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

Exploring distribution and genomic diversity of begomoviruses associated with yellow mosaic disease of legume crops from India, highlighting the dominance of mungbean yellow mosaic India virus

Yellow mosaic disease (YMD) caused by several begomoviruses is one of the major constraints of over a dozen leguminous crops worldwide, particularly in Asian and Southeast Asian countries. The present study aimed to investigate the distribution, diversity and prevalence of begomoviruses associated with YMD in leguminous hosts in five agro-climatic zones of India, to assess the extent of their geographical presence and develop location and crop-specific distribution maps. One hundred and seventy-four leguminous plant samples were tested from 32 locations in India to detect YMD-causing viruses. Additionally, publicly available data were incorporated into this study to provide a comprehensive overview of their distribution in India. This resulted in 581 reports on the DNA-A component representing 119 locations, which were also utilized to depict the distribution of YMD-causing viruses on a map of India. In this study, 117 full-length DNA-A and 103 DNA-B components were successfully characterized, representing the detected mungbean yellow mosaic India virus (MYMIV), mungbean yellow mosaic virus (MYMV), and horsegram yellow mosaic virus in the collected samples. Phylogenetic analysis of isolates of these species showed no differentiation based on location in India. Diversity indices revealed the abundance (55.9%) and dominance (0.56) of MYMIV across 119 locations. These findings hold significant implications for legume researchers, offering insights into disease prevalence and geographic distribution. Furthermore, the distribution of YMD-causing viruses in different agro-climatic zones will help researchers in developing zone-specific YMD-resistant cultivars of the legume crops and would facilitate effective disease management options.

Functional role of geminivirus encoded proteins in the host: Past and present

During plant-pathogen interaction, plant exhibits a strong defense system utilizing diverse groups of proteins to suppress the infection and subsequent establishment of the pathogen. However, in response, pathogens trigger an anti-silencing mechanism to overcome the host defense machinery. Among plant viruses, geminiviruses are the second largest virus family with a worldwide distribution and continue to be production constraints to food, feed, and fiber crops. These viruses are spread by a diverse group of insects, predominantly by whiteflies, and are characterized by a single-stranded DNA (ssDNA) genome coding for four to eight proteins that facilitate viral infection. The most effective means to managing these viruses is through an integrated disease management strategy that includes virus-resistant cultivars, vector management, and cultural practices. Dynamic changes in this virus family enable the species to manipulate their genome organization to respond to external changes in the environment. Therefore, the evolutionary nature of geminiviruses leads to new and novel approaches for developing virus-resistant cultivars and it is essential to study molecular ecology and evolution of geminiviruses. This review summarizes the multifunctionality of each geminivirus-encoded protein. These protein-based interactions trigger the abrupt changes in the host methyl cycle and signaling pathways that turn over protein normal production and impair the plant antiviral defense system. Studying these geminivirus interactions localized at cytoplasm-nucleus could reveal a more clear picture of host-pathogen relation. Data collected from this antagonistic relationship among geminivirus, vector, and its host, will provide extensive knowledge on their virulence mode and diversity with climate change.

The interaction between geminivirus pathogenicity proteins and adenosine kinase leads to increased expression of primary cytokinin-responsive genes

Pathogenicity proteins (AL2/C2) of begomo- and curtoviruses suppress silencing through inhibition of the methyl cycle, as a consequence of inhibiting adenosine kinase (ADK). ADK phosphorylates cytokinin nucleosides, helping maintain a pool of bioactive cytokinins through interconversion of free-bases, nucleosides and nucleotides. We provide evidence that inhibiting ADK affects expression of primary cytokinin-responsive genes. Specifically, we demonstrate increased activity of a primary cytokinin-responsive promoter in adk mutant Arabidopsis plants, and in response to silencing ADK expression or inhibiting ADK activity in transient assays. Similar changes in expression are observed in geminivirus infected tissue and when AL2/C2 are over-expressed. Increased cytokinin-responsive promoter activity may therefore be a consequence of an ADK/AL2/C2 interaction. Application of exogenous cytokinin increases susceptibility to geminivirus infection, characterized by a reduced mean latent period and enhanced viral replication. Thus, ADK appears to be a high value target of geminiviruses that includes increasing expression of primary cytokinin-responsive genes.

A conserved binding site within the Tomato golden mosaic virus AL-1629 promoter is necessary for expression of viral genes important for pathogenesis

We have identified a nine base pair sequence in Tomato golden mosaic virus that is required for binding of nuclear proteins from tobacco and Arabidopsis to viral DNA. The sequence is located within the promoter for a 0.7 kb complementary sense mRNA (AL-1629). Mutation of the binding site results in a two- to six-fold reduction in the accumulation of AL-1629 mRNA, leading to reduced AL2 and AL3 gene expression. Viral sequences located immediately adjacent to the core binding site appear to influence AL2 and AL3 expression, but retain some binding affinity to a soluble host protein(s). The ability of a nuclear protein(s) to bind sequences within the AL-1629 promoter correlates with efficient viral DNA replication, as mutation of these sequences results in reduced viral DNA levels. Analysis of begomo- and curtoviruses indicates extensive conservation of this binding site, which suggests a common mechanism regulating expression of two viral genes involved in replication and suppression of host defense responses.

AL1-dependent repression of transcription enhances expression of Tomato golden mosaic virus AL2 and AL3

Studies using Nicotiana benthamiana protoplasts have determined that repression of upstream transcription by AL1 protein enhances AL2 and AL3 expression in Tomato golden mosaic virus (TGMV). Mutations resulting in the inability of TGMV AL1 protein to associate with its cognate binding site, result in a decrease in both AL2 and AL3 expression. Reduced expression correlates with an increase in transcription from the AL62 start site, and decreased transcription from downstream initiation sites (AL1935 and AL1629) present within the AL1 coding region. The results demonstrate that, in a tobacco protoplast system, repression of AL62 transcription, regulated through binding of AL1 protein to sequences in the origin of replication, is required prior to AL2 and AL3 gene expression from the AL1935 and AL1629 viral transcripts. This provides a mechanism to regulate expression of AL2, which is involved in suppression of host defense responses and is required for late gene expression.

Abutilon mosaic virus DNA B component supports mechanical virus transmission, but does not counteract begomoviral phloem limitation in transgenic plants

Different Nicotiana benthamiana lines stably transformed with Abutilon mosaic virus (AbMV) dimeric DNA B were capable of systemically spreading complete bipartite AbMV genomes, following agroinoculation of DNA A alone. Constitutively expressed viral movement protein (BC1) did not induce any persistent disease phenotype, but plants developed transient morphological abnormalities such as radially symmetric leaves after kanamycin withdrawal. Systemic AbMV infection produced symptoms and virus titers indistinguishable from those in non-transgenic plants. In systemically invaded leaves, the begomovirus remained phloem-limited, whereas the plants' susceptibility to mechanical transmission of AbMV was enhanced by a factor of three to five, as compared to non-transgenic controls. Hence, DNA B-encoded movement functions can complement local movement to the phloem after mechanical transmission, but fail to support viral invasion of non-phloem cells in systemically infected organs, indicating that the phloem restriction of AbMV does not result predominantly from a lack of transport competence in mesophyll tissues.

New motifs within the NB-ARC domain of R proteins: probable mechanisms of integration of geminiviral signatures within the host species of Fabaceae family and implications in conferring disease resistance

The Gemini viruses are a group of plant infectious agents, of which mungbean yellow mosaic India virus (MYMIV) belongs to the bipartite subgroup of Gemini virus and causes serious yield penalty in the leguminous group of plants. In this investigation we have isolated two resistant gene homologues (RGHs; AY301990, AY301991) from two MYMIV-resistant lines of Vigna mungo and V. radiata that have high homology with a MYMIV-resistant linked marker, VMYR1 (AY 297425). These three resistance factors also have similarity with 221 reported R gene/RGH sequences in the NB-ARC domain of the family Fabaceae. NB-ARC domain is an ancient, highly conserved domain of a class of plant disease resistance genes/proteins. Out of 221 in silico translated protein sequences, multialignment of 188 sequences without large insertion or truncation, unlike that of the rest 33, illustrated presence of both TIR and non-TIR subfamilies of NB-ARC domain. A critical analysis of these sequences revealed eight new conserved motifs, in addition to the reported conserved motifs within the NB-ARC domains, which are hitherto not reported. Further analysis of these eight motifs with the aid of PRINTS and PROSITE databases revealed signatures of geminiviral coat protein (GVCP) within the favoured allele, R gene or RGHs. GVCP signatures are absent within the NB-ARC domain of three species of Medicago, which are non-host to Gemini virus. These observations tempted us to predict probable mechanism of integration of GVCP within the plant R gene/RGHs and their implications in conferring geminiviral disease resistance to the host plants. Our conjecture is that these signatures were integrated during plant pathogen interaction and are being maintained within this conserved domain through active selection of the favoured allele. We comprehensively addressed the biological significance of GVCP signatures, which probably provides additional defense against Gemini viruses through degradation of homologous transcript of the virus.

Distinct viral sequence elements are necessary for expression of Tomato golden mosaic virus complementary sense transcripts that direct AL2 and AL3 gene expression

Transient expression studies using Nicotiana benthamiana protoplasts and plants have identified sequences important for transcription of complementary sense RNAs derived from Tomato golden mosaic virus (TGMV) DNA component A that direct expression of AL2 and AL3. Transcription of two complementary sense RNAs, initiating at nucleotides 1,935 (AL1935) and 1,629 (AL1629), is directed by unique sequences located upstream of each transcription initiation site. One element is located between 28 and 124 nucleotides (nt) upstream of the AL1935 transcription start site, which differs from a second element located 150 nt downstream, between 129 and 184 nt upstream of the AL1629 transcription start site. Transcription initiation at nucleotide 1,935 is lower than that at nucleotide 1,629 as determined by run-on transcription assays, and the resulting transcript is only capable of expressing AL3. The transcript initiating at nucleotide 1,629 is capable of directing expression of both AL2 and AL3, although expression of AL3 is up to fourfold greater than that for AL2. Nuclear factors purified from tobacco suspension cells bind to sequences upstream of both AL1935 and AL1629, correlating with the ability of these sequences to direct gene expression. Thus, in tobacco, regulatory sequences direct transcription of two unique TGMV messenger RNAs that differentially express AL2 and AL3.

Recombination, pseudorecombination and synergism of geminiviruses are determinant keys to the epidemic of severe cassava mosaic disease in Uganda

The molecular variability of cassava geminiviruses occurring in Uganda was investigated in this study. Infected cassava plants and whiteflies were collected from cassava plantings in different geographical areas of the country and PCR was used for molecular characterization of the viruses. Two complete sequences of DNA-A and -B from African cassava mosaic virus (ACMV), two DNA-A sequences from East African cassava mosaic virus (EACMV), two DNA-B sequences of EACMV and the partial DNA-A nucleotide sequence of a new virus strain isolated in Uganda, EACMV-UG3, are reported here. Analysis of naturally infected cassava plants showed various assortments of DNA-A and DNA-B of the Ugandan viruses, suggesting the occurrence of natural inter- and intraspecies pseudorecombinations and a pattern of cassava mosaic disease (CMD) more complex than previously reported. EACMV-UG2 DNA-A, which contains a recombinant fragment between ACMV and EACMV-UG1 in the coat protein gene that resembles virus from Tanzania, was widespread in the country and always associated with EACMV-UG3 DNA-B, which probably resulted from another natural recombination event. Mixed infections of ACMV-UG and EACMV-UG in cassava and whiteflies were detected in most of the regions where both viruses occurred. These mixed-infected samples always showed extremely severe CMD symptoms, suggesting a synergistic interaction between ACMV-UG and EACMV-UG2. The first demonstration is provided of infectivity of EACMV clones to cassava, proving conclusively that the pseudorecombinant EACMV-UG2 DNA-A+EACMV-UG3 DNA-B is a causal agent of CMD in Uganda.

Chino del tomate virus:Relationships to Other Begomoviruses and Identification of A-Component Variants that Affect Symptom Expression

Phylogenetic and distance analyses place Chino del tomate virus (CdTV) in the New World clade of begomoviruses and indicate that CdTV and Tomato leaf crumple virus (TLCrV) are closely related strains of the same virus. One cloned CdTV A component (pCdTV-H6), when inoculated to tomato with the B component (pCdTV-B52), produced mild symptoms and low DNA titers. Another cloned CdTV A component (pCdTV-H8), when coinoculated to tomato with the B component, produced moderate leaf curling and veinal chlorosis similar to that of TLCrV. Coinoculation of both CdTV A components and the B component to tomato produced wild-type chino del tomate (CdT) disease symptoms consisting of severe leaf curling, veinal and interveinal chlorosis, and stunting. The two CdTV A components were nearly identical, except at nucleotide positions 1,722 and 2,324. The polymorphism at nucleotide 1,722 resulted in a change at Rep amino acid 261. The second polymorphism at nucleotide 2,324 resulted in changes at Rep amino acid 60 and AC4 amino acid 10. Two chimeric A components constructed by reciprocal exchange of a fragment bearing the polymorphic site at nucleotide 1,722 were evaluated for symptom phenotype. One chimeric A component (pCdTV-H86) produced wild-type CdT symptoms when coinoculated to tomato with the B component. The reciprocal chimeric A component (pCdTV-H68), when coin-oculated to tomato with the B component, also produced severe leaf curling, veinal chlorosis, and stunting. However, pCdTV-H68 induced less obvious interveinal chlorosis than wild-type or pCdTV-H86. Examination of A component genotypes recovered from tomato coinoculated with pCdTV-H6 and pCdTV-H8 indicated that recombination occurred to produce a genotype identical to pCdTV-H86. These results indicate that subtle genotypic variation has significant effects on symptom expression and may explain phenotypic differences observed among isolates and cloned DNAs of CdTV and TLCrV.

Chromosome condensation induced by geminivirus infection of mature plant cells

Tomato golden mosaic virus (TGMV) is a geminivirus that replicates its single-stranded DNA genome through double-stranded DNA intermediates in nuclei of differentiated plant cells using host replication machinery. We analyzed the distribution of viral and plant DNA in nuclei of infected leaves using fluorescence in situ hybridization (FISH). TGMV-infected nuclei showed up to a sixfold increase in total volume and displayed a variety of viral DNA accumulation patterns. The most striking viral DNA patterns were bright, discrete intranuclear compartments, but diffuse nuclear localization was also observed. Quantitative and spatial measurements of high resolution 3-dimensional image data revealed that these compartments accounted for 1-18% of the total nuclear volume or 2-45% of the total nuclear FISH signals. In contrast, plant DNA was concentrated around the nuclear periphery. In a significant number of nuclei, the peripheral chromatin was organized as condensed prophase-like fibers. A combination of FISH analysis and indirect immunofluorescence with viral coat protein antibodies revealed that TGMV virions are associated with the viral DNA compartments. However, the coat protein antibodies failed to cross react with some large viral DNA inclusions, suggesting that encapsidation may occur after significant viral DNA accumulation. Infection by a TGMV mutant with a defective coat protein open reading frame resulted in fewer and smaller viral DNA-containing compartments. Nevertheless, nuclei infected with the mutant virus increased in size and in some cases showed chromosome condensation. Together, these results established that geminivirus infection alters nuclear architecture and can induce plant chromatin condensation characteristic of cells arrested in early mitosis.

Distribution and diversity of geminiviruses in trinidad and tobago

ABSTRACT Seven crop and eight weed species from 12 agricultural locations in Trinidad and Tobago were assayed for the presence of whitefly-transmitted geminiviruses (WTGs) by using dot blot hybridization and polymerase chain reaction (PCR) amplification of the N-terminal coat protein sequence with degenerate primers. The amplified fragments were cloned and analyzed by restriction enzyme digestion to determine fragment length polymorphism among the cloned fragments. Representative clones were then sequenced and subjected to phylogenetic analysis to determine the sequence similarity to known WTGs. WTGs were found in every location sampled and in 10 of the 15 species investigated: Lycopersicon esculentum(tomato), Capsicum annuum (pepper), Capsicum frutescens (sweet pepper), Abelmoschus esculentus (okra), Phaseolus vulgaris (beans), Alternanthera tenella, Desmodium frutescens, Euphorbia heterophylla, Malva alceifolia, and Sida acuta. The geminiviruses infecting these plants were closely related to potato yellow mosaic virus from Venezuela (PYMV-VE) and tomato leaf curl virus from Panama (ToLCV-PA). However, in pepper, sweet pepper, okra, Alternanthera tenella, Euphorbia heterophylla, Des-modium frutescens, and in one sample of tomato, a PYMV-VE-related virus was found in mixed infections with a virus related to pepper huasteco virus. Full-length infectious DNA-A and DNA-B of a tomato-infecting geminivirus from Trinidad and Tobago were cloned and sequenced. DNA-A appears to be a recombinant derived from PYMV-VE or ToLCV-PA, and Sida golden mosaic from Honduras. The implications of these findings in the control of WTGs are discussed.

Mutational analysis of the monopartite geminivirus beet curly top virus

Mutants of the monopartite geminivirus beet curly top virus have been screened for infectivity and symptom development in Nicotiana benthamiana and Beta vulgaris, for replication competence in N. benthamiana leaf discs, and for transmission by the leafhopper Circulifer tenellus. Disruption of open reading frame (ORF) V2 by the introduction of a termination codon resulted in symptomless infection of N. benthamiana associated with low levels of virus and reduced single-stranded (ss) DNA and prevented systemic infection of B. vulgaris. Reduced levels of ssDNA were produced by the mutant in N. benthamiana leaf discs, suggesting that V2 affects the synthesis or accumulation of this viral DNA form. Mutants in which ORF C2 had been truncated by the introduction of termination codons or by frame-shifting remained highly infectious and induced severe symptoms in both N. benthamiana and B. vulgaris. Similarly, a mutant containing a termination codon within ORF C3 was highly infectious and induced severe symptoms in N. benthamiana although infectivity in B. vulgaris was greatly reduced, symptoms were extremely mild, and virus levels were low. A synergistic effect of a double mutation in ORFs C2 and C3, manifested by the inability of mutants to systemically infect N. benthamiana and the production of reduced amounts of ssDNA in N. benthamiana leaf discs, suggests that both ORFs are functional in this host. A mutant containing a termination codon within the 5' terminus of ORF C4 produced severe symptoms in both N. benthamiana and B. vulgaris resembling those induced by wild-type virus. Comparison with the phenotypes of previously characterized ORF C4 mutants suggests that a conserved core sequence of this ORF is an important symptom determinant. ORF C2, C3, and C4 mutants produced virus particles and were transmitted by C. tenellus, eliminating agroinoculation as a contributory factor to the mutant phenotypes. Our results are compared with those derived from mutagenesis studies on related bipartite geminiviruses.

Inhibition of African cassava mosaic virus systemic infection by a movement protein from the related geminivirus tomato golden mosaic virus

Plant viruses encode proteins that mediate their movement through the host plant leading to the establishment of a systemic infection. We have analyzed the effect of tomato golden mosaic virus (TGMV) genes BL1 and BR1, which are thought to be involved in the process of virus movement, on the infectivity of African cassava mosaic virus (ACMV) in Nicotiana benthamiana. Recombinant genomes were constructed by replacing the ACMV coat protein coding sequence with those of either BL1 or BR1. Replication of recombinants containing BL1 and BR1 coding sequences in the sense orientation with respect to the coat protein promoter was detected in the inoculated leaves only when the constructs were co-inoculated, suggesting that both genes are being expressed and act in a cooperative manner. Co-inoculated recombinants induced localized symptoms on inoculated leaves but did not spread systematically, either because of a defect in BL1 and/or BR1 expression or due to the inability of the TGMV gene products to functionally complement their ACMV counterparts. Systemic spread of ACMV was inhibited when the recombinant containing the BL1 coding sequence in the sense, but not in the antisense, orientation was co-inoculated with ACMV DNA B. Disruption of the BL1 coding sequence by a frameshift mutation restored the ability of the recombinant to spread systemically, suggesting that the gene product is responsible for the inhibitory effect. The inhibitory phenotype was mimicked by a chimera containing amino-terminal sequences of TGMV BL1 and carboxy-terminal sequences of its ACMV homologue, BC1. The chimera has characteristics of a dominant negative mutant. We suggest that dominant negative mutants of virus movement genes may provide a novel source for virus resistance 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.

Determinants of tomato golden mosaic virus symptom development located on DNA B

Infectious clones have been constructed from two strains of the bipartite geminivirus tomato golden mosaic virus. The common strain and the yellow vein strain show marked phenotypic differences in Nicotiana benthamiana which are reproduced following infection with the cloned viral genomes. Pseudorecombinants between the two strains, produced by exchange of genome components (DNAs A and B), established that the difference in symptoms in several species of the Solanaceae is determined by DNA B. Recombinants produced in vitro between the DNA B components showed that determinants of symptom development map to the common region and gene BL1. DNA B is known to carry functions necessary for spread of viral DNA through the host plant. Our results emphasize the link between symptom type and virus spread.

Tomato yellow leaf curl virus: a whitefly-transmitted geminivirus with a single genomic component

The genome of the tomato yellow leaf curl virus (TYLCV), a Bemisia tabaci-transmitted geminivirus, was cloned. All clones obtained were of one genomic molecule, analogous to DNA A of African cassava mosaic virus. Nucleotide sequence analysis of the TYLCV genome showed that it comprises 2787 nucleotides, encoding six open reading frames, two on the virion strand and four on the complementary strand. All of them have counterparts in other geminiviruses. Dimeric copies of the cloned viral genome were introduced into tomato plants by agroinoculation. Severe yellow leaf curl disease symptoms developed in all of them. Effective whitefly-mediated transmission of the virus from agroinoculated plants to test plants demonstrated that the cloned molecule carries all the information needed for virus replication, systemic infection, and transfer by whiteflies. Restriction and hybridization analyses of viral DNA forms in infected plants and viruliferous whiteflies did not support the presupposed existence of a second genomic component. This is the first report of a whitefly-transmitted geminivirus that possesses a single genomic molecule.

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.

Techniques in plant molecular biology--progress and problems

Progress in plant molecular biology has been dependent on efficient methods of introducing foreign DNA into plant cells. Gene transfer into plant cells can be achieved by either direct uptake of DNA or the natural process of gene transfer carried out by the soil bacterium Agrobacterium. Versatile gene-transfer vectors have been developed for use with Agrobacterium and more recently vectors based on the genomes of plant viruses have become available. Using this technology the expression of foreign DNA, the functional analysis of plant DNA sequences, the investigation of the mechanism of viral DNA replication and cell to cell spread, as well as the study of transposition, can be carried out. In addition, the versatility of the gene-transfer vectors is such that they may be used to isolate genes not amenable to isolation using conventional protocols. This review concentrates on these aspects of plant molecular biology and discusses the limitations of the experimental systems that are currently available.

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.

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.

Geminivirus genes and vectors

The geminiviruses are very small plant viruses with circular single-stranded DNA genomes. Recent advances have identified genes involved in replication, spread of virus or DNA in the plant, and insect transmission. Gene replacement experiments suggest that useful plant gene expression vectors can be constructed from these viruses.

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.