番茄丛矮病毒的分子生物学研究进展

近年来,多种植物RNA病毒载体被广泛地应用于外源基因的表达、植物病毒学和植物病理学基础理论的研究中.番茄丛矮病毒(Tomato bushy stunt virus,TBSV)是番茄丛矮病毒科(Tombusviridae)番茄丛矮病毒属(Tombusvirus)的典型成员.TBSV病毒基因组复制、转录和翻译等分子机制的研究取得了巨大的进展,使得利用TBSV构建稳定、高效的表达载体成为可能.     

Tomato bushy stunt virus (TBSV) infecting Lycopersicon esculentum

Tomato bushy stunt virus (TBSV) was detected in tomato crop (Lycopersicon esculentum) in Egypt with characteristic mosaic leaf deformation, stunting, and bushy growth symptoms. TBSV infection was confirmed serologically by ELISA and calculated incidence was 25.5%. Basic physicochemical properties of a purified TBSV Egh isolate were identical to known properties of tombusviruses of isometric 30-nm diameter particles, 41-kDa coat protein and the genome of approximately 4800 nt. This is the first TBSV isolate reported in Egypt. Cloning and partial sequencing of the isolate showed that it is more closely related to TBSV-P and TBSV-Ch than TBSV-Nf and TBSV-S strains of the virus. However, it is distinct from the above strains and could be a new strain of the virus which further confirms the genetic diversity of tombusviruses.     

An internally located RNA hairpin enhances replication of Tomato bushy stunt virus RNAs

Defective interfering (DI) RNAs of Tomato bushy stunt virus (TBSV), a plus-sense RNA virus, comprise four conserved noncontiguous regions (I through IV) derived from the viral genome. Region III, a 70-nucleotide-long sequence corresponding to a genomic segment located 378 nucleotides upstream of the 3' terminus of the genome, has been found to enhance DI RNA accumulation by approximately 10-fold in an orientation-independent manner (D. Ray and K. A. White, Virology 256:162-171, 1999). In this study, a more detailed structure-function analysis of region III was conducted. RNA secondary-structure analyses indicated that region III contains stem-loop structures in both plus and minus strands. Through deletion analyses of a DI RNA, a primary determinant of region III activity was mapped to the 5'-proximal 35-nucleotide segment. Compensatory-type mutational analyses showed that a stem-loop structure in the minus strand of this subregion was required for enhanced DI RNA replication. The same stem-loop structure was also found to function in a position-independent manner in a DI RNA (albeit at reduced levels) and to be important for efficient accumulation within the context of the TBSV genome. Taken together, these observations suggest that the 5'-proximal segment of region III is a modular RNA replication element that functions primarily through the formation of an RNA hairpin structure in the minus strand.     

Authentic replication and recombination of Tomato bushy stunt virus RNA in a cell-free extract from yeast

To study the replication of Tomato bushy stunt virus (TBSV), a small tombusvirus of plants, we have developed a cell-free system based on a Saccharomyces cerevisiae extract. The cell-free system was capable of performing a complete replication cycle on added plus-stranded TBSV replicon RNA (repRNA) that led to the production of approximately 30-fold-more plus-stranded progeny RNAs than the minus-stranded replication intermediate. The cell-free system also replicated the full-length TBSV genomic RNA, which resulted in production of subgenomic RNAs as well. The cell-free system showed high template specificity, since a mutated repRNA, minus-stranded repRNA, or a heterologous viral RNA could not be used as templates by the tombusvirus replicase. Similar to the in vivo situation, replication of the TBSV replicon RNA took place in a membraneous fraction, in which the viral replicase-RNA complex was RNase and protease resistant but sensitive to detergents. In addition to faithfully replicating the TBSV replicon RNA, the cell-free system was also capable of generating TBSV RNA recombinants with high efficiency. Altogether, tombusvirus replicase in the cell-free system showed features remarkably similar to those of the in vivo replicase, including carrying out a complete cycle of replication, high template specificity, and the ability to recombine efficiently.     

Tomato bushy stunt virus co-opts the RNA-binding function of a host metabolic enzyme for viral genomic RNA synthesis

Tomato bushy stunt virus (TBSV), a plus-stranded [(+)] RNA plant virus, incorporates the host metabolic enzyme glyceraldehyde-3-phosphate dehydrogenase (GAPDH) into the viral replicase complex. Here, we show that, during TBSV replication in yeast, the yeast GAPDH Tdh2p moves from the cytosol to the peroxisomal membrane surface, the site of viral RNA synthesis. In yeast cells lacking Tdh2p, decreasing the levels of its functionally redundant homolog Tdh3p inhibited TBSV replication and resulted in equivalent levels of (+) and minus-stranded [(-)] viral RNA, in contrast to the hallmark excess of (+)RNA. Tdh2p specifically bound an AU pentamer sequence in the (-)RNA, suggesting that GAPDH promotes asymmetric RNA synthesis by selectively retaining the (-)RNA template in the replicase complex. Downregulation of GAPDH in a natural plant host decreased TBSV genomic RNA accumulation. Thus, TBSV co-opts the RNA-binding function of a metabolic protein, helping convert the host cell into a viral factory.     

Structural properties of a multifunctional T-shaped RNA domain that mediate efficient tomato bushy stunt virus RNA replication

In positive-strand RNA viruses, 5' untranslated regions (5' UTRs) mediate many essential viral processes, including genome replication. Previously, we proposed that the 5'-terminal portion of the genomic leader sequence of Tomato bushy stunt virus (TBSV) forms an RNA structure containing a 3-helix junction, termed the T-shaped domain (TSD). In the present study, we have carried out structure-function analysis of the proposed TSD and have confirmed an important role for this domain in mediating efficient viral RNA amplification. Using a model TBSV defective interfering RNA replicon and a protoplast system, we demonstrated that various TSD subelements contribute to the efficiency of viral RNA replication. In particular, the stabilities of all three stems (S1, S2, and S4) forming the 3-helix junction are important, while stem-loop 3-a terminal extension of S2-is largely dispensable. Additionally, some of the sequences forming the 3-helix junction are required in an identity-dependent manner. Thus, both secondary structure and nucleotide identity are important for TSD-mediated viral RNA replication. Importantly, these results are fully consistent with the dual functions we defined previously for the sequences corresponding to loops 3 and 4, respectively, in facilitating 5' cap- and 3' poly(A) tail-independent translation of the genome by forming a loop-loop interaction with the 3'-proximal translational enhancer and in mediating viral RNA replication through formation of a pseudoknot with the adjacent downstream RNA domain. Also, since comparable TSDs and associated interactions are predicted in the 5' UTRs of all sequenced Aureusvirus genomes, members of at least one other genus in the family Tombusviridae appear to utilize this type of multifunctional RNA domain.     

On the rigidity of RNA in tomato bushy stunt virus

The motional state of RNA in tomato bushy stunt virus, both in the crystalline state and in solution, has been investigated using ³¹P nuclear magnetic resonance methods. It has been found that the RNA is highly immobile in the native virus and it is suggested that the lack of a high-resolution X-ray diffraction pattern for either the RNA or the N-terminal regions of the protein coat molecules (Harrison et al., 1978) is due to static disorder in the crystals. Dynamic disorder has been detected in the virus after treatment with EDTA, which causes a structural change and an increase in particle size.     

A Unique Role for the Host ESCRT Proteins in Replication of Tomato bushy stunt virus

Plus-stranded RNA viruses replicate in infected cells by assembling viral replicase complexes consisting of viral- and host-coded proteins. Previous genome-wide screens with Tomato bushy stunt tombusvirus (TBSV) in a yeast model host revealed the involvement of seven ESCRT (endosomal sorting complexes required for transport) proteins in viral replication. In this paper, we show that the expression of dominant negative Vps23p, Vps24p, Snf7p, and Vps4p ESCRT factors inhibited virus replication in the plant host, suggesting that tombusviruses co-opt selected ESCRT proteins for the assembly of the viral replicase complex. We also show that TBSV p33 replication protein interacts with Vps23p ESCRT-I and Bro1p accessory ESCRT factors. The interaction with p33 leads to the recruitment of Vps23p to the peroxisomes, the sites of TBSV replication. The viral replicase showed reduced activity and the minus-stranded viral RNA in the replicase became more accessible to ribonuclease when derived from vps23Δ or vps24Δ yeast, suggesting that the protection of the viral RNA is compromised within the replicase complex assembled in the absence of ESCRT proteins. The recruitment of ESCRT proteins is needed for the precise assembly of the replicase complex, which might help the virus evade recognition by the host defense surveillance system and/or prevent viral RNA destruction by the gene silencing machinery.     

A structural comparison of concanavalin a and tomato bushy stunt virus protein

Summary Significant structural equivalence has been found among the polypeptide folds of the two tomato bushy stunt virus (TBSV) subunit domains and concanavalin A. This suggests gene duplication in the TBSV coat protein and leads to speculation on common functional properties of concanavalin A and viral coat proteins.Non-standard abbreviations TBSV tomato bushy stunt virus - SBMV southern bean mosaic virus     

Chloroplast alterations induced by tomato bushy stunt virus inDatura leaves

Summary Peculiar chloroplast alterations were found in mesophyll cells ofDatura stramonium systemically infected with tomato bushy stunt virus. These alterations lead to complete rearrangement of the thylakoids.     

Natural infection of sugar beet with tomato bushy stunt virus

A virus transmissible toChenopodium quinoa was isolated from leaves of sugar beet showing large chlorotic ring spots and line pattern. The virus was serologically unrelated to tobacco necrosis virus and tomato black ring virus or to its beet ringspot strain either. A positive result was obtained with antiserum against tomato bushy stunt virus. Reactions of herbaceous indicators and properties of the virus in crude sap were in accordance with the serological diagnosis. A survey of natural hosts of tomato bushy stunt virus demonstrated recently by the authors is given.     

Studies on the occurrence of tomato bushy stunt virus in English rivers

Tomato bushy stunt virus (TBSV) of unknown source was isolated from water of the River Thames, near Oxford. The isolate designated TBSV-T was mechanically transmissible to several tomato (Lycopersicon esculentum) cvs and to other species including Petunia hybrida, pepper (Capsicum annuum). eggplant (Solanum melongena), Nicotiana clevelandii, Chenopodium amaranticolor and C. quinoa in which it caused systemic symptoms. It caused no infection of globe artichoke (Cynara scolymus) or Pelargonium domesticum. The virus was not adsorbed to soil and could be isolated from leachate of soil in which systemically-infected tomato or C. quinoa plants were grown. Tomato plants became infected when grown in soil watered with virus suspensions. TBSV-T was infective after 10 min at 80°C but not at 90°C and when diluted to 10^-5 but not to 10^-6. Purified virus preparations contained C. 30 nm isometric particles. In gel-diffusion serological tests, TBSV-T reacted with homologous anti-serum and with antiserum to petunia asteroid mosaic virus but not to pelargonium leaf curl virus. Seed-borne infection (50–65%) of TBSV was demonstrated in plants grown from seed of symptomlessly-infected tomato fruit. TBSV was isolated from symptomlessly-infected tomato fruit imported from Morocco during October-April 1981. One of the isolates (TBSV-M) was indistinguishable from TBSV-T in host range, symptomatology and serological reactions. TBSV was also found in tomato plants growing extraneously in primary settlement beds at sewage works; such plants having been derived from undigested seeds in sewage. Because of its ‘alimentary-resistance’ in man, it is possible that one ecological route whereby TBSV enters rivers is by man's consumption of TBSV-infected tomatoes and eventual sewage dispersal into rivers.