The E2F transcription factor is a cellular target for the RB protein

Transcriptional regulation of gene expression: mechanisms and pathophysiology

Transcription factors are key mediators of the genetic programs that underlie human development and physiology. Mutations in genes that encode transcription factors or in DNA sequences to which these factors bind may adversely affect gene expression and result in disease. Mutations in genes encoding transcription factors often have pleiotropic effects because each transcription factor is involved in the regulation of multiple genes. For several transcription factors, germline mutations have been shown to result in malformation syndromes whereas somatic mutations in the same genes contribute to the multistep process of tumorigenesis. The study of transcription factors and their involvement in human disease thus provides insight into the molecular mechanisms underlying human development, physiology, dysmorphology, and oncology.

Into and out of G1: the control of cell proliferation

Progression of cells through G1 is an orderly process which is regulated by a series of key proteins. Over the past few years a number of these proteins have been identified and their mode of action has been studied in detail. This review will concentrate on the current knowledge about the function in G1 of cyclins, cyclin dependent kinases, the retinoblastoma protein and other related 'pocket' proteins. Mutations or deregulation of some of these proteins confer a growth advantage and their role in malignant transformation will be discussed.

Mutations in the retinoblastoma gene and their expression in somatic and tumor cells of patients with hereditary retinoblastoma

Two intragenic deletions (exon 18-19 and exon 24) and two point mutations (one missense mutation in exon 21 and one mutation at splice-donor site for exon 13) were detected in the retinoblastoma gene in somatic and tumor cells of patients with hereditary retinoblastoma. Three mutations were located in a domain essential for binding to oncoproteins encoded by DNA tumor viruses (Hu et al., 1990; Huang et al., 1990). One mutation (deletion of exon 24) was outside this domain but it is in the region essential for binding to transcriptional factor E2F, and for suppression of malignant phenotypes (Qian et al., 1992; Qin et al., 1992). A minisatellite-like sequence and short repeated sequences were located at the breakpoint of the deletion of exon 24, suggesting that two deletions on both sides of the minisatellite-like sequence may be generated by a "DNA slippage and misalignment" mechanism. Upon amplification of cDNA by the polymerase chain reaction, no transcript of gene with frameshift mutation (deletion of exon 24) was detected in skin fibroblasts, while transcripts of genes with missense mutations were detected. The results, in combination with previous reports (Dunn et al., 1989; Hashimoto et al., 1991), suggest the instability of transcripts with a premature stop codon or the suppressed expression of alleles with a premature stop codon in the retinoblastoma gene in somatic cells of hereditary patients.

Independent regions of adenovirus E1A are required for binding to and dissociation of E2F-protein complexes

The transcription factor E2F is present in independent complexes with the product of the retinoblastoma susceptibility gene, pRB, and a related gene product, p107, in association with the cyclin A-cdk2 or the cyclin E-cdk2 kinase complex. pRB and p107 can negatively regulate E2F activity, since overexpression of pRB or p107 in cells lacking a functional pRB leads to the repression of E2F activity. The products of the adenovirus E1A gene can disrupt E2F complexes and result in free and presumably active E2F transcription factor. The regions of E1A required for this function are also essential for binding to a number of cellular proteins, including pRB and p107. Through the use of a number of glutathione S-transferase fusion proteins representing different regions of E1A, as well as in vivo expression of E1A proteins containing deletions of either conserved region 1 (CR1) or CR2, we find that CR2 of E1A can form stable complexes with E2F. E1A proteins containing both CR1 and CR2 also associate with E2F, although the presence of these proteins results in the release of free E2F from its complexes. In vitro reconstitution experiments indicate that E1A-E2F interactions are not direct and that pRB can serve to facilitate these interactions. Complexes containing E1A, p107, cyclin A, and E2F were identified in vivo, which indicates that E1A may associate with E2F through either p107 or pRB. Peptide competition experiments demonstrate that the pRB-binding domain of the human E2F-1 protein can compete with the CR1 but not CR2 domain of E1A for binding to pRB. These results indicate that E1A CR1 and E2F-1 may bind to the same or overlapping sites on pRB and that E1A CR2 binds to an independent region. On the basis of our results, we propose a two-step model for the release of E2F from pRB and p107 cellular proteins.

Analysis of p107-associated proteins: p107 associates with a form of E2F that differs from pRB-associated E2F-1

The binding of viral oncogenes to cellular proteins is thought to modulate the activities of these cellular targets. The p107 protein is targeted by many viral proteins, including adenovirus E1A, simian virus 40 large T antigen, and human papillomavirus type 16 E7 protein. A panel of monoclonal antibodies against p107 was raised and used to identify cellular proteins that interact with the p107 protein in vivo. p107-associated proteins included cyclin A, cyclin E, and cdk2. In addition, p107 was found to associate with 62- to 65- and 50-kDa phosphoproteins in ML-1 cells, a human myeloid leukemia cell line. The 62- to 65-kDa proteins have many of the properties of the transcription factor E2F but were distinguished from pRB-associated E2F-1 by both immunologic and biochemical properties.

Multiple, distinct trans-activation functions are encoded by the simian virus 40 large T and small t antigens, only some of which require the 82-residue amino-terminal common domain

Simian virus 40 (SV40) small t and large T antigens can each trans activate the adenovirus (Ad) E2A and the Ad VA-I promoters. The first 82 amino acids of large T and small t are identical. However, this large T-small t common domain between residues 1 and 82 does not trans activate, suggesting that large T and small t each encode separate trans-activation functions. To determine whether the large T or small t unique domains, which are required for trans activation of the E2A promoter, are sufficient for this activity, we have employed expression plasmids separately encoding the common and unique domains of large T and small t. Cotransfection of a large T unique domain expression plasmid efficiently trans activated the E2A promoter. Optimal trans activation by large T required the motif that binds cellular proteins such as the retinoblastoma gene product, which is located in the large T unique domain, and additional large T structures outside this motif. In contrast, the small t unique domain did not trans activate the E2A promoter. Experiments utilizing E2A promoter mutants containing only the ATF- or EIIF-binding sites demonstrated that trans activation by small t involves only the EIIF transcription factor and that this function requires both the common (residues 1 to 82) and the small t unique domains expressed as a colinear protein. trans activation by large T, in contrast, involves at least three mechanisms. There appear to be at least two mechanisms that involve the EIIF transcription factor, at least one of which does not require the common domain (residues 1 to 82) and one mechanism that involves the ATF factor and does require both the common and the large T unique domains.

Cloning and characterization of E2F-2, a novel protein with the biochemical properties of transcription factor E2F

E2F is a mammalian transcription factor that appears to play an important role in cell cycle regulation. While at least two proteins (E2F-1 and DP-1) with E2F-like activity have been cloned, studies from several laboratories suggest that additional homologs may exist. A novel protein with E2F-like properties, designated E2F-2, was cloned by screening a HeLa cDNA library with a DNA probe derived from the DNA binding domain of E2F-1 (K. Helin, J. A. Lees, M. Vidal, N. Dyson, E. Harlow, and A. Fattaey, Cell 70:337-350, 1992). E2F-2 exhibits overall 46% amino acid identity to E2F-1. Both the sequence and the function of the DNA and retinoblastoma gene product binding domains of E2F-1 are conserved in E2F-2. The DNA binding activity of E2F-2 is dramatically enhanced by complementation with particular sodium dodecyl sulfate-polyacrylamide gel electrophoresis-purified components of HeLa cell E2F, and anti-E2F-2 antibodies cross-react with components of purified HeLa cell E2F. These observations are consistent with a model in which E2F binds DNA as a heterodimer of two distinct proteins, and E2F-2 is functionally and immunologically related to one of these proteins.

Molecular genetic aspects of human cancers: the 1993 Frank Rose Lecture

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Isolation of a herpes simplex virus type 1 mutant with a deletion in the virion host shutoff gene and identification of multiple forms of the vhs (UL41) polypeptide

The virion host shutoff (vhs) gene (UL41) of herpes simplex virus type 1 (HSV-1) encodes a virion component that induces degradation of host mRNAs and the shutoff of most host protein synthesis. Subsequently, the vhs protein accelerates the turnover of all kinetic classes of viral mRNA. To identify the vhs (UL41) polypeptide within infected cells and virions, antisera raised against a UL41-lacZ fusion protein were used to characterize the polypeptides encoded by wild-type HSV-1 and two mutants: vhs1, a previously characterized mutant that lacks detectable virion host shutoff activity, and vhs-delta Sma, a newly constructed mutant containing a deletion of 196 codons from UL41. Two forms of the vhs (UL41) polypeptide were identified in cells infected with the wild-type virus or vhs1. Wild-type HSV-1 produced a major 58-kDa polypeptide, as well as a less abundant 59.5-kDa form of the protein, while vhs1 produced 57- and 59-kDa polypeptides that were approximately equally abundant. Although for either virus, both forms of the protein were phosphorylated, they differed in the extent of phosphorylation. While both vhs polypeptides were found in infected cells, only the faster migrating, less phosphorylated form was incorporated into virions. vhs-delta Sma encoded a smaller, 31-kDa polypeptide which, although present in infected cells, was not incorporated into virions. The results identify multiple forms of the vhs (UL41) polypeptide and suggest that posttranslational processing affects its packaging into virions, as well as its ability to induce mRNA degradation.

The retinoblastoma protein binds to a family of E2F transcription factors

E2F is a transcription factor that helps regulate the expression of a number of genes that are important in cell proliferation. Recently, several laboratories have isolated a cDNA clone that encodes an E2F-like protein, known as E2F-1. Subsequent characterization of this protein showed that it had the properties of E2F, but it was difficult to account for all of the suggested E2F activities through the function of this one protein. Using low-stringency hybridization, we have isolated cDNA clones that encode two additional E2F-like proteins, called E2F-2 and E2F-3. The chromosomal locations of the genes for E2F-2 and E2F-3 were mapped to 1p36 and 6q22, respectfully, confirming their independence from E2F-1. However, the E2F-2 and E2F-3 proteins are closely related to E2F-1. Both E2F-2 and E2F-3 bound to wild-type but not mutant E2F recognition sites, and they bound specifically to the retinoblastoma protein in vivo. Finally, E2F-2 and E2F-3 were able to activate transcription of E2F-responsive genes in a manner that was dependent upon the presence of at least one functional E2F binding site. These observations suggest that the E2F activities described previously result from the combined action of a family of proteins.

Identification of distinct roles for separate E1A domains in disruption of E2F complexes

The adenovirus E1A protein can disrupt protein complexes containing the E2F transcription factor in association with cellular regulatory proteins such as the retinoblastoma gene product (Rb) and the Rb-related p107 protein. Previous experiments have shown that the CR1 and CR2 domains of E1A are required for this activity. We now demonstrate that the CR2 domain is essential for allowing E1A to interact with the E2F-Rb or the E2F-p107-cyclin A-cdk2 complex. Multimeric complexes containing E1A can be detected when the CR1 domain has been rendered inactive by mutation. In addition, the E1A CR1 domain, but not the CR2 domain, is sufficient to prevent the interaction of E2F with Rb or p107. On the basis of these results, we suggest a model whereby the CR2 domain brings E1A to the E2F complexes and then, upon a normal equilibrium dissociation of Rb or p107 from E2F, the E1A CR1 domain is able to block the site of interaction on Rb or p107, thereby preventing the re-formation of the complexes.

Overproduction of Rb protein after the G1/S boundary causes G2 arrest

The Rb protein is known to exert its activity at decision points in the G1 phase of the cell cycle. To investigate whether it may also play some role(s) at later points in the cell cycle, we used a system of rapid inducible gene amplification to conditionally overexpress Rb protein during G2 phase. A cell line expressing a temperature-sensitive simian virus 40 large T antigen (T-Ag) was stably transfected with plasmids containing the Rb cDNA linked to the simian virus 40 origin of replication: pRB-wt, pRB-fs, and pRB-Dra, carrying wild-type murine Rb cDNA, a frameshift mutation close to the beginning of the Rb coding region, and a single-amino-acid deletion in the E1A/T-Ag binding pocket, respectively. Numerous independent cell lines were isolated at the nonpermissive temperature; cell lines displaying a high level of episomal amplification of an intact Rb expression cassette following shiftdown to the permissive temperature were chosen for further analysis. Plasmid pRB-fs did not express detectable Rb antigen, while pRB-Dra expressed full-length Rb protein. The Dra mutation has previously been shown to abrogate phosphorylation as well as T-Ag binding. Fluorescence-activated cell sorting (FACS) analysis revealed that cultures induced to overexpress either wild-type or Dra mutant Rb proteins were significantly enriched for cells with a G2 DNA content. Cultures that amplified pRB-fs or rearranged pRB-wt and did not express Rb protein had normal cell cycle profiles. Double-label FACS analysis showed that cells overexpressing Rb or Rb-Dra proteins were uniformly accumulating in G2, whereas cells expressing endogenous levels of Rb were found throughout the cell cycle. These results indicate that Rb protein is interacting with some component(s) of the cell cycle-regulatory machinery during G2 phase.

The retinoblastoma protein binds E2F residues required for activation in vivo and TBP binding in vitro

The retinoblastoma (RB) tumour suppressor protein is capable of repressing the activity of promoters containing DNA binding sites for the transcription factor E2F. Recently a protein which binds RB and possesses the DNA binding characteristics of E2F has been cloned. Here we show that the E2F activation domain is the target for RB-induced repression. RB can silence the 57 residue E2F activation domain but cannot effectively repress an E2F mutant which has reduced RB binding capacity. Extensive mutagenesis of E2F shows residues involved in RB binding are required for transcription activation. Mutations which affect both functions most dramatically lie within the minimal RB binding region. A further subset of sensitive residues lies within a new repeat motif E/DF XX L X P which flanks the minimum RB binding site. These data show that RB can mask E2F residues involved in the activation process, possibly by mimicking a component of the transcriptional machinery. Consistent with this model, we find that the TATA box binding protein TBP can bind to the E2F activation domain in vitro in a manner indistinguishable from that of RB.

Overproduction of Rb protein after the G1/S boundary causes G2 arrest

The Rb protein is known to exert its activity at decision points in the G1 phase of the cell cycle. To investigate whether it may also play some role(s) at later points in the cell cycle, we used a system of rapid inducible gene amplification to conditionally overexpress Rb protein during G2 phase. A cell line expressing a temperature-sensitive simian virus 40 large T antigen (T-Ag) was stably transfected with plasmids containing the Rb cDNA linked to the simian virus 40 origin of replication: pRB-wt, pRB-fs, and pRB-Dra, carrying wild-type murine Rb cDNA, a frameshift mutation close to the beginning of the Rb coding region, and a single-amino-acid deletion in the E1A/T-Ag binding pocket, respectively. Numerous independent cell lines were isolated at the nonpermissive temperature; cell lines displaying a high level of episomal amplification of an intact Rb expression cassette following shiftdown to the permissive temperature were chosen for further analysis. Plasmid pRB-fs did not express detectable Rb antigen, while pRB-Dra expressed full-length Rb protein. The Dra mutation has previously been shown to abrogate phosphorylation as well as T-Ag binding. Fluorescence-activated cell sorting (FACS) analysis revealed that cultures induced to overexpress either wild-type or Dra mutant Rb proteins were significantly enriched for cells with a G2 DNA content. Cultures that amplified pRB-fs or rearranged pRB-wt and did not express Rb protein had normal cell cycle profiles. Double-label FACS analysis showed that cells overexpressing Rb or Rb-Dra proteins were uniformly accumulating in G2, whereas cells expressing endogenous levels of Rb were found throughout the cell cycle. These results indicate that Rb protein is interacting with some component(s) of the cell cycle-regulatory machinery during G2 phase.

Efficient transcriptional activation of many simple modular promoters by simian virus 40 large T antigen

Simian virus 40 (SV40) large T antigen is a multifunctional protein which plays central roles during both lytic and transforming infections by SV40. It is a potent transcriptional activator and increases expression from the SV40 late promoter and from several cellular promoters. To understand better the transcriptional activation activity of large T antigen, we examined its ability to transactivate a set of simple modular promoters containing one of four upstream activation sequences coupled with one of three different TATA box sequences originally constructed and studied by Taylor and Kingston (Mol. Cell. Biol. 10:165-175, 1990). Large T antigen activated transcription from all of these simple promoters. The identity of the TATA box was a more important determinant of the final level of gene expression than was the identity of the upstream activating sequence element. We also determined the ability of a set of mutant SV40 large T antigens to activate a subset of these promoters. Several mutant SV40 large T antigens which had reduced ability to activate the complex SV40 late and Rous sarcoma virus long terminal repeat promoters showed reduced transcriptional activation activity on all of the modular promoters tested. We used a set of promoter derivatives of the human U6 small nuclear RNA promoter containing different TATA boxes and found that wild-type large T antigen could activate transcription from all of them, although to widely different levels of expression.

Identification of distinct roles for separate E1A domains in disruption of E2F complexes

The adenovirus E1A protein can disrupt protein complexes containing the E2F transcription factor in association with cellular regulatory proteins such as the retinoblastoma gene product (Rb) and the Rb-related p107 protein. Previous experiments have shown that the CR1 and CR2 domains of E1A are required for this activity. We now demonstrate that the CR2 domain is essential for allowing E1A to interact with the E2F-Rb or the E2F-p107-cyclin A-cdk2 complex. Multimeric complexes containing E1A can be detected when the CR1 domain has been rendered inactive by mutation. In addition, the E1A CR1 domain, but not the CR2 domain, is sufficient to prevent the interaction of E2F with Rb or p107. On the basis of these results, we suggest a model whereby the CR2 domain brings E1A to the E2F complexes and then, upon a normal equilibrium dissociation of Rb or p107 from E2F, the E1A CR1 domain is able to block the site of interaction on Rb or p107, thereby preventing the re-formation of the complexes.

Altered expression of the retinoblastoma susceptibility gene in chronic lymphocytic leukaemia

The pathogenesis of chronic lymphocytic leukaemia (CLL) is unknown. One of the most frequent cytogenetic abnormalities in CLL is a deletion within the long arm of chromosome 13, the region to which the retinoblastoma (Rb) gene has been mapped. Lack of Rb expression has been linked to the carcinogenic process in many human tumours. We therefore sought to investigate the role of Rb gene inactivation in CLL using differential polymerase chain reaction on reverse transcribed RNA. The result of the PCR was quantitated using HPLC. 5/39 patients revealed a lack or significantly impaired expression of the Rb gene upon differential PCR analysis. In addition, immunocytochemical studies were performed using the Rb-specific monoclonal antibody PMG245. 10/56 patients showed a weak or absent expression upon immunocytochemical analysis compared to monocytes or granulocytes. The samples lacking Rb were from both early and late stage CLL. Our results indicate that inactivation of the Rb protein occurs in a fraction of CLL cases and can be found in early and late stages of the disease.

A genetic analysis of the E2F1 gene distinguishes regulation by Rb, p107, and adenovirus E4

The cellular transcription factor E2F appears to be a target for the regulatory action of the retinoblastoma tumor suppressor gene product. The recent isolation of the E2F1 cDNA clone, which encodes a polypeptide with properties characteristic of E2F, has now allowed a more detailed analysis of the regulation of E2F function by Rb as well as the Rb-related p107 protein and the adenovirus 19-kDa E4 gene product. Previous experiments have shown that each of these regulatory proteins can modulate the activity of cellular E2F. We find that each of these regulatory events can be mediated through the E2F1 product. Moreover, an examination of various E2F1 mutations reveals distinct specificities for these regulatory proteins. For instance, the ability of E4 to alter E2F1 function is dependent upon sequences within a putative leucine repeat of E2F1 as well as within the C-terminal acidic domain. In contrast, the leucine repeat element was not important for Rb- or p107-mediated inhibition of E2F1 activity. Although the C-terminal acidic domain of E2F1, previously shown to be important for Rb binding, appears to be a site for regulation of E2F1 by Rb and p107, point mutations within this region distinguish recognition by Rb and p107. These results underscore the complexity of E2F regulatory interactions and also demonstrate a qualitative distinction in the interactions of Rb and p107 with E2F1, perhaps reflective of functional differences.

Inhibition of E2F-1 transactivation by direct binding of the retinoblastoma protein

Loss of a functional retinoblastoma tumor suppressor gene product, pRB, is a key step in the development of many human tumors. pRB is a negative regulator of cell proliferation and appears to participate in control of entry into the S phase of the cell cycle. The recent demonstration that pRB binds to transcription factor E2F has provided a model for the mechanism of pRB-mediated growth regulation. Since adenovirus E1A proteins dissociate the pRB-E2F complexes and stimulate E2F-dependent transcription, it has been suggested that pRB inhibits E2F transactivation. Although some evidence for this hypothesis has been provided, it has not been possible to determine the mechanism of pRB-mediated inhibition of E2F transactivation. In this study, we constructed mutants of E2F-1 that do not bind to pRB yet retain the ability to transactivate the adenovirus E2 promoter through E2F DNA-binding sites. We demonstrated that transactivation mediated by the wild-type E2F-1 protein was inhibited by overexpression of wild-type pRB but not by a naturally occurring mutant of pRB. Transactivation mediated by mutants of E2F-1 which do not bind to pRB was not affected by overexpression of wild-type pRB. Furthermore, when the E2F-1 transactivation domain was fused to the GAL4 DNA-binding domain, pRB inhibited GAL4-E2F-1 transactivation through GAL4 sites. Expression of pRB did not inhibit transactivation mediated by GAL4-E2F-1 mutant constructs which were devoid of pRB binding. In conclusion, these data demonstrate that pRB inhibits E2F-dependent transactivation by direct protein-protein interaction.

Tumor suppressor genes in urologic tumors

During the last decade remarkable progress has been made in our understanding of the malignant phenotype. There is evidence that a series of genetic changes are involved in the conversion of a normal cell to a malignant one. These changes have been directly identified with mutations in various genes usually involved in cell growth and proliferation. Two main classes of genes have been characterized: oncogenes, which promote growth and tumor suppressor genes, which restrain growth. While oncogenes have been studied in relative detail, little is known about tumor suppressor genes. However recent studies revealed that loss of tumor suppressor genes are a common mechanism for the progression of cancer and are of prognostic value. In this review we focus on the role of these tumor suppressor genes in urologic tumors in experimental as well as clinical studies.

Association of the human papillomavirus type 16 E7 protein with the S-phase-specific E2F-cyclin A complex

The transcription factor E2F has been shown to be involved in the expression of several cell cycle-regulated genes, and the activity of this factor is controlled by cellular proteins such as pRB and p107. E2F is also a target of the DNA virus oncoproteins (adenovirus E1A, simian virus 40 T antigen, and human papillomavirus [HPV] E7) (see the review by J. R. Nevins [Science 258: 424-429, 1992]). These viral oncoproteins dissociate an inactive complex between E2F and the retinoblastoma tumor suppressor protein (pRB), and this dissociation of the E2F-pRB complex correlates with a stimulation of the E2F-dependent transcription. In the S phase of the cell cycle, E2F forms a complex with p107, cyclin A, and the cdk2 kinase (E2F-cyclin A complex). The cellular function of this S-phase-specific complex is unclear. The adenovirus E1A protein dissociates the E2F-cyclin A complex. The HPV type 16 (HPV-16) E7 protein, which possesses significant sequence homology with E1A, does not dissociate the E2F-cyclin A complex. We find that the HPV-16 E7 protein associates very efficiently with the E2F-cyclin A complex. This association is dependent on the sequences that are also necessary for the transforming activity of E7. Moreover, the E7 protein of a low-risk HPV (type 6b) is much less efficient in binding to the E2F-cyclin A complex compared with that of the high-risk type. We also find that the E2F-cyclin A complex remains endogenously associated with the E7 protein in extracts of Caski cells, which express high levels of HPV-16 E7 protein. Finally, we have extensively purified the E2F-cyclin A complex from mouse L-cell extracts and show that, in cell extracts, the E2F-cyclin A complex remains associated with other cellular proteins.

A genetic analysis of the E2F1 gene distinguishes regulation by Rb, p107, and adenovirus E4

The cellular transcription factor E2F appears to be a target for the regulatory action of the retinoblastoma tumor suppressor gene product. The recent isolation of the E2F1 cDNA clone, which encodes a polypeptide with properties characteristic of E2F, has now allowed a more detailed analysis of the regulation of E2F function by Rb as well as the Rb-related p107 protein and the adenovirus 19-kDa E4 gene product. Previous experiments have shown that each of these regulatory proteins can modulate the activity of cellular E2F. We find that each of these regulatory events can be mediated through the E2F1 product. Moreover, an examination of various E2F1 mutations reveals distinct specificities for these regulatory proteins. For instance, the ability of E4 to alter E2F1 function is dependent upon sequences within a putative leucine repeat of E2F1 as well as within the C-terminal acidic domain. In contrast, the leucine repeat element was not important for Rb- or p107-mediated inhibition of E2F1 activity. Although the C-terminal acidic domain of E2F1, previously shown to be important for Rb binding, appears to be a site for regulation of E2F1 by Rb and p107, point mutations within this region distinguish recognition by Rb and p107. These results underscore the complexity of E2F regulatory interactions and also demonstrate a qualitative distinction in the interactions of Rb and p107 with E2F1, perhaps reflective of functional differences.

Association of the human papillomavirus type 16 E7 protein with the S-phase-specific E2F-cyclin A complex

The transcription factor E2F has been shown to be involved in the expression of several cell cycle-regulated genes, and the activity of this factor is controlled by cellular proteins such as pRB and p107. E2F is also a target of the DNA virus oncoproteins (adenovirus E1A, simian virus 40 T antigen, and human papillomavirus [HPV] E7) (see the review by J. R. Nevins [Science 258: 424-429, 1992]). These viral oncoproteins dissociate an inactive complex between E2F and the retinoblastoma tumor suppressor protein (pRB), and this dissociation of the E2F-pRB complex correlates with a stimulation of the E2F-dependent transcription. In the S phase of the cell cycle, E2F forms a complex with p107, cyclin A, and the cdk2 kinase (E2F-cyclin A complex). The cellular function of this S-phase-specific complex is unclear. The adenovirus E1A protein dissociates the E2F-cyclin A complex. The HPV type 16 (HPV-16) E7 protein, which possesses significant sequence homology with E1A, does not dissociate the E2F-cyclin A complex. We find that the HPV-16 E7 protein associates very efficiently with the E2F-cyclin A complex. This association is dependent on the sequences that are also necessary for the transforming activity of E7. Moreover, the E7 protein of a low-risk HPV (type 6b) is much less efficient in binding to the E2F-cyclin A complex compared with that of the high-risk type. We also find that the E2F-cyclin A complex remains endogenously associated with the E7 protein in extracts of Caski cells, which express high levels of HPV-16 E7 protein. Finally, we have extensively purified the E2F-cyclin A complex from mouse L-cell extracts and show that, in cell extracts, the E2F-cyclin A complex remains associated with other cellular proteins.

Inhibition of E2F-1 transactivation by direct binding of the retinoblastoma protein

Loss of a functional retinoblastoma tumor suppressor gene product, pRB, is a key step in the development of many human tumors. pRB is a negative regulator of cell proliferation and appears to participate in control of entry into the S phase of the cell cycle. The recent demonstration that pRB binds to transcription factor E2F has provided a model for the mechanism of pRB-mediated growth regulation. Since adenovirus E1A proteins dissociate the pRB-E2F complexes and stimulate E2F-dependent transcription, it has been suggested that pRB inhibits E2F transactivation. Although some evidence for this hypothesis has been provided, it has not been possible to determine the mechanism of pRB-mediated inhibition of E2F transactivation. In this study, we constructed mutants of E2F-1 that do not bind to pRB yet retain the ability to transactivate the adenovirus E2 promoter through E2F DNA-binding sites. We demonstrated that transactivation mediated by the wild-type E2F-1 protein was inhibited by overexpression of wild-type pRB but not by a naturally occurring mutant of pRB. Transactivation mediated by mutants of E2F-1 which do not bind to pRB was not affected by overexpression of wild-type pRB. Furthermore, when the E2F-1 transactivation domain was fused to the GAL4 DNA-binding domain, pRB inhibited GAL4-E2F-1 transactivation through GAL4 sites. Expression of pRB did not inhibit transactivation mediated by GAL4-E2F-1 mutant constructs which were devoid of pRB binding. In conclusion, these data demonstrate that pRB inhibits E2F-dependent transactivation by direct protein-protein interaction.

Viral immunopathology of human tumors

Virally induced tumors provide the strongest case of host surveillance against neoplastic cells and their precursors. Human cancers associated with Epstein-Barr virus, hepatitis B virus, papilloma virus and human T cell leukemia virus infection are responsible for approximately 15-20% of the total incidence of cancer world-wide. Current work in each of these virus/tumor systems seeks to understand the mechanisms of viral action and to identify strategies of immune intervention that may allow us to prevent viral infection or to control its potentially life-threatening consequences.

Heterodimerization of the transcription factors E2F-1 and DP-1 leads to cooperative trans-activation

The E2F transcription factor has been implicated in the regulation of genes whose products are involved in cell proliferation. Two proteins have recently been identified with E2F-like properties. One of these proteins, E2F-1, has been shown to mediate E2F-dependent trans-activation and to bind the hypophosphorylated form of the retinoblastoma protein (pRB). The other protein, murine DP-1, was purified from an E2F DNA-affinity column, and it was subsequently shown to bind the consensus E2F DNA-binding site. To study a possible interaction between E2F-1 and DP-1, we have now isolated a cDNA for the human homolog of DP-1. Human DP-1 and E2F-1 associate both in vivo and in vitro, and this interaction leads to enhanced binding to E2F DNA-binding sites. The association of E2F-1 and DP-1 leads to cooperative activation of an E2F-responsive promoter. Finally, we demonstrate that E2F-1 and DP-1 association is required for stable interaction with pRB in vivo and that trans-activation by E2F-1/DP-1 heterodimers is inhibited by pRB. We suggest that "E2F" is the activity that is formed when an E2F-1-related protein and a DP-1-related protein dimerize.

Expression of transcription factor E2F1 induces quiescent cells to enter S phase

Several lines of evidence implicate the E2F transcription factor as an important component of cell proliferation control. First, E2F binding sites are found in the promoters of genes responsive to proliferation signals and the level of E2F binding activity increases at a time when many of these genes are activated. Second, the tumour suppressor protein Rb, as well as the related p107 protein, complexes with E2F, resulting in an inhibition of E2F transcriptional activity. Third, oncogenic products of the DNA tumour viruses can dissociate these E2F complexes. We provide here direct evidence that E2F is involved in cellular proliferation control. Specifically, we demonstrate that overexpression of the E2F1 complementary DNA can activate DNA synthesis in cells that would otherwise growth-arrest, with an efficiency that is similar to that achieved by the expression of the adenovirus E1A gene. Moreover, microinjection of the E2F1 cDNA into quiescent cells can induce S-phase entry, whereas two E2F1 mutants, which are unable to transactivate the DHFR and TK promoters, are unable to induce S phase. We conclude that the E2F transcription factor plays an important role in progression into S phase and that this probably coincides with its capacity to stimulate transcription.

Interferons and interleukin-6 suppress the DNA-binding activity of E2F in growth-sensitive hematopoietic cells

Transcription factor E2F binds to cellular promoters of certain growth- and cell cycle-controlling genes and forms distinct heteromeric complexes with other nuclear proteins. We show here that alpha and beta interferons (alpha, beta) and interleukin-6 abolished the E2F-containing DNA-binding complexes in Daudi Burkitt lymphoma cells and in M1 myeloblastic cells, which responded to the cytokines by suppression of c-myc transcription. Time kinetics studies showed that the abolishment of E2F complexes coincided with reduction of c-myc expression and that both molecular events preceded the cell cycle block in G0/G1 phase. In contrast, the pattern of E2F complexes remained unchanged in an interferon-treated growth-resistant Daudi cell mutant that displayed relaxed regulation of c-myc. All of the DNA-binding E2F complexes, including those containing the retinoblastoma protein (pRB), cyclin A-p33cdk2, and the free forms of E2F, were reduced by interferons or interleukin-6. Their abolishment was unperturbed by pharmacological treatments that alleviated the cyclin A and pRB responses to interferon. Thus, changes in cyclin A expression and pRB phosphorylation are not primary events that influence the pattern of E2F responses to cytokines. Addition of EDTA to cell extracts of interferon-treated Daudi cells restored the DNA-binding activity of E2F, resulting in the appearance of a single E2F complex that exclusively contained pRB. It is suggested that the regulation of E2F by growth-inhibitory cytokines that induce cell cycle exit takes place at the level of the DNA-binding activity, and by that mean it differs basically from the phase-specific regulation of E2F in cycling cells.

Expression of a retinoblastoma transgene results in dwarf mice

Introduction of the normal retinoblastoma gene (RB) into different tumor cells possessing inactivated RB genes suppresses their tumorigenicity in nude mice. These results suggest that RB replacement is a potential strategy for developing future clinical treatments of cancer. In a transgenic mouse model, we found that the quantity of RB protein in a given cell may play an important role in dictating its effect. Four founder mice containing 1-7 copies of a human RB cDNA transgene under the transcriptional control of the human RB promoter were generated. Most of the transgenic mice were smaller than nontransgenic littermates. This effect was found as early as embryonic day 15. The degree of dwarfism correlated roughly with the copy number of the transgene and the corresponding level of RB protein. The expression pattern of the transgene products was similar to that of the endogenous mouse RB gene with regard to tissue and temporal distribution. Transferring the transgene to RB deficient mice, which are nonviable, resulted in the development of normal, healthy mice, indicating that the human RB gene can functionally complement the mouse homolog. These studies demonstrate that the effect of RB on overall mouse development is closely dependent upon its dosage.

Interferons and interleukin-6 suppress the DNA-binding activity of E2F in growth-sensitive hematopoietic cells

Transcription factor E2F binds to cellular promoters of certain growth- and cell cycle-controlling genes and forms distinct heteromeric complexes with other nuclear proteins. We show here that alpha and beta interferons (alpha, beta) and interleukin-6 abolished the E2F-containing DNA-binding complexes in Daudi Burkitt lymphoma cells and in M1 myeloblastic cells, which responded to the cytokines by suppression of c-myc transcription. Time kinetics studies showed that the abolishment of E2F complexes coincided with reduction of c-myc expression and that both molecular events preceded the cell cycle block in G0/G1 phase. In contrast, the pattern of E2F complexes remained unchanged in an interferon-treated growth-resistant Daudi cell mutant that displayed relaxed regulation of c-myc. All of the DNA-binding E2F complexes, including those containing the retinoblastoma protein (pRB), cyclin A-p33cdk2, and the free forms of E2F, were reduced by interferons or interleukin-6. Their abolishment was unperturbed by pharmacological treatments that alleviated the cyclin A and pRB responses to interferon. Thus, changes in cyclin A expression and pRB phosphorylation are not primary events that influence the pattern of E2F responses to cytokines. Addition of EDTA to cell extracts of interferon-treated Daudi cells restored the DNA-binding activity of E2F, resulting in the appearance of a single E2F complex that exclusively contained pRB. It is suggested that the regulation of E2F by growth-inhibitory cytokines that induce cell cycle exit takes place at the level of the DNA-binding activity, and by that mean it differs basically from the phase-specific regulation of E2F in cycling cells.

A bipartite nuclear localization signal in the retinoblastoma gene product and its importance for biological activity

The retinoblastoma gene product, p110RB1, appears to regulate cell growth by modulating the activities of nuclear transcription factors. The elements that specify the transport of p110RB1 into the nucleus have not yet been explored. We now report the identification of a basic region, KRSAEGGNPPKPLKKLR, in the C terminus of p110RB1, which has sequence similarity to known bipartite nuclear localization signals (NLSs). A two-amino-acid mutation introduced into this putative NLS [to give mutant NLS(NQ)] or deletion of the entire NLS (delta NLS) abrogated exclusive nuclear localization, yielding proteins which were distributed either equally throughout the cell or predominantly in the cytoplasm. A mutant protein [NLS(NQ)/delta 22] containing both the mutated NLS and a deletion of exon 22, previously shown to disrupt the interaction of p110RB1 with several cellular transcription factors and oncoproteins, accumulated only in the cytoplasm. When fused to the C terminus of Escherichia coli beta-galactosidase, the RB1 NLS directed this protein to the nucleus, indicating that the motif is not only necessary but also sufficient for nuclear transport. Neither NLS(NQ) nor delta NLS was hyperphosphorylated in vivo, but both retained their abilities to interact, in vitro, with simian virus 40 large T antigen, adenovirus E1a, and the cellular transcription factor E2F. When transfected at multiple copy number, the NLS mutant alleles displayed reduced biological activity, measured by inhibition of growth of the osteogenic sarcoma cell line Saos-2, which has no wild-type RB1. Naturally occurring mutations and deletions in exon 25 of RB1 which disrupt the NLS may lead to partial or complete inactivation of p110RB1 and may be responsible for some retinoblastoma and other tumors.

Amplification of a DEAD box protein gene in retinoblastoma cell lines

DEAD box proteins, characterized by the conserved motif Asp-Glu-Ala-Asp, are putative RNA helicases implicated in a number of cellular processes involving alteration of RNA secondary structure such as translation initiation, nuclear and mitochondrial splicing, and ribosome and spliceosome assembly. Based on their distribution patterns, some members of this family are believed to be involved in embryogenesis, spermatogenesis, and cellular growth and division. Here, we report that the mRNA encoding a DEAD box protein, designated HuDBP-RB, is present at elevated levels in two of six retinoblastoma (RB) cell lines tested and is preferentially expressed in fetal tissues of neuroectodermal origin. It is not possible to classify HuDBP-RB as a member of any of the DEAD box protein subgroups identified to date since the regions of amino acid similarity between HuDBP-RB and other DEAD box proteins are restricted to the conserved motifs found in all members of this family. The HuDBP-RB gene, which has been mapped to chromosome band 2p24, is amplified in the RB cell lines that overexpress HuDBP-RB RNA. Furthermore, the MYCN gene is also present in multiple copies in these two cell lines, suggesting coamplification of the two genes.

A bipartite nuclear localization signal in the retinoblastoma gene product and its importance for biological activity

The retinoblastoma gene product, p110RB1, appears to regulate cell growth by modulating the activities of nuclear transcription factors. The elements that specify the transport of p110RB1 into the nucleus have not yet been explored. We now report the identification of a basic region, KRSAEGGNPPKPLKKLR, in the C terminus of p110RB1, which has sequence similarity to known bipartite nuclear localization signals (NLSs). A two-amino-acid mutation introduced into this putative NLS [to give mutant NLS(NQ)] or deletion of the entire NLS (delta NLS) abrogated exclusive nuclear localization, yielding proteins which were distributed either equally throughout the cell or predominantly in the cytoplasm. A mutant protein [NLS(NQ)/delta 22] containing both the mutated NLS and a deletion of exon 22, previously shown to disrupt the interaction of p110RB1 with several cellular transcription factors and oncoproteins, accumulated only in the cytoplasm. When fused to the C terminus of Escherichia coli beta-galactosidase, the RB1 NLS directed this protein to the nucleus, indicating that the motif is not only necessary but also sufficient for nuclear transport. Neither NLS(NQ) nor delta NLS was hyperphosphorylated in vivo, but both retained their abilities to interact, in vitro, with simian virus 40 large T antigen, adenovirus E1a, and the cellular transcription factor E2F. When transfected at multiple copy number, the NLS mutant alleles displayed reduced biological activity, measured by inhibition of growth of the osteogenic sarcoma cell line Saos-2, which has no wild-type RB1. Naturally occurring mutations and deletions in exon 25 of RB1 which disrupt the NLS may lead to partial or complete inactivation of p110RB1 and may be responsible for some retinoblastoma and other tumors.

E2F-1-mediated transactivation is inhibited by complex formation with the retinoblastoma susceptibility gene product

Previous studies have shown that the carboxyl-terminal region of E2F-1 (residues 368-437) can support transcriptional activation when linked to the DNA-binding domain of the yeast transcription factor GAL4. This region also contains an 18-residue retinoblastoma (RB)-binding sequence, raising the possibility that RB binding might inhibit the ability of E2F-1 to form protein-protein contacts required for activation. Here we report a further analysis of the E2F-1 activation domain. In addition, we show that overexpression of RB, but not the RB mutant, RBd22, can inhibit GAL4/E2F-1 activity in vivo. Moreover, expression of the simian virus 40 large tumor antigen (T antigen), but not the RB-binding defective T antigen point mutant, K1, can overcome this repression. Three different GAL4/E2F-1 mutants that activate transcription, but fail to bind to RB, are not significantly affected by overexpression of RB. These findings support a model wherein RB suppresses E2F-1-mediated transcriptional activation through direct physical association.

Proteins with transcription regulatory properties encoded by human adenoviruses

Of the more than 30 genes encoded by the adenovirus genome, no less than six have been shown to encode proteins that have transcription regulatory properties. None of them is a sequence-specific DNA-binding protein. They act to modulate the activity of cellular transcription factors by causing their phosphorylation or dephosphorylation, by physically interacting with them, or by dissociating transcription factor inhibitory protein complexes.

Cyclin A expression in normal and transformed alveolar epithelial cells

The mature adult alveolar epithelial cell (AEC) is a highly differentiated phenotype that does not readily divide and exhibits numerous specialized functions. Yet, transformed AEC proliferate aggressively in certain forms of lung cancer. Normal AEC also proliferate but in a coordinated manner during embryonic growth and fetal development as well as during lung repair. Therefore, biochemical mechanisms regulating the cell cycle in AEC are clearly of fundamental significance for understanding lung development, lung injury, and cancer. Cyclin A is a protein that varies in abundance during the cell cycle and regulates critical transition points through its association with cyclin-dependent protein kinase subunits. We postulated that high expression of cyclin A might be associated with rapid proliferation in transformed AEC. We compared the expression of cyclin A mRNA and protein in primary cultures of fetal and adult rat AEC, in the E1A-T2 neonatal rat AEC, and in the malignant A549 human AEC. We used pharmacologic blockades with mimosine, aphidicolin, and nocodazole for cell cycle synchronization, which was verified by fluorescence-activated cell sorter (FACS) analysis of cellular DNA content. Transformed cells (A549 and E1A-T2) exhibited a much higher level of expression for both cyclin A mRNA and protein than did normal rat AEC. Induction of cyclin A mRNA expression in A549 human AEC and E1A-T2 rat AEC occurred in late G1, prior to the onset of S phase. Fetal and adult rat AEC and rat E1A-T2 AEC expressed two cyclin A mRNA transcripts, whereas human A549 cells in S phase and M phase expressed three cyclin A mRNA transcripts. We conclude that transformed AEC overexpress cyclin A in comparison with primary AEC cultures, while retaining cell cycle-dependent differences in cyclin A expression. We speculate that cyclin A expression is regulated both at the transcriptional and post-transcriptional levels, and that cyclin A may play a key role in the increased proliferation of transformed AEC that is associated with the pathogenesis of lung cancer.

Cell cycle analysis of E2F in primary human T cells reveals novel E2F complexes and biochemically distinct forms of free E2F

The transcription factor E2F activates the expression of multiple genes involved in cell proliferation, such as c-myc and the dihydrofolate reductase gene. Regulation of E2F involves its interactions with other cellular proteins, including the retinoblastoma protein (Rb), the Rb-related protein p107, cyclin A, and cdk2. We undertook a detailed analysis of E2F DNA-binding activities and their cell cycle behavior in primary human T cells. Three E2F DNA-binding activities were identified in resting (G0) T cells with mobilities in gel shift assays distinct from those of previously defined E2F complexes. One of these activities was found to be a novel, less abundant, Rb-E2F complex. The most prominent E2F activity in resting T cells (termed complex X) was abundant in both G0 and G1 but disappeared as cells entered S phase, suggesting a possible role in negatively regulating E2F function. Complex X could be dissociated by adenovirus E1A with a requirement for an intact E1A conserved region 2. However, X failed to react with a variety of antibodies against Rb or p107, implicating the involvement of an E1A-binding protein other than Rb or p107. In addition to these novel E2F complexes, three distinct forms of unbound (free) E2F were resolved in gel shift experiments. These species showed different cell cycle kinetics. UV cross-linking experiments suggested that a distinct E2F DNA-binding protein is uniquely associated with the S-phase p107 complex and is not associated with Rb. Together, these results suggest that E2F consists of multiple, biochemically distinct DNA-binding proteins which function at different points in the cell cycle.

Cell cycle analysis of E2F in primary human T cells reveals novel E2F complexes and biochemically distinct forms of free E2F

The transcription factor E2F activates the expression of multiple genes involved in cell proliferation, such as c-myc and the dihydrofolate reductase gene. Regulation of E2F involves its interactions with other cellular proteins, including the retinoblastoma protein (Rb), the Rb-related protein p107, cyclin A, and cdk2. We undertook a detailed analysis of E2F DNA-binding activities and their cell cycle behavior in primary human T cells. Three E2F DNA-binding activities were identified in resting (G0) T cells with mobilities in gel shift assays distinct from those of previously defined E2F complexes. One of these activities was found to be a novel, less abundant, Rb-E2F complex. The most prominent E2F activity in resting T cells (termed complex X) was abundant in both G0 and G1 but disappeared as cells entered S phase, suggesting a possible role in negatively regulating E2F function. Complex X could be dissociated by adenovirus E1A with a requirement for an intact E1A conserved region 2. However, X failed to react with a variety of antibodies against Rb or p107, implicating the involvement of an E1A-binding protein other than Rb or p107. In addition to these novel E2F complexes, three distinct forms of unbound (free) E2F were resolved in gel shift experiments. These species showed different cell cycle kinetics. UV cross-linking experiments suggested that a distinct E2F DNA-binding protein is uniquely associated with the S-phase p107 complex and is not associated with Rb. Together, these results suggest that E2F consists of multiple, biochemically distinct DNA-binding proteins which function at different points in the cell cycle.