Recent progress in the analyses of the mouse transcriptome leads to unexpected discoveries. The mouse genomic sequences read by RNA polymerase II may be six times more than previously expected for human chromosomes. The transcript-abundant regions (named "transcription forests") occupy more than half of the genomic sequence and are divided by transcript-scarce regions (transcription deserts). Many of the coding mRNAs may have partially overlapping antisense RNAs. There are transcripts bridging several adjacent genes that were previously regarded as distinct ones. The transcription start sites appearing as cap analysis of gene expression (CAGE) tags are mapped on the mouse genomic sequences. Distributions of CAGE tags show that the shapes of mammalian gene promoters can be classified into four major categories. These shapes were conserved between mouse and human. Most of the gene has exonic transcription start sites, especially in the 3' untranslated region (3' UTR) sequences. The term "RNA continent" has been invented to express this unexpectedly complex and prodigious mouse transcriptome. More than a half of the RNA polymerase II transcripts are regarded as noncoding RNAs (ncRNAs). The great variety of ncRNAs in mammalian transcriptome implies that there are many functional ncRNAs in the cells. Especially, the evolutionarily conserved microRNAs play critical roles in mammalian development and other biological functions. Moreover, many other ncRNAs have also been shown to have biological significant functions, mainly in the regulation of gene expression. The functional survey of the RNA continent has just started. We will describe the state of the art of the RNA continent and its impact on the modern molecular biology, especially on the cancer research.

To construct a novel HBV antisense RNA delivery system targeting hapatocellular carcinoma and study its inhibitory effect in vitro and in vivo.

GE7,a 16-peptide specific to EGFR, and HA20,a homologue of N-terminus of haemagglutinin of influenza viral envelope protein, were synthesized and conjugated with polylysin. The above conjugates were organized into the pEBAF-as-preS2, a hepatocarcinoma specific HBV antisense expression vector, to construct a novel HBV antisense RNA delivery system, named AFP-enhancing 4-element complex. Hepatocelluar carcinoma HepG2.2.15 cells was used to assay the in vitro inhibition of the complex on HBV. Expression of HBV antigen was assayed by ELISA. BALB/c nude mice bearing HepG2.2.15 cells were injected with AFP-enhancing 4-element complex. The expression of HBV antisense RNA was examined by RT-PCR and the size of tumor in nude mice were measured.

The AFP-enhancing 4-element complex was constructed and DNA was completely trapped at the slot with no DNA migration when the ratio of polypeptide to plasmid was 1:1. The expression of HBsAg and HBeAg of HepG2.2.15 cells was greatly decreased after being transfected by AFP-enhancing 4-element complex. The inhibitory rates were 33.4 % and 58.5 % respectively. RT-PCR showed HBV antisense RNA expressed specifically in liver tumor cells of tumor-bearing nude mice. After 4 injections of AFP-enhancing 4-element complex containing 0.2 micro g DNA, the diameter of the tumor was 0.995 cm+/-0.35, which was significantly smaller than that of the control groups(2.215 cm+/-0.25, P<0.05).

AFP-enhancing 4-element complex could deliver HBV antisense RNA targeting on hepatocarcinoma and inhibit both HBV and liver tumor cells in vitro and in vivo.

A previously described Moloney-based vector expressing a double copy anti-tat antisense tRNA (DC-tRNA-AT) (Biasolo et al., 1996. J. Virol. 70, 2154-2161) was modified to increase the copy number of the antisense molecule and to target the intra-cytoplasmic localization of the HIV genome. To this end, an anti-U5 hammerhead ribozyme, engineered as a hybrid small adenoviral VAI RNA (VAIalpha), was inserted into the vector as a single molecule or in combination with the double copy anti-tat sequence. The retroviral vector expressing only VAIalpha (DC-VAIalpha) inhibited HIV-1 replication to an extent comparable to that of DC-tRNA-AT. A more effective inhibition was produced by the vector expressing multiple copies of the anti-tat antisense (DC-6tRNA-AT). This higher effectiveness correlated with anti-tat stochiometry, i.e. with the absolute number of therapeutic molecules being produced on a per cell basis at the steady state. Surprisingly, when the tRNA-AT and VAIalpha genes were combined in the same vector (DC-AT-VAIalpha), an enhancement of viral replication was noticed. This study indicates that it is possible to potentiate the antiviral activity of a retroviral vector by increasing the steady-state level of the therapeutic molecule. Results also show that the combined expression of two singularly active therapeutic RNAs can have antagonistic rather than synergistic effects.

Prostate cancer (CaP) is the most commonly diagnosed cancer of aging men and the second leading cause of male cancer death in the United States. At present, no effective therapy is available for treating hormone independent CaP. Since Bcl2 is believed to play a role in protecting CaP cells from apoptosis, we investigated the effects of down-regulating Bcl2 expression on CaP cells. Genetically engineered LNCaP sublines were established by stably transfecting LNCaP cells with BCL2 antisense (BCL2-AS) transcript-expressing plasmids. Western blotting analysis showed that intracellular Bcl2 protein was decreased by 50-60% in BCL2-AS-transfected LNCaP cells. Expression of the antisense transcripts resulted in 50% growth inhibition of LNCaP cells in response to androgen withdrawal and markedly sensitized these cells to Adriamycin-induced apoptosis. These results suggest that down-regulation of Bcl2 protein using BCL2-AS transcripts could be exploited for improved treatment of advanced CaP.

Although the full sequence of the human immunodeficiency virus type 1 (HIV-1) genome has been known for more than a decade, effective genetic antivirals have yet to be developed. Here we show that, of 22 regions examined, one highly conserved sequence (ACTCTTTGGCAACGA) near the 3' end of the HIV-1 gag-pol transframe region, encoding viral protease residues 4 to 8 and a C-terminal Vpr-binding motif of p6(Gag) protein in two different reading frames, can be successfully targeted by an antisense peptide nucleic acid oligomer named PNA(PR2). A disrupted translation of gag-pol mRNA induced at the PNA(PR2)-annealing site resulted in a decreased synthesis of Pr160(Gag-Pol) polyprotein, hence the viral protease, a predominant expression of Pr55(Gag) devoid of a fully functional p6(Gag) protein, and the excessive intracellular cleavage of Gag precursor proteins, hindering the processes of virion assembly. Treatment with PNA(PR2) abolished virion production by up to 99% in chronically HIV-1-infected H9 cells and in peripheral blood mononuclear cells infected with clinical HIV-1 isolates with the multidrug-resistant phenotype. This particular segment of the gag-pol transframe gene appears to offer a distinctive advantage over other regions in invading viral structural genes and restraining HIV-1 replication in infected cells and may potentially be exploited as a novel antiviral genetic target.

Ribozymes are catalytic RNAs that offer several advantages as specific therapeutic genes against human immunodeficiency virus type 1 (HIV-1). Significant challenges in antiviral uses of ribozymes include (1) how best to express and to deliver this agent and (2) what is the best locale to target ribozymes against HIV-1 RNA. To explore the former, we have previously characterized several vector systems for efficient expression/delivery of anti-HIV-1 ribozymes (Dropulic et al., 1992; Dropulic and Jeang, 1994a; Smith et al., 1997). Here, to investigate an optimal locale for ribozyme-targeting, we asked whether it might be advantageous to direct ribozymes into HIV-1 virions as opposed to the more conventional approach of targeting ribozymes into infected cells. Two series of experiments were performed. First, we demonstrated that anti-HIV-1 ribozymes could indeed be packaged specifically and efficiently into virions. Second, we compared the virus suppressing activity of a packageable ribozyme with its counterpart, which cannot be packaged into HIV-1 virions. Our results showed that although both ribozymes cleaved HIV-1 genomic RNA in vitro with equivalent efficiencies, the former ribozyme demonstrated significantly higher virus-suppressing activity than the latter. These findings provide proof-of-principle that to combat productive HIV-1 replication, intravirion targeting is more effective than intracellular targeting of ribozymes.

We describe effects of sense RNA molecules on hepatitis B virus (HBV) replication and antigen synthesis in transiently transfected cells. When certain subgenomic fragments of HBV were expressed as sense RNA together with a replication-competent genome of HBV, they inhibited HBV replication by up to 75% and HBsAg secretion by up to 60%. The corresponding antisense sequences had a 50% inhibitory effect in one case and no effect in another case. The sense RNA species did not inhibit duck hepatitis B virus (DHBV) replication, suggesting specific inhibitory effects. HBV transcript levels were unaltered in the presence of sense RNA species, consistent with an inhibitory effect mediated at the posttranscriptional level. The inhibition of HBV replication by overexpression of sense RNA derived from the viral genome represents an example of sense cosuppression of an animal virus.

Traditionally, methods designed to impair translation through direct interactions with target messenger RNA (mRNA) have been designated as "antisense" strategies because of their reliance on the formation of reverse complementary (antisense) Watson-Crick base pairs between the targeting oligodeoxynucleotide (ODN) and the mRNA whose function is to be disrupted. Proof of putative "antisense effects," and other mechanistic studies, would be greatly facilitated by the ability to directly demonstrate hybridization between an antisense (AS) ODN and its mRNA target in vivo. In addition, evidence of AS activity by demonstrating reduced levels of RNA or protein or by showing cleaved target molecules would lend proof of the concept. In this article we discuss how AS ODN may be used to down-regulate target gene expression with an emphasis on those targets chosen for our investigations, and we summarize the methods employed for this type of study.

Alphavirus vectors use RNA replication in the cell cytoplasm to direct gene expression. New developments of vectors put persistency of expression and infection of specific cells in focus. Furthermore, a new application shows that the system can be used for production of retrovirus vectors carrying genes with introns and control/regulatory regions.

Chronic infection with the hepatitis B virus (HBV) is a major public health problem, and currently available therapies have limited efficacy. Gene therapy strategies for HBV infection are under active investigation. We evaluated the potential of antisense RNA transcribed from antisense genes to interfere with HBV replication.

Subgenomic fragments of the HBV genome were studied with respect to the property of inhibiting HBV replication when intracellularly expressed in the antisense orientation.

Antisense RNAs derived from the HBV genome specifically inhibited HBV replication and antigen expression in human hepatocellular carcinoma cells by 60%-75%. DNA sequences corresponding to the identified RNAs had no effect on HBV replication, indicating that inhibitory effects are mediated by RNA. Transcripts corresponding to the inhibitory subgenomic fragments were present at high levels. One antisense RNA was found to reduce the amount of pregenomic RNA encapsidated into core particles as a molecular mechanism of antiviral effects.

Certain antisense RNA molecules will have substantial antiviral effects against HBV. Antisense RNAs derived from the HBV genome are promising candidates as antiviral agents and may serve as novel tools to identify functionally important regions of HBV transcripts.

In the first part of this chapter, general concepts for gene inactivation, antisense techniques and catalytic RNAs (ribozymes) are presented. The requirements for modified oligonucleotides are discussed with their effects on the stability of base-paired hybrids and on resistance against nuclease attack. This also includes the problems in the choice of an optimal target sequence within the inactivated RNA and the options of cellular delivery systems. The second part describes the recently introduced antisense concept based on the ubiquitous cellular enzyme ribonuclease P. This system is unique, since the substrate recognition requires the proper tertiary structure of the cleaved RNA. General properties and possible advantages of this approach are discussed.

The antiviral activities of intracellularly expressed antisense RNAs complementary to the human immunodeficiency virus type 1 (HIV-1) pol, vif, and env genes and the 3' long terminal repeat (LTR) sequence were evaluated in this comparative study. Retroviral vectors expressing the antisense RNAs as part of the Moloney murine leukemia virus LTR promoter-directed retroviral transcript were constructed. The CD4+ T-cell line CEM-SS was transduced with retroviral constructs, and Northern blot analyses showed high steady-state antisense RNA expression levels. The most efficient inhibition of HIV-1 replication was observed with the env antisense RNA, followed by the pol complementary sequence, leading to 2- to 3-log10 reductions in p24 antigen production even at high inoculation doses (4 x 10(4) 50% tissue culture infective doses) of the HIV-1 strain HXB3. The strong antiviral effect correlated with a reduction of HIV-1 steady-state RNA levels, and with intracellular Tat protein production, suggesting that antisense transcripts act at an early step of HIV-1 replication. A lower steady-state antisense RNA level was detected in transduced primary CD4+ lymphocytes than in CEM-SS cells. Nevertheless, replication of the HIV-1 JR-CSF isolate was reduced with both the pol and env antisense RNA. Intracellularly expressed antisense sequences demonstrated more pronounced antiviral efficacy than the transdominant RevM10 protein, making these antisense RNAs a promising gene therapy strategy for HIV-1.

Transgenic mouse lines were engineered to express stably antisense mRNA or antisense mRNA containing catalytic ribozyme (rbz) structures complementary to bacterial chloramphenicol acetyltransferase (CAT) gene transcripts. One transgenic line expressed antisense mRNA that specifically targeted full-length CAT coding sequences (ACAT). Another transgenic line expressed full-length antisense CAT mRNA which was modified by mutagensis to include four rbz cassettes (rbz-ACAT) in order to compare antisense versus antisense-rbz function in vivo. Preliminary data were also collected from a transgenic mouse line expressing antisense mRNA targeting 72% of the 5' region of CAT coding sequences (5' ACAT). All constructs contained similar control elements in their design. Promoter elements were derived from the bovine alpha s1-casein gene, while the small t intron and 3' control sequences were derived from SV40. The ability of these various constructs to down-regulate CAT protein levels was compared by analysis of CAT protein production in lactating double-hemizygous transgenic female mice. Every double-hemizygous mouse analysed expressed mRNA from the alpha s1-casein-CAT construct (Clarke et al., 1994) and equivalent levels of mRNA from one of the three antisense constructs. Transgenic mouse lines expressing both ACAT and CAT mRNA down-regulated CAT protein levels by 90% of that found in the CAT only transgenic population. Similarly, double-hemizygous transgenic lines expressing both rbz-ACAT and CAT mRNA regulated CAT protein levels by 87%. Preliminary data suggests that expression of mRNA from 5' ACAT/CAT double-hemizygote mice allowed approximately 67% down-regulation of normal CAT protein levels. We conclude that incorporation of multiple ribozymes within the full-length antisense CAT construct does not enhance the effectiveness of antisense mRNA in the down-regulation of CAT protein production in our system.

Intracellular applications of ribozymes have been limited partly by the availability of suitable high-expression systems. For RNA effectors, consideration of an RNA virus vector system for delivery and expression is reasonable. We show that alphavirus replicons can be highly efficient nonintegrating ribozyme-expressing vectors. Using a hammerhead ribozyme targeted to a highly conserved sequence in the U5 region of the human immunodeficiency virus type 1 (HIV-1) long terminal repeat, we demonstrate that a full-length 8.3-kb Semliki Forest virus ribozyme (SFVRz) chimeric RNA maintains catalytic activity. SFVRz is packaged into viral particles, and these particles transduce mammalian cells efficiently. SFVRz-transduced BHK cells were found to produce large amounts of genomic and subgenomic forms of ribozyme-containing RNAs that are functional in cleaving a U5-tagged mRNA. The RNase protection assay shows that HIV-1 U5-chloramphenicol acetyltransferase mRNA expressed intracellularly from an RNA polymerase II promoter is quantitatively eliminated in SFVRz-transduced BHK cells.

Escherichia coli-based artificial chromosomes have become important tools for physical mapping and sequencing in various genome projects. The lack of a general method to modify these large bacterial clones, however, has limited their utility in functional studies. We developed a simple method to modify bacterial artificial chromosomes directly in the recombination-deficient E. coli host strain by homologous recombination for in vivo studies. The IRES-LacZ marker gene was introduced into a 131 kb BAC containing the murine zinc finger gene, RU49. No rearrangements or deletions were detected in the modified BACs. Furthermore, transgenic mice were generated by pronuclear injection of the modified BAC, and germline transmission of the intact BAC has been obtained. Proper expression of the lacZ transgene in the brain has been observed, which could not be obtained with conventional transgenic constructs.

The survival, proliferation and differentiation of neuroblastoma (NB) cells are largely dependent on adhesion to extracellular matrix (ECM) proteins. Integrin occupancy seems to play a primary role. To elucidate the role of integrin heterodimers during neuronal cell death, we have analysed the changes in integrin expression in 2 human NB cell lines which represent different stages of neuronal maturation. Retinoic acid (RA) had different effects on the 2 NB cell lines: on LAN-5 cells it acted as a differentiation-promoting agent, while it had an anti-proliferative effect on GI-LI-N cells, driving them to apoptosis. Indeed, this occurrence was evidenced by the visualization of a "DNA ladder" on gel electrophoresis, by propidium iodide staining, and by DNA flow cytofluorimetric analysis. RA treatment rapidly and drastically decreased integrin expression and cell adhesion on GI-LI-N cells. These findings were also obtained by treating both NB cell lines with the apoptotic agent fenretinide. Furthermore, treatment of NB cells with anti-sense oligonucleotides to beta 1 integrin chain specifically induced chromatin condensation and nucleosomal DNA laddering. Moreover, blocking cell-matrix interactions by means of perturbing antibody against beta 1 subunit resulted in the induction of typical features of apoptotic cells. In conclusion, these findings indicate that abrogation of cell adhesion through down-modulation of integrin receptors plays a crucial role in the induction of neuroblastoma programmed cell death.

To evaluate the real effectiveness of various chemical modifications in enhancing the ability of antisense molecules to inhibit gene expression, the toxicity, stability, uptake, and intracellular localization of an identical sequence, synthetized either with a phosphodiester or a phosphorothioate backbone, with or without a cholesteryl moiety linked to the 3'-end, were compared in three different human neuroblastoma cell lines. The toxicity, assessed by inhibition of cell viability, greatly depend on the presence of the lipid moiety and to a less extent on the cell line used. At high doses all the antisenses caused a necrotic lysis of plasma membranes. Typical features of apoptotic cell death were never observed. The presence of the lipid moiety enhanced the uptake of antisense molecules while the phosphorothioate backbone, as expected, conferred higher stability. At late times, therefore, the combination of lipid conjugation and phosphorothioate backbone seems to be the most effective in obtaining a consistent antisense accumulation inside the cells. The presence of the cholesteryl moiety also caused a stronger association of the antisense to membraneous compartments, so that a quite different biodistribution occurred among the four antisenses tested. However, the actual amount of antisense molecules found inside NB cells was low in all the conditions tested. Only following cellular permeabilization a significant uptake was obtained, making the use of delivery system mandatory to achieve an efficient inhibition of highly expressed genes.

rTS is a recently discovered gene, phylogenetically conserved and found to be expressed in a wide variety of cell lines. rTS has also been found to be overexpressed in two cell lines resistant to FU and to MTX. The MTX-resistant cell line was found to have a high degree of cross resistance to several TS inhibitors. An apparent paradox to this correlation of rTS overexpression and resistance to TS inhibitors is the observation that expression of transfected rTS alpha results in enhanced sensitivity of cells to the TS inhibitor prodrug TFT and a modest increase in resistance to FUdR. Since immunoprecipitation of TS leads to the co-immunoprecipitation of two proteins within the expected molecular weight range of the two rTS proteins, it may be that both proteins bind to TS in vivo and modify its activity. Preliminary data substantiate this conclusion. It is conceivable that the ratio of the two rTS proteins associated with TS in vivo may differentially alter TS activity depending upon their stoichiometry or possibly posttranslational modification. Thus it may be possible for rTS to confer greater sensitivity to one pyrimidine analog (e.g., TFT) which is a product analog but to increase resistance or have a minor effect on a substrate analog (e.g., FdUMP) by stabilizing different conformations of TS. The structure of the rTS proteins suggests they are expected to have catalytic activity which involves proton abstraction from an alpha-carbon of a carboxyl group. Whether this enzyme activity is functional and related to pyrimidine metabolism awaits further study.

Lysogenic Acetobacter methanolicus strains carrying the prophage Acm1 were found to be unable to synthesize both the capsular polysaccharide (CPS) and the O-specific side-chain of lipopolysaccharide (LPS) and to represent rough variants of the host bacterium. A 262 bp DNA fragment of phage Acm1, obviously required for interference with LPS biosynthesis, was cloned and expressed in Escherichia coli. Independently of the O-type, transformation of various E. coli strains with the recombinant DNA resulted in a suppression of biosynthesis of the O-specific chains. The DNA fragment of phage Acm1 contained three very short open reading frames of 21, 24, and 36 bp. However, attempts to express phage-encoded peptides were not successful. Instead, the Acm1-derived DNA fragment was shown to code for the synthesis of a trans-acting RNA molecule of 97 nucleotides, designated lbi (LPS biosynthesis-interfering) RNA. This RNA contains sequence complementarity to E. coli target RNA sequences and appears to have the ability to form intracellularly RNA hybrid duplexes with mRNA. The data presented in this study support the hypothesis that the phenotypic effect of conversion to rough-type LPS is accompanied by the expression of an antisense RNA of phage Acm1.

Inactivation of gene expression by antisense mechanisms in general and by ribozymes in particular is a powerful technique for studying the function of a gene product. We have designed a strategy for expression of ribozymes, for selection of accessible cleavage sites in target RNAs, and for isolation of ribozymes from a library of random sequences flanking the unique sequence of a hammerhead. The expression cassette for ribozyme genes is based on adenovirus-associated RNA. Alternatively, we used polymerase III or the T7 phage transcription machinery. The ribozyme sequences are positioned in the center of a stable stem-loop structure, allowing for a correctly folded ribozyme region within the expressed RNA. A library of ribozyme genes with random sequences of 13 nucleotides on both sides of the hammerhead was generated. As an example, ribozymes which are specific for seven sites within the mRNA or nuclear RNA of human growth hormone were selected and identified. Sequencing of ribozyme genes reamplified from the library confirmed not only the predicted cleavage sites but also the presence of different ribozyme variants in the library. In a test of the ribozyme variants for repression of growth hormone synthesis in a cellular assay, the strongest effect (more than 99% inhibition) was found for the variant with the shortest stretch of complementarity (7 and 8 nucleotides on either side) to the target RNA. This basic strategy seems to be applicable to the selection of suitable target sites and to the isolation of corresponding ribozymes for any mRNA of interest.

At the Third International Conference on AIDS, Taipei, Taiwan, gene therapy, HIV quasi species, and Asian epidemiology were the main issues. Various effectors for gene therapy such as ribozyme, thymidine kinase and PKR were tested. Though not clinically available in the near future, gene therapy will likely play an important role in the combat against HIV. That non-syncytia-inducing HIV-1s are capable of direct T lymphocyte killing was reported and provides a possible explanation for progression to AIDS in patients in whom no syncytia-inducing HIV-1 could be found. Epidemiological data concerning Asia were presented in this meeting; among them is a detailed description of the current status of HIV infections in Taiwan. The HIV epidemic is still in its early stage in Taiwan, but some ominous signs favoring disease spread have been found. Copyright 1995 S. Karger AG, Basel

We compared the levels of growth hormone (GH) mRNA in the pituitary, plasma GH concentration, and altered phenotype in rats heterozygous and homozygous for an antisense RNA transgene targeted to the rat GH gene, with those in nontransgenic rats. We initially investigated whether the transgene promoter, which is connected to four copies of a thyroid hormone response element (TRE) that increases promoter activity, affected in vivo transgene expression in the pituitary of the transgenic rats. Plasma GH concentration correlated negatively with T3 injection in surgically thyroidectomized heterozygous transgenic rats. There was a reduction of about approximately 35-40% in GH mRNA levels in the pituitary of homozygous animals compared with those in non-transgenic rats. Plasma GH concentration was significantly approximately 25-32 and approximately 29-41% lower in heterozygous and homozygous transgenic rats, respectively, compared with that in nontransgenic animals. Furthermore, the growth rates in homozygous transgenic rats were reduced by approximately 72-81 and approximately 51-70% compared with those of their heterozygous and nontransgenic littermates, respectively. The results of these studies suggested that the biological effect of GH in vivo is modulated dose-dependently by the antisense RNA transgene. The rat GH gene can therefore be targeted by antisense RNA produced from a transgene, as reflected in the protein and RNA levels.

A multidrug resistant (MDR) cell line was transfected with an antisense MDR1 expression vector and transfectant clones were analyzed for reversion of the MDR phenotype. Only one of 10 antisense-expressing transfectants showed a reduction in drug resistance, MDR1 mRNA and P-glycoprotein. Observations made using rhodamine-123, a fluorescent substrate for P-glycoprotein, revealed that dye retention in individual cells was highly variable within this antisense-expressing clone. Subpopulations were established from the original clone based on differences in rhodamine-123 retention. Rhodamine-123 retention varied inversely with levels of P-glycoprotein and MDR1 mRNA. All subpopulations expressed similar levels of antisense MDR1 RNA yet had dramatic differences in MDR1 mRNA levels. Analysis of vector integration site restriction fragment length polymorphisms confirmed that all populations originated from the same transfectant clone. Nuclear run-on analysis indicated that the mdr1 gene is transcribed at the same rate in all populations, suggesting that the reduction in MDR1 mRNA is mediated posttranscriptionally. Cells with the greatest reduction in MDR1 mRNA accumulate distinct antisense RNA transcripts in the nuclear RNA fraction, suggesting that antisense effectiveness in this system is associated with a nuclear event or process. These results reveal that antisense RNA activity is not necessarily distributed equally within a clonal population.

The complexity of signal transduction is becoming increasingly apparent following the cloning of multiple families of receptors, G proteins, and effectors. Therefore, new tools are needed to assess the importance of particular subtypes in receptor-mediated signal transduction. One such tool is the use of antisense approaches to specifically 'knockout' particular G protein subtypes and then assess the functional consequences for receptor-signalling pathways. In this article by Paul Albert and Stephen Morris, various antisense approaches (including transfection of full-length cDNA) are discussed and compared for their specificity and efficiency. The antisense approach is argued to be applicable to a wide variety of signal-transduction systems, including G-protein-coupled receptor signalling, for analysis of the downstream events that dictate biological responsiveness.