Characterisation of full genome of Dolichos yellow mosaic virus based on sequence comparison,genetic recombination and phylogenetic relationship

Yellow mosaic disease (YMD) is one of the most important diseases affecting different leguminous crops and causes significant yield losses in Indian sub‐continent. Eight different bipartite begomovirus species are known to cause YMD in more than 10 leguminous crops. These species are collectively known as legume yellow mosaic viruses (LYMVs), and their full genomes have been characterised except for Dolichos yellow mosaic virus (DoYMV). In this study, full genome of DoYMV isolate (KJ481204 and KJ481205) infecting dolichos has been characterised. The DNA‐A of DoYMV consists of 2761 nucleotides and DNA‐B of 2733 nucleotides with a genome organisation typical of Old World bipartite begomoviruses. Nucleotide identity of DNA‐B (KJ481205) of DoYMV with DNA‐B of other legumoviruses was 57.5–61.0%. Both components contain a nonanucleotide and conserved inverted repeat sequences with the potential to form a stem‐loop. Nucleotide identity of common region of DoYMV was 90.3%, above the threshold nucleotide identity (>85%) for considering a DNA‐B molecule as cognate of DNA‐A of a begomovirus. Four recombination events in DNA‐A and two in DNA‐B of DoYMV isolate were detected. Mungbean yellow mosaic virus, Rhynchosia yellow mosaic virus and Horsegram yellow mosaic virus were identified as probable parents.     

Genetic diversity of legume yellow mosaic begomoviruses in Indonesia and Vietnam

High incidences of yellow mosaic symptoms were observed in soybean and yard‐long bean crops in Indonesia in 2009 and in mungbean crops in Vietnam in 2011. All five soybean and 20 yard‐long bean samples from Java, Indonesia, and 15 mungbean samples from Vietnam with symptoms tested positive for begomovirus infection by polymerase chain reaction (PCR) with primer pair PAL1v1978B/PAR1c715H. On the basis of collection location and the nucleotide sequence comparisons of the 1.5 kb begomoviral DNA‐A components amplified, a subset of samples comprising two soybean and six yard‐long bean isolates from Indonesia and five mungbean isolates from Vietnam were taken forward for more detailed examination. Sequence comparison and phylogenetic analysis of the full‐length sequences of all Indonesian and Vietnam isolates alongside other legume‐infecting begomoviruses revealed that all the isolates from Indonesia were Mungbean yellow mosaic India virus (MYMIV) strain‐A, and all from Vietnam were Mungbean yellow mosaic virus (MYMV) strain‐B. To the best of our knowledge, this is the first identification of MYMIV and MYMV associated with yellow mosaic of legumes in Indonesia and Vietnam, respectively. The epidemiological implications and potential consequences of the emergence of legume‐infecting begomoviruses on legume production in these areas of Southeast Asia are discussed.     

Comparative epitope profiles of the particle proteins of whitefly-transmitted geminiviruses from nine crop legumes in India

Geminiviruses associated with yellow or golden mosaic diseases of legume crops in two regions of India were compared by testing their reactivity with 27 monoclonal antibodies (MAbs) prepared to the particles of African cassava mosaic (ACMV) or Indian cassava mosaic (ICMV) viruses. The viruses fell into two main groups. Group 1 comprised isolates of dolichos yellow mosaic virus; these reacted with three or four ACMV MAbs and four ICMV MAbs. Group 2 comprised isolates of horsegram yellow mosaic virus, together with isolates from blackgram, cowpea, French bean, pigeonpea, soybean, Indigofera hirsuta and probably also isolates from mungbean. These reacted with three or four ACMV MAbs but with few or no ICMV MAbs. Isolates within each group differed slightly in epitope profile, depending on the source species (Group 2) or geographical origin (Groups 1 and 2). Isolates from lima bean resembled those in Group 2 but had some antigenic differences, and their status is uncertain. The poor detectability of geminivirus isolates in mungbean may reflect a low virus concentration in this species.     

Host range, vector relationships and sequence comparison of a begomovirus infecting hibiscus in India

Hibiscus leaf curl disease (HLCuD) occurs widely in India. Infected hibiscus plants show vein thickening, upward curling of leaves and enations on the abaxial leaf surface, reduction in leaf size and stunting. The commonly‐occurring weeds (Ageratum conyzoides, Croton bonplandianum and Euphorbia geniculata), Nicotiana benthamiana, Nicotiana glutinosa and Nicotiana tabacum (var. Samsun, Xanthi), cotton and tomato were shown to be susceptible to HLCuD. One of the four species of hibiscus (Hibiscus rosa‐sinensis) and 75 of the 101 commercial hybrids/varieties grown in the Bangalore area of southern India were also susceptible. Two virus isolates associated with HLCuD from Bangalore, South India (Ban), and Bhubaneswar, North India (Bhu), were detected serologically and by PCR‐mediated amplification of virus genomes. The isolates were characterised by sequencing a fragment of DNA‐A component (1288 nucleotides) and an associated satellite DNA molecule of 682 nucleotides. Phylogenetic analyses of these DNA‐A sequences clustered them with Old World cotton‐infecting begomoviruses and closest to Cotton leaf curl Multan virus (CLCuMV) at 95–97% DNA‐A nucleotide identities. The 682‐nucleotide satellite DNA molecules associated with the HLCuD samples Ban and Bhu shared 96.9% sequence identity with each other and maximum identity (93.1–93.9% over positions 158–682) with ～1350‐nucleotide DNA‐β satellite molecules associated with cotton leaf curl disease in Pakistan and India (accession nos AJ298903, AJ316038). HLCuD in India, therefore, appears to be associated with strains of CLCuMV, a cotton‐infecting begomovirus from Pakistan, which is transmitted in a persistent manner by Bemisia tabaci.     

The ever increasing diversity of begomoviruses infecting non‐cultivated hosts: new species from Sida spp. and Leonurus sibiricus,plus two New World alphasatellites

Begomoviruses (whitefly‐transmitted, single‐stranded DNA plant viruses) are among the most damaging pathogens causing epidemics in economically important crops worldwide. Besides cultivated plants, many weed and wild hosts act as virus reservoirs where recombination may occur, resulting in new species. The aim of this study was to further characterise the diversity of begomoviruses infecting two major weed genera, Sida and Leonurus. Total DNA was extracted from samples collected in the states of Rio Grande do Sul, Paraná and Mato Grosso do Sul during the years 2009–2011. Viral genomes were enriched by rolling circle amplification (RCA), linearised into unit length genomes using various restriction enzymes, cloned and sequenced. A total of 78 clones were obtained: 37 clones from Sida spp. plants and 41 clones from Leonurus sibiricus plants. Sequence analysis indicated the presence of six bipartite begomovirus species and two alphasatellites. In Sida spp. plants we found Sida micrantha mosaic virus (SiMMV), Euphorbia yellow mosaic virus (EuYMV), and three isolates that represent new species, for which the following names are proposed: Sida chlorotic mottle virus (SiCMoV), Sida bright yellow mosaic virus (SiBYMV) and Sida golden yellow spot virus (SiGYSV), an Old World‐like begomovirus. L. sibiricus plants had a lower diversity of begomoviruses compared to Sida spp., with only Tomato yellow spot virus (ToYSV) and EuYMV (for the first time detected infecting plants of the genus Leonurus) detected. Two satellite DNA molecules were found: Euphorbia yellow mosaic alphasatellite, for the first time detected infecting plants of the genus Sida, and a new alphasatellite associated with ToYSV in L. sibiricus. These results constitute further evidence of the high species diversity of begomoviruses in non‐cultivated hosts, particularly Sida spp.     

Molecular Characterization of a Distinct Begomovirus and its Associated Satellite DNA Molecule Infecting Sida acuta in China*

Three viral isolates Hn8, Hn40 and Hn41 were obtained from Sida acuta showing yellow mosaic symptom in the Hainan province, China. Comparison of partial DNA‐A sequences amplified with degenerate primers confirmed the existence of single type of Begomovirus. The complete nucleotide sequence of the DNA‐A‐like molecule of Hn8 was determined to be 2749 nucleotides, having a typical genetic organization of a Begomovirus. Hn8 DNA‐A had the highest sequence identity (78%) with that of Ageratum yellow vein China virus‐[G13] ( AJ558120 ), and had less sequence identity with other begomoviruses. Based on the above molecular data, Hn8 was thus considered as a new Begomovirus species, for which the name Sida yellow mosaic China virus (SiYMCNV) is proposed. Satellite DNA‐β molecules (Hn8‐β, Hn40‐β and Hn41‐β) were found to be associated with Hn8, Hn40 and Hn41 and their complete nucleotide sequences were determined. Sequence analysis showed that Hn8‐β, Hn40‐β and Hn41‐β shared more than 84% nucleotide sequence identity, and they were different from other characterized DNA‐β, sharing the highest nucleotide sequence identity (47.8%) with DNA‐β of Ageratum yellow vein virus.     

Occurrence of Six Begomoviruses Infecting Tomato Fields in Venezuela and Genetic Characterization of Potato Yellow Mosaic Virus Isolates

Begomoviruses are one of the major pathogens in tomato crops worldwide. In Venezuela, six begomovirus species have been described infecting tomato: Potato yellow mosaic virus (PYMV), Euphorbia mosaic Venezuela virus (EuMVV), Merremia mosaic virus (MeMV), Tomato chlorotic leaf distortion virus (ToCLDV), Tomato yellow margin leaf curl virus (TYMLCV) and Tomato yellow leaf curl virus (TYLCV). In this study, the occurrence of these viruses was analysed by PCR in 338 tomato plants exhibiting virus‐like symptoms. Sixty‐three per cent of the plants were positive at least to one of the begomoviruses tested. PYMV and TYLCV were the most frequent viruses showing 39.6 and 23.7% occurrence, respectively. Phylogenetic analyses revealed two groups of PYMV isolates from several Caribbean Basin countries. The first group clustered isolates from several countries, including Venezuela, and the second group clustered only Colombian isolates. Due to the high prevalence of PYMV and TYLCV in Venezuela, it is suggested that the surveillance and control strategies currently applied in the country should be focused on these two begomoviruses.     

Molecular evidence for association of Cotton leaf curl Alabad virus with yellow vein mosaic disease of okra in North India

Two virus isolates (OY77 and OY81B) from okra plants showing yellow vein mosaic, downward curling and vein twisting symptoms were collected from different farmer's fields in Karnal, Haryana state, India. The genomes of the two isolates were amplified, cloned, sequenced and analysed. The analysis indicated that the isolates are similar with 89.2% nucleotide sequence identity. Based on the current threshold cut-off value for taxonomy distinguishing the genus begomoviruses species from strains, the two isolates are designated as strains of Cotton leaf curl Alabad virus (CLCuAV) which shared nucleotide sequence identity of >90% with CLCuAV infecting cotton in Pakistan. Phylogenetic and recombination analyses of the major genome component of OY77 and OY81B is derived from different begomviruses (CLCuAV, BYVMV, CLCuMuV) as the foremost parents for evolution of these new recombinant strains.     

Occurrence of three distinct begomoviruses in cassava in Madagascar

The presence of East African cassava mosaic virus in association with cassava mosaic disease in Madagascar has previously been reported. We now describe virus isolates from mosaic‐affected Madagascan cassava with epitope profiles typical of African cassava mosaic virus, and an isolate with a nucleotide sequence similar to that of South African cassava mosaic virus. Thus, three distinct begomoviruses occur in cassava in Madagascar.     

Assessment of variation in Aceria cajani using analysis of rDNA ITS regions and scanning electron microscopy: implications for the variability observed in host plant resistance to pigeonpea sterility mosaic disease

Aceria cajani on pigeonpea (Cajanus cajan) is the vector of the agent of pigeonpea sterility mosaic disease (PSMD), a very damaging virus‐like disease in the Indian subcontinent. PCR was used to amplify A. cajani nuclear ribosomal DNA (rDNA) internal transcribed spacers (ITS) and associated rDNA genes. They were assessed for variation in this genome region by nucleotide sequencing and RFLP. A. cajani‐specific rDNA primers are described. Several A. cajani populations were collected from pigeonpea plants from various PSMD endemic locations in India, Nepal and Myanmar. No significant variation was identified in rDNA regions, or in morphological features. These results suggest strongly that A. cajani on pigeonpea across the Indian subcontinent constitutes one species and that no other Aceria species and probably no A. cajani biotypes that differ in vectoring ability are involved in the transmission of the agent of PSMD. The implications of these findings for the variability observed in PSMD‐resistant pigeonpea genotypes across various locations in India are discussed.     

Tomato yellow leaf curl virus and Tomato leaf curl Taiwan virus Invade South-east Coast of China

An epidemic outbreak of severe yellow leaf curl disease was reported in field grown tomato within Zhejiang Province of China in the autumn–winter cropping season of 2006. A molecular diagnostic survey was carried out based on comparisons of partial and complete viral DNA sequences. Comparison of partial DNA‐A sequences amplified with degenerate primers specific for begomoviruses confirmed the presence of two types of begomoviruses. The complete DNA sequences of five isolates, corresponding to the two types, were determined. Sequence comparisons and phylogenetic analysis revealed that they correspond to two previously identified begomoviruses, Tomato yellow leaf curl virus and Tomato leaf curl Taiwan virus. The satellite DNAβ molecule was not detected in these samples by either PCR or Southern blot hybridization analysis. There has been no previous report of geminivirus disease incidence in Zhejiang Province, indicating that the introduction of these two tomato infecting geminiviruses into the agro‐ecological zone of South‐eastern China is a fairly recent event. The implications for disease control are discussed.     

Molecular characterisation and relative incidence of bean‐ and soybean‐infecting begomoviruses in northwestern Argentina

Recent studies identified three begomoviruses infecting soybean and bean crops in northwestern (NW) Argentina, bean golden mosaic virus (BGMV), a virus with high capsid protein identity with Sida mottle virus (SiMoV) and a possible new viral species (isolate A). Analysis of complete DNA‐A sequences confirmed that isolate A represents a new viral species for which the authors propose the name soybean blistering mosaic virus (SbBMV), whereas the SiMoV‐like virus is actually an isolate of tomato yellow spot virus (ToYSV). Molecular hybridisation‐based detection of the three begomoviruses was accomplished using a general probe obtained by mixing full‐length DNA‐A clones of the three begomoviruses and specific probes comprising part of the common region of each viral genome. These probes were used to test samples collected in NW Argentina from 2004 through 2007. Fifty‐three percent of the bean samples were infected with BGMV, 11.5% with ToYSV and 9% with SbBMV. For soybean samples, 33% were infected with SbBMV and 18% with ToYSV. BGMV was not detected in soybean. ToYSV was also detected in the wild species Abutilon theophrasti.     

Recombination Among Begomoviruses on Malvaceous Plants Leads to the Evolution of Okra Enation Leaf Curl Virus in Pakistan

Whitefly transmitted begomoviruses (family Geminiviridae) are the major reason for significant yield losses of dicotyledonous crops in tropics and subtropics. Okra (Abelmoschus esculentus) is one of the important vegetable crops, and leaf curl disease caused by geminiviruses is the most important limiting factor for its production in Pakistan. Here, we report a new species of okra‐infecting begomovirus in south‐eastern region of Pakistan and the name Okra enation leaf curl virus (OELCuV) complex is proposed. This okra enation leaf curl disease complex (OELCuD) in Pakistan is found to be associated with Ageratum conyzoides symptomless alphasatellite (AConSLA). All efforts to clone the betasatellite were unsuccessful. Comprehensive sequence analyses suggest that intermalvaceous recombination between okra and cotton‐infecting begomoviruses resulted in the evolution of the new species. Surprisingly, Bhendi yellow vein mosaic virus (BYVMV) which has not been reported previously from Pakistan is the major parent while Cotton leaf curl Multan virus (CLCuMV) acts as a distant parent of the virus. Comparative recombination analysis also reveals that okra‐infecting begomoviruses from south and north‐western India is causing OELCuD in the Pakistan by recombining with CLCuMV at the Rep (1964–1513 nts). Recombination is common among geminiviruses and recombining of BYVMV and CLCuMV resulted in a new species: OELCuV. To the best of our knowledge, this evolution of a new species of okra‐infecting begomovirus is the first report of intermalvaceous recombination where Rep acts as the target region.     

Cloning, restriction mapping and phylogenetic relationship of genomic components of MYMIV from Lablab purpureus

The present work describes cloning of genomic components of whitefly transmitted geminivirus infecting Lablab purpureus syn. Dolichos lablab (commonly known as Dolichos bean or Hyacinth bean). The genome characterization using PCR with geminiviral degenerate primers and DNA sequencing were used to describe the bipartite virus associated with yellow mosaic disease of Dolichos lablab. Full-length DNA-A and DNA-B clones were obtained. The DNA-A sequence analysis showed that the isolate was similar to other Mungbean yellow mosaic India virus (MYMIV) isolates reported earlier. The nucleotide sequence analysis of the full-length DNA-A of virus isolate revealed more than 97% homology with Mungbean yellow mosaic India virus-[Cowpea] (AF481865), while the DNA-B also showed >95% homology with MYMIV-[Cp] (AF503580) and MYMIV-[Sb] (AY049771). The phylogenetic analysis of present isolate showed close relationship to legume geminiviruses. The nucleotide sequence analysis showed presence of six open reading frames (ORFs) in DNA-A, with 2 ORFs aligned in sense and 4 ORFs in antisense orientation. Similarly, DNA-B contained two open reading frames (ORFs), one in sense and another in antisense orientation.     

Molecular Characterization of a Distinct Begomovirus Infecting Crassocephalum crepidioides in China

A Begomovirus isolate JH1 was obtained from Crassocephalum crepidioides showing yellow vein symptoms in Jinghong of Yunnan province, China. The complete sequence of Begomovirus DNA‐A‐like molecule of JH1 was determined to be 2745 nucleotides long. When compared with other begomoviruses, JH1 DNA‐A has the highest nucleotide sequence identity (86.4%) with that of Tobacco curly shoot virus. Comparisons of individual encoded proteins with other begomoviruses show that different parts of JH1 DNA‐A have different ancestors. The molecular data show that JH1 is a distinct Begomovirus species, for which the name Crassocephalum yellow vein virus is proposed.     

Biology and interactions of two distinct monopartite begomoviruses and betasatellites associated with radish leaf curl disease in India

Background

Emerging whitefly transmitted begomoviruses are major pathogens of vegetable and fibre crops throughout the world, particularly in tropical and sub-tropical regions. Mutation, pseudorecombination and recombination are driving forces for the emergence and evolution of new crop-infecting begomoviruses. Leaf curl disease of field grown radish plants was noticed in Varanasi and Pataudi region of northern India. We have identified and characterized two distinct monopartite begomoviruses and associated beta satellite DNA causing leaf curl disease of radish (Raphanus sativus) in India.

Results

We demonstrate that RaLCD is caused by a complex of two Old World begomoviruses and their associated betasatellites. Radish leaf curl virus-Varanasi is identified as a new recombinant species, Radish leaf curl virus (RaLCV) sharing maximum nucleotide identity of 87.7% with Tomato leaf curl Bangladesh virus-[Bangladesh:2] (Accession number AF188481) while the virus causing radish leaf curl disease-Pataudi is an isolate of Croton yellow vein mosaic virus-[India] (CYVMV-IN) (Accession number AJ507777) sharing 95.8% nucleotide identity. Further, RDP analysis revealed that the RaLCV has a hybrid genome, a putative recombinant between Euphorbia leaf curl virus and Papaya leaf curl virus. Cloned DNA of either RaLCV or CYVMV induced mild leaf curl symptoms in radish plants. However, when these clones (RaLCV or CYVMV) were individually co-inoculated with their associated cloned DNA betasatellite, symptom severity and viral DNA levels were increased in radish plants and induced typical RaLCD symptoms. To further extend these studies, we carried out an investigation of the interaction of these radish-infecting begomoviruses and their associated satellite, with two tomato infecting begomoviruses (Tomato leaf curl Gujarat virus and Tomato leaf curl New Delhi virus). Both of the tomato-infecting begomoviruses showed a contrasting and differential interaction with DNA satellites, not only in the capacity to interact with these molecules but also in the modulation of symptom phenotypes by the satellites.

Conclusion

This is the first report and experimental demonstration of Koch's postulate for begomoviruses associated with radish leaf curl disease. Further observations also provide direct evidence of lateral movement of weed infecting begomovirus in the cultivated crops and the present study also suggests that the exchange of betasatellites with other begomoviruses would create a new disease complex posing a serious threat to crop production.     

Recognition and differentiation of seven whitefly-transmitted geminiviruses from India, and their relationships to African cassava mosaic and Thailand mung bean yellow mosaic viruses

Particles resembling those of geminiviruses were found by immunosorbent electron microscopy in extracts of plants infected in India with bhendi yellow vein mosaic, croton yellow vein mosaic, dolichos yellow mosaic, horsegram yellow mosaic, Indian cassava mosaic and tomato leaf curl viruses. All these viruses were transmitted by Bemisia tabaci whiteflies, all reacted with at least one out of ten monoclonal antibodies to African cassava mosaic virus (ACMV), and all reacted with a probe for ACMV DNA-1, but scarcely or not at all with a full-length probe for ACMV DNA-2. Most of the viruses were distinguished by their host ranges when transmitted by whiteflies, and the rest could be distinguished by their pattern of reactions with the panel of monoclonal antibodies. Horsegram yellow mosaic virus was distinguished from Thailand mung bean yellow mosaic virus by its lack of sap transmissibility, ability to infect Arachis hypogaea, failure to react strongly with the probe for ACMV DNA-2 and its pattern of reactions with the monoclonal antibodies. Structures resembling a ‘string of pearls’, but not geminate particles, were found in leaf extracts containing malvastrum yellow vein mosaic virus. Such extracts reacted with two of the monoclonal antibodies, suggesting that this whitefly-transmitted virus too is a geminivirus. All seven viruses from India can therefore be considered whitefly-transmitted geminiviruses.     

Book Review

To study the variability and to identify the species of Begomovirus associated with yellow mosaic disease of blackgram in Andhra Pradesh, India, infected blackgram samples were collected from six districts belonging to three regions of Andhra Pradesh. The total DNA was isolated by modified CTAB method and amplified with coat protein gene-specific primers (RHA-F and AC abut) resulting in 900?bp gene product. The PCR products were cloned, sequenced and deposited in GenBank. The sequence analysis of six clones showed that the size of amplified CP gene of YMV was 920?bp. Based on nucleotide sequence identity of six isolates representing three regions of Andhra Pradesh, the isolates from Rayalaseema and Telangana region are the same variant of YMV (>99.5% identity) and isolate from coastal Andhra is another variant of YMV (>95.4%) when compared with other region isolates. Comparison of CP gene sequence of YMV-TPT isolate with 27 other isolates in database revealed more than 93.2 and 86.2% identity with MYMIV isolates and less than 80 and 64% identity with MYMY isolates that originate from Indian sub-continent and South-East Asia at nucleotide and amino acid level, respectively. Phylogenetic tree based on CP gene sequences of six isolates with other isolates from GenBank formed unique cluster with MYMIV. Hence the YMV infecting blackgram in Andhra Pradesh is caused by MYMIV rather than MYMY as reported in Tamil Nadu which is adjoining state in southern India.     

A mixture of begomoviruses in leaf curl-affected tobacco in Karnataka, South India

Tobacco leaf curl is widespread in several states in India including Andhra Pradesh, Gujarat, Karnataka, Bihar and West Bengal. Tobacco leaf curl virus (TbLCV) isolates collected from five different parts of India induced four distinct symptom phenotypes (group I, II, III & IV) on tobacco cultivars Samsun and Anand 119 (Valand & Muniyappa, 1992). PCR was performed on DNA extracted from group I and IV leaf curl‐affected tobacco from Karnataka, India using degenerate begomovirus‐specific primers. Subsequent cloning and sequencing of PCR products revealed preliminary evidence for the presence of at least three begomoviruses in the affected material following alignment of a 333 bp region of the coat protein gene (CP). The complete CP and common region (CR) of two putative begomoviruses, Tobacco leaf curl virus‐Karnataka1 (TbLCV‐Kar1) and Tobacco leaf curl virus‐Karnataka2 (TbLCV‐Kar2), were sequenced using PCR clones obtained with designed sequence‐specific primers. Phylogenetic analysis of the CP and CR of TbLCV‐Kar1 and TbLCV‐Kar2 placed them in the Asian Old World begomovirus cluster. The two viruses differed from each other significantly in both the CP gene and the CR (< 90% nucleotide sequence identity). This difference, in conjunction with distinct iterative sequences strongly suggests that these begomoviruses are distinct from one another. Group I and IV tobacco were also found to harbour a possible third begomovirus following the 333 bp CP alignment. Comparison of TbLCV‐Kar1 and TbLCV‐Kar2 with other geminiviruses, showed that both sequences shared high nucleotide sequence identity (> 90%) with other begomoviruses in either the CP or CR, thereby suggesting these viruses to be possible strains of other reported begomoviruses. Combined comparison of the CP and CR sequences however, suggests that the two viruses are not strains of other reported begomoviruses, but may be distinct begomoviruses that could have arisen through recombination events during mixed infections. Phylogenetic comparison demonstrated no significant homology between the Indian tobacco begomoviruses and a tobacco‐infecting begomovirus from Zimbabwe, again showing that as with other geminiviruses, there is a geographic basis for phylogenetic relationships rather than an affiliation with tobacco as a host.