Segregation of cauliflower mosaic virus symptom genetic determinants

Joining the Crowd: Integrating Plant Virus Proteins into the Larger World of Pathogen Effectors

The first bacterial and viral avirulence ( avr) genes were cloned in 1984. Although virus and bacterial avr genes were physically isolated in the same year, the questions associated with their characterization after discovery were very different, and these differences had a profound influence on the narrative of host-pathogen interactions for the past 30 years. Bacterial avr proteins were subsequently shown to suppress host defenses, leading to their reclassification as effectors, whereas research on viral avr proteins centered on their role in the viral infection cycle rather than their effect on host defenses. Recent studies that focus on the multifunctional nature of plant virus proteins have shown that some virus proteins are capable of suppression of the same host defenses as bacterial effectors. This is exemplified by the P6 protein of Cauliflower mosaic virus (CaMV), a multifunctional plant virus protein that facilitates several steps in the infection, including modulation of host defenses. This review highlights the modular structure and multifunctional nature of CaMV P6 and illustrates its similarities to other, well-established pathogen effectors.

Setting Up Shop: The Formation and Function of the Viral Factories of Cauliflower mosaic virus

Similar to cells, viruses often compartmentalize specific functions such as genome replication or particle assembly. Viral compartments may contain host organelle membranes or they may be mainly composed of viral proteins. These compartments are often termed: inclusion bodies (IBs), viroplasms or viral factories. The same virus may form more than one type of IB, each with different functions, as illustrated by the plant pararetrovirus, Cauliflower mosaic virus (CaMV). CaMV forms two distinct types of IBs in infected plant cells, those composed mainly of the viral proteins P2 (which are responsible for transmission of CaMV by insect vectors) and P6 (required for viral intra-and inter-cellular infection), respectively. P6 IBs are the major focus of this review. Much of our understanding of the formation and function of P6 IBs comes from the analyses of their major protein component, P6. Over time, the interactions and functions of P6 have been gradually elucidated. Coupled with new technologies, such as fluorescence microscopy with fluorophore-tagged viral proteins, these data complement earlier work and provide a clearer picture of P6 IB formation. As the activities and interactions of the viral proteins have gradually been determined, the functions of P6 IBs have become clearer. This review integrates the current state of knowledge on the formation and function of P6 IBs to produce a coherent model for the activities mediated by these sophisticated virus-manufacturing machines.

Mapping genetic determinants of viral traits with FST and quantitative trait locus (QTL) approaches

The genetic determinism of viral traits can generally be dissected using either forward or reverse genetics because the clonal reproduction of viruses does not require the use of approaches based on laboratory crosses. Nevertheless, we hypothesized that recombinant viruses could be analyzed as sexually reproducing organisms, using either a quantitative trait loci (QTL) approach or a locus-by-locus fixation index (F_ST). Locus-by-locus F_ST analysis, and four different regressions and interval mapping algorithms of QTL analysis were applied to a phenotypic and genotypic dataset previously obtained from 47 artificial recombinant genomes generated between two begomovirus species. Both approaches assigned the determinant of within-host accumulation—previously identified using standard virology approaches—to a region including the 5׳ end of the replication-associated protein (Rep) gene and the upstream intergenic region. This study provides a proof of principle that QTL and population genetics tools can be extended to characterize the genetic determinants of viral traits.

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F_ST and QTL approaches were used to map the genetic determinants of viral traits.

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Genetic determinants were detected using 47 begomovirus recombinant genomes.

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Genetic determinants of begomovirus infectivity and accumulation were identified.

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Proof of principles that F_ST and QTL can be used in virology.

Identification of the domains of cauliflower mosaic virus protein P6 responsible for suppression of RNA silencing and salicylic acid signalling

Cauliflower mosaic virus (CaMV) encodes a 520 aa polypeptide, P6, which participates in several essential activities in the virus life cycle including suppressing RNA silencing and salicylic acid-responsive defence signalling. We infected Arabidopsis with CaMV mutants containing short in-frame deletions within the P6 ORF. A deletion in the distal end of domain D-I (the N-terminal 112 aa) of P6 did not affect virus replication but compromised symptom development and curtailed the ability to restore GFP fluorescence in a GFP-silenced transgenic Arabidopsis line. A deletion in the minimum transactivator domain was defective in virus replication but retained the capacity to suppress RNA silencing locally. Symptom expression in CaMV-infected plants is apparently linked to the ability to suppress RNA silencing. When transiently co-expressed with tomato bushy stunt virus P19, an elicitor of programmed cell death in Nicotiana tabacum, WT P6 suppressed the hypersensitive response, but three mutants, two with deletions within the distal end of domain D-I and one involving the N-terminal nuclear export signal (NES), were unable to do so. Deleting the N-terminal 20 aa also abolished the suppression of pathogen-associated molecular pattern-dependent PR1a expression following agroinfiltration. However, the two other deletions in domain D-I retained this activity, evidence that the mechanisms underlying these functions are not identical. The D-I domain of P6 when expressed alone failed to suppress either cell death or PR1a expression and is therefore necessary but not sufficient for all three defence suppression activities. Consequently, concerns about the biosafety of genetically modified crops carrying truncated ORFVI sequences appear unfounded.

Excision and episomal replication of cauliflower mosaic virus integrated into a plant genome

Transgenic Arabidopsis (Arabidopsis thaliana) plants containing a monomeric copy of the cauliflower mosaic virus (CaMV) genome exhibited the generation of infectious, episomally replicating virus. The circular viral genome had been split within the nonessential gene II for integration into the Arabidopsis genome by Agrobacterium tumefaciens-mediated transformation. Transgenic plants were assessed for episomal infections at flowering, seed set, and/or senescence. The infections were confirmed by western blot for the CaMV P6 and P4 proteins, electron microscopy for the presence of icosahedral virions, and through polymerase chain reaction across the recombination junction. By the end of the test period, a majority of the transgenic Arabidopsis plants had developed episomal infections. The episomal form of the virus was infectious to nontransgenic plants, indicating that no essential functions were lost after release from the Arabidopsis chromosome. An analysis of the viral genomes recovered from either transgenic Arabidopsis or nontransgenic turnip (Brassica rapa var rapa) revealed that the viruses contained deletions within gene II, and in some cases, the deletions extended to the beginning of gene III. In addition, many of the progeny viruses contained small regions of nonviral sequence derived from the flanking transformation vector. The nature of the nucleotide sequences at the recombination junctions in the circular progeny virus indicated that most were generated by nonhomologous recombination during the excision event. The release of the CaMV viral genomes from an integrated copy was not dependent upon the application of environmental stresses but occurred with greater frequency with either age or the late stages of plant maturation.

Distinct cavemoviruses interact synergistically with sweet potato chlorotic stunt virus (genus Crinivirus) in cultivated sweet potato

Two serologically unrelated sweet potato viruses causing symptoms of vein clearing in the indicator plant Ipomoea setosa were isolated and their genomes have been sequenced. They are associated with symptomless infections in sweet potato but distinct vein-clearing symptoms and higher virus titres were observed when these viruses co-infected with sweet potato chlorotic stunt virus (SPCSV), a virus that is distributed worldwide and is a mediator of severe virus diseases in this crop. Molecular characterization and phylogenetic analysis revealed an overall nucleotide identity of 47.6 % and an arrangement of the movement protein and coat protein domains characteristic of members of the genus Cavemovirus, in the family Caulimoviridae. We detected both cavemoviruses in cultivated sweet potato from East Africa, Central America and the Caribbean islands, but not in samples from South America. One of the viruses characterized showed a similar genome organization as, and formed a phylogenetic sublineage with, tobacco vein clearing virus (TVCV), giving further support to the previously suggested separation of TVCV, and related viral sequences, into a new caulimovirid genus. Given their geographical distribution and previous reports of similar but yet unidentified viruses, sweet potato cavemoviruses may co-occur with SPCSV more often than previously thought and they could therefore contribute to the extensive yield losses and cultivar decline caused by mixed viral infections in sweet potato.

The cauliflower mosaic virus protein P6 forms motile inclusions that traffic along actin microfilaments and stabilize microtubules

The gene VI product (P6) of Cauliflower mosaic virus (CaMV) is a multifunctional protein known to be a major component of cytoplasmic inclusion bodies formed during CaMV infection. Although these inclusions are known to contain virions and are thought to be sites of translation from the CaMV 35S polycistronic RNA intermediate, the precise role of these bodies in the CaMV infection cycle remains unclear. Here, we examine the functionality and intracellular location of a fusion between P6 and GFP (P6-GFP). We initially show that the ability of P6-GFP to transactivate translation is comparable to unmodified P6. Consequently, our work has direct application for the large body of literature in which P6 has been expressed ectopically and its functions characterized. We subsequently found that P6-GFP forms highly motile cytoplasmic inclusion bodies and revealed through fluorescence colocalization studies that these P6-GFP bodies associate with the actin/endoplasmic reticulum network as well as microtubules. We demonstrate that while P6-GFP inclusions traffic along microfilaments, those associated with microtubules appear stationary. Additionally, inhibitor studies reveal that the intracellular movement of P6-GFP inclusions is sensitive to the actin inhibitor, latrunculin B, which also inhibits the formation of local lesions by CaMV in Nicotiana edwardsonii leaves. The motility of P6 along microfilaments represents an entirely new property for this protein, and these results imply a role for P6 in intracellular and cell-to-cell movement of CaMV.

Cauliflower mosaic virus gene VI product N-terminus contains regions involved in resistance-breakage, self-association and interactions with movement protein

Cauliflower mosaic virus (CaMV) gene VI encodes a multifunctional protein (P6) involved in the translation of viral RNA, the formation of inclusion bodies, and the determination of host range. Arabidopsis thaliana ecotype Tsu-0 prevents the systemic spread of most CaMV isolates, including CM1841. However, CaMV isolate W260 overcomes this resistance. In this paper, the N-terminal 110 amino acids of P6 (termed D1) were identified as the resistance-breaking region. D1 also bound full-length P6. Furthermore, binding of W260 D1 to P6 induced higher beta-galactosidase activity and better leucine-independent growth in the yeast two-hybrid system than its CM1841 counterpart. Thus, W260 may evade Tsu-0 resistance by mediating P6 self-association in a manner different from that of CM1841. Because Tsu-0 resistance prevents virus movement, interaction of P6 with P1 (CaMV movement protein) was investigated. Both yeast two-hybrid analyses and maltose-binding protein pull-down experiments show that P6 interacts with P1. Although neither half of P1 interacts with P6, the N-terminus of P6 binds P1. Interestingly, D1 by itself does not interact with P1, indicating that different portions of the P6 N-terminus are involved in different activities. The P1-P6 interactions suggest a role for P6 in virus transport, possibly by regulating P1 tubule formation or the assembly of movement complexes.

Cauliflower mosaic virus protein P6 is a suppressor of RNA silencing

We infected a transgenic Arabidopsis line (GxA), containing an amplicon-silenced 35S : : GFP transgene, with cauliflower mosaic virus (CaMV), a plant pararetrovirus with a DNA genome. Systemically infected leaves showed strong GFP fluorescence and amplicon transcripts were detectable in Northern blots, indicating that silencing of GFP had been suppressed during CaMV-infection. Transgenic Arabidopsis lines expressing CaMV protein P6, the major genetic determinant of symptom severity, were crossed with GxA. Progeny showed strong GFP fluorescence throughout and amplicon transcripts were detectable in Northern blots, indicating that P6 was suppressing local and systemic silencing. However, levels of 21 nt siRNAs derived from the GFP transgene were not reduced. In CaMV-infected plants, the P6 transgene did not reduce levels of CaMV leader-derived 21 and 24 nt siRNAs relative to levels of CaMV 35S RNA. These results demonstrate that CaMV can efficiently suppress silencing of a GFP transgene, and that P6 acts as a silencing suppressor.

The plant gene CCD1 selectively blocks cell death during the hypersensitive response to Cauliflower mosaic virus infection

The P6 protein of Cauliflower mosaic virus (CaMV) W260 elicits a hypersensitive response (HR) on inoculated leaves of Nicotiana edwardsonii. This defense response, common to many plant pathogens, has two key characteristics, cell death within the initially infected tissues and restriction of the pathogen to this area. We present evidence that a plant gene designated CCD1, originally identified in N. bigelovii, can selectively block the cell death pathway during HR, whereas the resistance pathway against W260 remains intact. Suppression of cell death was evident not only macroscopically but also microscopically. The suppression of HR-mediated cell death was specific to CaMV, as Tobacco mosaic virus was able to elicit HR in the plants that contained CCD1. CCD1 also blocks the development of a systemic cell death symptom induced specifically by the P6 protein of W260 in N. clevelandii. Introgression of CCD1 from N. bigelovii into N. clevelandii blocked the development of systemic cell death in response to W260 infection but could not prevent systemic cell death induced by Tomato bushy stunt virus. Thus, CCD1 blocks both local and systemic cell death induced by P6 of W260 but does not act as a general suppressor of cell death induced by other plant viruses. Furthermore, experiments with CCD1 provide further evidence that cell death could be uncoupled from resistance in the HR of Nicotiana edwardsonii to CaMV W260.

Arabidopsis mutants that suppress the phenotype induced by transgene-mediated expression of cauliflower mosaic virus (CaMV) gene VI are less susceptible to CaMV-infection and show reduced ethylene sensitivity

Protein P6 is the main symptom determinant of cauliflower mosaic virus (CaMV), and transgene-mediated expression in Arabidopsis induces a symptom-like phenotype in the absence of infection. Seeds of a P6-transgenic line, A7, were mutagenized by gamma-irradiation and M2 seedlings were screened for mutants that suppressed the phenotype of chlorosis and stunting. We identified four mutants that were larger and less chlorotic than the A7 parent but which contained an intact and transcriptionally active transgene. The two mutants with the strongest suppression phenotype, were recessive and allelic. The transgene was eliminated by back-crossing with wild-type Arabidopsis. In progeny lines that were homozygous for the putative suppressor mutation the proportion of plants becoming infected following inoculation with CaMV was 40% that of wild-type, although in plants that did become infected, levels of virus DNA in mutants and wild-type did not differ significantly. Symptoms in the mutants were milder and delayed although this was somewhat dependent on the virus isolate. This phenotype was inherited stably. Both mutant alleles showed a partially ethylene-insensitive phenotype in an ethylene triple response assay. P6-transgenic plants were also almost completely insensitive to ethylene in the triple response assay. We suggest that the chlorosis and stunting in P6-transgenic and CaMV-infected plants are dependent on interactions between P6 and components involved in ethylene signalling, and that the suppressor gene product may function to augment these interactions.

Differential induction of symptoms in Arabidopsis by P6 of Cauliflower mosaic virus

The gene VI protein (P6) of Cauliflower mosaic virus (CaMV) functions as a virulence factor in crucifers by eliciting chlorotic symptoms in infected plants. The ability to induce chlorosis has been associated previously with P6 through gene-swapping experiments between strains and through the development of transgenic plants that express P6. The primary role that has been identified for P6 in the CaMV infection cycle is to modify the host translation machinery to facilitate the translation of the polycistronic CaMV 35S RNA. This function for P6 has been designated as the translational transactivator (TAV) function. In the present study, we have characterized an unusual variant of P6, derived from CaMV strain D4, that does not induce chlorosis upon transformation into Arabidopsis thaliana. The level of D4 P6 produced in transgenic Arabidopsis line D4-2 was comparable to the amount found in transgenic plants homozygous for W260 and CM1841 P6, two versions of P6 that induce strong chlorotic symptoms and stunting in Arabidopsis. A complementation assay proved that P6 expressed in the D4-2 line was functional, as it could support the systemic infection of a CM1841 mutant that contained a lethal frame-shift mutation within gene VI. This complementation assay allowed us to separately assess the contribution of CM1841 gene VI to symptom development versus the contribution of other CM1841 genes. Furthermore, a previous study had shown that the TAV activity of D4 P6 was comparable to that of W260 P6. That comparative analysis of TAV function, coupled with the characterization of the D4-2 transgenic line in the present paper, indicates that the TAV function of P6 may play only a minor role in the development of chlorotic symptoms.

Multiple domains within the Cauliflower mosaic virus gene VI product interact with the full-length protein

The Cauliflower mosaic virus (CaMV) gene VI product (P6) is a multifunctional protein essential for viral propagation. It is likely that at least some of these functions require P6 self-association. The work described here was performed to confirm that P6 self-associates and to identify domains involved in this interaction. Yeast two-hybrid analyses indicated that full-length P6 self-associates and that this interaction is specific. Additional analyses indicated that at least four independent domains bind to full-length P6. When a central domain (termed domain D3) was removed, these interactions were abolished. However, this deleted P6 was able to bind to the full-length wild-type protein and to isolated domain D3. Viruses lacking domain D3 were incapable of producing a systemic infection. Isolated domain D3 was capable of binding to at least two of the other domains but was unable to self-associate. This suggests that domain D3 facilitates P6 self-association by binding to the other domains but not itself. The presence of multiple domains involved in P6 self-association may help explain the ability of this protein to form the intracellular inclusions characteristic of caulimoviruses.

Third position codon composition suggests two classes of genes within the Cauliflower mosaic virus genome

The translation of viral mRNAs by host ribosomes is essential for infection. Hence, codon usage of virus genes may influence efficiency of infection. In addition, composition of nucleotides in the third position within codons of genes can reflect evolutionary relationships. In this study, third position codon composition was examined for the seven genes of eight Cauliflower mosaic virus isolates. Genes IV-VII had similar codon composition values and were termed Class 1 genes. Genes I-III possessed corresponding codon composition values and were termed Class 2 genes. The codon composition values of Class 1 and genes differed significantly. Neither Class 1 nor Class 2 genes had codon composition values identical to that of the host plant, Arabidopsis thaliana. However, Class 1 genes possessed codon composition values closer to those of the host than Class 2 genes. Examination of the genomes of three Rous sarcoma virus isolates indicated that codon composition values were similar for the gag, pol, and env genes but these genes differed significantly from the src genes. Since codon composition values for Rous sarcoma virus distinguished a "foreign" gene from the rest of the viral genome, it is possible that the Cauliflower mosaic virus genome is composed of genes from two different sources. Others have suggested that Cauliflower mosaic virus evolved in this manner and our data provide support for this hypothesis.

Mutations that delay flowering in Arabidopsis de-couple symptom response from cauliflower mosaic virus accumulation during infection

summary The development of disease symptoms in plants infected with a compatible virus involves complex signalling interactions between host and viral gene products. Photoperiod is an important influence on the transition from vegetative growth to flowering. Symptoms in wild-type Arabidopsis plants grown under long days were much less severe than in plants grown under short days, although under long days, the levels of replicating virus were 1.5-1.8 times greater than in plants grown in short days. We tested the effects on response to CaMV infection of mutations at two of the loci that control the transition from vegetative growth to flowering, FCA and GI. In long days, CaMV-infected fca-1 mutants and strong gi alleles developed much more severe symptoms than wild-type. Despite the increased symptom severity, levels and distribution of replicating CaMV in fca-1 and gi mutants were similar to those in wild-type. In short days, both mutants and wild-type grew vegetatively. Virus accumulation and symptom developments in fca-1 were similar to the wild-type, but in strong gi alleles, symptom progression in apical leaves was very delayed, although virus accumulation was similar to the wild-type controls. The developmental state of the plants influences the symptom response; however, it does not appear to do so by directly effecting overall virus titre or distribution. The altered symptom response of gi mutants in short days suggests an additional role for GI. These mutants provide compelling evidence for the existence of specific pathways for disease signalling.

A comparative analysis of the avirulence and translational transactivator functions of gene VI of Cauliflower mosaic virus

The primary function associated at present with the gene VI product of Cauliflower mosaic virus (CaMV) is that of a translational transactivator (TAV). In this capacity, it alters the host translational machinery to allow reinitiation of translation of other CaMV genes on the polycistronic 35S RNA of CaMV. In addition, the gene VI protein can elicit a specific type of plant defense response called the hypersensitive response (HR) in Nicotiana edwardsonii. In this study, we have adapted the agroinfiltration technique to compare the sequences of CaMV gene VI required for TAV function and elicitation of HR. To measure the activity of the TAV, we coagroinfiltrated gene VI of CaMV strain W260 with a bicistronic GUS reporter plasmid. TAV function could be assayed 4 days postinfiltration, before the onset of HR in N. edwardsonii. Through the use of the TAV and HR assays, we could show that the TAV functions of gene VI of CaMV strains W260 and D4 were equivalent, but only W260 gene VI elicited HR. A mutational analysis of W260 gene VI showed that the structural requirements for elicitation of HR were much more stringent than those for TAV function. Small deletions from either the 5' or 3' end of W260 gene VI abolished its ability to elicit HR, although the TAV function was retained in the mutant. The TAV function could also tolerate a small insertion within gene VI; this insertion abolished the elicitor function. This study provides direct evidence that the TAV function of gene VI is separate from its role as an elicitor of HR.

The 5' Third of Cauliflower mosaic virus Gene VI Conditions Resistance Breakage in Arabidopsis Ecotype Tsu-0

ABSTRACT Arabidopsis thaliana ecotypes vary in their responses to viruses. In this study, we analyzed the variation in response of A. thaliana ecotype Tsu-0 to Cauliflower mosaic virus (CaMV). This ecotype was previously reported to be resistant to two CaMV isolates (CM1841 and CM4-184), but susceptible to W260. In this study, we show that Tsu-0 is resistant to four additional CaMV isolates. CaMV propagated within the rosette leaves of Tsu-0 plants, but did not appear to spread systemically into the inflorescence. However, virus viability in rosette leaves of Tsu-0 plants apparently was not compromised because infectious CaMV could be recovered from these organs. W260 overcomes Tsu-0 resistance by a passive mechanism (i.e., this virus avoids activating plant defenses). The portion of the viral genome responsible for W260 resistance breakage was mapped to the 5' third of gene VI, which we have termed RBR-1. This region is also responsible for controlling the ability of CaMV to infect different types of solanaceous plants. Hence, the pathways by which plants of different families interact with CaMV may be conserved through evolution.

Pararetrovirus-crucifer interactions: attack and defence or modus vivendi?

Abstract The compatible infection of plants by viruses usually leads to the development of systemic symptoms. Symptom expression of this kind is generally understood to be a host response that indicates an inability of the host to defend itself from attack. We have been studying compatible interactions between the plant pararetrovirus cauliflower mosaic virus (CaMV) and its crucifer hosts in order to understand the relationship between viral activity, symptom expression and plant defence. A CaMV protein (P6) appears to play a major role in eliciting symptom expression. This host response leads to a regulation of the viral multiplication cycle that is associated with leaf mosaics. The host regulation of CaMV appears to operate at the transcriptional level through an effect on the 35S promoter, or at the post-transcriptional level by a process that is akin to gene silencing, and can lead to host recovery depending upon the genetic background of the host. The plant apex is a focus for antiviral defence mechanisms, presumably because viral infection of the apical meristem would rapidly compromise the ability of the plant to generate new leaves and flowers for reproduction. The balance of interactions between CaMV and crucifers can provide a sustainable source of host plants to ensure viral propagation and viral exposure allows the host to adapt and develop its repertoire of defence mechanisms.

Stunting induced by cucumber mosaic cucumovirus-infected Nicotiana glutinosa is determined by a single amino acid residue in the coat protein

R-CMV, a subgroup II strain of cucumber mosaic cucumovirus (CMV) induces a very strong stunting response in Nicotiana glutinosa plants, while Trk7-CMV causes green mosaic in this host. The genetic determinant of this phenotype was mapped to a 534-nucleotide region at the 3' end of RNA3 with biologically active, full-length cDNA clones of R-CMV and Trk7-CMV and RNA3 chimeras of the two strains. Within this region, R-CMV differs from Trk7-CMV by a single amino acid at position 193 in the coat protein. Changing the codon for Lys at this position to Asn or Ser, by site-directed mutagenesis, also changed the phenotype of the viruses from green mosaic to induction of stunting. Profound differences in both the spread and the accumulation of the viruses causing stunting and green mosaic were observed, although these did not correlate with the host specificity of stunting. Since expression of R-CMV coat protein with the PVX vector did not cause stunting, the data suggest that the presence of other CMV components is necessary for the induction of this symptom.

Altered patterns of gene expression in Arabidopsis elicited by cauliflower mosaic virus (CaMV) infection and by a CaMV gene VI transgene

Cauliflower mosaic virus (CaMV) gene VI protein (P6) is an important determinant of symptom expression. Differential display polymerase chain reaction (PCR) was used to identify changes in gene expression in Arabidopsis elicited by a P6 transgene that causes a symptomatic phenotype. We used slot blot hybridization to measure the abundance of mRNAs complementary to 66 candidate PCR products in transgenic, CaMV-infected, and uninfected Arabidopsis plants. CaMV-infected and P6 transgenic plants showed broadly similar changes in abundance of mRNA species. In P6 transgenic plants we detected 18 PCR products that showed unambiguous changes in abundance plus another 15 that showed more limited changes (approximately twofold). CaMV-infected plants showed 17 unambiguous and 13 limited changes. Down-regulated species include those encoding a novel, phenol-like sulfotransferase, and a glycine-rich, RNA-binding protein. Up-regulated species included ones encoding an myb protein, glycine-rich and stress-inducible proteins, and a member of a previously unreported gene family. CaMV infection causes alterations in expression of many Arabidopsis genes. Transgene-mediated expression of P6 mimics virus infection in its effect on host gene expression, providing a potential mechanism for this process.

Transgenic Arabidopsis lines expressing gene VI from cauliflower mosaic virus variants exhibit a range of symptom-like phenotypes and accumulate inclusion bodies

Gene VI of cauliflower mosaic virus (CaMV) is an important determinant of symptom expression during infection. We have constructed a series of transgenic Arabidopsis lines that express gene VI protein (P6) from two CaMV isolates (Bari-1 and Cabb B-JI) that cause mild and severe symptoms, respectively, in Arabidopsis, and from a recombinant virus (Baji-31) with a hybrid gene VI that causes very severe symptoms. From 41 transgenic lines analyzed, 17 showed symptom-like phenotypes that ranged from mild vein chlorosis to severe chlorosis and stunting. P6 levels in transgenic lines varied from undetectable in the lowest expressors to levels greater than those in CaMV-infected plants. There was a strong correlation between phenotype severity and the level of P6, and with the gene VI origin in the order, Baji-31 > B-JI > Bari-1. This was similar to symptom severity in Arabidopsis infected with the respective CaMV variant. We also found that transgenic P6 accumulated in inclusion bodies that were similar to those found in infected plants but lacking virions. We conclude that expression of P6, in the absence of virus replication, elicits a subset of the host symptom responses normally observed during infection and that the level, sequence, and possibly the form of P6 are important in potentiating the process.

Roles of the 35S promoter and multiple overlapping domains in the pathogenicity of the pararetrovirus cauliflower mosaic virus

Elements associated with the 35S promoter involved in generating the pregenomic RNA (35S RNA) of the pararetrovirus cauliflower mosaic virus have been extensively studied in heterologous systems, but little is known about their role in viral pathogenicity. To investigate these elements, premature termination codons were progressively inserted into the 3' end of the adjacent gene VI to dissect it from colinear 35S enhancer sequences. The ability to cause a systemic infection in plants was retained with loss of up to 40 amino acids from the gene VI polypeptide, but truncations into a putative zinc finger proved lethal. In the 35S promoter, removal of the TATA box also abolished infectivity. However, upstream deletions encompassing the 35S enhancer showed that the sequence between -207 and -56 from the cap site comprised nonessential elements, although complete removal of this fragment caused loss of infectivity even when domain spacing was restored by linker insertion. Two separate enhancer domains (-207 to - 150 and -95 to -56) were identified, of which either one or the other, but not both, was required for infectivity. Some mutations affected the cellular levels of viral RNAs in unexpected ways, as with removal of the as-1 enhancer element causing an increase in 35S RNA. Others altered the relative abundance of nuclear and cytoplasmic viral DNAs. Mutations in promoter domains thought to be involved in regulating tissue-specific expression did not significantly affect virus accumulation in leaves versus roots, whereas gene VI mutants showed reduced root accumulation. We conclude that elements associated with the cauliflower mosaic virus 35S promoter contain extensive nonessential regions that can behave differently in their proper context than as isolated elements.

Arabidopsis thaliana expressing the cauliflower mosaic virus ORF VI transgene has a late flowering phenotype

Expression of open reading frame (ORF) VI of cauliflower mosaic virus (CaMV) in transgenic Arabidopsis thaliana caused a typical syndrome characterised by leaf chlorosis, vein clearing, plant stunting and reduced fertility. In addition and in comparison to untransformed controls we observed the formation of much larger rosettes of leaves combined with much later flowering and more extensive tillering. In these aspects, the ORF VI transgenic plants resembled late flowering mutants. All these phenotypes correlated with expression of ORF VI in three lines of transgenic plants which were produced independently, with different Ti-plasmid derived vectors and with different selective markers. The late flowering phenotype cosegregated with the transgene.

Expression of a plant viral polycistronic mRNA in yeast, Saccharomyces cerevisiae, mediated by a plant virus translational transactivator

We demonstrate that the cauliflower mosaic virus (CaMV) gene VI product can transactivate the expression of a reporter gene in bakers' yeast, Saccharomyces cerevisiae. The gene VI coding sequence was placed under the control of the galactose-inducible promoter GAL1, which is presented in the yeast shuttle vector pYES2, to create plasmid JS169. We also created a chloramphenicol acetyltransferase (CAT) reporter plasmid, JS161, by inserting the CAT reporter gene in-frame into CaMV gene II and subsequently cloning the entire CaMV genome into the yeast vector pRS314. When JS161 was transformed into yeast and subsequently assayed for CAT activity, only a very low level of CAT activity was detected in cellular extracts. To investigate whether the CaMV gene VI product would mediate an increase in CAT activity, we cotransformed yeast with JS169 and JS161. Upon induction with galactose, we found that CAT activity in yeast transformed with JS161 and JS169 was about 19 times higher than the level in the transformants that contained only JS161. CAT activity was dependent on the presence of the gene VI protein, because essentially no CAT activity was detected in yeast cells grown in the presence of glucose, which represses expression from the GAL1 promoter. RNase protection assays showed that the gene VI product had no effect on transcription from the 35S RNA promoter, demonstrating that regulation was occurring at the translation level. This yeast system will prove useful for understanding how the gene VI product of CaMV mediates the translation of genes present on a eukaryotic polycistronic mRNA.

A defective movement protein of TMV in transgenic plants confers resistance to multiple viruses whereas the functional analog increases susceptibility

Transgenic tobacco plants that express a gene encoding a defective mutant of the tobacco mosaic virus (TMV) movement protein which are known to be resistant to several tobamoviruses were inoculated with viruses from different taxonomic groups to determine the breadth of resistance. There were significant delays in the time of appearance of disease symptoms and/or there was reduced systemic accumulation of virus in upper leaves of plants inoculated with tobacco rattle tobravirus, tobacco ringspot nepovirus, alfalfa mosaic alfamovirus, peanut chlorotic streak caulimovirus, and cucumber mosaic cucumovirus. Conversely, tobacco plants that express a gene encoding the functional tobacco mosaic virus wild-type movement protein accelerated symptom development, enhanced the severity of symptom formation, and/or increased the accumulation of these viruses and, additionally, TMV. Our results indicate that there are similar functions among the movement proteins of a number of plant viruses despite the apparent lack of sequence similarity between them.

Analysis of cauliflower mosaic virus RNAs in Brassica species showing a range of susceptibility to infection

Cauliflower mosaic virus (CaMV) is a plant pararetrovirus i.e., a DNA virus that replicates through reverse transcription of its terminally redundant genomic RNA (the 35 S RNA). In this study, the absolute levels and relative ratios of CaMV-encoded RNA species were analyzed in Brassica host plants with different susceptibilities to infection. As reported previously, only very low levels of CaMV RNAs were detected in plants of low susceptibility such as cauliflower. Early in infection, a large proportion of these RNAs were the "short-stop" RNA: a 180-nucleotide RNA generated by mRNA 3' end processing at the first encounter of the polyadenylation [poly(A)] signal rather than at the second encounter by which the 35 S RNA is generated. In contrast, in highly susceptible plants such as turnip, high levels of CaMV RNAs were detected, and the short-stop RNA represented only a small fraction of the RNA. In leaf protoplasts, bypass of the poly(A) signal was similar in all Brassica species. Finally, the ratio of the 19 S RNA, a subgenomic RNA encoding a post-transcriptional trans-activator, to the 35 S RNA was lower in cauliflower than in turnip. These results are discussed in light of the CaMV life cycle.

Agroinfection of transgenic plants leads to viable cauliflower mosaic virus by intermolecular recombination

Intermolecular reconstitution of a plant virus has been detected in whole plants in a system using a defective cauliflower mosaic virus genome and transgenic host plants containing the missing viral gene. The information for the gene VI protein of the virus was integrated into the chromosome of host Brassica napus plants and leaves of these plants were inoculated with Agrobacterium tumefaciens containing the complementing viral sequences. In several cases, upper leaves contained replicating viral DNA which was able to incite CaMV symptoms on turnip plants. The sequence of the resultant recombinant viral molecules suggested that both DNA and RNA recombination events may have been involved in the production of functional virus, one event being gene targeting of the T-DNA.

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.

How do plant virus nucleic acids move through intercellular connections?

In addition to their function in transport of water, ions, small metabolites, and growth factors in normal plant tissue, the plasmodesmata presumably serve as routes for cell-to-cell movement of plant viruses in infected tissue. Virus cell-to-cell spread through plasmodesmata is an active process mediated by specialized virus encoded movement proteins; however, the mechanism by which these proteins operate is not clear. We incorporate recent information on the biochemical properties of plant virus movement proteins and their interaction with plasmodesmata in a model for transport of nucleic acids through plasmodesmatal channels. We propose that only single stranded (ss) nucleic acids can be transported efficiently through plasmodesmata, and that movement proteins function as molecular chaperones for ss nucleic acids to form unfolded movement protein-ss nucleic acid complexes. These complexes are targeted to plasmodesmata. Plasmodesmatal permeability is then increased following interaction with movement protein and the entire movement complex or its nucleic acid component is translocated across the plasmodesmatal channel.

Genetic analysis of determinants of disease severity and virus concentration in cauliflower mosaic virus

Cauliflower mosaic virus (CaMV) strains CM1841 and W260 produced markedly different symptoms when inoculated onto turnips (Brassica campestris L. 'Just Right'). The CM1841 strain induced a mild degree of stunting of infected plants while strain W260 caused moderate to severe stunting. Although CM1841 was significantly milder than W260, it accumulated to a significantly higher concentration than W260 in systemically infected leaves. We constructed a series of hybrid viruses in order to map regions of W260 responsible for enhanced disease severity relative to CM1841 and to map regions of CM1841 responsible for higher virus accumulation. We found that the characteristic degree of stunting caused by a CaMV isolate is determined in a complex manner by viral genes that influence viral gene expression and viral genes that disrupt host metabolism. Genes I and VI influenced both virus concentration and stunting severity, suggesting that these regions affected disease severity primarily through their effect on gene expression. In addition, an interaction between genes IV and VI was observed which further indicated that stunting severity was influenced by differential accumulation of virus. In contrast, three regions of W260 influenced the stunting phenotype but had no effect, or a negative effect, on virus concentration. The three regions contained (1) portions of genes II and III, (2) gene IV, independent of gene VI, and (3) the 3' half of gene V and the 19 S promoter. These regions may influence stunting severity primarily by disrupting host metabolism. Additionally, some of the chimeric viruses induced systemic necrosis on leaves, a symptom that is not characteristic of either CM1841 or W260. The necrotic flecking symptom was caused by an interaction between a W260 DNA segment containing gene I and the 5' half of gene II and a CM1841 DNA segment containing the 3' half of gene II, gene III, and gene IV.

Role of alfalfa mosaic virus coat protein gene in symptom formation

On Samsun NN tobacco plants strains 425 and YSMV of alfalfa mosaic virus (AIMV) cause mild chlorosis and local necrotic lesions, respectively. DNA copies of RNA3 of both strains were transcribed in vitro into infectious RNA molecules. When the 425 and YSMV transcripts were inoculated to tobacco plants transformed with DNA copies of AIMV RNAs 1 and 2, they induced symptoms indistinguishable from those of the corresponding parent strains. Exchange of restriction fragments between the infectious clones showed that symptom expression was determined by the coat protein gene in RNA3. The sequence of YSMV RNA3 was determined and compared with the known sequence of 425 RNA3. When the codon for Gln-29 in the coat protein of strain 425 was mutated into the Arg codon present at this position in strain YSMV, the symptoms induced by the transcript on inoculated leaves changed from chlorosis to necrosis. Genetic determinants for the systemic response were more complex.

Gene I, a potential cell-to-cell movement locus of cauliflower mosaic virus, encodes an RNA-binding protein

Cauliflower mosaic virus (CaMV) is a double-stranded DNA (dsDNA) pararetrovirus capable of cell-to-cell movement presumably through intercellular connections, the plasmodesmata, of the infected plant. This movement is likely mediated by a specific viral protein encoded by the gene I locus. Here we report that the purified gene I protein binds RNA and single-stranded DNA (ssDNA) but not dsDNA regardless of nucleotide sequence specificity. The binding is highly cooperative, and the affinity of the gene I protein for RNA is 10-fold higher than for ssDNA. CaMV replicates by reverse transcription of a 358 RNA that is homologous to the entire genome. We propose that the 35S RNA may be involved in cell-to-cell movement of CaMV as an intermediate that is transported through plasmodesmata as an RNA-gene I protein complex.

Host range and symptoms are determined by specific domains of the maize streak virus genome

We have cloned two distinct symptomatic variants of the geminivirus streak virus from maize plants infected with the Nigerian strain (MSV-N). Following "agroinoculation" to maize plants MSV-Nm produces narrow, mildly chlorotic discontinuous streaks, whereas MSV-Ns-infected tissue has wide, severely chlorotic streaks. Symptom appearance is delayed following MSV-Nm inoculation. MSV-Nm has a narrow host range within the Gramineae comprising a fraction of that of the wide host range isolate MSV-Ns. The two isolates are highly homologous and have identical restriction enzyme maps. In order to localize the determinants of pathogenicity we constructed, in vitro, hybrid genomes by restriction enzyme fragment exchange. The determinants of host range, severity of chlorosis, streak length, and timing of symptom appearance map to a fragment which includes the large intergenic region and the 5' terminus of the complementary sense C1 gene. Streak width is determined by the virion-sense portion of the genome, which is consistent with the observation that the virion-sense gene products (V1 and V2) are required for spread of the virus.

Recombination sites in cauliflower mosaic virus DNAs: implications for mechanisms of recombination

Pairs of mutant cauliflower mosaic virus (CaMV) DNAs readily recombine in plants. Five plasmid clones of CaMV DNAs resulting from infection of turnips with pairs of mutant DNAs from DNAs resulting from infection of turnips with pairs of mutant DNAs from different isolates were obtained. Restriction analysis and nucleotide sequencing identified deletions in two cloned recombinants, VR1249 and VR244B. The sequence missing in the former was consistent with its deletion by splicing of an RNA intermediate. These DNAs were not infectious in turnips. VR1243, VR244A, and VR246 induced in turnips disease symptoms that were mixtures of those produced by the parental isolates. Junctions between sequences of the parental isolates were identified by restriction fragment analysis. Three cloned chimeras resulted from multiple recombination events. Nucleotide sequencing identified more precisely the junctions in the five cloned chimeras and in three chimeras previously characterized. Consistent with a model in which reverse transcription plays a major role in generating recombinants, six chimeras had junctions at or near the site for initiation of DNA(-) strand synthesis, three had junctions near the initiation site of 35 S RNA transcription, and one junction was found near the initiation site of 19 S mRNA transcription. Junctions were also found in regions not bearing any obvious relation to DNA (-) strand synthesis by reverse transcription, suggesting that recombination of double-stranded DNAs may also generate CaMV DNA recombinants.