["Matreshka" Genes with Alternative Reading Frames].

Although a relatively small part of the human genome contains protein encoding genes, the latest data on the discovery of alternative open reading frames (ORFs) in conventional mRNAs has highlighted the expanded coding potential of these genes. Until recently, it was believed that each mRNA transcript encodes a single protein. Recent proteogenomics data indicate the existence of exceptions to this rule, which greatly changes the usual meaning of the term "gene". The topology of a gene with overlapping ORFs resembles a Russian "matreshka" toy. There are two levels of "matreshka" genetic systems. First, the chromosomal level, when the "nested" gene is located within introns and exons of the main chromosomal gene, both in the sense and antisense orientation relative to the external gene. The second level is a mature mRNA molecule containing overlapping ORFs or an ORF with an alternative-start codon. In this review we will focus on the properties of "matreshka" genes of the second type and methods for their detection and verification. Particular attention is paid to the biological properties of the polypeptides encoded by these genes.

Plant cell death caused by fungal, bacterial, and viral elicitors: protective effect of mitochondria-targeted quinones.

Chitosan (partially deacetylated chitin), a component of fungal cell walls, caused epidermal cell (EC) death in the leaves of pea (Pisum sativum L.) and tobacco Nicotiana tabacum or Nicotiana benthamiana detected by destruction of cell nuclei. The mitochondria-targeted quinone SkQ1 prevented the destruction of EC nuclei induced by chitosan. Chitosan increased and SkQ1 suppressed the activity of protein kinases in N. benthamiana and P. sativum and eliminated the effect of chitosan. Chitosan induced the generation of reactive oxygen species (ROS) in the guard cells (GC) of pea plants. Treatment with chitosan or H2O2 did not cause destruction of GC nuclei; however, it resulted in disruption of the permeability barrier of the plasma membrane detected by propidium iodide fluorescence. Treatment with bacterial lipopolysaccharide but not peptidoglycan caused destruction of pea EC nuclei, which was prevented by SkQ1. Leaves of tobacco plants containing the N gene responsible for resistance to tobacco mosaic virus (TMV) were infiltrated with Agrobacterium tumefaciens cells. These cells contained a genetic construct with the gene of the helicase domain of TMV replicase (p50); its protein product p50 is a target for the N-gene product. As a result, the hypersensitive response (HR) was initiated. The HR manifested itself in the death of leaves and was suppressed by SkQ3. Treatment of tobacco epidermal peels with the A. tumefaciens cells for the p50 gene expression stimulated the destruction of EC nuclei, which was inhibited by SkQ1 or SkQ3. The p50-lacking A. tumefaciens cells did not induce the destruction of EC nuclei. The protective effect of mitochondria-targeted antioxidants SkQ1 and SkQ3 demonstrates the involvement of mitochondria and their ROS in programmed cell death caused by pathogen elicitors.

Rapid and massive green fluorescent protein production leads to formation of protein Y-bodies in plant cells.

Although high level of recombinant protein production can be achieved via transient expression in plant cells, the mechanism by which tolerance to the presence of recombinant protein is acquired remains unclear. Here we show that green fluorescent protein (GFP) encoded by an intron-optimized tobacco mosaic viral vector formed large membraneless GFP bodies called Y-bodies that demonstrated mainly perinuclear localization. The Y-bodies were heterogeneous in size, approaching the size of the cell nucleus. Experiments with extracted GFP and live cell imaging showed that Y-bodies included actively fluorescent, non-aggregated, tightly packed GFP molecules. The plant cells probably formed Y-bodies to exclude the recombinant protein from normal physiological turnover.

A new viral vector exploiting RNA polymerase I-mediated transcription.

We have developed a new viral vector system exploiting RNA-polymerase I transcription. The vector is based on the crucifer-infecting tobacco mosaic virus (crTMV) cDNA inserted into the rRNA transcriptional cassette (promoter and terminator). To visualize reproduction of the vector, the coat protein gene was replaced with the gene encoding green fluorescent protein (GFP) resulting in a Pr(rRNA)-crTMV-GFP construct. Our results showed that agroinjection of Nicotiana benthamiana leaves with this vector results in GFP production from uncapped crTMV-GFP RNA because RNA polymerase I mediates synthesis of rRNA lacking a cap. Coexpression of the crTMV 122 kDa capping protein gene and the silencing suppressor encoded by the tomato bushy stunt virus p19 gene stimulated virus-directed GFP production more than 100-fold. We conclude that the Pol I promoter can be used to drive transcription in a transient expression system.

Highly efficient expression of Escherichia coli heat-labile enterotoxin B subunit in plants using potato virus X-based vector.

A synthetic gene of the B-subunit of Escherichia coli heat-labile toxin, optimized for expression in plants, was designed and synthesized. The recombinant viral vector was constructed on the basis of potato virus X containing the LTB gene instead of the removed triple block of transport genes and the coat protein gene, which provides for LTB expression in plants. The vector is introduced into the plant cells during cell infiltration by agrobacteria incorporating a binary vector, the T-DNA region of which contains a cDNA copy of the recombinant viral genome. Under conditions of posttranscriptional gene silencing inhibition, the LTB yield in Nicotiana benthamiana plants is 1-2% of total soluble protein; in this case, LTB synthesized in plants forms pentameric complexes analogous to those found in the native toxin. The designed viral system of LTB transient expression can be used to obtain in plants a vaccine against enteropathogenic Escherichia coli.

New viral vector for efficient production of target proteins in plants.

A new potato virus X (PVX)-based viral vector for superproduction of target proteins in plants has been constructed. The triple gene block and coat protein gene of PVX were substituted by green fluorescent protein. This reduced viral vector was delivered into plant cells by agroinjection (injection of Agrobacterium tumefaciens cells, carrying viral vector cDNA within T-DNA, into plant leaves), and this approach allowed to dramatically reduce the size of the vector genome. The novel vector can be used for production of different proteins including pharmaceuticals in plants.

An internal ribosome entry site located upstream of the crucifer-infecting tobamovirus coat protein (CP) gene can be used for CP synthesis in vivo.

It was previously shown that, unlike the type member of the genus Tobamovirus (TMV U1), a crucifer-infecting tobamovirus (crTMV) contains a 148 nt internal ribosome entry site (IRES)(CP,148)(CR) upstream of the coat protein (CP) gene. Here, viral vectors with substitutions in the stem-loop (SL) region of CP subgenomic promoters (TMV U1-CP-GFP/SL-mut and crTMV-CP-GFP/SL-mut) were constructed and the levels of CP synthesis in agroinoculation experiments were compared. No CP-GFP (green fluorescent protein) synthesis was detected in Nicotiana benthamiana leaves inoculated with TMV U1-CP-GFP/SL-mut, whereas a small amount of CP-GFP synthesis was obtained in crTMV-CP-GFP/SL-mut-injected leaves. Northern blots proved that both promoters were inactive. It could be hypothesized that IRES-mediated early production of the CP by crTMV is needed for realization of its crucifer-infecting capacity.

Evidence for contribution of an internal ribosome entry site to intercellular transport of a tobamovirus.

Previously, it has been shown that tobacco mosaic virus (TMV) U1 and crucifer-infecting TMV contain a 75 nt internal ribosome entry site (IRES) upstream of movement protein (MP) gene (IRES(U1)(MP,75) and IRES(CR)(MP,75), respectively). A movement-deficient TMV mutant, KK6, has been constructed previously [Lehto, K., Grantham, G. L. & Dawson, W. O. (1990). Virology 174, 145-157] by insertion of the second coat protein subgenomic promoter (CP SGP-2) upstream of the MP gene, in addition to the natural CP SGP-1. Here, the authors compare the efficiency of movement function expression by KK6 and a derivative, K86, obtained by insertion of IRES(CR)(MP,75) between the CP SGP-2 and MP genes resulting in restoration of IRES(CR)(MP,75) function in the 5'-untranslated sequence of the I(2) subgenomic RNA of K86. The data indicate that the efficiency of K86 movement was largely restored by this insertion, which was apparently due to the translation-enhancing ability of IRES(CR)(MP,75).

Dysfunctionality of a tobacco mosaic virus movement protein mutant mimicking threonine 104 phosphorylation.

Replication of tobacco mosaic virus (TMV) is connected with endoplasmic reticulum (ER)-associated membranes at early stages of infection. This study reports that TMV movement protein (MP)-specific protein kinases (PKs) associated with the ER of tobacco were capable of phosphorylating Thr(104) in TMV MP. The MP-specific PKs with apparent molecular masses of about 45-50 kDa and 38 kDa were revealed by gel PK assays. Two types of mutations were introduced in TMV MP gene of wild-type TMV U1 genome to substitute Thr(104) by neutral Ala or by negatively charged Asp. Mutation of Thr(104) to Ala did not affect the size of necrotic lesions induced by the mutant virus in Nicotiana tabacum Xanthi nc. plants. Conversely, mutation of Thr to Asp mimicking Thr(104) phosphorylation strongly inhibited cell-to-cell movement. The possible role of Thr(104) phosphorylation in TMV MP function is discussed.