MDM2 but not MDM4 promotes retinoblastoma cell proliferation through p53-independent regulation of MYCN translation.

Retinoblastomas can arise from cone photoreceptor precursors in response to the loss of pRB function. Cone precursor-specific circuitry cooperates with pRB loss to initiate this process and subsequently contributes to the malignancy. Intrinsic high-level MDM2 expression is a key component of the cone precursor circuitry and is thought to inactivate p53-mediated tumor surveillance, which could otherwise be induced in response to pRB loss. However, the MDM2-related MDM4 has also been proposed to abrogate p53-mediated tumor surveillance in the absence of detectable MDM2 in retinoblastoma cells, bringing into question the importance of high-level MDM2 versus MDM4 expression. Here we report that high-level MDM2 but not MDM4 has a consistent critical role in retinoblastoma cell proliferation in vitro, as well as in orthotopic xenografts. Reduction of either MDM2 or MDM4 weakly induced p53, yet reduction of MDM2 but not MDM4 severely impaired proliferation and survival through a p53-independent mechanism. Specifically, MDM2 upregulated the mRNA expression and translation of another component of the cone circuitry, MYCN, in retinoblastoma cells. Moreover, MYCN was essential to retinoblastoma cell growth and tumor formation, and ectopic MYCN partially reversed the effects of MDM2 depletion, indicating that MYCN is an important MDM2 target. These findings indicate that high-level MDM2 expression is needed in order to perform a critical p53-independent function and may obviate the need for genomic alterations to the p53 pathway during retinoblastoma tumorigenesis.

Concurrent loss of the PTEN and RB1 tumor suppressors attenuates RAF dependence in melanomas harboring (V600E)BRAF.

Identifying the spectrum of genetic alterations that cooperate with critical oncogenes to promote transformation provides a foundation for understanding the diversity of clinical phenotypes observed in human cancers. Here, we performed integrated analyses to identify genomic alterations that co-occur with oncogenic BRAF in melanoma and abrogate cellular dependence upon this oncogene. We identified concurrent mutational inactivation of the PTEN and RB1 tumor suppressors as a mechanism for loss of BRAF/MEK dependence in melanomas harboring (V600E)BRAF mutations. RB1 alterations were mutually exclusive with loss of p16(INK4A), suggesting that whereas p16(INK4A) and RB1 may have overlapping roles in preventing tumor formation, tumors with loss of RB1 exhibit diminished dependence upon BRAF signaling for cell proliferation. These findings provide a genetic basis for the heterogeneity of clinical outcomes in patients treated with targeted inhibitors of the mitogen-activated protein kinase pathway. Our results also suggest a need for comprehensive screening for RB1 and PTEN inactivation in patients treated with RAF and MEK-selective inhibitors to determine whether these alterations are associated with diminished clinical benefit in patients whose cancers harbor mutant BRAF.

Cdk2-dependent phosphorylation and functional inactivation of the pRB-related p130 protein in pRB(-), p16INK4A(+) tumor cells.

The retinoblastoma family proteins pRB, p107, and p130 are phosphorylated and released from E2Fs in the late G(1) phase of the cell cycle. This phosphorylation is thought to contribute to the derepression of E2F-responsive genes and to be mediated, in part, by Cdk4 and Cdk6. Evidence that Cdk4/6 activity is inhibited by p16(INK4A) in most pRB(-) cells suggests that p107 and p130 may be underphosphorylated and remain associated with E2Fs during G(1)-S progression in cells that lack pRB. To examine this, we evaluated the cell cycle-dependent phosphorylation and E2F binding abilities of p107 and p130 in pRB(-), p16(+) Saos-2 osteosarcoma cells. p130, but not p107, was phosphorylated and released from E2F-4 in late G(1) and S phase cells, although p130 phosphorylation differed qualitatively in these and other pRB(-), p16(+) cells as compared with pRB(+), p16(-) cell types. p130 phosphorylation occurred in the absence of cyclin D-Cdk4/6 complexes, coincided with cyclin E- and Cdk2-associated kinase activity, and was prevented by expression of dominant negative Cdk2. Moreover, dominant negative Cdk2 prevented the dissociation of endogenous p130-E2F-4 complexes and inhibited E2F-4-dependent transcription. These findings show that p130 can be phosphorylated and functionally inactivated in a Cdk2-dependent process, and they highlight the involvement of distinct Cdks in the regulation of different pRB family proteins.

Growth factor-dependent induction of p21(CIP1) by the green tea polyphenol, epigallocatechin gallate.

Tea polyphenols inhibit tumorigenesis and cell proliferation in rodent models, but their effects on cell signaling and cell cycle control pathways are undefined. Here, we show that the major polyphenol in green tea, epigallocatechin gallate (EGCG), inhibits S phase entry in epidermal growth factor (EGF) - stimulated MCF10A breast epithelial cells when provided in G0 or mid G1, but not when provided after the late G1 restriction point. EGCG induced p21(CIP1/WAF1/SDI1), inhibited cyclin D1-associated pRB kinase activity, and impaired pRB phosphorylation. The ability of EGCG to induce p21 depended upon the addition of EGF, indicating that EGCG synergizes with growth factor-dependent signals to induce p21 and impair cell cycle progression.

pRB and p107/p130 are required for the regulated expression of different sets of E2F responsive genes.

The activity of the E2F transcription factor is controlled by physical association with the retinoblastoma protein (pRB) and two related proteins, p107 and p130. The pRB family members are thought to control different aspects of E2F activity, but it has been unclear what the respective functions of these proteins might be. To dissect the specific functions of pRB, p107, and p130 we have investigated how the expression of E2F-regulated genes is changed in cultures of primary cells lacking each of these family members. Whereas no changes were found in the expression of E2F-target genes in cells lacking either p107 or p130, deregulated expression of E2F targets was seen in cells lacking pRB and in cells lacking both p107 and p130. Surprisingly, the genes that were disregulated in these two settings were completely different. These findings show that pRB and p107/p130 indeed provide different functions in E2F regulation and identify target genes that are dependent on pRB family proteins for their normal expression.

Shared role of the pRB-related p130 and p107 proteins in limb development.

The p130 protein shares extensive sequence similarity with pRB, the product of the retinoblastoma gene, and is a major E2F-associated protein in quiescent cells. To investigate its biological function, we have mutated p130 via gene targeting in the mouse. Homozygous mutation of p130 had little discernible effect on development or on the growth of mouse embryo fibroblasts in culture. Much of the E2F activity that normally associates with p130 in serum-starved mouse embryo fibroblasts associated instead with the highly related p107 protein. To determine whether p130 and p107 have overlapping biological roles, we produced mice having simultaneous inactivation of the p130 and p107 genes. Such mice exhibited deregulated chondrocyte growth, defective endochondral bone development, shortened limbs, and neonatal lethality. These findings indicate that p130 and p107 play an important role in limb development through their abilities to control chondrocyte proliferation. Thus, in certain settings p107 and p130 perform growth-regulatory functions that are not fulfilled by pRB.

E2F-4 and E2F-5, two members of the E2F family, are expressed in the early phases of the cell cycle.

The E2F transcription factors play a role in regulating the expression of genes required for cell proliferation. Their activity appears to be regulated by association with the retinoblastoma protein (pRb) and the pRb-related proteins p107 and p130. In vivo, pRb is found in complex with a subset of E2F components--namely, E2F-1, E2F-2, and E2F-3. Here we describe the characterization of cDNAs encoding two unusual E2Fs, E2F-4 and E2F-5, each identified by the ability of their gene product to interact with p130 in a yeast two-hybrid system. E2F-4 and -5 share common sequences with E2F-1, E2F-2, and E2F-3 and, like these other E2Fs, the ability to heterodimerize with DP-1, thereby acquiring the ability to bind an E2F DNA recognition sequence with high affinity. However, in contrast to E2F-1, E2F-4 and E2F-5 fail to bind pRb in a two-hybrid assay. Moreover, they show a unique pattern of expression in synchronized human keratinocytes: E2F-4 and E2F-5 mRNA expression is maximal in mid-G1 phase before E2F-1 expression is detectable. These findings suggest that E2F-4 and E2F-5 may contribute to the regulation of early G1 events including the G0/G1 transition.

Cell cycle-specific association of E2F with the p130 E1A-binding protein.

Association of the E2F transcription factor with the pRb and p107 proteins appears to regulate the activity of E2F and, in turn, affect cell cycle progression. We found, however, that pRb and p107 are only minor E2F-associated proteins in G0/G1 mouse fibroblasts, and we sought to identify the major E2F partner protein in these cells. Because the adenovirus E1A oncoprotein seemed able to bind to the G0 E2F partner, we enriched for proteins that associated both with an E2F-binding site DNA column and with E1A. The major species in G0 and early G1 fibroblasts detected with this approach had properties identical to the pRb- and p107-related p130 protein. In serum-stimulated cells, p107 replaced p130 as the major E2F-associated protein near the G1/S border, concomitant with an increase in p107 protein levels. p130-E2F complexes resembled p107-E2F complexes in their ability to bind to cyclin-cdk kinases, and they appeared to be associated with the cyclin E-cdk2 kinase in late G1 cells. These observations indicate that E2F transcription factors are regulated by a succession of partner proteins with which they associate during defined stages of the cell cycle.

The retinoblastoma protein and the regulation of cell cycling.

Increasing attention has been focused on how the retinoblastoma (RB) protein regulates cell growth. Recent evidence indicates that it is a substrate for phosphorylation by cyclin-dependent kinase-cyclin complexes and suggests that this phosphorylation modulates the ability of this protein to regulate transit through the cell cycle, perhaps in its G1 phase.

Interaction between retroviral U5 RNA and the T psi C loop of the tRNA(Trp) primer is required for efficient initiation of reverse transcription.

The 5' end of avian sarcoma and leukosis virus RNA near the primer binding site forms two RNA secondary structures, U5-inverted repeat (U5-IR) and U5-leader stems, which are required for efficient initiation of reverse transcription. Lying between these two secondary structures is a 7-base sequence that can anneal to the T psi C loop of the tRNA(Trp) primer. Base substitutions in U5 RNA which disrupt this potential interaction result in a defect in the initiation of reverse transcription both in vivo and in vitro. The defect can be complemented in vitro by base substitutions in the primer. The U5 RNA-T psi C interaction is also dependent upon the presence of both the U5-IR and the U5-leader structures. These RNA secondary structures and primer interactions are conserved in other type C and D retroviruses, suggesting that there is a common mechanism for the initiation of reverse transcription in all of these retroviruses.

Overlapping retrovirus U5 sequence elements are required for efficient integration and initiation of reverse transcription.

A secondary structure in the 5' noncoding region of avian retrovirus RNA, called the U5-leader stem, was shown previously to have a role in initiation of reverse transcription (D. Cobrinik, L. Soskey, and J. Leis, J. Virol. 62:3622-3630, 1988). We now show that an additional RNA secondary structure near the U5 terminus, called the U5-IR stem, is also important for reverse transcription. Mutations that disrupt the U5-IR stem cause a replication defect associated with both a decrease in synthesis of viral DNA in infected cells and a decrease in initiation of reverse transcription in melittin-permeabilized virions. Structure-compensating base substitutions in the U5-IR restore reverse transcription efficiency. In viral DNA, U5-IR sequences are included in the U5 terminal region that functions as a viral integration donor site. When base substitutions are introduced into these sequences, a reduced efficiency of integration in vitro and in vivo is observed. These observations indicate that U5-IR sequences have a structural role in reverse transcription of viral RNA and a sequence-specific role in the integration of viral DNA.

A retroviral RNA secondary structure required for efficient initiation of reverse transcription.

Genetic evidence is presented which suggests the existence of an important structural element in the 5' noncoding region of avian retrovirus RNA. The proposed structure, which we term the U5-leader stem, is composed of sequences in the middle of U5 and in the leader, flanking the primer-binding site. U5 and leader mutations which would disrupt this structure caused a partial replication defect. However, nucleotide substitutions in the leader, which would structurally compensate for a U5 deletion mutation, restored normal replication. Analysis of replication intermediates of viruses with the above mutations suggests that the U5-leader stem is required for efficient DNA synthesis in vivo and for initiation of DNA synthesis from the tRNA(Trp) primer in melittin-activated virions. However, this structure does not appear to be required for binding of the tRNA(Trp) primer to viral RNA. These results support a role for the U5-leader stem structure, independent of its primary sequence, in the initiation of retroviral replication.

Properties of avian sarcoma-leukosis virus pp32-related pol-endonucleases produced in Escherichia coli.

The gag-pol precursor protein of the avian sarcoma-leukosis virus is processed into three known pol-encoded mature polypeptides; the 95- and 63-kilodalton (kDa) beta and alpha subunits, respectively, of reverse transcriptase and the 32-kDa pp32 protein. The pp32 protein possesses DNA endonuclease activity and is produced from the precursor by two proteolytic cleavage events, one of which removes 4.1 kDa of protein from the C terminus. A 36-kDa protein (p36pol) which retains this C-terminal segment is detectable in small quantities in virions. We have constructed Escherichia coli plasmid clones that express the C-terminal domains of pol corresponding to pp32 and p36. These proteins have been purified by column chromatographic methods to near homogeneity. No significant differences could be detected in the enzymatic properties of the bacterially produced p32pol and p36pol proteins. Both possess DNA endonuclease activity and, like the pp32 protein isolated from virions, can cleave near the junction of two tandem avian sarcoma-leukosis virus long terminal repeats in double-stranded supercoiled DNA substrates. In the presence of Mg2+, both p32pol and viral pp32 cleave either strand of DNA 2 nucleotides 5' to the junction.

Avian sarcoma and leukosis virus pol-endonuclease recognition of the tandem long terminal repeat junction: minimum site required for cleavage is also required for viral growth.

Integration of retroviral DNA is a site-specific reaction involving an endonuclease encoded by the viral pol gene (pol-endo). In vitro the pol-endo from avian sarcoma and leukosis viruses (ASLVs) cleaves both DNA strands near the U5-U3 junction of tandem long terminal repeats (LTR-LTR junction) in single-stranded and replicative form (RF)-I substrates. We have reported previously that the sequences that are required for cleavage of single-stranded substrates by the alpha beta form of the pol-endo differ for the plus and minus strands (G. Duyk, M. Longiaru, D. Cobrinik, R. Kowal, P. deHaseth, A. M. Skalka, and J. Leis, J. Virol. 56:589-599, 1985). This is not the case with RF-I substrates, in which a maximum of 22 base pairs of U5 and 8 base pairs of U3 were required for alpha beta pol-endo cleavage in each strand. Insertion of a palindromic octanucleotide (CATCGATG) at the LTR-LTR junction abolished cleavage in RF-I but not in single-stranded DNA substrates. Deletion of the four nucleotides (TTAA) at the junction prevented cleavage in the plus strand of RF-I DNA, but did not affect cleavage of single-stranded DNA. Furthermore, the alpha beta form of ASLV pol-endo did not recognize heterologous LTR-LTR junction sequences from the reticuloendotheliosis virus or Moloney murine leukemia virus in either substrate form, despite their sequence and structural similarities to the ASLV junction. These results support a role for a sequence-specific interaction between the ASLV pol-endo and the LTR-LTR junction domains that are required for cleavage. By using the infectious Rous sarcoma virus clone pATV8-K, we introduced a set of deletions into the U5 region that would be incorporated into the LTR-LTR junction on viral replication. In the unintegrated provirus, the deletions started 43 base pairs from the LTR-LTR junction and extended various lengths toward the junction. Results of transfection studies with these clones indicated that the U5 sequences that are required for virus production in vivo correspond to those that are required for cleavage of RF-I DNA in vitro.

Circles with two tandem long terminal repeats are specifically cleaved by pol gene-associated endonuclease from avian sarcoma and leukosis viruses: nucleotide sequences required for site-specific cleavage.

The avian retroviral pol gene-encoded DNA endonuclease (pol-endo) has been shown to selectively cleave the viral long terminal repeat sequences (LTRs) in single-stranded DNA substrates in a region known to be joined to host DNA during integration (G. Duyk, J. Leis, M. Longiaru, and A.M. Skalka, Proc. Natl. Acad. Sci. USA 80:6745-6749, 1983). The preferred sites of cleavage were mapped to the unique U5/U3 junctions found only in covalently closed circular DNA molecules containing two tandem LTRs. The cuts occurred three nucleotides 5' to the axis of symmetry of the 12-of-15-base-pair nearly perfect inverted repeat which marks the LTR junction. Experiments with double-stranded supercoiled DNA substrates revealed a similar specificity for nicking. Also, the endonuclease associated with the pol cleavage product, pp32, has the same specificity as the alpha beta form. The limits of sequence required for site-selective cleavage near the U5/U3 junction were established with single-stranded DNA substrates. A domain no larger than 44 base pairs allowed site-selective cleavage in each strand in vitro. Recognition of either strand appeared to be independent of the other, and in each case, the critical sequence was asymmetrically distributed with respect to the U5/U3 junction. The predominant contribution was from the U5 domain; this is consistent with its conservation in the LTR sequences of a number of avian sarcoma and leukosis viruses.