Composition and arrangement of genes define the strength of IRES-driven translation in bicistronic mRNAs.

In addition to the cap-dependent mechanism, eukaryotic initiation of translation can occur by a cap-independent mechanism which directs ribosomes to defined start codons enabled by internal ribosome entry site (IRES) elements. IRES elements from poliovirus and encephalomyocarditis virus are often used to construct bi- or oligocistronic expression vectors to co-express various genes from one mRNA. We found that while cap-dependent translation initiation from bicistronic mRNAs remains comparable to monocistronic expression, internal initiation mediated by these viral IRESs is often very inefficient. Expression of bicistronic expression vectors containing the hepatitis B virus core antigen (HBcAg) together with various cytokines in the second cistron of bicistronic mRNAs gave rise to very low levels of the tested cytokines. On the other hand, the HBcAg was well expressed when positioned in the second cistron. This suggests that the arrangement of cistrons in a bicistronic setting is crucial for IRES-dependent translation of the second cistron. A systematic examination of expression of reporter cistrons from bicistronic mRNAs with respect to position was carried out. Using the dual luciferase assay system we show that the composition of reading frames on a bicistronic mRNA and the order in which they are arranged define the strength of IRES-dependent translation. Although the cellular environment and the nature of the IRES element influence translation strength the dominant determinant is the nature and the arrangement of cistrons on the mRNA.

Interplay between repressing and activating domains defines the transcriptional activity of IRF-1.

Interferon regulatory factor-1 (IRF-1) is a transcriptional activator with weak activation capacity. By defining the transcriptional activation domain of IRF-1 we identified two activator fragments located between amino acids 185 and 256 functioning in an additive manner. Another fragment of IRF-1, which has no activator function alone, acts as a strong enhancer element of these activator sequences. This enhancer element resides between the activator domains and the C-terminus. In addition, we identified a novel type of inhibitory domain in the N-terminal 60 amino acids of IRF-1 which strongly inhibits its transcriptional activity. Because this fragment is conserved in all interferon regulatory factors, we found similar repression effects in the corresponding fragments in IRF-2, IRF-3 and interferon consensus sequence binding protein (ICSBP/IRF-8). Interestingly, the corresponding sequence in p48/IRF-9 is divergent, so that it does not show this inhibitory activity. A five-amino-acid sequence distinguishes the p48/IRF-9 N-terminus from the homologous parts in other interferon regulatory factors containing the repressing function. Replacing the diverged amino acids in IRF-1 with the corresponding sequence of p48/IRF-9 resulted in a loss of inhibitory activity within IRF-1. The opposing activities within interferon regulatory factors may contribute to balanced or tuned regulation of gene activation, depending on the promoter context.

Translation of NRF mRNA is mediated by highly efficient internal ribosome entry.

The ubiquitous transcription factor NRF (NF-kappaB repressing factor) is a constitutive transcriptional silencer of the multifunctional cytokine interferon-beta. NRF mRNA contains a long 5' untranslated region (5'UTR) predicted to fold into a strong secondary structure. The presence of stable hairpins is known to be incompatible with efficient translation by ribosomal scanning. Using dicistronic reporter gene constructs, we show that the NRF 5'UTR acts as an internal ribosome entry site (IRES) which directs ribosomes to the downstream start codon by a cap-independent mechanism. The relative activity of this IRES in various cell lines is at least 30-fold higher than that of picornaviral IRESs. The NRF 5'UTR also functions as a translational enhancer in the context of monocistronic mRNAs. Our results indicate that the NRF 5'UTR contains a highly potent IRES, which may allow for an alternate mode of translation under physiological conditions in which cap-dependent translation is inhibited.

NRF, a nuclear inhibitor of NF-kappaB proteins silencing interferon-beta promoter.

The family of NF-kappaB/rel transcription factors regulates a variety of promoters through specific DNA-binding sites. Consistent with the role of NF-kappaB activation as a response to pathogens, it regulates the expression of immune modulating cytokines like interferon-beta3 (IFN-3). Transcriptional regulation of IFN-beta is characterized by strict constitutive repression and virus-mediated activation. A nuclear protein, called NRF (NF-kappaB repressing factor) silences constitutively the IFN-beta3 promoter by binding to the negative regulatory element (NRE). This control is achieved by a direct protein-protein interaction between NRF and proximal bound NF-kappaB factors preventing the transcriptional activation. After viral induction NRF still binds but does not any more exert its specific inhibition. NRE-related sequences found in a number of promoters like those of HIV-1, HTLV-1 and the genes of the IL-2Ralpha and IL-8 constitute functionally related silencer elements which repress the constitutive enhancing activity of NF-kappaB/rel-binding sites from these promoters.

Protein-protein and DNA-protein interactions affect the activity of lymphoid-specific IFN regulatory factors.

IFN regulatory factors (IRFs) constitute a family of transcription factors that are involved in IFN signaling and the development and differentiation of the immune system. Targeted gene disruption studies in mice assigned their primary role to the immune system. Two lymphoid-specific IRF members, IFN consensus sequence binding protein (ICSBP) and IRF-4, bind target DNA with greater efficiency following interaction with two transcription factors, PU.1 and E47, leading to transcriptional synergy. PU.1 and E47 are essential for proper differentiation and maturation of lymphoid cells. In addition, ICSBP interacts with two IRF members, IRF-1 and IRF-2, which also have central roles in the regulation of cell-mediated immunity. Previously, we identified a region in ICSBP, termed the IRF association domain (IAD), that is conserved in all IRFs (excluding IRF-1 and IRF-2) and is essential for its interactions with other IRF proteins. Here we show that the IAD is an independent module used by ICSBP and IRF-4 for protein-protein interactions. In addition, an IAD of IRF-2 (IAD2), necessary for interaction with ICSBP, was identified and found to be conserved in IRF-1. The IAD2 shares similar characteristics with the PEST domain that is essential for the interaction of PU.1 with IRF-4. We also show that the ICSBP DNA binding domain is indispensable for the formation of DNA binding heterocomplexes and transcriptional activity. Therefore, our results shed light on the molecular mechanisms that affect IRF activities in the immune system via discrete functional domains.

In vivo formation of IRF-1 homodimers.

Interferon regulatory factor 1 (IRF-1) is a transcriptional activator which exerts different biological activities. IRF-1 activates interferon induced genes as well as genes which are not directly linked to the interferon system, such as the ICE protease gene. IRF-1 activity is post-transcriptionally regulated in addition to transcriptional regulation by interferons, cytokines, hormones and many other factors. This includes heterodimerisation with activators and repressors of transcription. These protein interactions modulate the transactivating capacity of IRF-1. By using a two-hybrid system, we demonstrate that IRF-1 forms homodimers in vivo. The homodimerization domain was determined to be located in the N-terminal part of IRF-1 which belongs to the DNA-binding domain. Since this sequence is highly conserved between members of the IRF-family, our observation raises the question of homodimerization of other IRFs through this domain.

Functional domains of interferon regulatory factor I (IRF-1).

Interferon (IFN) regulatory factors (IRFs) are a family of transcription factors among which are IRF-1, IRF-2, and IFN consensus sequence binding protein (ICSBP). These factors share sequence homology in the N-terminal DNA-binding domain. IRF-1 and IRF-2 are further related and have additional homologous sequences within their C-termini. Whereas IRF-2 and ICSBP are identified as transcriptional repressors, IRF-1 is an activator. In the present work, the identification of functional domains in murine IRF-1 with regard to DNA-binding, nuclear translocation, heterodimerization with ICSBP and transcriptional activation are demonstrated. The minimal DNA-binding domain requires the N-terminal 124 amino acids plus an arbitrary C-terminal extension. By using mutants of IRF-1 fusion proteins with green fluorescent protein and monitoring their distribution in living cells, a nuclear location signal (NLS) was identified and found to be sufficient for nuclear translocation. Heterodimerization was confirmed by a two-hybrid system adapted to mammalian cells. The heterodimerization domain in IRF-1 was defined by studies in vitro and was shown to be homologous with a sequence in IRF-2, suggesting that IRF-2 also heterodimerizes with ICSBP through this sequence. An acidic domain in IRF-1 was found to be required and to be sufficient for transactivation. Epitope mapping of IRF-1 showed that regions within the NLS, the heterodimerization domain and the transcriptional activation domain are exposed for possible contacts with interacting proteins.