Phosphorylation of the retinoblastoma gene product is modulated during the cell cycle and cellular differentiation

Introduction of an exogenous retinoblastoma (RB) gene in RB-deficient retinoblastoma or osteosarcoma cells has been shown to suppress their neoplastic phenotype. In experiments designed to explore the potential mechanism of RB tumor suppression, we report here that the phosphorylation state of RB protein is modulated during normal cellular events. In resting cells, RB protein is present in its least phosphorylated form; in rapidly proliferating cells, RB protein is highly phosphorylated. Maximal phosphorylation is associated with S phase of the cell cycle. Induction of differentiation in several human leukemia cell lines by treatment with phorbol ester or retinoic acid leads to dephosphorylation of RB. Time course studies indicate that RB dephosphorylation precedes the total arrest of cell growth during differentiation. These observations strongly suggest that the function of RB protein is modulated by a phosphorylation/dephosphorylation mechanism during cell proliferation and differentiation.     

Stability of retinoblastoma gene expression determines the tumorigenicity of reconstituted retinoblastoma cells.

Mutational inactivation of the retinoblastoma gene (RB) is an invariant feature of the childhood eye cancer retinoblastoma and of tumor cells derived therefrom. In a previous study, retrovirus-mediated transfer of wild-type RB into cultured retinoblastoma cells resulted in a marked enlargement and reduced growth rate of these cells, as well as loss of their tumorigenic properties in nude mice. It was therefore difficult to separate the proposed growth-suppressing and tumor-suppressing activities of RB protein. Here, we show that clones of RB-reconstituted retinoblastoma cells can be isolated that stably express apparently normal RB protein for at least 20 months of continuous culture. These clones were indistinguishable from nonreconstituted cells by multiple parameters including morphology, growth rate, and cell cycle distribution. Despite similar phenotypes in culture, clones with stable RB expression were uniformly nontumorigenic in nude mice, whereas those that lost such expression regained their tumorigenic properties. These results indicate that the tumorigenicity of these cells is entirely determined by the presence or absence of exogenous RB protein expression and that suppression of tumorigenicity is distinct from inhibition of cellular growth in culture.     

Regulated expression of the RB "tumor suppressor gene" in normal lymphocyte mitogenesis: elevated expression in transformed leukocytes and role as a "status quo" gene.

Expression of the RB retinoblastoma tumor suppressor gene product is regulated early during the stimulation of normal human peripheral blood lymphocytes, suggesting a regulatory role for the amount of this protein in mitogenesis of normal cells. When normal human peripheral blood lymphocytes were mitogenically stimulated with pokeweed mitogen, bivariate flow cytometric measurements of cellular DNA and RB protein content showed an early decrease in the amount of RB protein per cell, anteceding onset of S phase. A subsequent increase in the amount of RB protein per cell occurred with cell proliferation. Thus the amount of RB protein relative to the total cell mass underwent a biphasic response with mitogenesis. The resulting proliferating cells had a slightly elevated level of RB protein per cell compared to the unstimulated cells. Comparison of other proliferating leukocytes to normal lymphocytes showed that both EBV virally transformed lymphocytes and human promyelocytic leukemia cells (HL-60) had elevated levels of RB protein per cell compared to normal peripheral blood lymphocytes. Mitogenic stimulation or transformation by other means thus is associated with regulation of the amount of RB protein per cell, suggesting a regulatory role for the RB protein in normal cell growth control.     

Retinoblastoma cancer suppressor gene product is a substrate of the cell cycle regulator cdc2 kinase.

The retinoblastoma gene product (RB) is a nuclear protein which has been shown to function as a tumor suppressor. It is phosphorylated from S to M phase of the cell cycle and dephosphorylated in G1. This suggests that the function of RB is regulated by its phosphorylation in the cell cycle. Ten phosphotryptic peptides are found in human RB proteins. The pattern of RB phosphorylation does not change from S to M phases of the cell cycle. Hypophosphorylated RB prepared from insect cells infected with an RB-recombinant baculovirus is used as a substrate for in vitro phosphorylation reactions. Of several protein kinases tested, only cdc2 kinase phosphorylates RB efficiently and all 10 peptides can be phosphorylated by cdc2 in vitro. Removal of cdc2 from mitotic cell extracts by immunoprecipitation causes a concomitant depletion of RB kinase activity. These results indicate that cdc2 or a kinase with similar substrate specificity is involved in the cell cycle-dependent phosphorylation of the RB protein.     

Detection of small RB1 gene deletions in retinoblastoma by multiplex PCR and high-resolution gel electrophoresis

Summary Loss of function of both copies of the RB1 gene is a causal event in the development of retinoblastoma. The predisposition to this tumor can be inherited as an autosomal dominant trait. Direct detection of the genetic defect is important for presymptomatic DNA diagnosis and genetic counseling in families with hereditary retinoblastoma. We have used multiplex polymerase chain reaction and high-resolution polyacrylamide gel electrophoresis to detect RB1 gene deletions as small as one base pair. By using three independent sets of amplification reactions, which cover 26% of the RB1 gene coding region, we identified RB1 gene deletions in the DNA of peripheral blood cells in 3 out of 24 (12.5%) unrelated patients with hereditary retinoblastoma. In one case, formalin-fixed paraffin-embedded tumor material was also used to detect the mutation. Sequencing of the mutated alleles revealed deletions of 1, 3 and 10 base pairs. Each deleted region was flanked by direct repeats.     

Role of the retinoblastoma protein in cell cycle arrest mediated by a novel cell surface proliferation inhibitor

A novel cell regulatory sialoglycopeptide (CeReS-18), purified from the cell surface of bovine cerebral cortex cells has been shown to be a potent and reversible inhibitor of proliferation of a wide array of fibroblasts as well as epithelial-like cells and nontransformed and transformed cells. To investigate the possible mechanisms by which CeReS-18 exerts its inhibitory action, the effect of the inhibitor on the posttranslational regulation of the retinoblastoma susceptibility gene product (RB), a tumor suppressor gene, has been examined. It is shown that CeReS-18 mediated cell cycle arrest of both human diploid fibroblasts (HSBP) and mouse fibroblasts (Swiss 3T3) results in the maintenance of the RB protein in the hypophosphorylated state, consistent with a late G1 arrest site. Although their normal nontransformed counterparts are sensitive to cell cycle arrest mediated by CeReS-18, cell lines lacking a functional RB protein, through either genetic mutation or DNA tumor virus oncoprotein interaction, are less sensitive. The refractory nature of these cells is shown to be independent of specific surface receptors for the inhibitor, and another tumor suppressor gene (p53) does not appear to be involved in the CeReS-18 inhibition of cell proliferation. The requirement for a functional RB protein product, in order for CeReS-18 to mediate cell cycle arrest, is discussed in light of regulatory events associated with density-dependent growth inhibition. © 1994 Wiley-Liss, Inc.     

Distinct patterns of expression of the RB gene family in mouse and human retina

Although RB1 function is disrupted in the majority of human cancers, an undefined cell of developing human retina is uniquely sensitive to cancer induction when the RB1 tumor suppressor gene is lost. Murine retinoblastoma is initiated only when two of the RB family of genes, RB1 and p107 or p130, are inactivated. Although whole embryonic retina shows RB family gene expression by several techniques, when E14 developing retina was depleted of the earliest differentiating cells, ganglion cells, the remaining proliferating murine embryonic retinal progenitor cells clearly did not express RB1 or p130, while the longer splice form of p107 was expressed. Each retinal cell type expressed some member of the RB family at some stage of differentiation. Rod photoreceptors stained for the RB1 protein product, pRB, and p107 in only a brief window of postnatal murine development, with no detectable staining for any of the RB family proteins in adult human and mouse rod photoreceptors. Adult mouse and human Muller glia, ganglion and rare horizontal cells, and adult human, but not adult mouse, cone photoreceptors stained for pRB. The RB gene family is dynamically and variably expressed through retinal development in specific retinal cells.     

Subcellular localization of the retinoblastoma protein

The subcellular localization of the retinoblastoma (RB) protein has been studied in primate cell lines by immunofluorescence staining using different monoclonal and polyclonal antibodies. The protein appeared as granules of heterogeneous size over the interphase nuclei. Computer assisted digital overlap analysis indicated that it was predominantly localized in euchromatic areas with low DNA density. The largest RB positive grains lined up on the heterochromatin/euchromatin boundary. During mitosis, the RB protein dissociated from the condensing chromosomes. It was dispersed throughout the cytoplasm during metaphase and anaphase, and it reassociated with the decondensing chromatin during telophase. A new monoclonal antibody, designated aRB1C1, was raised against a bacterial TrpE/human retinoblastoma protein. It specifically recognized the nonphosphorylated and differentially phosphorylated forms of the RB protein in immunoprecipitation experiments. A collection of RB expressing cell lines gave a positive staining reaction with the antibody, whereas the RB negative Weri-RB-27 retinoblastoma and OHS osteosarcoma cells failed to react. Wild-type RB complementary DNA was introduced into Weri-RB-27 by retrovirus mediated gene transfer. Similar experiments were performed with the DU145 prostatic carcinoma cell line that expresses a mutant RB protein. Reconstituted cells of both lines expressed the normal size RB protein and gave a positive immunofluorescence reaction with the aRB1C1 and other anti-RB antibodies. The new monoclonal antibody, however, showed cell type dependent differences of the staining pattern compared to other anti-RB antibodies, suggesting differentiation dependent accessibility to its epitope.     

Studies on the human retinoblastoma susceptibility gene

The retinoblastoma susceptibility (RB) gene is unique among other cloned cancer genes because its causal role in a human cancer, retinoblastoma, was established by classical genetic methods before its isolation. Earlier hypotheses and experimental data suggested that inactivation of a gene in chromosome band 13q14 resulted in retinoblastoma formation. A gene in this region was identified as the RB gene on the basis of mutations found specifically in retinoblastoma tumors; however, its proposed biological activity in suppressing neoplasia has yet to be demonstrated. The RB gene product was identified as a nuclear phosphoprotein of 110 kD associated with DNA binding activity, suggesting that the RB protein may regulate other genes. Probes for the RB gene and gene product will be useful for genetic diagnosis of retinoblastoma susceptibility in affected families; for direct detection of mutant RB alleles; and, potentially, for genetic diagnosis of susceptibility to osteosarcoma and other tumors tentatively linked to RB-gene dysfunction. Continued study of the RB gene should yield further insight into mechanisms of oncogenesis, development, and gene regulation.     

Tumorspheres but Not Adherent Cells Derived from Retinoblastoma Tumors Are of Malignant Origin

Verification that cell lines used for cancer research are derived from malignant cells in primary tumors is imperative to avoid invalidation of study results. Retinoblastoma is a childhood ocular tumor that develops from loss of functional retinoblastoma protein (pRb) as a result of genetic or epigenetic changes that affect both alleles of the RB1 gene. These patients contain unique identifiable genetic signatures specifically present in malignant cells. Primary cultures derived from retinoblastoma tumors can be established as non-adherent tumorspheres when grown in defined media or as attached monolayers when grown in serum-containing media. While the RB1 genotypes of tumorspheres match those of the primary tumor, adherent cultures have the germline RB1 genotype. Tumorspheres derived from pRb-negative tumors do not express pRb and express the neuroendocrine tumor markers synaptophysin and microtubule-associated protein 2 (MAP2). Adherent cells are synaptophysin-negative and express pRb, the epithelial cell marker cytokeratin that is expressed in the retinal pigmented epithelium and the vascular endothelial cell marker CD34. While tumorspheres are of malignant origin, our results cast doubt on the assumption that adherent tumor-derived cultures are always valid in vitro models of malignant cells and emphasize the need for validation of primary tumor cultures.     

RB基因与肿瘤抑制

RB基因位于13q14,全长150kb,编码一个由928个氨基酸组成的分子量为110 000蛋白(pp110RB).它能特异性与SV40大T,E1A和E7结合.在视网膜细胞中,RB呈衡定组成性表达,其缺陷除引起RB外,在骨肉瘤、乳腺癌、小细胞肺癌、软组织肉瘤及造血系统增生性疾病也有RB基因的突变.把RB基因导入到基因缺陷的恶性肿瘤细胞能全部或部分抑制其恶性表现.     

Nucleocytoplasmic shuttling of the retinoblastoma tumor suppressor protein via Cdk phosphorylation-dependent nuclear export

The retinoblastoma (RB) tumor suppressor protein is a negative regulator of cell proliferation that is functionally inactivated in the majority of human tumors. Elevated Cdk activity via RB pathway mutations is observed in virtually every human cancer. Thus, Cdk inhibitors have tremendous promise as anticancer agents although detailed mechanistic knowledge of their effects on RB function is needed to harness their full potential. Here, we illustrate a novel function for Cdks in regulating the subcellular localization of RB. We present evidence of significant cytoplasmic mislocalization of ordinarily nuclear RB in cells harboring Cdk4 mutations. Our findings uncover a novel mechanism to circumvent RB-mediated growth suppression by altered nucleocytoplasmic trafficking via the Exportin1 pathway. Cytoplasmically mislocalized RB could be efficiently confined to the nucleus by inhibiting the Exportin1 pathway, reducing Cdk activity, or mutating the Cdk-dependent phosphorylation sites in RB that result in loss of RB-Exportin1 association. Thus RB-mediated tumor suppression can be subverted by phosphorylation-dependent enhancement of nuclear export. These results support the notion that tumor cells can modulate the protein transport machinery thereby making the protein transport process a viable therapeutic target.     

Retinoblastoma tumor suppressor: where cancer meets the cell cycle

The retinoblastoma tumor suppressor gene, Rb, was the first tumor suppressor identified and plays a fundamental role in regulation of progression through the cell cycle. This review details facets of RB protein function in cell cycle control and focuses on specific questions that remain intensive areas of investigation.     

Expression of the human retinoblastoma gene product pp110RB in insect cells using the baculovirus system

The product of the retinoblastoma susceptibility gene (RB) was overproduced in cultured insect cells using the baculovirus expression system. Upon insertion of the cloned human RB complementary DNA sequence into the viral genome downstream of the promoter of the polyhedrin gene, full-length RB protein with an apparent molecular weight of 110,000 was expressed in the insect cells. This protein was found to be phosphorylated, located in the nuclei of the infected cells, and immunologically indistinguishable from pp110RB of human cells as assayed by several anti-RB antibodies. Following cell disruption and a one-step immunoaffinity chromatographic purification, 6-12 mg of soluble pp110RB with approximately 95% purity were obtained per liter of infected suspension culture. Characterization of the two known biochemical properties of RB protein showed that this purified protein from insect cells behaved similarly to the authentic human pp110RB. First, it bound to DNA, and second, it could form a specific complex with SV40 T antigen in vitro. Prompt translocation of the protein from cytoplasm to nucleus after microinjection further indicated that the purified RB protein may be active. The availability of soluble, intact, and presumably active pp110RB in large quantity represents a significant advance for studying the biochemical and biophysical properties of the RB gene product as well as its potential biological function in cancer suppression.     

Inducers of leukemic cell differentiation cause down-regulation of RB gene expression.

Expression of the retinoblastoma (RB) tumor suppressor gene during cell differentiation induced by dimethyl sulfoxide or sodium butyrate was studied in HL-60 human promyelocytic leukemia cells. As cells progressed through the cell cycle, the amount of RB protein per cell increased with homeostasis maintained, so that the amount of RB protein relative to the total cell mass remained almost constant. Dimethyl sulfoxide was used to induce these promyelocytic leukemia cells to undergo terminal differentiation into mature myeloid cells. There was an early reduction in the RB protein expressed per cell. The reduction in expression was similar for cells in all cell cycle phases. There was also progressively reduced expression at later times as cells terminally differentiated. This was compared to the case in which sodium butyrate was used to induce the differentiation of HL-60 cells into mature monocytic cells. An early reduction in RB protein expression per cell also occurred. It occurred for cells in all cell cycle phases as well. Thus, the induced differentiation of HL-60 cells along either the myeloid or the monocytic differentiation lineage involves an early reduction in RB expression, which is common to both pathways. The reduction anteceded proliferative arrest or differentiation. In both cases, the final, resulting G0-differentiated cells had less RB protein per cell than the proliferating, immature, leukemic precursor cells.     

The regions of the retinoblastoma protein needed for binding to adenovirus E1A or SV40 large T antigen are common sites for mutations

The protein product of the retinoblastoma (RB) gene is thought to function in a pathway that restricts cell proliferation. Recently, transforming proteins from three different classes of DNA tumor viruses have been shown to form complexes with the RB protein. Genetic studies suggest that these interactions with the RB protein are important steps in transformation by these viruses. In order to understand better the function of the RB-viral oncoprotein complexes, we have mapped the regions of the RB protein that are necessary for these associations. Two non-contiguous regions of RB were found to be essential for complex formation with adenovirus E1A or SV40 large T antigen. These two regions are found between amino acids 393 and 572 and 646 and 772. Interestingly, these binding sites on RB overlap with the positions of naturally occurring, inactivating mutations of the RB gene. These results strongly suggest that these viral oncoproteins are targeting a protein domain that is an important site in the normal function of the RB protein.     

The 100-kDa Proteolytic Fragment of RB Is Retained Predominantly within the Nuclear Compartment of Apoptotic Cells

The retinoblastoma tumor suppressor protein (RB) has been shown to play a role in regulating the eukaryotic cell cycle, promoting cellular differentiation, and modulating programmed cell death. Although regulation of RB tumor suppressor activity is mediated by reversible phosphorylation, an additional posttranslational modification involves the cleavage of 42 residues from the carboxy terminus of RB during the onset of drug-induced or receptor-mediated apoptosis. We now demonstrate that a recombinant p100cl RB species localizes to the nucleus where it may retain wildtype “pocket” protein binding activity. In addition, using immunocytochemistry, we show that cleavage of the endogenous RB protein occurs in vivo in human cells and that p100cl is predominantly retained within the nuclear compartment of cells during early apoptosis. We also show that the carboxy-terminal cleavage of RB is detected immediately following caspase-3 and PARP cleavage during FAS-mediated apoptosis of MCF10 cells. These findings suggest that this cleavage event may be a component of a downstream cascade during programmed cell death.     

How the other half lives, the amino-terminal domain of the retinoblastoma tumor suppressor protein

The retinoblastoma tumor suppressor gene (RB1) is currently the only known gene whose mutation is necessary and sufficient for the development of a human cancer. Mutation or deregulation of RB1 is observed so frequently in other tumor types that compromising RB1 function may be a prerequisite for malignant transformation. Identifying the molecular mechanisms that provide the basis for RB1-mediated tumor suppression has become an important goal in the quest to understand and treat cancer. The lion's share of research on these mechanisms has focused on the carboxy-terminal half of the RB1 encoded protein (pRB). This focus is with good reason since this part of the protein, now called the "large pocket," is required for most of its known activities identified in vitro and in vivo. Large pocket mediated mechanisms alone, however, cannot account for all observed properties of pRB. The thesis presented here is that the relatively uncharacterized amino-terminal half of the protein makes important contributions to pRB-mediated tumor suppression. The goals of this review are to summarize evidence indicating that an amino-terminal structural domain is important for pRB function and to suggest a general hypothesis as to how this domain can be integrated with current models of pRB function.