Q genes, specifying Qa antigens and situated in the extended part of the major histocompatibility complex (MHC) of the mouse, comprise a subgroup of MHC class I genes whose significance and function are still largely unknown. In screening a cDNA library made from the BALB/c inducer T-cell line Cl.Ly1-T1, we isolated 11 clones representing Q8/9, but none representing Q6 or Q7. Confirmatory evidence is given that the Q8/9 gene originated from fusion of the 5' region of the Q8 gene with the 3' region of the Q9 gene at a recombination site or hot spot in the vicinity of intron 4. Contrary to previous impressions that Q8/9 is an inert pseudogene, we find that the Q8/9 gene can be functional and encode a Qa-2, 3 antigen. One variety of the 11 Q8/9 clones isolated lacked exon 5, which encodes the transmembrane domain of class I glycoproteins, and thus may account for secretion of a soluble form of Qa-2, 3 antigen thought to be released by activated T cells.

Qa-12--a novel determinant of activated T and B lymphocytes

Investigation of the antigenic phenotype of activated lymphocytes using the broadly cross-reactive mAb 6.3.4 revealed two phenotypic alterations as compared with the resting lymphocytes. The Qa specificity Qa-m208 disappears after lectin activation of Qa-m208-positive T lymphocytes. Analysis of Q7 and Q9 transfectants expressing the Qa-2 polypeptides shows that Qa-m208 is an epitope of the Qa-2 antigen. Because the Qa-2 antigens are still expressed on T lymphoblasts which have lost Qa-m208, changes of the Qa-2 molecules occur and result in the loss of certain epitopes. The second phenotypic change that we observed is the appearance of a novel specificity, Qa-12. Its expression is induced by lymphocyte activation and it is expressed on lymphoblasts of both T and B cell origin. The presence of this novel non-ubiquitous antigenic specificity is determined by the Tla region.

Genetics and expression of the Q6 and Q8 genes. An LTR-like sequence in the 3' untranslated region

A unique 2.2-kb mRNA is transcribed from the Q6 and Q8 genes of the mouse major histocompatibility complex. RNase protection experiments and DNA sequence analysis have mapped the 3' terminus to a site located 1110 bp downstream from exon 8. Comparison of the 3' sequence of Q8 to that of Q7 revealed that the two genes diverge from one another at a point located 200 bp into the untranslated domain. This finding explains the increased size of the transcript. RNase protection experiments involving twelve different strains of mice have revealed few sequence polymorphisms. A tissue distribution of the 2.2-kb transcript in B6 mice revealed that the highest quantities of message were present in the spleen with decreasingly lower amounts in the thymus, liver, kidney, testis, and brain. The H-2r haplotype appeared novel; it is phenotypically Qa-2-, yet expressed a 2.2-kb transcript which hybridizes to a Q8 probe. A comparison of a Qa-2hi expressor, B6, and a Qa-2low expressor, BALB/cFla, has established that these quantitative cell surface differences are reflected in mRNA differences. A homology search of the Genbank database has revealed that the 3' portion of Q8 contains extensive homology to a retrovirus-like long terminal repeat sequence that is characteristic of an embryonic-specific transposon (ETn).

Soluble interleukin 2 receptors are released from the cell surface of normal murine B lymphocytes stimulated with interleukin 5

Murine T and B lymphocytes can be induced to release soluble interleukin 2 receptors (IL2Rs). This receptor is believed to be a truncated form of the 55-kDa chain of the cell-membrane-associated receptor. It has been speculated that this receptor may play an important immunoregulatory role by binding to interleukin 2 (IL-2). We report here that interleukin 5 can induce normal murine B cells to release soluble IL2Rs. This extends our finding that interleukin 5 similarly can induce murine B cells to express functional cell-surface-associated IL2Rs. Two possible mechanisms of release of soluble IL2Rs have been suggested. Soluble IL2R could be synthesized as a secretory form of the receptor lacking the transmembrane domain or by cleavage of the extracellular domain of the cell-surface-associated IL2R at the cell surface. To investigate which mechanism was operative, we radioiodinated the cell surface of normal murine splenocytes that had been cultured for 1 day with Con A to stimulate the expression of cell-surface-associated IL2Rs and the release of soluble IL2Rs. Under the conditions used, radiolabeling of internal proteins was not apparent. Labeled cells were then recultured with Con A, conditioned medium was taken from replicate cultures at various times after radioiodination, and the specific radioactivity of released soluble IL2Rs was determined by ELISA and RIA. We demonstrate that the specific radioactivity and the kinetics of change of the specific radioactivity are consistent with the hypothesis that the soluble IL2Rs are derived from the cell-surface-associated IL2Rs rather than being released in a secretory form.

Qa-region class I gene expression: identification of a second class I gene, Q9, encoding a Qa-2 polypeptide

A feature of the expression of the tissue-specific class I antigen Qa-2 is the quantitative variation among mouse strains. Recently, the class I gene Q7 has been shown to encode a protein product that is biochemically indistinguishable from the lymphocyte-bound Qa-2 molecule. Utilizing gene transfection, we have identified a second Qa-2 subregion class I gene (Q9), in H-2b mice, which encodes a polypeptide biochemically similar to the Q7 and the Qa-2 polypeptides. Furthermore, we have observed that cell lines transfected with the allelic forms of the Q7 gene from C57BL/10 (Qa-2hi) or BALB/C (Qa-2low) display quantitative differences in cell-surface expression. Based on these studies, we suggest that gene dosage and allele-specific variation in cell-surface expression contribute to the strain-specific variation in the levels of Qa-2 antigen expression.

Biochemical complexity of serum HLA class I molecules

Human serum was found to contain a variety of class I-like molecules by Western blotting with anti-class I heavy chain reagents: major bands usually are observed around Mr 44,000, 40,000, and 35,000-37,000. HLA-A24-positive individuals are distinguished by higher serum levels of Mr 44,000 and 40,000 class I-like molecules than those found in HLA-A24-negative individuals. The Mr 44,000 serum molecules are probably intact class I molecules that have been shed from the cell membrane, because they contain both a transmembrane segment (TM), as deduced from detergent-binding experiments, and a cytoplasmic tail (CT), as inferred from reactivity with an antipeptide serum specific for the cytoplasmic domain of class I antigens (RaCT). The Mr 35,000 and 37,000 molecules contain neither a TM nor a CT region and therefore are probably proteolytic breakdown products of cellular and/or serum Mr 44,000 molecules, although the existence of Q10-like molecules in man cannot be ruled out. The Mr 40,000 molecules do not contain a TM region. Mr 40,000 molecules reactive with the RaCT serum were found in the minority (2/13) of sera tested. We conclude that alternative splicing resulting in a precise excision of the TM exon plays a minor role in the generation of serum HLA class I antigens.

Sequence of the mouse Q4 class I gene and characterization of the gene product

The Q4 class I gene has been shown to participate in gene conversion events within the mouse major histocompatibility complex. Its complete genomic nucleotide sequence has been determined. The 5' half of Q4 resembles H-2 genes more strongly than other Q genes. Its 3' end, in contrast, is Q-like and contains a translational stop signal in exon 5 which predicts a polypeptide with an incomplete membrane spanning segment. The presence of two inverted B1 repeats suggests that part of the Q4 gene may be mobile within the genome. Gene transfer experiments have shown that the Q4 gene encodes a beta 2-microglobulin associated polypeptide of Mr 41,000. A similar protein was found in activated mouse spleen cells. The Q4 polypeptide was found to be secreted both by spleen cells and by transfected fibroblasts and was not detectable on the cell surface. Antibody binding and two-dimensional gel electrophoresis indicate that the Q4 molecule is identical to a mouse class I polypeptide, Qb-1, which has been previously described.

Structural and functional roles of glycosyl-phosphatidylinositol in membranes

Glycosylated forms of phosphatidylinositol, which have only recently been described in eukaryotic organisms, are now known to play important roles in biological membrane function. These molecules can serve as the sole means by which particular cell-surface proteins are anchored to the membrane. Lipids with similar structures may also be involved in signal transduction mechanisms for the hormone insulin. The utilization of this novel class of lipid molecules for these two distinct functions suggests new mechanisms for the regulation of proteins in biological membranes.

Molecular mapping of signals in the Qa-2 antigen required for attachment of the phosphatidylinositol membrane anchor

Proteins anchored in the membrane by covalent linkage to phosphatidylinositol (PtdIns) can be released by treatment with purified PtdIns-specific phospholipase C (Ptd-Ins-PLC). A recent survey of leukocyte antigens using flow cytometry has shown that staining of certain Qa antigens was diminished after PtdIns-PLC treatment, but staining of structurally related H-2 antigens was not affected. Therefore, in this study, the sensitivity of cell-surface Qa-2, H-2Kb, and H-2Db to hydrolysis by PtdIns-PLC was investigated biochemically by immunoprecipitation of radioiodinated molecules from cell lysates or supernatants. Qa-2, but not H-2Kb, was released from the surface of PtdIns-PLC-treated C57BL/10 mouse spleen cells and recovered in the cell supernatants. Similar analysis of thymoma cells transfected with cloned C57BL/10 genes showed that cell-surface Qa-2 molecules encoded by a Q7b cDNA and the Q7b or Q9b gene were sensitive to hydrolysis by PtdIns-PLC, whereas the H-2Kb and H-2Db gene products were resistant. Using thymoma cells transfected with hybrid genes constructed by exchanging exons between Q7b and H-2Db, the signals for PtdIns modification were localized to a defined region of Qa-2. This region differs from H-2Db most significantly by the presence of a central aspartate residue in the transmembrane segment and in the length of the cytoplasmic portion.

Molecular complexity of Qa-2 antigens demonstrated by two-dimensional gel electrophoresis

Biosynthetically labelled Qa-2 antigens were isolated from mouse spleen cells by immunoprecipitation with anti-Qa-2 antisera. When newly synthesized Qa-2 molecules from several different inbred strains were analysed by two-dimensional (2D) gel electrophoresis; four different phenotypes were observed that differed in the number of polypeptides present. The ability to distinguish Qa-2+ phenotypes was used to map the recombination points in two congenic strains, B6.Tlaa and A.Tlab. No alternative Qa-2-like polypeptides were detected in B6.K1 (Qa-2-) cells using a polyspecific rabbit antiserum against mouse class I antigens, but a new molecule was detected in BALB/cBy (Qa-2-) cells. Pulse-chase and surface-labelling experiments showed that some, but not all, of the newly synthesized Qa-2 precursor forms are processed to mature cell surface molecules.