Gene expression from both intronless and intron-containing Rous sarcoma virus clones is specifically inhibited by anti-sense RNA

Towards Gene-Inhibition Therapy: A Review of Progress and Prospects in the Field of Antiviral Antisense Nucleic Acids and Ribozymes

Antisense RNA and its derivatives may provide the basis for highly selective gene inhibition therapies of virus infections. In this review, I concentrate on advances made in the study of antisense RNA and ribozymes during the last five years and their implications for the development of such therapies. It appears that antisense RNAs synthesized at realistic levels within the cell can be much more effective inhibitors than originally supposed. Looking at those experiments that enable comparisons to be made, it seems that inhibitory antisense RNAs are not those that are complementary to particular sites within mRNAs but those that are able to make stable duplexes with their targets, perhaps by virtue of their secondary structure and length. The inclusion of ribozyme sequences within antisense RNAs confers RNA-cleaving activity upon them in vitro and possibly in cells, thereby offering the possibility of markedly increasing their therapeutic potential. The varieties of natural ribozyme and their adaptation as artificial catalysts are reviewed. The implications of these developments for antiviral therapy are discussed.

Context-specific microRNA function in developmental complexity

Since their discovery, microRNAs (miRNA) have been implicated in a vast array of biological processes in animals, from fundamental developmental functions including cellular proliferation and differentiation, to more complex and specialized roles such as long-term potentiation and synapse-specific modifications in neurons. This review recounts the history behind this paradigm shift, which has seen small non-coding RNA molecules coming to the forefront of molecular biology, and introduces their role in establishing developmental complexity in animals. The fundamental mechanisms of miRNA biogenesis and function are then considered, leading into a discussion of recent discoveries transforming our understanding of how these molecules regulate gene network behaviour throughout developmental and pathophysiological processes. The emerging complexity of this mechanism is also examined with respect to the influence of cellular context on miRNA function. This discussion highlights the absolute imperative for experimental designs to appreciate the significance of context-specific factors when determining what genes are regulated by a particular miRNA. Moreover, by establishing the timing, location, and mechanism of these regulatory events, we may ultimately understand the true biological function of a specific miRNA in a given cellular environment.

Characterization of loose and tight dimer forms of avian leukosis virus RNA

Retroviral genomes consist of two identical RNA molecules joined non-covalently near their 5'-ends. Recently, we showed that an imperfect autocomplementary sequence, located in the L3 domain, plays an essential role in avian sarcoma-leukosis virus (ASLV) RNA dimerization in vitro. This sequence can adopt a stem-loop structure and is involved in ASLV replication. Here, we found that in the absence of nucleocapsid protein, RNA transcripts of avian leukosis virus (ALV) were able to form two types of dimers in vitro that differ in their stability: a loose dimer, formed at a physiological temperature, and a tight dimer, formed at a high temperature. A mutational analysis was performed to define the features of these dimers. The results of this analysis unambiguously confirm that the two L3 stem-loops interact directly in both types of dimers. A loop-loop interaction is the main linkage in the loose dimer. In contrast, in the tight dimer, the stem and the loop of the L3 hairpin form an extended duplex. Surprisingly, we also found that the dimerization properties defined for our ALV strain (type SR-A) differ from those found in other ASLV strains.

Analysis of the systemic and intrathecal humoral immune response in progressive multifocal leukoencephalopathy

Progressive multifocal leukoencephalopathy (PML) is a subacute viral infection of oligodendrocytes by JC virus occurring almost exclusively in immunocompromised patients. By use of partially purified recombinant VP1 as antigen, the IgG response was analyzed by a quantitative ELISA of paired cerebrospinal fluid (CSF) and serum samples. An intrathecal immune response to VP1, defined as an antibody-specificity index of CSF to serum antibody titers > or =1.5, was found in 76% of PML patients (47/62) but in only 3.2% of controls (5/155) (P < .001). Intra-blood-brain barrier synthesis of VP1-specific IgG antibodies is 76% sensitive and 96.8% specific for the diagnosis of PML. Furthermore, the excellent correlation (r = .985) between the plasma cell count in brain tissue and the humoral intrathecal immune response to VP1 in PML patients suggests a role for B cells in this disorder.

Transcriptional inhibition of the parvovirus minute virus of mice by constitutive expression of an antisense RNA targeted against the NS-1 transactivator protein

We have assessed a genetic resistance approach based on antisense RNA to interfere with the prototype Minute Virus of Mice (MVMp), an autonomous parvovirus. MVMp is a cytolytic virus when infecting the permissive A9 mouse fibroblast cell line, and its gene expression is largely regulated at the level of transcription initiation by the nonstructural transactivator NS-1 protein, a multifunctional polypeptide also involved in viral DNA replication and cytotoxicity. An NS-1 specific antisense RNA constitutively expressed in transfected A9 clones increased several fold the proliferative viability of the cells upon high multiplicity virus infection, and cultures infected at low multiplicity reached confluence overcoming virus progression. All clones shared a common phenotype of resistance characterized by a lowered synthesis of viral DNA replicative intermediates and genomic forms, a significant reduction in the accumulation of the three viral messengers in the cytoplasmic and nuclear compartments, and a specific inhibition in viral protein synthesis. These results indicate that the constitutive antisense RNA mediates an overall repression of viral macromolecular synthesis by preventing the onset of NS-1 functions. Therefore, cytocidal parvoviruses may be hampered by engineered antisense RNA targeted against early regulators of virus growth.

Antisense RNA. History and perspective

Antisense RNA was first an in vitro curiosity that was found to shut off protein synthesis in cell-free extracts. It was later shown to function in prokaryotic cells as a natural modulator of the synthesis of some proteins. Artificial antisense constructs can inhibit protein synthesis in prokaryotic and eukaryotic cells. To inhibit synthesis of proteins effectively, high ratios of antisense to sense RNAs are required. Thus, the challenge is to develop strategies to locate suitable targets and provide for amplification of the antisense RNA. This report provides a summary of our original work on antisense RNA.

Mechanism of action of antisense RNA. Sometime inhibition of transcription, processing, transport, or translation

Anyone considering the use of AS RNA, generated endogenously, to inhibit gene expression should plan to generate several independent transfectants with nonoverlapping sequences; strategies that maximize both the transcription rate and the stability of the AS RNA are obviously desirable. Reasons why different results are obtained in different systems or with different constructs likely include the specific nucleotide sequence under investigation, the location of the AS gene in the nucleus relative to the endogenous gene, and the rate-limiting step in the expression of the target gene. Splicing may not be necessary, but an efficient polyadenylation signal likely is. Employment of a ribozyme-mediated strategy, discussed by various investigators in this volume, may be beneficial. There is no reason at present to conclude that any gene, however abundant its transcript might be, is inherently recalcitrant to AS-mediated down-regulation of expression.

Expression of antisense RNA fails to inhibit influenza virus replication

Cell lines were constructed which permanently express influenza virus-specific RNA. Two approaches were followed. C127 cells were transformed with bovine papilloma virus (BPV) vectors and the resulting cell lines were found to inhibit the replication of influenza virus at low multiplicity of infection (MOI 0.05). However, examination of cellular RNA using single-stranded probes revealed the presence of both (+)sense and antisense RNA transcripts (45-70 copies per cell). In this BPV-based system the inhibitory activity appeared to be associated with a non-specific, interferon (IFN)-mediated effect. In the second approach, an expression system was used which involved 293 cells, a chimeric human cytomegalovirus (CMV)/human immunodeficiency virus (HIV) promoter, and methotrexate- (Mtx)-mediated gene amplification. Cells were found to express up to 7500 copies of influenza virus-specific RNA per cell at a steady state level. In this system no RNA transcripts of the opposite orientation were found. However, all cell lines permanently expressing either (-)sense or (+)sense viral RNA failed to reduce influenza virus titers in a multi-cycle replication experiment (MOI 0.01).

Inhibition of human T-cell leukemia virus type I replication in primary human T cells that express antisense RNA

The human T-cell leukemia virus type I is associated with adult T-cell leukemia-lymphoma in humans, a disease which is induced by a malignant transformation of T lymphocytes. Retrovirus vectors carrying human T-cell leukemia virus type I-derived sequences in reversed transcriptional orientation were used to express antisense RNA transcripts in primary human leukocytes. Human T-cell leukemia virus type I replication and virus-mediated immortalization were inhibited in cells harboring antisense constructs. This study suggests that retrovirus-mediated antisense RNA inhibition can be used to protect primary human T-lymphocytes from human T-cell leukemia virus type I-mediated cell transformation.

Antisense RNA: effect of ribosome binding sites, target location, size, and concentration on the translation of specific mRNA molecules

A series of plasmids were constructed to generate RNA complementary to the beta-galactosidase messenger RNA under control of the phage lambda PL promoter. These plasmids generate anti-lacZ mRNA bearing or lacking a synthetic ribosome binding site adjacent to the lambda PL promoter and/or the lacZ ribosome binding site in reverse orientation. Fragments of lacZ DNA from the 5' and/or the 3' region were used in these constructions. When these anti-mRNA molecules were produced in Escherichia coli 294, maximal inhibition of beta-galactosidase synthesis occurred when a functional ribosome binding site was present near the 5' end of the anti-mRNA and the anti-mRNA synthesized was complementary to the 5' region of the mRNA corresponding to the lacZ ribosome binding site and/or the 5'-coding sequence. Anti-mRNAs producing maximal inhibition of beta-galactosidase synthesis exhibited an anti-lacZ mRNA:normal lacZ mRNA ratio of 100:1 or higher. Those showing lower levels of inhibition exhibited much lower anti-lacZ mRNA:normal lacZ mRNA ratios. A functional ribosome binding site at the 5'-end was found to decrease the decay rate of the anti-lacZ mRNAs. In addition, the incorporation of a transcription terminator just downstream of the antisense segment provided for more efficient inhibition of lacZ mRNA translation due to synthesis of smaller and more abundant anti-lacZ mRNAs. The optimal constructions produced undetectable levels of beta-galactosidase synthesis.

Antisense RNA: its functions and applications in gene regulation--a review

All known antisense RNAs existing in nature are described. Of 11 natural antisense RNAs, nine function at the level of transcription and two at the level of DNA replication. On the basis of their inhibitory mechanisms they can be separated into three classes. From what can be found in the naturally occurring antisense RNAs, strategies in designing artificial antisense RNAs for gene expression are proposed, and applications and potential problems discussed.

Inhibition of rabbit beta-globin synthesis by complementary oligonucleotides: identification of mRNA sites sensitive to inhibition

We tested the effects of a series of synthetic oligonucleotides (hybridons) complementary to the 5' noncoding and coding regions of rabbit beta-globin mRNA on endogenous protein synthesis in a rabbit reticulocyte cell-free translation system. With highly purified hybridons inhibition was completely specific for beta-globin. The sites most sensitive to inhibition are the beginning of the 5' noncoding region and a sequence including the initiation codon and several upstream bases. The region between these was relatively insensitive to inhibition. The sites of maximum sensitivity coincide with known protein binding sites, suggesting that hybridons exert their effects in part by blocking the binding of proteins required for translation. Their effectiveness seems related to the ease with which they are displaced by ribosomes.