Importance of translation and nonnucleolytic ago proteins for on-target RNA interference.

In animals, both siRNAs and miRNAs are thought to diminish protein synthesis from transcripts that are perfectly complementary by directing endonucleolytic cleavage where they anneal, thereby triggering rapid degradation of the entire message [1-4]. By contrast, partially complementary messages are downregulated by a combination of translational repression and accelerated decay caused by rapid poly(A) tail removal [3, 5-12]. Here we present evidence that translational repression can also make a substantial contribution to the downregulation of fully complementary messages by RNA interference.

Allele-specific targeting of microRNAs to HLA-G and risk of asthma.

HLA-G is a nonclassic, class I HLA molecule that has important immunomodulatory properties. Previously, we identified HLA-G as an asthma-susceptibility gene and discovered that the risk of asthma in a child was determined by both the child's HLA-G genotype and the mother's affection status. Here we report a SNP in the 3' untranslated region of HLA-G that influences the targeting of three microRNAs (miRNAs) to this gene, and we suggest that allele-specific targeting of these miRNAs accounts, at least in part, for our earlier observations on HLA-G and the risk of asthma.

CD24 is expressed by myofiber synaptic nuclei and regulates synaptic transmission.

The genes encoding several synaptic proteins, including acetylcholine receptors, acetylcholinesterase, and the muscle-specific kinase, MuSK, are expressed selectively by a small number of myofiber nuclei positioned near the synaptic site. Genetic analysis of mutant mice suggests that additional genes, expressed selectively by synaptic nuclei, might encode muscle-derived retrograde signals that regulate the differentiation of motor axon terminals. To identify candidate retrograde signals, we used a microarray screen to identify genes that are preferentially expressed in the synaptic region of muscle, and we analyzed one such gene, CD24, further.

MicroRNAs direct rapid deadenylation of mRNA.

MicroRNAs (miRNAs) are ubiquitous regulators of eukaryotic gene expression. In addition to repressing translation, miRNAs can down-regulate the concentration of mRNAs that contain elements to which they are imperfectly complementary. Using miR-125b and let-7 as representative miRNAs, we show that in mammalian cells this reduction in message abundance is a consequence of accelerated deadenylation, which leads to rapid mRNA decay.

A modified TMV-based vector facilitates the expression of longer foreign epitopes in tobacco.

Based upon a mutant isolated from tobacco infected with a recombinant tobacco mosaic virus (TMV), a new TMV-based vector was developed in which four to six C-terminal amino acid residues were deleted from the viral coat protein (CP) subunit. The new vector was quite similar to the original TMV-based vector, which all expressed a well characterized epitope peptide F11 (P(142)-A(152)) of VP1 from foot-and-mouth disease virus (FMDV) serotype O in tobacco, in the infectivity, yield of the virus particles and more importantly protective activity of F11 in guinea pigs and swine against the FMDV. Furthermore, the capacity of the length of foreign peptide encoded by this new vector was much improved to successfully express a peptide F25 containing two fused epitopes F14 (R(200)-L(213)) and F11 of FMDV VP1, which was failed using the original vector in tobacco.

Runx1 prevents wasting, myofibrillar disorganization, and autophagy of skeletal muscle.

Disruptions in the use of skeletal muscle lead to muscle atrophy. After short periods of disuse, muscle atrophy is reversible, and even after prolonged periods of inactivity, myofiber degeneration is uncommon. The pathways that regulate atrophy, initiated either by peripheral nerve damage, immobilization, aging, catabolic steroids, or cancer cachexia, however, are poorly understood.

Expression of foot-and-mouth disease virus epitopes in tobacco by a tobacco mosaic virus-based vector.

We expressed two immunogenic dominant epitopes of foot-and-mouth disease virus (FMDV) serotype O in tobacco plant using a vector based on a recombinant tobacco mosaic virus (TMV). The recombinant viruses TMVF11 and TMVF14 contained peptides of 11 and 14 amino acid residues, respectively, from FMDV VP 1 fused to the open reading frame of TMV coat protein (CP) gene between amino acid residues 154 and 155. TMVF11 and TMVF14 systemically infected tobacco plant and produced large quantities of stable progeny viral particles assembled with the modified CP subunits.

A specific cis-hairpin ribozyme facilitates infection of a TMV-based DNA vector in tobacco protoplasts.

The effect of a specific cis-hairpin ribozyme on TMV-based vectors in the infection of tobacco protoplasts was studied. Vectors contained full-length TMV genome cDNA linked to a T7 promoter or a CaMV 35S promoter at the 5'-end and an NOS gene polyadenylation signal at the 3'-end. The coat protein (CP) gene was replaced with the green fluorescent protein (GFPuv) gene allowing quantification of protoplast infection.