Illumina Sequencing Reveals the First Near-Complete Genome Sequence of Ugandan Passiflora Virus.

Here, we present the first near-complete genome of Ugandan Passiflora virus (UPV) sequenced from a symptomatic sample of KH7 passion fruit (Passiflora edulis Sims) variety. UPV had limited amino acid identity with other potyviruses known to cause passion fruit woodiness disease (PWD). The closest relationship (71.2% amino acid similarity) was with Bean common mosaic necrosis virus.

Next-Generation Sequencing Reveals the First Complete Genome Sequence of Cowpea aphid-borne mosaic virus from Uganda.

We present here the first complete genome sequence of Cowpea aphid-borne mosaic virus (CABMV) isolated from cowpea in Uganda and compare it with five CABMV complete genome sequences from Brazil (2), India (2), and Zimbabwe (1). It most resembled the genomes of two Brazilian isolates (MG-Avr and BR1) and one Indian isolate (RR3).

Identification of relevant non-target organisms exposed to weevil-resistant Bt sweetpotato in Uganda.

Assessment of the impact of transgenic crops on non-target organisms (NTO) is a prerequisite to their release into the target environment for commercial use. Transgenic sweetpotato varieties expressing Cry proteins (Bt sweetpotato) are under development to provide effective protection against sweetpotato weevils (Coleoptera) which cause severe economic losses in sub-Saharan Africa. Like any other pest control technologies, genetically engineered crops expressing insecticidal proteins need to be evaluated to assess potential negative effects on non-target organisms that provide important services to the ecosystem. Beneficial arthropods in sweetpotato production systems can include pollinators, decomposers, and predators and parasitoids of the target insect pest(s). Non-target arthropod species commonly found in sweetpotato fields that are related taxonomically to the target pests were identified through expert consultation and literature review in Uganda where Bt sweetpotato is expected to be initially evaluated. Results indicate the presence of few relevant non-target Coleopterans that could be affected by Coleopteran Bt sweetpotato varieties: ground, rove and ladybird beetles. These insects are important predators in sweetpotato fields. Additionally, honeybee (hymenoptera) is the main pollinator of sweetpotato and used for honey production. Numerous studies have shown that honeybees are unaffected by the Cry proteins currently deployed which are homologous to those of the weevil-resistant Bt sweetpotato. However, because of their feeding behaviour, Bt sweetpotato represents an extremely low hazard due to negligible exposure. Hence, we conclude that there is good evidence from literature and expert opinion that relevant NTOs in sweetpotato fields are unlikely to be affected by the introduction of Bt sweetpotato in Uganda.

Transgenic banana expressing Pflp gene confers enhanced resistance to Xanthomonas wilt disease.

Banana Xanthomonas wilt (BXW), caused by Xanthomonas campestris pv. musacearum, is one of the most important diseases of banana (Musa sp.) and currently considered as the biggest threat to banana production in Great Lakes region of East and Central Africa. The pathogen is highly contagious and its spread has endangered the livelihood of millions of farmers who rely on banana for food and income. The development of disease resistant banana cultivars remains a high priority since farmers are reluctant to employ labor-intensive disease control measures and there is no host plant resistance among banana cultivars. In this study, we demonstrate that BXW can be efficiently controlled using transgenic technology. Transgenic bananas expressing the plant ferredoxin-like protein (Pflp) gene under the regulation of the constitutive CaMV35S promoter were generated using embryogenic cell suspensions of banana. These transgenic lines were characterized by molecular analysis. After challenge with X. campestris pv. musacearum transgenic lines showed high resistance. About 67% of transgenic lines evaluated were completely resistant to BXW. These transgenic lines did not show any disease symptoms after artificial inoculation of in vitro plants under laboratory conditions as well as potted plants in the screen-house, whereas non-transgenic control plants showed severe symptoms resulting in complete wilting. This study confirms that expression of the Pflp gene in banana results in enhanced resistance to BXW. This transgenic technology can provide a timely solution to the BXW pandemic.

Simultaneous virus-specific detection of the two cassava brown streak-associated viruses by RT-PCR reveals wide distribution in East Africa, mixed infections, and infections in Manihot glaziovii.

The expanding cassava brown streak disease (CBSD) epidemic in East Africa is caused by two ipomoviruses (genus Ipomovirus; Potyviridae), namely, Cassava brown streak virus (CBSV), and Ugandan cassava brown streak virus (UCBSV) that was described recently. A reverse transcription polymerase chain reaction (RT-PCR) based diagnostic method was developed in this study for simultaneous virus-specific detection of the two viruses. Results showed that CBSV and UCBSV are distributed widely in the highlands (> 1000 m above the sea level) of the Lake Victoria zone in Uganda and Tanzania and also in the Indian Ocean costal lowlands of Tanzania. Isolates of UCBSV from the Lake Victoria zone were placed to two phylogenetic clusters in accordance with their origin in Uganda or Tanzania, respectively. Mixed infections with CBSV and UCBSV were detected in many cassava plants in the areas surveyed. CBSV was also detected in the perennial species Manihot glaziovii (DNA-barcoded in this study) in Tanzania, which revealed the first virus reservoir other than cassava. The method for detection of CBSV and UCBSV described in this study has important applications for plant quarantine, resistance breeding of cassava, and studies on epidemiology and control of CBSD in East Africa.

Evolution of cassava brown streak disease-associated viruses.

Cassava brown streak disease (CBSD) has occurred in the Indian Ocean coastal lowlands and some areas of Malawi in East Africa for decades, and makes the storage roots of cassava unsuitable for consumption. CBSD is associated with Cassava brown streak virus (CBSV) and the recently described Ugandan cassava brown streak virus (UCBSV) [picorna-like (+)ssRNA viruses; genus Ipomovirus; family Potyviridae]. This study reports the first comprehensive analysis on how evolution is shaping the populations of CBSV and UCBSV. The complete genomes of CBSV and UCBSV (four and eight isolates, respectively) were 69.0-70.3 and 73.6-74.4% identical at the nucleotide and polyprotein amino acid sequence levels, respectively. They contained predictable sites of homologous recombination, mostly in the 3'-proximal part (NIb-HAM1h-CP-3'-UTR) of the genome, but no evidence of recombination between the two viruses was found. The CP-encoding sequences of 22 and 45 isolates of CBSV and UCBSV analysed, respectively, were mainly under purifying selection; however, several sites in the central part of CBSV CP were subjected to positive selection. HAM1h (putative nucleoside triphosphate pyrophosphatase) was the least similar protein between CBSV and UCBSV (aa identity approx. 55%). Both termini of HAM1h contained sites under positive selection in UCBSV. The data imply an on-going but somewhat different evolution of CBSV and UCBSV, which is congruent with the recent widespread outbreak of UCBSV in cassava crops in the highland areas (>1000 m above sea level) of East Africa where CBSD has not caused significant problems in the past.

Genetically distinct strains of Cassava brown streak virus in the Lake Victoria basin and the Indian Ocean coastal area of East Africa.

Six isolates of Cassava brown streak virus (CBSV, genus Ipomovirus; Potyviridae) from the Lake Victoria basin in Uganda and Tanzania were characterized. Virus particles were 650 nm long. The complete coat protein (CP)-encoding sequences (1,101 nucleotides, nt) were 90.7-99.5 and 93.7-99.5% identical at the nt and amino acid (aa) levels, respectively. The 3' untranslated region was 225, 226 or 227 nt long. These eight isolates were only 75.8-77.5% (nt) and 87.0-89.9% (aa) identical when compared to the partial CP sequences (714 nt) of six CBSV isolates characterized previously from the costal lowlands of Tanzania and Mozambique. Hence, two genetically different and geographically separated populations of CSBV exist in East Africa.

Natural wild hosts of sweet potato feathery mottle virus show spatial differences in virus incidence and virus-like diseases in Uganda.

Sweet potato feathery mottle virus (SPFMV, genus Potyvirus) is globally the most common pathogen of sweetpotato. An East African strain of SPFMV incites the severe 'sweetpotato virus disease' in plants co-infected with Sweet potato chlorotic stunt virus and threatens subsistence sweetpotato production in East Africa; however, little is known about its natural hosts and ecology. In all, 2,864 wild plants growing in sweetpotato fields or in their close proximity in Uganda were observed for virus-like symptoms and tested for SPFMV in two surveys (2004 and 2007). SPFMV was detected at different incidence in 22 Ipomoea spp., Hewittia sublobata, and Lepistemon owariensis, of which 19 species are new hosts for SPFMV. Among the SPFMV-positive plants, approximately 60% displayed virus-like symptoms. Although SPFMV incidence was similar in annual and perennial species, virus-like diseases were more common in annuals than perennials. Virus-like diseases and SPFMV were more common in the eastern agroecological zone than the western, central, and northern zones, which contrasted with known incidence of SPFMV in sweetpotato crops. The data on a large number of new natural hosts of SPFMV detected in this study provide novel insights into the ecology of SPFMV in East Africa.

Sequence divergence of four soilborne sugarbeet-infecting viruses.

Soilborne viruses are among the most harmful pathogens of sugarbeet (Beta vulgaris L.ssp. vulgaris) but most of them lack information on genetic variability due to paucity of sequence data. Only one isolate of Beet soil borne virus (BSBV; genus Pomovirus), Beet virus Q (BVQ; genus Pomovirus) and Beet soil borne mosaic virus (BSBMV; genus Benyvirus) has been characterised for the coat protein (CP) gene. In this study, the CP gene sequences of three isolates each of BSBV and Beet necrotic yellow vein virus (BNYVV; genus Benyvirus) (France, Germany and USA), two isolates of BVQ (France and Germany), and one isolate of BSBMV (USA) were determined. Phylogenetic analyses including sequences from databanks indicated that the French BNYVV isolate of this study belongs to so-called P-type, the American isolate to A-type and the German isolate to B-type. The CP genes of the three BSBV isolates characterised in this study and the one available from databank were highly identical (98.4-99.0% at nucleotide level; one variable amino acid). The BSBMV isolate studied here differed from the previously characterised isolate for five nucleotides and four amino acids in the CP region. The two BVQ isolates characterised in this study contained three additional nucleotides resulting in an additional amino acid residue (arginine) at CP position 86, as compared to the only isolate available in databank.

Some molecular characteristics of three viruses from SPVD-affected sweet potato plants in Egypt.

Sweet potato feathery mottle virus (SPFMV, genus Potyvirus, family Potyviridae), Sweet potato chlorotic stunt virus (SPCSV, genus Crinivirus, family Closteroviridae) and sweet potato virus G (SPVG) were detected in naturally infected sweet potato plants grown in the Delta region in Egypt. Before this study, SPVG was reported only from China. Two isolates of SPFMV and one isolate of SPVG were characterized for the 3'-proximal genomic sequences. Phylogenetic analyses indicated that the SPFMV isolates belong to the "russet crack" strain group (RC). Serological tests using monoclonal antibodies, and phylogenetic analysis of a partial sequence of the Hsp70 gene, indicated that the Egyptian SPCSV belongs to the so-called non-East African strain group of SPCSV.

Coat protein sequence analysis reveals occurrence of new strains of Sweet potato feathery mottle virus in Uganda and Tanzania.

The 3'-proximal part (1.8 kb) of the Sweet potato feathery mottle virus (SPFMV) genome was studied in four SPFMV isolates collected from farmers' fields in western Uganda (SPFMV-Bny), eastern Uganda (SPFMV-Sor) and Bagamoyo district, Tanzania (SPFMV-TZ1 and SPFMV-TZ2). Unlike the other three SPFMV isolates, SPFMV-Sor was not detected with the polyclonal antisera to SPFMV. It showed moderately high coat protein (CP) nucleotide (93.3-96.7%) and amino acid (93.6-96.8%) sequence identity to the isolates of the SPFMV strain group C. In contrast, identities (78.1-80.1%, and 79.9-83.1%) to isolates of the SPFMV strain groups O, RC, and the East African (EA) strain group were low. Similar to some isolates (SPFMV-CH2 and SPFMV-6) of strain group C, but different from other SPFMV isolates, SPFMV-Sor contained a deletion of 6 nucleotides in the CP-encoding region (CP amino acid positions 62-63). Phylogenetic analysis of the CP sequences indicated that SPFMV-Sor belongs to the SPFMV strain group C that has not been reported from Africa. Sequence data were obtained for the first time from Tanzanian SPFMV isolates in this study, and phylogenetic analysis indicated that they belong to the strain group EA, which is unique to East Africa.

Sequence variability within the 3'-proximal part of the Sweet potato mild mottle virus genome.

Sweet potato mild mottle virus (SPMMV) is the type member of the genus Ipomovirus (family Potyviridae) and is only known to occur in East Africa. In Uganda, SPMMV is the third most prevalent virus infecting sweet potato. The sequence variability of SPMMV was studied by cloning and sequencing a 1.8-kb fragment representing the 3'-end of the genome of eight SPMMV isolates collected from different districts of Uganda. Sequence comparisons indicated 85.9-99.9% nucleotide sequence identity and 92.8-100% amino acid sequence similarity for the coat protein (CP) encoding region. The nucleotide sequence identity within the 3'-untranslated region (3' UTR) was 84.7-100%, and the region was variable in length (303-308 nucleotides) due to some deletions within the 5'-proximal part of the 3' UTR. Phylogenetic analysis of the CP amino acid sequences revealed significant clustering, indicating the existence of distinguishable sequence variants or strains. The low CP amino acid sequence similarity of SPMMV isolates with other characterised viruses of the family Potyviridae and the unusual putative proteolytic cleavage site at the NIb/CP junction further demonstrate SPMMV as a very distinct virus in the family Potyviridae.