Cycling of gut mucosal CD4+ T cells decreases after prolonged anti-retroviral therapy and is associated with plasma LPS levels.

The gut mucosa is an important site of HIV immunopathogenesis with severe depletion of CD4+ T cells occurring during acute infection. The effect of prolonged anti-retroviral therapy (ART) on cycling and restoration of T lymphocytes in the gut remains unclear. Colon and terminal ileal biopsies and peripheral blood samples were collected from viremic, untreated, HIV-infected participants, patients treated with prolonged ART (>5 years), and uninfected controls and analyzed by flow cytometry. In the gut, the proportion of cycling T cells decreased and the number of CD4+ T cells normalized in treated patients in parallel with beta 7 expression on CD4+ T cells in blood. Cycling of gut T cells in viremic patients was associated with increased plasma LPS levels, but not colonic HIV-RNA. These data suggest that gut T-cell activation and microbial translocation may be interconnected whereas prolonged ART may decrease activation and restore gut CD4+ T cells.

[HPV infection: comparison between morphological studies and molecular biology]. / L'infezione da HPV: confronto diagnostico tra indagini morfologiche e biologia molecolare.

Human Papilloma Virus plays an essential role in the development of cervical cancer. We investigated the global prevalence of Human Papilloma Virus infection in a population of 699 women recruited at the Ospedali Riuniti in Foggia for gynaecological controls from September 2005 to March 2007, and compared with a group of 90 women, selected on clinical aspects for Human Papilloma Virus features. The observed prevalence was 27.4%, which is higher that that reported in the literature. In the study group, the most frequent viral type was 16, while type 18 was considerably less frequent compared with other emergent viral types (39, 52, 56, 58, 59). The high prevalence of Human Papilloma Virus-DNA in women with negative cytology or inflammatory changes raises doubts about the utility of the Human Papilloma Virus-DNA method as a primary screening test because of the low cost/benefit ratio. The absence of uniform and standardised reports does not allow objective comparison between different methods of analysis (cytology, colposcopy and molecular biology), pointing out the need for a unique centre for collection and data analysis.

CD1d expression on B-precursor acute lymphoblastic leukemia subsets with poor prognosis.

Acute lymphoblastic leukemia (ALL) is the most frequent malignancy of childhood. Although therapeutical advances have been achieved, some ALL subgroups still fare poorly. CD1d is a monomorphic molecule that provides a suitable target for immunotherapy in view of the characterization of a glycolipid, alpha-galactosylceramide (alpha-GalCer), capable of being presented to CD1d-restricted T cells with cytotoxic potential. We investigated CD1d expression in 80 pediatric B-cell precursor (BCP) ALL cases defined according to immunophenotype, cytogenetic features and age at onset. CD1d was detected on ALL cells in 15% of the patients. CD1d+ ALLs were significantly associated with infant leukemia, pro-B phenotype and mixed-lineage leukemia (MLL)/AF4 gene rearrangement. Accordingly, overall survival of patients with CD1d+ ALL was significantly shorter. CD1d+ leukemic blasts were able to present alpha-GalCer via CD1d to cytotoxic CD1d-restricted T cells, which induced apoptosis of ALL cells that was inhibited by mAb to CD1d. CD1d+ blasts loaded with alpha-GalCer elicited cytokine secretion by CD1d-restricted T cells. Analysis of bone marrow (BM) cells derived from normal donors revealed that CD19+/CD1d+ cells were mostly mature B lymphocytes. However, a minority of BCPs expressed CD1d. Thus, expression of CD1d in ALL cases heralds an adverse prognosis but may provide a therapeutic tool.

CD85/LIR-1/ILT2 and CD152 (cytotoxic T lymphocyte antigen 4) inhibitory molecules down-regulate the cytolytic activity of human CD4+ T-cell clones specific for Mycobacterium tuberculosis.

Antigen-specific cytolytic CD4+ T lymphocytes control Mycobacterium tuberculosis infection by secreting cytokines and by killing macrophages that have phagocytosed the pathogen. However, lysis of the latter cells promotes microbial dissemination, and other macrophages engulf the released bacteria. Subsequently, CD4+ T-cell-mediated killing of macrophages goes on, and this persistent process may hamper control of infection, unless regulatory mechanisms maintain a subtle balance between lysis of macrophages by cytolytic CD4+ cells and activation of cytolytic CD4+ cells by infected macrophages. We asked whether inhibitory molecules expressed by CD4+ cytolytic T lymphocytes could play a role in such a balance. To this end, human CD4+ T-cell clones specific for M. tuberculosis were produced that displayed an autologous major histocompatibility complex class II-restricted lytic ability against purified protein derivative (PPD)-pulsed antigen-presenting cells. All T-cell clones expressed CD152 (cytotoxic T-lymphocyte antigen 4 [CTLA-4]) and CD85/leukocyte immunoglobulin-like receptor 1 (LIR-1)/immunoglobulin-like transcript 2 (ILT2) inhibitory receptors, but not CD94 and the killer inhibitory receptor (or killer immunoglobulin-like receptor [KIR]) p58.2. CD3-mediated activation of the clones was inhibited in a redirected killing assay in which CD152 and CD85/LIR-1/ILT2 were cross-linked. Specific antigen-mediated proliferation of the clones was also sharply reduced when CD152 and CD85/LIR-1/ILT2 were cross-linked by specific monoclonal antibody (MAb) followed by goat anti-mouse antiserum. In contrast, blockade of the receptors by specific MAb only increased their proliferation. Production of interleukin 2 (IL-2) and gamma interferon (IFN-gamma) by the T-cell clones was also strongly reduced when CD152 and CD85/LIR-1/ILT2 were cross-linked. The lytic activity of the T-cell clones against PPD-pulsed autologous monocytes or Epstein-Barr virus-activated B cells was increased by blockade and decreased by cross-linking of the receptors. These results indicate that CD152 and CD85/LIR-1/ILT2 play a role in the regulation of the antigen-specific activity of CD4+ cytolytic T lymphocytes against PPD-presenting cells.

A novel human homologue of the SH3BGR gene encodes a small protein similar to Glutaredoxin 1 of Escherichia coli.

Glutaredoxins (GRXs) are ubiquitous GSH-dependent oxidoreductases, which catalyze the reduction of protein-glutathionyl-mixed disulfides and are considered to play an important role in the enzymatic regulation of redox-sensitive proteins. In this paper, we describe the identification and characterization of a new human homologue of the SH3BGR gene, named SH3BGRL3 (SH3 domain binding glutamic acid-rich protein like 3). SH3BGRL3 is widely expressed and codes for a highly conserved small protein, which shows a significant similarity to Glutaredoxin 1 (GRX1) of Escherichia coli and is predicted to belong to the Thioredoxin Superfamily. However, the SH3BGRL3 protein lacks both the conserved cysteine residues, which characterize the enzymatic active site of GRX. This structural feature raises the possibility that SH3BGRL3 could function as an endogenous modulator of GRX biological activity. EGFP-SH3BGRL3 fusion protein expressed in COS-7 cells localizes both to the nucleus and to the cytoplasm. The SH3BGRL3 gene was mapped to chromosome 1p34.3-35.

Cytokine gene expression and T-cell proliferative responses in lymph node mononuclear cells from children with early stage human immunodeficiency virus infection.

BACKGROUND AND OBJECTIVES: The immunologic events taking place in secondary lymphoid tissue from children with early stage human immunodeficiency virus (HIV) infection are poorly understood. The aim of this study was to investigate cytokine gene expression and proliferative responses in lymph node (LN) biopsies from five children with early stage HIV infection, in the context of LN morphology and viral load. DESIGN AND METHODS: The design of the study was approved by the local Ethical Committee. Cytokine gene expression was studied in LN biopsies and in paired peripheral blood (PB) samples from HIV-infected children by reverse transcriptase-polymerase chain reaction. T-cell proliferation was assessed by 3H-thymidine incorporation. Viral burden in germinal centers was assessed by video densitometric analysis following immunohistochemical staining for HIV p24. RESULTS: Interleukin (IL)-2, IL-4 and IL-5 mRNA were not detected in any LN or PB sample from HIV-infected children. Interferon (IFN)-gamma mRNA was found only in CD8+ cells. IL-12 p35, IL-10, transforming growth factor-(TGF)-beta1, regulated on activation normal T-cell expressed and secreted (RANTES), macrophage inflammatory protein (MIP)-1alpha, MIP-1beta and IL-16 transcripts were detected in all samples. Proliferation of LN and PB mononuclear cells to polyclonal mitogens and soluble (recall and HIV-related) antigens was impaired as compared with the responses in a group of age-matched healthy controls. INTERPRETATION AND CONCLUSIONS: Changes in cytokine gene expression and T-cell proliferative responses are already detectable in lymph nodes from HIV-infected children at an early stage of disease.

The CD85/LIR-1/ILT2 inhibitory receptor is expressed by all human T lymphocytes and down-regulates their functions.

The inhibitory molecule CD85/LIR-1/ILT2 has been detected previously on the surface of a small proportion of T lymphocytes. In this study, evidence is provided that, although only a fraction of CD3+ cells are stained by mAb specific for CD85/LIR-1/ILT2 on their surface, this inhibitory receptor is present in the cytoplasm of all T lymphocytes, and that it is detectable on the surface of all T cell clones by the M402 mAb. Biochemical analyses further demonstrate that CD85/LIR-1/ILT2 is present in all T clones analyzed, and that the protein is tyrosine-phosphorylated. Expression of mRNA coding for CD85/LIR-1/ILT2 has been assessed by RT-PCR. Notably, in the NKL cell line and in one T cell clone, amplification of the messenger required 30 cycles only, whereas, in other T cell clones, an amplification product was detected by increasing the number of cycles. CD85/LIR-1/ILT2 inhibits CD3/TCR-mediated activation in both CD4+ and CD8+ clones, and it down-regulates Ag recognition by CD8+ cells in a clonally distributed fashion. Addition of anti-ILT2 HP-F1 mAb in the cytolytic assay enhances target cell lysis mediated by Ag-specific CTL. This could be due to interference of the mAb with receptor/ligand interactions. In contrast, HP-F1 mAb cross-linking triggers inhibitory signals that reduce cytotoxicity. CD85/LIR-1/ILT2 also controls responses to recall Ags and, in low responders, its engagement sharply increases T cell proliferation. The inhibitory function of the molecule is also confirmed by its ability to reduce CD3/TCR-induced intracellular Ca2+ mobilization.

A video densitometric analysis of viral burden and follicular dendritic cell damage in lymph nodes in the latency phase of HIV infection.

BACKGROUND: The aim of this study was to collect quantitative data on damage to follicular dendritic cells (FDC) and on the structure of germinal centers (GC) in the early phase of HIV infection. METHODS: Lymph node sections from 10 HIV(+) subjects and from 5 HIV(-) control subjects were stained by immunohistochemistry for CD21, an FDC marker; gp24, to assess the HIV load; and IgM, to measure antibodies within the GC. RESULTS: The volume fraction (V(area)) and the logarithm of the inverse gray value (ArLIGV) of CD21 areas showed a highly significant decrease in HIV(+) specimens. The mean ArLIGV values ranged between 0.0916 +/- 0.01 and 0.3826 +/- 0.11 versus 0.6856 +/- 0.19 on average in controls (P < 0.001 for both). Six of 10 HIV(+) specimens were positive for gp24. Staining was limited to GC and showed a distribution pattern similar to that of CD21. CONCLUSIONS: FDC already undergo considerable damage during the latency phase of HIV infection. The pattern of CD21 indicates that, although FDC decrease in number, the staining intensity of positive cells is basically preserved. Video densitometric analysis, an approach requiring a strict standardized protocol, may help monitor disease course and evaluate response to therapy by quantifying viral burden and lymph node damage.

Molecules that inhibit T-cell functions: cytochemical localization and shuttling.

Adaptive immune responses to antigens are mediated by specific receptors expressed on B cells (BCR's) and T cells (TCR's). Effector cells and memory cells are produced following a proliferative wave that accounts for clonal expansion. If not down-regulated, clonal expansion might lead to uncontrolled lymphoproliferation that would be harmful for the organism. Several mechanisms that account for the down-sizing of activated lymphocyte clones are briefly reviewed here. We next consider in detail one such mechanism that deals with the functional characterization and the immunocytochemical localization of two T-cell inhibitory molecules, namely the Cytotoxic T Lymphocyte Antigen-4 (CTLA-4) and the HP-F1 antigen, both present in all T lymphocytes. CTLA-4 and HP-F1 inhibit CD4+ T-helper cell proliferation and the lytic ability of CD8+ T-cytotoxic cells in non-specific and in antigen-specific cytolytic assays. Interestingly, a clonal distribution exists as for the ability of CTLA-4 and HP-F1 to inhibit T-cell functions. In resting and activated T cells, both molecules are largely confined in the endosomal compartment, as shown by immunofluorescence analyses. However, upon interaction of T cells with Antigen-Presenting Cells (APC's) or with target cells that must be killed, CTLA-4 molecules are transported to the plasma membrane, at the site of cell-to-cell contact where, following interaction with ligands, they trigger inhibitory signals.

Cell activation via CD44 occurs in advanced stages of squamous cell carcinogenesis.

Squamous cell carcinoma (SCC) derives from dysplastic or metaplastic stratified epithelia. The process of squamous cell carcinogenesis has been investigated for the potential role of the adhesion molecule CD44, whose standard form (CD44s) and isoforms generated by alternative splicing of variant exons are known to display altered expression during tumorigenesis in other systems. We have utilized an in vitro correlate of squamous cell carcinogenesis, in which progression stages from normal squamous epithelium to dysplastic lesions and to SCC are represented by primary cultures of normal keratinocytes, by human papilloma virus-immortalized keratinocytes (UP) and by HPVimmortalized/v-Ha-ras transfected tumorigenic keratinocytes (UPR). We investigated expression of CD44 and of variant isoforms, from mRNA to intracellular and surface protein levels, and found no relationship between expression of CD44 and stages of squamous cell carcinogenesis. However, when the function of CD44 was analyzed as Ca(2+) mobilization ability upon monoclonal antibody binding and crosslinking, signal transduction via CD44 was found only for the neoplastic stage (UPR cells). Ca(2+) mobilization was completely independent of density of surface CD44. We have performed similar analyses in an in vitro model of SCC in which four squamous tumor cell lines and UPR cells were sorted according to increasing resistance to external cytotoxic stimuli, i.e. starving conditions, treatment with the retinoid N-(4-hydroxyphenyl)retinamide and cytolytic activity of effector lymphokine-activated killer cells. No relationship between expression of CD44 and level of cell resistance against external cell death-inducing stimuli was found, while CD44-mediated Ca(2+) mobilization ability was restricted to the highly resistant tumor cell lines. Our results indicate that the role(s) of CD44 in squamous cell proliferative disorders can be evinced from the functional features of the molecule, rather than from its phenotypic repertoire.

Anatomy of the immune system: facts and problems.

In the introductory section of this report, the anatomy of the immune system, from organs and tissues to molecules, will be reviewed briefly. Cell proliferation and differentiation in the central lymphoid organs (thymus and bone marrow) yield a repertoire of T- and B-cell clones that seed into peripheral lymphoid organs (spleen, lymph nodes and Mucosa-Associated Lymphoid Tissue, MALT), where humoral and cell-mediated antigen-specific immune responses occur. The stringent process of clonal selection in the central lymphoid organs implies deletion of inappropriate cells via apoptosis. In the peripheral lymphoid organs, the potential of unlimited activation and expansion of lymphocytes in response to antigens is primarily regulated by apoptosis and anergy. These events, on the one hand, are relevant to prevent autoimmunity and lymphoproliferative disorders; on the other hand, clonal deletion and anergy provide a detrimental escape to immune recognition of malignant cells. Two major inhibitory mechanisms of the immune response have emerged recently. One is linked to the existence of bona fide suppressor cells and cytokines; the other relies on the existence of inhibitory molecules expressed by T, B and NK cells, as well as by other leukocytes. In the studies herein reported, emphasis will be given to surface membrane molecules that down-regulate T-cell-mediated immune responses. These molecules control interactions between T cells and antigen presenting cells (APC's) or target (virus-infected or mutated) cells that have to be killed. Two sets of molecules exist that either upregulate (coactivation molecules) or down-regulate (inhibitory molecules) T-cell mediated responses. The latter aspect of the immune regulation, i.e. molecules that limit the expansion of T-cell clones following specific recognition of antigens will be considered in depth. Two inhibitory molecules, CD152 (CTLA-4) and CD85/LIR-1/ILT2 are expressed in all T cells, being largely confined within intracellular compartments of these lymphocytes when they are in a resting state, but ready to be shuttled to and from the plasma membrane when cells are activated following encounter with antigen. Membrane expression of the two inhibitory molecules is transient and is regulated by an internalization process directed to endosomal compartments and to receptor degradation and/or recycling. CTLA-4 and CD85/LIR-1/ILT2 play a pivotal role in T-cell homeostasis that follows any cell-mediated immune response; their localization and functional role will be thoroughly analyzed. In the last part of this study a major question will be faced, i.e. is the containment of the possibly unlimited expansion of the immune system due to a blockade of the cell cycle? Or, else, could be apoptosis the sole mechanism responsible? Experimental data in support of the latter contention will be provided.

A novel pleckstrin homology-related gene family defined by Ipl/Tssc3, TDAG51, and Tih1: tissue-specific expression, chromosomal location, and parental imprinting.

We previously described a gene, Ipl (Tssc3), that is expressed selectively from the maternal allele in placenta, yolk sac, and fetal liver and that maps within the imprinted domain of mouse distal Chromosome (Chr) 7/human Chr 11p15.5 (Hum Mol Genet 6, 2021, 1997). Ipl is similar to TDAG51, a gene that is involved in FAS/CD95 expression. Here we describe another gene, Tih1 (TDAG/Ipl homologue 1), with equivalent sequence similarity to Ipl. Structural prediction indicates that the products of these three genes share a central motif resembling a pleckstrin-homology (PH) domain, and TIH1 protein has weak sequence similarity to the PH-domain protein SEC7/CYTOHESIN. Like Ipl, Tih1 is a small gene with a single small intron. Tih1 maps to distal mouse Chr 1 and human Chr 1q31, chromosomal regions that have not shown evidence for imprinting and, in contrast to Ipl, Tih1 is expressed equally from both parental alleles. Ipl, Tih1, and TDAG51 have overlapping but distinct patterns of expression. Tih1 and TDAG51 are expressed in multiple fetal and adult tissues. In contrast, during early mouse development Ipl mRNA and protein are highly specific for two tissues involved in maternal/fetal exchange: visceral endoderm of the yolk sac and labyrinthine trophoblast of the placenta. These findings highlight the dominance of chromosomal context over gene structure in some examples of parental imprinting and extend previous evidence for placenta-specific expression of imprinted genes. The data also define a new subfamily of PH domain genes.

CTLA-4 (CD152) inhibits the specific lysis mediated by human cytolytic T lymphocytes in a clonally distributed fashion.

Since the functional outcome of effector T lymphocytes depends on a balance between activatory and inhibitory receptors, we studied the ability of CTLA-4 (CD152) to inhibit the cytolytic function of CTL. In 22 TCR alpha/beta+ CD3+ 8+ CTL clones, activation induced by anti-CD3, anti-CD28, or anti-CD2 mAb was inhibited by anti-CD152 mAb in a redirected killing assay. In eight clones inhibition was >40%, in 10 it ranged between 20-40%, and in four it was <20%. This suggests the existence of a clonal heterogeneity as well as for the ability of CTLA-4 to inhibit CD3/TCR-, CD28-, or CD2-mediated CTL activation. To support further this contention, we used an experimental model based upon Ag-specific CTL. Eight Ag-specific T cell clones that lyse autologous EBV-infected B lymphocytes, but are unable to lyse allogeneic EBV-infected B cell lines, were used in a cytolytic assay in which anti-CD152 mAb or soluble recombinant receptor (i.e., CTLA-4 Ig) were included. In this system, at variance from the redirected killing assay, cross-linking of surface molecules by mAb does not occur. Thus, addition of anti-CD152 mAb or of CTLA-4 Ig and anti-CD80/CD86 mAb to the assay should result in a blockade of receptor/ligand interactions. As a consequence, inhibition of a negative signal, such as that delivered via CD152, should enhance lysis. A >40% increment of target cell lysis was achieved in three of eight clones studied. Since it is not equally shared by all CTL clones, this feature also appears to be clonally distributed.

Lymphoid complement of the human salivary glands: function and pathology.

In normal human salivary glands the Duct-Associated Lymphoid Tissue (DALT) is poorly developed. In contrast, in the course of autoimmune disorders, typified by Sjögren's syndrome (SS), organized lymphoid accumulations are formed around the ducts. B cell-dependent zones with secondary follicles and T cell-dependent zones with HEV are detected in these lymphoid structures. In addition, the duct epithelium is infiltrated by abundant lymphocytes. A persistent antigenic stimulation may lead to development of B-cell Mucosa-Associated Lymphoid Tissue (MALT) lymphomas that, in low-grade cases, maintain the lobular organization of normal and of SS salivary glands.

HIV is trapped and masked in the cytoplasm of lymph node follicular dendritic cells.

To gain further insight into the pathogenesis of human immunodeficiency virus (HIV) infection, lymph nodes from seven asymptomatic HIV+ subjects were analyzed during the latent phase of disease. Both ultrastructural and immunohistochemical analyses revealed that, in all of the cases, plasma cells producing IgM/gamma were present in germinal centers. Secreted immunoglobulins formed extracellular deposits mimicking the follicular dendritic cell network. Immunoglobulin produced by germinal center plasma cells are specific for HIV because they bind the HIV env protein gp 120. Plasma cells producing antibodies with the same specificity were also abundant in the extrafollicular regions of lymph nodes. During the latent phase of infection, the virus largely accumulates within the germinal centers. Therefore, extracellular immunoglobulin may form immune complexes, as shown by the presence of HIV-specific antibodies, HIV particles, and complement components C3c, C3d, and C1q in the interdendritic spaces. When the ultrastructural localization of HIV in germinal centers was analyzed, abundant virus particles were found in the interdendritic spaces. In addition to this extracellular localization of HIV, receptor-mediated endocytosis of viral particles by follicular dendritic cells was observed. Complete HIV particles were found within the endosomal compartment of the follicular dendritic cells and, as complete viral particles, free in the cytoplasm, indicating that the virus may escape from the endocytic compartment. As the virus is abundant in the cytoplasm, this event leads to formation of a hidden reservoir within follicular dendritic cells. In this location, HIV escapes recognition by cytotoxic T lymphocytes. In contrast, virus budding indicating a productive infection of follicular dendritic cells that would render them susceptible to T-cell-mediated lysis has been seldom observed.

General role of HLA class I molecules in the protection of target cells from lysis by natural killer cells: evidence that the free heavy chains of class I molecules are not sufficient to mediate the protective effect.

Some HLA-C alleles have been shown to exert a specific protective effect preventing target cells from lysis by groups of natural killer (NK) clones displaying a defined specificity. In this study, we analyzed whether class I-mediated protection is a more general phenomenon involving all NK cells. First, we utilized two anti-class I mAbs (6A4 of IgG1 isotype and A6-136 of IgM isotype), which had been shown to induce lysis of protected target cells by group 1 and group 2 NK clones. Addition of A6-136 or 6A4 used as F(ab')2 mAb resulted in lysis of protected target cells by all NK clones analyzed. Target cells were represented by a panel of HLA homozygous Epstein-Barr virus-transformed B cell lines (B-EBV) while NK clones were representative of clones displaying different GL183/EB6 surface phenotypes and/or different abilities to lyse allogeneic cells. Unselected NK clones derived from seven different individuals were tested against autologous target cells represented by phytohemagglutinin-induced blasts or B-EBV transformed cell lines. In both instances, addition of a mixture of 6A4 F(ab')2 and A6-136 mAbs resulted in lysis of autologous target cells, thus suggesting that class I molecules prevent lysis of normal cells by self NK cells. We further investigated whether the class I-mediated protection requires the complexed form of class I molecules (composed of alpha chain, beta 2-microglobulin and the antigen peptide) or rather the free alpha chain. Acidic treatment of the C1R (Cw4+) target cells or 81.22 (Cw3+, Cw4+) at pH 2.2 resulted in loss of reactivity with 6A4, A6-136 and W6-32 mAb (known to react with the assembled form of class I molecules) and in the de novo reactivity with L31 mAb (specific for the HLA-C free chain). While the untreated Cw+ C1R cells were resistant to lysis by the Cw4-specific group 1 NK clones, the pH 2.2-treated cells became highly susceptible to lysis by the same clones. These data indicate that, at least for the NK clones analyzed, the protection of target cells requires class I molecules in the complexed form.

Peptide specificity in the recognition of MHC class I by natural killer cell clones.

Recognition by natural killer (NK) cells of major histocompatibility complex (MHC) class I molecules on target cells inhibits NK-mediated lysis. Here, inhibition of NK clones by HLA-B*2705 molecules mutated at single amino acids in the peptide binding site varied among HLA-B*2705-specific NK clones. In addition, a subset of such NK clones was inhibited by only one of several self peptides loaded onto HLA-B*2705 molecules expressed in peptide transporter-deficient cells, showing that recognition was peptide-specific. These data demonstrate that specific self peptides, complexed with MHC class I, provide protection from NK-mediated lysis.

The human natural killer cell receptor for major histocompatibility complex class I molecules. Surface modulation of p58 molecules and their linkage to CD3 zeta chain, Fc epsilon RI gamma chain and the p56lck kinase.

The natural killer cell (NK)-specific p58 surface molecules, recognized by the GL183 and EB6 monoclonal antibodies (mAb), have been shown to represent the putative NK receptor for HLA-C molecules. The interaction between p58 receptors and HLA-C results in inhibition of the NK-mediated target cell lysis. In this study, GL183-EB6+ clones (Cw4-specific), after mAb-induced surface modulation of EB6 molecules, acquired the ability to lyse the Cw4+ C1R cells. In NK clones co-expressing both GL183 and EB6 molecules and unable to kill Cw3-protected target cells, the mAb-induced modulation of EB6 molecules resulted both in selective co-modulation of GL183 molecules and in the lysis of Cw3-transfected P815 murine cells. In line with the co-modulation experiments we also show that the GL183 and EB6 molecules can be co-immunoprecipitated from GL183+/EB6+ clones after cell lysis in the presence of digitonin. The p58 receptor also revealed an association with molecules belonging to the zeta family (i.e. CD3 zeta and Fc epsilon RI gamma chains). Two-dimensional diagonal gel analysis of the p58 complex immunoprecipitated from polyclonally activated p58+ NK cells indicated a preferential association with CD3 zeta chains either in the form of covalently linked zeta-zeta homodimers or in the form of zeta-gamma heterodimers, while gamma-gamma homodimers were detectable in low amounts. However, p58+ clones displaying a unique association with gamma-gamma homodimers could also be isolated. Probing the immunoprecipitated p58 complex with anti-p56lck antibody also revealed an association with this member of the src family. In addition, mAb-mediated signaling of NK clones via p58 molecules induced increments of p58/p56lck association. However, under the same experimental conditions that induced optimal in vivo tyrosine phosphorylation of the CD16-associated CD3 zeta chains, no tyrosine phosphorylation was detected in the p58-associated CD3 zeta chains. In these in vivo experiments neither anti-CD16 nor anti-p58 mAb could induce tyrosine phosphorylation of the gamma chains. Finally, the anti-p58-mediated inhibition of the NK cell triggering via CD16 molecules was not accompanied by a down-regulation of the tyrosine phosphorylation of the CD16-associated CD3 zeta chains.