Tetsuo Meshi

Arabidopsis Cys2/His2-Type Zinc-Finger Proteins Function as Transcription Repressors under Drought, Cold, and High-Salinity Stress Conditions

ZPT2-related proteins that have two canonical Cys-2/His-2-type zinc-finger motifs in their molecules are members of a family of plant transcription factors. To characterize the role of this type of protein, we analyzed the function of Arabidopsis L. Heynh. genes encoding four different ZPT2-related proteins (AZF1, AZF2, AZF3, and STZ). Gel-shift analysis showed that the AZFs and STZ bind to A(G/C)T repeats within an EP2 sequence, known as a target sequence of some petunia (Petunia hybrida) ZPT2 proteins. Transient expression analysis using synthetic green fluorescent protein fusion genes indicated that the AZFs and STZ are preferentially localized to the nucleus. These four ZPT2-related proteins were shown to act as transcriptional repressors that down-regulate the transactivation activity of other transcription factors. RNA gel-blot analysis showed that expression of AZF2 and STZ was strongly induced by dehydration, high-salt and cold stresses, and abscisic acid treatment. Histochemical analysis of β-glucuronidase activities driven by the AZF2 or STZ promoters revealed that both genes are induced in leaves rather than roots of rosette plants by the stresses. Transgenic Arabidopsis overexpressing STZ showed growth retardation and tolerance to drought stress. These results suggest that AZF2 and STZ function as transcriptional repressors to increase stress tolerance following growth retardation.

Expression of bacterial chloramphenicol acetyltransferase gene in tobacco plants mediated by TMV-RNA.

We have constructed three tobacco mosaic virus (TMV) cDNA derivatives by modification of the full‐length cDNA clone from which infectious TMV‐RNA can be transcribed in vitro. A coatless TMV construct lacks most of the coat protein gene and chimeric TMV constructs retain the bacterial chloramphenicol acetyltransferase (CAT) gene in place of the coat protein gene. When in vitro transcripts from these cDNA derivatives were inoculated on the local lesion tobacco plants, TMV‐specific lesions were produced. In the case of the TMV–CAT chimeras, however, the lesions were small compared to those of wild‐type TMV and those produced by transcript derived from the coatless construct. Northern blot analysis of RNA extracted from the inoculated leaves of the systemic host plants revealed replication of the derivative genomic RNAs and production of their own subgenomic RNAs corresponding to the coat protein mRNA. The TMV–CAT chimeras produced biologically active CAT in the inoculated leaves of the systemic host. CAT activity increased at least until 2 weeks post‐inoculation and was ~0.1 units/mg of tissue at 10 days post‐inoculation. Thus, TMV–RNA may be utilized as a new plant expression vector.

Localization by immunogold cytochemistry of the virus-coded 30K protein in plasmodesmata of leaves infected with tobacco mosaic virus.

The 30K protein of tobacco mosaic virus (TMV) was localized to the plasmodesmata of infected tobacco leaves by immunogold cytochemistry. This protein has been reported to be in the nuclear fraction of TMV-infected protoplasts, but as it has been proposed to function in cell-to-cell transport of virus, probably via the plasmodesmata, intact tissue was investigated with particular attention directed to plasmodesmata and nuclei. Thin sections were made from leaves mechanically inoculated with TMV at different times. Affinity-purified antibodies against a synthetic peptide corresponding to the C-terminal sequence of the 30K protein were used in the incubations, and parallel sections were incubated with antibodies against TMV. The 30K protein label accumulated inside the plasmodesmata, with a maximum 24 hr after inoculation. No specific label was found in the nuclei or at any other site in the cells.

Function of the 30 kd protein of tobacco mosaic virus: involvement in cell-to-cell movement and dispensability for replication

We have investigated the function of the 30 kd protein of tobacco mosaic virus (TMV) by a reverse genetics approach. First, a point mutation of TMV Ls1 (a temperature‐sensitive mutant defective in cell‐to‐cell movement), that causes an amino acid substitution in the 30 kd protein, was introduced into the parent strain, TMV L. The generated mutant showed the same phenotype as TMV Ls1, and therefore the one‐base substitution in the 30 kd protein gene adequately explains the defectiveness of TMV Ls1. Next, four kinds of frame‐shift mutants were constructed, whose mutations are located at three different positions of the 30 kd protein gene. All the frame‐shift mutants were replication‐competent in protoplasts but none showed infectivity on tobacco plants. From these observations the 30 kd protein was confirmed to be involved in cell‐to‐cell movement. To clarify that the 30 kd protein is not necessary for replication, two kinds of deletion mutants were constructed; one lacking most of the 30 kd protein gene and the other lacking both the 30 kd and coat protein genes. Both mutants replicated in protoplasts and the former still produced the subgenomic mRNA for the coat protein. These results clearly showed that the 30 kd protein, as well as the coat protein, is dispensable for replication and that no cis‐acting element for replication is located in their coding sequences. It is also suggested that the signal for coat protein mRNA synthesis may be located within about 100 nucleotides upstream of the initiation codon of the coat protein gene.

In vitro assembly of plant RNA-induced silencing complexes facilitated by molecular chaperone HSP90.

RNA-induced silencing complexes (RISCs) play central roles in posttranscriptional gene silencing. In plants, the mechanism of RISC assembly has remained elusive due to the lack of cell-free systems that recapitulate the process. In this report, we demonstrate that plant AGO1 protein synthesized by in vitro translation using an extract of evacuolated tobacco protoplasts incorporates synthetic small interfering RNA (siRNA) and microRNA (miRNA) duplexes to form RISCs that sequester the single-stranded siRNA guide strand and miRNA strand, respectively. The formed RISCs were able to recognize and cleave the complementary target RNAs. In this system, the siRNA duplex was incorporated into HSP90-bound AGO1, and subsequent removal of the passenger strand was triggered by ATP hydrolysis by HSP90. Removal of the siRNA passenger strand required the ribonuclease activity of AGO1, while that of the miRNA star strand did not. Based on these results, the mechanism of plant RISC formation is discussed.

Tomato Mosaic Virus Replication Protein Suppresses Virus-Targeted Posttranscriptional Gene Silencing

ABSTRACT Posttranscriptional gene silencing (PTGS), a homology-dependent RNA degradation system, has a role in defending against virus infection in plants, but plant viruses encode a suppressor to combat PTGS. Using transgenic tobacco in which the expression of green fluorescent protein (GFP) is posttranscriptionally silenced, we investigated a tomato mosaic virus (ToMV)-encoded PTGS suppressor. Infection with wild-type ToMV (L strain) interrupted GFP silencing in tobacco, coincident with visible symptoms, whereas some attenuated strains of ToMV (L11 and L11A strains) failed to suppress GFP silencing. Analyses of recombinant viruses containing the L and L11A strains revealed that a single base change in the replicase gene, which causes an amino acid substitution, is responsible for the symptomless and suppressor-defective phenotypes of the attenuated strains. An agroinfiltration assay indicated that the 130K replication protein acts as a PTGS suppressor. Small interfering RNAs (siRNAs) of 21 to 25 nucleotides accumulated during ToMV infection, suggesting that the major target of the ToMV-encoded suppressor is downstream from the production of siRNAs in the PTGS pathway. Analysis with GFP-tagged recombinant viruses revealed that the suppressor inhibits the establishment of the ToMV-targeted PTGS system in the inoculated leaves but does not detectably suppress the activity of the preexisting, sequence-specific PTGS machinery there. Taken together, these results indicate that it is likely that the ToMV-encoded suppressor, the 130K replication protein, blocks the utilization of silencing-associated small RNAs, so that a homology-dependent RNA degradation machinery is not newly formed.

Mutations in the tobacco mosaic virus 30-kD protein gene overcome Tm-2 resistance in tomato.

A resistance-breaking strain of tobacco mosaic virus (TMV), Ltb1, is able to multiply in tomatoes with the Tm-2 gene, unlike its parent strain, L. Nucleotide sequence analysis of Ltb1 RNA revealed two amino acid changes in the 30-kD protein: from Cys68 to Phe and from Glu133 to Lys (from L to Ltb1). Strains with these two changes generated in vitro multiplied in tomatoes with the Tm-2 gene and induced essentially the same symptoms as those caused by Ltb1. Strains with either one of the two changes did not overcome the resistance as efficiently as Ltb1, although increased levels of multiplication were observed compared with the L strain. Results showed that both mutations are involved in the resistance-breaking property of Ltb1. Sequence analysis indicated that another resistance-breaking strain and its parent strain had two amino acid changes in the 30-kD protein: from Glu52 to Lys and from Glu133 to Lys. The fact that the amino acid changes occurred in or near the well conserved regions in the 30-kD protein suggests that the mechanism of Tm-2 resistance may be closely related to the fundamental function of the 30-kD protein, presumably in cell-to-cell movement.

Two concomitant base substitutions in the putative replicase genes of tobacco mosaic virus confer the ability to overcome the effects of a tomato resistance gene, Tm-1

A resistance‐breaking strain of tobacco mosaic virus (TMV), Ltal, is able to multiply in tomatoes with the Tm‐1 gene, unlike its parent strain, L. Comparison of the genomic sequences of L and Lta1 revealed two base substitutions resulting in amino acid changes in the 130 and 180 kd proteins: Gln‐979 → Glu and His‐984 → Tyr. To clarify their involvement in the resistance‐breaking property of Lta1, the two substitions were introduced into L by an in vitro transcription system to generate a mutant strain, T1. T1 multiplied in Tm‐1/Tm‐1 tomatoes with symptoms as did Lta1. Two additional mutant strains were constructed, each of which had one base substitution which caused a His‐984 → Tyr change (T2) or a Gln‐979 → Glu change (T3). T3 multiplied in tomato plants and protoplasts with the Tm‐1 gene, indicating that the single base substitution is sufficient to overcome the resistance. T2 also multiplied, but its multiplication was greatly decreased. Although no sequence changes were detected in any progeny viruses recovered from plants without the Tm‐1 gene, progeny viruses recovered from T2‐ or T3‐ inoculated Tm‐1/Tm‐1 tomatoes contained in most cases viruses with additional second base substitutions. They caused amino acid changes near the mutagenized residues, suggesting that the ability of T3 to overcome the resistance is not the same as that of Lta1. Sequencing of the genomic RNAs of other independently isolated resistance‐breaking strains revealed the same two base substitutions found in the Lta1 RNA. These observations suggest that the two concomitant base substitutions, and possibly also the resulting amino acid changes, guarantee successful replication of these TMV strains in tomatoes containing the Tm‐1 gene. A strong correlation was found between the ability to overcome the resistance and a decrease in local net charge, suggesting the involvement of an electrostatic interaction between the viral 130 and 180 kd proteins and a putative host resistance factor.

Expression of a subset of the Arabidopsis Cys2/His2-type zinc-finger protein gene family under water stress.

The genes encoding Cys(2)/His(2)-type zinc-finger proteins constitute a large family in higher plants. To elucidate the functional roles of these types of protein, four different members of the gene family were cloned from Arabidopsis by PCR-aided methods. One was identical to the already reported gene STZ/ZAT10 and three were as yet unidentified genes, then designated AZF1 (Arabidopsis zinc-finger protein 1), AZF2 and AZF3. The AZF- and STZ-encoded proteins contain two canonical Cys(2)/His(2)-type zinc-finger motifs, separated by a long spacer. Three conserved regions, named B-box, L-box, and DNL-box, were also recognized outside the zinc-finger motifs, as in other members of the two-fingered Cys(2)/His(2)-type zinc-finger protein family. These four genes were positioned on the same branch of a phylogenetic tree constructed based on the zinc-finger motif sequences, suggesting their structural and functional relationship. RNA blot analysis showed that all four genes were mainly expressed in roots and at different levels in other organs. Expression of the four genes responded to water stress. High-salt treatment resulted in elevated levels of expression of all of these genes. Low-temperature treatment increased the expression levels of AZF1, AZF3, and STZ, but not AZF2. Only AZF2 expression was strongly induced by ABA treatment, where the time course of the induction was similar to that caused by high salinity. In situ localization showed that AZF2 mRNA accumulated in the elongation zone of the roots under the salt-stress condition. These results suggest that AZF1, AZF2, AZF3, and STZ are all involved in the water-stress response in an ABA-dependent or -independent pathway to regulate downstream genes.

Subcellular localization of host and viral proteins associated with tobamovirus RNA replication

Arabidopsis TOM1 (AtTOM1) and TOM2A (AtTOM2A) are integral membrane proteins genetically identified to be necessary for efficient intracellular multiplication of tobamoviruses. AtTOM1 interacts with the helicase domain polypeptide of tobamovirus‐encoded replication proteins and with AtTOM2A, suggesting that both AtTOM1 and AtTOM2A are integral components of the tobamovirus replication complex. We show here that AtTOM1 and AtTOM2A proteins tagged with green fluorescent protein (GFP) are targeted to the vacuolar membrane (tonoplast)‐like structures in plant cells. In subcellular fractionation analyses, GFP–AtTOM2A, AtTOM2A and its tobacco homolog NtTOM2A were predominantly fractionated to low‐density tonoplast‐rich fractions, whereas AtTOM1–GFP, AtTOM1 and its tobacco homolog NtTOM1 were distributed mainly into the tonoplast‐rich fractions and partially into higher‐buoyant‐density fractions containing membranes from several other organelles. The tobamovirus‐encoded replication proteins were co‐fractionated with both NtTOM1 and viral RNA‐dependent RNA polymerase activity. The replication proteins were also found in the fractions containing non‐membrane‐bound proteins, but neither NtTOM1 nor the polymerase activity was detected there. These observations suggest that the formation of tobamoviral RNA replication complex occurs on TOM1‐containing membranes and is facilitated by TOM2A.