Time-dependent increase in ribosome processivity

We created a novel tripartite reporter RNA to separately and simultaneously examine ribosome translation rates at the 5′- and 3′-ends of a large open reading frame (ORF) in vitro in HeLa cell lysates. The construct contained Renilla luciferase (RLuc), β-galactosidase and firefly luciferase (FLuc) ORFs linked in frame and separated by a viral peptide sequence that causes cotranslational scission of emerging peptide chains. The length of the ORF contributed to low ribosome processivity, a low number of initiating ribosomes completing translation of the entire ORF. We observed a time-dependent increase in FLuc production rate that was dependent on a poly(A) tail and poly(A)-binding protein, but was independent of eIF4F function. Stimulation of FLuc production occurred earlier on shorter RNA templates. Cleavage of eIF4G at times after ribosome loading on templates occurred did not cause immediate cessation of 5′-RLuc translation; rather, a delay was observed that shortened when shorter templates were translated. Electron microscopic analysis of polysome structures in translation lysates revealed a time-dependent increase in ribosome packing and contact that correlated with increased processivity on the FLuc ORF. The results suggest that ORF transit combined with PABP function contribute to interactions between ribosomes that increase or sustain processivity on long ORFs

Gemin5 proteolysis reveals a novel motif to identify L protease targets

Translation of picornavirus RNA is governed by the internal ribosome entry site (IRES) element, directing the synthesis of a single polyprotein. Processing of the polyprotein is performed by viral proteases that also recognize as substrates host factors. Among these substrates are translation initiation factors and RNA-binding proteins whose cleavage is responsible for inactivation of cellular gene expression. Foot-and-mouth disease virus (FMDV) encodes two proteases, Lpro and 3Cpro. Widespread definition of Lpro targets suffers from the lack of a sufficient number of characterized substrates. Here, we report the proteolysis of the IRES-binding protein Gemin5 in FMDV-infected cells, but not in cells infected by other picornaviruses. Proteolysis was specifically associated with expression of Lpro, yielding two stable products, p85 and p57. In silico search of putative L targets within Gemin5 identified two sequences whose potential recognition was in agreement with proteolysis products observed in infected cells. Mutational analysis revealed a novel Lpro target sequence that included the RKAR motif. Confirming this result, the Fas-ligand Daxx, was proteolysed in FMDV-infected and Lpro-expressing cells. This protein carries a RRLR motif whose substitution to EELR abrogated Lpro recognition. Thus, the sequence (R)(R/K)(L/A)(R) defines a novel motif to identify putative targets of Lpro in host factors

Dual Mechanism for the Translation of Subgenomic mRNA from Sindbis Virus in Infected and Uninfected Cells

Infection of BHK cells by Sindbis virus (SV) gives rise to a profound inhibition of cellular protein synthesis, whereas translation of viral subgenomic mRNA that encodes viral structural proteins, continues for hours. To gain further knowledge on the mechanism by which this subgenomic mRNA is translated, the requirements for some initiation factors (eIFs) and for the presence of the initiator AUG were examined both in infected and in uninfected cells. To this end, BHK cells were transfected with different SV replicons or with in vitro made SV subgenomic mRNAs after inactivation of some eIFs. Specifically, eIF4G was cleaved by expression of the poliovirus 2A protease (2Apro) and the alpha subunit of eIF2 was inactivated by phosphorylation induced by arsenite treatment. Moreover, cellular location of these and other translation components was analyzed in BHK infected cells by confocal microscopy. Cleavage of eIF4G by poliovirus 2Apro does not hamper translation of subgenomic mRNA in SV infected cells, but bisection of this factor blocks subgenomic mRNA translation in uninfected cells or in cell-free systems. SV infection induces phosphorylation of eIF2α, a process that is increased by arsenite treatment. Under these conditions, translation of subgenomic mRNA occurs to almost the same extent as controls in the infected cells but is drastically inhibited in uninfected cells. Notably, the correct initiation site on the subgenomic mRNA is still partially recognized when the initiation codon AUG is modified to other codons only in infected cells. Finally, immunolocalization of different eIFs reveals that eIF2 α and eIF4G are excluded from the foci, where viral RNA replication occurs, while eIF3, eEF2 and ribosomes concentrate in these regions. These findings support the notion that canonical initiation takes place when the subgenomic mRNA is translated out of the infection context, while initiation can occur without some eIFs and even at non-AUG codons in infected cells

Rh(II)-Catalyzed Reactions of Differentially Substituted <i>Bis</i>(diazo) Functionalities

The chemoselective reaction of donor/acceptor (D/A) and acceptor/acceptor (A/A) diazo moieties in the same molecule was examined using 3-diazo-1-(ethyl 2-diazomalonyl)indolin-2-one under rhodium(II) catalysis. The D/A diazo group undergoes selective cyclopropanation as well as XH-insertion, leaving behind the second diazo group for a further intramolecular dipolar cycloaddition reaction

Rh(II)-Catalyzed Reactions of Differentially Substituted <i>Bis</i>(diazo) Functionalities

The chemoselective reaction of donor/acceptor (D/A) and acceptor/acceptor (A/A) diazo moieties in the same molecule was examined using 3-diazo-1-(ethyl 2-diazomalonyl)indolin-2-one under rhodium(II) catalysis. The D/A diazo group undergoes selective cyclopropanation as well as XH-insertion, leaving behind the second diazo group for a further intramolecular dipolar cycloaddition reaction