RNA-mediated gene silencing in the phytopathogenic fungus Bipolaris oryzae

The Ascomycetous fungus Bipolaris oryzae is the causal agent of brown leaf spot disease in rice and is a model for studying photomorphogenetic responses by near-UV radiation. Targeted gene disruption (knockout) for functional analysis of photomorphogenesis-related genes in B. oryzae can be achieved by homologous recombination with low efficiency. Here, the applicability of RNA silencing (knockdown) as a tool for targeting endogenous genes in B. oryzae is reported. A polyketide synthase gene (PKS1), involved in fungal DHN melanin biosynthesis pathways, was targeted by gene silencing as a marker. The silencing vector encoding hairpin RNA of the PKS1 fragment was constructed in a two-step PCR-based cloning, and introduced into the B. oryzae genomic DNA. Silencing of the PKS1 gene resulted in albino phenotypes and reduction of PKS1 mRNA expression. These results demonstrate the applicability of targeted gene silencing as a useful reverse-genetics approach in B. oryzae.     

Small interfering RNA-mediated gene silencing in T lymphocytes

Introduction of small interfering RNAs (siRNAs) into a cell can cause a specific interference of gene expression known as RNA interference (RNAi). However, RNAi activity in lymphocytes and in normal primary mammalian cells has not been thoroughly demonstrated. In this report, we show that siRNAs complementary to CD4 and CD8alpha specifically reduce surface expression of these coreceptors and their respective mRNA in a thymoma cell line model. We show that RNAi activity is only caused by a subset of siRNAs complementary to the mRNA target and that ineffective siRNAs can compete with effective siRNAs. Using primary differentiated T lymphocytes, we provide the first evidence of siRNA-mediated RNAi gene silencing in normal nontransformed somatic mammalian lymphocytes.     

RNA-mediated gene silencing of ToxB in Pyrenophora tritici-repentis

The fungus Pyrenophora tritici-repentis causes tan spot, a wheat leaf disease of worldwide importance. The pathogen produces three host-selective toxins, including Ptr ToxB, which causes chlorophyll degradation and foliar chlorosis on toxin-sensitive wheat genotypes. The ToxB gene, which codes for Ptr ToxB, was silenced in a wild-type race 5 isolate of the fungus thorough a sense- and antisense-mediated silencing mechanism. Toxin production by the silenced strains was evaluated in culture filtrates of the fungus via Western blotting analysis, and plant bioassays were conducted to test the virulence of the transformants in planta. The chlorosis-inducing ability of the silenced strains was correlated with the quantity of Ptr ToxB, and transformants in which toxin production was strongly decreased also caused very little disease on toxin-sensitive wheat genotypes. Cytological analysis of the infection process revealed that, in addition to a reduced capacity to induce chlorosis, the silenced strains with the greatest decrease in the levels of Ptr ToxB produced significantly fewer appressoria than the wild-type isolate, 12 and 24 h after inoculation onto wheat leaves. The results provide strong support for the suggestion that the amount of Ptr ToxB protein produced by fungal isolates plays a significant role in the quantitative variation in the virulence of P. tritici-repentis.     

Defective RNA-mediated c-myc gene silencing pathway in Burkitt's lymphoma

Keeping in view the fact that molecular basis of Burkitt's lymphoma (BL) is poorly understood, we attempted to explore the small interfering RNA (siRNA) mediated c-myc gene regulation using BL-derived EB-3 cell line as archetype cellular model. Such a study revealed that EB-3 cells possess 4-fold higher expression of Dicer gene coupled with 2-fold higher activity of RNA polymerase III than that observed in normal human lymphocytes. siRNAs derived from EB-3 cells had the inherent capacity to suppress c-myc gene expression in normal cells but not in native cells. Based on these findings we have proposed a novel RNA-mediated c-myc gene regulation pathway that may be responsible for BL.     

Small RNA-mediated gene silencing pathways in C. elegans

Small RNA pathways, including the RNA interference (RNAi) pathway and the microRNA (miRNA) pathway, regulate gene expression, defend against transposable elements and viruses, and, in some organisms, guide genome rearrangements. The nematode Caenorhabditis elegans (C. elegans) has been at the forefront of small RNA research; not only were the first miRNAs and their function as regulators of gene expression discovered in C. elegans, but also double-stranded RNA-induced gene silencing by RNAi was discovered in this model organism. Since then, genetic and RNAi-mediated screens, candidate gene approaches, and biochemical studies have uncovered numerous factors in the small RNA pathways and painted a rich palette of interacting pathways. Here we review the different small RNAs that have been discovered in C. elegans and discuss our understanding of their biogenesis pathways and mechanisms of action.     

RNA-mediated RNA degradation in transgene- and virus-induced gene silencing

In the 'RNA world' hypothesis it is postulated that RNA was the first genetic molecule. Recent discoveries in gene silencing research on plants, fungi and animals show that RNA indeed plays a key role not only in controlling invading nucleic acids, like viruses and transposable elements, but also in regulating the expression of transgenes and endogenous genes. Double-stranded RNAs were identified to be the triggering structures for the induction of a specific and highly efficient RNA silencing system, in which enzyme complexes, like Dicer and RISC, facilitate as 'molecular machines' the processing of dsRNA into characteristic small RNA species. RNA silencing can be transmitted rapidly from silenced to non-silenced cells by short and long distance signaling. There is evidence that at least one component of the signal is a specific, degradation-resistant RNA.     

RNA-mediated gene silencing in monokaryons and dikaryons of Schizophyllum commune

Disruption of genes by homologous recombination occurs at a low frequency in the basidiomycete Schizophyllum commune. For instance, the SC3 and SC15 genes were inactivated at frequencies of 1 and 5%, respectively. As an alternative to disruption, we used gene silencing through the introduction of a hairpin construct. The SC15 gene, which encodes an abundantly secreted structural protein, was silenced at a frequency of 80% in monokaryons of S. commune after introduction of a hairpin construct of the gene. Silencing also occurred in dikaryons in which one of the partners was not a silenced strain. The silencing mechanism resembles RNAi in other filamentous fungi and is a powerful tool for the functional analysis of genes expressed in monokaryons or dikaryons.     

High-stearic and High-oleic cottonseed oils produced by hairpin RNA-mediated post-transcriptional gene silencing

We have genetically modified the fatty acid composition of cottonseed oil using the recently developed technique of hairpin RNA-mediated gene silencing to down-regulate the seed expression of two key fatty acid desaturase genes, ghSAD-1-encoding stearoyl-acyl-carrier protein Delta 9-desaturase and ghFAD2-1-encoding oleoyl-phosphatidylcholine omega 6-desaturase. Hairpin RNA-encoding gene constructs (HP) targeted against either ghSAD-1 or ghFAD2-1 were transformed into cotton (Gossypium hirsutum cv Coker 315). The resulting down-regulation of the ghSAD-1 gene substantially increased stearic acid from the normal levels of 2% to 3% up to as high as 40%, and silencing of the ghFAD2-1 gene resulted in greatly elevated oleic acid content, up to 77% compared with about 15% in seeds of untransformed plants. In addition, palmitic acid was significantly lowered in both high-stearic and high-oleic lines. Similar fatty acid composition phenotypes were also achieved by transformation with conventional antisense constructs targeted against the same genes, but at much lower frequencies than were achieved with the HP constructs. By intercrossing the high-stearic and high-oleic genotypes, it was possible to simultaneously down-regulate both ghSAD-1 and ghFAD2-1 to the same degree as observed in the individually silenced parental lines, demonstrating for the first time, to our knowledge, that duplex RNA-induced posttranslational gene silencing in independent genes can be stacked without any diminution in the degree of silencing. The silencing of ghSAD-1 and/or ghFAD2-1 to various degrees enables the development of cottonseed oils having novel combinations of palmitic, stearic, oleic, and linoleic contents that can be used in margarines and deep frying without hydrogenation and also potentially in high-value confectionery applications.