Reinitiation after Translation of Two Upstream Open Reading Frames (ORF) Governs Expression of the ORF35-37 Kaposi's Sarcoma-Associated Herpesvirus Polycistronic mRNA

The Kaposi''s sarcoma-associated herpesvirus (KSHV) ORF36 protein kinase is translated as a downstream gene from the ORF35-37 polycistronic mRNA via a unique mechanism involving short upstream open reading frames (uORFs) located in the 5′ untranslated region. Here, we confirm that ORF35-37 is functionally dicistronic during infection and demonstrate that mutation of the dominant uORF restricts KSHV replication. Leaky scanning past the uORFs facilitates ORF35 expression, while a reinitiation mechanism after translation of the uORFs enables ORF36 expression.     

A Eukaryotic (Insect) Tricistronic mRNA Encodes Three Proteins Selected by Context-dependent Scanning

Eukaryotic mRNAs are generally considered monocistronic and encode only one protein. Although dicistronic mRNAs encoding two proteins were found in fungi, plants, and animals, polycistronic mRNAs encoding more than two proteins have remained elusive so far in any eukaryote. Here we demonstrate that a single mRNA from silkworm encodes the precursor of an insect cytokine paralytic peptide (PP) and two new cytokine precursor-like proteins, uENF1 and uENF2. RT-PCR analysis showed that this mRNA is widely conserved in moths. Western blot analyses and reporter assays using its modified mRNAs, created by replacing each one of the three ORFs with the firefly luciferase ORF, showed that all three proteins were translated from this mRNA in cell lines, larval tissues, and cell-free systems. Insertion experiments using the Renilla luciferase ORF or a stem loop ruled out the possible involvement of internal ribosome entry site in the three protein translation. On the other hand, systematic mutation analysis of the translation initiation sequence of the 5′-proximal uENF1 ORF suggested that the context-dependent leaky-scanning mechanism is involved in translation of the downstream uENF2 and PP ORFs. In vitro, a synthetic peptide corresponding to the putative mature form of uENF1 stimulated spreading of hemocytes as did the synthetic PP, whereas that of uENF2 antagonized the stimulating activities of PP and the uENF1 peptide, suggesting that the three proteins control cellular immunity interactively. Thus, eukaryotes have a cellular tricistronic mRNA that encodes three functionally related proteins as in an operon.     

A GFP-based reporter system to monitor nonsense-mediated mRNA decay

Aberrant mRNAs whose open reading frame (ORF) is truncated by the presence of a premature translation-termination codon (PTC) are recognized and degraded in eukaryotic cells by a process called nonsense-mediated mRNA decay (NMD). Here, we report the development of a reporter system that allows monitoring of NMD in mammalian cells by measuring the fluorescence of green fluorescent protein (GFP). The NMD reporter gene consists of a T-cell receptor-β minigene construct, in which the GFP-ORF was inserted such that the stop codon of GFP is recognized as PTC. The reporter mRNA is therefore subjected to NMD, resulting in a low steady-state mRNA level, an accordingly low protein level and hence a very low green fluorescence in normal, NMD-competent cells that express this reporter gene. We show that the inactivation of NMD by RNAi-mediated knockdown of the essential NMD factor hUpf1 or hSmg6 increases the NMD reporter mRNA level, resulting in a proportional increase of the green fluorescence that can be detected by flow cytometry, spectrofluorometry and fluorescence microscopy. With these properties, our GFP-based NMD reporter system could be used for large-scale screenings to identify NMD-inhibiting drugs or NMD-deficient mutant cells.     

FemA, a host-mediated factor essential for methicillin resistance in Staphylococcus aureus: Molecular cloning and characterization

Summary The methicillin resistance determinant (mec) in Staphylococcus aureus resides on additional DNA not present in isogenic sensitive cells. However, besides mec, other chromosomally determined factors are essential for expression of methicillin resistance. We cloned and characterized a chromosomally determined gene which encodes a factor essential for the expression of methicillin resistance (femA) in S. aureus. femA mapped in chromosomal segment number 18, genetically very distant from the methicillin resistance determinant (mec). The product of femA was a protein of an apparent size of 48 kDa. FemA restored methicillin resistance in S. aureus that had become sensitive to methicillin by insertion of 22003 (femA::Tn551). Although FemA was needed for cell growth in the presence of -lactam antibiotics, it had no influence on the synthesis of the low affinity, additional penicillin-binding protein (PBP2) encoded by mec and known to be essential for cell wall synthesis in the presence of inhibitory concentrations of methicillin. Nucleotide sequence analysis, Northern RNA blotting and S1 nuclease RNA mapping suggested that femA was transcribed on a polycistronic mRNA. This mRNA contained the coding region for FemA (ORF433) and a second coding region (ORF419) producing a protein of 47 kDa. The nucleotide and amino acid sequence of FemA showed homologies with ORF419, suggesting that these genes arose by gene duplication. In addition we present evidence for a second chromosomal factor, femB, involved in expression of methicillin resistance which maps close to femA.     

Improved vectors for stable expression of foreign genes in mammalian cells by use of the untranslated leader sequence from EMC virus.

Dicistronic mRNA expression vectors efficiently translate a 5' open reading frame (ORF) and contain a selectable marker within the 3' end which is inefficiently translated. In these vectors, the efficiency of translation of the selectable 3' ORF is reduced approximately 100-fold and is highly dependent on the particular sequences inserted into the 5' cloning site. Upon selection for expression of the selection marker gene product, deletions within the 5' ORF occur to yield more efficient translation of the selectable marker. We have generated improved dicistronic mRNA expression vectors by utilization of a putative internal ribosomal entry site isolated from encephalomyocarditis (EMC) virus. Insertion of the EMC virus leader sequence upstream of an ORF encoding either a wildtype or methotrexate resistant dihydrofolate reductase (DHFR) reduces DHFR translation up to 10-fold in a monocistronic DHFR expression vector. However, insertion of another ORF upstream of the EMC leader to produce a dicistronic mRNA does not further reduce DHFR translation. In the presence of the EMC virus leader, DHFR translation is not dependent on sequences inserted into the 5' end of the mRNA. We demonstrate that stable high level expression of inserted cDNAs may be rapidly achieved by selection for methotrexate resistance in DHFR deficient as well as DHFR containing cells. In contrast to previously described dicistronic expression vectors, these new vectors do not undergo rearrangement or deletion upon selection for amplification by propagation in increasing concentrations of methotrexate. The explanation may be either that the EMC virus leader sequence allows internal initiation of translation or that cryptic splice sites in the EMC virus sequence mediate production of monocistronic mRNAs. These vectors may be generally useful to rapidly obtain high level expression of cDNA genes in mammalian cells.     

Dicistronic Gene Expression in Developing Zebrafish

Internal ribosome entry sites (IRESs) allow ribosomal access to messenger RNA without a requirement for cap recognition and subsequent scanning to an initiator AUG. Hence, IRESs have been adapted into dicistronic vectors for the expression of more than one gene from a single mRNA. Dicistronic vectors have been used for many applications in mammalian tissue culture and transgenesis. However, whether the IRESs from mammalian viruses function without temporal or spatial restrictions in nonmammalian organisms like zebra fish (Danio rerio) is unknown. Therefore, we have examined the expression capabilities of the encephalomyocarditis virus (EMCV) IRES during zebrafish embryogenesis. We determined that the EMCV IRES was sufficient to permit detectable expression of several second cistron reporters during zebrafish embryogenesis, including luciferase and green fluorescent protein. This suggests that our dicistronic vectors are suitable for general use in any vertebrate system, from fish to humans. Received March 26, 1999; accepted June 14, 1999.     

Picornavirus internal ribosome entry site elements can stimulate translation of upstream genes

Certain viral and cellular mRNAs initiate translation cap-independently at internal ribosome entry site (IRES) elements. Picornavirus IRES elements are widely used in dicistronic or multicistronic vectors in gene therapy, virus replicon systems, and analysis of IRES function. In such vectors, expression of the upstream gene often serves as internal control to standardize the readings of IRES-driven downstream reporter activity. Picornaviral IRES elements translate optimally at up to 120 mM K(+) concentration, whereas genes used as upstream reporters usually have lower salt optima when present in monocistronic mRNAs. However, here we show that such reporter genes are efficiently translated at higher K(+) concentrations when placed upstream of a functional picornavirus IRES. This translation enhancement occurs in cis, is independent of the nature of the first reporter and of second reporter translation, and is conferred by the IRESs of picornaviruses but not of hepatitis C virus. A defective picornavirus IRES with a deletion killing IRES activity but leaving the binding site for initiation factor eIF4G intact retains translation enhancement activity. Translation enhancement on a capped mRNA is disabled by m(7)GDP. In addition, the C-terminal fragment of eIF4G can confer translation enhancement also on uncapped mRNA. We conclude that whenever eIF4F has been captured to a dicistronic mRNA by binding to a picornavirus IRES via its eIF4G moiety, it can be provided in cis to the 5'-end of the RNA and there stimulate translation initiation, either by binding to the cap nucleotide using its eIF4E moiety or by binding to the RNA cap-independently using its eIF4G moiety.