Transcription factor E2F plays an important role in orchestrating early cell cycle progression through its ability to co-ordinate and integrate the cell cycle with the transcription apparatus. Physiological E2F arises when members of two distinct families of proteins interact as E2F-DP heterodimers, in which the E2F component mediates transcriptional activation and the physical interaction with pocket proteins, such as the tumour suppressor protein pRb. In contrast, a discrete role for the DP subunit has not been defined. We report the identification and characterization of DIP, a novel mammalian protein that can interact with the DP component of E2F. DIP was found to contain a BTB/ POZ domain and shows significant identity with the Drosophila melanogaster germ cell-less gene product. In mammalian cells, DIP is distributed in a speckled pattern at the nuclear envelope region, and can direct certain DP subunits and the associated heterodimeric E2F partner into a similar pattern. DIP-dependent growth arrest is modulated by the expression of DP proteins, and mutant derivatives of DIP that are compromised in cell cycle arrest exhibit reduced binding to the DP subunit. Our study defines a new pathway of growth control that is integrated with the E2F pathway through the DP subunit of the heterodimer.
The product of varicella-zoster virus gene 62 (VZV 140k) is a potent transactivator protein. We have identified a region within the DNA binding domain of VZV 140k that shows a striking similarity to the DNA recognition helix of the homeodomain, with an especially highly conserved quartet of residues, WLQN. The 140k protein has functional counterparts within the other alphaherpesviruses, which include the major transcriptional regulatory protein of HSV-1, (ICP4), and the WLQN region is highly conserved among the members of this family of viral transactivators. Substitution of VZV 140k residue lysine 548, just adjacent to the WLQN region, drastically reduces the DNA binding activity of the 140k DNA binding domain and the intact 140k mutant protein fails to activate gene expression. Substitutions of two other VZV 140k residues in this conserved WLQN region result in alterations to the DNA binding interaction and reduced transactivation activities. All three mutations act at the level of DNA recognition, as they have no apparent effect on the dimerization state, solubility or efficiency of expression of the mutant peptides.
The crucial role of herpes simplex virus type 1 immediate early protein Vmw175 (ICP4) in the regulation of all classes of viral genes has been established by extensive analysis of temperaturesensitive, insertion and deletion mutants. It has long been known that Vmw175 binds to selected DNA sequences, and recent studies have shown that it interacts with components of the basal transcription machinery. However, the role of DNA binding in its mechanism of action has been controversial. Despite the presence of Vmw175 recognition sites at numerous locations throughout the viral genome, it has proved difficult to establish that these sites are
Transcription factor E2F plays an important role in coordinating and integrating early cell cycle progression with the transcription apparatus. It is known that physiological E2F arises when a member of two families of proteins, E2F and DP, interact as E2F/DP heterodimers and that transcriptional activity is regulated through the physical association of pocket proteins such as pRb. However, little information is available regarding the mechanisms which control the levels of functional E2F. In this study, we have characterised one such mechanism which regulates the nuclear accumulation and activity of E2F. Specifically, we show that E2F proteins fall into two distinct categories according to their ability to accumulate in nuclei, one being exemplified by E2F-1 and the other by E2F-4 and -5. Thus, E2F-1 possesses an intrinsic nuclear localization signal whereas E2F-4 and -5 are devoid of such a signal. Furthermore, we find for E2F-4 and -5 that two distinct processes govern their nuclear accumulation whereby the nuclear localization signal is supplied in trans from either a DP heterodimer partner or a physically associated pocket protein. It is consistent with the role of pocket proteins in regulating nuclear accumulation that we find E2F-5 to be nuclear during early cell cycle progression with an increased cytoplasmic concentration in cycling cells. Our data show that the mechanism of nuclear accumulation determines the functional consequence of E2F on cell cycle progression: pocket protein-mediated accumulation impedes cell cycle progression, whereas DP-regulated nuclear accumulation promotes cell cycle progression. Moreover, the inactivation of pocket proteins by the adenovirus Ela protein, and subsequent release of E2F, failed to displace nuclear E2F. Our study identifies a new level of regulation in the control of E2F activity exerted at the level of nuclear accumulation where subunit composition and interaction with pocket proteins dictates the functional consequence on cell cycle progression.
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