Envelope-dependent transactivation by the retroviral oncoprotein v-Rel is required for efficient malignant transformation of chicken spleen cells.

The retroviral oncoprotein v-Rel is a chimeric protein that has 11 helper virus-derived Envelope (Env) amino acids (aa) at its N terminus. Within these N-terminal Env aa of v-Rel there are three aa substitutions compared to the Rev-A helper virus Env. These aa substitutions have previously been shown to impart a number of unique properties onto v-Rel, including increased transforming and transactivating ability. In this study, we have analysed the sequence requirements for the Env aa to influence several properties of v-Rel. Phe residues at aa 3 and 9 are critical for an N-terminal transactivation function of v-Rel, and the analysis of several Env mutants demonstrates that transactivation ability parallels the transforming ability of v-Rel. Substitutions of conservative aa, such as leucine and tyrosine, for Phe 3 and 9 are tolerated for transactivation in chicken embryo fibroblasts and for transformation of chicken spleen cells. In contrast, the substitution of 10 Phe residues at the N terminus of v-Rel does not enable transactivation, indicating that a distinct structure surrounding Phe-3 and Phe-9 is essential for v-Rel function. We also show that the addition of the v-Rel Env aa to the N terminus of human c-Rel can enable it to activate transcription. Taken together, these results indicate that Phe residues at positions 3 and 9 have been selected for their ability to enhance the oncogenicity of v-Rel by increasing its ability to activate transcription.

Mutant envelope residues confer a transactivation function onto N-terminal sequences of the v-Rel oncoprotein.

The retroviral oncoprotein v-Rel is a member of the Rel/ NF-kappaB family of transcription factors. v-Rel has multiple changes as compared to the proto-oncoprotein c-Rel, and these changes render v-Rel highly oncogenic in avian lymphoid cells. Previous results have shown that three mutant residues in the eleven helper virus-derived Envelope (Env) amino acids (aa) at the N-terminus of v-Rel are required for its full oncogenicity. In this report, we show that these mutant Env aa also enable sequences in the N-terminal half of v-Rel to activate transcription in yeast and chicken cells, under conditions where the analogous sequences from c-Rel either do not or only weakly activate transcription. Removal of the Env aa from v-Rel or site-directed mutations that revert the three mutant residues to the residues present in the Rev-A helper virus Env protein abolish this transactivation ability of v-Rel. Addition of mutant Env aa onto c-Rel is not sufficient to fully restore the transactivation function; other sequences in the N-terminal half of v-Rel are needed for full transactivating ability. A C terminally-truncated form of NF-kappaB p100 (p85), produced in HUT-78 human leukemic cells, also activates transcription in yeast, under conditions where the normal p52 and p100 proteins do not. Furthermore, transcriptional activation by p85 in yeast is likely to occur through N-terminal sequences. Taken together, these results are consistent with a model in which transactivation by N-terminal Rel Homology (RH) domain sequences in oncogenic Rel family proteins is influenced by sequences outside the RH domain.

Diverse agents act at multiple levels to inhibit the Rel/NF-kappaB signal transduction pathway.

Rel/NF-kappaB transcription factors regulate several important physiological processes, including developmental processes, inflammation and immune responses, cell growth, cancer, apoptosis, and the expression of certain viral genes. Therefore, they have also been sought-after molecular targets for pharmacological intervention. As details of the Rel/NF-kappaB signal transduction pathway are revealed, it is clear that modulators of this pathway can act at several levels. Inhibitors of the Rel/NF-kappaB pathway include a variety of natural and designed molecules, including anti-oxidants, proteasome inhibitors, peptides, small molecules, and dominant-negative or constitutively active polypeptides in the pathway. Several of these molecules act as general inhibitors of Rel/NF-kappaB induction, whereas others inhibit specific pathways of induction. Inhibitors of Rel/NF-kappaB are likely to gain stature as treatments for certain cancers and neurodegenerative and inflammatory diseases.

In vitro-translated diphtheria toxin A chain inhibits translation in wheat germ extracts: analysis of biologically active, caspase-3-resistant diphtheria toxin mutants.

The diphtheria toxin A chain (DTA) is a potent cytocidal agent that inactivates elongation factor 2. This activity of DTA inhibits protein synthesis and rapidly leads to cell death through apoptosis. In this paper, we have developed a simple in vitro assay for DTA activity in which in vitro-translated DTA is used to inhibit the translation of proteins in wheat germ extracts. Inhibition of translation by DTA is dependent on cofactor NAD+, and the analysis of an attenuated DTA mutant indicates that this in vitro assay accurately reflects the in vivo activity of DTA. We have also identified aspartic acid at residue 8 (Asp-8) of DTA as a site of cleavage by the cell-death protease caspase-3. Cleavage of DTA by caspase-3 inactivates its ability to inhibit translation in wheat germ extracts. Conservative mutations at Asp-8 render DTA resistant to cleavage by caspase-3, but only slightly affect the ability of DTA to inhibit translation in vitro. Moreover, caspase-3-resistant DTA mutants are toxic in cells in tissue culture. The in vitro assay that we describe here will be useful for the rapid analysis of DTA activity and the development of DTA mutants with altered biological properties that may be of therapeutic value. Lastly, these studies serve as a prototype for the creation of caspase-resistant effector molecules.

IkappaBepsilon-deficient mice: reduction of one T cell precursor subspecies and enhanced Ig isotype switching and cytokine synthesis.

Three major inhibitors of the NF-kappaB/Rel family of transcription factors, IkappaBalpha, IkappaBbeta, and IkappaBepsilon, have been described. To examine the in vivo role of the most recently discovered member of the IkappaB family, IkappaBepsilon, we generated a null allele of the murine IkappaBepsilon gene by replacement of all coding sequences with nlslacZ. Unlike IkappaBalpha nullizygous mice, mice lacking IkappaBepsilon are viable, fertile, and indistinguishable from wild-type animals in appearance and histology. Analysis of beta-galactosidase expression pattern revealed that IkappaBepsilon is mainly expressed in T cells in the thymus, spleen, and lymph nodes. Flow cytometric analysis of immune cell populations from the bone marrow, thymus, spleen, and lymph nodes did not show any specific differences between the wild-type and the mutant mice, with the exception of a reproducible 50% reduction of the CD44-CD25+ T cell subspecies. The IkappaBepsilon-null mice present constitutive up-regulation of IgM and IgG1 Ig isotypes together with a further increased synthesis of these two isotypes after immunization against T cell-dependent or independent Ags. The failure of observable augmentation of constitutive nuclear NF-kappaB/Rel-binding activity is probably due to compensatory mechanisms involving IkappaBalpha and IkappaBbeta, which are up-regulated in several organs. RNase-mapping analysis indicated that IL-1alpha, IL-1beta, IL-1Ra, and IL-6 mRNA levels are constitutively elevated in thioglycolate-elicited IkappaBepsilon-null macrophages in contrast to GM-CSF, G-CSF, and IFN-gamma, which remain undetectable.

Reconstitution of the NF-kappa B system in Saccharomyces cerevisiae for isolation of effectors by phenotype modulation.

NF-kappa B is a ubiquitous transcription factor that contributes to the induction of many genes playing a central role in immune and inflammatory responses. The NF-kappa B proteins are subject to multiple regulatory influences including post-translational modifications such as phosphorylation and proteolytic processing. A very important component of this regulation is the control of their subcellular localization: cytoplasmic retention of NF-kappa B is achieved through interaction with I kappa B molecules. In response to extracellular signals, these molecules undergo degradation, NF-kappa B translocates to the nucleus and activates its target genes. To investigate novel proteins involved in this dynamic response, we have reconstituted the NF-kappa B/I kappa Beta system in the yeast Saccharomyces cerevisiae. We have successively introduced p65, the main transcriptional activator of the NF-kappa B family, which leads to the activation of two reporter genes controlled by kappa B sites, and the I kappa B alpha inhibitory protein, which abolishes this activation. By transforming such a yeast strain with a cDNA library we have performed a genetic screen for cDNAs encoding proteins capable of either dissociating the p65/I kappa B alpha complex or directly transactivating the expression of the reporter genes. The efficiency of our screen was demonstrated by the isolation of a cDNA encoding the p105 precursor of the p50 subunit of NF-kappa B. We also used this system to test stimuli known to activate signalling pathways in yeast, in order to investigate whether the related mammalian cascades might be involved in NF-kappa B activation. We showed that yeast endogenous kinase cascades activated by pheromone, hypo- or hyperosmotic shock cannot modulate NF-kappa B activity in our system, and that the p38 human MAP kinase does not act directly on the p65/I kappa B alpha complex.

I kappa B epsilon, a novel member of the I kappa B family, controls RelA and cRel NF-kappa B activity.

We have isolated a human cDNA which encodes a novel I kappa B family member using a yeast two-hybrid screen for proteins able to interact with the p52 subunit of the transcription factor NF-kappa B. The protein is found in many cell types and its expression is up-regulated following NF-kappa B activation and during myelopoiesis. Consistent with its proposed role as an I kappa B molecule, I kappa B-epsilon is able to inhibit NF-kappa B-directed transactivation via cytoplasmic retention of rel proteins. I kappa B-epsilon translation initiates from an internal ATG codon to give rise to a protein of 45 kDa, which exists as multiple phosphorylated isoforms in resting cells. Unlike the other inhibitors, it is found almost exclusively in complexes containing RelA and/or cRel. Upon activation, I kappa B-epsilon protein is degraded with slow kinetics by a proteasome-dependent mechanism. Similarly to I kappa B-alpha and I kappa B, I kappa B-epsilon contains multiple ankyrin repeats and two conserved serines which are necessary for signal-induced degradation of the molecule. A unique lysine residue located N-terminal of the serines appears to be not strictly required for degradation. Unlike I kappa B- alpha and I kappa B-beta, I kappa B-epsilon does not contain a C-terminal PEST-like sequence. I kappa B-epsilon would, therefore, appear to regulate a late, transient activation of a subset of genes, regulated by RelA/cRel NF-kappa B complexes, distinct from those regulated by other I kappa B proteins.

Cloning and characterization of a yeast cytochrome b5-encoding gene which suppresses ketoconazole hypersensitivity in a NADPH-P-450 reductase-deficient strain.

Cytochrome P-450 (Cyp) 51 or lanosterol-C14-demethylase is the main target for antifungal compounds of the triazole family like ketoconazole (Kz). Disruption of the associated NADPH-P-450 reductase-encoding gene (YRED) is not lethal, but decreases by about 20-fold the Kz resistance (KzR) of wild-type (wt) Saccharomyces cerevisiae. Transformation of a YRED-disrupted strain by a yeast genomic library based on a multicopy vector allowed us to identify a suppressor of Kz hypersensitivity. Deletion analysis of the 5-kb cloned fragment indicated that yeast cytochrome b5-encoding gene (CYB5), which encodes a 120-amino-acid (aa) protein, is required and sufficient for the suppressor effect. The encoded polypeptide shares about 30% aa identity with mammalian cytochromes b5 (Cyb5). CYB5 disruption and tetrad analysis demonstrate that yeast Cyb5 is not required for growth in a Yred+ strain. Determination of the microsomal content of b-type cytochromes by differential spectra indicated the presence of a strongly decreased or null Cyb5 level in the disrupted strain. This confirms that we have cloned the gene encoding the major microsomal form of Cyb5 which appears not to be essential. Minor Cyb5 isoforms could also be present in yeast or other redox proteins could substitute for the pleiotropic roles of Cyb5 in the sterol and lipid biosynthesis pathways.