Pathogenesis of influenza virus infections: the good, the bad and the ugly.

The clinical outcome of different influenza virus infections ranges from subclinical upper respiratory tract disease to fatal lower respiratory tract disease. An important determinant in the pathogenesis of these diseases is the tissue tropism of the influenza virus. Furthermore, virulence is often correlated with virus replication and is regulated by multiple virus genes. Host defense against virus infection consists of both innate and adaptive immune responses. However, excessive or dysbalanced immune response may result in lung tissue damage, reduced respiratory capacity, and severe disease or even death. By interdisciplinary efforts to better understand the intricate interaction between virus, tissue, and immune response, we may be able to find new ways to improve the outcome of influenza virus infections.

HLA-G2, -G3, and -G4 isoforms expressed as nonmature cell surface glycoproteins inhibit NK and antigen-specific CTL cytolysis.

HLA-G is a nonclassical MHC class I molecule that plays a major role in maternal-fetal tolerance. Four membrane-bound (HLA-G1 to -G4) and two soluble (HLA-G5, and -G6) proteins are generated by alternative splicing. Only HLA-G1 has been extensively studied in terms of both expression and function. We provide evidence here that HLA-G2, -G3, and -G4 truncated isoforms reach the cell surface of transfected cells, as endoglycosidase H-sensitive glycoproteins, after a 2-h chase period. Moreover, cytotoxicity experiments show that these transfected cells are protected from the lytic activity of both innate (NK cells) and acquired (CTL) effectors. These findings highlight the immunomodulatory role that HLA-G2, -G3, and -G4 proteins will assume during physiologic or pathologic processes in which HLA-G1 expression is altered.

HLA-G1 co-expression boosts the HLA class I-mediated NK lysis inhibition.

It is now acknowledged that the pattern of HLA-G expression is not restricted to extravillous cytotrophoblast cells, as several studies described HLA-G in HLA class I+ cells, such as thymic epithelial cells, cytokine-activated monocytes and some tumors. In these situations, HLA-G may provide an additional inhibitory signal to escape from NK cell-mediated cytotoxicity. Accordingly, the aim of this study was to define the behavior of HLA-G once it is co-expressed into an HLA-A, -B, -C and -E+ cell line. For this purpose, HLA-G1 cDNA was transfected into an HLA class I+ melanoma cell line which was used as a target towards freshly isolated peripheral blood NK cells. Cytotoxic experiments using either anti-HLA-G1 or anti-HLA-G1 inhibitory receptor mAb show that HLA-G1 boosts the HLA class I-mediated inhibition of polyclonal NK cells through interaction with ILT-2, which appears as the major HLA-G1 inhibitory receptor involved. Nevertheless, HLA-G1 is also able to inhibit the cytolytic activity of an ILT-2- NK clone which otherwise expresses another HLA-G1 inhibitory receptor belonging to the KIR103 gene family. In order to more precisely define the relative role exerted by HLA-G1 versus -E on polyclonal NK cells, antibody-blocking assays were carried out using either anti-HLA class I or anti-CD94/NKG2A. Results demonstrate that in the absence of HLA-G1, the naturally expressed HLA class I-mediated NK inhibition is predominantly exerted by HLA-E through binding with CD94/NKG2A. In contrast, once HLA-G1 is expressed, it becomes the major NK inhibitory ligand.

HLA-G truncated isoforms can substitute for HLA-G1 in fetal survival.

Pregnancy is considered as an immunologic paradox because the fetus can be viewed as a semiallograft by the mother's immune system. Among the different factors implicated in the maternal-fetal tolerance, a central role has been attributed to HLA-G. The primary HLA-G mRNA is alternatively spliced, encoding four membrane-bound isoforms (HLA-G1, -G2, -G3, and -G4), and three soluble forms (HLA-G5, -G6, and -G7). Whereas HLA-G1 is expressed on trophoblast cells, HLA-G2, -G3, and -G4 isoforms have been only identified as transcripts in trophoblast and term placentas. In this work, we first showed that these HLA-G transcripts are translated into proteins in first trimester cytotrophoblast cells. Then, using a target cell line transfected with HLA-G genomic DNA, we analyzed the functional implication of HLA-G isoforms expression on NK function. Our results show that not only HLA-G1, but also the other HLA-G truncated isoforms, can inhibit NK cytolysis and therefore contribute to immune privilege for the fetus.

Role of HLA-G versus HLA-E on NK function: HLA-G is able to inhibit NK cytolysis by itself.

Recent studies have shown that endogenous HLA-E molecules are stabilized on the cell surface upon the expression of HLA-G which contains within its leader sequence, a nonapeptide capable of binding with the HLA-E/beta2m complex. Since HLA-E was found to be the major ligand for the CD94/NKG2A inhibitory receptor, we determined the role of HLA-G versus HLA-E on NK lysis inhibition. We showed that K562 cells transfected with HLA-G1 cDNA are protected from NK lysis by direct interaction between HLA-G1 and killing inhibitory receptor(s). This NK lysis inhibition is not dependent on HLA-E expression, since no HLA-E protein was detected on K562 cells; HLA-G1 is therefore able to inhibit NK lysis by itself.

HLA-G expression in human melanoma cells: protection from NK cytolysis.

Expression of the non-classical HLA-G class I antigen is physiologically restricted to a limited number of tissues including trophoblasts, and is thought to play a role in establishing tolerance of the fetus by the maternal immune system. We investigated whether ectopic expression of HLA-G could also be detected in tumor cells and confer them the ability to escape immune cytotoxic responses. High levels of all alternatively spliced HLA-G transcripts could be detected in melanoma cells by RT-PCR. Analysis of biopsies from a melanoma patient revealed a higher HLA-G transcription level in skin metastasis as compared to healthy skin, while specific amplification of the HLA-G5 transcript was only observable in the tumor. HLA-G protein expression could also be detected in two melanoma cell lines. HLA-G-positive tumors inhibit cytotoxic lysis by the NK cell line YT2C2-PR. This inhibition is not observed with B-EBV cell lines bearing matched class I specificities, and is thought to occur through interaction of HLA-G with inhibitory receptors that are distinct from known KIRs interacting with HLA-E or classical class I molecules. Together, these results confirm that HLA-G expression at the surface of tumor cells can participate in the evasion of antitumoral immune responses and favor tumor progression.

HLA-G inhibits the allogeneic proliferative response.

HLA-G is a non-classical MHC class I molecule expressed at the feto/maternal interface where it plays a role in materno-fetal tolerance by inhibiting NK cells. Expression of killing inhibitory receptors capable of interacting with HLA-G on T lymphocytes led us to hypothesize that HLA-G molecules could also modulate T cell responses, analyzed here in the context of the allogeneic proliferative response. Using LCL-HLA-G transfectants as stimulators of T cells present among peripheral mononuclear cells and K562-HLA-G1 transfectants as inhibitors in a classical mixed lymphocyte reaction, we showed that HLA-G is able to inhibit T cell allo-proliferation. These findings provide new insight into the role of HLA-G in preventing allograft rejection.

HLA-G-mediated inhibition of antigen-specific cytotoxic T lymphocytes.

In the present study, we demonstrate that the non-classical MHC class I molecule HLA-G impairs specific cytolytic T cell functions in addition to its well-established inhibition of NK lysis. The antigen-specific cytotoxic T lymphocyte (CTL) response analyzed was mediated by CD8(+) T cells specific for the influenza virus matrix epitope, M58-66, presented by HLA-A2. The transfection of HLA-G1 cDNA in target cells carrying the M58-66 epitope reduced their lysis by these virus-specific CTL. This HLA-G-mediated inhibition of antigen-specific CTL lysis was (i) peptide dose dependent, (ii) reversed by blocking HLA-G with a specific mAb and (iii) still observed despite the blockade of HLA-E/CD94/NKG2A interaction. By inhibiting both CTL and NK functions, HLA-G appears to have an extensive role in immune tolerance.

The immunotolerance role of HLA-G.

HLA-G is a non-classical MHC class I molecule involved in immune tolerance. We present our results concerning the effects of HLA-G on the cellular immune response, where it impairs both NK and T cell functions. We describe the NK inhibitory properties of HLA-G ex vivo, demonstrating its role in materno-fetal tolerance, which is supported by our in vitro studies using membrane-bound HLA-G1- and HLA-G2-transfected cells and a full-length soluble HLA-G molecule. We also report how HLA-G interacts at the T cell level, here exemplified by its inhibitory effect on both T cell allogeneic proliferative and Ag-specific CTL responses.

Brain-derived neurotrophic factor and neurotrophin-3 enhance somatostatin gene expression through a likely direct effect on hypothalamic somatostatin neurons.

Although neurotrophins (NTs) have been extensively studied as neuronal survival factors in some areas of the central nervous system, little is known about their function or cellular targets in the hypothalamus. To understand their functional significance and sites of action on hypothalamic neurons, we examined the effects of their cognate ligands on neuropeptide content and messenger RNA (mRNA) expression in somatostatin neurons present in fetal rat hypothalamic cultures. Treatments were performed in defined insulin-free medium between days 6 and 8 of culture, since the maximal effects of NTs on somatostatin content and mRNA expression were observed after 48-h incubations. Brain-derived neurotrophic factor and NT-3, but not nerve growth factor, induced a dose-dependent increase in somatostatin content, which was influenced by plating density. The same treatment increased somatostatin mRNA and immunostaining intensity of somatostatin neurons, but had no effect on the number of these labeled neurons. The increased levels of somatostatin (peptide and mRNA) induced by NTs were not blocked by tetrodotoxin or by glutamate receptor antagonists, suggesting that endogenous neurotransmitters (e.g. glutamate) were not involved in these effects. In contrast, the stimulatory effects were completely blocked by K-252a, an inhibitor of tyrosine kinase (Trk) receptors, whereas the less active analog K-252b was ineffective. Double-labeling studies demonstrated that both TrkB or TrkC receptors were located on somatostatin neurons. Our results show that, in rat hypothalamic cultures, brain-derived neurotrophic factor, and NT-3 have a potent stimulatory effect on peptide synthesis in somatostatinergic neurons, likely through direct activation of TrkB and TrkC receptors.

HLA-G expression in melanoma: a way for tumor cells to escape from immunosurveillance.

Considering the well established role of nonclassical HLA-G class I molecules in inhibiting natural killer (NK) cell function, the consequence of abnormal HLA-G expression in malignant cells should be the escape of tumors from immunosurveillance. To examine this hypothesis, we analyzed HLA-G expression and NK sensitivity in human malignant melanoma cells. Our analysis of three melanoma cell lines and ex vivo biopsy demonstrated that (i) IGR and M74 human melanoma cell lines exhibit a high level of HLA-G transcription with differential HLA-G isoform transcription and protein expression patterns, (ii) a higher level of HLA-G transcription ex vivo is detected in a skin melanoma metastasis biopsy compared with a healthy skin fragment from the same individual, and (iii) HLA-G protein isoforms other than membrane-bound HLA-G1 protect IGR from NK lysis. It thus appears of critical importance to consider the specific role of HLA-G expression in tumors in the design of future cancer immunotherapies.