Mark E. Ewen

Functional interactions of the retinoblastoma protein with mammalian D-type cyclins

The retinoblastoma gene product (Rb) can interact efficiently with two of three D-type G1 cyclins (D2 and D3) in vitro. Binding depended upon the minimal regions of Rb necessary for its growth-suppressive activity, as well as upon the D-type cyclin sequence motif shared with Rb-binding DNA tumor virus oncoproteins. Coexpression of the three D-type cyclins with the cyclin-dependent kinase (cdk4) in insect cells generated Rb kinase activity. By contrast, cyclins D2 and D3, but not D1, activated another such kinase, cdk2. Introduction of cyclin D2 and Rb into the Rb-deficient cell line SAOS-2 led to overt Rb hyperphosphorylation, whereas Rb, expressed alone or together with cyclin D1, remained unphosphorylated. Cyclin D2-dependent phosphorylation inhibited its binding to the transcription factor E2F and reversed the Rb G1 exit block in the cell cycle. Thus, all D-type cyclins do not function equivalently, and one of them plays a major role in reversing the cycle-blocking function of a known tumor suppressor.

Identification and properties of an atypical catalytic subunit (p34PSK-J3/cdk4) for mammalian D type G1 cyclins

Murine D type cyclins associate with a catalytic subunit (p34PSK-J3) with properties distinct from known cyclin-dependent kinases (cdks). Mouse p34PSK-J3 shows less than 50% amino acid identity to p34cdc2, p33cdk2, and p36cdk3, lacks a PSTAIRE motif, and does not bind to p13suc1. Cyclin D1-p34PSK-J3 complexes accumulate in macrophages during G1 and decline in S phase, whereas complexes involving cyclins D2 and D3 form in proliferating T cells. Although histone H1 kinase activity is not detected in cyclin D or PSK-J3 immunoprecipitates, cyclin D-p34PSK-J3 complexes assembled in vitro stably bind and phosphorylate the retinoblastoma gene product (pRb) and an Rb-like protein (p107) but do not interact with pRb mutants that are functionally inactive. Thus, p34PSK-J3 is a cyclin D-regulated catalytic subunit that acts as an Rb (but not H1) kinase.

TGFβ inhibition of Cdk4 synthesis is linked to cell cycle arrest

Abstract Transforming growth factor β1 (TGFβ1) causes G1 growth arrest and the accumulation of unphosphorylated retinoblastoma protein (Rb) in responsive cells. Cdk4 (cyclin-dependent kinase), a major catalytic subunit of the mammalian D-type G1 cyclins, can phosphorylate Rb in vitro, and at least one D-type cyclin, D2, directs the phosphorylation of Rb in vivo. Here we show that TGFβ1 induces suppression of cdk4 synthesis in G1 in mink lung epithelial cells. Constitutive cdk4 synthesis in these cells led to TGFβ1 resistance. It also resulted in growth in low serum medium when these cells were released from contact inhibition. Cdk2 activity was also suppressed by TGFβ1 action, but its constitutive expression failed to override a TGFβ1-induced G1 block. Hence, the TGFβ1 block is primarily mediated by cdk4 modulation. Further evidence suggests that TGFβ1-induced down-modulation of cdk4 leads to inhibition of cdk2 activation and that both events might contribute to TGFβ1 growth suppression.

Negative regulation of the growth-promoting transcription factor E2F-1 by a stably bound cyclin A-dependent protein kinase

Cyclin A-kinase, an enzyme required for coordinating S phase progression, forms stable in vivo complexes with E2F-1, a growth-promoting transcription factor, which binds to the retinoblastoma gene product and is involved in the timely activation of genes whose products contribute to G1 exit and S phase traversal. Complex formation results in a negative biochemical effect of cyclin A-kinase: the shut-off of E2F-1-dependent DNA binding function in S/G2. Thus, specific and timely cell cycle-dependent interactions of E2F-1 with proteins that inhibit its function (i.e., RB during G1 and cyclin A-kinase during S/G2) may contribute to the periodicity of expression of certain E2F-1-responsive genes at the G1/S transition.

Molecular cloning, chromosomal mapping, and expression of the cDNA for p107, a retinoblastoma gene product-related protein

p107 is a cellular protein that forms specific complexes with adenovirus E1A and SV40 large T antigen (T). The genetics of the p107-T/E1A interaction as well as other features of this protein suggests that p107 shares functional properties with the tumor suppressor product, RB. A partial cDNA for human p107 has been cloned. Its sequences map to 20q11.2 and encode a 936 residue protein. Comparison analysis of the p107 protein sequence reveals a major region of RB homology extending over 564 residues. This region in RB is essential to its growth-controlling function. Sequences outside of these two regions are largely unique to each protein. The p107 and RB homology regions can independently bind to T and E1A. Thus, these two proteins display similarities of structure that may, at least in part, explain their known functional similarities and suggest a generic function for p107 in cell cycle regulation.

A Mechanism of Cyclin D1 Action Encoded in the Patterns of Gene Expression in Human Cancer

Here we describe how patterns of gene expression in human tumors have been deconvoluted to reveal a mechanism of action for the cyclin D1 oncogene. Computational analysis of the expression patterns of thousands of genes across hundreds of tumor specimens suggested that a transcription factor, C/EBPbeta/Nf-Il6, participates in the consequences of cyclin D1 overexpression. Functional analyses confirmed the involvement of C/EBPbeta in the regulation of genes affected by cyclin D1 and established this protein as an indispensable effector of a potentially important facet of cyclin D1 biology. This work demonstrates that tumor gene expression databases can be used to study the function of a human oncogene in situ.

Cyclin D1 stimulation of estrogen receptor transcriptional activity independent of cdk4.

Cyclin D1 plays an important role in the development of breast cancer and is required for normal breast cell proliferation and differentiation associated with pregnancy. We show that ectopic expression of cyclin D1 can stimulate the transcriptional activity of the estrogen receptor in the absence of estradiol and that this activity can be inhibited by 4-hydroxytamoxifen and ICI 182,780. Cyclin D1 can form a specific complex with the estrogen receptor. Stimulation of the estrogen receptor by cyclin D1 is independent of cyclin-dependent kinase 4 activation. Cyclin D1 may manifest its oncogenic potential in breast cancer in part through binding to the estrogen receptor and activation of the transcriptional activity of the receptor.

The cell cycle and the retinoblastoma protein family

Tumor formation results from alterations in the control of normal cell proliferation. To further our understanding of the molecular mechanisms underlying the deregulation of cell proliferation much attention, over the past decade, has been focused on the function of proto-oncogenes. Cellular oncogenes are thought to be growth promoting. More recently, a class of genes known as tumor suppressors have come under intense study. Tumor suppressors are largely thought to restrain cell proliferation. The retinoblastoma protein (Rb) is one of a growing list of tumor suppressors. Concurrent with the study of tumor suppressor genes has been a rapid increase in our understanding of the cell cycle at the molecular level. Rb and a related protein p107 are involved in the processes of cell proliferation and differentiation. Each functionally interacts with and affects the activity of the transcription factor E2F as well as other transcription factors involved in cell proliferation and differentiation. Additionally, Rb and p107 are modified by, and/or form specific complexes with, several elements of the basic cell cycle machinery. Specifically, Rb and p107 interact with and are modified by various cyclins and cyclin dependent kinases (cdk), some of which have been shown to be essential for cell cycle progression and in some cases their deregulation has been implicated in the development of cancer. This review will attempt to convey our current functional and mechanistic understanding of the biological roles Rb and p107 play in proliferation, development and differentiation. A knowledge of the interplay between these positive and negative regulators of cell proliferation and differentiation, noted above, is central to our understanding of human cancer.

The transcription factor E2F-1 is a downstream target of RB action.

Reintroduction of RB into SAOS2 (RB-/-) cells causes a G1 arrest and characteristic cellular swelling. Coexpression of the cellular transcription factor E2F-1 could overcome these effects. The ability of E2F-1 to bind to RB was neither necessary nor sufficient for this effect, and S-phase entry was not accompanied by RB hyperphosphorylation under these conditions. Furthermore, E2F-1 could overcome the actions of a nonphosphorylatable but otherwise intact RB mutant. These data, together with the fact that RB binds to E2F-1 in vivo, suggest that E2F-1 is a downstream target of RB action. Mutational analysis showed that the ability of E2F-1 to bind to DNA was necessary and sufficient to block the formation of large cells by RB, whereas the ability to induce S-phase entry required a functional transactivation domain as well. Thus, the induction of a G1 arrest and the formation of large cells by RB in these cells can be genetically dissociated. Furthermore, the ability of the E2F-1 DNA-binding domain alone to block one manifestation of RB action is consistent with the notion that RB-E2F complexes actively repress transcription upon binding to certain E2F-responsive promoters. In keeping with this view, we show here that coproduction of an E2F1 mutant capable of binding to DNA, yet unable to transactivate, is sufficient to block RB-mediated transcriptional repression.

An N-Terminal transformation-governing sequence of SV40 large T antigen contributes to the binding of both p110Rb and a second cellular protein, p120

In addition to Rb and p53, a third cellular protein, p120 in monkey and p118 in human cells, forms a specific complex with SV40 large T antigen (T). p118/120 is not a product of the Rb-gene. As was shown with T/Rb complex formation, the interaction between T and p120 is dependent on the intact nature of a ten residue, transformation-controlling domain in T (residues 105-114). In mouse cells, a readily detectable protein of 115 kd was detected, which, like murine Rb, also forms a stable complex with T. Like p118/120, p115 binding is also dependent on the intact nature of the 105-114 sequence. Given their similar size and T antigen binding sequence dependence, p115 and p118/120 may be products of the same gene in different species. These results suggest that interactions between T and p115/118/120, as well as T and Rb, contribute to the SV40 transforming mechanism.