Cell-cell adhesion mediated by CD8 and human histocompatibility leukocyte antigen G, a nonclassical major histocompatibility complex class 1 molecule on cytotrophoblasts.

The lymphocyte differentiation marker CD8 acts as a coreceptor with the T cell receptor (TCR) during recognition of peptide presented by major histocompatibility complex (MHC) class I molecules. The functions of CD8 in the TCR complex are thought to be signaling through the association of CD8 with the protein tyrosine kinase p56lck and adhesion to MHC class I through the alpha 3 domain. While the ability of the CD8 alpha/alpha homodimer to bind to classical MHC class I molecules has been shown, it is unclear whether CD8 can also bind nonclassical molecules. Of particular interest is human histocompatibility leukocyte antigen (HLA)-G which is expressed on placental cytotrophoblast cells. These cells do not express HLA-A, -B and -C molecules. In this report, we demonstrate that CD8 can bind to HLA-G. It is possible, therefore, that a cell bearing CD8 may interact with HLA-G-expressing cells.

Mutations in CD8 that affect interactions with HLA class I and monoclonal anti-CD8 antibodies.

The T cell co-receptor, CD8, binds to the alpha 3 domain of HLA class I (Salter, R.D., R.J. Benjamin, P.K. Wesley, S.E. Buxton, T.P.J. Garrett, C. Clayberger, A.M. Krensky, A.M. Norman, D.R. Littman, and P. Parham. 1990. Nature [Lond.]. 345:41; Connolly, J.M., T.A. Potter, E.M. Wormstall, and T.H. Hansen. 1988. J. Exp. Med. 168:325; and Potter, T.A., T.V. Rajan, R.F. Dick II, and J.A. Bluestone. 1989. Nature [Lond.]. 337:73). To identify regions of CD8 that are important for binding to HLA class I, we performed a mutational analysis of the CD8 molecule in the immunoglobulin (Ig)-like variable domain. Our mutational analysis was based on our finding that using a cell-cell adhesion assay murine CD8 (Lyt-2) did not bind to human class I. Since the interaction of human CD8 with HLA class I is species specific, we substituted nonconservative amino acids from mouse CD8 and analyzed the ability of the mutated CD8 molecules expressed in COS 7 cells to bind HLA class I-bearing B lymphoblastoid cells, UC. Mutants with the greatest effect on binding were located in a portion of the molecule homologous to the first and second hypervariable regions of an antibody combining site. In addition, a panel of 12 anti-CD8 monoclonal antibodies were used to stain the 10 CD8 mutants, and amino acids that affected antibody binding were localized on the crystal structure of the Bence-Jones homodimer, REI. Support for an Ig-like structure of CD8 can be found in the pattern of substitutions affecting antibody binding. This work supports the similar tertiary structure of the CD8 alpha-terminal domain and an Ig variable domain.

Interaction between CD8 and major histocompatibility complex (MHC) class I mediated by multiple contact surfaces that include the alpha 2 and alpha 3 domains of MHC class I.

The cell surface glycoprotein CD8 functions as a coreceptor with the TCR on cytotoxic T lymphocytes. Mutational analysis of the binding site of CD8 for MHC class I predicted that distinct surfaces of CD8 would interact with both the alpha 2 and alpha 3 domains of class I. Using a cell-cell adhesion assay, we identified three residues Q115, D122, and E128 in the alpha 2 domain of class I critical for interaction with CD8. The side chains of these residues point towards a cavity formed by the alpha 1/alpha 2 platform, the alpha 3 domain and beta 2-microglobulin (beta 2m) of class I. These residues were predicted to contact CD8 based on a bivalent model of interaction between one CD8 alpha/alpha homodimer and two MHC class I molecules. These results therefore provide support for the model.

A dormant TIL phenotype defines non-small cell lung carcinomas sensitive to immune checkpoint blockers.

The biological determinants of sensitivity and resistance to immune checkpoint blockers are not completely understood. To elucidate the role of intratumoral T-cells and their association with the tumor genomic landscape, we perform paired whole exome DNA sequencing and multiplexed quantitative immunofluorescence (QIF) in pre-treatment samples from non-small cell lung carcinoma (NSCLC) patients treated with PD-1 axis blockers. QIF is used to simultaneously measure the level of CD3+ tumor infiltrating lymphocytes (TILs), in situ T-cell proliferation (Ki-67 in CD3) and effector capacity (Granzyme-B in CD3). Elevated mutational load, candidate class-I neoantigens or intratumoral CD3 signal are significantly associated with favorable response to therapy. Additionally, a "dormant" TIL signature is associated with survival benefit in patients treated with immune checkpoint blockers characterized by elevated TILs with low activation and proliferation. We further demonstrate that dormant TILs can be reinvigorated upon PD-1 blockade in a patient-derived xenograft model.

Epstein-Barr virus shuttle vector for stable episomal replication of cDNA expression libraries in human cells.

Efficient transfection and expression of cDNA libraries in human cells has been achieved with an Epstein-Barr virus-based subcloning vector (EBO-pcD). The plasmid vector contains a resistance marker for hygromycin B to permit selection for transformed cells. The Epstein-Barr virus origin for plasmid replication (oriP) and the Epstein-Barr virus nuclear antigen gene have also been incorporated into the vector to ensure that the plasmids are maintained stably and extrachromosomally. Human lymphoblastoid cells can be stably transformed at high efficiency (10 to 15%) by such plasmids, thereby permitting the ready isolation of 10(6) to 10(7) independent transformants. Consequently, entire high-complexity EBO-pcD expression libraries can be introduced into these cells. Furthermore, since EBO-pcD plasmids are maintained as episomes at two to eight copies per cell, intact cDNA clones can be readily isolated from transformants and recovered by propagation in Escherichia coli. By using such vectors, human cells have been stably transformed with EBO-pcD-hprt to express hypoxanthine-guanine phosphoribosyltransferase and with EBO-pcD-Leu-2 to express the human T-cell surface marker Leu-2 (CD8). Reconstruction experiments with mixtures of EBO-pcD plasmids demonstrated that one clone of EBO-pcD-hprt per 10(6) total clones or one clone of EBO-pcD-Leu-2 per 2 x 10(4) total clones can be recovered intact from the transformed cells. The ability to directly select for expression of very rare EBO-pcD clones and to then recover these episomes should make it possible to clone certain genes where hybridization and immunological screening methods are not applicable but where a phenotype can be scored or selected in human cell lines.

Identification and characterization of an Alu-containing, T-cell-specific enhancer located in the last intron of the human CD8 alpha gene.

Expression of the human CD8 alpha gene is restricted to cells of the lymphoid lineage and developmentally regulated during thymopoiesis. As an initial step towards understanding the molecular basis for tissue-specific expression of this gene, we surveyed the surrounding chromatin structure for potential cis-acting regulatory regions by DNase I hypersensitivity mapping and found four hypersensitive sites, three of which were T cell restricted. By using a reporter-based expression approach, a T-cell-specific enhancer was identified by its close association with a prominent T-cell-restricted hypersensitive sites in the last intron of the CD8 alpha gene. Deletion studies demonstrated that the minimal enhancer is adjacent to a negative regulatory element. DNA sequence analysis of the minimal enhancer revealed a striking cluster of consensus binding sites for Ets-1, TCF-1, CRE, GATA-3, LyF-1, and bHLH proteins which were verified by electrophoretic mobility shift assays. In addition, the 5' end of the enhancer was composed of an Alu repeat which contained the GATA-3, bHLH, and LyF-1 binding sites. Site-directed mutation of the Ets-1 and GATA-3 sites dramatically reduced enhancer activity. The functional importance of the other binding sites only became apparent when combinations of mutations were analyzed. Taken together, these results suggest that the human CD8 alpha gene is regulated by the interaction of multiple T-cell nuclear proteins with a transcriptional enhancer located in the last intron of the gene. Comparison of the CD8 alpha enhancer with other recently identified T-cell-specific regulatory elements suggests that a common set of transcription factors regulates several T-cell genes.

Transfer of cloned human class I major histocompatibility complex genes into HLA mutant human lymphoblastoid cells.

Three new kinds of recombinant DNA constructs were used to transfer cloned human class I HLA genes (A2 and B8) into unique HLA mutant lymphoblastoid cells: pHeBo(x): a class I gene, "x," in plasmid vector pHeBo, which contains a hygromycin resistance gene and Epstein-Barr virus oriP element that sustains extrachromosomal replication; pHPT(x): gene x in a vector with a hypoxanthine-guanine phosphoribosyltransferase (HPRT) gene; pHPTe(x): gene x in a vector with the HPRT gene and oriP element. Cell surface class I antigen expression was strong in transferents made with class I-deficient lymphoblastoid cell line mutants .144 (A-null), .53 (B-null), and .184 (A-null, B-null). Transferents expressing HLA-A2 were recognized specifically by HLA-A2-specific cytotoxic T lymphocytes. When introduced on either of the vectors with the Epstein-Barr virus oriP element, the class I gene replicated extrachromosomally and was lost at rates of 0.2 to 0.3 per cell division. When introduced with vector pHPT (lacking Epstein-Barr virus oriP), the B8 gene was inserted at different chromosomal locations. Introduction of the HLA-B8 gene failed to restore antigen expression by HLA-B-null mutant .174, providing evidence that, unlike mutants exemplified by .53, .144, and .184, some HLA antigen loss mutants are deficient in a trans-acting function needed for class I antigen expression. Of more general interest, the results obtained with HLA class I genes in vectors that replicate extrachromosomally suggest ways of relating genic expression to chromatin structure and function and of attempting to clone functional human centromeres.

Short related sequences in the cytoplasmic domains of CD4 and CD8 mediate binding to the amino-terminal domain of the p56lck tyrosine protein kinase.

We report that the cytoplasmic domains of the T-lymphocyte glycoproteins CD4 and CD8 alpha contain short related amino acid sequences that are involved in binding the amino-terminal domain of the intracellular tyrosine protein kinase, p56lck. Transfer of as few as six amino acid residues from the cytoplasmic domain of the CD8 alpha protein to the cytoplasmic domain of an unrelated protein conferred p56lck binding to the hybrid protein in HeLa cells. The common sequence motif shared by CD4 and CD8 alpha contains two cysteines, and mutation of either cysteine in the CD4 sequence eliminated binding of p56lck.p56lck also contains two cysteine residues within its CD4-CD8 alpha-binding domain, and both are critical to the interaction with CD4 or CD8 alpha. Because the interaction does not involve disulfide bond formation, a metal ion could stabilize the complex.

Repetitive Alu elements form a cruciform structure that regulates the function of the human CD8 alpha T cell-specific enhancer.

We previously identified a T cell-specific enhancer in the last intron of the human CD8 alpha gene that is adjacent to a sequence element that significantly represses enhancer function. This negative regulatory region consists of a half-Alu sequence that has potential to base-pair with a downstream Alu element, which is part of the fully active enhancer, to form a cruciform structure. The activity of this half-Alu silencer sequence is position and orientation-dependent, suggesting that DNA structure plays an important role in its function. Using site-directed mutational analysis and P1 nuclease mapping, we directly demonstrate that formation of a cruciform structure is required for repression of enhancer function in transient transfection assays. Finally, a P1 nuclease-sensitive site is present in the endogenous CD8 alpha gene in T cell lines providing indirect evidence that the stem-loop may form in vivo. Taken together, these results suggest that Alu elements may contribute to the regulation of the CD8 alpha gene enhancer through the formation of secondary structure that disrupts enhancer function.

Molecular analysis of protein interactions mediating the function of the cell surface protein CD8.

The T cell coreceptor CD8 is a cell-surface glycoprotein expressed either as a disulfide-linked homodimer of two CD8alpha monomers, or a heterodimer of CD8alpha and CD8beta. These receptors interact with ligands, such as major histocompatibility complex (MHC) class I, on the outside of the cell, with proteins inside the cell, such as the tyrosine kinase p56lck, and possibly with proteins on the same cell-surface. The molecular details describing such protein interactions can shed light on how the proteins function and the functional differences between the two forms of CD8. Crystal structures, mutational analysis, affinity measurements, and other approaches are providing those details.

Hemizygous HLA mutants of lymphoblastoid cells: a new cell type for histocompatibility testing.

HLA variants that have lost expression of multiple cis-linked alleles as determined serologically and enzymatically were analyzed for expression of HLA-D PLT-stimulating (PL) determinants using the primed lymphocyte test. All 19 variants that had lost HLA-DRw3 expression simultaneously had lost expression of the HLA-D region-associated PL specificity. PLT cells made by priming to a variant that was hemizygous for HLA genes resulted in priming to HLA-D PL determinants encoded for by just one haplotype, analogous to priming to an HLA homozygous cell.

Nod1, but not the ASC inflammasome, contributes to induction of IL-1ß secretion in human trophoblasts after sensing of Chlamydia trachomatis.

Chlamydia trachomatis (Ct) is an obligate intracellular bacterial pathogen. Previously, we showed that infection of human trophoblast cells by Ct triggers the secretion of the pro-inflammatory cytokine, interleukin (IL)-1ß. The aim of this study was to understand the innate immune pathways involved in trophoblast production of IL-1ß after Ct infection. The approach we took was to inhibit the expression or function of the key Toll-like receptors (TLRs), Nod-like receptors, and inflammasome components that have been associated with chlamydia infection. In this study, we report that Ct-induced trophoblast IL-1ß secretion is associated with the transcription of IL-1ß mRNA, the translation and processing of pro-IL-1ß, and the activation of caspase-1. In addition, we demonstrate that Ct-induced IL-1ß production and secretion by the trophoblast is independent of TLR2, TLR4, MyD88, and the Nalp3/ASC inflammasome. Instead we report, for the first time, the importance of Nod1 for mediating trophoblast IL-1ß secretion in response to a Ct infection.

A new variant glyoxalase I allele that is readily detectable in stimulated lymphocytes and lymphoblastoid cell lines but not in circulating lymphocytes or erythrocytes.

We describe an allele of the human glyoxalase GLO locus that encodes an enzymatically inactive form of the protein, which would not have been detected if only circulating erythrocytes and lymphocytes had been studied. The new allele is named GLO*3 and its protein product, GLO 3. Circulating blood cells of GLO*2/GLO*3 heterozygotes have just one electrophoretic band that migrates as the normal 2-2 dimer. Lymphoblastoid cell lines and phytohemagglutinin-stimulated lymphocytes from the same individuals have two electrophoretic bands, one with the mobility of the 2-2 dimer and one with the mobility of the 2-1 dimer that is present in GLO*2/GLO*1 heterozygotes, but a band with the mobility of the 1-1 dimer is not present. Therefore, the GLO*3 allele encodes a monomer that has the electrophoretic mobility of GLO 1 but is enzymatically inactive unless it is combined with normal monomers in 2-3 and 1-3 heterodimers. The failure to detect the GLO 3 protein in red cells and unstimulated lymphocytes is attributed to a relatively great instability or small rate of production in those cells. Consistent with this interpretation is the reduction of GLO activity in red cells of GLO*2/GLO*3 and GLO*1/GLO*3 heterozygotes to 65% or less of that in normal homozygotes and heterozygotes, while the activity of GLO*3 heterozygous lymphoblastoid cells is about 80% of normal. In contrast, the GLO activity of lymphoblastoid cells that had one copy of the GLO locus deleted by gamma-irradiation was 50%-60% of normal. Our observations indicate that certain kinds of mutant alleles of the GLO locus, and perhaps other loci, may not be detected in electrophoretic surveys on circulating blood cells only. The segregation of alleles that are not expressed in circulating red and white blood cells could confuse attempts to determine parentage, as they might have in the family described here. The observations also demonstrate the feasibility of mapping human genes by using ionizing radiation to create partial chromosome deletions in cultured cells.

Stable transformation of mouse L cells for human membrane T-cell differentiation antigens, HLA and beta 2-microglobulin: selection by fluorescence-activated cell sorting.

We isolated stable transformants of mouse L cells expressing human cell surface differentiation antigens by using immunofluorescence with monoclonal antibodies and selection with a fluorescence-activated cell sorter (FACS). Mouse L cells (TK-) were cotransformed with human cellular DNA and the herpes simplex virus thymidine kinase (TK) gene. TK+ transformants were first selected. The TK+ populations were stained with various fluorescent antibodies to membrane antigens, and positive cells were sorted and cloned by using a FACS. Transformants for HLA class I antigens, for beta 2-microglobulin, and for the T-cell differentiation antigens Leu-1 and Leu-2 were isolated. The frequency of antigen transformants among the TK+ transformants was about 0.5 X 10(-3). The sizes of the HLA, Leu-1, and Leu-2 molecules expressed by the transformants were the same as those of the proteins present on DNA-donor cells.

A modified cell surface marker gene for transgenic animal studies.

We developed a marker gene encoding a human cell surface molecule called CD8 for use in transgenic animal studies. The CD8 cDNA contains three mutations: one in the extracellular domain which prevents interaction with its ligand MHC class I and the other two in the cytoplasmic domain which inhibit its signalling function. The cDNA was linked to a fragment of the human growth hormone gene and in transgenic animal studies, expression was observed in the appropriate cell types using a CD2 enhancer. The advantage of the CD8 marker gene is that it is incapable of signalling via its only known signalling pathway and its expression can be monitored using monoclonal antibodies and microscopy or flow cytometry.

Functional importance of the cyclic AMP response element-like decamer motif in the CD8 alpha promoter.

Expression of the CD8 gene is highly regulated during lymphocyte differentiation and in a tissue-specific manner. We characterized the human CD8 alpha promoter region to determine whether tissue specificity resides within the promoter and to define important regulatory elements. A set of six fragments 5' of the CD8 alpha gene were linked to a luciferase reporter gene. The luciferase activity was then measured in a transient transfection assay. We found that CD8 alpha promoter activity can be detected from a 146-bp fragment upstream of the translation start site, but not from a 133-bp fragment. The cyclic AMP response element (CRE)-like site within the 10 bp from -143 to -133 is critical for promoter activity. Mutation of the CRE/decamer in the context of a 429-bp fragment causes loss of activity. Tissue specificity does not reside in the 146-bp fragment because this fragment directs expression in both T and non-T cell lines. Fragments longer than 146 bp are generally expressed less well in the cell lines suggesting the potential existence of negative regulatory elements upstream of -146. Using a CRE/decamer-containing oligomer as a probe in an electrophoresis mobility shift assay, three retarded bands formed by proteins binding to the DNA were detected using nuclear extracts from two T cell lines. Two of the three bands contain proteins of the CRE-binding protein (CREB)/activating transcription factor (ATF) family. Because the CRE-binding protein/activating transcription factor proteins play a role in the expression of many other T cell-specific genes, our work strengthens the hypothesis that the CRE motif is important for regulating the expression of T cell-specific genes.

Comparison of the roles of CD8 alpha alpha and CD8 alpha beta in interaction with MHC class I.

The CD8 molecule is expressed either as an alpha/alpha homodimer or an alpha/beta heterodimer on thymocytes and cytotoxic T cells, and functions as a coreceptor in concert with TCR for binding the MHC class I/peptide complex. Although CD8alpha/beta heterodimers have been shown to be more effective coreceptors, the precise role of the beta-chain in TCR-mediated thymic maturation and T cell activation is not understood. To understand the role of CD8beta in mediating CD8/MHC class I interaction, we examined whether cell surface CD8alpha/beta heterodimer promotes better cell-cell adhesion with MHC class I than the CD8alpha/alpha homodimer. The abilities of different forms of CD8 to adhere to MHC class I were measured with a cell-cell binding assay. Using a wild-type CD8beta and -alpha, we found that CD8alphabeta heterodimers did not mediate greater cell-cell adhesion than CD8alphaalpha homodimers. Furthermore, we found that chimeric CD8beta-alpha homodimers afforded no detectable binding. These results do not support the idea that CD8alphabeta binding to MHC class I is greater than that of CD8alphaalpha. Rather, they point to an alternative explanation in which CD8beta may play an role in promoting CD8/TCR interaction and/or in signaling/regulatory pathways.

Amplification of a gene coding for human T-cell differentiation antigen.

Using previously isolated mouse L-cell transferents for the human T-cell differentiation antigen Leu-2, we now report the first example of spontaneous gene amplification for membrane antigens. The Leu-2 (or T8) antigen is normally expressed on T lymphocytes that have cytotoxic or suppressor functions. Cells of a Leu-2 transfected clone were stained with fluorescein-tagged monoclonal anti-Leu-2, and the brightest 0.1-0.3% of cells were viably separated using a fluorescence activated cell sorter (FACS). After growth of these selected cells, sorting and regrowth was repeated six times, resulting in a population of cells that, compared with the starting population, stains 40 times brighter for Leu-2 and whose DNA transforms 20 times more efficiently for Leu-2. In addition, these cells have 10- to 50-fold amplified human DNA sequences and numerous double minute chromosome fragments, a common indicator of gene amplication in mouse cells.

A secreted form of the human lymphocyte cell surface molecule CD8 arises from alternative splicing.

The human lymphocyte differentiation antigen CD8 is encoded by a single gene that gives rise to a 33- to 34-kDa glycoprotein expressed on the cell surface as a dimer and in higher molecular mass forms. We demonstrate that the mRNA is alternatively spliced so that an exon encoding a transmembrane domain is deleted. This gives rise to a 30-kDa molecule that is secreted and exists primarily as a monomer. mRNA corresponding to both forms is present in peripheral blood lymphocytes, Con A-activated peripheral blood lymphocytes, and three CD8+ T-cell lines, with the membrane form being the major species. However, differences in the ratio of mRNA for membrane CD8 and secreted CD8 exist. In addition, the splicing pattern we observe differs from the pattern found for the mouse CD8 gene. This mRNA is also alternatively spliced, but an exon encoding a cytoplasmic region is deleted, giving rise to a cell surface molecule that differs in its cytoplasmic tail from the protein encoded by the longer mRNA. Neither protein is secreted. This is one of the first examples of a different splicing pattern between two homologous mouse and human genes giving rise to very different proteins. This represents one mechanism of generating diversity during speciation.