Interferon-mediated induction of class I MHC products in human neuronal cell lines: analysis of HLA and beta 2-m RNA, and HLA-A and HLA-B proteins and polymorphic specificities

Mechanism of effective combination radio-immunotherapy against 9464D-GD2, an immunologically cold murine neuroblastoma

BACKGROUND

Most pediatric cancers are considered immunologically cold with relatively few responding to immune checkpoint inhibition. We recently described an effective combination radio-immunotherapy treatment regimen ( c ombination a daptive- i nnate immunotherapy r egimen (CAIR)) targeting adaptive and innate immunity in 9464D-GD2, an immunologically cold model of neuroblastoma. Here, we characterize the mechanism of CAIR and the role of major histocompatibility complex class I (MHC-I) in the treatment response.

METHODS

Mice bearing GD2-expressing 9464D-GD2 tumors were treated with CAIR (external beam radiotherapy, hu14.18-IL2 immunocytokine, CpG, anti-CD40, and anti-CTLA4) and tumor growth and survival were tracked. Depletion of specific immune cell lineages, as well as testing in immunodeficient R2G2 mice, were used to determine the populations necessary for treatment efficacy. Induction of MHC-I expression in 9464D-GD2 cells in response to interferon-γ (IFN-γ) and CAIR was measured in vitro and in vivo, respectively, by flow cytometry and quantitative real-time PCR. A cell line with IFN-γ-inducible MHC-I expression (9464D-GD2-I) was generated by transfecting a subclone of the parental cell line capable of expressing MHC-I with GD2 synthase and was used in vivo to assess the impact of MHC-I expression on responsiveness to CAIR.

RESULTS

CAIR cures some mice bearing small (50 mm3) but not larger (100 mm3) 9464D-GD2 tumors and these cured mice develop weak memory responses against tumor rechallenge. Early suppression of 9464D-GD2 tumors by CAIR does not require T or natural killer (NK) cells, but eventual tumor cures are NK cell dependent. Unlike the parental 9464D cell line, 9464D-GD2 cells have uniformly very low MHC-I expression at baseline and fail to upregulate expression in response to IFN-γ. In contrast, 9464D-GD2-I upregulates MHC-I in response to IFN-γ and is less responsive to CAIR.

CONCLUSION

Treatment with CAIR cures 9464D-GD2 tumors in a NK cell dependent manner and induction of MHC-I by tumors cells was associated with decreased efficacy. These results demonstrate that the early tumor response to this regimen is T and NK cell independent, but that NK cells have a role in generating lasting cures in the absence of MHC-I expression by tumor cells. Further strategies to better inhibit tumor outgrowth in this setting may require further NK activation or the ability to engage alternative immune effector cells.

Epigenetic state determines inflammatory sensing in neuroblastoma

Immunotherapy has revolutionized cancer treatment, but many cancers are not impacted by currently available immunotherapeutic strategies. Here, we investigated inflammatory signaling pathways in neuroblastoma, a classically "cold" pediatric cancer. By testing the functional response of a panel of 20 diverse neuroblastoma cell lines to three different inflammatory stimuli, we found that all cell lines have intact interferon signaling, and all but one lack functional cytosolic DNA sensing via cGAS-STING. However, double-stranded RNA (dsRNA) sensing via Toll-like receptor 3 (TLR3) was heterogeneous, as was signaling through other dsRNA sensors and TLRs more broadly. Seven cell lines showed robust response to dsRNA, six of which are in the mesenchymal epigenetic state, while all unresponsive cell lines are in the adrenergic state. Genetically switching adrenergic cell lines toward the mesenchymal state fully restored responsiveness. In responsive cells, dsRNA sensing results in the secretion of proinflammatory cytokines, enrichment of inflammatory transcriptomic signatures, and increased tumor killing by T cells in vitro. Using single-cell RNA sequencing data, we show that human neuroblastoma cells with stronger mesenchymal signatures have a higher basal inflammatory state, demonstrating intratumoral heterogeneity in inflammatory signaling that has significant implications for immunotherapeutic strategies in this aggressive childhood cancer.

New immunotherapeutic strategies for the treatment of neuroblastoma

The prognosis of high-risk neuroblastoma (NB) is still poor, in spite of aggressive multimodal treatment. Recently, adjuvant immunotherapy with anti-GD2 antibodies combined with IL-2 or GM-CSF has been shown to improve survival. Several other immunotherapy strategies proved efficacy in preclinical models of NB, including different types of vaccines, adoptive cell therapies and combined approaches. The remarkable differences in the immunobiology of syngeneic models and human NB may, at least in part, limit the translation of preclinical therapies to a clinical setting. Nonetheless, several preliminary evidences suggest that new antibodies, cancer vaccines and adoptive transfer of lymphocytes, genetically engineered to acquire NB specificity, may result in clinical benefit, and clinical studies are currently ongoing.

Parallel declines in cognition, motivation, and locomotion in aging mice: association with immune gene upregulation in the medial prefrontal cortex

Aging in humans is associated with parallel changes in cognition, motivation, and motoric performance. Based on the human aging literature, we hypothesized that this constellation of age-related changes is mediated by the medial prefrontal cortex and that it would be observed in aging mice. Toward this end, we performed detailed assessments of cognition, motivation, and motoric behavior in aging mice. We assessed behavioral and cognitive performance in C57Bl/6 mice aged 6, 18, and 24 months, and followed this with microarray analysis of tissue from the medial prefrontal cortex and analysis of serum cytokine levels. Multivariate modeling of these data suggested that the age-related changes in cognition, motivation, motor performance, and prefrontal immune gene expression were highly correlated. Peripheral cytokine levels were also correlated with these variables, but less strongly than measures of prefrontal immune gene upregulation. To determine whether the observed immune gene expression changes were due to prefrontal microglial cells, we isolated CD11b-positive cells from the prefrontal cortex and subject them to next-generation RNA sequencing. Many of the immune changes present in whole medial prefrontal cortex were enriched in this cell population. These data suggest that, as in humans, cognition, motivation, and motoric performance in the mouse change together with age and are strongly associated with CNS immune gene upregulation.

What is the role of alternate splicing in antigen presentation by major histocompatibility complex class I molecules?

The expression of major histocompatibility complex (MHC) class I molecules on the cell surface is critical for recognition by cytotoxic T lymphocytes (CTL). This recognition event leads to destruction of cells displaying MHC class I-viral peptide complexes or cells displaying MHC class I-mutant peptide complexes. Before they can be transported to the cell surface, MHC class I molecules must associate with their peptide ligand in the endoplasmic reticulum (ER) of the cell. Within the ER, numerous proteins assist in the appropriate assembly and folding of MHC class I molecules. These include the heterodimeric transporter associated with antigen processing (TAP1 and TAP2), the heterodimeric chaperone-oxidoreductase complex of tapasin and ERp57 and the general ER chaperones calreticulin and calnexin. Each of these accessory proteins has a well-defined role in antigen presentation by MHC class I molecules. However, alternate splice forms of MHC class I heavy chains, TAP and tapasin, have been reported suggesting additional complexity to the picture of antigen presentation. Here, we review the importance of these different accessory proteins and the progress in our understanding of alternate splicing in antigen presentation.

Interferon-gamma-dependent infiltration of human T cells into neuroblastoma tumors in vivo

PURPOSE

To investigate the impact of interferon-gamma-mediated upregulation of major histocompatibility complex class I expression on tumor-specific T-cell cytotoxicity and T-cell trafficking into neuroblastoma tumors in vivo.

EXPERIMENTAL DESIGN

Restoration of major histocompatibility complex class I expression by interferon-gamma treatment enhances killing of neuroblastoma cells. To understand the potential of this approach in vivo, we developed a novel model of neuroblastoma in which NOD/scid/IL2R gamma(null) immunodeficient mice are engrafted with both human T cells and tumor cells.

RESULTS

Here, we show enhanced killing of neuroblastoma cells by patient-derived, tumor-specific T cells in vitro. In addition, interferon-gamma treatment in vivo induces efficient upregulation of major histocompatibility complex class I expression on neuroblastoma tumor cells, and this is accompanied by significantly enhanced infiltration of T cells into the tumor. In a pilot clinical trial in patients with high-risk neuroblastoma, we similarly observed augmented T-cell trafficking into neuroblastoma nests in tumor biopsy specimens obtained from patients after 5 days of systemic interferon-gamma therapy.

CONCLUSIONS

Interferon-gamma overcomes critical obstacles to the killing of human neuroblastoma cells by specific T cells. Together, these findings provide a rationale for the further testing of interferon-gamma as an approach for improving the efficacy of T cell-based therapies for neuroblastoma and other major histocompatibility complex class I-deficient malignancies. In addition, we describe a model that may expedite the preclinical screening of approaches aimed at augmenting T-cell trafficking into human tumors.

Human Neuroblastoma Cells Trigger an Immunosuppressive Program in Monocytes by Stimulating Soluble HLA-G Release

HLA-G is overexpressed in different tumors and plays a role in immune escape. Because no information is available on HLA-G in relation to human neuroblastoma, we have investigated the expression of membrane-bound and secretion of soluble isoforms of HLA-G in neuroblastoma and functionally characterized their immunosuppressive activities. At diagnosis, serum soluble HLA-G (sHLA-G) levels were significantly higher in patients than in age-matched healthy subjects. In addition, patients who subsequently relapsed exhibited higher sHLA-G levels than those who remained in remission. Neuroblastoma patient sera selected according to high sHLA-G concentrations inhibited natural killer (NK) cell and CTL-mediated neuroblastoma cell lysis. Such lysis was partially restored by serum depletion of sHLA-G. In 6 of 12 human neuroblastoma cell lines, low HLA-G surface expression was not up-regulated by IFN-gamma. Only the ACN cell line secreted constitutively sHLA-G. IFN-gamma induced de novo sHLA-G secretion by LAN-5 and SHSY5Y cells and enhanced that by ACN cells. Primary tumor lesions from neuroblastoma patients tested negative for HLA-G. Neuroblastoma patients displayed a higher number of sHLA-G-secreting monocytes than healthy controls. Incubation of monocytes from normal donors with IFN-gamma or pooled neuroblastoma cell line supernatants significantly increased the proportion of sHLA-G-secreting cells. In addition, tumor cell supernatants up-regulated monocyte expression of CD68, HLA-DR, CD69, and CD71 and down-regulated IL-12 production. Our conclusions are the following: (a) sHLA-G serum levels are increased in neuroblastoma patients and correlate with relapse, (b) sHLA-G is secreted by monocytes activated by tumor cells rather than by tumor cells themselves, and (c) sHLA-G dampens anti-neuroblastoma immune responses.

Multiple defects of the antigen-processing machinery components in human neuroblastoma: immunotherapeutic implications

Low expression of human leukocyte antigen (HLA) class I in human tumors may be related to defects of the antigen-processing machinery (APM) components. Neuroblastoma cells are virtually HLA class I negative, but (i) the underlying mechanisms are unknown, and (ii) expression of the APM components has never been investigated. Here we have used a panel of novel monoclonal antibodies to proteasomal and immunoproteasomal components, chaperons and transporter associated with antigen processing (TAP) to characterize 24 stroma-poor neuroblastoma tumors and six neuroblastoma cell lines. Primary tumors showed defects in the expression of zeta, tapasin, TAP1 or TAP2, HLA class I heavy chain and beta2 microglobulin, LMP2 and LMP7, as compared to normal adrenal medulla. Neuroblastoma cell lines displayed roughly similar patterns of APM expression in comparison to primary tumors. Incubation of neuroblastoma cell lines with interferon-gamma caused upregulation of HLA class I molecules and reduced lysis by killer inhibitory receptor HLA ligand-matched NK cells. Defects in APM components explain reduced peptide loading on HLA class I molecules, their instability and failure to be expressed on the cell surface. HLA class I upregulation by interferon-gamma, although enhancing neuroblastoma cell recognition by cytotoxic T cells, dampens their susceptibility to NK cells.

Downregulation and/or release of NKG2D ligands as immune evasion strategy of human neuroblastoma

Neuroblastoma (NB) is a pediatric extracranial tumor characterized by downregulation of human leukocyte antigen class I and defects of the antigen processing machinery, two features that make it an appropriate target for natural killer (NK)-mediated lysis. NKG2D is an activating immunoreceptor expressed by cytotoxic T lymphocytes and NK cells. The ligands for NKG2D are the major histocompatibility complex class I-related chain (MIC)A and MICB glycoproteins, and the UL-16-binding proteins (ULBPs). Here, the expression of NKG2D ligands was investigated in human primary NB tumors and cell lines because scanty information is available on this issue. MICA, MICB, and ULBP transcripts were found in most tumors and cell lines. MICA protein was detected in some NB cell lines but not in primary tumors. A soluble form of MICA (sMICA) was identified in most patient sera and in some cell line supernatants. sMICA downregulated surface NKG2D in normal peripheral blood CD8(+) cells and decreased NK-mediated killing of MICA(+) NB cells. MICB was detected exclusively in the cytosol of primary tumors and cell lines. Approximately 50% of primary tumors expressed ULBP-2, but not ULBP-1 or -3. ULBP-3 was expressed in 5 of 9 cell lines, ULBP-2 in 2 of 9, whereas ULBP-1 was never detected. These studies delineate novel potential pathways of tumor escape and immunodeficiency in NB.

Lack of HLA-class I antigens in human neuroblastoma cells: analysis of its relationship to TAP and tapasin expression

We studied the constitutive and the interferon (IFN)-gamma-induced expression of HLA class I antigen heavy chain, beta2-microglobulin (beta2m), TAP-1, TAP-2 and tapasin in a panel of eleven neuroblastoma cell lines. Surface expression of HLA class I antigens was low in eight out of eight neuroblastoma cell lines bearing MYC-N amplification and/or 1p deletion, while two out of three neuroblastoma cell lines lacking these genetic alterations showed normal expression. IFN-gamma treatment restored HLA class I antigen surface expression in all neuroblastoma cell lines. Eight out of 11 neuroblastoma cell lines did not express TAP-1 mRNA and three of them also lacked TAP-2 mRNA. beta2 m mRNA was barely detectable or absent in five neuroblastoma cell lines, while tapasin mRNA was always expressed. IFN-gamma upregulated the expression of HLA class I heavy chain, beta2 m, TAP-1, TAP-2 and tapasin, as detected at mRNA or protein level. Post-transcriptional events were involved in altered TAP-1 and beta2 m expression in one peculiar neuroblastoma cell line. These data indicate that multiple mechanisms play a role in the HLA class I antigen-deficient phenotype of human neuroblastoma.

Changes in beta-2 microglobulin expression in prostate cancer

Increased shedding of beta-2 microglobulin (B2m, 11.8 kDa), a component of the major histocompatibility complex class I (MHC I), by tumor cells has significance with regard to escape from immune-surveillance, cellular proliferation, and tumor development and progression. Aberrant expression of MHC I is known to occur in prostate cancer (PCa) but not in benign prostatic hyperplasia. We have determined B2m released by PCa cells in culture and in the urine of 101 patients with advanced PCa by Western blotting and radioimmunoassay. B2m levels in the conditioned medium of human PCa cell lines and primary cultures derived from distant metastasis as well as in the urine of patients with bone and visceral metastasis were higher than normal and also higher than those from patients with local/regional extensions of the disease. In the group of patients with bone metastasis (66 patients), high urine B2m was associated with significantly shortened survival. In addition to the 11.8 kDa B2m, a high molecular weight B2m immunoreactivity of approximately 38 kDa was found in highly tumorigenic PC-3 cell line, but not in the relatively indolent DU-145 and LNCaP human PCa cell lines. The approximately 38 kDa B2m was found in the urine of several PCa patients but not of healthy controls examined by Western analysis. The conditioned medium of a prostatic small cell carcinoma cell line, NCI-H660, had high levels of chromogranin A and B2m, but prostate specific antigen was absent. In conclusion, increased B2m shedding was associated with distant metastasis of PCa and an abnormal B2m immunoreactivity was found in PCa.

Virus et auto-immunité

Les virus sont depuis longtemps associés aux maladies auto-immunes. Plusieurs mécanismes ont été proposés pour expliquer comment une infection virale peut annuler la tolérance immunitaire et initier un processus autoréactif spécifique d'organe. Nous discutons deux mécanismes potentiels d'initiation virale de l'autoimmunité, le mimétisme moléculaire et l'inflammation locale accompagnée d'activation. Ils jouent un rôle central dans le développement de l'auto-immunité et ne sont pas mutuellement exclusifs, ce qui leur permet une contribution individuelle à la maladie.Des arguments récents suggèrent un rôle supplémentaire des virus dans la réactivation et la chronicité des maladies auto-immunes.

Viruses, host responses, and autoimmunity

Conceptually, the initiation of autoimmune disease can be described as a three-stage process involving both genetic and environmental influences. This process begins with the development of an autoimmune cellular repertoire, followed by activation of these autoreactive cells in response to a localized target and, finally, the immune system's failure to regulate these self-reactive constituents. Viruses have long been associated with inciting autoimmune disorders. Two mechanisms have been proposed to explain how a viral infection can overcome immunological tolerance to self-components and initiate an organ-specific autoreactive process; these mechanisms are molecular mimicry and bystander activation. Both pathways, as discussed here, could play pivotal roles in the development of autoimmunity without necessarily excluding each other. Transgene technology has allowed us and others to examine more closely the roles of these mechanisms in mice and to dissect the requirements for initiating disease. These results demonstrate that bystander activation is the most likely explanation for disease development. Additional evidence suggests a further role for viruses in the reactivation and chronicity of autoimmune diseases. In this scenario, a second invasion by a previously infecting virus may restimulate already existing autoreactive lymphocytes, and thereby contribute to the diversity of the immune response.

A comparative analysis of neuroblastic and substrate-adherent human neuroblastoma cell lines

In human neuroblastoma cell cultures, two phenotypes with differing biological properties have been described: neuroblastic (N) and substrate-adherent (Schwannian or S). In nude mice, N cells are rapidly growing, clonigenic in soft agar, and tumorigenic, whereas S cells are not. The difference in malignant properties between these two cell types and their ability to interconvert in vitro may have clinical relevance. In an attempt to identify genes that may be important in the phenotypic differences and the interconversion, the authors analyzed five representative N and three S cell lines for differential expression of six genes relevant to uncontrolled growth. Beta2-microglobulin was the only gene measured that showed differential expression between the N and S cell lines. This finding supports the theory that beta2-microglobulin and class I MHC expression are markers for differentiation as well as the use of beta2-microglobulin as a differentiation marker in neuroblastoma. The data also suggest that a disregulation of the beta2-microglobulin gene may be partly responsible for the tumorigenicity of the N phenotype.

Interpreting MHC class I expression and class I/class II reciprocity in the CNS: reconciling divergent findings

MHC-restricted T cells are thought to contribute to clinical demyelination in MS and other circumstances. The step-by-step mechanisms involved and ways of controlling them are still being defined. Identification of the MHC+ cells in the CNS in situ has been controversial. This chapter reviews MHC expression in neural tissue, including normal, pathological, experimental, and developing tissue in situ and isolated cells in vitro. A basic pattern is defined, in which MHC expression is limited to nonneural cells and strongest class I and II expression are on different cell types. Variations from the basic pattern are reviewed. Ways of reconciling divergent findings are discussed, including the use of "mock tissue" to help choose between technical and biological bases for divergent findings, the potential contribution of internal antigen to the in situ staining patterns, and the possibility that class I upregulation is actively suppressed in situ. Functional implications of the observed patterns of MHC expression and ways of confirming the function of each MHC+ cell type in situ are described. It is suggested that modulating MHC expression in different cell types at different times or in different directions might be desirable.

Induction of HLA class I and class II expression in human T-lymphotropic virus type I-infected neuroblastoma cells

Human T-lymphotropic virus type I (HTLV-I) is associated with a neurologic disease, HTLV-I-associated myelopathy-tropical spastic paraparesis, in which both pathological and immunological changes are observed within the central nervous system. The pathogenesis of infection in HTLV-I-associated myopathy-tropical spastic paraparesis is not well understood with respect to the cell tropism of HTLV-I and its relationship to the destruction of neural elements. In this study, neuroblastoma cells were infected with HTLV-I by coculturing with HUT-102 cells to demonstrate that cells of neuronal origin are susceptible to this retroviral infection. HTLV-I infection of the neuroblastoma cells was confirmed by verifying the presence of HTLV-I gp46 surface antigens by flow cytometry and by verifying the presence of HTLV-I pX RNA by Northern (RNA) blotting and in situ hybridization techniques. To determine whether HTLV-I infection could potentially lead to changes in cell surface recognition by the immune system, the infected neuroblastoma cells were analyzed for altered HLA expression. The HTLV-I-infected, cocultured neuroblastoma cells were shown, through cell surface antigen expression and RNA transcripts, to express HLA classes I and II. In contrast, cocultured neuroblastoma cells that did not become infected with HTLV-I expressed only HLA class I. HLA class I expression was enhanced by the cytokines tumor necrosis factor alpha and gamma interferon and in the presence of HUT-102 supernatant. In this system, expression of HLA class I and II molecules appeared to be regulated by different mechanisms. HLA class I expression was probably induced by cytokines present in the HUT-102 supernatant and was not dependent on HTLV-I infection. HLA class II expression required HTLV-I infection of the cells. The observation of HTLV-I infection leading to HLA induction in these neuroblastoma cells provides a possible mechanism for immunologic recognition of infected neuronal cells.

Induction of class I major histocompatibility complex antigens on adult primate retinal neurons

The expression of class I major histocompatibility complex (MHC) antigens was examined on adult monkey and human retinal cells following injury caused by dissociation. In a panning assay, neurons and glia demonstrated a rapid induction of class I MHC antigens following enzymatic dissociation, and expression was sustained on regenerating neurons as well as on glia in culture. Class I MHC antigen expression was also enhanced following optic nerve crush of monkey eyes in vivo. These results suggest that the functions of class I MHC antigens may be relevant to primate CNS neurons and glia following injury.

The effects of gamma interferon on the natural killer and tumor cells of children with neuroblastoma. A preliminary report

Human neuroblastoma cells lack HLA-A,-B,-C molecules which can be induced in vitro by gamma interferon (gamma IFN). To test the hypothesis that the same induction would occur in vivo leading to tumor regression, a Phase I study was initiated. Seven patients with neuroblastoma were entered on a Phase I study of recombinant gamma IFN in children. Three received 0.05 mg/m2 intravenously (IV) three times a week, three received 0.1 mg/m2 for 4 weeks, and one patient withdrew from study before receiving adequate treatment for evaluation. No significant clinical response was seen. The side effects were fever and chills, and no serious toxicity occurred. Natural killer (NK) and lymphocyte activated killer (LAK) precursor activity of peripheral blood mononuclear cells was determined before and during treatment, and expression of HLA-A,B,C molecules was looked for on the tumor cells in the bone marrow of five patients. The NK activity initially low, reached control levels in six patients, but the increase was transient. The LAK precursor activity remained normal. Expression of HLA-A,B,C, initially absent, was induced on the neuroblastoma cells in four of six patients.

Interferon induces astrocyte maturation causing an increase in cholinergic properties of cultured human spinal cord cells

It has been well established that interferon-gamma (IFN-gamma) can modify the immune status of cells in the central nervous system (CNS) by inducing major histocompatibility antigens. Furthermore, it has been shown that endogenous IFN can be produced in the brain following viral infection and a form of IFN-alpha/beta can be produced by astrocytes in culture. Here we show that IFN can induce astrocyte maturation and alter neurotransmitter properties in cultured CNS neurons at a given developmental stage. IFN causes a dose-dependent increase in choline acetyltransferase activity and glial fibrillary acidic protein (GFAP) immunoreactivity in cultures of human embryonic spinal cord neurons. The GABAergic activity and the Thy1 immunoreactivity remain unchanged. IFN-gamma does not act directly on the neurons but via the nonneuronal cells, probably the astrocytes, which in turn stimulate the cholinergic traits. These studies could be important for demonstrating an action of the immune system on glial cell maturation and on the neurotransmitter phenotype expression in CNS neurons.

Phenotypic and molecular characterization of inducible human neuroblastoma cell lines

Two new neuroblastoma (NB) cell lines, NUB-6 and NUB-7, were established from recurrent and primary NB tumours respectively and identified conclusively as NB by their phenotypic characteristics, catecholamine production and N-myc amplification. The cell lines could be distinguished on the bases of distinctive growth patterns in monolayer culture and semi-solid media (collagen gel and agarose), neurite formation and their response to four classes of growth and differentiation modulators. The NUB-6 cell line consisted of two distinct cell subtypes, small typical neuroblasts and larger spheroid-forming cells, while NUB-7 was homogeneously neuroblastic. Class-I agents (dibutyrl cyclic AMP [dbcAMP], butyrate, and papaverine) inhibited growth of both cell lines, while only dbcAMP stimulated the formation of short neurites by NUB-6 neuroblast cells in monolayer culture and collagen. Of the class-II agents (vitamins), retinoic acid inhibited growth of both cell lines and stimulated formation of long neurites by NUB-6 cells and NUB-7 cells in later passages. In contrast, vitamin E inhibited growth of NUB-6 and late-passage NUB-7, but stimulated early passage NUB-7. The class III agent (nerve growth factor) resembled vitamin E. The class-IV agents (interferons; rIFN-alpha 2a and rIFN-gamma 1) inhibited growth of both cell lines in monolayer culture and agarose, but stimulated NUB-6 neuroblasts and early passage NUB-7 cells to form long neurites. Thus phenotypically distinct NB cell lines were established in vitro and shown to be differentially influenced by various growth and differentiation modulators. The potent effect of IFN suggests a role for these modulators in NB behaviour in vivo.

Molecular bases of the immune response to neural antigens

Long-standing ideas about the immune response to neural antigens can now be revised. While the brain may be ‘immunologically privileged’, the privilege is not absolute; both immune and autoimmune responses can occur. While the blood-brain barrier contributes to this immunological isolation, other factors are also important. One is the normal absence of products of the major histocompatibility complex (MHC) from neural tissue. Without these cell surface proteins, neural cells are protected from T cell-mediated immune surveillance. MHC expression and modulation in neural tissue, and the implications for understanding and control of the immune response to neural antigens, are reviewed below.