Characterisation of Sri Lankan cassava mosaic virus and Indian cassava mosaic virus: evidence for acquisition of a DNA B component by a monopartite begomovirus

Two bipartite begomoviruses, Indian cassava mosaic virus (ICMV) and Sri Lankan cassava mosaic virus (SLCMV), have been isolated from mosaic-diseased cassava originating from central India and Sri Lanka, respectively. ICMV was transmitted with low efficiency from cassava to Nicotiana benthamiana by sap inoculation to give leaf curl symptoms. SLCMV was much more virulent in this host, producing severe stunting, leaf curl, and chlorosis. These symptoms were reproduced when their cloned genomic components (DNAs A and B) were introduced into N. benthamiana by either mechanical or Agrobacterium-mediated inoculation (agroinoculation). SLCMV is more closely related to ICMV (DNA A, 84%; DNA B, 94% nucleotide identity) than African cassava mosaic virus (ACMV) (DNA A, 74%; DNA B, 47% nucleotide identity). Sequence comparisons suggest that SLCMV DNA B originated from ICMV DNA B by a recombination event involving the SLCMV DNA A intergenic region. Pseudorecombinants produced by reassortment of the cloned components of ICMV and ACMV were not infectious in N. benthamiana, emphasising their status as distinct virus species. In contrast, a pseudorecombinant between ACMV DNA A and SLCMV DNA B was infectious. Consistent with these observations, iteron motifs located within the intergenic region that may be involved in the initiation of viral DNA replication are conserved between SLCMV and ACMV but not ICMV. When introduced into N. benthamiana by agroinoculation, SLCMV DNA A alone produced a severe upward leaf roll symptom, reminiscent of the phenotype associated with some monopartite begomoviruses. Furthermore, coinoculation of SLCMV DNA A and the satellite DNA beta associated with ageratum yellow vein virus (AYVV) produced severe downward leaf curl in N. glutinosa and yellow vein symptoms in Ageratum conyzoides, resembling the phenotypes associated with AYVV DNA A and DNA beta infection in these hosts. Thus, SLCMV DNA A has biological characteristics of a monopartite begomovirus, and the virus probably evolved by acquisition of a DNA B component from ICMV.     

Geminivirus coat protein gene replacement alters insect specificity

Chimeric clones have been constructed in which the coat protein encoded by DNA A of the bipartite genome of the geminivirus African cassava mosaic virus (ACMV) has been replaced by that of beet curly top virus (BCTV). Constructs containing the coding region inserted in either orientation were infectious when co-inoculated with ACMV DNA B onto Nicotiana benthamiana, producing symptoms typical of ACMV infection. The onset of symptom production was delayed relative to plants inoculated with parental ACMV clones and remission of symptoms was observed. When inserted in the correct orientation for expression from the ACMV coat protein promoter, the BCTV gene was expressed in plants and the coat protein synthesized encapsidated ssDNA of both ACMV genomic components. The BCTV leafhopper vector, Circulifer tenellus (Baker), transmitted both BCTV and the chimeric virus but not ACMV when injected with virus preparations and transferred to N. benthamiana seedlings. The results show that the specificity of leafhopper transmission from insect to plant resides with the coat protein.     

Efficient replication of cloned African cassava mosaic virus in cassava leaf disks

A transient viral replication assay for cloned African cassava mosaic virus (ACMV) was developed using cassava leaf disks. TMS60444 leaf disks were transfected using biolistic-mediated inoculation with ACMV clones pKACMVA and pKACMVB, which originate from West Kenya ACMV isolate 844 (ACMV-KE). Viral DNA synthesized de novo was monitored by Southern hybridization with an AV1 DNA probe. By using the methylation-sensitive restriction enzymes DpnI and MboI, it was possible to distinguish between the input DNA (dam-methylated) and the de novo synthesized viral DNA (not methylated). Different media used for pre- and post-culture of inoculated leaf disks significantly affected the efficiency of viral DNA accumulation. Without pre-culture, replicated viral DNA was not detectable. Culture time in optimized medium also affected the accumulation of nascent viral DNA, and the best results were obtained after 4 days pre-culture on CIM medium followed by 4-6 days post-culture in SH medium. Time-course analysis showed that viral DNA replication can persist for 5-6 days post-inoculation. Our results also confirmed that DNA B of ACMV could assist the accumulation of viral DNA in the leaf disks. The novel protocol described here has also been used successfully with other cassava cultivars (MCol22, MCol1505, TME282 and TMS92/0326) and ACMV clones from the ACMV Nigeria isolate (ACMV-NOg).     

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.     

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.     

Infectivity of African cassava mosaic virus clones to cassava by biolistic inoculation

Summary.  Clones of an African cassava mosaic virus isolate originating from Nigeria (ACMV-NOg) were shown to be infectious to cassava by biolistic inoculation. The production of pseudorecombinants between ACMV-NOg and clones of an ACMV isolate originating from Kenya (ACMV-K) indicated that the lack of infectivity of ACMV-K to cassava was due to defect(s) in the DNA B genomic component; this component encodes two proteins involved in cell-to-cell movement. This is the first demonstration of infectivity of a cloned geminivirus to cassava and conclusively proves that ACMV is the causative agent of cassava mosaic disease. The potential uses of infectious ACMV clones and the means by which to introduce them into cassava are discussed. Received January 18, 1998 Accepted May 27, 1998     

Simultaneous Analysis of the Bidirectional African Cassava Mosaic Virus Promoter Activity Using Two Different Luciferase Genes

The expression of geminivirus genes is controlled by bidirectional promoters which are located in the large intergenic region of the circular DNA genomes and specifically regulated by virus encoded proteins. In order to study the simultaneous regulation of both orientations of the DNA A and DNA B promoters of African cassava mosaic virus (ACMV), they were cloned between two different luciferase genes with the firefly luciferase gene in complementary-sense and the Renilla luciferase gene in virion-sense orientation. The regulation of the ACMV promoters by proteins encoded by the complete DNA A, as well as by the individually expressed transactivator (TrAP) or replication-associated (Rep) proteins was assessed in tobacco and cassava protoplasts using dual luciferase assays. In addition, the regulation of the DNA A promoter integrated into tobacco genome was also assessed. The results show that TrAP activates virion-sense expression strongly both in cassava and tobacco protoplasts, but not in transgenic tobacco plants. In contrast to this, DNA A encoded proteins activate virion-sense expression both in protoplasts and in transgenic plants. At the same time they reduce the expression of the complementary-sense Rep gene on DNA A but activate the expression of the complementary-sense movement protein (MPB) gene on DNA B. The degree of MBP activation is higher in cassava than in tobacco protoplasts, indicating that the plant host also influences the promoter strength. Transient transformation experiments using linearized DNA indicate that the different regulation of the ACMV DNA A promoter in protoplasts and transgenic plants could be due to different DNA curvature in free plasmids and in genes integrated in plant genomic DNA.     

Dual infection by cassava begomoviruses in two leguminous species (Fabaceae) in Yangambi, Northeastern Democratic Republic of Congo

A study on cassava mosaic begomoviruses was conducted around Yangambi (DR Congo) by sampling 10 different leguminous species with or without symptoms similar to cassava mosaic disease. DNA was isolated to amplify CMBs using primers targeting AC2 and AC4 genes for virus detection by PCR. The results showed a dual infection by ACMV and EACMV in two weed species, Centrosema pubescens and Pueraria javanica, associated with mosaic symptoms. The DNA-A genome component of ACMV and EACMV from the infested weeds was sequenced. Seven ACMV and four EACMV isolates are reported. The major ACMV strains were closely related to ACMV-NGogo, ACMV-IC and ACMV-UGMld, whereas all EACMV strains were closely related to a Uganda variant, the most prevalent virus. This study shows that whiteflies may transmit CMBs to non-cassava plants under high epidemic pressure.     

Molecular interaction between two cassava geminiviruses exhibiting cross-protection

There are increasing reports of geminivirus mixed infections of field plant hosts. These mixed infections have been suggested to result in recombinations, emergence of new viruses and new disease epidemics. We previously reported the occurrence of mixed infection between African cassava mosaic virus (ACMV) and East African cassava mosaic Cameroon virus (EACMCV) resulting in severe symptoms in cassava fields in Cameroon. Here, we show that reassortment of DNA-A and DNA-B components of ACMV and EACMCV does not form viable recombinants. However, in the presence of both components of either virus, the DNA-A component of the other virus replicated and spread in the absence of its DNA-B component. This result suggests that failure of ACMV and EACMCV to form viable recombinants is due to the inability of each DNA-A component to trans-replicate the heterologous DNA-B component. This study also shows that ACMV DNA-A induces a resistance to ACMV and EACMCV as indicated by absence or late symptom development. Moreover, this resistance enabled plants to recover from severe symptoms caused by EACMCV in Nicotiana benthamiana, suggesting that the resistance induced is not specific to ACMV and is consistent with the phenomenon of cross-protection between related viruses.     

Multiplex PCR for the detection of African cassava mosaic virus and East African cassava mosaic Cameroon virus in cassava

A multiplex PCR was developed for simultaneous detection of African cassava mosaic virus (ACMV) and East African cassava mosaic Cameroon virus (EACMCV) in cassava affected with cassava mosaic disease (CMD). One set of three primers consisting of an upstream primer common for both viruses and two down stream virus-specific primers were designed for simultaneous amplification of 368 base pair (bp) and 650 bp DNA fragments specific to the replicase gene of ACMV and EACMCV, respectively. Similarly, a second set of three primers were designed for simultaneous amplification of 540 bp and 655 bp fragments specific to the coat protein gene of EACMCV and ACMV, respectively. Primers that can amplify a 171 bp fragment of the large subunit of ribulose bisphosphate carboxylase oxygenase L were included as an internal control in these assays to determine the reliability of multiplex PCR. A simplified, cost-effective and rapid sample preparation method was adapted in place of the conventional plant DNA extraction procedure for multiplex PCR detection of ACMV and EACMCV. The method was validated using CMD-infected cassava samples obtained from farmers' fields in Nigeria. The multiplex PCR is useful for reliable assessment of the prevalence of CMBs in epidemiological studies and for crop improvement and phytosanitary programs in African countries.     

Alternate hosts of African cassava mosaic virus and East African cassava mosaic Cameroon virus in Nigeria

Cassava mosaic disease (CMD) caused by African cassava mosaic virus (ACMV) and East African cassava mosaic Cameroon virus (EACMCV) is the major constraint to cassava production in Nigeria. Sequences of the DNA-A component of ACMV and EACMCV isolates from leguminous plant species (Senna occidentalis, Leucana leucocephala and Glycine max), castor oil plant (Ricinus communis), a weed host (Combretum confertum) and a wild species of cassava (Manihot glaziovii) were determined. All ACMV isolates from these hosts showed 96-98% nucleotide sequence identity with cassava isolates from West Africa. EACMCV was found only in four hosts (S. occidentalis, L. leucocephala, C. confertum, M. glaziovii), and sequences of these isolates showed 96-99% identity with cassava isolates from West Africa. These results provide definitive evidence for the natural occurrence of ACMV and EACMCV in plant species besides cassava.     

The use of biolistic inoculation of cassava mosaic begomoviruses in screening cassava for resistance to cassava mosaic disease

Inoculation of cassava with infectious clones of cassava mosaic geminiviruses (Geminiviridae: Begomovirus) and total DNA extracts from plants infected with well-characterised viruses was evaluated using the Bio-Rad Helios Gene Gun System. Total DNA extracts from infected plants and cloned viruses were produced for coating gold particles and bombardment onto new cassava genotypes, 96/1089A, 96/1039, 96/0160, 96/0304 and three local landraces TME 117, TME 3 and TME 4. Cloned DNA of a Kenyan isolate of the recombinant variant of East African cassava mosaic virus (EACMV-UG2-[Ka]), was only infectious to TME 117 (7/10 plants), 3 weeks post-inoculation with mild infection symptoms in the newly developing leaves. Biolistic inoculation with a chimeric pseudorecombinant virus between DNA A and B components from EACMV-[Ke-Kilifi] and EACMV-UG2-[Ka], respectively, was infectious to TME 117, 96/1039 and 96/0304 and developed very severe and persistent symptoms. TME 3 and TME 4 also developed symptoms, 12 days post-inoculation (d.p.i.). Total DNA extracts of ACMV and EACMV-[Ke-Kilifi] resulted in serious infections with symptoms already evident, 10d.p.i. In general, biolistic inoculation trials with total DNA extracts resulted in a higher number of infected plants expressing symptoms at a much earlier stage (10-12d.p.i.) compared with trials inoculated with virus clones.     

Expression of full-length and truncated Rep genes from Mungbean yellow mosaic virus-Vigna inhibits viral replication in transgenic tobacco

Mungbean yellow mosaic virus-Vigna (MYMV-Vig) is a bipartite geminivirus that causes a severe yellow mosaic disease in blackgram. An assay was developed to study MYMV-Vig replication by agroinoculation of tobacco leaf discs with partial dimers of the virus. This assay, in a non-host model plant, was used to evaluate pathogen-derived resistance contributed by MYMV-Vig genes in transgenic plants. Viral DNA accumulation was optimum in tobacco leaf discs cultured for 10 days after infection with Agrobacterium tumefaciens strain Ach5 containing partial dimers of both DNA A and DNA B of MYMV-Vig. Transgenic tobacco plants with MYMV-Vig genes for coat protein (CP), replication-associated protein (Rep)-sense, Rep-antisense, truncated Rep (T-Rep), nuclear shuttle protein (NSP) and movement protein (MP) were generated. Leaf discs from transgenic tobacco plants, harbouring MYMV-Vig genes, were agroinoculated with partial dimers of MYMV-Vig and analyzed for viral DNA accumulation. The leaf discs from transgenic tobacco plants harbouring CP and MP genes supported the accumulation of higher levels of MYMV-Vig DNA. However, MYMV-Vig accumulation was inhibited in one transgenic plant harbouring the Rep-sense gene and in two plants harbouring the T-Rep gene. Northern analysis of these plants revealed a good correlation between expression of Rep or T-Rep genes and inhibition of MYMV-Vig accumulation.     

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.     

Potential gene products of bean golden mosaic virus have higher sequence homologies to those of tomato golden mosaic virus than to those of cassava latent virus

Comparison of the nucleotide sequences of the DNAs of bean golden mosaic virus (BGMV), tomato golden mosaic virus (TGMV) and cassava latent virus (CLV) revealed a fairly close relationship between BGMV DNA1, TGMV DNA1, and CLV DNA1 and a comparatively distant relationship between BGMV DNA2, TGMV DNA2, and CLV DNA2. The 200-base region common to the two DNAs of each virus had little sequence homology, except for a highly conserved 33–36 base sequence potentially capable of forming a stable hairpin structure. All the potential coding regions in the BGMV DNAs had counterparts in the TGMV and CLV DNAs suggesting an overall similarity in genome organization but two potential coding regions in the BGMV DNAs had no counterparts in the TGMV DNAs. The most highly conserved ORFs, BGMV 1R1, TGMV 1R1, and CLV 1R1, are the putative genes for the coat proteins of BGMV, TGMV, and CLV. BGMV 1R1 has 91.9% and 71.6% homology with respect to TGMV and CLV. The ORFs (BGMV 1L1; CLV 1L1; TGMV 1L1) and the two smaller overlapping ORFs (BGMV 1L2, 1L3; TGMV 1L2, 1L3; CLV 1L5, 1L3) are conserved in the three viruses. BGMV 2R1 and BGMV 2L1 have higher homology with respect to TGMV but not with respect to 2R1 and 2L1 in CLV. From this study we conclude that BGMV is more closely related to TGMV than CLV.     

Cloned tomato golden mosaic virus back in tomatoes

Clones of tomato golden mosaic virus (TGMV), a key model for geminivirus research, have been transmitted back to their original host tomato for the first time. In contrast to the high pathogenicity in other solanaceous species, TGMV induced only very mild symptoms: a few chlorotic spots on the leaf lamina for the common variant (formerly strain cs), and limited vein yellowing for the yellow vein variant (yv). Symptoms disappeared over time, though viral DNA remained detectable in newly developed leaves. Both TGMV variants invaded phloem and, occasionally, also mesophyll parenchyma cells in tomato. Complete direct sequencing of rolling circle amplification products of the viral progeny in tomato plants revealed the consensus of the DNA populations for the two genome components (DNA-A, DNA-B) of both TGMV variants. The DNA-A components showed 98.5% and 99.9% nucleotide sequence identity, respectively, with the independently cloned TGMV molecule sequenced initially in 1984, confirming the classification of csTGMV and yvTGMV as variants. The results are discussed with reference to the history of the Brazilian "mosaico dourado" disease in tomato, and the odyssey of TGMV passaging through Nicotiana benthamiana plants and bacteria of numerous laboratories worldwide.     

Molecular characterisation of a distinct South African cassava infecting geminivirus

Summary.  African cassava mosaic virus (ACMV) and East African cassava mosaic virus (EACMV) are whitefly-transmitted geminiviruses (WTGs) which are widespread in cassava in Africa and cause serious yield losses. Recently, a new geminivirus affecting cassava in South Africa (SACMV) has been reported. In this work SACMV was found to have DNA-A and DNA-B components. Comparisons of amino acid sequences of the putative coat protein, and nucleotide sequences of the common region and a 687-bp DNA B fragment of SACMV with other WTGs, showed that SACMV clustered with the Old World subgroup of the Begomovirus genus of geminiviruses. Despite its bipartite nature, SACMV was most closely related to monopartite TYLCVs, but was sufficiently different to justify designating it as a distinct virus. In serological studies, SACMV grouped biologically with EACMV isolates. Received January 22, 1998 Accepted May 21, 1998     

Identification of Genes Directly and Indirectly Involved in the Insect Transmission of African Cassava Mosaic Geminivirus by Bemisia Tabaci

The inability to transmit progeny virus resulting from the cloned components of an isolate of African cassava mosaic virus originating from Kenya (ACMV-K) has been shown to be due to defects in both genomic components. This was achieved by the production of infectious pseudorecombinants between ACMV-K and the cloned components of a whitefly-transmissible ACMV isolate originating from Nigeria (ACMV-NOg). The exchange of gene fragments between ACMV-K and ACMV-NOg has been used to demonstrate that the defects responsible for lack of transmissibility reside on the coat protein and DNA-B C1 gene of ACMV-K. The significance of these finding with respect to the present understanding of the function of these gene products are discussed.     

Single-stranded DNA of Tomato leaf curl virus accumulates in the cytoplasm of phloem cells

Geminiviruses have been reported to replicate in, and localize to, the nuclei of host plant cells. We have investigated the tissue and intracellular distribution of the monopartite Tomato leaf curl virus (TLCV) by in situ hybridization. Contrary to the current understanding of geminiviral localization, single-stranded (ss) DNA of TLCV accumulated in the cytoplasm. TLCV ssDNA was also found in the nucleus, as was lower levels of replicative form double-stranded (ds) DNA. Under the same conditions, Tomato golden mosaic virus (TGMV) ssDNA and dsDNA were found in nuclei. ssDNA of TLCV, TGMV, and Tomato yellow leaf curl Sardinia virus (TYLCSV) was detected in some xylem vessels under specific hybridization conditions. Tissue specificity of TLCV was partially released by co-infection with TGMV. Our observations suggest that the mechanism of TLCV movement may differ from that of bipartite begomoviruses.