Cotton leaf curl Multan betasatellite impaired ToLCNDV ability to maintain cotton leaf curl Multan alphasatellite

Abstract Alphasatellites (family Alphasatellitidae) are circular, single-stranded (ss) DNA molecules of ~1350 nucleotide in size that have been characterized in both the Old and New Worlds. Alphasatellites have inherent ability to self-replicate, which is accomplished by a single protein, replication-associated protein (Rep). Although the precise function of alphasatellite is yet unknown, and these consider dispensable for infectivity, however, their Rep protein functions as a suppressor of host defence. While alphasatellites are most frequently associated with begomoviruses, particularly with monopartite than bipartite begomoviruses, they have recently been found associated with mastreviruses. The in planta maintenance of alphasatellites by helper geminivirus is still an enigma, with no available study on the topic. This study aimed to investigate whether a widely distributed bipartite begomovirus, tomato leaf curl New Delhi virus (ToLCNDV), can maintain cotton leaf curl Multan alphasatellite (CLCuMuA) in the presence or absence of cotton leaf curl Multan betasatellite (CLCuMuB). The findings of this study demonstrated that ToLCNDV or its DNA A could maintain CLCuMuA in Nicotiana benthamiana plants. However, the presence of CLCuMuB interferes with the maintenance of CLCuMuA, and mutations in the CP of ToLCNDV further reduces it. Our study highlighted that the maintenance of alphasatellites is impaired in the presence of a betasatellite by ToLCNDV. Further investigation is needed to unravel all the interactions between a helper virus and an alphasatellites.

The antisense 5' end of the V2 gene confers enhanced resistance against the monopartite begomovirus cotton leaf curl Kokhran virus-Burewala strain

Whitefly-transmitted viruses of the genus Begomovirus (the family Geminiviridae) have become a limiting factor for agricultural productivity in many warmer parts of the world. The economies of Pakistan and India have, since the early 1990s, suffered losses due to cotton leaf curl disease (CLCuD). The disease is caused by begomoviruses, the most important of which at this time is cotton leaf curl Kokhran virus strain Burewala (CLCuKoV-Bu), and a disease-specific betasatellite, cotton leaf curl Multan betasatellite (CLCuMuB). Efforts to minimize losses due to CLCuD rely mainly on the use of insecticides to kill the whitefly vector; no resistant cotton varieties are currently commercially available. The study described here has investigated RNA interference technology for its potential to yield resistance against CLCuKoV-Bu and three other begomoviruses; CLCuKoV, tomato leaf curl New Delhi virus (ToLCNDV) and Pedilanthus leaf curl virus (PeLCV). Three fragments of the virion-sense V2 gene of CLCuKoV-Bu were transformed into Nicotiana benthamiana in antisense orientation and transgenic lines expressing virus-specific short RNAs were assessed for their ability to yield resistance. Only CLCuKoV-Bu with the V2 sequence closest to the promoter was resistant. Inoculation of CLCuKoV-Bu with CLCuMuB into transgenic plants did not significantly affect the outcome, although viral DNA was detected in number of plants, suggesting that the betasatellite may impair RNAi resistance. Overall the results indicate that targeting the 5' end of V2 gene using antisense-RNA has the potential to deliver resistance against begomoviruses and that RNAi-based resistance imparts some degree of resistance to heterologous viruses. Keywords: geminivirus; begomovirus; RNAi; resistance; CLCuKoV-Burewala; CLCuMuB.

Use of the cotton leaf curl Multan alphasatellite as a silencing or expression vector

Alphasatellites, formerly known as DNA 1, are a satellite-like components associated with begomoviruses (the family Geminiviridae) that require betasatellite for symptom induction but depend on DNA-A for systemic movement. We have converted alphasatellite into gene-silencing vector (modified alphasatellite (∆DNA 1)) by deleting its A-rich region that does not affect the replication nor the movement of the helper virus. Insertion of a transgene green florescence protein (GFP) into ∆DNA 1 resulted in the silencing g of the cognate gene in Nicotiana benthamiana. The silencing persisted for more than one and half month and was associated with the decreased level of mRNA of the target gene. This satellite-like DNA vector induced gene silencing (VIGS) promises to be applicable to other begomovirus/alphasatellite systems, thereby providing the powerful approach to gene discovery and the analysis of gene functions in malvaceous crops. Keywords: cotton; begomovirus; alphasatellite; RNAi.

Molecular characterization of a distinct monopartite begomovirus associated with betasatellites and alphasatellites infecting Pisum sativum in Nepal

Pea (Pisum sativum) plants exhibiting leaf distortion, yellowing, stunted growth and reduction in leaf size from Rampur, Nepal were shown to be infected by a begomovirus in association with betasatellites and alphasatellites. The begomovirus associated with the disease showed only low levels of nucleotide sequence identity (<91%) to previously characterized begomoviruses. This finding indicates that the pea samples were infected with an as yet undescribed begomovirus for which the name Pea leaf distortion virus (PLDV) is proposed. Two species of betasatellite were identified in association with PLDV. One group of sequences had high (>78%) nucleotide sequence identity to isolates of Ludwigia leaf distortion betasatellite (LuLDB), and the second group had less than 78% to all other betasatellite sequences. This showed PLDV to be associated with either LuLDB or a previously undescribed betasatellite for which the name Pea leaf distortion betasatellite is proposed. Two types of alphasatellites were identified in the PLDV-infected pea plants. The first type showed high levels of sequence identity to Ageratum yellow vein alphasatellite, and the second type showed high levels of identity to isolates of Sida yellow vein China alphasatellite. These are the first begomovirus, betasatellites and alphasatellites isolated from pea.

A Distinct Strain of Chickpea chlorotic dwarf virus Infecting Pepper in Oman

During a field survey in 2011, pepper (Capsicum annum) plants showing symptoms suggestive of geminivirus infection were observed in three fields in the Al-Sharqiya region of Oman. Symptoms observed included upward leaf curling leading to cupping and stunting with 15 to 25% disease incidence in surveyed fields. Total DNA was extracted from the leaves of seven symptomatic plants and subjected to rolling circle amplification (RCA). The RCA product was digested with several restriction endonucleases to obtain unit length of ~2.6 to 2.8, typical of geminivirus. Out of seven samples, only four yielded a product of ~2.6 kb in size by KpnI digestion. The fragments were cloned in pUC19 and sequenced. The partial sequences of four isolates were >95% identical to each other at the nucleotide (nt) level and thus only one isolate (P-25) was fully sequenced, determined to be 2,572 nt in length, and its sequence deposited in GenBank (KF111683). The P-25 sequence showed a genome organization typical of a mastrevirus, with four open reading frames (ORFs), two in virion-sense and two in complementary-sense. The virion and complementary-sense ORFs were separated by a long intergenic region, containing a predicted hairpin structure with the nonanucleotide sequence (TAATATTAC) in the loop, and a short intergenic region. An initial comparison to all sequences in the NCBI database using BlastN showed the isolate to have the highest level of sequence identity with isolates of the dicot-infecting mastrevirus Chickpea chlorotic dwarf virus (CpCDV). Subsequent alignments of all available CpCDV isolates using the species demarcation tool (2) showed the isolate P-25 to share between 83.6 and 90.3% identity to isolates of CpCDV available in databases, with the highest (90.3%) to CpCDV strain A originating from Syria (FR687959) (3). Amino acid sequence comparison showed that the predicted proteins encoded by the four ORFs of P-25 (coat protein [CP], movement protein [MP], replication associated protein A [RepA], and RepB) share 91.5, 88.2, 89.1, and 90.8% amino acid sequence identity, respectively, with the homologous proteins of the CpCDV isolate from Syria. Based on the recently revised mastreviruses species and strain demarcation criteria (78 and 94% whole genome nt identity, respectively) proposed by Muhire et al. (2), the results indicate that isolate P-25 represents a newly identified strain (strain F) of CpCDV. The presence of CpCDV in symptomatic pepper plants was further confirmed by Southern blot hybridization technique using digoxygenin (DIG) labeled probe prepared from CpCDV isolate P-25. The genus Mastrevirus consists of geminiviruses with single component genomes that are transmitted by leafhoppers. Mastreviruses have so far only been identified in the Old World and infect either monocotyledonous or dicotyledonous plants (1). To our knowledge, this is the first report of a mastrevirus on the Arabian Peninsula and the first record of pepper as host of CpCDV. Recently, several begomoviruses of diverse geographic origins have been found infecting vegetable crops in Oman. The propensity of geminiviruses to evolve through recombination may lead to evolution of recombinant CpCDV with new host adaptability. Due to extensive agricultural/travel links of Oman with rest of the world, there exists high probability for the spread of this virus. References: (1) M. I. Boulton. Physiol. Mol. Plant Pathol. 60:243, 2002. (2) B. Muhire et al. Arch. Virol. 158:1411, 2013 (3) H. Mumtaz et al. Virus Genes 42:422, 2011.

A Distinct Strain of Tomato leaf curl Sudan virus Causes Tomato Leaf Curl Disease in Oman

Tomato leaf curl disease (ToLCD) is a significant constraint for tomato production in the Sultanate of Oman. The disease in the north of the country has previously been shown to be caused by the monopartite begomoviruses (family Geminiviridae) Tomato yellow leaf curl virus and Tomato leaf curl Oman virus. Many tomato plants infected with these two viruses were also found to harbor a symptom enhancing betasatellite. Here an analysis of a virus isolated from tomato exhibiting ToLCD symptoms originating from south and central Oman is reported. Three clones of a monopartite begomovirus were obtained. One of the clones was shown to be infectious to tomato and Nicotiana benthamiana and to induce symptoms typical of ToLCD. Analysis of the cloned sequences show them to correspond to isolates of Tomato leaf curl Sudan virus (ToLCSDV), a virus that occurs in Sudan and Yemen. However, the sequences showed less than 93% nucleotide sequence identity to previously characterized ToLCSDV isolates, indicating that the viruses represent a distinct strain of the species, for which we propose the name "Oman" strain (ToLCSDV-OM). Closer analysis of the sequences showed them to differ from their closest relative, the "Tobacco" strain of ToLCSDV originating from Yemen, in three regions of the genome. This suggests that the divergence of the "Oman" and "Tobacco" strains has occurred due to recombination. Surprisingly, ToLCSDV-OM was not found to be associated with a betasatellite, even though the isolates of the other ToLCSDV strains have been shown to be. The significance of these findings and the possible reasons for the distinct geographic distributions of the tomato-infecting begomoviruses within Oman are discussed.

Complete nucleotide sequence of a monopartite Begomovirus and associated satellites infecting Carica papaya in Nepal

Carica papaya (papaya) is a fruit crop that is cultivated mostly in kitchen gardens throughout Nepal. Leaf samples of C. papaya plants with leaf curling, vein darkening, vein thickening, and a reduction in leaf size were collected from a garden in Darai village, Rampur, Nepal in 2010. Full-length clones of a monopartite Begomovirus, a betasatellite and an alphasatellite were isolated. The complete nucleotide sequence of the Begomovirus showed the arrangement of genes typical of Old World begomoviruses with the highest nucleotide sequence identity (>99 %) to an isolate of Ageratum yellow vein virus (AYVV), confirming it as an isolate of AYVV. The complete nucleotide sequence of betasatellite showed greater than 89 % nucleotide sequence identity to an isolate of Tomato leaf curl Java betasatellite originating from Indonesian. The sequence of the alphasatellite displayed 92 % nucleotide sequence identity to Sida yellow vein China alphasatellite. This is the first identification of these components in Nepal and the first time they have been identified in papaya.

Identification of Cotton leaf curl Gezira virus in Papaya in Oman

Papaya is an important fruit crop in Oman covering some 130 ha with an annual production of 20 tonnes. In 2011, during surveys of farms in the Quriyat region of Oman, papaya plants were found severely affected by leaf curl disease. Leaves with severe curling, vein darkening, and vein thickening were collected for study. Disease incidence ranged from 30 to 50%, particularly in fields with young papaya. A begomovirus (family Geminiviridae) was suspected as the causal agent based on symptoms (1) and the presence of whiteflies in the field. Samples (four to five) were collected from three farms. Total nucleic acids extracted from symptomatic leaves using the CTAB method were used as templates to amplify circular DNAs using Φ29 DNA polymerase and products were digested with restriction enzymes to identify fragments of 2.6 to 2.8 kb typical of geminiviruses. PstI yielded a fragment of ~1.8 kb when the digested product was analyzed by electrophoresis on a 1% agarose gel. The fragment was cloned and sequenced using primer walking strategy in both directions. The sequencing confirmed the exact size (1,764 bp) and the sequence was deposited in GenBank (HE800524). The viral sequence from Oman (isolate Pap-2) showed four open reading frames (ORFs) in the complementary sense (replication associated protein [Rep] gene, the C2 gene, the replication enhancer protein [REn] gene, and the C4 gene) and the virion-sense ORFs (V1 and V2) were missing in the sequence. An initial comparison to NCBI database sequences using BLAST showed the clone from Oman had the highest level of sequence identity to Cotton leaf curl Gezira virus (CLCuGeV) (FJ868828) cloned from okra in Sudan. Subsequent pair wise sequence comparison was done using ClustalV algorithm. Full length sequences of CLCuGeV from database were trimmed according to the size and genomic coordinates of Pap-2 isolate. The Pap-2 isolate sequence was found to have 83.3 to 95.1% sequence identity to CLCuGeV sequences with maximum value to the Sudan isolate. Amino acid sequence comparison showed that the four predicted proteins (Rep, C2, REn, and C4) encoded by the Pap-2 isolate shared 95.3%, 97.8%, 97.7%, and 87.6% sequence identity, respectively, with the homologous proteins of CLCuGeV-SD (FJ868828). The absence of virion-sense protein sequences indicated it to be a subgenomic molecule of CLCuGeV. According to the recommendations of International Committee on Taxonomy of Viruses, these results indicate that the virus identified in association with papaya leaf curl disease in Oman is a variant of CLCuGeV. CLCuGeV is a begomovirus of African origin which is distinct from the begomoviruses of the Middle East and Asia. To our knowledge, this is the first report of CLCuGeV, or any other cotton infecting begomovirus, from papaya in Oman. The presence of a recombinant fragment of CLCuGeV in a Tomato yellow leaf curl virus isolate from Iran (2), and the association of CLCuGeV with cotton in Pakistan (3) and hollyhock in Jordan (GU945265) suggests this virus has moved into the Middle East and Asia from Africa. The identification of CLCuGeV in Oman shows the widespread occurrence of this virus species. This discovery is important since Oman, and other countries in the area, are a hub of international trade and travel, particularly by air and sea, meaning that the virus could spread further. References: (1) R. W. Briddon and P. G. Markham. Virus Res. 71:151, 2000. (2) P. Lefeuvre et al. PLoS Pathog. 6:e1001164, 2010. (3) M. N. Tahir et al. PLoS ONE 6:e20366, 2011.

Xanthium strumarium: a weed host of components of begomovirus-betasatellite complexes affecting crops

Xanthium strumarium is a common weed that often shows symptoms typical of begomovirus infection, such as leaf curling and vein thickening. The virus complex isolated from the weed consisted of two begomoviruses along with a betasatellite and an alphasatellite. The first begomovirus was shown to be an isolate of Cotton leaf curl Burewala virus, a new recombinant begomovirus species that is associated with resistance breaking in previously resistant cotton varieties in Pakistan, whereas the second was shown to be an isolate of Tomato leaf curl Gujarat virus (ToLCGV), a begomovirus previously reported to be bipartite. However, there was no evidence for the presence of the second genomic component, DNA B, of ToLCGV in X. strumarium. The betasatellite was shown to be an isolate of Tomato yellow leaf curl Thailand betasatellite, the first time this satellite has been identified in Pakistan. The alphasatellite associated with infection of X. strumarium was shown to be a species recently identified in potato and various weeds; Potato leaf curl alphasatellite. Although each component has been identified previously, this is the first time they have been identified in a single host. These findings reinforce the hypothesis that weeds are reservoirs of crop-infecting begomoviruses that may contribute to virus diversity by virtue of harboring multiple viruses and virus associated components, which may lead to interspecific recombination and component exchange.

Diversity of begomoviruses associated with mosaic disease of cultivated cassava (Manihot esculenta Crantz) and its wild relative (Manihot glaziovii Mull. Arg.) in Uganda

Cassava (Manihot esculenta) growing in Uganda during 2001-2002 has been screened for the presence of begomoviruses using PCR-RFLP, cloning full-length genomic components and nucleotide sequence analysis. In contrast with a recent survey in neighbouring Kenya, which identified three distinct strains of East African cassava mosaic virus (EACMV, EACMV-UG and EACMV-KE2) as well as East African cassava mosaic Zanzibar virus and the new species East African cassava mosaic Kenya virus, only EACMV-UG and, to a lesser extent, African cassava mosaic virus (ACMV) were found associated with cassava in Uganda. The integrity of the cloned genomic components of representative virus isolates was confirmed by demonstrating their infectivity in Nicotiana benthamiana and cassava using biolistic inoculation, providing a convenient means to screen cassava varieties for disease resistance. Both EACMV-UG and ACMV were also associated with Manihot glaziovii. Infectivity studies using cloned components confirmed that viruses from one host could infect the other, suggesting that this wild relative of cassava might be a reservoir host for the disease. The relatively low level of diversity of begomoviruses associated with cassava mosaic disease in Uganda is consistent with reports that EACMV-UG has displaced other begomovirus species and strains during the recent epidemic that swept through the country.

Two dicot-infecting mastreviruses (family Geminiviridae) occur in Pakistan

Most mastreviruses (family Geminiviridae) infect monocotyledonous hosts and are transmitted by leafhopper vectors. Only two mastrevirus species, Tobacco yellow dwarf virus from Australia and Bean yellow dwarf virus (BeYDV) from South Africa, have been identified whose members infect dicotyledonous plants. We have identified two distinct mastreviruses in chickpea stunt disease (CSD)-affected chickpea originating from Pakistan. The first is an isolate of BeYDV, previously only known to occur in South Africa. The second is a member of a new species with the BeYDV isolates as its closest relatives. A PCR-based diagnostic test was developed to differentiate these two virus species. Our results show that BeYDV plays no role in the etiology of CSD in Pakistan, while the second virus occurs widely in chickpea across Pakistan. A genomic clone of the new virus was infectious to chickpea (Cicer arietinum L.) and induced symptoms typical of CSD. We propose the use of the name Chickpea chlorotic dwarf Pakistan virus for the new species. The significance of these findings with respect to our understanding of the evolution, origin and geographic spread of dicot-infecting mastreviruses is discussed.

Satellite DNA beta overrides the pathogenicity phenotype of the C4 gene of tomato leaf curl virus but does not compensate for loss of function of the coat protein and V2 genes

We have investigated the ability of satellite DNA beta to complement mutations in the CP, V2 and C4 genes of the monopartite begomovirus, tomato leaf curl virus, which are potentially involved in movement. A mutation in the coat protein was not complemented by DNA beta. Mutations of the C4 and V2 genes attenuated and abolished symptoms, respectively. In the presence of the C4 mutant, but not the V2 mutant, DNA beta induced typical symptoms, confirming that the satellite encodes a dominant symptom determinant. In contrast to the C4 mutant, DNA beta did not enhance the viral DNA levels of the V2 mutant, suggesting that V2 is required for this phenomenon. The significance of these findings is discussed based on our present understanding of the functions of the viral genes and DNA beta.

First Report of Cotton Leaf Curl Disease in Central and Southern Sindh Province in Pakistan

Cotton leaf curl is a devastating disease of cotton that has resulted in severe losses (estimated at more than US$87 million per annum) in Pakistan. The epidemic is centered in Punjab, the province that contributes approximately 80% of Pakistan's cotton. Previously, the disease had been observed sporadically on single plants in the northern Sindh Province but did not cause economically significant damage. During the years 2004 and 2005, a high incidence (approximately 20%) of the disease was observed in Shahdadpur and parts of District Sanghar, located in central Sindh Province. The disease was also observed at low incidence (<1%) in southern Sindh. To confirm the identity of the causal agent of the disease, 18 samples from three districts in central southern Sindh (Sanghar, Hala, and Hyderabad) were collected, and total DNA was extracted using cetyltrimethylammoniumbromide (2). Universal primers for begomoviruses based on conserved sequences as follows were used in polymerase chain reaction (PCR): BegomoF (5'-CCGTGCTGCTGCCCCCATTGTCCGCGTCAC-3') and BegomoR (5'-CTGCCACAACCATGGATTCACGCACAGGG-3'). Universal primers for amplification of DNA β with PCR were also used (1). A full-length clone of Cotton leaf curl Multan virus (CLCuMV) was labeled with alpha-³²PdCTP by the oligo-labeling method and used as a probe in Southern hybridization for the detection of geminivirus DNA forms (2). Similarly, cotton leaf curl disease associated DNA β was also labeled and used as a probe in Southern hybridization. The use of universal primers for begomoviruses resulted in amplification of viral DNA of the expected size from all samples while no PCR product was obtained from healthy plants. PCR results confirmed that all plants were infected with begomoviruses. Southern hybridization with CLCuMV and DNA β probes detected begomovirus DNA forms associated with virus replication when washed at medium stringency, further confirming that the plants were infected with the cotton leaf curl geminivirus complex (2). Our results indicate that cotton leaf curl complex has become established in central and southern districts of Sindh Province and it poses a major threat to cotton grown in the region. References: (1) R. W. Briddon et al. Mol. Biotechnol. 20:315, 2002. (2). S. Mansoor et al. Arch. Virol. 148:1969, 2003.

Mobilisation into cotton and spread of a recombinant cotton leaf curl disease satellite

Analysis of a DNA beta satellite associated with a recently identified cotton leaf curl disease (CLCuD) strain indicated it to be recombinant, with most of the molecule originating from CLCuD DNA beta but with some sequence from a satellite isolated from tomato. Analysis of both archival (pre 2001) and recent cotton samples, shows the recombinant satellite is confined to a small area but was not present in cotton prior to 2001. This indicates that the recombinant DNA beta was recently mobilized into cotton, likely from tomato, and that recombination plays a role in the evolution of these satellites.

Subviral agents associated with plant single-stranded DNA viruses

Begomoviruses (family Geminiviridae) are responsible for many economically important crop diseases worldwide. The majority of these diseases are caused by bipartite begomovirus infections, although a rapidly growing number of diseases of the Old World are associated with monopartite begomoviruses. With the exception of several diseases of tomato, most of these are caused by a monopartite begomovirus in association with a recently discovered essential satellite component (DNA-beta). These begomovirus/satellite disease complexes are widespread and diverse and collectively infect a wide variety of crops, weeds and ornamental plants. Non-essential subviral components (DNA-1) originating from nanoviruses are frequently associated with these disease complexes, and there are tantalizing hints that further novel satellites may also be associated with some begomovirus diseases. DNA-beta components can be maintained in permissive plants by more than one distinct begomovirus, reflecting less stringent requirements for trans-replication that will undoubtedly encourage diversification and adaptation as a consequence of component exchange and recombination. In view of their impact on agriculture, there is a pressing need to develop a more comprehensive picture of the diversity and distribution of the disease complexes. A greater understanding of how they elicit the host response may provide useful information for their control as well as an insight into plant developmental processes.

Identification of a second begomovirus, Sri Lankan cassava mosaic virus, causing cassava mosaic disease in India

The DNA A and DNA B components of a begomovirus associated with cassava mosaic disease (CMD) originating from Kerala, India, were cloned. Biolistically inoculated clones induced symptoms typical of CMD in cassava. Sequence comparisons showed the virus to be an isolate of Sri Lankan cassava mosaic virus (SLCMV). This is the first time this begomovirus species has been identified in India and only the second species shown to cause CMD in the country. The implication of these findings on our understanding of the diversity and geographic distribution of CMD-associated begomoviruses in the region and on efforts to obtain resistance to CMD are discussed.

Biolistic infection of cassava using cloned components of Indian cassava mosaic virus

Cassava mosaic disease (CMD) is a major constraint to cassava production in Africa and Asia. Of the two begomoviruses associated with CMD on the Indian subcontinent, Indian cassava mosaic virus (ICMV) and Sri Lankan cassava mosaic virus, only the latter has been successfully reintroduced into cassava to resolve the aetiology of the disease. Here, we report the complete nucleotide sequence of an ICMV isolate from Maharashtra (ICMV-[Mah2]), central India. Biolistic inoculation of the cloned components produced a systemic infection and typical mosaic symptoms in cassava, thereby fulfilling Koch's postulates. The availability of infectious clones will provide a valuable tool to screen new cassava cultivars for disease resistance under defined conditions.

East African cassava mosaic Zanzibar virus - a recombinant begomovirus species with a mild phenotype

Cassava plants exhibiting mild symptoms of cassava mosaic disease (CMD) were collected from Unguja island, Zanzibar. Cuttings grown from these plants in the glasshouse produced similar symptoms, which were milder than those caused by other known cassava mosaic geminiviruses (CMGs). The whitefly vector, Bemisia tabaci (Gennadius), transmitted the putative virus to 27.7% (n = 18) of target plants. Total DNA extracted from diseased leaves did not yield diagnostic PCR-bands using virus-specific primers to known CMGs. Degenerate primers, however, produced a diagnostic band indicating the presence of a begomovirus. Full-length DNA-A (2785 nucleotides) and DNA-B (2763 nucleotides) components were subsequently PCR-amplified, cloned and sequenced. Phylogenetic analyses of DNA-A and -B sequences showed that they were most similar to strains of East African cassava mosaic virus from Tanzania and Uganda at 83% and 86% nucleotide identities, respectively. The number and arrangement of open reading frames were similar to those of bipartite begomoviruses from the Old World. DNA-A was predicted to have recombined in the intergenic region (IR), AC1 and AC4 genes, and DNA-B in the IR. A maximum nucleotide identity of 83% in the DNA-A component with other sequenced begomoviruses, together with different biological properties allows this virus to be recognised as belonging to a new species named East African cassava mosaic Zanzibar virus (EACMZV).

Diversity of begomovirus DNA beta satellites of non-malvaceous plants in east and south east Asia

Two previous analyses of the diversity of begomovirus-associated DNA beta satellites focused predominantly on molecules originating from the Indian sub-continent and southern China. They showed the satellites to group according to the hosts from which they were isolated, either malvaceous or non-malvaceous plants, and then to form sub-groups based upon geographic origin and host. In this study we analysed the diversity of DNA beta satellites in east and south east Asia. Here the satellites group by geographic location and are considerably more diverse than previously indicated. This probably reflects the limited movement of begomovirus/DNA beta complexes in this region and their subsequent diversification from a common ancestor to a variety of hosts.

Cotton leaf curl disease is associated with multiple monopartite begomoviruses supported by single DNA beta

For bipartite begomoviruses (family Geminiviridae) trans-replication of the DNA B component by the DNA A-encoded replication-associated protein (Rep) is achieved by virtue of a shared sequence, the "common region", which contains repeated motifs (iterons) which are sequence-specific Rep binding sites and form part of the origin of replication. Recently cotton leaf curl disease (CLCuD), a major constraint to cotton production on the Indian subcontinent, has been shown to be caused by a monopartite begomovirus ( Cotton leaf curl Multan virus [CLCuMV]) and a novel single-stranded DNA satellite molecule termed CLCuD DNA beta. The satellite molecule is trans-replicated by CLCuMV but does not possess the iteron sequences of this virus. We have investigated the ability of CLCuD DNA beta to interact with three further clones of monopartite begomoviruses, isolated from cotton, that have distinct Rep binding specificities. All three cloned viruses were capable of trans-replicating the satellite molecule and inducing CLCuD symptoms in cotton, indicating that the interaction between begomovirus and DNA beta is relaxed in comparison to the interaction between DNA A and DNA B components. Field surveys across all the cotton growing regions of Pakistan indicate that dual and multiple infections are the norm for CLCuD with no evidence of synergism. Despite the diversity of begomoviruses associated with CLCuD, only a single class of DNA beta has been detected, suggesting that this satellite has the capacity to be recruited by unrelated begomoviruses.

Universal primers for the PCR-mediated amplification of DNA 1: a satellite-like molecule associated with begomovirus-DNA beta complexes

DNA 1 is a single-stranded DNA molecule of approximately 1370 nucleotides. It is associated with monopartite geminiviruses of the genus Begomovirus, which require a DNA beta component for symptomatic infection. The DNA 1 molecule requires the helper begomovirus for movement in plants, but is capable of self-replication. We designed two abutting primer pairs (DNA101/DNA102 and UN101/UN102) to conserved sequences of DNA 1. This allowed polymerase chain reaction-mediated amplification of the full-length molecule from total nucleic acid extracts produced from various host plants from geographically distinct, worldwide locations. These primers are useful both as diagnostic probes and for producing full-length infectious clones for in planta studies.

Association of a Monopartite Begomovirus Producing Subgenomic DNA and a Distinct DNA Beta on Croton bonplandianus Showing Yellow Vein Symptoms in Pakistan

The recent discovery that monopartite begomoviruses on ageratum and cotton essentially require a DNA satellite called DNA β (2,4) is leading to identification of several other hosts that have similar disease complexes. A weed species (Croton bonplandianus) belonging to the family Euphorbiaceae is one such example. C. bonplandianus is widely distributed on wastelands throughout the Punjab Province in Pakistan. It very often shows yellow vein symptoms indicating infection by a begomovirus. To detect a begomovirus, both symptomatic and asymptomatic plants were collected from several widely separated locations in the Punjab Province. Total DNA was isolated from these samples by the cetyltrimethylammoniumbromide (CTAB) method, resolved in an agarose gel, and blotted on a nylon membrane (2). A full-length clone of DNA A of Cotton leaf curl virus (CLCuV) labeled with ³²PdCTP was used as a probe in Southern hybridization (2). The probe detected hybridizing bands only in symptomatic plants, confirming the presence of a begomovirus. In addition to hybridizing bands of the expected sizes, smaller bands were also detected, suggesting the presence of subgenomic molecules derived from DNA A. Universal polymerase chain reaction (PCR) primers for dicot-infecting geminiviruses (1) were used in PCR for amplification of DNA A of the begomovirus associated with the disease. The use of these primers in PCR was expected to result in amplification of full-length DNA A. In addition to a product of the expected size (2.7 to 2.8 kb), another product of approximately 1.4 kb was amplified. The presence of subgenomic DNAs that are derived from DNA A is an indicator of the monopartite nature of begomoviruses, because in bipartite begomoviruses subgenomic DNAs are derived solely from DNA B. The presence of a DNA β, a DNA satellite associated with certain monopartite begomoviruses, was suspected because of symptoms and the possible monopartite nature of the virus. Universal primers for amplification of DNA β (3) were used in PCR for amplification of a putative DNA β. The PCR reaction yielded a product of expected size (≈1.4 kb). A probe from the amplified product was made by the oligolabeling method. The probe detected hybridizing bands in all symptomatic samples collected from three locations, confirming the association of a DNA β with the disease. A duplicate blot when hybridized with a DNA β associated with ageratum yellow vein disease did not hybridize to these samples. These results confirm that yellow vein disease on this weed is associated with a monopartite begomovirus and a distinct DNA β. References: (1) R. W. Briddon et al. Mol. Biotechnol. 1:202, 1994. (2) R. W. Briddon et al. Virology 285:234, 2001. (3) R. W. Briddon et al. Mol. Biotechnol. In press. (4) K. Saunders et al. Proc. Natl. Acad. Sci. U S A 97:6890, 2000.

Universal primers for the PCR-mediated amplification of DNA beta: a molecule associated with some monopartite begomoviruses

DNA beta is an approx 1350 nucleotide, single-stranded DNA molecule which has been shown to be associated with some monopartite geminiviruses of the genus Begomovirus. This component requires the helper begomovirus for replication in the cells of host plants and for insect transmission, possibly by trans-encapsidation. Sequence comparisons of the two available DNA beta sequences has identified a highly conserved region upstream of a predicted hairpin structure. Abutting primers designed to this conserved region allows PCR-mediated amplification of the full-length DNA beta component from total nucleic acid extracts isolated from infected plants originating from a variety of geographically distinct sources and host plants.

Exchange of three amino acids in the coat protein results in efficient whitefly transmission of a nontransmissible Abutilon mosaic virus isolate

Geminiviruses are transmitted in a circulative manner by whiteflies, leafhoppers, or treehoppers. The whitefly species Bemisia tabaci (Genn.) is the vector for members of the genus Begomovirus. The closely related bipartite Central American begomoviruses Abutilon mosaic virus (AbMV), Sida golden mosaic virus originating from Costa Rica (SiGMV-CR), and Sida golden mosaic virus originating from Honduras (SiGMV-Hoyv) were used to study transmission by their insect vector. The AbMV isolate is defective in transmission, whereas the two Sida-infecting viruses are readily transmitted by B. tabaci. These three viruses are able to form pseudorecombinant viruses by exchange of genomic components. The pseudorecombinant virus SiGMV-Hoyv A/AbMV B was transmissible, whereas the reciprocal pseudorecombinant virus AbMV A/SiGMV-Hoyv B was not transmitted, indicating that DNA B is not involved in the transmission defect. However, the uptake of the pseudorecombinant virus AbMV A/SiGMV-Hoyv B was much better than AbMV itself, indicating that DNA B or DNA B gene products enhance uptake of viral DNA. Exchange of AbMV coat protein with that of SiGMV-CR resulted in a transmissible chimeric AbMV. Mutagenesis of the AbMV coat protein showed that the exchange of two amino acids, at positions 124 and 149, was sufficient to obtain a whitefly-transmissible AbMV mutant. However, when amino acid 174 was altered in addition to amino acids 124 and 149 AbMV was readily transmitted by B. tabaci. From this we conclude that it is not a concise motif, such as the amino acid triplet, aspartate-alanine-glycine (DAG), involved in aphid transmission of potyviruses, that determines transmissibility of begomoviruses by B. tabaci. Instead it is the composition of the coat protein domain from amino acid 123 to 149, as a minimal transmission domain, with the contribution of amino acids 149 to 174 for efficient transmission.

Association of a Disease Complex Involving a Begomovirus, DNA 1 and a Distinct DNA Beta with Leaf Curl Disease of Okra in Pakistan

Okra leaf curl disease (OLCD), characterized by either upward or downward leaf curl and stunted plant growth, is one of the major diseases of okra (Hibiscus esculentis L.) in Pakistan. OLCD is transmitted by the whitefly Bemisia tabaci and is suspected of being associated with a whitefly-transmitted geminivirus (Genus Begomovirus). Total DNAs isolated from both symptomatic and healthy okra plants collected from several locations in Pakistan were resolved on agarose gels and blotted to nylon membranes. A full-length DNA A clone of Cotton leaf curl virus (CLCuV) from Pakistan (2) was labeled with 32PdCTP and used as a probe at medium stringency. The probe detected the presence of characteristic geminivirus DNA forms in infected plants, while no hybridization was observed to healthy plant extracts, confirming the association of a begomovirus with OLCD. Degenerate oligonucleotide primers based on conserved sequences of DNA B components of begomoviruses were used in PCR for the detection of a potential DNA B (3). No amplification was observed with these primers from okra plants, while amplification of a product of expected size was obtained from plants infected with African cassava mosaic virus, suggesting the lack of a genomic component equivalent to DNA B. We have reported previously that monopartite begomoviruses on cotton and Ageratum conyzoides in Pakistan are associated with a disease complex involving a DNA component termed DNA 1, which shows homology to components of nanoviruses that encode the replication-associated protein (2). Recently, another molecule, DNA beta, has been identified, associated with Ageratum yellow vein disease from Singapore (4) and with cotton leaf curl disease (CLCuD) from Pakistan (1). These molecules are DNAs satellite and are essential for the development of typical disease symptoms in their respective hosts. Duplicate blots were probed for the presence of DNAs homologous to DNA 1 and DNA beta (using full-length clones of these molecules isolated from CLCuD originating from Pakistan [1,2]) and washed at medium stringency. The probes detected bands hybridizing to DNA 1 in extracts from infected okra plants but not DNA beta. No hybridizing bands were detected for either probe in extracts from healthy okra. A pair of primers, designed to conserved sequences in DNA beta molecules (4), were used in PCR for the amplification of DNA beta from symptomatic plants. The use of these primers amplified a product of the expected size (approximately 1.35 kb) from extracts of infected okra plants. The amplified DNA was cloned in TA cloning vector and labeled with 32PdCTP. The use of this as a probe detected the presence of a hybridizing band in infected okra plants, while no signal was observed in extracts from cotton plants showing symptoms of CLCuD. These results show that OLCD in Pakistan is associated with a DNA beta molecule that is distinct from that reported on cotton and Ageratum. In particular, the DNA beta of CLCuD and OLCD originating from Pakistan are sufficiently diverse not to cross-hybridize under the conditions used here, and are most likely different disease complexes. To our knowledge this is the first report of the association of a whitefly-transmitted begomovirus/DNA 1/DNA beta complex with okra leaf curl disease. References: (1) R. W. Briddon et al. Virology, 2001 (In press). (2) S. Mansoor et al. Virology 259:190, 1999. (3) M R. Rojas et al. Plant Dis. 77: 340, 1993. (4) K. Saunders et al. PNAS 97:6890, 2000.

Identification of dna components required for induction of cotton leaf curl disease

Cotton leaf curl disease (CLCuD) is a major constraint to cotton production in Pakistan. Infectious clones of the monopartite begomovirus cotton leaf curl virus (CLCuV), associated with diseased cotton, are unable to induce typical symptoms in host plants. We have identified and isolated a single-stranded DNA molecule approximately 1350 nucleotides in length which, when coinoculated with the begomovirus to cotton, induces symptoms typical of CLCuD, including vein swelling, vein darkening, leaf curling, and enations. This molecule (termed DNA beta) requires the begomovirus for replication and encapsidation. The CLCuV/DNA 1/DNA beta complex, together with a similar complex previously identified in Ageratum conyzoides, represent members of an entirely new type of infectious, disease-causing agents. The implications of this finding to our understanding of the evolution of new disease-causing agents are discussed.

Complementation of bipartite begomovirus movement functions by topocuviruses and curtoviruses

The DNA A components of bipartite species of the genus Begomovirus (family Geminiviridae) encode all viral functions required for replication and encapsidation but require gene products encoded on DNA B for cell-to-cell movement in plants. We demonstrate that geminiviruses of the genera Curtovirus and Topocuvirus are able to trans-complement efficient movement of DNA A for two bipartite begomoviruses in the absence of their corresponding DNA B. It previously has been shown that DNA A can, at low efficiency and without inducing symptoms, spread in the absence of DNA B. The spread of DNA A independent of DNA B, following Agrobacterium-mediated inoculation, is shown to require coat protein whereas trans-complemented spread of DNA A can occur independent of the coat protein encoded on DNA A. The significance of these findings to our understanding of the geminiviral infection cycle is discussed.

Cotton leaf curl virus disease

Cotton is one of the most important crops of Pakistan, accounting for over 60% of foreign exchange earnings. The present epidemic of cotton leaf curl disease (CLCuD) originated in the Punjab region near the city of Multan and was first reported in 1985, although it was noted in this region as early as 1967. By the early 1990s, CLCuD had become the major limitation to cotton production in Pakistan and it has now spread into India and, more recently, south and west into other provinces of Pakistan. The very characteristic symptoms include leaf curling, darkened veins, vein swelling and enations that frequently develop into cup-shaped, leaf-like structures on the undersides of leaves. Identification of the vector of CLCuD as the whitefly Bemisia tabaci (Genn.) quickly led to the suggestion that the causative agent of the disease is a geminivirus. Researchers soon confirmed the presence of such a virus that is currently ascribed to the genus Begomovirus of the family Geminiviridae, However, in 1999, the aetiology of the disease was shown to be more complex than was originally assumed. Despite the identification of both a begomovirus and a so-called nanovirus-like component, the precise causal agent of CLCuD remains uncertain.

Clones of cotton leaf curl geminivirus induce symptoms atypical of cotton leaf curl disease

The causative agent of cotton leaf curl disease has previously been shown to be transmissible by the whitefly Bemisia tabaci (Gennadius) and a begomovirus (Geminiviridae) was shown to be associated with the disease. This virus was provisionally called cotton leaf curl virus (CLCuV) although no causal relationship between virus and disease was shown. In the present study full-length clones of CLCuV, equivalent to the DNA A component of bipartite begomoviruses, were obtained. The clones of CLCuV were systemically infectious to both Nicotiana benthamiana and cotton. Infected plants did not exhibit symptoms characteristic of cotton leaf curl disease, producing mild leaf curling, yellowing and some stunting. Efforts to identify a second genomic component were not successful. These findings suggest that the begomovirus, CLCuV, is not or not the sole cause of cotton leaf curl disease. The transmission of cotton leaf curl disease by B. tabaci, however, may indicate that the begomovirus plays a part in the transmission of the disease. The implications of these findings are discussed.

A unique virus complex causes Ageratum yellow vein disease

Ageratum conyzoides L., a weed species widely distributed throughout southeast Asia, frequently exhibits striking yellow vein symptoms associated with infection by Ageratum yellow vein virus (AYVV), a member of the Geminiviridae (genus Begomovirus). Most begomoviruses have bipartite genomes (DNAs A and B), but only a DNA A has been identified for AYVV. We demonstrate that yellow vein disease of A. conyzoides results from co-infection by AYVV DNA A (2,741 nt) and a circular DNA that is approximately half its size (1,347 nt) that we designate DNA beta. Apart from the sequence TAATATTAC, common to all geminiviruses and containing the initiation site of rolling circle replication, DNA beta shows negligible sequence homology either to AYVV DNA A or to DNA B associated with bipartite begomoviruses. DNA beta depends on DNA A for replication and is encapsidated by DNA A-encoded coat protein and so has characteristics of a DNA satellite. However, systemic infection of A. conyzoides by DNA A alone is sporadic and asymptomatic, and DNA A accumulation is reduced to 5% or less of its accumulation in the presence of DNA beta. Therefore, DNA A and DNA beta together form a previously unrecognized disease-inducing complex. Our data also demonstrate that the nanovirus-like DNA 1 component associated with infected A. conyzoides plays no essential role in the disease and represents a satellite-like DNA. Furthermore, the satellite DNA previously found associated with tomato leaf curl virus is probably a defective DNA beta homologue.

Association of a Begomovirus and Nanovirus-like Molecule with Ageratum Yellow Vein Disease in Pakistan

Whitefly-transmitted geminiviruses (begomoviruses) cause heavy losses to many food and fiber crops in Pakistan. Many weeds also show symptoms typical of begomoviruses. Ageratum (Ageratum conyzoides) is a common perennial weed in Pakistan, growing along irrigation canals, that often shows symptoms, such as yellow vein and mosaic, suggesting infection by a begomovirus. To confirm this, symptomatic and asymptomatic ageratum plants were collected from three locations in the Punjab Province of Pakistan, and total DNA was isolated, subjected to agarose gel electrophoresis, transferred to a nylon membrane, and Southern blotted. Total DNA isolated from cotton infected with Cotton leaf curl virus (CLCuV), tomato infected with Tomato leaf curl virus from Pakistan (TLCV-Pak), tobacco infected with African cassava mosaic virus (ACMV) from Nigeria, and healthy tobacco were included as controls. A full-length clone of CLCuV DNA A was labeled with ^[32P]dCTP by oligo-labeling and hybridized at medium stringency. The probe detected characteristic geminivirus DNA forms in symptomatic ageratum and plants infected with CLCuV, TLCV-Pak, and ACMV, while no signal was detected in asymptomatic ageratum from the field or healthy tobacco. To confirm infection by a begomovirus, degenerate primers WTGF (5'-GATTGTACGCGTCCDCCTTTAATTT GAAYBGG-3'), designed in the rep gene of begomoviruses, and WTGR (5'-TANACGCGTGGC TTCKRTACATGGCCTDT-3'), designed in the coat protein gene of DNA A of begomoviruses, were used in polymerase chain reaction (PCR). Degenerate primers (PBLv2040 and PCRc1) also were used in PCR (2). A product of expected size (≈1.4 kb) was obtained with DNA A primers from symptomatic ageratum, while no product was obtained with DNA B primers in the same sample. Previously we were unable to detect a DNA component equivalent to begomovirus DNA B in cotton showing symptoms of cotton leaf curl disease (1). We recently reported a novel circular DNA molecule that was approximately half as long as the full-length DNA A (CLCuV DNA-1) associated with CLCuV that share homology to plant nanoviruses (1). The supercoiled replicative form of viral DNA isolated from infected ageratum plants indicated the presence of smaller molecules, as was found in cotton leaf curl disease, suggesting that a nanovirus-like molecule might be associated with ageratum yellow vein disease. A duplicate blot of samples used in Southern hybridization with the DNA A probe was prepared, and a probe of the full-length clone of the nanovirus-like molecule (CLCuV DNA-1) was prepared as described for DNA A. The probe detected characteristic nanovirus DNA forms in ageratum with yellow vein symptoms and cotton infected with CLCuV, while no signal was detected in plants infected with TLCV-Pak or ACMV, healthy tobacco, or asymptomatic ageratum. Abutting primers PB2-F and PB2R (1), designed based on the CLCuV DNA-1 sequence, were unable to amplify a PCR product from ageratum with yellow vein symptoms, suggesting the nanovirus-like molecule associated with ageratum yellow vein disease is distinct from CLCuV DNA-1. Our results show that yellow vein disease of ageratum in Pakistan is associated with a begomovirus infection and single-stranded circular DNA molecule with similarity to CLCuV DNA-1. References: (1) S. Mansoor et al. Virology 259:190, 1999. (2) M. R. Rojas et al., Plant Dis. 77:340, 1993.

Analysis of the sequence of dioscorea Alata bacilliform virus: comparison to others members of the badnavirus group

The complete nucleotide sequence of the genome of Dioscorea alata bacilliform virus (DaBV) has been determined from cloned fragments. Features of the genome confirm DaBV to be a pararetrovirus of the genus Badnavirus which is more similar to other mealy-bug transmitted badnaviruses, in particular to cacao swollen shoot virus, than to rice tungro bacilliform virus. Sequence variability between cloned fragments suggests that the genetic variability of the virus may be quite high (up to 11% nucleotide sequence variation for some small regions of the genome) although the overall variability detected was 4.2% at the nucleotide level.

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

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.

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.

Efficient whitefly transmission of African cassava mosaic geminivirus requires sequences from both genomic components

Clones of two subgroup III geminiviruses, the common strain of tomato golden mosaic virus (csTGMV) and African cassava mosaic virus originating from Kenya (ACMV-K), were shown to be non-transmissible by whitefiles. Lack of transmissibility of cloned ACMV-K was investigated by exchanging genomic components with a whitefly-transmissible ACMV isolate from Nigeria (ACMV-NOg). Neither pseudorecombinant was transmissible, indicating that defects in both genomic components contributed to the lack of transmissibility. Analysis of the acquisition of the pseudorecombinats by Bemisia tabaci indicated that accumulation of virus within the insect was DNA B dependent. Return of virus to plants was determined by DNA A, although the coat protein was essential for acquisition. Repeated passaging of both the wild strain of ACMV-NOg and the cloned virus led to loss of insect transmissibility of the wild isolate but not the cloned virus. Products encoded on both genomic components are required for transmission of bipartite geminiviruses by B. tabaci.

Analysis of the nucleotide sequence of the treehopper-transmitted geminivirus, tomato pseudo-curly top virus, suggests a recombinant origin

The genome of tomato pseudo-curly top virus (TPCTV), originating from Florida, has been cloned and sequenced. TPCTV is the only geminivirus identified with a vector specificity which falls outside the Cicadellidae (leafhoppers) and Aleyrodidae (whiteflies). Infectivity of the cloned viral genome was demonstrated by Agrobacterium-mediated inoculation of several host species. Progeny virus was transmissible by the treehopper vector of TPCTV, Micrutalis malleifera (Fowler). The genome of TPCTV shows features typical of both subgroups I and III genera of the family Geminiviridae. The coat protein of TPCTV, although distinct from all previously characterized geminiviruses, exhibits features more akin to the leafhopper-transmitted geminiviruses than those transmissible by the whitefly Bemisia tabaci Genn. The relationship of TPCTV to other geminiviruses, particularly beet curly top virus, is discussed in relation to the possible evolutionary origins of this virus.

Analysis of the genetic variability of maize streak virus

The nucleotide sequences of the small intergenic region (SIR) and the gene encoding the coat protein of 12 maize streak virus (MSV) isolates from different geographic locations have been determined. These have been used to assess the variability of the virus and to construct evolutionary dendrograms. For the viruses analyzed, the maximum levels of sequence divergence were found to be 10.9% and 2.0% at the nucleotide and amino acid levels, respectively. A genetically distinct strain of MSV was collected from islands in the Indian ocean. The significance of these findings for detection of the virus in epidemiological studies and breeding of resistant plant varieties is discussed.

Rapid production of full-length, infectious geminivirus clones by abutting primer PCR (AbP-PCR)

The application of the polymerase chain reaction (PCR) method of DNA amplification for the isolation of full-length, infectious clones of geminiviruses is described. Non-overlapping, abutting 20-mer oligonucleotide primers were used to produce a linear product from the circular geminivirus genomic template. Clones of African cassava mosaic virus (ACMV) DNA A, obtained by this method, were infectious following mechanical inoculation (in the presence of ACMV DNA B) onto Nicotiana benthamiana. Normal ACMV symptoms resulted and typical geminate viral particles were detected by electron microscopy. The use of PCR for the detection and production of full-length, infectious geminivirus clones is discussed.

The nucleotide sequence of an infectious insect-transmissible clone of the geminivirus Panicum streak virus

The infectious genome of a Kenyan isolate of Panicum streak virus (PSV) has been cloned and sequenced. Infection of host plants was done using an Agrobacterium binary vector containing a partial repeat of the genome. Progeny virus from resultant infections proved to be transmissible by the leafhopper Cicadulina mbila (Naude). Comparisons of the amino acid sequences of PSV DNA-encoded proteins with those of previously characterized geminiviruses infecting monocotyledonous plants, including maize streak virus, revealed high levels of identity. The evolutionary relationship between PSV and other geminiviruses infecting monocotyledons is discussed.

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.

The coat protein of beet curly top virus is essential for infectivity

We have applied the procedure of Agrobacterium-mediated inoculation to develop a simple, efficient, and reproducible assay for the infectivity of the leafhopper-transmitted geminivirus, beet curly top virus (BCTV). This assay system was used to show that a coat protein mutant of BCTV is not infectious, but could be complemented by coagroinoculation with a second mutant bearing a lethal mutation in the complementary-sense open reading frame, C1. Furthermore, the coat protein mutant retained the ability to replicate and to produce both ssDNA and dsDNA when electroporated into Nicotiana tabacum protoplasts. We conclude that the coat protein of BCTV is essential for spread of the virus. The results are discussed in the light of results with coat protein mutants of other geminiviruses.