Mutational analysis of bovine papillomavirus type 1 E5 peptide domains involved in induction of cellular DNA synthesis.

Early gene E5 of bovine papillomavirus type 1 encodes a 44-amino-acid protein whose expression can transform immortalized mouse cell lines. We have previously reported that a chemically synthesized E5 peptide functions to induce cellular DNA synthesis upon microinjection into growth-arrested mouse cells. We further defined the two E5 domains essential for the full DNA synthesis induction activity by the analysis of E5 deletion and amino acid substitution mutant peptides. The first domain is the C-terminal 13-amino-acid core which is sufficient to activate DNA synthesis at high peptide concentration and contains two essential, highly conserved cysteine residues. The second domain is the 7-amino-acid hydrophobic sequence contiguous to the core domain which is sufficient to confer a 1,000-fold higher molar specific activity to the E5 peptide. A random hydrophobic sequence, but not charged amino acids, fulfills the function of the second domain.     

The E5 oncoprotein of bovine papillomavirus binds to a 16 kd cellular protein.

The E5 oncoprotein of bovine papillomavirus type 1 is the smallest known viral transforming protein. It is a 44 amino acid polypeptide asymmetrically oriented in Golgi and plasma membranes which appears to modify (either directly or indirectly) the internalization and phosphorylation of at least two growth factor receptors: EGF and CSF-1. To identify cellular proteins associated with E5, we have constructed two E5 fusion proteins, each of which contains a well-characterized epitope at the E5 amino terminus. These E5-epitope fusion proteins are biologically active, localize normally to cellular membranes and form dimers. Both monoclonal and polyclonal antibodies against the inserted epitopes specifically co-precipitate E5 and an associated 16 kd cellular protein. A transformation-defective E5 mutant containing a substitution within the hydrophobic portion of E5 is defective in its ability to bind the 16 kd protein. These findings suggest a role for E5/16 kd binding in the process of cellular transformation.     

The v-sis protein retains biological activity as a type II membrane protein when anchored by various signal-anchor domains, including the hydrophobic domain of the bovine papilloma virus E5 oncoprotein

Membrane-anchored forms of the v-sis oncoprotein have been previously described which are oriented as type I transmembrane proteins and which efficiently induce autocrine transformation. Several examples of naturally occurring membrane-anchored growth factors have been identified, but all exhibit a type I orientation. In this work, we wished to construct and characterize membrane-anchored growth factors with a type II orientation. These experiments were designed to determine whether type II membrane-anchored growth factors would in fact exhibit biological activity. Additionally, we wished to determine whether the hydrophobic domain of the E5 oncoprotein of bovine papilloma virus (BPV) can function as a signal-anchor domain to direct type II membrane insertion. Type II derivatives of the v-sis oncoprotein were constructed, with the NH2 terminus intracellular and the COOH terminus extracellular, by substituting the NH2 terminal signal sequence with the signal-anchor domain of a known type II membrane protein. The signal-anchor domains of neuraminidase (NA), asialoglycoprotein receptor (ASGPR) and transferrin receptor (TR) all yielded biologically active type II derivatives of the v-sis oncoprotein. Although transforming all of the type II signal/anchor-sis proteins exhibited a very short half-life. The short half-life exhibited by the signal/anchor-sis constructs suggests that, in some cases, cellular transformation may result from the synthesis of growth factors so labile that they activate undetectable autocrine loops. The E5 oncoprotein encoded by BPV exhibits amino acid sequence similarity with PDGF, activates the PDGF beta-receptor, and thus resembles a miniature membrane-anchored growth factor with a putative type II orientation. The hydrophobic domain of the E5 oncoprotein, when substituted in place of the signal sequence of v-sis, was indistinguishable compared with the signal-anchor domains of NA, TR, and ASGPR, demonstrating its ability to function as a signal-anchor domain. NIH 3T3 cells transformed by the signal/anchor-sis constructs exhibited morphological reversion upon treatment with suramin, indicating a requirement for ligand/receptor interactions in a suramin- sensitive compartment, most likely the cell surface. In contrast, NIH 3T3 cells transformed by the E5 oncoprotein did not exhibit morphological reversion in response to suramin.     

The BPV-1 E5 protein, the 16 kDa membrane pore-forming protein and the PDGF receptor exist in a complex that is dependent on hydrophobic transmembrane interactions.

The E5 oncoprotein of bovine papillomavirus type 1 is a 44 amino acid, highly hydrophobic protein that induces the stable transformation of immortalized murine fibroblasts, presumably through its activation of growth factor receptors. Previous studies have shown that the E5 protein complexes with the 16 kDa (16k) pore-forming protein of vacuolar H(+)-ATPases. This integral membrane protein is essential for the acidification and function of subcellular compartments that process growth factor receptors. Using an SV40 expression system in COS cells, we analyzed whether the E5-16k complexes bind additional cellular proteins, including growth factor receptors. These studies demonstrate that E5 binds to both the 16k protein and the PDGF receptor and that this tri-component complex can be isolated with antibodies specific for each protein. Importantly, the 16k protein bound to the PDGF receptor in the absence of E5, suggesting that E5 binds to the PDGF receptor via its interaction with the 16k protein. An E5 mutant lacking the hydrophilic carboxyl-terminal 14 amino acids retained binding to both 16k and the PDGF receptor, indicating that E5 binds to these proteins through its hydrophobic, membrane-associating domain. These studies reveal that hydrophobic, intramembrane interactions govern the association of E5, 16k and the PDGF receptor, suggesting a ligand-independent mechanism for receptor activation and a potential link between receptor signal transduction pathways and membrane pore activity.     

The human T-cell leukemia/lymphotropic virus type I p12I protein cooperates with the E5 oncoprotein of bovine papillomavirus in cell transformation and binds the 16-kilodalton subunit of the vacuolar H+ ATPase.

The human T-cell leukemia/lymphotropic virus type I (HTLV-I) induces T-cell leukemia and transforms human T cells in vitro. A recently identified protein with a molecular weight of 12,000 (12K) (p12I), encoded by single- and double-spliced mRNAs transcribed from the 3' end of the HTLV-I genome, has been shown to localize in the perinuclear compartment and in the cellular endomembranes. The p12I protein exhibits significant amino acid sequence similarity to the E5 oncoprotein of bovine papillomavirus type 1 (BPV-1). Both proteins are very hydrophobic, contain a glutamine residue in the middle of a potential transmembrane region(s), and are localized in similar cellular compartments. Because of these observations, we investigated whether the p12I resemblance to E5 correlated with a similarity in their biological behavior. We expressed the p12I protein to evaluate its ability to functionally cooperate with the BPV-1 E5 oncoprotein and to bind to a cellular target of the E5 protein, the 16K component of the vacuolar H+ ATPase. Cotransfection of the mouse C127 cell line with the p12I and E5 cDNAs showed that although p12I alone could not induce focus formation, it strongly potentiated the transforming activity of E5. In addition, the p12I protein bound to the 16K protein as efficiently as the E5 protein. These findings might provide new insight for potential mechanisms of HTLV-I transformation and suggest that p12I and E5 represent an example of convergent evolution between RNA and DNA viruses.     

A glutamine residue in the membrane-associating domain of the bovine papillomavirus type 1 E5 oncoprotein mediates its binding to a transmembrane component of the vacuolar H(+)-ATPase.

The 44-amino-acid E5 oncoprotein is the major transforming protein of bovine papillomavirus type 1. It is a highly hydrophobic polypeptide which dimerizes and localizes to the Golgi apparatus and endoplasmic reticulum membranes. Recent evidence suggests that E5 modulates the phosphorylation and internalization of the epidermal growth factor and colony-stimulating factor 1 receptors and constitutively activates platelet-derived growth factor receptors in C127 and FR3T3 cells. Although no direct interaction with these growth factor receptors has yet been identified, the E5 oncoprotein has been shown recently to interact with the hydrophobic 16-kDa component of the vacuolar H(+)-ATPase (16K protein) [D. J. Goldstein, M. E. Finbow, T. Andresson, P. McLean, K. Smith, V. Bubb, and R. Schlegel, Nature (London) 352:347-349, 1991]. In the current study, we have further analyzed the E5-16K protein complex by fast protein liquid chromatography and shown that each E5 dimer appears to bind two 16K proteins. In order to define the specific amino acid residues of E5 which participate in this binding, mutated E5 epitope fusion proteins were analyzed for their ability to coprecipitate 16K protein. Transformation-defective mutants containing amino acid substitutions within the short hydrophilic carboxyl-terminal domain retained the ability to associate with the 16K protein. However, E5 mutants lacking the glutamine residue in the hydrophobic domain were markedly inhibited in 16K protein binding. Most interestingly, the placement of a glutamine in several random hydrophobic sequences facilitated 16K protein binding, defining this residue as a potential binding site for the 16K protein component of the proton pump and exemplifying the critical role of hydrophilic amino acids for mediating specific interactions between transmembrane proteins.     

The herpes simplex virus type 1 (HSV-1) regulatory protein ICP0 interacts with and Ubiquitinates p53

Herpes simplex virus type 1 regulatory protein ICP0 contains a zinc-binding RING finger and has been shown to induce the proteasome-dependent degradation of a number of cellular proteins in a RING finger-dependent manner during infection. This domain of ICP0 is also required to induce the formation of unanchored polyubiquitin chains in vitro in the presence of ubiquitin-conjugating enzymes UbcH5a and UbcH6. These data indicate that ICP0 has the potential to act as a RING finger ubiquitin ubiquitin-protein isopeptide ligase (E3) and to induce the degradation of certain cellular proteins through ubiquitination and proteasome-mediated degradation. Here we demonstrate that ICP0 is a genuine RING finger ubiquitin E3 ligase that can interact with and mediate the ubiquitination of the major oncoprotein p53 both in vitro and in vivo. Ubiquitination of p53 requires ICP0 to have an intact RING finger domain and occurs independently of its ability to bind to the ubiquitin-specific protease USP7.     

Selection and characterization of small random transmembrane proteins that bind and activate the platelet-derived growth factor beta receptor

Growth factor receptors are typically activated by the binding of soluble ligands to the extracellular domain of the receptor, but certain viral transmembrane proteins can induce growth factor receptor activation by binding to the receptor transmembrane domain. For example, homodimers of the transmembrane 44-amino acid bovine papillomavirus E5 protein bind the transmembrane region of the PDGF beta receptor tyrosine kinase, causing receptor dimerization, phosphorylation, and cell transformation. To determine whether it is possible to select novel biologically active transmembrane proteins that can activate growth factor receptors, we constructed and identified small proteins with random hydrophobic transmembrane domains that can bind and activate the PDGF beta receptor. Remarkably, cell transformation was induced by approximately 10% of the clones in a library in which 15 transmembrane amino acid residues of the E5 protein were replaced with random hydrophobic sequences. The transformation-competent transmembrane proteins formed dimers and stably bound and activated the PDGF beta receptor. Genetic studies demonstrated that the biological activity of the transformation-competent proteins depended on specific interactions with the transmembrane domain of the PDGF beta receptor. A consensus sequence distinct from the wild-type E5 sequence was identified that restored transforming activity to a non-transforming poly-leucine transmembrane sequence, indicating that divergent transmembrane sequence motifs can activate the PDGF beta receptor. Molecular modeling suggested that diverse transforming sequences shared similar protein structure, including the same homodimer interface as the wild-type E5 protein. These experiments have identified novel proteins with transmembrane sequences distinct from the E5 protein that can activate the PDGF beta receptor and transform cells. More generally, this approach may allow the creation and identification of small proteins that modulate the activity of a variety of cellular transmembrane proteins.     

Analysis of E1A-mediated growth regulation functions: binding of the 300-kilodalton cellular product correlates with E1A enhancer repression function and DNA synthesis-inducing activity.

Adenovirus E1A transforming function requires two distinct regions of the protein. Transforming activity is closely linked with the presence of a region designated conserved domain 2 and the ability of this region to bind the product of the cellular retinoblastoma tumor suppressor gene. We have investigated the biological properties of the second transforming region of E1A, which is located near the N terminus. Transformation-defective mutants containing deletions in the N terminus (deletion of residues between amino acids 2 and 36) were deficient in the ability to induce DNA synthesis and repress insulin enhancer-stimulated activity. The function of the N-terminal region correlated closely with binding of the 300-kilodalton E1A-associated protein and not with binding of the retinoblastoma protein. These results indicate that transformation by E1A is mediated by two functionally independent regions of the protein which interact with different specific cellular proteins and suggest that the 300-kilodalton E1A-associated protein plays a major role in E1A-mediated cell growth control mechanisms.     

The central hydrophobic domain of the bovine papillomavirus E5 transforming protein can be functionally replaced by many hydrophobic amino acid sequences containing a glutamine.

The 44-amino-acid E5 transforming protein of bovine papillomavirus can induce growth transformation of cultured rodent fibroblast cell lines. Previous studies revealed that efficient transformation of mouse C127 cells by the E5 protein required a central core of hydrophobic amino acids and several specific carboxyl-terminal amino acids. Although a randomly derived sequence of hydrophobic amino acids could functionally replace the wild-type hydrophobic core, most such sequences could not. We show here that the conserved glutamine at position 17 in the hydrophobic domain is also important for transformation and that insertion of the glutamine can rescue the transforming activity of many but not all otherwise defective mutants containing random hydrophobic sequences. However, a class of mutants was identified that transform efficiently even in the absence of glutamine, demonstrating that the presence of this amino acid is not absolutely required for efficient transformation. E5 proteins containing the glutamine appear to display increased homodimer formation compared with mutant proteins lacking the glutamine, but this amino acid has no apparent effect on protein stability.     

The conserved C-terminal domain of the bovine papillomavirus E5 oncoprotein can associate with an alpha-adaptin-like molecule: a possible link between growth factor receptors and viral transformation.

The bovine papillomavirus E5 gene encodes an oncoprotein that can independently transform rodent fibroblasts. This small 44-amino-acid protein is thought to function through the activation of growth factor receptors. E5 activation of the epidermal growth factor receptor results in an increase in the number of activated receptors at the cell surface. This finding suggests that E5 may act by inhibiting the normal down regulation of activated epidermal growth factor receptor via coated pit-mediated endocytosis. We have constructed a fusion protein consisting of glutathione S-transferase and the conserved C-terminal domain of E5 (GST-E5) in order to identify E5-associated cellular proteins that may be involved in its transforming activity. We have identified a 125-kDa cellular protein with a strong associated serine kinase activity that specifically associated with GST-E5 in the reduced form but not with GST-E5 fusions that contained changes in several conserved amino acids. Microsequence and biochemical analyses suggest that p125 is a novel member of the alpha-adaptin family. Since alpha-adaptins have previously been shown to be involved in coated pit-mediated cell surface receptor endocytosis and down regulation, these results suggest that p125 may be an alpha-adaptin-like molecule involved in growth factor receptor down regulation and that E5 may act by inhibiting its activity.     

Failure to trigger the autolytic enzymes in minicells of Escherichia coli

Minicells from Escherichia coli P678-54 are refractory towards procedures known to induce bacteriolysis of DNA-containing E. coli cells. Although still engaged in murein synthesis, minicells could not be lysed by penicillin G. Likewise, endogenous overproduction of the cloned soluble lytic transglycosylase, the predominant murein hydrolytic activity in E. coli, failed to lyse minicells. Furthermore, induction of the phage MS2 lysis protein, a hydrophobic protein assumed to trigger the autolytic system of the host, did not result in bacteriolysis. It is concluded that the murein hydrolases present in minicells are under a tight cellular control.     

Transforming activity of a 16-amino-acid segment of the bovine papillomavirus E5 protein linked to random sequences of hydrophobic amino acids.

The 44-amino-acid E5 protein of bovine papillomavirus type 1 is the smallest transforming protein yet described. Previous results from our laboratory indicate that a hydrophobic core and specific carboxyl-terminal amino acids are required for the E5 protein to exert its transforming function. In this study, additional substitution mutations were generated in the E5 gene to determine the minimal amino acid sequence requirements for focus formation in mouse C127 cells. In most cases examined, substitution of the hydrophobic middle third of the E5 protein with unrelated hydrophobic sequences severely inhibited transforming activity. However, we have identified one hydrophobic amino acid sequence apparently unrelated to the wild-type one that can replace the middle third of the wild-type E5 protein without affecting the ability of the protein to stably transform cells or interact with cell membranes. Furthermore, a mutant E5 protein in which only the carboxyl-terminal 16 amino acids of the protein have been derived from E5 sequences retains transforming activity. Since several residues in the carboxyl-terminal portion of the E5 protein can be freely substituted with different amino acids (B. H. Horwitz, A. L. Burkhardt, R. Schlegel, and D. DiMaio, Mol. Cell. Biol. 8:4071-4078, 1988), the results reported here imply that much of the specific information necessary for cell transformation can be supplied by a subset of the carboxyl-terminal 16 amino acids of this protein.     

Activation of the platelet-derived growth factor receptor by the bovine papillomavirus E5 transforming protein.

The bovine papillomavirus E5 gene encodes a 44 amino acid membrane-associated protein that can induce tumorigenic transformation of rodent fibroblast cell lines. Genetic studies suggest that the E5 protein may transform cells by influencing the activity of cellular proteins involved in growth regulation. We report here that the endogenous cellular beta type receptor for the platelet-derived growth factor (PDGF) is constitutively activated in C127 and FR3T3 cells stably transformed by the E5 protein, but not in these cell types transformed by a variety of other oncogenes. In C127 cells, a metabolic precursor as well as the mature form of the receptor is activated by E5 transformation. Activation of the receptor also occurs upon acute E5-mediated transformation of these cells and precedes mitogenic stimulation in this system. Moreover, activation of the receptor by addition of PDGF or the v-sis gene to untransformed cells is sufficient to induce DNA synthesis and stable growth transformation. We propose that the PDGF receptor is an important cellular intermediate in the transforming activity of the bovine papillomavirus E5 protein. There is a short region of sequence similarity between the fibropapillomavirus E5 proteins and PDGF, suggesting that the E5 proteins may activate the PDGF receptor by binding directly to it.     

E5 oncoprotein transmembrane mutants dissociate fibroblast transforming activity from 16-kilodalton protein binding and platelet-derived growth factor receptor binding and phosphorylation.

The E5 oncoprotein of bovine papillomavirus type 1 is a 44-amino-acid, hydrophobic polypeptide which localizes predominantly in Golgi membranes and appears to transform cells through the activation of tyrosine kinase growth factor receptors. In fibroblasts, E5 interacts with both the 16-kilodalton vacuolar ATPase subunit and the platelet-derived growth factor receptor (PDGF-R) via its hydrophobic transmembrane domain and induces autophosphorylation of the receptor. To further analyze the correlation between E5 biological activity and its ability to bind these cellular proteins, a series of nine E5 transmembrane mutants was evaluated. In 32D mouse hematopoietic cells, there was an incomplete correlation between the abilities of the E5 mutant proteins to associate the PDGF-R and to transform cells. However, all transforming E5 mutant proteins induced PDGF-R tyrosine phosphorylation. In NIH 3T3 and C127 mouse fibroblasts, both transforming and nontransforming E5 mutant proteins were defective for PDGF-R binding. In addition, while most of the transforming E5 proteins induced PDGF-R phosphorylation, one hypertransforming mutant (serine 17) neither bound nor induced receptor autophosphorylation. These findings support the hypothesis that the transformation of fibroblasts by E5 transmembrane mutants can involve alternative cellular targets or potentially independent activities of the E5 protein. In addition, these results underscore the critical role of the transmembrane domain in mediating E5 biological activities.     

The adenovirus E1A protein overrides the requirement for cellular ras in initiating DNA synthesis.

The adenovirus E1A protein can induce cellular DNA synthesis in growth-arrested cells by interacting with the cellular protein p300 or pRb. In addition, serum- and growth factor-dependent cells require ras activity to initiate DNA synthesis and recently we have shown that Balb/c 3T3 cells can be blocked in either early or late G1 following microinjection of an anti-ras antibody. In this study, the E1A 243 amino acid protein is shown through microinjection not only to shorten the G0 to S phase interval but, what is more important, to override the inhibitory effects exerted by the anti-ras antibody in either early or late G1. Specifically, whether E1A is co-injected with anti-ras into quiescent cells or injected 18 h following a separate injection of anti-ras after serum stimulation, it efficiently induces cellular DNA synthesis in cells that would otherwise be blocked in G0/G1. Moreover, injection of a mutant form of E1A that can no longer associate with p300 is just as efficient as wild-type E1A in stimulating DNA synthesis in cells whose ras activity has been neutralized by anti-ras. The results presented here show that E1A is capable of overriding the requirement of cellular ras activity in promoting the entry of cells into S phase. Moreover, the results suggest the possibility that pRb and/or pRb-related proteins may function in a ras-dependent pathway that enables E1A to achieve this activity.