Retinoblastoma protein regulation of surface CD74 (invariant chain) expression in breast carcinoma cells

The RB tumor suppressor at the intersection of proliferation and immunity: relevance to disease immune evasion and immunotherapy

The retinoblastoma tumor suppressor (RB) was the first identified tumor suppressor based on germline predisposition to the pediatric eye tumor. Since these early studies, it has become apparent that the functional inactivation of RB is a common event in nearly all human malignancy. A great deal of research has gone into understanding how the loss of RB promotes tumor etiology and progression. Since malignant tumors are characterized by aberrant cell division, much of this research has focused upon the ability of RB to regulate the cell cycle by repression of proliferation-related genes. However, it is progressively understood that RB is an important mediator of multiple functions. One area that is gaining progressive interest is the emerging role for RB in regulating diverse features of immune function. These findings suggest that RB is more than simply a regulator of cellular proliferation; it is at the crossroads of proliferation and the immune response. Here we review the data related to the functional roles of RB on the immune system, relevance to immune evasion, and potential significance to the response to immune-therapy.

Retinoblastoma protein potentiates the innate immune response in hepatocytes: significance for hepatocellular carcinoma

Cancers mediated by viral etiology must exhibit deregulated cellular proliferation and evade immune recognition. The role of the retinoblastoma tumor suppressor (RB) pathway, which is lost at relatively high frequency in hepatocellular carcinoma (HCC), has recently been expanded to include the regulation of innate immune responsiveness. In this study we investigated the coordinate impact of RB-loss on cell cycle control and immune function in the liver. We found that RB depletion in hepatoma cells resulted in a compromised immunological response to multiple stimuli and reduced the potential of these cells to recruit myeloid cells. Viral-mediated liver-specific RB deletion in vivo led to the induction of genes associated with proliferation and cell cycle entry as well as the significant attenuation of genes associated with immune function, as evidenced by decreases in cytokine and chemokine expression, leukocyte recruitment, and hepatic inflammation. To determine if these changes in gene expression were instructive in human disease, we compared our liver-specific RB-loss gene signature to existing profiles of HCC and found that this signature was associated with disease progression and confers a worse prognosis.

CONCLUSION

Our data confirm that RB participates in the regulation of innate immunity in liver parenchymal cells both in vitro and in vivo and to our knowledge describes the first gene signature associated with HCC that includes both immunoregulatory and proliferative genes and that can also be attributed to the alteration of a single gene in vitro.

pRB is required for interferon-gamma-induction of the MHC class II abeta gene

pRB is required for IFN-gamma-induction of MHC class II in human tumor cell lines, providing a potential link between tumor suppressors and the immune system. However, other genes, such as cyclin D1, show pRB-dependency only in tumor cells, so by analogy, pRB may not be necessary for cII-regulation in normal cells. Here, we demonstrate that induction of the mouse MHC class II I-A heterodimer is normal in RB+/+ mouse embryonic fibroblasts (MEFs), but deficient in RB-/- MEFs. Inducibility is restored in RB-/- MEFs stably transfected with wild type RB cDNA or infected with an adenovirus expressing pRB. Thus, involvement of pRB in MHC class II expression is conserved in the mouse and is not an aberrant feature of tumorigenic, aneuploid, human tumor cells. Although cII genes are generally induced in a coordinate fashion, suggesting a common mechanism, we found that pRB was specifically required for induction of the Abeta, but not Aalpha or other MHC cII genes including Ebeta, Ii and H2-Malpha. Finally, IFN-gamma-induction of class II transactivator (CIITA), was pRB-independent, suggesting that pRB works downstream of this master-regulator of MHC class II expression.

Retinoblastoma protein expression facilitates chromatin remodeling at the HLA-DRA promoter

The major histocompatibility complex (MHC) class II genes encode a series of heterodimeric cell surface glycoproteins that bind peptide antigen. The MHC class II/peptide complex is bound by the T-cell receptor of CD4(+) T cells, thereby stimulating an immune response. The MHC class II genes are coordinately regulated by conserved promoter elements and are inducible by IFN-gamma. Furthermore, IFN-gamma induction of the MHC class II genes in solid human tumor lines requires retinoblastoma protein (Rb). In vivo footprinting analyses of the HLA-DRA gene, which encodes the heavy chain subunit of the human MHC class II molecule, HLA-DR, revealed that Rb facilitates occupancy of multiple HLA-DRA promoter elements. Detecting the effect of Rb on HLA-DRA promoter occupancy in vivo required IFN-gamma treatment. However, use of a variation on the in vivo footprinting technique, nuclei footprinting, which assays for promoter occupancy in isolated nuclei, revealed that expression of Rb facilitates promoter occupancy even in the absence of IFN-gamma. These results indicate that expression of Rb leads to modification of the chromatin environment of the HLA-DRA promoter independently of transcription.

Effects of vitamin D3 on proliferation of cancer cells in vitro

The principal cause of death from most forms of cancer is metastatic disease. Cancer cells appear to grow quickly out of the control of the normal host regulatory mechanisms. Many factors contribute to this unrestrained proliferation, including increased metalloproteinase activity causing degradation of the extracellular matrix surrounding cancer cells, angiogenesis permitting easy access of the cells to the bloodstream and decrease or loss of programmed cell death, or apoptosis, an important mechanism for removal of abnormal or senescent cells. Treatment modalities targeted towards arresting cancer cell proliferation and spread are needed to improve the survival of patients with cancer. Vitamin D3, 1,25-dihydroxychole-calciferol D3, has been shown to induce apoptosis in the human breast cancer cell line, MCF-7. We have studied the effects of three concentrations of vitamin D3 on the human breast cancer cell line, MDA-MB-435, the human prostate cancer cell line, LNCaP, and a human osteosarcoma cell line, U20S. We report here that vitamin D3 strikingly inhibits cell proliferation and induces apoptosis in all three cell lines.

IFN-gamma inducibility of class II transactivator is specifically lacking in human tumour lines: relevance to retinoblastoma protein rescue of IFN-gamma inducibility of the HLA class II genes

We have previously reported that HLA class II induction by IFN-gamma is rescuable by reconstitution of functional retinoblastoma protein (RB) in two RB-defective tumour lines: the breast carcinoma line, MDA-468-S4 (S4) and the non-small cell lung carcinoma line, H2009. To determine the range of tumours and tumour types in which RB rescues HLA class II inducibility, we examined another RB-defective tumour line, the retinoblastoma line, WERI-Rb1. As in the case of S4 and H2009, HLA-DRA and -DRB were non-inducible by IFN-gamma in WERI-Rb1. However, neither inducibility of DRA nor DRB mRNA was resulted in an RB-positive stable transformant of WERI-Rb1, WLRB-8. While guanylate-binding protein (GBP) inducibility indicated that the basic IFN-gamma signal transduction pathway remained intact in WERI-Rb1, mRNA for class II transactivator (CIITA), a mediator of the IFN-gamma activation of the HLA class II genes and several other genes related to immune function, was not detectable in IFN-gamma-treated WERI-Rb1, indicating that the lack of CIITA expression was responsible, at least in part, for the inability of RB to rescue HLA class II-inducibility. The HLA class II-associated invariant chain (Ii), the expression of which is also up-regulated by CIITA, was non-inducible in WERI-Rb1, consistent with non-inducible CIITA. Also, IFN-gamma failed to activate the DRA, DRB and Ii promoters in WERI-Rb1. However, exogenous CIITA expression in WERI-Rb1 activated the DRA, DRB and Ii promoter-chloramphinocol acetyltransferase constructs, confirming that CIITA was not induced in WERI-Rb1 and indicating that other proteins required for activation of the class II and Ii promoters were functional in this cell line. Examination of additional cell lines for GBP and CIITA induction revealed that a specific lack of the CIITA IFN-gamma response is common in human tumour lines. The possible role of CIITA defects in tumorigenesis is discussed.

RB and a novel E2F-1 binding protein in MHC class II deficient B-cell lines and normal IFN-gamma induction of the class IL transactivator CIITA in class II non-inducible RB-defective tumor lines

The major histocompatibility (MHC) class II genes encode cell surface proteins that bind antigenic peptide for presentation to T-cells. The class II proteins are expressed constitutively on B-cells and EBV-transformed B-cells, and are inducible by IFN-gamma on a wide variety of cell types. Retinoblastoma protein (RB) is a tumor suppressor and functions as a transcriptional repressor by binding and inactivating the transactivator E2F-I. RB-defective tumor lines are non-inducible for MHC class II by IFN-gamma, or very weakly inducible, but transfection of 2 different lines with RB expression vectors re-establishes or substantially enhances class II inducibility. Therefore, we examined the RB status of a series of B-cell mutants that are defective in class II expression, generated either in vitro or derived from Bare Lymphocyte Syndrome (BLS) patients. Nuclear matrix-bound RB was detectable in all cases, indicating that loss of RB is not responsible for decreased class II expression in these lines. A second E2F-I binding protein, most likely DP-I, was also apparently normal in both class II-positive and -negative B-cell lines. We also examined the IFN-gamma induction of CIITA in RB-defective lines. CIITA is a class II gene transactivator known to be defective in one form of BLS and to be required for the induction of MHC class II by IFN-gamma. CIITA mRNA is normally inducible by IFN-gamma in class II non-inducible, RB-defective lines, and in one line, re-expression of RB has no effect on CIITA mRNA induction levels. Thus, the block in MHC class II inducibility in RB-defective cells is not due to a block in CIITA inducibility.