Tomato yellow leaf curl virus in Tomato in Texas, Originating from Transplant Facilities.

Tomato yellow leaf curl virus (TYLCV), a monopartite virus in the genus Begomovirus (family, Geminiviridae) from the Middle East, is one of the most damaging whitefly-transmitted viruses of tomato (Lycopersicon esculentum) worldwide. TYLCV was first identified in the United States in 1997 in Florida (4), and most recently, in the Pacific Coast states of Mexico where fresh market tomatoes are grown for the U.S. market (1). During September 2006, tomatoes grown from transplants in Waller County, TX exhibited shortened internodes, stunting and puckering of leaflets, green vein banding, and diffuse chlorosis. The disease incidence in two fields (4 ha total) was 95% and yield was substantially reduced. Many of the transplants were symptomatic at planting. The transplants originated from two facilities in Hidalgo County, TX. Both facilities had experienced heavy infestations of the whitefly, Bemisia tabaci (Genn.), during transplant production. At the same time, transplants produced in Uvalde and Bexar counties, TX, where whitefly infestations were also prevalent, had similar virus symptoms. Total DNA was extracted from the leaves of symptomatic tomato plants from 10 samples from these four counties and amplified by PCR (2). DNA samples from Waller, Hidalgo, and Uvalde counties were cloned, and a partial fragment of the viral coat protein gene (core Cp) was sequenced. BLAST analysis of the core Cp sequences of each sample confirmed the presence of TYLCV. No other begomovirus was detected, and all attempts to amplify a bipartite begomovirus by PCR using degenerate DNA-B specific primers (3) were unsuccessful. The full-length TYLCV DNA was amplified from three samples using the rolling circle amplification method as described (1), cloned, and the sequences were determined. The three sequences shared 99.6 to 100% nt identity and so only one sequence was deposited in the NCBI GenBank database (Accession No. EF110890) (1). Analysis of the complete genome nucleotide sequence corroborated TYLCV identity predicted by core Cp analysis that was 98.1% identical with TYLCV from Egypt (GenBank Accession No. AY594174) and Spain (GenBank Accession No. AJ489258), 97.6% with TYLCV from Mexico (GenBank Accession No. DQ631892), and 96.5% with TYLCV-Is (GenBank Accession No. X15656). Additionally, a Southern blot with TYLCV as the probe detected replicating (double-stranded) TYLCV DNA in all samples consisting of three plants from Uvalde County and 21 plants from Bexar County. To our knowledge, this is the first report of TYLCV in Texas that occurred in two transplant production areas approximately 400 km apart. Transplants produced in Uvalde and Bexar counties were planted there, while Hidalgo County transplants were shipped outside of the usual range of the whitefly. Hidalgo County has a subtropical climate, which can allow overwintering of TYLCV and the whitefly vector, allowing the establishment and spread of this virus in the future. References: (1) J. K. Brown and A. M. Idris. Plant Dis. 90:1360, 2006. (2) J. K. Brown et al. Arch. Virol. 146:1581, 2001. (3) A. M. Idris and J. K. Brown. Phytopathology 88:648, 1998. (4) J. E. Polston et al. Plant Dis. 83:984, 1999.

Plants expressing tomato golden mosaic virus AL2 or beet curly top virus L2 transgenes show enhanced susceptibility to infection by DNA and RNA viruses.

The AL2 gene of the geminivirus tomato golden mosaic virus (TGMV) encodes a transcriptional activator protein (TrAP) that is required for efficient expression of the viral coat protein (CP) and BR1 gene promoters. In contrast, L2, the positional homolog of AL2 in the related beet curly top virus (BCTV), is not required for CP expression, raising questions about the functional relationship between the AL2 and L2 gene products. In this study, transgenic Nicotiana benthamiana and N. tabacum var. Samsun plants expressing a truncated AL2 gene (AL2(1-100), lacking the activation domain) or full-length L2 were prepared. These transgenic plants showed a novel enhanced susceptibility (ES) phenotype following inoculation with TGMV, BCTV, or tobacco mosaic virus (TMV), an unrelated RNA virus. ES is characterized by a reduction in the mean latent period (from 1 to 9 days) and by a decrease in the inoculum concentration required to infect transgenic plants (ID50 reduced 6- to 60-fold). However, ES does not result in an enhancement of disease symptoms, and viral nucleic acids do not accumulate to substantially greater levels in infected transgenic plants. That both viral transgenes condition ES suggests that their products share the ability to suppress a host stress or defense response that acts against DNA and RNA viruses. The data further indicate that the transcriptional activation activity of AL2 protein is not required for suppression. The nature of the response targeted by the AL2 and L2 gene products is discussed.

The tomato golden mosaic virus transactivator (TrAP) is a single-stranded DNA and zinc-binding phosphoprotein with an acidic activation domain.

The AL2 gene found in members of the genus Begomovirus of the Geminiviridae encodes a transcriptional activator protein (TrAP; also known as AL2, AC2, or C2 protein). TrAP activates expression from the viral coat protein (CP) and BR1 movement gene promoters in mesophyll cells and protoplasts and acts to derepress the CP promoter in vascular tissue. The experiments presented here were designed to elucidate some of the biochemical properties of this multifunctional regulatory protein and to define its activation domain. The results indicate that TrAP from tomato golden mosaic virus (TGMV) binds single-stranded DNA in a sequence nonspecific manner and only weakly interacts with double-stranded DNA, confirming earlier results obtained with TrAP from other begomoviruses. In addition, evidence is presented that indicates that TrAP binds zinc and that zinc is necessary for optimal interaction with ssDNA. We also show that TrAP is phosphorylated when expressed in insect cells and that it contains a transcriptional activation domain of the acidic type. The minimal activation domain is quite small; the region comprising only the 15 C-terminal amino acids of the protein is capable of activating transcription in mouse fibroblasts (NIH3T3 cells) when fused to a heterologous DNA-binding domain.

Regulation of a geminivirus coat protein promoter by AL2 protein (TrAP): evidence for activation and derepression mechanisms.

Tomato golden mosaic virus (TGMV) is a bipartite member of the subgroup III Geminiviridae. Like all geminiviruses, TGMV replicates in the nucleus of susceptible cells by rolling circle replication (RCR). Double-stranded replicative form DNA generated during RCR serves as template for the transcription of viral genes by RNA polymerase II and the associated cellular transcription machinery. Previous studies in tobacco protoplasts and Nicotiana benthamiana leaf discs have shown that the viral AL2 gene product transactivates expression of the coat protein (CP) and BR1 movement protein genes, and that activation occurs at the level of transcription. Because of its function and properties, we propose the name TrAP, transcriptional activator protein, for the AL2 gene product. Using transgenes consisting of complete and truncated versions of the CP promoter fused to the GUS reporter gene, we show in the studies presented here that TrAP is required for CP gene expression in both mesophyll and phloem tissues. Surprisingly, TrAP appears to induce CP expression by different mechanisms in different cell types: it may activate the CP promoter in mesophyll cells, and acts to derepress the promoter in phloem tissue. In addition, TrAP is clearly capable of inducing the expression of responsive chromosomal promoters and could, in principle, activate host genes. Distinct viral sequence elements mediate expression and derepression in phloem and activation in mesophyll, suggesting that TrAP interacts with different components of the cellular transcription machinery to accomplish CP gene expression in different cell types, and underscoring the intricacy and complexity of virus-host interactions.

Heterologous complementation by geminivirus AL2 and AL3 genes.

The geminivirus group is diverse and contains viruses which can be placed into three distinct subgroups on the basis of their genome organization and biological properties. However, most dicot-infecting gemiviruses possess AL1, AL2, and AL3 open reading frames. AL1 encodes the only viral protein that is absolutely required for replication, AL2 codes for a protein that transactivates the expression of virion sense promoters, and AL3 specifies a protein that enhances viral DNA replication. In the studies presented here, we examined the functional specificity of the AL1, AL2, and AL3 specifies gene products of subgroup II and subgroup III geminiviruses. Surprisingly, we found that all viruses tested were able to produce a gene product which complemented the reduced DNA replication phenotype of a tomato golden mosaic virus (TGMV) AL3 mutant. We also found that all bipartite subgroup III viruses tested produced a protein that could transactivate the virion sense promoters of a TGMV AL2 mutant, although a subgroup II virus did not. In contrast, the replication activity of AL1 protein proved to be virus specific. The data are discussed with regard to the functions of these proteins in viral replication and their practical significance for the development of crop protection strategies.

Tomato golden mosaic virus leftward gene expression: autoregulation of geminivirus replication protein.

The genome of the geminivirus tomato golden mosaic virus (TGMV) consists of two DNA components, designated DNA A and DNA B. DNA A encodes AL1, the only viral protein required for DNA replication. AL1 protein interacts specifically with sequences in the common region that is conserved between the two genome components, near sequences involved in the transcription of complementary sense genes encoding BL1 protein and the AL1 protein itself. In the experiments described here, we replaced the AL1 and BL1 open reading frames with the beta-glucuronidase (GUS) reporter gene and used the gene replacement constructs to examine AL1 and BL1 gene expression in tobacco protoplasts. We found that expression of the GUS reporter in the AL1 replacement construct was reduced to background levels when transfections included a plasmid expressing AL1 protein from the cauliflower mosaic virus 35S promoter, indicating that AL1 gene expression is autoregulated. Surprisingly, a similar repression of BL1 gene expression by AL1 protein was not observed. Plasmids expressing the TGMV AL2 or AL3 proteins had no significant effect on AL1 or BL1 gene expression. In the course of these studies, we showed for the first time that the product of the AL3 ORF alone is sufficient to complement the replication-deficient phenotype of a TGMV AL3 mutant. The results are discussed in light of the multiple activities of AL1 protein.

Transactivation of geminivirus AR1 and BR1 gene expression by the viral AL2 gene product occurs at the level of transcription.

Tomato golden mosaic virus is a bipartite geminivirus whose genome is divided between two circular DNA molecules. DNA A encodes functions necessary for viral DNA replication and encapsidation, whereas DNA B provides functions needed for movement in the host. Previous studies have shown that the viral AL2 gene product transactivates expression of the coat protein gene (AR1). We have investigated the role of the AL2 protein in the regulation of B component gene expression and examined the transcriptional and post-transcriptional components of this regulation. We found that AL2 protein is required for efficient expression of both the AR1 and BR1 genes, but not the BL1 gene. A comparison of steady state transcript levels and transcript levels determined by nuclear run-on analysis showed that activation of AR1 and BR1 gene expression by the AL2 protein occurs primarily at the level of transcription. These results provide an explanation for the lack of infectivity demonstrated by AL2 mutants, and suggest that the AL2 protein interacts with the cellular transcription machinery to activate the expression of rightward viral genes.

Kinetics of tomato golden mosaic virus DNA replication and coat protein promoter activity in Nicotiana tabacum protoplasts.

We have analyzed the replication kinetics of the DNA A and DNA B genome components of the geminivirus tomato golden mosaic virus (TGMV) in protoplasts derived from Nicotiana tabacum suspension culture. In addition, the kinetics of TGMV coat protein promoter activity, as measured by expression of a beta-glucuronidase (GUS) reporter, have been examined. In our protoplast system, double-stranded DNA forms of both viral genome components appeared by 18 hr post-transfection, while single-stranded DNA accumulated to detectable levels after 18-24 hr. Expression of GUS from the TGMV coat protein promoter did not require viral DNA replication, nor was it dependent on expression of AL1, the only viral gene necessary for DNA replication. However, maximal expression was achieved following AL1-mediated replication of DNA A. GUS activity from replicating templates exceeded that from nonreplicating templates by 60- to 90-fold. Expression of the GUS reporter gene from nonreplicating viral DNA templates was similar to GUS expression from the 35S promoter of cauliflower mosaic virus in N. tabacum protoplasts.

Transactivation in a geminivirus: AL2 gene product is needed for coat protein expression.

The beta-glucuronidase (GUS) reporter gene was used to replace the coat protein gene (open reading frame AR1) of tomato golden mosaic virus (TGMV) and transiently expressed in tobacco protoplasts. While these TGMV/GUS genomes gave a high level of GUS activity, genomes which also contained a mutation in the AL2 open reading frame (TGMV/GUS/AL2-) did not express GUS. GUS activity could be restored by cotransfecting protoplasts with the TGMV/GUS/AL2- genome and a wild-type TGMV genome. Thus, the AL2 gene product transactivates expression of TGMV coat protein gene.

Genetic analysis of tomato golden mosaic virus: ORF AL2 is required for coat protein accumulation while ORF AL3 is necessary for efficient DNA replication.

Tomato golden mosaic virus (TGMV) is a geminivirus whose genome is divided between two DNA components, designated A and B. The TGMV genome contains six open reading frames (ORFs) which can encode proteins of greater than 10 kDa. We have used a protoplast transfection system to determine the effects of viral proteins, as defined by these ORFs, on the accumulation of viral DNA in infected cells. The accumulation of cost protein was also examined in leaf discs. Our results indicate that mutations in ORFs AR1 and AL2 do not affect viral double-stranded DNA (dsDNA) levels, although AR1 and AL2 mutants accumulate only small amounts of single-stranded viral DNA (ssDNA). In contrast, a large reduction in both ss- and dsDNA levels is observed when a mutation is introduced into ORF AL3. Mutations within either of the two DNA B ORFs do not affect DNA replication. The AL3, BR1, and BL1 mutants are capable of synthesizing coat protein; however, coat protein is not detected in leaf discs inoculated with AR1 or AL2 mutants. Testable models are proposed to explain the influence of AL2 protein on coat protein accumulation and to account for the stimulation of viral DNA synthesis mediated by the AL3 gene product.

Transcription map of the B genome component of tomato golden mosaic virus and comparison with A component transcripts.

In a previous study, the bipartite genome of tomato golden mosaic virus (TGMV) was shown to be transcribed into at least six polyadenylated RNAs (G. Sunter, W.E. Gardiner, and D. M. Bisaro, 1989, Virology 170, 243-250). Two of these, a 1.3-kb complementary sense and a 0.9-kb viral sense transcript, were mapped to the B genome component of this geminivirus. The results of more detailed primer extension and S1 nuclease protection experiments presented here define the limits of the single transcription unit corresponding to the 0.9-kb RNA which spans the BR1 open reading frame (ORF). The data also demonstrate that complementary sense TGMV RNAs are more complex than indicated by our earlier studies. Analysis of the 1.3-kb BL1-specific RNA indicates that it is actually a family of distinct transcripts with different start sites. Three transcripts have 5' ends that map near the common region of DNA B and all of these start sites lie upstream of the BL1 ORF. Similar analysis of the 1.6-kb complementary sense AL1 RNA indicates that a complex set of transcripts also map to the analogous region of genome component A. Four transcripts have 5' ends that map near the common region but only one of these start sites is upstream of the initiation codon for the AL1 open reading frame (ORF). None of the transcripts appear to be processed. The possible significance of multiple transcripts in these regions of the TGMV genome is discussed, and the common region-proximal transcription units of the A and B genome components are compared.

DNA sequences essential for replication of the B genome component of tomato golden mosaic virus.

The genome of the geminivirus tomato golden mosaic virus (TGMV) is divided between two DNA components, designated A and B, which differ in sequence except for a 230-nucleotide common region. The A genome component is known to encode viral functions necessary for viral DNA replication, while the B genome component specifies functions necessary for spread of the virus through the infected plant. To identify cis-acting sequences required for viral DNA replication, several mutants were constructed by the introduction of small insertions into TGMV B at selected sites within and just outside the common region. Other mutants had the common region inverted or deleted. All of the mutants were tested for their effects on infectivity and DNA replication in whole plants and leaf discs. Our results indicate that the common region in its correct orientation is required for infectivity and for replication of TGMV B. Furthermore, the conserved hairpin loop sequence located within the TGMV common region and found in all geminiviruses is necessary for DNA replication, and may be part of the viral replication origin.

Identification of tomato golden mosaic virus-specific RNAs in infected plants.

The bipartite genome of the geminivirus tomato golden mosaic virus (TGMV) contains at least six open reading frames (ORFs) with the potential to code for proteins of greater than 100 amino acids. In order to investigate the expression of these coding regions, RNA preparations from plants infected with TGMV have been examined for the presence of viral transcripts. We have identified six polyadenylated, virus-specific RNAs which correspond in size, polarity and map location to the six ORFs. Primer extension and S1 nuclease analysis of an RNA which maps to the viral coat protein gene (ORF AR1) has shown that this transcription unit begins at nucleotide 319 or 320 and ends in the vicinity of nucleotide 1090 of the TGMV A sequence, in agreement with a previous report (I.T.D. Petty, R.H.A. Coutts, and K.W. Buck, 1988, J. Gen. Virol. 69, 1359-1365). The data presented here confirm the bidirectional transcription strategy implied by the arrangement of ORFs on both strands of double-stranded TGMV DNA intermediates and lay the ground-work for further studies of viral transcription and its control.

Genetic analysis of the tomato golden mosaic virus. II. The product of the AL1 coding sequence is required for replication.

Tomato golden mosaic virus (TGMV) belongs to the geminivirus subgroup that is characterized by a split genome consisting of two single-stranded circular DNAs. The TGMV A genome component encodes the virus coat protein as well as all of the functions necessary for viral DNA replication. Analysis of the nucleotide sequence indicates that the TGMV A component has, in addition to the coat protein encoding ORF, four overlapping open reading frames (ORFs) with the potential to encode proteins of greater than 10 kD. We have investigated the functions of these putative proteins in both symptom formation and DNA replication by creating mutations in each of the ORFs. Our results show that the AL4 ORF, which is encoded within the N-terminal region of ORF AL1, is not essential for normal virus infection. In contrast, we find that disruption of the AL3 ORF results in delay and attenuation of symptom formation. We also report that the products of the AL1 and AL2 ORFs are absolutely required for symptom formation. Studies of DNA replication show that only the AL1 open reading frame is essential for viral DNA synthesis. The significance of these results for the development of vectors from the geminiviruses is discussed.

Genetic analysis of tomato golden mosaic virus: the coat protein is not required for systemic spread or symptom development.

The geminiviruses are a unique group of higher plant viruses that are composed of twin isometric particles which contain circular, single-stranded DNA. Tomato golden mosaic virus (TGMV), a whitefly-transmitted agent, belongs to the subgroup of geminiviruses whose members possess a bipartite genome. The TGMV A genome component has the capacity to encode at least four proteins. One of these is the viral coat protein, as inferred by homology with coat-protein, genes of other geminiviruses and by the observation of typical geminate particles in transgenic plants that contain inserts of TGMV A DNA. We have investigated the role of the coat protein in TGMV replication and report here that its coding sequence may be interrupted or substantially deleted without loss of infectivity. However, certain coat-protein mutants showed reproducible delays in time of symptom appearance as well as reduced symptom development, when inoculated onto transgenic Nicotiana benthamiana plants containing the TGMV B component. The most attenuated symptoms were seen with a mutant in which the coat-protein coding sequence was almost entirely deleted. The significance of these findings for the development of plant vectors from TGMV DNA is discussed.

Agrobacterium-mediated inoculation of plants with tomato golden mosaic virus DNAs.

We have adapted the "agroinfection" procedure of Grimsley and co-workers [4,5] to develop a simple, efficient, reproducible infectivity assay for the insect-transmitted, split-genome geminivirus, tomato golden mosaic virus (TGMV). Agrobacterium T-DNA vectors provide efficient delivery of both components of TGMV when used in mixed inoculation of wild-type host plants. A greater increase in infection efficiency can be obtained by Agrobacterium delivery of the TGMV A component to "permissive" transgenic plants. These "permissive" plants contain multiple tandem copies of the B component integrated into the host genome. An inoculum containing as few as 2000 Agrobacterium cells can produce 100% infection under these conditions. Further, our results show that there is a marked effect of the configuration of the TGMV A components within the T-DNA vector on time of symptom development. We have also found that transgenic plants carrying tandem copies of the A component do not complement the B component. Possible mechanisms to explain these results and the potential use of this system to further study the functions of the geminivirus components in infection are discussed.

Independent encapsidation of tomato golden mosaic virus A component DNA in transgenic plants.

Tomato golden mosaic virus (TGMV), a member of the geminivirus group, has a genome consisting of two DNA molecules designated the A and B components. Both are required for infectivity in healthy plants, although the former has been shown to replicate independently in transgenic plants containing tandem direct repeats of the A genome component. In the studies presented here, petunia plants transgenic for either both components (A×B hybrids) or the A component alone were examined for the presence of virus particles and encapsidated, single stranded viral DNA. The results of DNase protection experiments and direct observation of extracts from transgenic plants by electron microscopy indicate that single stranded TGMV DNA is in both cases packaged into paired particles identical to those obtained from virus-infected plants. DNase-treated virions isolated from A×B hybrid petunia are infectious when inoculated onto healthy Nicotiana benthamiana. Likewise, virions obtained from transgenic A petunia are infectious for plants transgenic for the B component.Our observations of TGMV replication in transgenic plants indicate that TGMV A DNA encodes all viral functions necessary for the replication and encapsidation of viral DNA. The possible role of the B component in TGMV replication is discussed.

S1-sensitive sites in the supercoiled double-stranded form of tomato golden mosaic virus DNA component B: identification of regions of potential alternative secondary structure and regulatory function.

The sensitivity of the supercoiled double-stranded form of the DNA of tomato golden mosaic virus (TGMV), a geminivirus, to the single-strand specific enzyme S1 nuclease has been demonstrated. Specific S1 cleavage sites were identified in TGMV DNA component B by cloning into the single-strand bacteriophage vector M13 mp8 and sequencing of the inserted DNA. Analysis of the DNA sequence at the sites of S1 sensitivity in TGMV DNA component B revealed several possible regions of alternative secondary structure which were clustered in an intergenic region upstream of the starts of the two major open reading frames which are in opposite orientations. This region contains putative transcriptional promoter and modulatory sequences and a possible replication origin. The extreme S1 sensitivity of the supercoiled form of TGMV DNA component A precluded its cloning under the conditions employed for selective cleavage of DNA component B.

Negatively supercoiled DNA from plants infected with a single-stranded DNA virus.

A method for isolating covalently closed circular double-stranded DNA from plants infected with the geminivirus, tomato golden mosaic virus, is described. Ethidium bromide titration showed this DNA to be negatively supercoiled with a superhelical density of -0.062. The presence of S1 nuclease-sensitive secondary structure in the supercoiled DNA was demonstrated by its conversion to the open circular and linear DNA forms on treatment with this enzyme.