Efficient CRM197-mediated drug targeting to monocytes.

Efficient delivery of drugs to specific cellular reservoirs is of particular importance for therapeutics that are not able to pass cellular barriers and that may have unwanted side effects in off-target tissues. Heparin-binding epidermal growth factor (HB-EGF) is expressed on leukocytes and may be targeted for specific drug delivery using cross-reacting material (CRM)197, a non-toxic variant of diphtheria toxin and exogenous substrate for HB-EGF. We used fluorescently labeled CRM197 and CRM197-coated liposomes to investigate their potential use for drug delivery to leukocytes. We demonstrate that CRM197-guided systems are efficiently taken up by human leukocytes in vitro. CRM197 was also found to specifically target leukocytes in vivo in mice with components of the human immune system (HIS mice) and hamsters. Monocytes represent the most prominent subset of leukocytes that showed highly specific CRM197-mediated uptake. We therefore propose the application of CRM197 as a novel targeting approach in diseases that require the selective treatment of monocytes.

A conditionally replicating HIV-based vector that stably expresses an antiviral shRNA against HIV-1 replication.

Human pathogenic viruses can be targeted by therapeutic strategies based on RNA interference. Whereas the administration of synthetic short interfering RNAs (siRNAs) may transiently inhibit viral replication, long-term inhibition may be achieved through stable intracellular expression of siRNAs or short hairpin RNAs (shRNAs). Both approaches face serious problems with delivery to the right cells in an infected individual. We explored the potential of a replicating HIV-based vector to deliver an antiviral shRNA cassette into HIV-1-susceptible target cells to block chronic HIV-1 infection. The vector is based on a doxycycline (dox)-dependent HIV-1 variant that we previously proposed as a conditional-live HIV-1 vaccine. With dox, this virus spreads efficiently to all HIV-susceptible cells. Subsequent dox withdrawal generates cells with a transcriptionally silent integrated provirus, but with an active shRNA expression cassette. Because the shRNA targets viral sequences that are removed from the vector construct, there is no self-targeting, yet there is specific shutdown of HIV-1 replication.

Suppression of RNA interference by adenovirus virus-associated RNA.

We show that human adenovirus inhibits RNA interference (RNAi) at late times of infection by suppressing the activity of two key enzyme systems involved, Dicer and RNA-induced silencing complex (RISC). To define the mechanisms by which adenovirus blocks RNAi, we used a panel of mutant adenoviruses defective in virus-associated (VA) RNA expression. The results show that the virus-associated RNAs, VA RNAI and VA RNAII, function as suppressors of RNAi by interfering with the activity of Dicer. The VA RNAs bind Dicer and function as competitive substrates squelching Dicer. Further, we show that VA RNAI and VA RNAII are processed by Dicer, both in vitro and during a lytic infection, and that the resulting short interfering RNAs (siRNAs) are incorporated into active RISC. Dicer cleaves the terminal stem of both VA RNAI and VA RNAII. However, whereas both strands of the VA RNAI-specific siRNA are incorporated into RISC, the 3' strand of the VA RNAII-specific siRNA is selectively incorporated during a lytic infection. In summary, our work shows that adenovirus suppresses RNAi during a lytic infection and gives insight into the mechanisms of RNAi suppression by VA RNA.

The HIV-1 leader RNA conformational switch regulates RNA dimerization but does not regulate mRNA translation.

The untranslated leader RNA is the most conserved part of the human immunodeficiency virus type I (HIV-1) genome. It contains many regulatory motifs that mediate a variety of steps in the viral life cycle. Previous work showed that the full-length leader RNA can adopt two alternative structures: a long distance interaction (LDI) and a branched multiple-hairpin (BMH) structure. The BMH structure exposes the dimer initiation site (DIS) hairpin, whereas this motif is occluded in the LDI structure. Consequently, these structures differ in their capacity to form RNA dimers in vitro. The BMH structure is dimerization-competent, due to DIS hairpin formation, but also presents the splice donor (SD) and RNA packaging (Psi) hairpins. In the LDI structure, an extended RNA packaging (Psi(E)) hairpin is folded, which includes the splice donor site and gag coding sequences. The gag initiation codon is engaged in a long distance base pairing interaction with sequences in the upstream U5 region in the BMH structure, thus forming the evolutionarily conserved U5-AUG duplex. Therefore, the LDI-BMH equilibrium may affect not only the process of RNA dimer formation but also translation initiation. In this study, we designed mutations in the 3'-terminal region of the leader RNA that alter the equilibrium of the LDI-BMH structures. The mutant leader RNAs are affected in RNA dimer formation, but not in their translation efficiency. These results indicate that the LDI-BMH status does not regulate HIV-1 RNA translation, despite the differential presentation of the gag initiation codon in both leader RNA structures.

Similarities and differences between the subgenomic and minus-strand promoters of an RNA plant virus.

Promoter regions required for minus-strand and subgenomic RNA synthesis have been mapped for several plus-strand RNA viruses. In general, the two types of promoters do not share structural features even though they are recognized by the same viral polymerase. The minus-strand promoter of Alfalfa mosaic virus (AMV), a plant virus of the family Bromoviridae, consists of a triloop hairpin (hpE) which is attached to a 3' tRNA-like structure (TLS). In contrast, the AMV subgenomic promoter consists of a single triloop hairpin that bears no sequence homology with hpE. Here we show that hpE, when detached from its TLS, can function as a subgenomic promoter in vitro and can replace the authentic subgenomic promoter in the live virus. Thus, the AMV subgenomic and minus-strand promoters are basically the same, but the minus-strand promoter is linked to a 3' TLS to force the polymerase to initiate at the very 3'end.

A plant virus replication system to assay the formation of RNA pseudotriloop motifs in RNA-protein interactions.

A pseudotriloop is formed by transloop base pairing between the first (5') and the fifth nucleotide in a hexanucleotide RNA loop ("hexaloop") to subtend a triloop of nucleotides 2-4. This structure has been found in hairpins involved in the regulation of iron metabolism in mammalian cells and in transcription of plant virus subgenomic RNA. Several hexaloop hairpins, including HIV-transactivation-responsive element and hepatitis B virus , potentially adopt a pseudotriloop conformation. Here we show that an RNA plant virus whose replication depends on a conventional triloop hairpin can be used to verify the existence of pseudotriloop structures in vivo. Our data suggest that the pseudotriloop may represent a common motif in RNA-protein recognition.

Inhibition of virus replication by RNA interference.

RNA interference (RNAi) is a sequence-specific gene-silencing mechanism in eukaryotes, which is believed to function as a defence against viruses and transposons. Since its discovery, RNAi has been developed into a widely used technique for generating genetic knock-outs and for studying gene function by reverse genetics. Additionally, inhibition of virus replication by means of induced RNAi has now been reported for numerous viruses, including several important human pathogens such as human immunodeficiency virus type 1, hepatitis C virus, hepatitis B virus, dengue virus, poliovirus and influenza virus A. In this review, we will summarize the current data on RNAi-mediated inhibition of virus replication and discuss the possibilities for the development of RNAi-based antiviral therapeutics.

The Brome mosaic virus subgenomic promoter hairpin is structurally similar to the iron-responsive element and functionally equivalent to the minus-strand core promoter stem-loop C.

In the Bromoviridae family of plant viruses, trinucleotide hairpin loops play an important role in RNA transcription. Recently, we reported that Brome mosaic virus (BMV) subgenomic (sg) transcription depended on the formation of an unusual triloop hairpin. By native gel electrophoresis, enzymatic structure probing, and NMR spectroscopy it is shown here that in the absence of viral replicase the hexanucleotide loop 5'C1AUAG5A3' of this RNA structure can adopt a pseudo trinucleotide loop conformation by transloop base pairing between C1 and G5. By means of in vitro replication assays using partially purified BMV RNA-dependent RNA polymerase (RdRp) it was found that other base pairs contribute to sg transcription, probably by stabilizing the formation of this pseudo triloop, which is proposed to be the primary element recognized by the viral replicase. The BMV pseudo triloop structure strongly resembles iron-responsive elements (IREs) in cellular messenger RNAs and may represent a general protein-binding motif. In addition, in vitro replication assays showed that the BMV sg hairpin is functionally equivalent to the minus-strand core promoter hairpin stem-loop C at the 3' end of BMV RNAs. Replacement of the sg hairpin by stem-loop C yielded increased sg promoter activity whereas replacement of stem-loop C by the sg hairpin resulted in reduced minus-strand promoter activity. We conclude that AUA triloops represent the common motif in the BMV sg and minus-strand promoters required for recruitment of the viral replicase. Additional sequence elements of the minus-strand promoter are proposed to direct the RdRp to the initiation site at the 3' end of the genomic RNA.

The influence of downstream protein-coding sequence on internal ribosome entry on hepatitis C virus and other flavivirus RNAs.

Some studies suggest that the hepatitis C virus (HCV) internal ribosome entry site (IRES) requires downstream 5' viral polyprotein-coding sequence for efficient initiation of translation, but the role of this RNA sequence in internal ribosome entry remains unresolved. We confirmed that the inclusion of viral sequence downstream of the AUG initiator codon increased IRES-dependent translation of a reporter RNA encoding secretory alkaline phosphatase, but found that efficient translation of chloramphenicol acetyl transferase (CAT) required no viral sequence downstream of the initiator codon. However, deletion of an adenosine-rich domain near the 5' end of the CAT sequence, or the insertion of a small stable hairpin structure (deltaG = -18 kcal/mol) between the HCV IRES and CAT sequences (hpCAT) substantially reduced IRES-mediated translation. Although translation could be restored to both mutants by the inclusion of 14 nt of the polyprotein-coding sequence downstream of the AUG codon, a mutational analysis of the inserted protein-coding sequence demonstrated no requirement for either a specific nucleotide or amino acid-coding sequence to restore efficient IRES-mediated translation to hpCAT. Similar results were obtained with the structurally and phylogenetically related IRES elements of classical swine fever virus and GB virus B. We conclude that there is no absolute requirement for viral protein-coding sequence with this class of IRES elements, but that there is a requirement for an absence of stable RNA structure immediately downstream of the AUG initiator codon. Stable RNA structure immediately downstream of the initiator codon inhibits internal initiation of translation but, in the case of hpCAT, did not reduce the capacity of the RNA to bind to purified 40S ribosome subunits. Thus, stable RNA structure within the 5' proximal protein-coding sequence does not alter the capacity of the IRES to form initial contacts with the 40S subunit, but appears instead to prevent the formation of subsequent interactions between the 40S subunit and viral RNA in the vicinity of the initiator codon that are essential for efficient internal ribosome entry.

A conserved hairpin structure in Alfamovirus and Bromovirus subgenomic promoters is required for efficient RNA synthesis in vitro.

The coat protein gene in RNA 3 of alfalfa mosaic virus (AMV; genus Alfamovirus, family Bromoviridae) is translated from the subgenomic RNA 4. Analysis of the subgenomic promoter (sgp) in minus-strand RNA 3 showed that a sequence of 37 nt upstream of the RNA 4 start site (nt +1) was sufficient for full sgp activity in an in vitro assay with the purified viral RNA-dependent RNA-polymerase (RdRp). The sequence of nt -6 to -29 could be folded into a potential hairpin structure with a loop represented by nt -16, -17, and -18, and a bulge involving nt -23. By introducing mutations that disrupted base pairing and compensatory mutations that restored base pairing, it was shown that base pairing in the top half of the putative stem (between the loop and bulge) was essential for sgp activity, whereas base pairing in the bottom half of the stem was less stringently required. Deletion of the bulged residue A-23 or mutation of this residue into a C strongly reduced sgp activity, but mutation of A-23 into U or G had little effect on sgp activity. Mutation of loop residues A-16 and A-17 affected sgp activity, whereas mutation of U-18 did not. Using RNA templates corresponding to the sgp of brome mosaic virus (BMV; genus Bromovirus, family Bromoviridae) and purified BMV RdRp, evidence was obtained indicating that also in BMV RNA a triloop hairpin structure is required for sgp activity.

The influence of AUG codons in the hepatitis C virus 5' nontranslated region on translation and mapping of the translation initiation window.

The initiation of translation of hepatitis C virus (HCV) is cap-independent and mediated by an internal ribosome entry site (IRES) that is located in the 5' nontranslated region (5' NTR) of the viral genome. This 5' NTR is relatively long and folds into a complex structure involving multiple hairpins and a pseudoknot. Within the sequence encompassing the IRES there are several AUG triplets. Some of these AUG codons are conserved between HCV genotypes and the related pestiviruses. In this study the 5 AUG codons (positions 13, 32, 85, 96, and 215) that are present in the 5' NTR of the HCV H-strain have been mutagenized to determine their influence on HCV cap-independent translation. The effect of these mutations on the expression of a chloramphenicol acetyl transferase (CAT) gene was tested in vaccinia virus. vTF7-3 infected Hep2 cells transfected with plasmids for the expression of a monocistronic HCV 5' NTR-CAT mRNA. Mutating the AUG codons at positions 13, 32, and 215 does not have a significant effect on CAT expression, inactivating the AUG codons at either position 85 or position 96 severely impaired IRES function. To determine whether ribosomes scan the RNA to select the initiation site, AUG codons were inserted up- and downstream of the authentic HCV polyprotein translation initiation codon (position 342). Analysis of these mutants has revealed that the ribosome is unable to use an AUG codon that is placed either 7 nucleotides upstream or 8 nucleotides downstream of the inactivated AUG at position 342. These results indicate that when scanning is involved in the recognition of the translation initiating AUG, it is limited to a narrow region between nucleotides 335 and 350.