The coat protein (CP) of geminiviruses is involved in a number of processes during the life cycle of the virus. The predominant function is encapsidation of single-stranded DNA and formation of the virus particle to protect viral DNA during transmission. The CP of monopartite geminiviruses is absolutely essential for virus movement, whereas CP mutants of bipartite geminiviruses are able to infect some host plants systemically, indicating an involvement of the CP in host specificity. During the life cycle of geminiviruses, the viral DNA enters the nucleus of the infected cell where virus replication, transcription, and encapsidation occur. For systemic infection, the virus moves cell-to-cell from the site of inoculation to vascular tissue and via phloem to other plant tissues. To move, viral DNA has to shuttle in and out of the nucleus and through plasmodesmata. Parts of the bipartite African cassava mosaic virus (ACMV) CP were fused with green fluorescent protein (GFP) or beta-glucuronidase (GUS). CP domains were identified that mediate both nuclear import and export, as well as targeting of CP-fusion proteins to the cell periphery. These results indicate that domains of the CP facilitate several aspects of geminivirus movement, including nuclear import and export and transport of the viral genome to the cell periphery.
We report on the nucleotide sequences of geminiviruses of the genus Bemogovirus infecting Sida micrantha Schr., a common weed in Brazil. For decades, the mosaic frequently associated with Sida plants was considered to be caused by a Brazilian strain of Abutilon mosaic virus (AbMV). By infection studies and sequence comparisons, we demonstrate that it is associated with a complex of at least two begomoviruses as different from AbMV as most South American geminiviruses. Two molecules of DNA A (A1, A2) and three of DNA B (B1, B2, B3) were cloned and sequenced. According to the high homology in their common regions, DNA A1 and DNA B3, as well as DNA A2 and DNA B2, are cognate components of two begomoviruses, which were infectious in Nicotiana benthamiana plants. No trans-replication was found for any other A/B combination. The intergenic region of DNA B2 appears to be the product of the recombination between DNA B1 and DNA A2. These results show that a coinfection of begomoviruses can persist over decades, producing a reservoir of partially recombined but distinct geminiviruses.
Transgenic Nicotiana benthamiana plants harbouring a defective interfering (DI) DNA of African cassava mosaic virus (ACMV) and control plants were inoculated with ACMV. Virus particles were purified from infected plants, separated in sucrose gradients and fractions were analysed by Southern blotting. Transgenic plant-derived virus particles taken from the top fractions of sucrose gradients contained DI DNA, middle fractions contained a mixture of genomic and DI DNA and bottom fractions contained a mixture of multimeric, genomic and DI DNA. Virus particles from selected top, middle and bottom fractions were analysed by electron microscopy. In fractions containing only DI DNA, isometric particles of 18-20 nm were detected. In fractions containing DI DNA as well as genomic size DNA, isometric and geminate particles were found. Fractions containing multimeric size DNA were found to comprise particles consisting of three subunits adjacent to geminate particles. From these data, it is concluded that the size of encapsidated DNA determines the multiplicity of ACMV particles.Geminiviruses are small plant viruses with circular singlestranded (ss) DNA encapsidated in twinned (geminate) particles (see Fig. 1, panel B3). They have been divided into three genera on the basis of their genome organization, host range and insect transmission. Members of the genera Mastrevirus and Curtovirus have monopartite genomes and infect mainly monocotyledonous or dicotyledonous plants, respectively. Members of the genus Begomovirus infect dicotyledonous plants, are whitefly transmitted and have monopartite or bipartite genomes (DNA A and B). The coat protein (CP) of bipartite geminiviruses is encoded by the DNA A molecule (reviewed by Frischmuth, 1999).
Within the whitefly group only the species Bemisia tabaci (Gennadius) is the vector. Most whitefly-transmitted geminiviruses possess bipartite DNA genomes, DNAs A and B. Although they are closely related to each other, the production of viable pseudorecombinants between bipartite geminiviruses by reassortment of infectious cloned components is generally limited to strains of a particular virus. Following exchange of cloned genomic components of Sida golden mosaic virus (SiGMV/Hoyv) and Abutilon mosaic virus (AbMV), the pseudorecombinant viruses were infectious in various host plants. The symptom type of pseudorecombinant virus was in most cases determined by DNA B. However, in some host plants also DNA A of the pseudorecombinant virus was involved in the symptom phenotype.
Most whitefly-transmitted geminiviruses possess bipartite genomes comprising DNAs A and B. The production of viable pseudorecombinants by reassortment of infectious cloned components is generally limited to isolates/strains of a particular virus. Following exchange of cloned genomic components of Sida golden mosaic virus from Costa Rica (SiGMV/Co) and Sida golden mosaic virus from Honduras (SiGMV/Ho(yv)), the pseudorecombinant viruses were infectious in various plant species. Three DNA B components (B(1), B(2), B(3)), different in a few nucleotides, were isolated from Sida rhombifolia naturally infected with SiGMV/Ho(yv). Only SiGMV/Ho(yv) DNA B(2) was able to form a viable pseudorecombinant with SiGMV/Co DNA A. In protoplasts, as well as in inoculated leaves, SiGMV/Co DNA A trans-replicated the heterogenomic SiGMV/Ho(yv) DNA B(1) component, indicating that impaired movement is involved in the deficiency of SiGMV/Ho(yv) DNA B(1) to form a pseudorecombinant virus with SiGMV/Co DNA A. Even after extensive mutation analysis of SiGMV/Ho(yv) DNA B(1) and B(2), we were unable to pinpoint differences in SiGMV/Ho(yv) DNA B(2) that allowed the formation of a pseudorecombinant virus with SiGMV/Co DNA A. We observed a gradual increase of infectivity from noninfectious SiGMV/Co DNA A/SiGMV/Ho(yv) DNA B(1) and B(3) pseudorecombinant virus to pseudorecombinant viruses showing normal systemic spread of both genomic components associated with symptomatic plants.
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